January 2013 I
© 2013 Microsemi Corporation
Fusion Family of Mixed Signal FPGAs
Features and Benefits
High-Performance Reprogrammable Flash Technology
Advanced 130-nm, 7-Layer Metal, Flash-Based CMOS Process
Nonvolatile, Retains Program when Powered Off
Instant On Single-Chip Solution
350 MHz System Performance
Embedded Flash Memory
User Flash Memory – 2 Mbits to 8 Mbits
Configurable 8-, 16-, or 32-Bit Datapath
10 ns Access in Read-Ahead Mode
1 Kbit of Additional FlashROM
Integrated A/D Converter (ADC) and Analog I/O
Up to 12-Bit Resolution and up to 600 Ksps
Internal 2.56 V or External Reference Voltage
ADC: Up to 30 Scalable Analog Input Channels
High-Voltage Input Tolerance: –10.5 V to +12 V
Current Monitor and Temperature Monitor Blocks
Up to 10 MOSFET Gate Driver Outputs
P- and N-Channel Power MOSFET Support
Programmable 1, 3, 10, 30 µA, and 20 mA Drive Strengths
ADC Accuracy is Better than 1%
On-Chip Clocking Support
Internal 100 MHz RC Oscillator (accurate to 1%)
Crystal Oscillator Support (32 KHz to 20 MHz)
Programmable Real-Time Counter (RTC)
6 Clock Conditioning Circuits (CCCs) with 1 or 2 Integrated PLLs
Phase Shift, Multiply/Divide, and Delay Capabilities
Frequency: Input 1.5–350 MHz, Output 0.75–350 MHz
Low Power Consumption
Single 3.3 V Power Supply with On-Chip 1.5 V Regulator
Sleep and Standby Low-Power Modes
In-System Programming (ISP) and Security
ISP with 128-Bit AES via JTAG
FlashLock® Designed to Protect FPGA Contents
Advanced Digital I/O
1.5 V, 1.8 V, 2.5 V, and 3.3 V Mixed-Voltage Operation
Bank-Selectable I/O Voltages – Up to 5 Banks per Chip
Single-Ended I/O Standards: LVTTL, LVCMOS
3.3 V / 2.5 V /1.8 V / 1.5 V, 3.3 V PCI / 3.3 V PCI-X, and
LVCMOS 2.5 V / 5.0 V Input
Differential I/O Standards: LVPECL, LVDS, B-LVDS, M-LVDS
Built-In I/O Registers
700 Mbps DDR Operation
Hot-Swappable I/Os
Programmable Output Slew Rate, Drive Strength, and Weak
Pull-Up/Down Resistor
Pin-Compatible Packages across the Fusion® Family
SRAMs and FIFOs
Variable-Aspect-Ratio 4,608-Bit SRAM Blocks (×1, ×2, ×4, ×9,
and ×18 organizations available)
True Dual-Port SRAM (except ×18)
Programmable Embedded FIFO Control Logic
Soft ARM Cortex-M1 Fusion Devices (M1)
•ARM
® Cortex-™M1–Enabled
Pigeon Point ATCA IP Support (P1)
Targeted to Pigeon Point® Board Management Reference
(BMR) Starter Kits
Designed in Partnership with Pigeon Point Systems
ARM Cortex-M1 Enabled
MicroBlade Advanced Mezzanine Card Support (U1)
Targeted to Advanced Mezzanine Card (AdvancedMC™ Designs)
Designed in Partnership with MicroBlade
8051-Based Module Management Controller (MMC)
Table 1 • Fusion Family
Fusion Devices AFS090 AFS250 AFS600 AFS1500
ARM Cortex-M1* Devices M1AFS250 M1AFS600 M1AFS1500
Pigeon Point Devices P1AFS600 P1AFS1500
MicroBlade Devices U1AFS250 U1AFS600 U1AFS1500
General
Information
System Gates 90,000 250,000 600,000 1,500,000
Tiles (D-flip-flops) 2,304 6,144 13,824 38,400
Secure (AES) ISP Yes Yes Yes Yes
PLLs 1122
Globals 18 18 18 18
Memory
Flash Memory Blocks (2 Mbits) 1 1 2 4
Total Flash Memory Bits 2M 2M 4M 8M
FlashROM Bits 1,024 1,024 1,024 1,024
RAM Blocks (4,608 bits) 6 8 24 60
RAM kbits 27 36 108 270
Analog and I/Os
Analog Quads 5 6 10 10
Analog Input Channels 15 18 30 30
Gate Driver Outputs 5 6 10 10
I/O Banks (+ JTAG) 4 4 5 5
Maximum Digital I/Os 75 114 172 252
Analog I/Os 20 24 40 40
Note: *Refer to the Cortex-M1 product brief for more information.
Revision 4
Fusion Family of Mixed Signal FPGAs
II Revision 4
Fusion Device Architecture Overview
Package I/Os: Single-/Double-Ended (Analog)
Figure 1 • Fusion Device Architecture Overview (AFS600)
Fusion Devices AFS090 AFS250 AFS600 AFS1500
ARM Cortex-M1 Devices M1AFS250 M1AFS600 M1AFS1500
Pigeon Point Devices P1AFS600 1P1AFS1500 1
MicroBlade Devices U1AFS250 2U1AFS600 2U1AFS1500 2
QN108 37/9 (16)
QN180 60/16 (20) 65/15 (24)
PQ208 393/26 (24) 95/46 (40)
FG256 75/22 (20) 114/37 (24) 119/58 (40) 119/58 (40)
FG484 172/86 (40) 223/109 (40)
FG676 252/126 (40)
Notes:
1. Pigeon Point devices are only offered in FG484 and FG256.
2. MicroBlade devices are only offered in FG256.
3. Fusion devices in the same package are pin compatible with the exception of the PQ208 package (AFS250 and AFS600).
VersaTile
CCC
CCC
I/Os
OSC
CCC/PLL
Bank 0
Bank 4
Bank 2
Bank 1
Bank 3
SRAM Block
4,608-Bit Dual-Port SRAM
or FIFO Block
SRAM Block
4,608-Bit Dual-Port SRAM
or FIFO Block
Flash Memory Blocks Flash Memory BlocksADC
Analog
Quad
ISP AES
Decryption
User Nonvolatile
FlashROM Charge Pumps
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Analog
Quad
Fusion Family of Mixed Signal FPGAs
Revision 4 III
Product Ordering Codes
Fusion Device Status
Notes:
1. For Fusion devices, Quad Flat No Lead packages are only offered as RoHS compliant, QNG packages.
2. MicroBlade and Pigeon Point devices only support FG packages.
Fusion Status Cortex-M1 Status Pigeon Point Status MicroBlade Status
AFS090 Production
AFS250 Production M1AFS250 Production U1AFS250 Production
AFS600 Production M1AFS600 Production P1AFS600 Production U1AFS600 Production
AFS1500 Production M1AFS1500 Production P1AFS1500 Production U1AFS1500 Production
M1AFS600 FG
_
Part Number
Fusion Devices
Speed Grade
1
Blank = Standard
1 = 15% Faster than Standard
2 = 25% Faster than Standard
Package Type
QN =Quad Flat No Lead (0.5 mm pitch)
256 IG
Package Lead Count
Y
Security Feature
Application (junction temperature range)
Blank = Commercial (0 to +85°C)
I = Industrial (–40 to +100°C)
PP = Pre-Production
ES = Engineering Silicon (room temperature only)
90,000 System Gates
AFS090 =
250,000 System Gates
AFS250 =
ARM-Enabled Fusion Devices
600,000 System Gates
AFS600 =
1,500,000 System Gates
AFS1500 =
MicroBlade Devices
250,000 System Gates
U1AFS250 =
600,000 System Gates
U1AFS600 =
1,500,000 System Gates
U1AFS1500 =
Pigeon Point Devices
600,000 System Gates
P1AFS600 =
1,500,000 System Gates
P1AFS1500 =
250,000 System Gates
M1AFS250 =
600,000 System Gates
M1AFS600 =
1,500,000 System Gates
M1AFS1500 =
PQ =Plastic Quad Flat Pack (0.5 mm pitch)
FG =Fine Pitch Ball Grid Array (1.0 mm pitch)
Lead-Free Packaging Options
Blank = Standard Packaging
G = RoHS-Compliant (green) Packaging
1
2
Y = Device Includes License to Implement IP Based on
the Cryptography Research, Inc. (CRI) Patent Portfolio
Blank = Device Does Not Include License to Implement IP Based
on the Cryptography Research, Inc. (CRI) Patent Portfolio
Fusion Family of Mixed Signal FPGAs
IV Revision 4
Temperature Grade Offerings
Speed Grade and Temperature Grade Matrix
Contact your local Microsemi SoC Products Group representative for device availability:
http://www.microsemi.com/soc/contact/offices/index.html.
Cortex-M1, Pigeon Point, and MicroBlade Fusion Device Information
This datasheet provides information for all Fusion (AFS), Cortex-M1 (M1), Pigeon Point (P1), and MicroBlade (U1) devices. The
remainder of the document will only list the Fusion (AFS) devices. Please apply relevant information to M1, P1, and U1 devices
when appropriate. Please note the following:
Cortex-M1 devices are offered in the same speed grades and packages as basic Fusion devices.
Pigeon Point devices are only offered in –2 speed grade and FG484 and FG256 packages.
MicroBlade devices are only offered in standard speed grade and the FG256 package.
Fusion Devices AFS090 AFS250 AFS600 AFS1500
ARM Cortex-M1 Devices M1AFS250 M1AFS600 M1AFS1500
Pigeon Point Devices P1AFS600 3P1AFS1500 3
MicroBlade Devices U1AFS250 4U1AFS600 4U1AFS1500 4
QN108 C, I
QN180 C, I C, I
PQ208 C, I C, I
FG256 C, IC, IC, IC, I
FG484 C, I C, I
FG676 –––C, I
Notes:
1. C = Commercial Temperature Range: 0°C to 85°C Junction
2. I = Industrial Temperature Range: –40°C to 100°C Junction
3. Pigeon Point devices are only offered in FG484 and FG256.
4. MicroBlade devices are only offered in FG256.
Std.1–1 –22
C3333
I4333
Notes:
1. MicroBlade devices are only offered in standard speed grade.
2. Pigeon Point devices are only offered in –2 speed grade.
3. C = Commercial Temperature Range: 0°C to 85°C Junction
4. I = Industrial Temperature Range: –40°C to 100°C Junction
Fusion Family of Mixed Signal FPGAs
Revision 4 V
Table of Contents
Fusion Device Family Overview
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
General Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
Unprecedented Integration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4
Related Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-10
Device Architecture
Fusion Stack Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1
Core Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
Clocking Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-19
Real-Time Counter System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-33
Embedded Memories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-41
Analog Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-79
Analog Configuration MUX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-129
User I/Os . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-135
Pin Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-226
Security . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-231
DC and Power Characteristics
General Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Calculating Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10
Power Consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-32
Package Pin Assignments
QN108 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
QN180 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
PQ208 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-7
FG256 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
FG484 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-19
FG676 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-27
Datasheet Information
List of Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Datasheet Categories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-17
Safety Critical, Life Support, and High-Reliability Applications Policy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-17
Revision 4 1-1
1 – Fusion Device Family Overview
Introduction
The Fusion mixed signal FPGA satisfies the demand from system architects for a device that simplifies
design and unleashes their creativity. As the world’s first mixed signal programmable logic family, Fusion
integrates mixed signal analog, flash memory, and FPGA fabric in a monolithic device. Fusion devices
enable designers to quickly move from concept to completed design and then deliver feature-rich
systems to market. This new technology takes advantage of the unique properties of Microsemi flash-
based FPGAs, including a high-isolation, triple-well process and the ability to support high-voltage
transistors to meet the demanding requirements of mixed signal system design.
Fusion mixed signal FPGAs bring the benefits of programmable logic to many application areas,
including power management, smart battery charging, clock generation and management, and motor
control. Until now, these applications have only been implemented with costly and space-consuming
discrete analog components or mixed signal ASIC solutions. Fusion mixed signal FPGAs present new
capabilities for system development by allowing designers to integrate a wide range of functionality into a
single device, while at the same time offering the flexibility of upgrades late in the manufacturing process
or after the device is in the field. Fusion devices provide an excellent alternative to costly and time-
consuming mixed signal ASIC designs. In addition, when used in conjunction with the ARM Cortex-M1
processor, Fusion technology represents the definitive mixed signal FPGA platform.
Flash-based Fusion devices are Instant On. As soon as system power is applied and within normal
operating specifications, Fusion devices are working. Fusion devices have a 128-bit flash-based lock and
industry-leading AES decryption, used to secure programmed intellectual property (IP) and configuration
data. Fusion devices are the most comprehensive single-chip analog and digital programmable logic
solution available today.
To support this new ground-breaking technology, Microsemi has developed a series of major tool
innovations to help maximize designer productivity. Implemented as extensions to the popular Microsemi
Libero® System-on-Chip (SoC) software, these new tools allow designers to easily instantiate and
configure peripherals within a design, establish links between peripherals, create or import building
blocks or reference designs, and perform hardware verification. This tool suite will also add
comprehensive hardware/software debug capability as well as a suite of utilities to simplify development
of embedded soft-processor-based solutions.
General Description
The Fusion family, based on the highly successful ProASIC®3 and ProASIC3E flash FPGA architecture,
has been designed as a high-performance, programmable, mixed signal platform. By combining an
advanced flash FPGA core with flash memory blocks and analog peripherals, Fusion devices
dramatically simplify system design and, as a result, dramatically reduce overall system cost and board
space.
The state-of-the-art flash memory technology offers high-density integrated flash memory blocks,
enabling savings in cost, power, and board area relative to external flash solutions, while providing
increased flexibility and performance. The flash memory blocks and integrated analog peripherals enable
true mixed-mode programmable logic designs. Two examples are using an on-chip soft processor to
implement a fully functional flash MCU and using high-speed FPGA logic to offer system and power
supervisory capabilities. Instant On, and capable of operating from a single 3.3 V supply, the Fusion
family is ideally suited for system management and control applications.
The devices in the Fusion family are categorized by FPGA core density. Each family member contains
many peripherals, including flash memory blocks, an analog-to-digital-converter (ADC), high-drive
outputs, both RC and crystal oscillators, and a real-time counter (RTC). This provides the user with a
high level of flexibility and integration to support a wide variety of mixed signal applications. The flash
memory block capacity ranges from 2 Mbits to 8 Mbits. The integrated 12-bit ADC supports up to 30
independently configurable input channels.
Fusion Device Family Overview
1-2 Revision 4
The on-chip crystal and RC oscillators work in conjunction with the integrated phase-locked loops (PLLs)
to provide clocking support to the FPGA array and on-chip resources. In addition to supporting typical
RTC uses such as watchdog timer, the Fusion RTC can control the on-chip voltage regulator to power
down the device (FPGA fabric, flash memory block, and ADC), enabling a low power standby mode.
The Fusion family offers revolutionary features, never before available in an FPGA. The nonvolatile flash
technology gives the Fusion solution the advantage of being a highly secure, low power, single-chip
solution that is Instant On. Fusion is reprogrammable and offers time-to-market benefits at an ASIC-level
unit cost. These features enable designers to create high-density systems using existing ASIC or FPGA
design flows and tools.
Flash Advantages
Reduced Cost of Ownership
Advantages to the designer extend beyond low unit cost, high performance, and ease of use. Flash-
based Fusion devices are Instant On and do not need to be loaded from an external boot PROM. On-
board security mechanisms prevent access to the programming information and enable remote updates
of the FPGA logic that are protected with high level security. Designers can perform remote in-system
reprogramming to support future design iterations and field upgrades, with confidence that valuable IP is
highly unlikely to be compromised or copied. ISP can be performed using the industry-standard AES
algorithm with MAC data authentication on the device. The Fusion family device architecture mitigates
the need for ASIC migration at higher user volumes. This makes the Fusion family a cost-effective ASIC
replacement solution for applications in the consumer, networking and communications, computing, and
avionics markets.
Security
As the nonvolatile, flash-based Fusion family requires no boot PROM, there is no vulnerable external
bitstream. Fusion devices incorporate FlashLock, which provides a unique combination of
reprogrammability and design security without external overhead, advantages that only an FPGA with
nonvolatile flash programming can offer.
Fusion devices utilize a 128-bit flash-based key lock and a separate AES key to provide the highest level
of protection in the FPGA industry for programmed IP and configuration data. The FlashROM data in
Fusion devices can also be encrypted prior to loading. Additionally, the flash memory blocks can be
programmed during runtime using the industry-leading AES-128 block cipher encryption standard (FIPS
Publication 192). The AES standard was adopted by the National Institute of Standards and Technology
(NIST) in 2000 and replaces the DES standard, which was adopted in 1977. Fusion devices have a built-
in AES decryption engine and a flash-based AES key that make Fusion devices the most comprehensive
programmable logic device security solution available today. Fusion devices with AES-based security
provide a high level of protection for remote field updates over public networks, such as the Internet, and
are designed to ensure that valuable IP remains out of the hands of system overbuilders, system cloners,
and IP thieves. As an additional security measure, the FPGA configuration data of a programmed Fusion
device cannot be read back, although secure design verification is possible. During design, the user
controls and defines both internal and external access to the flash memory blocks.
Security, built into the FPGA fabric, is an inherent component of the Fusion family. The flash cells are
located beneath seven metal layers, and many device design and layout techniques have been used to
make invasive attacks extremely difficult. Fusion with FlashLock and AES security is unique in being
highly resistant to both invasive and noninvasive attacks. Your valuable IP is protected with industry-
standard security, making remote ISP possible. A Fusion device provides the best available security for
programmable logic designs.
Single Chip
Flash-based FPGAs store their configuration information in on-chip flash cells. Once programmed, the
configuration data is an inherent part of the FPGA structure, and no external configuration data needs to
be loaded at system power-up (unlike SRAM-based FPGAs). Therefore, flash-based Fusion FPGAs do
not require system configuration components such as EEPROMs or microcontrollers to load device
configuration data. This reduces bill-of-materials costs and PCB area, and increases security and system
reliability.
Fusion Family of Mixed Signal FPGAs
Revision 4 1-3
Instant On
Flash-based Fusion devices are Level 0 Instant On. Instant On Fusion devices greatly simplify total
system design and reduce total system cost by eliminating the need for CPLDs. The Fusion Instant On
clocking (PLLs) replaces off-chip clocking resources. The Fusion mix of Instant On clocking and analog
resources makes these devices an excellent choice for both system supervisor and system management
functions. Instant On from a single 3.3 V source enables Fusion devices to initiate, control, and monitor
multiple voltage supplies while also providing system clocks. In addition, glitches and brownouts in
system power will not corrupt the Fusion device flash configuration. Unlike SRAM-based FPGAs, the
device will not have to be reloaded when system power is restored. This enables reduction or complete
removal of expensive voltage monitor and brownout detection devices from the PCB design. Flash-
based Fusion devices simplify total system design and reduce cost and design risk, while increasing
system reliability.
Firm Errors
Firm errors occur most commonly when high-energy neutrons, generated in the upper atmosphere, strike
a configuration cell of an SRAM FPGA. The energy of the collision can change the state of the
configuration cell and thus change the logic, routing, or I/O behavior in an unpredictable way. Another
source of radiation-induced firm errors is alpha particles. For an alpha to cause a soft or firm error, its
source must be in very close proximity to the affected circuit. The alpha source must be in the package
molding compound or in the die itself. While low-alpha molding compounds are being used increasingly,
this helps reduce but does not entirely eliminate alpha-induced firm errors.
Firm errors are impossible to prevent in SRAM FPGAs. The consequence of this type of error can be a
complete system failure. Firm errors do not occur in Fusion flash-based FPGAs. Once it is programmed,
the flash cell configuration element of Fusion FPGAs cannot be altered by high-energy neutrons and is
therefore immune to errors from them.
Recoverable (or soft) errors occur in the user data SRAMs of all FPGA devices. These can easily be
mitigated by using error detection and correction (EDAC) circuitry built into the FPGA fabric.
Low Power
Flash-based Fusion devices exhibit power characteristics similar to those of an ASIC, making them an
ideal choice for power-sensitive applications. With Fusion devices, there is no power-on current surge
and no high current transition, both of which occur on many FPGAs.
Fusion devices also have low dynamic power consumption and support both low power standby mode
and very low power sleep mode, offering further power savings.
Advanced Flash Technology
The Fusion family offers many benefits, including nonvolatility and reprogrammability through an
advanced flash-based, 130-nm LVCMOS process with seven layers of metal. Standard CMOS design
techniques are used to implement logic and control functions. The combination of fine granularity,
enhanced flexible routing resources, and abundant flash switches allows very high logic utilization (much
higher than competing SRAM technologies) without compromising device routability or performance.
Logic functions within the device are interconnected through a four-level routing hierarchy.
Advanced Architecture
The proprietary Fusion architecture provides granularity comparable to standard-cell ASICs. The Fusion
device consists of several distinct and programmable architectural features, including the following
(Figure 1-1 on page 1-5):
Embedded memories
Flash memory blocks
–FlashROM
SRAM and FIFO
Clocking resources
PLL and CCC
Fusion Device Family Overview
1-4 Revision 4
RC oscillator
Crystal oscillator
No-Glitch MUX (NGMUX)
Digital I/Os with advanced I/O standards
FPGA VersaTiles
Analog components
–ADC
Analog I/Os supporting voltage, current, and temperature monitoring
1.5 V on-board voltage regulator
Real-time counter
The FPGA core consists of a sea of VersaTiles. Each VersaTile can be configured as a three-input logic
lookup table (LUT) equivalent or a D-flip-flop or latch (with or without enable) by programming the
appropriate flash switch interconnections. This versatility allows efficient use of the FPGA fabric. The
VersaTile capability is unique to the Microsemi families of flash-based FPGAs. VersaTiles and larger
functions are connected with any of the four levels of routing hierarchy. Flash switches are distributed
throughout the device to provide nonvolatile, reconfigurable interconnect programming. Maximum core
utilization is possible for virtually any design.
In addition, extensive on-chip programming circuitry allows for rapid (3.3 V) single-voltage programming
of Fusion devices via an IEEE 1532 JTAG interface.
Unprecedented Integration
Integrated Analog Blocks and Analog I/Os
Fusion devices offer robust and flexible analog mixed signal capability in addition to the high-
performance flash FPGA fabric and flash memory block. The many built-in analog peripherals include a
configurable 32:1 input analog MUX, up to 10 independent MOSFET gate driver outputs, and a
configurable ADC. The ADC supports 8-, 10-, and 12-bit modes of operation with a cumulative sample
rate up to 600 k samples per second (Ksps), differential nonlinearity (DNL) < 1.0 LSB, and Total
Unadjusted Error (TUE) of 0.72 LSB in 10-bit mode. The TUE is used for characterization of the
conversion error and includes errors from all sources, such as offset and linearity. Internal bandgap
circuitry offers 1% voltage reference accuracy with the flexibility of utilizing an external reference voltage.
The ADC channel sampling sequence and sampling rate are programmable and implemented in the
FPGA logic using Designer and Libero SoC software tool support.
Two channels of the 32-channel ADCMUX are dedicated. Channel 0 is connected internally to VCC and
can be used to monitor core power supply. Channel 31 is connected to an internal temperature diode
which can be used to monitor device temperature. The 30 remaining channels can be connected to
external analog signals. The exact number of I/Os available for external connection signals is device-
dependent (refer to the "Fusion Family" table on page I for details).
With Fusion, Microsemi also introduces the Analog Quad I/O structure (Figure 1-1 on page 1-5). Each
quad consists of three analog inputs and one gate driver. Each quad can be configured in various built-in
circuit combinations, such as three prescaler circuits, three digital input circuits, a current monitor circuit,
or a temperature monitor circuit. Each prescaler has multiple scaling factors programmed by FPGA
signals to support a large range of analog inputs with positive or negative polarity. When the current
monitor circuit is selected, two adjacent analog inputs measure the voltage drop across a small external
sense resistor. For more information, refer to the "Analog System Characteristics" section on
page 2-120. Built-in operational amplifiers amplify small voltage signals for accurate current
measurement. One analog input in each quad can be connected to an external temperature monitor
diode. In addition to the external temperature monitor diode(s), a Fusion device can monitor an internal
temperature diode using dedicated channel 31 of the ADCMUX.
Figure 1-1 on page 1-5 illustrates a typical use of the Analog Quad I/O structure. The Analog Quad
shown is configured to monitor and control an external power supply. The AV pad measures the source
of the power supply. The AC pad measures the voltage drop across an external sense resistor to
Fusion Family of Mixed Signal FPGAs
Revision 4 1-5
calculate current. The AG MOSFET gate driver pad turns the external MOSFET on and off. The AT pad
measures the load-side voltage level.
Embedded Memories
Flash Memory Blocks
The flash memory available in each Fusion device is composed of one to four flash blocks, each 2 Mbits
in density. Each block operates independently with a dedicated flash controller and interface. Fusion
flash memory blocks combine fast access times (60 ns random access and 10 ns access in Read-Ahead
mode) with a configurable 8-, 16-, or 32-bit datapath, enabling high-speed flash operation without wait
states. The memory block is organized in pages and sectors. Each page has 128 bytes, with 33 pages
comprising one sector and 64 sectors per block. The flash block can support multiple partitions. The only
constraint on size is that partition boundaries must coincide with page boundaries. The flexibility and
granularity enable many use models and allow added granularity in programming updates.
Fusion devices support two methods of external access to the flash memory blocks. The first method is a
serial interface that features a built-in JTAG-compliant port, which allows in-system programmability
during user or monitor/test modes. This serial interface supports programming of an AES-encrypted
stream. Data protected with security measures can be passed through the JTAG interface, decrypted,
and then programmed in the flash block. The second method is a soft parallel interface.
FPGA logic or an on-chip soft microprocessor can access flash memory through the parallel interface.
Since the flash parallel interface is implemented in the FPGA fabric, it can potentially be customized to
meet special user requirements. For more information, refer to the CoreCFI Handbook. The flash
memory parallel interface provides configurable byte-wide (×8), word-wide (×16), or dual-word-wide
Figure 1-1 Analog Quad
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Power Line Side Load Side
Pre-
scaler
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor/Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pre-
scaler
Pre-
scaler
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip R
pullup
From FPGA
(GDONx)
Fusion Device Family Overview
1-6 Revision 4
(×32) data-port options. Through the programmable flash parallel interface, the on-chip and off-chip
memories can be cascaded for wider or deeper configurations.
The flash memory has built-in security. The user can configure either the entire flash block or the small
blocks to protect against unintentional or intrusive attempts to change or destroy the storage contents.
Each on-chip flash memory block has a dedicated controller, enabling each block to operate
independently.
The flash block logic consists of the following sub-blocks:
Flash block – Contains all stored data. The flash block contains 64 sectors and each sector
contains 33 pages of data.
Page Buffer – Contains the contents of the current page being modified. A page contains 8 blocks
of data.
Block Buffer – Contains the contents of the last block accessed. A block contains 128 data bits.
ECC Logic – The flash memory stores error correction information with each block to perform
single-bit error correction and double-bit error detection on all data blocks.
User Nonvolatile FlashROM
In addition to the flash blocks, Fusion devices have 1 Kbit of user-accessible, nonvolatile FlashROM on-
chip. The FlashROM is organized as 8×128-bit pages. The FlashROM can be used in diverse system
applications:
Internet protocol addressing (wireless or fixed)
System calibration settings
Device serialization and/or inventory control
Subscription-based business models (for example, set-top boxes)
Secure key storage for communications algorithms protected by security
Asset management/tracking
Date stamping
Version management
The FlashROM is written using the standard IEEE 1532 JTAG programming interface. Pages can be
individually programmed (erased and written). On-chip AES decryption can be used selectively over
public networks to load data such as security keys stored in the FlashROM for a user design.
The FlashROM can be programmed (erased and written) via the JTAG programming interface, and its
contents can be read back either through the JTAG programming interface or via direct FPGA core
addressing.
The FlashPoint tool in the Fusion development software solutions, Libero SoC and Designer, has
extensive support for flash memory blocks and FlashROM. One such feature is auto-generation of
sequential programming files for applications requiring a unique serial number in each part. Another
feature allows the inclusion of static data for system version control. Data for the FlashROM can be
generated quickly and easily using the Libero SoC and Designer software tools. Comprehensive
programming file support is also included to allow for easy programming of large numbers of parts with
differing FlashROM contents.
SRAM and FIFO
Fusion devices have embedded SRAM blocks along the north and south sides of the device. Each
variable-aspect-ratio SRAM block is 4,608 bits in size. Available memory configurations are 256×18,
512×9, 1k×4, 2k×2, and 4k×1 bits. The individual blocks have independent read and write ports that can
be configured with different bit widths on each port. For example, data can be written through a 4-bit port
and read as a single bitstream. The SRAM blocks can be initialized from the flash memory blocks or via
the device JTAG port (ROM emulation mode), using the UJTAG macro.
In addition, every SRAM block has an embedded FIFO control unit. The control unit allows the SRAM
block to be configured as a synchronous FIFO without using additional core VersaTiles. The FIFO width
and depth are programmable. The FIFO also features programmable Almost Empty (AEMPTY) and
Almost Full (AFULL) flags in addition to the normal EMPTY and FULL flags. The embedded FIFO control
unit contains the counters necessary for the generation of the read and write address pointers. The
SRAM/FIFO blocks can be cascaded to create larger configurations.
Fusion Family of Mixed Signal FPGAs
Revision 4 1-7
Clock Resources
PLLs and Clock Conditioning Circuits (CCCs)
Fusion devices provide designers with very flexible clock conditioning capabilities. Each member of the
Fusion family contains six CCCs. In the two larger family members, two of these CCCs also include a
PLL; the smaller devices support one PLL.
The inputs of the CCC blocks are accessible from the FPGA core or from one of several inputs with
dedicated CCC block connections.
The CCC block has the following key features:
Wide input frequency range (fIN_CCC) = 1.5MHz to 350MHz
Output frequency range (fOUT_CCC) = 0.75 MHz to 350 MHz
Clock phase adjustment via programmable and fixed delays from –6.275 ns to +8.75 ns
Clock skew minimization (PLL)
Clock frequency synthesis (PLL)
On-chip analog clocking resources usable as inputs:
100 MHz on-chip RC oscillator
Crystal oscillator
Additional CCC specifications:
Internal phase shift = 0°, 90°, 180°, and 270°
Output duty cycle = 50% ± 1.5%
Low output jitter. Samples of peak-to-peak period jitter when a single global network is used:
70 ps at 350 MHz
90 ps at 100 MHz
180 ps at 24 MHz
Worst case < 2.5% × clock period
Maximum acquisition time = 150 µs
Low power consumption of 5 mW
Global Clocking
Fusion devices have extensive support for multiple clocking domains. In addition to the CCC and PLL
support described above, there are on-chip oscillators as well as a comprehensive global clock
distribution network.
The integrated RC oscillator generates a 100 MHz clock. It is used internally to provide a known clock
source to the flash memory read and write control. It can also be used as a source for the PLLs.
The crystal oscillator supports the following operating modes:
Crystal (32.768 KHz to 20 MHz)
Ceramic (500 KHz to 8 MHz)
RC (32.768 KHz to 4 MHz)
Each VersaTile input and output port has access to nine VersaNets: six main and three quadrant global
networks. The VersaNets can be driven by the CCC or directly accessed from the core via MUXes. The
VersaNets can be used to distribute low-skew clock signals or for rapid distribution of high-fanout nets.
Digital I/Os with Advanced I/O Standards
The Fusion family of FPGAs features a flexible digital I/O structure, supporting a range of voltages (1.5 V,
1.8 V, 2.5 V, and 3.3 V). Fusion FPGAs support many different digital I/O standards, both single-ended
and differential.
The I/Os are organized into banks, with four or five banks per device. The configuration of these banks
determines the I/O standards supported. The banks along the east and west sides of the device support
the full range of I/O standards (single-ended and differential). The south bank supports the Analog Quads
(analog I/O). In the family's two smaller devices, the north bank supports multiple single-ended digital I/O
Fusion Device Family Overview
1-8 Revision 4
standards. In the family’s larger devices, the north bank is divided into two banks of digital Pro I/Os,
supporting a wide variety of single-ended, differential, and voltage-referenced I/O standards.
Each I/O module contains several input, output, and enable registers. These registers allow the
implementation of the following applications:
Single-Data-Rate (SDR) applications
Double-Data-Rate (DDR) applications—DDR LVDS I/O for chip-to-chip communications
Fusion banks support LVPECL, LVDS, BLVDS, and M-LVDS with 20 multi-drop points.
VersaTiles
The Fusion core consists of VersaTiles, which are also used in the successful ProASIC3 family. The
Fusion VersaTile supports the following:
All 3-input logic functions—LUT-3 equivalent
Latch with clear or set
D-flip-flop with clear or set and optional enable
Refer to Figure 1-2 for the VersaTile configuration arrangement.
Specifying I/O States During Programming
You can modify the I/O states during programming in FlashPro. In FlashPro, this feature is supported for
PDB files generated from Designer v8.5 or greater. See the FlashPro User’s Guide for more information.
Note: PDB files generated from Designer v8.1 to Designer v8.4 (including all service packs) have
limited display of Pin Numbers only.
The I/Os are controlled by the JTAG Boundary Scan register during programming, except for the analog
pins (AC, AT and AV). The Boundary Scan register of the AG pin can be used to enable/disable the gate
driver in software v9.0.
1. Load a PDB from the FlashPro GUI. You must have a PDB loaded to modify the I/O states during
programming.
2. From the FlashPro GUI, click PDB Configuration. A FlashPoint – Programming File Generator
window appears.
3. Click the Specify I/O States During Programming button to display the Specify I/O States
During Programming dialog box.
4. Sort the pins as desired by clicking any of the column headers to sort the entries by that header.
Select the I/Os you wish to modify (Figure 1-3 on page 1-9).
5. Set the I/O Output State. You can set Basic I/O settings if you want to use the default I/O settings
for your pins, or use Custom I/O settings to customize the settings for each pin. Basic I/O state
settings:
1 – I/O is set to drive out logic High
0 – I/O is set to drive out logic Low
Last Known State – I/O is set to the last value that was driven out prior to entering the
programming mode, and then held at that value during programming
Z -Tri-State: I/O is tristated
Figure 1-2 VersaTile Configurations
X1
Y
X2
X3
LUT-3
Data Y
CLK
Enable
CLR
D-FFE
Data Y
CLK
CLR
D-FF
LUT-3 Equivalent D-Flip-Flop with Clear or Set Enable D-Flip-Flop with Clear or Set
Fusion Family of Mixed Signal FPGAs
Revision 4 1-9
6. Click OK to return to the FlashPoint – Programming File Generator window.
I/O States During programming are saved to the ADB and resulting programming files after completing
programming file generation.
Figure 1-3 • I/O States During Programming Window
Fusion Device Family Overview
1-10 Revision 4
Related Documents
Datasheet
Core8051
www.microsemi.com/soc/ipdocs/Core8051_DS.pdf
Application Notes
Fusion FlashROM
http://www.microsemi.com/soc/documents/Fusion_FROM_AN.pdf
Fusion SRAM/FIFO Blocks
http://www.microsemi.com/soc/documents/Fusion_RAM_FIFO_AN.pdf
Using DDR in Fusion Devices
http://www.microsemi.com/soc/documents/Fusion_DDR_AN.pdf
Fusion Security
http://www.microsemi.com/soc/documents/Fusion_Security_AN.pdf
Using Fusion RAM as Multipliers
http://www.microsemi.com/soc/documents/Fusion_Multipliers_AN.pdf
Handbook
Cortex-M1 Handbook
www.microsemi.com/soc/documents/CortexM1_HB.pdf
Users Guides
Designer User's Guide
http://www.microsemi.com/soc/documents/designer_UG.pdf
Fusion FPGA Fabric User’s Guide
http://www.microsemi.com/soc/documents/Fusion_UG.pdf
IGLOO, ProASIC3, SmartFusion and Fusion Macro Library Guide
http://www.microsemi.com/soc/documents/pa3_libguide_ug.pdf
SmartGen, FlashROM, Flash Memory System Builder, and Analog System Builder User's Guide
http://www.microsemi.com/soc/documents/genguide_ug.pdf
White Papers
Fusion Technology
http://www.microsemi.com/soc/documents/Fusion_Tech_WP.pdf
Revision 4 2-1
2 – Device Architecture
Fusion Stack Architecture
To manage the unprecedented level of integration in Fusion devices, Microsemi developed the Fusion
technology stack (Figure 2-1). This layered model offers a flexible design environment, enabling design
at very high and very low levels of abstraction. Fusion peripherals include hard analog IP and hard and
soft digital IP. Peripherals communicate across the FPGA fabric via a layer of soft gates—the Fusion
backbone. Much more than a common bus interface, this Fusion backbone integrates a micro-sequencer
within the FPGA fabric and configures the individual peripherals and supports low-level processing of
peripheral data. Fusion applets are application building blocks that can control and respond to
peripherals and other system signals. Applets can be rapidly combined to create large applications. The
technology is scalable across devices, families, design types, and user expertise, and supports a well-
defined interface for external IP and tool integration.
At the lowest level, Level 0, are Fusion peripherals. These are configurable functional blocks that can be
hardwired structures such as a PLL or analog input channel, or soft (FPGA gate) blocks such as a UART
or two-wire serial interface. The Fusion peripherals are configurable and support a standard interface to
facilitate communication and implementation.
Connecting and controlling access to the peripherals is the Fusion backbone, Level 1. The backbone is a
soft-gate structure, scalable to any number of peripherals. The backbone is a bus and much more; it
manages peripheral configuration to ensure proper operation. Leveraging the common peripheral
interface and a low-level state machine, the backbone efficiently offloads peripheral management from
the system design. The backbone can set and clear flags based upon peripheral behavior and can define
performance criteria. The flexibility of the stack enables a designer to configure the silicon, directly
bypassing the backbone if that level of control is desired.
One step up from the backbone is the Fusion applet, Level 2. The applet is an application building block
that implements a specific function in FPGA gates. It can react to stimuli and board-level events coming
through the backbone or from other sources, and responds to these stimuli by accessing and
manipulating peripherals via the backbone or initiating some other action. An applet controls or responds
to the peripheral(s). Applets can be easily imported or exported from the design environment. The applet
structure is open and well-defined, enabling users to import applets from Microsemi, system developers,
third parties, and user groups.
Note: Levels 1, 2, and 3 are implemented in FPGA logic gates.
Figure 2-1 • Fusion Architecture Stack
Flash
Memory
Analog
Smart
Peripheral 1
Analog
Smart
Peripheral 2
Analog
Smart
Peripheral n
Smart Peripherals
in FPGA
Fabric
(e.g., Logic, PLL, FIFO)
Fusion Smart Backbone
Fusion Applets
User Applications
Level 1
Level 0
Level 2
Level 3
Optional ARM or 8051 Processor
Device Architecture
2-2 Revision 4
The system application, Level 3, is the larger user application that utilizes one or more applets. Designing
at the highest level of abstraction supported by the Fusion technology stack, the application can be easily
created in FPGA gates by importing and configuring multiple applets.
In fact, in some cases an entire FPGA system design can be created without any HDL coding.
An optional MCU enables a combination of software and HDL-based design methodologies. The MCU
can be on-chip or off-chip as system requirements dictate. System portioning is very flexible, allowing the
MCU to reside above the applets or to absorb applets, or applets and backbone, if desired.
The Fusion technology stack enables a very flexible design environment. Users can engage in design
across a continuum of abstraction from very low to very high.
Core Architecture
VersaTile
Based upon successful ProASIC3/E logic architecture, Fusion devices provide granularity comparable to
gate arrays. The Fusion device core consists of a sea-of-VersaTiles architecture.
As illustrated in Figure 2-2, there are four inputs in a logic VersaTile cell, and each VersaTile can be
configured using the appropriate flash switch connections:
Any 3-input logic function
Latch with clear or set
D-flip-flop with clear or set
Enable D-flip-flop with clear or set (on a 4th input)
VersaTiles can flexibly map the logic and sequential gates of a design. The inputs of the VersaTile can be
inverted (allowing bubble pushing), and the output of the tile can connect to high-speed, very-long-line
routing resources. VersaTiles and larger functions are connected with any of the four levels of routing
hierarchy.
When the VersaTile is used as an enable D-flip-flop, the SET/CLR signal is supported by a fourth input,
which can only be routed to the core cell over the VersaNet (global) network.
The output of the VersaTile is F2 when the connection is to the ultra-fast local lines, or YL when the
connection is to the efficient long-line or very-long-line resources (Figure 2-2).
Note: *This input can only be connected to the global clock distribution network.
Figure 2-2 • Fusion Core VersaTile
Switch (flash connection) Ground
Via (hard connection)
Legend:
Y
Pin 1
0
1
0
1
0
1
0
1
Data
X3
CLK
X2
CLR/
Enable
X1
CLR
XC*
F2
YL
Fusion Family of Mixed Signal FPGAs
Revision 4 2-3
VersaTile Characteristics
Sample VersaTile Specifications—Combinatorial Module
The Fusion library offers all combinations of LUT-3 combinatorial functions. In this section, timing
characteristics are presented for a sample of the library (Figure 2-3). For more details, refer to the
IGLOO, ProASIC3, SmartFusion and Fusion Macro Library Guide.
Figure 2-3 • Sample of Combinatorial Cells
MAJ3
A
C
BY
MUX2
B
0
1
A
S
Y
AY
B
B
A
XOR2 Y
NOR2
B
A
Y
B
A
YOR2
INV
A
Y
AND2
B
A
Y
NAND3
B
A
C
XOR3 Y
B
A
C
NAND2
Device Architecture
2-4 Revision 4
Figure 2-4 • Combinatorial Timing Model and Waveforms
t
PD
t
PD
t
PD
VCCA
VCCA
t
PD
t
PD
VCCA
t
PD
= MAX(t
PD(RR)
, t
PD(RF)
, t
PD(FF)
, t
PD(FR)
)
where edges are applicable for the
particular combinatorial cell
NAND2 or
Any Combinatorial
Logic
A
B
Y
(RR)
A, B, C
OUT
50%
GND
(FF)
50%
50%
50%
GND
(RF)
50% (FR) 50%
OUT
GND
Fusion Family of Mixed Signal FPGAs
Revision 4 2-5
Timing Characteristics
Sample VersaTile Specifications—Sequential Module
The Fusion library offers a wide variety of sequential cells, including flip-flops and latches. Each has a
data input and optional enable, clear, or preset. In this section, timing characteristics are presented for a
representative sample from the library (Figure 2-5). For more details, refer to the IGLOO, ProASIC3,
SmartFusion and Fusion Macro Library Guide.
Table 2-1 • Combinatorial Cell Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Combinatorial Cell Equation Parameter –2 –1 Std. Units
INV Y = !A tPD 0.40 0.46 0.54 ns
AND2 Y = A · B tPD 0.47 0.54 0.63 ns
NAND2 Y = !(A · B) tPD 0.47 0.54 0.63 ns
OR2 Y = A + B tPD 0.49 0.55 0.65 ns
NOR2 Y = !(A + B) tPD 0.49 0.55 0.65 ns
XOR2 Y = A Bt
PD 0.74 0.84 0.99 ns
MAJ3 Y = MAJ(A, B, C) tPD 0.70 0.79 0.93 ns
XOR3 Y = A B Ct
PD 0.87 1.00 1.17 ns
MUX2 Y = A !S + B S tPD 0.51 0.58 0.68 ns
AND3 Y = A · B · C tPD 0.56 0.64 0.75 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-6 Revision 4
Figure 2-5 Sample of Sequential Cells
Figure 2-6 Sequential Timing Model and Waveforms
DQ
DFN1
Data
CLK
Out
DQ
DFN1C1
Data
CLK
Out
CLR
DQ
DFI1E1P1
Data
CLK
Out
En
PRE
DQ
DFN1E1
Data
CLK
Out
En
PRE
CLR
Out
CLK
Data
EN
t
SUE
50%
50%
t
SUD
t
HD
50% 50%
t
CLKQ
0
t
HE
t
RECPRE
t
REMPRE
t
RECCLR
t
REMCLR
t
WCLR
t
WPRE
t
PRE2Q
t
CLR2Q
t
CKMPWH
t
CKMPWL
50% 50%
50% 50% 50%
50% 50%
50% 50% 50% 50% 50% 50%
50%
50%
Fusion Family of Mixed Signal FPGAs
Revision 4 2-7
Sequential Timing Characteristics
Table 2-2 • Register Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tCLKQ Clock-to-Q of the Core Register 0.55 0.63 0.74 ns
tSUD Data Setup Time for the Core Register 0.43 0.49 0.57 ns
tHD Data Hold Time for the Core Register 0.00 0.00 0.00 ns
tSUE Enable Setup Time for the Core Register 0.45 0.52 0.61 ns
tHE Enable Hold Time for the Core Register 0.00 0.00 0.00 ns
tCLR2Q Asynchronous Clear-to-Q of the Core Register 0.40 0.45 0.53 ns
tPRE2Q Asynchronous Preset-to-Q of the Core Register 0.40 0.45 0.53 ns
tREMCLR Asynchronous Clear Removal Time for the Core Register 0.00 0.00 0.00 ns
tRECCLR Asynchronous Clear Recovery Time for the Core Register 0.22 0.25 0.30 ns
tREMPRE Asynchronous Preset Removal Time for the Core Register 0.00 0.00 0.00 ns
tRECPRE Asynchronous Preset Recovery Time for the Core Register 0.22 0.25 0.30 ns
tWCLR Asynchronous Clear Minimum Pulse Width for the Core Register 0.22 0.25 0.30 ns
tWPRE Asynchronous Preset Minimum Pulse Width for the Core Register 0.22 0.25 0.30 ns
tCKMPWH Clock Minimum Pulse Width High for the Core Register 0.32 0.37 0.43 ns
tCKMPWL Clock Minimum Pulse Width Low for the Core Register 0.36 0.41 0.48 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-8 Revision 4
Array Coordinates
During many place-and-route operations in the Microsemi Designer software tool, it is possible to set
constraints that require array coordinates. Table 2-3 is provided as a reference. The array coordinates
are measured from the lower left (0, 0). They can be used in region constraints for specific logic
groups/blocks, designated by a wildcard, and can contain core cells, memories, and I/Os.
Table 2-3 provides array coordinates of core cells and memory blocks.
I/O and cell coordinates are used for placement constraints. Two coordinate systems are needed
because there is not a one-to-one correspondence between I/O cells and edge core cells. In addition, the
I/O coordinate system changes depending on the die/package combination. It is not listed in Tab le 2 -3 .
The Designer ChipPlanner tool provides array coordinates of all I/O locations. I/O and cell coordinates
are used for placement constraints. However, I/O placement is easier by package pin assignment.
Figure 2-7 illustrates the array coordinates of an AFS600 device. For more information on how to use
array coordinates for region/placement constraints, see the Designer User's Guide or online help
(available in the software) for Fusion software tools.
Table 2-3 • Array Coordinates
Device VersaTiles Memory Rows All
Min. Max. Bottom Top Min. Max.
x y x y (x, y) (x, y) (x, y) (x, y)
AFS090 3 2 98 25 None (3, 26) (0, 0) (101, 29)
AFS250 3 2 130 49 None (3, 50) (0, 0) (133, 53)
AFS600 3 4 194 75 (3, 2) (3, 76) (0, 0) (197, 79)
AFS1500 3 4 322 123 (3, 2) (3, 124) (0, 0) (325, 129)
Note: The vertical I/O tile coordinates are not shown. West side coordinates are {(0, 2) to (2, 2)} to {(0, 77) to (2, 77)};
east side coordinates are {(195, 2) to (197, 2)} to {(195, 77) to (197, 77)}.
Figure 2-7 Array Coordinates for AFS600
(0, 79)
(197, 1)
Top Row (5, 1) to (168, 1)
Bottom Row (7, 0) to (165, 0)
Top Row (169, 1) to (192, 1)
Memory
Blocks
Memory
Blocks
Memory
Blocks
UJTAG FlashROM
Top Row (7, 79) to (189, 79)
Bottom Row (5, 78) to (192, 78)
I/O Tile
(3, 77)
(3, 76)
Memory
Blocks
(3, 3)
(3, 2)
VersaTile (Core)
(3, 75)
VersaTile (Core)
(3, 4)
(0, 0) (197, 0)
(194, 2)
(194, 3)
(194, 4)
VersaTile(Core)
(194, 75)
VersaTile (Core)
(197, 79)
(194, 77)
(194, 76)
I/O Tile to Analog Block
Fusion Family of Mixed Signal FPGAs
Revision 4 2-9
Routing Architecture
The routing structure of Fusion devices is designed to provide high performance through a flexible four-
level hierarchy of routing resources: ultra-fast local resources; efficient long-line resources; high-speed
very-long-line resources; and the high-performance VersaNet networks.
The ultra-fast local resources are dedicated lines that allow the output of each VersaTile to connect
directly to every input of the eight surrounding VersaTiles (Figure 2-8). The exception to this is that the
SET/CLR input of a VersaTile configured as a D-flip-flop is driven only by the VersaNet global network.
The efficient long-line resources provide routing for longer distances and higher-fanout connections.
These resources vary in length (spanning one, two, or four VersaTiles), run both vertically and
horizontally, and cover the entire Fusion device (Figure 2-9 on page 2-10). Each VersaTile can drive
signals onto the efficient long-line resources, which can access every input of every VersaTile. Active
buffers are inserted automatically by routing software to limit loading effects.
The high-speed very-long-line resources, which span the entire device with minimal delay, are used to
route very long or high-fanout nets: length ±12 VersaTiles in the vertical direction and length ±16 in the
horizontal direction from a given core VersaTile (Figure 2-10 on page 2-11). Very long lines in Fusion
devices, like those in ProASIC3 devices, have been enhanced. This provides a significant performance
boost for long-reach signals.
The high-performance VersaNet global networks are low-skew, high-fanout nets that are accessible from
external pins or from internal logic (Figure 2-11 on page 2-12). These nets are typically used to distribute
clocks, reset signals, and other high-fanout nets requiring minimum skew. The VersaNet networks are
implemented as clock trees, and signals can be introduced at any junction. These can be employed
hierarchically, with signals accessing every input on all VersaTiles.
Note: Input to the core cell for the D-flip-flop set and reset is only available via the VersaNet global network connection.
Figure 2-8 Ultra-Fast Local Lines Connected to the Eight Nearest Neighbors
L
LL
LL
LInputs
Output
Ultra-Fast Local Lines
(connects a VersaTile to the
adjacent VersaTile, I/O buffer,
or memory block)
LLL
Long Lines
Device Architecture
2-10 Revision 4
Figure 2-9 Efficient Long-Line Resources
Fusion Family of Mixed Signal FPGAs
Revision 4 2-11
Figure 2-10 • Very-Long-Line Resources
High-Speed, Very-Long-Line Resources
Pad Ring
Pad Ring
I/O Ring
I/O Ring
16×12 Block of VersaTiles
SRAM
Device Architecture
2-12 Revision 4
Global Resources (VersaNets)
Fusion devices offer powerful and flexible control of circuit timing through the use of analog circuitry.
Each chip has six CCCs. The west CCC also contains a PLL core. In the two larger devices (AFS600 and
AFS1500), the west and the east CCCs each contain a PLL. The PLLs include delay lines, a phase
shifter (0°, 90°, 180°, 270°), and clock multipliers/dividers. Each CCC has all the circuitry needed for the
selection and interconnection of inputs to the VersaNet global network. The east and west CCCs each
have access to three VersaNet global lines on each side of the chip (six lines total). The CCCs at the four
corners each have access to three quadrant global lines on each quadrant of the chip.
Advantages of the VersaNet Approach
One of the architectural benefits of Fusion is the set of powerful and low-delay VersaNet global networks.
Fusion offers six chip (main) global networks that are distributed from the center of the FPGA array
(Figure 2-11). In addition, Fusion devices have three regional globals (quadrant globals) in each of the
four chip quadrants. Each core VersaTile has access to nine global network resources: three quadrant
and six chip (main) global networks. There are a total of 18 global networks on the device. Each of these
networks contains spines and ribs that reach all VersaTiles in all quadrants (Figure 2-12 on page 2-13).
This flexible VersaNet global network architecture allows users to map up to 180 different
internal/external clocks in a Fusion device. Details on the VersaNet networks are given in Table 2-4 on
page 2-13. The flexibility of the Fusion VersaNet global network allows the designer to address several
design requirements. User applications that are clock-resource-intensive can easily route external or
gated internal clocks using VersaNet global routing networks. Designers can also drastically reduce
delay penalties and minimize resource usage by mapping critical, high-fanout nets to the VersaNet global
network.
Figure 2-11 • Overview of Fusion VersaNet Global Network
Main (chip)
Global Network
Top Spine
Bottom Spine
Pad Ring
Pad Ring
I/O Ring
I/O Ring
Chip (main)
Global Pads
Global
Pads
High-Performance
VersaNet Global Network
Global Spine
Global Ribs
Spine-Selection
Tree MUX
Quadrant Global Pads
Fusion Family of Mixed Signal FPGAs
Revision 4 2-13
Figure 2-12 • Global Network Architecture
Table 2-4 • Globals/Spines/Rows by Device
AFS090 AFS250 AFS600 AFS1500
Global VersaNets (trees)* 9 9 9 9
VersaNet Spines/Tree 4 8 12 20
Total Spines 36 72 108 180
VersaTiles in Each Top or Bottom Spine 384 768 1,152 1,920
Total VersaTiles 2,304 6,144 13,824 38,400
Note: *There are six chip (main) globals and three globals per quadrant.
Northwest Quadrant Global Network
Southeast Quadrant Global Network
Chip (main)
Global
Network
3
3
3
333
3333
6
6
6
6
6
6
6
6
Global Spine Quadrant Global Spine
CCC
CCC
CCC CCC
CCC
CCC
Device Architecture
2-14 Revision 4
VersaNet Global Networks and Spine Access
The Fusion architecture contains a total of 18 segmented global networks that can access the
VersaTiles, SRAM, and I/O tiles on the Fusion device. There are 6 chip (main) global networks that
access the entire device and 12 quadrant networks (3 in each quadrant). Each device has a total of 18
globals. These VersaNet global networks offer fast, low-skew routing resources for high-fanout nets,
including clock signals. In addition, these highly segmented global networks offer users the flexibility to
create low-skew local networks using spines for up to 180 internal/external clocks (in an AFS1500
device) or other high-fanout nets in Fusion devices. Optimal usage of these low-skew networks can
result in significant improvement in design performance on Fusion devices.
The nine spines available in a vertical column reside in global networks with two separate regions of
scope: the quadrant global network, which has three spines, and the chip (main) global network, which
has six spines. Note that there are three quadrant spines in each quadrant of the device. There are four
quadrant global network regions per device (Figure 2-12 on page 2-13).
The spines are the vertical branches of the global network tree, shown in Figure 2-11 on page 2-12. Each
spine in a vertical column of a chip (main) global network is further divided into two equal-length spine
segments: one in the top and one in the bottom half of the die.
Each spine and its associated ribs cover a certain area of the Fusion device (the "scope" of the spine;
see Figure 2-11 on page 2-12). Each spine is accessed by the dedicated global network MUX tree
architecture, which defines how a particular spine is driven—either by the signal on the global network
from a CCC, for example, or another net defined by the user (Figure 2-13). Quadrant spines can be
driven from user I/Os on the north and south sides of the die, via analog I/Os configured as direct digital
inputs. The ability to drive spines in the quadrant global networks can have a significant effect on system
performance for high-fanout inputs to a design.
Details of the chip (main) global network spine-selection MUX are presented in Figure 2-13. The spine
drivers for each spine are located in the middle of the die.
Quadrant spines are driven from a north or south rib. Access to the top and bottom ribs is from the corner
CCC or from the I/Os on the north and south sides of the device. For details on using spines in Fusion
devices, see the application note Using Global Resources in Actel Fusion Devices.
Figure 2-13 • Spine-Selection MUX of Global Tree
Internal/External
Signal
Internal/External
Signal
Internal/External
Signals
Spine
Global Rib
Global Driver MUX
Tree Node MUX
Tree Node MUX
Internal/External
Signals
Tree Node MUX
Fusion Family of Mixed Signal FPGAs
Revision 4 2-15
Clock Aggregation
Clock aggregation allows for multi-spine clock domains. A MUX tree provides the necessary flexibility to
allow long lines or I/Os to access domains of one, two, or four global spines. Signal access to the clock
aggregation system is achieved through long-line resources in the central rib, and also through local
resources in the north and south ribs, allowing I/Os to feed directly into the clock system. As Figure 2-14
indicates, this access system is contiguous.
There is no break in the middle of the chip for north and south I/O VersaNet access. This is different from
the quadrant clocks, located in these ribs, which only reach the middle of the rib. Refer to the Using
Global Resources in Actel Fusion Devices application note.
Figure 2-14 • Clock Aggregation Tree Architecture
Global Spine
Global Rib
Global Driver and MUX
I/O Access
Internal Signal Access
I/O Tiles
Global Signal Access
Tree Node MUX
Device Architecture
2-16 Revision 4
Global Resource Characteristics
AFS600 VersaNet Topology
Clock delays are device-specific. Figure 2-15 is an example of a global tree used for clock routing. The
global tree presented in Figure 2-15 is driven by a CCC located on the west side of the AFS600 device. It
is used to drive all D-flip-flops in the device.
Figure 2-15 • Example of Global Tree Use in an AFS600 Device for Clock Routing
Central
Global Rib
VersaTile
Rows
Global Spine
CCC
Fusion Family of Mixed Signal FPGAs
Revision 4 2-17
VersaNet Timing Characteristics
Global clock delays include the central rib delay, the spine delay, and the row delay. Delays do not
include I/O input buffer clock delays, as these are dependent upon I/O standard, and the clock may be
driven and conditioned internally by the CCC module. Ta b l e 2- 5, Table 2-6, Ta bl e 2- 7 , and Table 2-8 on
page 2-18 present minimum and maximum global clock delays within the device Minimum and maximum
delays are measured with minimum and maximum loading, respectively.
Timing Characteristics
Table 2-5 • AFS1500 Global Resource Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description
–2 –1 Std.
UnitsMin.1Max.2Min.1Max.2Min.1Max.2
tRCKL Input Low Delay for Global Clock 1.53 1.75 1.74 1.99 2.05 2.34 ns
tRCKH Input High Delay for Global Clock 1.53 1.79 1.75 2.04 2.05 2.40 ns
tRCKMPWH Minimum Pulse Width High for Global Clock ns
tRCKMPWL Minimum Pulse Width Low for Global Clock ns
tRCKSW Maximum Skew for Global Clock 0.26 0.29 0.34 ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element located in a
fully loaded row (all available flip-flops are connected to the global net in the row).
3. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Table 2-6 • AFS600 Global Resource Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description
–2 –1 Std.
UnitsMin.1Max.2Min.1Max.2Min.1Max.2
tRCKL Input Low Delay for Global Clock 1.27 1.49 1.44 1.70 1.69 2.00 ns
tRCKH Input High Delay for Global Clock 1.26 1.54 1.44 1.75 1.69 2.06 ns
tRCKMPWH Minimum Pulse Width High for Global Clock ns
tRCKMPWL Minimum Pulse Width Low for Global Clock ns
tRCKSW Maximum Skew for Global Clock 0.27 0.31 0.36 ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element located in a
fully loaded row (all available flip-flops are connected to the global net in the row).
3. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Device Architecture
2-18 Revision 4
Table 2-7 • AFS250 Global Resource Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description
–2 –1 Std.
UnitsMin.1Max.2Min.1Max.2Min.1Max.2
tRCKL Input Low Delay for Global Clock 0.89 1.12 1.02 1.27 1.20 1.50 ns
tRCKH Input High Delay for Global Clock 0.88 1.14 1.00 1.30 1.17 1.53 ns
tRCKMPWH Minimum Pulse Width High for Global Clock ns
tRCKMPWL Minimum Pulse Width Low for Global Clock ns
tRCKSW Maximum Skew for Global Clock 0.26 0.30 0.35 ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Table 2-8 • AFS090 Global Resource Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description
–2 –1 Std.
UnitsMin.1Max.2Min.1Max.2Min.1Max.2
tRCKL Input Low Delay for Global Clock 0.84 1.07 0.96 1.21 1.13 1.43 ns
tRCKH Input High Delay for Global Clock 0.83 1.10 0.95 1.25 1.12 1.47 ns
tRCKMPWH Minimum Pulse Width High for Global Clock ns
tRCKMPWL Minimum Pulse Width Low for Global Clock ns
tRCKSW Maximum Skew for Global Clock 0.27 0.30 0.36 ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-19
Clocking Resources
The Fusion family has a robust collection of clocking peripherals, as shown in the block diagram in
Figure 2-16. These on-chip resources enable the creation, manipulation, and distribution of many clock
signals. The Fusion integrated RC oscillator produces a 100 MHz clock source with no external
components. For systems requiring more precise clock signals, the Fusion family supports an on-chip
crystal oscillator circuit. The integrated PLLs in each Fusion device can use the RC oscillator, crystal
oscillator, or another on-chip clock signal as a source. These PLLs offer a variety of capabilities to modify
the clock source (multiply, divide, synchronize, advance, or delay). Utilizing the CCC found in the popular
ProASIC3 family, Fusion incorporates six CCC blocks. The CCCs allow access to Fusion global and local
clock distribution nets, as described in the "Global Resources (VersaNets)" section on page 2-12.
Figure 2-16 • Fusion Clocking Options
Device Architecture
2-20 Revision 4
RC Oscillator
The RC oscillator is an on-chip free-running clock source generating a 100 MHz clock. It can be used as
a source clock for both on-chip and off-chip resources. When used in conjunction with the Fusion PLL
and CCC circuits, the RC oscillator clock source can be used to generate clocks of varying frequency
and phase.
The Fusion RC oscillator is very accurate at ±1% over commercial temperature ranges and and ±3%
over industrial temperature ranges. It is an automated clock, requiring no setup or configuration by the
user. It requires only that the power and GNDOSC pins be connected; no external components are
required. The RC oscillator can be used to drive either a PLL or another internal signal.
RC Oscillator Characteristics
Table 2-9 • Electrical Characteristics of RC Oscillator
Parameter Description Conditions Min. Typ. Max. Units
FRC Operating
Frequency
100 MHz
Accuracy Temperature: 0°C to 85°C
Voltage: 3.3 V ± 5%
1%
Temperature: –40°C to 125°C
Voltage: 3.3 V ± 5%
3%
Output Jitter Period Jitter (at 5 k cycles) 100 ps
Cycle–Cycle Jitter (at 5 k cycles) 100 ps
Period Jitter (at 5 k cycles) with
1 KHz / 300 mV peak-to-peak noise
on power supply
150 ps
Cycle–Cycle Jitter (at 5 k cycles) with
1 KHz / 300 mV peak-to-peak noise
on power supply
150 ps
Output Duty Cycle 50 %
IDYNRC Operating Current 1 mA
Fusion Family of Mixed Signal FPGAs
Revision 4 2-21
Crystal Oscillator
The Crystal Oscillator (XTLOSC) is source that generates the clock from an external crystal. The output
of XTLOSC CLKOUT signal can be selected as an input to the PLL. Refer to the "Clock Conditioning
Circuits" section for more details. The XTLOSC can operate in normal operations and Standby mode
(RTC is running and 1.5 V is not present).
In normal operation, the internal FPGA_EN signal is '1' as long as 1.5 V is present for VCC. As such,
the internal enable signal, XTL_EN, for Crystal Oscillator is enabled since FPGA_EN is asserted. The
XTL_MODE has the option of using MODE or RTC_MODE, depending on SELMODE.
During Standby, 1.5 V is not available, as such, and FPGA_EN is '0'. SELMODE must be asserted in
order for XTL_EN to be enabled; hence XTL_MODE relies on RTC_MODE. SELMODE and RTC_MODE
must be connected to RTCXTLSEL and RTCXTLMODE from the AB respectively for correct operation
during Standby (refer to the "Real-Time Counter System" section on page 2-33 for a detailed
description).
The Crystal Oscillator can be configured in one of four modes:
RC network, 32 KHz to 4 MHz
Low gain, 32 to 200 KHz
Medium gain, 0.20 to 2.0 MHz
High gain, 2.0 to 20.0 MHz
In RC network mode, the XTAL1 pin is connected to an RC circuit, as shown in Figure 2-16 on
page 2-19. The XTAL2 pin should be left floating. The RC value can be chosen based on Figure 2-18 for
any desired frequency between 32 KHz and 4 MHz. The RC network mode can also accommodate an
external clock source on XTAL1 instead of an RC circuit.
In Low gain, Medium gain, and High gain, an external crystal component or ceramic resonator can be
added onto XTAL1 and XTAL2, as shown in Figure 2-16 on page 2-19. In the case where the Crystal
Oscillator block is not used, the XTAL1 pin should be connected to GND and the XTAL2 pin should be left
floating.
Note: *Internal signal—does not exist in macro.
Figure 2-17 • XTLOSC Macro
XTLOSC
CLKOUT
XTL
0
1
MODE[1:0]
RTC_MODE[1:0]
SELMODE
FPGA_EN*
XTL_EN*
XTL_MODE*
Device Architecture
2-22 Revision 4
Figure 2-18 • Crystal Oscillator: RC Time Constant Values vs. Frequency (typical)
Table 2-10 • XTLOSC Signals Descriptions
Signal Name Width Direction Function
XTL_EN* 1 Enables the crystal. Active high.
XTL_MODE* 2 Settings for the crystal clock for different frequency.
Value Modes Frequency Range
b'00 RC network 32 KHz to 4 MHz
b'01 Low gain 32 to 200 KHz
b'10 Medium gain 0.20 to 2.0 MHz
b'11 High gain 2.0 to 20.0 MHz
SELMODE 1 IN Selects the source of XTL_MODE and also enables the
XTL_EN. Connect from RTCXTLSEL from AB.
0 For normal operation or sleep mode, XTL_EN
depends on FPGA_EN, XTL_MODE depends on
MODE
1 For Standby mode, XTL_EN is enabled,
XTL_MODE depends on RTC_MODE
RTC_MODE[1:0] 2 IN Settings for the crystal clock for different frequency ranges.
XTL_MODE uses RTC_MODE when SELMODE is '1'.
MODE[1:0] 2 IN Settings for the crystal clock for different frequency ranges.
XTL_MODE uses MODE when SELMODE is '0'. In Standby,
MODE inputs will be 0's.
FPGA_EN* 1 IN 0 when 1.5 V is not present for VCC 1 when 1.5 V is present
for VCC
XTL 1 IN Crystal Clock source
CLKOUT 1 OUT Crystal Clock output
Note: *Internal signal—does not exist in macro.
0.0
1.00E-0.7
1.00E-0.6
1.00E-0.5
1.00E-0.4
1.00E-0.3
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5
RC Time Constant (sec)
Frequency (MHz)
RC Time Constant Values vs. Frequency
Fusion Family of Mixed Signal FPGAs
Revision 4 2-23
Clock Conditioning Circuits
In Fusion devices, the CCCs are used to implement frequency division, frequency multiplication, phase
shifting, and delay operations.
The CCCs are available in six chip locations—each of the four chip corners and the middle of the east
and west chip sides.
Each CCC can implement up to three independent global buffers (with or without programmable delay),
or a PLL function (programmable frequency division/multiplication, phase shift, and delays) with up to three
global outputs. Unused global outputs of a PLL can be used to implement independent global buffers, up
to a maximum of three global outputs for a given CCC.
A global buffer can be placed in any of the three global locations (CLKA-GLA, CLKB-GLB, and CLKC-
GLC) of a given CCC.
A PLL macro uses the CLKA CCC input to drive its reference clock. It uses the GLA and, optionally, the
GLB and GLC global outputs to drive the global networks. A PLL macro can also drive the YB and YC
regular core outputs. The GLB (or GLC) global output cannot be reused if the YB (or YC) output is used
(Figure 2-19). Refer to the "PLL Macro" section on page 2-29 for more information.
Each global buffer, as well as the PLL reference clock, can be driven from one of the following:
3 dedicated single-ended I/Os using a hardwired connection
2 dedicated differential I/Os using a hardwired connection
The FPGA core
The CCC block is fully configurable, either via flash configuration bits set in the programming bitstream or
through an asynchronous interface. This asynchronous interface is dynamically accessible from inside
the Fusion device to permit changes of parameters (such as divide ratios) during device operation. To
increase the versatility and flexibility of the clock conditioning system, the CCC configuration is
determined either by the user during the design process, with configuration data being stored in flash
memory as part of the device programming procedure, or by writing data into a dedicated shift register
during normal device operation. This latter mode allows the user to dynamically reconfigure the CCC
without the need for core programming. The shift register is accessed through a simple serial interface.
Refer to the "UJTAG Applications in Microsemi’s Low-Power Flash Devices" chapter of the Fusion FPGA
Fabric User’s Guide and the "CCC and PLL Characteristics" section on page 2-30 for more information.
Device Architecture
2-24 Revision 4
Notes:
1. Visit the Microsemi SoC Products Group website for application notes concerning dynamic PLL reconfiguration. Refer to
the "PLL Macro" section on page 2-29 for signal descriptions.
2. Many specific INBUF macros support the wide variety of single-ended and differential I/O standards for the Fusion family.
3. Refer to the IGLOO, ProASIC3, SmartFusion and Fusion Macro Library Guide for more information.
Figure 2-19 • Fusion CCC Options: Global Buffers with the PLL Macro
Table 2-11 • Available Selections of I/O Standards within CLKBUF and CLKBUF_LVDS/LVPECL Macros
CLKBUF Macros
CLKBUF_LVCMOS5
CLKBUF_LVCMOS331
CLKBUF_LVCMOS18
CLKBUF_LVCMOS15
CLKBUF_PCI
CLKBUF_LVDS2
CLKBUF_LVPECL
Notes:
1. This is the default macro. For more details, refer to the IGLOO, ProASIC3, SmartFusion and Fusion Macro Library
Guide.
2. The B-LVDS and M-LVDS standards are supported with CLKBUF_LVDS.
PADN
PADP
Y
PAD Y
Input LVDS/LVPECL Macro
INBUF
2
Macro
GLA
or
GLA and (GLB or YB)
or
GLA and (GLC or YC)
or
GLA and (GLB or YB) and
(GLC or YC)
Clock Source Clock Conditioning Output
OADIVHALF
OADIV[4:0]
OAMUX[2:0]
DLYGLA[4:0]
OBDIV[4:0]
OBMUX[2:0]
DLYYB[4:0]
DLYGLB[4:0]
OCDIV[4:0]
OCMUX[2:0]
DLYYC[4:0]
DLYGLC[4:0]
FINDIV[6:0]
FBDIV[6:0]
FBDLY[4:0]
FBSEL[1:0]
XDLYSEL
VCOSEL[2:0]
CLKA
EXTFB
POWERDOWN
OADIVRST
GLA
LOCK
GLB
YB
GLC
YC
Fusion Family of Mixed Signal FPGAs
Revision 4 2-25
Global Buffers with No Programmable Delays
The CLKBUF and CLKBUF_LVPECL/LVDS macros are composite macros that include an I/O macro
driving a global buffer, hardwired together (Figure 2-20).
The CLKINT macro provides a global buffer function driven by the FPGA core.
The CLKBUF, CLKBUF_LVPECL/LVDS, and CLKINT macros are pass-through clock sources and do not
use the PLL or provide any programmable delay functionality.
Many specific CLKBUF macros support the wide variety of single-ended and differential I/O standards
supported by Fusion devices. The available CLKBUF macros are described in the IGLOO, ProASIC3,
SmartFusion and Fusion Macro Library Guide.
Figure 2-20 • Global Buffers with No Programmable Delay
CLKBUF_LVDS/LVPECL Macro
PADN
PADP YYA
PAD Y
CLKINT MacroCLKBUF Macro
GLA
or
GLB
or
GLC
Clock Source Clock Conditioning Output
None
Device Architecture
2-26 Revision 4
Global Buffers with Programmable Delay
The CLKDLY macro is a pass-through clock source that does not use the PLL, but provides the ability to
delay the clock input using a programmable delay (Figure 2-21). The CLKDLY macro takes the selected
clock input and adds a user-defined delay element. This macro generates an output clock phase shift
from the input clock.
The CLKDLY macro can be driven by an INBUF macro to create a composite macro, where the I/O
macro drives the global buffer (with programmable delay) using a hardwired connection. In this case, the
I/O must be placed in one of the dedicated global I/O locations.
Many specific INBUF macros support the wide variety of single-ended and differential I/O standards
supported by the Fusion family. The available INBUF macros are described in the IGLOO, ProASIC3,
SmartFusion and Fusion Macro Library Guide.
The CLKDLY macro can be driven directly from the FPGA core.
The CLKDLY macro can also be driven from an I/O that is routed through the FPGA regular routing
fabric. In this case, users must instantiate a special macro, PLLINT, to differentiate from the hardwired
I/O connection described earlier.
The visual CLKDLY configuration in the SmartGen part of the Libero SoC and Designer tools allows the
user to select the desired amount of delay and configures the delay elements appropriately. SmartGen
also allows the user to select the input clock source. SmartGen will automatically instantiate the special
macro, PLLINT, when needed.
Figure 2-21 • Fusion CCC Options: Global Buffers with Programmable Delay
PADN
PADP
Y
PAD Y
Input LVDS/LVPECL Macro
INBUF* Macro
GLA
or
GLB
or
GLC
Clock Source Clock Conditioning Output
CLK
DLYGL[4:0]
GL
Fusion Family of Mixed Signal FPGAs
Revision 4 2-27
Global Input Selections
Each global buffer, as well as the PLL reference clock, can be driven from one of the following (Figure 2-
22):
3 dedicated single-ended I/Os using a hardwired connection
2 dedicated differential I/Os using a hardwired connection
The FPGA core
Notes:
1. Represents the global input pins. Globals have direct access to the clock conditioning block and are not
routed via the FPGA fabric. Refer to the "User I/O Naming Convention" section on page 2-161 for more
information.
2. Instantiate the routed clock source input as follows:
a) Connect the output of a logic element to the clock input of the PLL, CLKDLY, or CLKINT macro.
b) Do not place a clock source I/O (INBUF or INBUF_LVPECL/LVDS) in a relevant global pin location.
3. LVDS-based clock sources are available in the east and west banks on all Fusion devices.
Figure 2-22 • Clock Input Sources Including CLKBUF, CLKBUF_LVDS/LVPECL, and CLKINT
+
+
Source for CCC
(CLKA or CLKB or CLKC)
Each shaded box represents an
input buffer called out by the
appropriate name: INBUF or
INBUF_LVDS/LVPECL. To Core
Routed Clock
(from FPGA core)
2
Sample Pin Names
GAA0
1
GAA1
1
GAA2
1
GAA[0:2]: GA represents global in the northwest corner
of the device. A[0:2]: designates specific A clock source.
Device Architecture
2-28 Revision 4
CCC Physical Implementation
The CCC circuit is composed of the following (Figure 2-23):
PLL core
3 phase selectors
6 programmable delays and 1 fixed delay
5 programmable frequency dividers that provide frequency multiplication/division (not shown in
Figure 2-23 because they are automatically configured based on the user's required frequencies)
1 dynamic shift register that provides CCC dynamic reconfiguration capability (not shown)
CCC Programming
The CCC block is fully configurable. It is configured via static flash configuration bits in the array, set by
the user in the programming bitstream, or configured through an asynchronous dedicated shift register,
dynamically accessible from inside the Fusion device. The dedicated shift register permits changes of
parameters such as PLL divide ratios and delays during device operation. This latter mode allows the
user to dynamically reconfigure the PLL without the need for core programming. The register file is
accessed through a simple serial interface.
Note: Clock divider and multiplier blocks are not shown in this figure or in SmartGen. They are
automatically configured based on the user's required frequencies.
Figure 2-23 • PLL Block
PLL Core Phase
Select
Phase
Select
Phase
Select
GLA
CLKA
GLB
YB
GLC
YC
Fixed Delay
Programmable
Delay Type 1
Programmable
Delay Type 2
Programmable
Delay Type 2
Programmable
Delay Type 1
Programmable
Delay Type 2
Programmable
Delay Type 1
Four-Phase Output
Fusion Family of Mixed Signal FPGAs
Revision 4 2-29
PLL Macro
The PLL functionality of the clock conditioning block is supported by the PLL macro. Note that the PLL
macro reference clock uses the CLKA input of the CCC block, which is only accessible from the global
A[2:0] package pins. Refer to Figure 2-22 on page 2-27 for more information.
The PLL macro provides five derived clocks (three independent) from a single reference clock. The PLL
feedback loop can be driven either internally or externally. The PLL macro also provides power-down
input and lock output signals. During power-up, POWERDOWN should be asserted Low until VCC is up.
See Figure 2-19 on page 2-24 for more information.
Inputs:
CLKA: selected clock input
POWERDOWN (active low): disables PLLs. The default state is power-down on (active low).
Outputs:
LOCK (active high): indicates that PLL output has locked on the input reference signal
GLA, GLB, GLC: outputs to respective global networks
YB, YC: allows output from the CCC to be routed back to the FPGA core
As previously described, the PLL allows up to five flexible and independently configurable clock outputs.
Figure 2-23 on page 2-28 illustrates the various clock output options and delay elements.
As illustrated, the PLL supports three distinct output frequencies from a given input clock. Two of these
(GLB and GLC) can be routed to the B and C global networks, respectively, and/or routed to the device
core (YB and YC).
There are five delay elements to support phase control on all five outputs (GLA, GLB, GLC, YB, and YC).
There is also a delay element in the feedback loop that can be used to advance the clock relative to the
reference clock.
The PLL macro reference clock can be driven by an INBUF macro to create a composite macro, where
the I/O macro drives the global buffer (with programmable delay) using a hardwired connection. In this
case, the I/O must be placed in one of the dedicated global I/O locations.
The PLL macro reference clock can be driven directly from the FPGA core.
The PLL macro reference clock can also be driven from an I/O routed through the FPGA regular routing
fabric. In this case, users must instantiate a special macro, PLLINT, to differentiate it from the hardwired
I/O connection described earlier.
The visual PLL configuration in SmartGen, available with the Libero SoC and Designer tools, will derive
the necessary internal divider ratios based on the input frequency and desired output frequencies
selected by the user. SmartGen allows the user to select the various delays and phase shift values
necessary to adjust the phases between the reference clock (CLKA) and the derived clocks (GLA, GLB,
GLC, YB, and YC). SmartGen also allows the user to select where the input clock is coming from.
SmartGen automatically instantiates the special macro, PLLINT, when needed.
Device Architecture
2-30 Revision 4
CCC and PLL Characteristics
Timing Characteristics
Table 2-12 • Fusion CCC/PLL Specification
Parameter Min. Typ. Max. Unit
Clock Conditioning Circuitry Input Frequency fIN_CCC 1.5 350 MHz
Clock Conditioning Circuitry Output Frequency fOUT_CCC 0.75 350 MHz
Delay Increments in Programmable Delay Blocks1, 2 1603ps
Number of Programmable Values in Each Programmable
Delay Block
32
Input Period Jitter 1.5 ns
CCC Output Peak-to-Peak Period Jitter FCCC_OUT Max Peak-to-Peak Period Jitter
1 Global
Network
Used
3 Global
Networks
Used
0.75 MHz to 24 MHz 1.00% 1.00%
24 MHz to 100 MHz 1.50% 1.50%
100 MHz to 250 MHz 2.25% 2.25%
250 MHz to 350 MHz 3.50% 3.50%
Acquisition Time LockControl = 0 300 µs
LockControl = 1 6.0 ms
Tracking Jitter4LockControl = 0 1.6 ns
LockControl = 1 0.8 ns
Output Duty Cycle 48.5 51.5 %
Delay Range in Block: Programmable Delay 1 1, 2 0.6 5.56 ns
Delay Range in Block: Programmable Delay 2 1, 2 0.025 5.56 ns
Delay Range in Block: Fixed Delay 1, 2 2.2 ns
Notes:
1. This delay is a function of voltage and temperature. See Table 3-7 on page 3-9 for deratings.
2. TJ = 25°C, VCC = 1.5 V
3. When the CCC/PLL core is generated by Microsemi core generator software, not all delay values of the specified delay
increments are available. Refer to the Libero SoC Online Help associated with the core for more information.
4. Tracking jitter is defined as the variation in clock edge position of PLL outputs with reference to PLL input clock edge.
Tracking jitter does not measure the variation in PLL output period, which is covered by period jitter parameter.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-31
No-Glitch MUX (NGMUX)
Positioned downstream from the PLL/CCC blocks, the NGMUX provides a special switching sequence
between two asynchronous clock domains that prevents generating any unwanted narrow clock pulses.
The NGMUX is used to switch the source of a global between three different clock sources. Allowable
inputs are either two PLL/CCC outputs or a PLL/CCC output and a regular net, as shown in Figure 2-24.
The GLMUXCFG[1:0] configuration bits determine the source of the CLK inputs (i.e., internal signal or
GLC). These are set by SmartGen during design but can also be changed by dynamically reconfiguring
the PLL. The GLMUXSEL[1:0] bits control which clock source is passed through the NGMUX to the global
network (GL). See Table 2-13.
Figure 2-24 • NGMUX
Table 2-13 • NGMUX Configuration and Selection Table
GLMUXCFG[1:0] GLMUXSEL[1:0]
Selected Input
Signal MUX Type
00 X 0 GLA 2-to-1 GLMUX
X1GLC
01 X 0 GLA 2-to-1 GLMUX
X 1 GLINT
Crystal Oscillator
RC Oscillator
W I/O Ring
CCC/PLL
Clock I/Os
From FPGA Core
PLL/
CCC
GLINT
GLA
GLC
NGMUX
GLMUXCFG[1:0]
PWR UP
GLMUXSEL[1:0]
GL
To Clock Rib Driver
Device Architecture
2-32 Revision 4
The NGMUX macro is simplified to show the two clock options that have been selected by the
GLMUXCFG[1:0] bits. Figure 2-25 illustrates the NGMUX macro. During design, the two clock sources
are connected to CLK0 and CLK1 and are controlled by GLMUXSEL[1:0] to determine which signal is to
be passed through the MUX.
The sequence of switching between two clock sources (from CLK0 to CLK1) is as follows (Figure 2-26):
GLMUXSEL[1:0] transitions to initiate a switch.
GL drives one last complete CLK0 positive pulse (i.e., one rising edge followed by one falling
edge).
From that point, GL stays Low until the second rising edge of CLK1 occurs.
At the second CLK1 rising edge, GL will begin to continuously deliver the CLK1 signal.
Minimum tsw = 0.05 ns at 25°C (typical conditions)
For examples of NGMUX operation, refer to the Fusion FPGA Fabric User’s Guide.
Figure 2-25 • NGMUX Macro
Figure 2-26 • NGMUX Waveform
CLK0
CLK1
G
L
GLMUXSEL[1:0]
CLK0
CLK1
GLMUXSEL[1:0]
GL
tSW
Fusion Family of Mixed Signal FPGAs
Revision 4 2-33
Real-Time Counter System
The RTC system enables Fusion devices to support standby and sleep modes of operation to reduce
power consumption in many applications.
Sleep mode, typical 10 µA
Standby mode (RTC running), typical 3 mA with 20 MHz
The RTC system is composed of five cores:
RTC sub-block inside Analog Block (AB)
Voltage Regulator and Power System Monitor (VRPSM)
Crystal oscillator (XTLOSC); refer to the "Crystal Oscillator" section in the Fusion Clock
Resources chapter of the Fusion FPGA Fabric User’s Guide for more detail.
Crystal clock; does not require instantiation in RTL
1.5 V voltage regulator; does not require instantiation in RTL
All cores are powered by 3.3 V supplies, so the RTC system is operational without a 1.5 V supply during
standby mode. Figure 2-27 shows their connection.
Notes:
1. Signals are hardwired internally and do not exist in the macro core.
2. User is only required to instantiate the VRPSM macro if the user wishes to specify PUPO behavior of the voltage regulator
to be different from the default, or employ user logic to shut the voltage regulator off.
Figure 2-27 • Real-Time Counter System (not all the signals are shown for the AB macro)
VRPU PTBASE
1
PTEM
1
PUB
VRINITSTATE
RTCPSMMATCH
FPGAGOOD
PUCORE
VREN
1
VREN
1
VRPSM 1.5 Voltage Regulator
RTCXTLSEL
RTCMATCH
RTCPSMMATCH
XTLOSC
Real-Time Counter
XTAL1 XTAL2
CLKOUT
RTC_MODE[1:0]SELMODE
RTCCLK
External
Pass
Transistor
2N2222
3.3 V
Power-Up/-Down
Toggle Control
Switch
1.5 V
TRST
1
External Pin
Internal Pin
Can Be Route
to PLL
RTCXTLMODE[1:0]
Cores do not require any
RTL instantiation
Cores require RTL instantiation
2
Sub-block in cores does not
require additional RTL instantiation
XTL
XTL
1
Crystal Clock
MODE[1:0]
FPGA_EN
1
AB
Device Architecture
2-34 Revision 4
Modes of Operation
Standby Mode
Standby mode allows periodic power-up and power-down of the FPGA fabric. In standby mode, the real-
time counter and crystal block are ON. The FPGA is not powered by disabling the 1.5 V voltage
regulator. The 1.5 V voltage regulator can be enabled when the preset count is matched. Refer to the
"Real-Time Counter (part of AB macro)" section for details. To enter standby mode, the RTC must be first
configured and enabled. Then VRPSM is shut off by deasserting the VRPU signal. The 1.5 V voltage
regulator is then disabled, and shuts off the 1.5 V output.
Sleep Mode
In sleep mode, the real-time counter and crystal blocks are OFF. The 1.5 V voltage regulator inside the
VRPSM can only be enabled by the PUB or TRST pin. Refer to the "Voltage Regulator and Power
System Monitor (VRPSM)" section on page 2-37 for details on power-up and power-down of the 1.5 V
voltage regulator.
Standby and Sleep Mode Circuit Implementation
For extra power savings, VJTAG and VPUMP should be at the same voltage as VCC, floated or ground,
during standby and sleep modes. Note that when VJTAG is not powered, the 1.5 V voltage regulator
cannot be enabled through TRST.
VPUMP and VJTAG can be controlled through an external switch. Microsemi recommends ADG839,
ADG849, or ADG841 as possible switches. Figure 2-28 shows the implementation for controlling
VPUMP. The IN signal of the switch can be connected to PTBASE of the Fusion device. VJTAG can be
controlled in same manner.
Figure 2-28 • Implementation to Control VPUMP
PTBASE
PTEM
External
Pass
Transistor
2N2222
3.3 V
1.5 V
VPUMP (or JTAG)
Pin of Fusion
VPUMP (or JTAG) Supply
Fusion ADG841
S
IN
Fusion Family of Mixed Signal FPGAs
Revision 4 2-35
Real-Time Counter (part of AB macro)
The RTC is a 40-bit loadable counter and used as the primary timekeeping element (Figure 2-29). The
clock source, RTCCLK, must come from the CLKOUT signal of the crystal oscillator. The RTC can be
configured to reset itself when a count value reaches the match value set in the Match Register.
The RTC is part of the Analog Block (AB) macro. The RTC is configured by the analog configuration
MUX (ACM). Each address contains one byte of data. The circuitry in the RTC is powered by VCC33A,
so the RTC can be used in standby mode when the 1.5 V supply is not present.
The 40-bit counter can be preloaded with an initial value as a starting point by the Counter Register. The
count from the 40-bit counter can be read through the same set of address space. The count comes from
a Read-Hold Register to avoid data changing during read.
When the counter value equals the Match Register value, all Match Bits Register values will be
0xFFFFFFFFFF. The RTCMATCH and RTCPSMMATCH signals will assert. The 40-bit counter can be
configured to automatically reset to 0x0000000000 when the counter value equals the Match Register
value. The automatic reset does not apply if the Match Register value is 0x0000000000.
The RTCCLK has a prescaler to divide the clock by 128 before it is used for the 40-bit counter. Below is
an example of how to calculate the OFF time.
Figure 2-29 • RTC Block Diagram
Table 2-14 • RTC Signal Description
Signal Name Width Direction Function
RTCCLK 1 In Must come from CLKOUT of XTLOSC.
RTCXTLMODE[1:0] 2 Out Controlled by xt_mode in CTRL_STAT. Signal must connect to
the RTC_MODE signal in XTLOSC, as shown in Figure 2-27.
RTCXTLSEL 1 Out Controlled by xtal_en from CTRL_STAT register. Signal must
connect to RTC_MODE signal in XTLOSC in Figure 2-27.
RTCMATCH 1 Out Match signal for FPGA
0 – Counter value does not equal the Match Register value.
1 – Counter value equals the Match Register value.
RTCPSMMATCH 1 Out Same signal as RTCMATCH. Signal must connect to
RTCPSMMATCH in VRPSM, as shown in Figure 2-27.
xt_mode[1:0]
RTCMATCH
RTCPSMMATCH
RTCCLK
ACM
Registers
1.5 V to
3.3 V
Level
Shifter
Control Status
40-Bit Counter
Match Reg
MatchBits Reg
Counter Reg
Counter
Read-Hold Reg
Real-Time Counter
Crystal Prescaler
FRTCCLK Divide by 128
xtal_en RTCXTLSEL
RTCXTLMODE[1:0]
Device Architecture
2-36 Revision 4
Example: Calculation for Match Count
To put the Fusion device on standby for one hour using an external crystal of 32.768 KHz:
The period of the crystal oscillator is Tcrystal:
Tcrystal = 1 / 32.768 KHz = 30.518 µs
The period of the counter is Tcounter:
Tcounter = 30.518 us X 128 = 3.90625 ms
The Match Count for 1 hour is tmatch:
tmatch / Tcounter = (1 hr X 60 min/hr X 60 sec/min) / 3.90625 ms = 921600 or 0xE1000
Using a 32.768 KHz crystal, the maximum standby time of the 40-bit counter is 4,294,967,296 seconds,
which is 136 years.
Table 2-16 • RTC Control/Status Register
Bit Name Description
Default
Value
7 rtc_rst RTC Reset
1 – Resets the RTC
0 – Deassert reset on after two ACM_CLK cycle.
6 cntr_en Counter Enable
1 – Enables the counter; rtc_rst must be deasserted as well. First
counter increments after 64 RTCCLK positive edges.
0 – Disables the crystal prescaler but does not reset the counter
value. Counter value can only be updated when the counter is
disabled.
0
5 vr_en_mat Voltage Regulator Enable on Match
1 – Enables RTCMATCH and RTCPSMMATCH to output 1 when the
counter value equals the Match Register value. This enables the 1.5 V
voltage regulator when RTCPSMMATCH connects to the
RTCPSMMATCH signal in VRPSM.
0 – RTCMATCH and RTCPSMMATCH output 0 at all times.
0
4:3 xt_mode[1:0] Crystal Mode
Controls RTCXTLMODE[1:0]. Connects to RTC_MODE signal in
XTLOSC. XTL_MODE uses this value when xtal_en is 1. See the
"Crystal Oscillator" section on page 2-21 for mode configuration.
00
2 rst_cnt_omat Reset Counter on Match
1 – Enables the sync clear of the counter when the counter value
equals the Match Register value. The counter clears on the rising
edge of the clock. If all the Match Registers are set to 0, the clear is
disabled.
0 – Counter increments indefinitely
0
1 rstb_cnt Counter Reset, active Low
0 - Resets the 40-bit counter value
0
0 xtal_en Crystal Enable
Controls RTCXTLSEL. Connects to SELMODE signal in XTLOSC.
0 – XTLOSC enables control by FPGA_EN; xt_mode is not used.
Sleep mode requires this bit to equal 0.
1 – Enables XTLOSC, XTL_MODE control by xt_mode
Standby mode requires this bit to be set to 1.
See the "Crystal Oscillator" section on page 2-21 for further details on
SELMODE configuration.
0
Fusion Family of Mixed Signal FPGAs
Revision 4 2-37
Voltage Regulator and Power System Monitor (VRPSM)
The VRPSM macro controls the power-up state of the FPGA. The power-up bar (PUB) pin can turn on
the voltage regulator when set to 0. TRST can enable the voltage regulator when deasserted, allowing
the FPGA to power-up when user want access to JTAG ports. The inputs VRINITSTATE and
RTCPSMMATCH come from the flash bits and RTC, and can also power up the FPGA.
Table 2-15 • Memory Map for RTC in ACM Register and Description
ACMADDR Register Name Description Use
Default
Value
0x40 COUNTER0 Counter bits 7:0 Used to preload the counter to
a specified start point.
0x00
0x41 COUNTER1 Counter bits 15:8 0x00
0x42 COUNTER2 Counter bits 23:16 0x00
0x43 COUNTER3 Counter bits 31:24 0x00
0x44 COUNTER4 Counter bits 39:32 0x00
0x48 MATCHREG0 Match register bits 7:0 The RTC comparison bits 0x00
0x49 MATCHREG1 Match register bits 15:8 0x00
0x4A MATCHREG2 Match register bits 23:16 0x00
0x4B MATCHREG3 Match register bits 31:24 0x00
0x4C MATCHREG4 Match register bits 39:32 0x00
0x50 MATCHBIT0 Individual match bits 7:0 The output of the XNOR gates
0 – Not matched
1 – Matched
0x00
0x51 MATCHBIT1 Individual match bits 15:8 0x00
0x52 MATCHBIT2 Individual match bits 23:16 0x00
0x53 MATCHBIT3 Individual match bits 31:24 0x00
0x54 MATCHBIT4 Individual match bits 29:32 0x00
0x58 CTRL_STAT Control (write/read) / Status
(read only) register bits
Refer to Table 2-16 on
page 2-36 for details.
0x00
Note: *Signals are hardwired internally and do not exist in the macro core.
Figure 2-30 • VRPSM Macro
VRPU
PUB
VRINITSTATE
RTCPSMMATCH
FPGAGOOD
PUCORE
VREN*
VRPSM
TRST*
Device Architecture
2-38 Revision 4
Table 2-17 • VRPSM Signal Descriptions
Signal Name Width Dir. Function
VRPU 1 In Voltage Regulator Power-Up
0 – Voltage regulator disabled. PUB must be floated or pulled up, and
the TRST pin must be grounded to disable the voltage regulator.
1 – Voltage regulator enabled
VRINITSTATE 1 In Voltage Regulator Initial State
Defines the voltage Regulator status upon power-up of the 3.3 V. The
signal is configured by Libero SoC when the VRPSM macro is
generated.
Tie off to 1 – Voltage regulator enables when 3.3 V is powered.
Tie off to 0 – Voltage regulator disables when 3.3 V is powered.
RTCPSMMATCH 1 In RTC Power System Management Match
Connect from RTCPSMATCH signal from RTC in AB
0 transition to 1 turns on the voltage regulator
PUB 1 In External pin, built-in weak pull-up
Power-Up Bar
0 – Enables voltage regulator at all times
TRST* 1 In External pin, JTAG Test Reset
1 – Enables voltage regulator at all times
FPGAGOOD 1 Out Indicator that the FPGA is powered and functional
No need to connect if it is not used.
1 – Indicates that the FPGA is powered up and functional.
0 – Not possible to read by FPGA since it has already powered off.
PUCORE 1 Out Power-Up Core
Inverted signal of PUB. No need to connect if it is not used.
VREN* 1 Out Voltage Regulator Enable
Connected to 1.5 V voltage regulator in Fusion device internally.
0 – Voltage regulator disables
1 – Voltage regulator enables
Note: *Signals are hardwired internally and do not exist in the macro core.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-39
When TRST is 1 or PUB is 0, the 1.5 V voltage regulator is always ON, putting the Fusion device in
normal operation at all times. Therefore, when the JTAG port is not in reset, the Fusion device cannot
enter sleep mode or standby mode.
To enter standby mode, the Fusion device must first power-up into normal operation. The RTC is enabled
through the RTC Control/Status Register described in the "Real-Time Counter (part of AB macro)"
section on page 2-35. A match value corresponding to the wake-up time is loaded into the Match
Register. The 1.5 V voltage regulator is disabled by setting VRPU to 0 to allow the Fusion device to enter
standby mode, when the 1.5 V supply is off but the RTC remains on.
Note: * To enter and exit standby mode without any external stimulus on PUB or TRST, the vr_en_mat in the
CTRL_STAT register must also be set to 1, so that RTCPSMMATCH will assert when a match occurs; hence the
device exits standby mode.
Figure 2-31 • State Diagram for All Different Power Modes
Normal Operation
3.3 V on,
VREN Enable
Standby Mode
3.3 V On,
RTC Enabled
VREN Disabled
OFF State
3.3 V Off,
PUB Pull-Up,
TRST Pull-Down,
VREN Disabled VRPU = 0
And PUB = 1
And TRST = 0
PUB = 0
or TRST = 1
VRPU = 0
And PUB = 1
And TRST = 0
And *RTC: CTRL_STAT:
xtal_en = 1
*RTCPSMMATCH = 1
Or PUB = 0
Or TRST = 1
Sleep Mode
3.3 V On,
VREN Disabled
3.3 V ON, 1.5 V ON (VR on)
3.3 V OFF 3.3 V ON
3.3 V Power Supply ON/OFF
VINITSTATE = 0
And PUB = 1
And TRST = 0
VRINITSTATE = 1
or PUB = 0
or TRST = 1
Device Architecture
2-40 Revision 4
1.5 V Voltage Regulator
The 1.5 V voltage regulator uses an external pass transistor to generate 1.5 V from a 3.3 V supply. The
base of the pass transistor is tied to PTBASE, the collector is tied to 3.3 V, and an emitter is tied to
PTBASE and the 1.5 V supplies of the Fusion device. Figure 2-27 on page 2-33 shows the hook-up of
the 1.5 V voltage regulator to an external pass transistor.
Microsemi recommends using a PN2222A or 2N2222A transistor. The gain of such a transistor is
approximately 25, with a maximum base current of 20 mA. The maximum current that can be supported
is 0.5 A. Transistors with different gain can also be used for different current requirements.
Table 2-18 • Electrical Characteristics
VCC33A = 3.3 V
Symbol Parameter Condition Min Typical Max Units
VOUT Output Voltage Tj = 25ºC 1.425 1.5 1.575 V
ICC33A Operation Current Tj = 25ºC ILOAD = 1 mA
ILOAD = 100 mA
ILOAD = 0.5 A
11
11
30
mA
mA
mA
VOUT Load Regulation Tj = 25ºC ILOAD = 1 mA to 0.5 A 90 mV
VOUT Line Regulation Tj = 25ºC VCC33A = 2.97 V to 3.63 V
ILOAD = 1 mA
VCC33A = 2.97 V to 3.63 V
ILOAD = 100 mA
VCC33A = 2.97 V to 3.63 V
ILOAD = 500 mA
10.6
12.1
10.6
mV/V
mV/V
mV/V
Dropout Voltage* Tj = 25ºC ILOAD = 1 mA
ILOAD = 100 mA
ILOAD = 0.5 A
0.63
0.84
1.35
V
V
V
IPTBAS
E
PTBase Current Tj = 25ºC ILOAD = 1 mA
ILOAD = 100 mA
ILOAD = 0.5 A
48
736
12 20
µA
µA
mA
Note: *Data collected with 2N2222A.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-41
Embedded Memories
Fusion devices include four types of embedded memory: flash block, FlashROM, SRAM, and FIFO.
Flash Memory Block
Fusion is the first FPGA that offers a flash memory block (FB). Each FB block stores 2 Mbits of data. The
flash memory block macro is illustrated in Figure 2-32. The port pin name and descriptions are detailed
on Table 2-19 on page 2-42. All flash memory block signals are active high, except for CLK and active
low RESET. All flash memory operations are synchronous to the rising edge of CLK.
Figure 2-32 • Flash Memory Block
ADDR[17:0]
WD[31:0]
PROGRAM
CLK RESET
RD[31:0]
BUSY
STATUS[1:0]
UNPROTECTPAGE
DISCARDPAGE
OVERWRITEPROTECT
PAGELOSSPROTECT
DATAWIDTH[1:0]
REN
WEN
ERASEPAGE
SPAREPAGE
AUXBLOCK
READNEXT
OVERWRITEPAGE
PAGESTATUS
PIPE
LOCKREQUEST
Device Architecture
2-42 Revision 4
Flash Memory Block Pin Names
Table 2-19 • Flash Memory Block Pin Names
Interface Name Width Direction Description
ADDR[17:0] 18 In Byte offset into the FB. Byte-based address.
AUXBLOCK 1 In When asserted, the page addressed is used to access the auxiliary
block within that page.
BUSY 1 Out When asserted, indicates that the FB is performing an operation.
CLK 1 In User interface clock. All operations and status are synchronous to the
rising edge of this clock.
DATAWIDTH[1:0] 2 In Data width
00 = 1 byte in RD/WD[7:0]
01 = 2 bytes in RD/WD[15:0]
1x = 4 bytes in RD/WD[31:0]
DISCARDPAGE 1 In When asserted, the contents of the Page Buffer are discarded so that
a new page write can be started.
ERASEPAGE 1 In When asserted, the address page is to be programmed with all zeros.
ERASEPAGE must transition synchronously with the rising edge of
CLK.
LOCKREQUEST 1 In When asserted, indicates to the JTAG controller that the FPGA
interface is accessing the FB.
OVERWRITEPAGE 1 In When asserted, the page addressed is overwritten with the contents of
the Page Buffer if the page is writable.
OVERWRITEPROTECT 1 In When asserted, all program operations will set the overwrite protect bit
of the page being programmed.
PAGESTATUS 1 In When asserted with REN, initiates a read page status operation.
PAGELOSSPROTECT 1 In When asserted, a modified Page Buffer must be programmed or
discarded before accessing a new page.
PIPE 1 In Adds a pipeline stage to the output for operation above 50 MHz.
PROGRAM 1 In When asserted, writes the contents of the Page Buffer into the FB
page addressed.
RD[31:0] 32 Out Read data; data will be valid from the first non-busy cycle (BUSY = 0)
after REN has been asserted.
READNEXT 1 In When asserted with REN, initiates a read-next operation.
REN 1 In When asserted, initiates a read operation.
RESET 1 In When asserted, resets the state of the FB (active low).
SPAREPAGE 1 In When asserted, the sector addressed is used to access the spare
page within that sector.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-43
All flash memory block input signals are active high, except for RESET.
STATUS[1:0] 2 Out Status of the last operation completed:
00: Successful completion
01: Read-/Unprotect-Page: single error detected and corrected
Write: operation addressed a write-protected page
Erase-Page: protection violation
Program: Page Buffer is unmodified
Protection violation
10: Read-/Unprotect-Page: two or more errors detected
11: Write: attempt to write to another page before programming
current page
Erase-Page/Program: page write count has exceeded the 10-year
retention threshold
UNPROTECTPAGE 1 In When asserted, the page addressed is copied into the Page Buffer
and the Page Buffer is made writable.
WD[31:0] 32 In Write data
WEN 1 In When asserted, stores WD in the page buffer.
Table 2-19 • Flash Memory Block Pin Names (continued)
Interface Name Width Direction Description
Device Architecture
2-44 Revision 4
Flash Memory Block Diagram
A simplified diagram of the flash memory block is shown in Figure 2-33.
The logic consists of the following sub-blocks:
Flash Array
Contains all stored data. The flash array contains 64 sectors, and each sector contains 33 pages
of data.
Page Buffer
A page-wide volatile register. A page contains 8 blocks of data and an AUX block.
Block Buffer
Contains the contents of the last block accessed. A block contains 128 data bits.
ECC Logic
The FB stores error correction information with each block to perform single-bit error correction and
double-bit error detection on all data blocks.
Figure 2-33 • Flash Memory Block Diagram
ADDDR[17:0]
DATAWIDTH[1:0]
REN
READNEXT
PAGESTATUS
WEN
ERASEPAGE
PROGRAM
SPAREPAGE
AUXBLOCK
UNPROTECTPAGE
OVERWRITEPAGE
DISCARDPAGE
OVERWRITEPROTECT
PAGELOSSPROTECT
PIPE
LOCKREQUEST
CLK
RESET
STATUS[1:0]
BUSY
Control
Logic
Output
MUX
Block Buffer
(128 bits)
ECC
Logic
Flash Array = 64 Sectors
RD[31:0]
WD[31 :0]
Page Buffer = 8 Blocks
Plus AUX Block
Fusion Family of Mixed Signal FPGAs
Revision 4 2-45
Flash Memory Block Addressing
Figure 2-34 shows a graphical representation of the flash memory block.
Each FB is partitioned into sectors, pages, blocks, and bytes. There are 64 sectors in an FB, and each
sector contains 32 pages and 1 spare page. Each page contains 8 data blocks and 1 auxiliary block.
Each data block contains 16 bytes of user data, and the auxiliary block contains 4 bytes of user data.
Addressing for the FB is shown in Table 2-20.
When the spare page of a sector is addressed (SPAREPAGE active), ADDR[11:7] are ignored.
When the Auxiliary block is addressed (AUXBLOCK active), ADDR[6:2] are ignored.
Note: The spare page of sector 0 is unavailable for any user data. Writes to this page will return an error,
and reads will return all zeroes.
Figure 2-34 • Flash Memory Block Organization
Byte 0
Byte 1
Byte 2
Byte 3
Byte 14
Byte 15
Block Organization
User Data
(32 bits)
140
Block
01234567
Aux
Block
. . . .
. . . .
Sector 0
Sector 1
Sector n
. . . .
33 Pages
Page 0
Page 1
Page 2
Page 3
Page 31
Spare Pag e
1190
Notes:
1 block = 128 bits
1 page = 8 blocks plus the AUX block
1 sector = 33 pages
1 Flash array = 64 sectors
Table 2-20 • FB Address Bit Allocation ADDR[17:0]
17121176430
Sector Page Block Byte
Device Architecture
2-46 Revision 4
Data operations are performed in widths of 1 to 4 bytes. A write to a location in a page that is not already
in the Page Buffer will cause the page to be read from the FB Array and stored in the Page Buffer. The
block that was addressed during the write will be put into the Block Buffer, and the data written by WD will
overwrite the data in the Block Buffer. After the data is written to the Block Buffer, the Block Buffer is then
written to the Page Buffer to keep both buffers in sync. Subsequent writes to the same block will
overwrite the Block Buffer and the Page Buffer. A write to another block in the page will cause the
addressed block to be loaded from the Page Buffer, and the write will be performed as described
previously.
The data width can be selected dynamically via the DATAWIDTH input bus. The truth table for the data
width settings is detailed in Tab l e 2- 21 . The minimum resolvable address is one 8-bit byte. For data
widths greater than 8 bits, the corresponding address bits are ignored—when DATAWIDTH = 0 (2 bytes),
ADDR[0] is ignored, and when DATAWIDTH = '10' or '11' (4 bytes), ADDR[1:0] are ignored. Data pins are
LSB-oriented and unused WD data pins must be grounded.
Flash Memory Block Protection
Page Loss Protection
When the PAGELOSSPROTECT pin is set to logic 1, it prevents writes to any page other than the
current page in the Page Buffer until the page is either discarded or programmed.
A write to another page while the current page is Page Loss Protected will return a STATUS of '11'.
Overwrite Protection
Any page that is Overwrite Protected will result in the STATUS being set to '01' when an attempt is made
to either write, program, or erase it. To set the Overwrite Protection state for a page, set the
OVERWRITEPROTECT pin when a Program operation is undertaken. To clear the Overwrite Protect
state for a given page, an Unprotect Page operation must be performed on the page, and then the page
must be programmed with the OVERWRITEPROTECT pin cleared to save the new page.
LOCKREQUEST
The LOCKREQUEST signal is used to give the user interface control over simultaneous access of the FB
from both the User and JTAG interfaces. When LOCKREQUEST is asserted, the JTAG interface will hold
off any access attempts until LOCKREQUEST is deasserted.
Flash Memory Block Operations
FB Operation Priority
The FB provides for priority of operations when multiple actions are requested simultaneously.
Table 2-22 shows the priority order (priority 0 is the highest).
Table 2-21 • Data Width Settings
DATAWIDTH[1:0] Data Width
00 1 byte [7:0]
01 2 byte [15:0]
10, 11 4 bytes [31:0]
Table 2-22 FB Operation Priority
Operation Priority
System Initialization 0
FB Reset 1
Read 2
Write 3
Erase Page 4
Program 5
Unprotect Page 6
Discard Page 7
Fusion Family of Mixed Signal FPGAs
Revision 4 2-47
Access to the FB is controlled by the BUSY signal. The BUSY output is synchronous to the CLK signal.
FB operations are only accepted in cycles where BUSY is logic 0.
Write Operation
Write operations are initiated with the assertion of the WEN signal. Figure 2-35 on page 2-47 illustrates
the multiple Write operations.
When a Write operation is initiated to a page that is currently not in the Page Buffer, the FB control logic
will issue a BUSY signal to the user interface while the page is loaded from the FB Array into the Page
Buffer. A Copy Page operation takes no less than 55 cycles and could take more if a Write or Unprotect
Page operation is started while the NVM is busy pre-fetching a block. The basic operation is to read a
block from the array into the block register (5 cycles) and then write the block register to the page buffer
(1 cycle) and if necessary, when the copy is complete, reading the block being written from the page
buffer into the block buffer (1 cycle). A page contains 9 blocks, so 9 blocks multiplied by 6 cycles to
read/write each block, plus 1 is 55 cycles total. Subsequent writes to the same block of the page will incur
no busy cycles. A write to another block in the page will assert BUSY for four cycles (five cycles when
PIPE is asserted), to allow the data to be written to the Page Buffer and have the current block loaded
into the Block Buffer.
Write operations are considered successful as long as the STATUS output is '00'. A non-zero STATUS
indicates that an error was detected during the operation and the write was not performed. Note that the
STATUS output is "sticky"; it is unchanged until another operation is started.
Only one word can be written at a time. Write word width is controlled by the DATAWIDTH bus. Users are
responsible for keeping track of the contents of the Page Buffer and when to program it to the array. Just
like a regular RAM, writing to random addresses is possible. Users can write into the Page Buffer in any
order but will incur additional BUSY cycles. It is not necessary to modify the entire Page Buffer before
saving it to nonvolatile memory.
Write errors include the following:
1. Attempting to write a page that is Overwrite Protected (STATUS = '01'). The write is not
performed.
2. Attempting to write to a page that is not in the Page Buffer when Page Loss Protection is enabled
(STATUS = '11'). The write is not performed.
Figure 2-35 • FB Write Waveform
CLK
WEN
ADDR[17:0]
WD[31:0]
DATAWIDTH[1:0]
PAGELOSSPROTECT
BUSY
STATUS[1:0]
A0 A1 A2 A3 A4 A5 A6
D0 D1 D2 D3 D4 D5 D6
S0 S1 S2 S3 S4 S5 S6
Device Architecture
2-48 Revision 4
Program Operation
A Program operation is initiated by asserting the PROGRAM signal on the interface. Program operations
save the contents of the Page Buffer to the FB Array. Due to the technologies inherent in the FB, a
program operation is a time consuming operation (~8 ms). While the FB is writing the data to the array,
the BUSY signal will be asserted.
During a Program operation, the sector and page addresses on ADDR are compared with the stored
address for the page (and sector) in the Page Buffer. If there is a mismatch between the two addresses,
the Program operation will be aborted and an error will be reported on the STATUS output.
It is possible to write the Page Buffer to a different page in memory. When asserting the PROGRAM pin,
if OVERWRITEPAGE is asserted as well, the FB will write the contents of the Page Buffer to the sector
and page designated on the ADDR inputs if the destination page is not Overwrite Protected.
A Program operation can be utilized to either modify the contents of the page in the flash memory block or
change the protections for the page. Setting the OVERWRITEPROTECT bit on the interface while
asserting the PROGRAM pin will put the page addressed into Overwrite Protect Mode. Overwrite Protect
Mode safeguards a page from being inadvertently overwritten during subsequent Program or Erase
operations.
Program operations that result in a STATUS value of '01' do not modify the addressed page. For all other
values of STATUS, the addressed page is modified.
Program errors include the following:
1. Attempting to program a page that is Overwrite Protected (STATUS = '01')
2. Attempting to program a page that is not in the Page Buffer when the Page Buffer has entered
Page Loss Protection Mode (STATUS = '01')
3. Attempting to perform a program with OVERWRITEPAGE set when the page addressed has
been Overwrite Protected (STATUS = '01')
4. The Write Count of the page programmed exceeding the Write Threshold defined in the part
specification (STATUS = '11')
5. The ECC Logic determining that there is an uncorrectable error within the programmed page
(STATUS = '10')
6. Attempting to program a page that is not in the Page Buffer when OVERWRITEPAGE is not set
and the page in the Page Buffer is modified (STATUS = '01')
7. Attempting to program the page in the Page Buffer when the Page Buffer is not modified
The waveform for a Program operation is shown in Figure 2-36.
Note: OVERWRITEPAGE is only sampled when the PROGRAM or ERASEPAGE pins are asserted.
OVERWRITEPAGE is ignored in all other operations.
Figure 2-36 • FB Program Waveform
CLK
PROGRAM
ADDR[17:0]
OVERWRITEPAGE
OVERWRITEPROTECT
PAGELOSSPROTECT
BUSY
STATUS[1:0]
Page
0Valid
Fusion Family of Mixed Signal FPGAs
Revision 4 2-49
Erase Page Operation
The Erase Page operation is initiated when the ERASEPAGE pin is asserted. The Erase Page operation
allows the user to erase (set user data to zero) any page within the FB.
The use of the OVERWRITEPAGE and PAGELOSSPROTECT pins is the same for erase as for a
Program Page operation.
As with the Program Page operation, a STATUS of '01' indicates that the addressed page is not erased.
A waveform for an Erase Page operation is shown in Figure 2-37.
Erase errors include the following:
1. Attempting to erase a page that is Overwrite Protected (STATUS = '01')
2. Attempting to erase a page that is not in the Page Buffer when the Page Buffer has entered Page
Loss Protection mode (STATUS = '01')
3. The Write Count of the erased page exceeding the Write Threshold defined in the part
specification (STATUS = '11')
4. The ECC Logic determining that there is an uncorrectable error within the erased page (STATUS
= '10')
Figure 2-37 • FB Erase Page Waveform
CLK
ERASE
ADDR[17:0]
OVERWRITEPROTECT
PAGELOSSPROTECT
BUSY
STATUS[1:0]
Page
Valid
Device Architecture
2-50 Revision 4
Read Operation
Read operations are designed to read data from the FB Array, Page Buffer, Block Buffer, or status
registers. Read operations support a normal read and a read-ahead mode (done by asserting
READNEXT). Also, the timing for Read operations is dependent on the setting of PIPE.
The following diagrams illustrate representative timing for Non-Pipe Mode (Figure 2-38) and Pipe Mode
(Figure 2-39) reads of the flash memory block interface.
Figure 2-38 • Read Waveform (Non-Pipe Mode, 32-bit access)
Figure 2-39 • Read Waveform (Pipe Mode, 32-bit access)
CLK
REN
ADDR[17:0]
DATAWIDTH[1:0]
BUSY
STATUS[1:0]
RD[31:0]
A0 A1 A2 A3 A4
0 S0S1S2 S4
0D0D1D20D3
0S3
D4 0
A0 A1 A2 A3 A4
0S0S1S2
D2
S4
0
0
D0 D1 D4X0
CLK
REN
ADDR[17:0]
DATAWIDTH[1:0]
BUSY
STATUS[1:0]
RD[31:0]
S3
0D3
Fusion Family of Mixed Signal FPGAs
Revision 4 2-51
The following error indications are possible for Read operations:
1. STATUS = '01' when a single-bit data error was detected and corrected within the block
addressed.
2. STATUS = '10' when a double-bit error was detected in the block addressed (note that the error is
uncorrected).
In addition to data reads, users can read the status of any page in the FB by asserting PAGESTATUS
along with REN. The format of the data returned by a page status read is shown in Ta bl e 2- 23 , and the
definition of the page status bits is shown in Tabl e 2- 2 4.
Table 2-23 • Page Status Read Data Format
31 8 7 4 3 2 1 0
Write Count Reserved Over Threshold Read Protected Write Protected Overwrite Protected
Table 2-24 • Page Status Bit Definition
Page Status
Bit(s) Definition
31–8 The number of times the page addressed has been programmed/erased
7–4 Reserved; read as 0
3 Over Threshold indicator (see the"Program Operation" section on page 2-48)
2 Read Protected; read protect bit for page, which is set via the JTAG interface and
only affects JTAG operations. This bit can be overridden by using the correct user
key value.
1 Write Protected; write protect bit for page, which is set via the JTAG interface and
only affects JTAG operations. This bit can be overridden by using the correct user
key value.
0 Overwrite Protected; designates that the user has set the OVERWRITEPROTECT
bit on the interface while doing a Program operation. The page cannot be written
without first performing an Unprotect Page operation.
Device Architecture
2-52 Revision 4
Read Next Operation
The Read Next operation is a feature by which the next block relative to the block in the Block Buffer is
read from the FB Array while performing reads from the Block Buffer. The goal is to minimize wait states
during consecutive sequential Read operations.
The Read Next operation is performed in a predetermined manner because it does look-ahead reads.
The general look-ahead function is as follows:
Within a page, the next block fetched will be the next in linear address.
When reading the last data block of a page, it will fetch the first block of the next page.
When reading spare pages, it will read the first block of the next sector's spare page.
Reads of the last sector will wrap around to sector 0.
Reads of Auxiliary blocks will read the next linear page's Auxiliary block.
When an address on the ADDR input does not agree with the predetermined look-ahead address, there
is a time penalty for this access. The FB will be busy finishing the current look-ahead read before it can
start the next read. The worst case is a total of nine BUSY cycles before data is delivered.
The Non-Pipe Mode and Pipe Mode waveforms for Read Next operations are illustrated in Figure 2-40
and Figure 2-41.
Figure 2-40 • Read Next Waveform (Non-Pipe Mode, 32-bit access)
Figure 2-41 • Read Next WaveForm (Pipe Mode, 32-bit access)
CLK
REN
READNEXT
ADDR[17:0]
DATAWIDTH[1:0]
BUSY
STATUS[1:0]
RD[31:0]
A0 A1 A2 A3 A4 A5 A6 A7 A8 A9
0 S0S1S2 S4S5S6 S8S9
0D0D1D2
S3
D3
0
0
S7
D7
0
0D4 D5 D6 D8 D9
CLK
REN
READNEXT
ADDR[17:0]
BUSY
STATUS[1:0]
RD[31:0]
A0 A1 A2 A3 A4 A5 A6 A7 A8
S0 S1 S2 S4 S5 S6
0D0D1D2
S3
D3
0
0D4D5D6
S7 0
0D7
Fusion Family of Mixed Signal FPGAs
Revision 4 2-53
Unprotect Page Operation
An Unprotect Page operation will clear the protection for a page addressed on the ADDR input. It is
initiated by setting the UNPROTECTPAGE signal on the interface along with the page address on
ADDR.
If the page is not in the Page Buffer, the Unprotect Page operation will copy the page into the Page
Buffer. The Copy Page operation occurs only if the current page in the Page Buffer is not Page Loss
Protected.
The waveform for an Unprotect Page operation is shown in Figure 2-42.
The Unprotect Page operation can incur the following error conditions:
1. If the copy of the page to the Page Buffer determines that the page has a single-bit correctable
error in the data, it will report a STATUS = '01'.
2. If the address on ADDR does not match the address of the Page Buffer, PAGELOSSPROTECT is
asserted, and the Page Buffer has been modified, then STATUS = '11' and the addressed page is
not loaded into the Page Buffer.
3. If the copy of the page to the Page Buffer determines that at least one block in the page has a
double-bit uncorrectable error, STATUS = '10' and the Page Buffer will contain the corrupted data.
Discard Page Operation
If the contents of the modified Page Buffer have to be discarded, the DISCARDPAGE signal should be
asserted. This command results in the Page Buffer being marked as unmodified.
The timing for the operation is shown in Figure 2-43. The BUSY signal will remain asserted until the
operation has completed.
Figure 2-42 • FB Unprotected Page Waveform
CLK
UNPROTECTPAGE
ADDR[17:0]
BUSY
STATUS[1:0]
Page
Valid
Figure 2-43 • FB Discard Page Waveform
CLK
DISCARDPAGE
BUSY
Device Architecture
2-54 Revision 4
Flash Memory Block Characteristics
Figure 2-44 • Reset Timing Diagram
Table 2-25 • Flash Memory Block Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std.
Units
tCLK2RD Clock-to-Q in 5-cycle read mode of the Read Data 7.99 9.10 10.70 ns
Clock-to-Q in 6-cycle read mode of the Read Data 5.03 5.73 6.74 ns
tCLK2BUSY Clock-to-Q in 5-cycle read mode of BUSY 4.95 5.63 6.62 ns
Clock-to-Q in 6-cycle read mode of BUSY 4.45 5.07 5.96 ns
tCLK2STATUS Clock-to-Status in 5-cycle read mode 11.24 12.81 15.06 ns
Clock-to-Status in 6-cycle read mode 4.48 5.10 6.00 ns
tDSUNVM Data Input Setup time for the Control Logic 1.92 2.19 2.57 ns
tDHNVM Data Input Hold time for the Control Logic 0.00 0.00 0.00 ns
tASUNVM Address Input Setup time for the Control Logic 2.76 3.14 3.69 ns
tAHNVM Address Input Hold time for the Control Logic 0.00 0.00 0.00 ns
tSUDWNVM Data Width Setup time for the Control Logic 1.85 2.11 2.48 ns
tHDDWNVM Data Width Hold time for the Control Logic 0.00 0.00 0.00 ns
tSURENNVM Read Enable Setup time for the Control Logic 3.85 4.39 5.16 ns
tHDRENNVM Read Enable Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUWENNVM Write Enable Setup time for the Control Logic 2.37 2.69 3.17 ns
tHDWENNVM Write Enable Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUPROGNVM Program Setup time for the Control Logic 2.16 2.46 2.89 ns
tHDPROGNVM Program Hold time for the Control Logic 0.00 0.00 0.00 ns
tSUSPAREPAGE SparePage Setup time for the Control Logic 3.74 4.26 5.01 ns
tHDSPAREPAGE SparePage Hold time for the Control Logic 0.00 0.00 0.00 ns
tSUAUXBLK Auxiliary Block Setup Time for the Control Logic 3.74 4.26 5.00 ns
tHDAUXBLK Auxiliary Block Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSURDNEXT ReadNext Setup Time for the Control Logic 2.17 2.47 2.90 ns
tHDRDNEXT ReadNext Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUERASEPG Erase Page Setup Time for the Control Logic 3.76 4.28 5.03 ns
tHDERASEPG Erase Page Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUUNPROTECTPG Unprotect Page Setup Time for the Control Logic 2.01 2.29 2.69 ns
tHDUNPROTECTPG Unprotect Page Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUDISCARDPG Discard Page Setup Time for the Control Logic 1.88 2.14 2.52 ns
tHDDISCARDPG Discard Page Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUOVERWRPRO Overwrite Protect Setup Time for the Control Logic 1.64 1.86 2.19 ns
tHDOVERWRPRO Overwrite Protect Hold Time for the Control Logic 0.00 0.00 0.00 ns
CLK
RESET
Active Low, Asynchronous
BUSY
Fusion Family of Mixed Signal FPGAs
Revision 4 2-55
tSUPGLOSSPRO Page Loss Protect Setup Time for the Control Logic 1.69 1.93 2.27 ns
tHDPGLOSSPRO Page Loss Protect Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUPGSTAT Page Status Setup Time for the Control Logic 2.49 2.83 3.33 ns
tHDPGSTAT Page Status Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSUOVERWRPG Over Write Page Setup Time for the Control Logic 1.88 2.14 2.52 ns
tHDOVERWRPG Over Write Page Hold Time for the Control Logic 0.00 0.00 0.00 ns
tSULOCKREQUEST Lock Request Setup Time for the Control Logic 0.87 0.99 1.16 ns
tHDLOCKREQUEST Lock Request Hold Time for the Control Logic 0.00 0.00 0.00 ns
tRECARNVM Reset Recovery Time 0.94 1.07 1.25 ns
tREMARNVM Reset Removal Time 0.00 0.00 0.00 ns
tMPWARNVM Asynchronous Reset Minimum Pulse Width for the
Control Logic
10.00 12.50 12.50 ns
tMPWCLKNVM Clock Minimum Pulse Width for the Control Logic 4.00 5.00 5.00 ns
tFMAXCLKNVM Maximum Frequency for Clock for the Control Logic – for
AFS1500/AFS600
80.00 80.00 80.00 MHz
Maximum Frequency for Clock for the Control Logic – for
AFS250/AFS090
100.00 80.00 80.00 MHz
Table 2-25 • Flash Memory Block Timing (continued)
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std.
Units
Device Architecture
2-56 Revision 4
FlashROM
Fusion devices have 1 kbit of on-chip nonvolatile flash memory that can be read from the FPGA core
fabric. The FlashROM is arranged in eight banks of 128 bits during programming. The 128 bits in each
bank are addressable as 16 bytes during the read-back of the FlashROM from the FPGA core (Figure 2-
45).
The FlashROM can only be programmed via the IEEE 1532 JTAG port. It cannot be programmed directly
from the FPGA core. When programming, each of the eight 128-bit banks can be selectively
reprogrammed. The FlashROM can only be reprogrammed on a bank boundary. Programming involves
an automatic, on-chip bank erase prior to reprogramming the bank. The FlashROM supports a
synchronous read and can be read on byte boundaries. The upper three bits of the FlashROM address
from the FPGA core define the bank that is being accessed. The lower four bits of the FlashROM
address from the FPGA core define which of the 16 bytes in the bank is being accessed.
The maximum FlashROM access clock is given in Table 2-26 on page 2-57. Figure 2-46 shows the
timing behavior of the FlashROM access cycle—the address has to be set up on the rising edge of the
clock for DOUT to be valid on the next falling edge of the clock.
If the address is unchanged for two cycles:
D0 becomes invalid tCK2Q ns after the second rising edge of the clock.
D0 becomes valid again tCK2Q ns after the second falling edge.
If the address unchanged for three cycles:
D0 becomes invalid tCK2Q ns after the second rising edge of the clock.
D0 becomes valid again tCK2Q ns after the second falling edge.
D0 becomes invalid tCK2Q ns after the third rising edge of the clock.
D0 becomes valid again tCK2Q ns after the third falling edge.
Figure 2-45 • FlashROM Architecture
Bank Number
3 MSB of ADDR (READ)
Byte Number in Bank 4 LSB of ADDR (READ)
7
0
1
2
3
4
5
6
0123456789101112131415
Fusion Family of Mixed Signal FPGAs
Revision 4 2-57
FlashROM Characteristics
Figure 2-46 • FlashROM Timing Diagram
Table 2-26 • FlashROM Access Time
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description 2 –1 Std. Units
tSU Address Setup Time 0.53 0.61 0.71 ns
tHOLD Address Hold Time 0.00 0.00 0.00 ns
tCK2Q Clock to Out 21.42 24.40 28.68 ns
FMAX Maximum Clock frequency 15.00 15.00 15.00 MHz
t
SU
t
HOLD
Address
A0
t
CK2Q
D0 D0
A1
t
SU
t
HOLD
t
CK2Q
D1
t
SU
t
HOLD
t
CK2Q
Device Architecture
2-58 Revision 4
SRAM and FIFO
All Fusion devices have SRAM blocks along the north side of the device. Additionally, AFS600 and
AFS1500 devices have an SRAM block on the south side of the device. To meet the needs of high-
performance designs, the memory blocks operate strictly in synchronous mode for both read and write
operations. The read and write clocks are completely independent, and each may operate at any desired
frequency less than or equal to 350 MHz. The following configurations are available:
4k×1, 2k×2, 1k×4, 512×9 (dual-port RAM—two read, two write or one read, one write)
512×9, 256×18 (two-port RAM—one read and one write)
Sync write, sync pipelined/nonpipelined read
The Fusion SRAM memory block includes dedicated FIFO control logic to generate internal addresses
and external flag logic (FULL, EMPTY, AFULL, AEMPTY).
During RAM operation, addresses are sourced by the user logic, and the FIFO controller is ignored. In
FIFO mode, the internal addresses are generated by the FIFO controller and routed to the RAM array by
internal MUXes. Refer to Figure 2-47 for more information about the implementation of the embedded
FIFO controller.
The Fusion architecture enables the read and write sizes of RAMs to be organized independently,
allowing for bus conversion. This is done with the WW (write width) and RW (read width) pins. The
different D×W configurations are 256×18, 512×9, 1k×4, 2k×2, and 4k×1. For example, the write size can
be set to 256×18 and the read size to 512×9.
Both the write and read widths for the RAM blocks can be specified independently with the WW (write
width) and RW (read width) pins. The different D×W configurations are 256×18, 512×9, 1k×4, 2k×2, and
4k×1.
Refer to the allowable RW and WW values supported for each of the RAM macro types in Table 2-27 on
page 2-61.
When a width of one, two, or four is selected, the ninth bit is unused. For example, when writing 9-bit
values and reading 4-bit values, only the first four bits and the second four bits of each 9-bit value are
addressable for read operations. The ninth bit is not accessible.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-59
Conversely, when writing 4-bit values and reading 9-bit values, the ninth bit of a read operation will be
undefined. The RAM blocks employ little-endian byte order for read and write operations.
Figure 2-47 • Fusion RAM Block with Embedded FIFO Controller
RCLK
WD
WCLK
Reset
RBLK
REN
ESTOP
WBLK
WEN
FSTOP
RD[17:0]
WD[17:0]
RCLK
WCLK
RADD[J:0]
WADD[J:0]
REN
FREN FWEN WEN
FULL
AEMPTY
AFULL
EMPTY
RD
RPIPE
RW[2:0]
WW[2:0]
RAM
CNT 12
E=
E
=
AFVAL
AEVAL
SUB 12
CNT 12
Device Architecture
2-60 Revision 4
RAM4K9 Description
Figure 2-48 • RAM4K9
ADDRA11 DOUTA8
DOUTA7
DOUTA0
DOUTB8
DOUTB7
DOUTB0
ADDRA10
ADDRA0
DINA8
DINA7
DINA0
WIDTHA1
WIDTHA0
PIPEA
WMODEA
BLKA
WENA
CLKA
ADDRB11
ADDRB10
ADDRB0
DINB8
DINB7
DINB0
WIDTHB1
WIDTHB0
PIPEB
WMODEB
BLKB
WENB
CLKB
RAM4K9
RESET
Fusion Family of Mixed Signal FPGAs
Revision 4 2-61
The following signals are used to configure the RAM4K9 memory element:
WIDTHA and WIDTHB
These signals enable the RAM to be configured in one of four allowable aspect ratios (Table 2-27).
BLKA and BLKB
These signals are active low and will enable the respective ports when asserted. When a BLKx signal is
deasserted, the corresponding port’s outputs hold the previous value.
WENA and WENB
These signals switch the RAM between read and write mode for the respective ports. A Low on these
signals indicates a write operation, and a High indicates a read.
CLKA and CLKB
These are the clock signals for the synchronous read and write operations. These can be driven
independently or with the same driver.
PIPEA and PIPEB
These signals are used to specify pipelined read on the output. A Low on PIPEA or PIPEB indicates a
nonpipelined read, and the data appears on the corresponding output in the same clock cycle. A High
indicates a pipelined, read and data appears on the corresponding output in the next clock cycle.
WMODEA and WMODEB
These signals are used to configure the behavior of the output when the RAM is in write mode. A Low on
these signals makes the output retain data from the previous read. A High indicates pass-through
behavior, wherein the data being written will appear immediately on the output. This signal is overridden
when the RAM is being read.
RESET
This active low signal resets the output to zero, disables reads and writes from the SRAM block, and
clears the data hold registers when asserted. It does not reset the contents of the memory.
ADDRA and ADDRB
These are used as read or write addresses, and they are 12 bits wide. When a depth of less than 4 k is
specified, the unused high-order bits must be grounded (Table 2-28).
Table 2-27 • Allowable Aspect Ratio Settings for WIDTHA[1:0]
WIDTHA1, WIDTHA0 WIDTHB1, WIDTHB0 D×W
00 00 4k×1
01 01 2k×2
10 10 1k×4
11 11 512×9
Note: The aspect ratio settings are constant and cannot be changed on the fly.
Table 2-28 • Address Pins Unused/Used for Various Supported Bus Widths
D×W
ADDRx
Unused Used
4k×1 None [11:0]
2k×2 [11] [10:0]
1k×4 [11:10] [9:0]
512×9 [11:9] [8:0]
Note: The "x" in ADDRx implies A or B.
Device Architecture
2-62 Revision 4
DINA and DINB
These are the input data signals, and they are nine bits wide. Not all nine bits are valid in all
configurations. When a data width less than nine is specified, unused high-order signals must be
grounded (Ta b l e 2 - 2 9).
DOUTA and DOUTB
These are the nine-bit output data signals. Not all nine bits are valid in all configurations. As with DINA
and DINB, high-order bits may not be used (Ta bl e 2- 29 ). The output data on unused pins is undefined.
Table 2-29 • Unused/Used Input and Output Data Pins for Various Supported Bus Widths
D×W
DINx/DOUTx
Unused Used
4k×1 [8:1] [0]
2k×2 [8:2] [1:0]
1k×4 [8:4] [3:0]
512×9 None [8:0]
Note: The "x" in DINx and DOUTx implies A or B.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-63
RAM512X18 Description
Figure 2-49 • RAM512X18
RADDR8 RD17
RADDR7 RD16
RADDR0 RD0
WD17
WD16
WD0
WW1
WW0
RW1
RW0
PIPE
REN
RCLK
RAM512X18
WADDR8
WADDR7
WADDR0
WEN
WCLK
RESET
Device Architecture
2-64 Revision 4
RAM512X18 exhibits slightly different behavior from RAM4K9, as it has dedicated read and write ports.
WW and RW
These signals enable the RAM to be configured in one of the two allowable aspect ratios (Table 2-30).
WD and RD
These are the input and output data signals, and they are 18 bits wide. When a 512×9 aspect ratio is
used for write, WD[17:9] are unused and must be grounded. If this aspect ratio is used for read, then
RD[17:9] are undefined.
WADDR and RADDR
These are read and write addresses, and they are nine bits wide. When the 256×18 aspect ratio is used
for write or read, WADDR[8] or RADDR[8] are unused and must be grounded.
WCLK and RCLK
These signals are the write and read clocks, respectively. They are both active high.
WEN and REN
These signals are the write and read enables, respectively. They are both active low by default. These
signals can be configured as active high.
RESET
This active low signal resets the output to zero, disables reads and/or writes from the SRAM block, and
clears the data hold registers when asserted. It does not reset the contents of the memory.
PIPE
This signal is used to specify pipelined read on the output. A Low on PIPE indicates a nonpipelined read,
and the data appears on the output in the same clock cycle. A High indicates a pipelined read, and data
appears on the output in the next clock cycle.
Clocking
The dual-port SRAM blocks are only clocked on the rising edge. SmartGen allows falling-edge-triggered
clocks by adding inverters to the netlist, hence achieving dual-port SRAM blocks that are clocked on
either edge (rising or falling). For dual-port SRAM, each port can be clocked on either edge or by
separate clocks, by port.
Fusion devices support inversion (bubble pushing) throughout the FPGA architecture, including the clock
input to the SRAM modules. Inversions added to the SRAM clock pin on the design schematic or in the
HDL code will be automatically accounted for during design compile without incurring additional delay in
the clock path.
The two-port SRAM can be clocked on the rising edge or falling edge of WCLK and RCLK.
If negative-edge RAM and FIFO clocking is selected for memory macros, clock edge inversion
management (bubble pushing) is automatically used within the Fusion development tools, without
performance penalty.
Table 2-30 • Aspect Ratio Settings for WW[1:0]
WW[1:0] RW[1:0] D×W
01 01 512×9
10 10 256×18
00, 11 00, 11 Reserved
Fusion Family of Mixed Signal FPGAs
Revision 4 2-65
Modes of Operation
There are two read modes and one write mode:
Read Nonpipelined (synchronous—1 clock edge): In the standard read mode, new data is driven
onto the RD bus in the same clock cycle following RA and REN valid. The read address is
registered on the read port clock active edge, and data appears at RD after the RAM access time.
Setting PIPE to OFF enables this mode.
Read Pipelined (synchronous—2 clock edges): The pipelined mode incurs an additional clock
delay from the address to the data but enables operation at a much higher frequency. The read
address is registered on the read port active clock edge, and the read data is registered and
appears at RD after the second read clock edge. Setting PIPE to ON enables this mode.
Write (synchronous—1 clock edge): On the write clock active edge, the write data is written into
the SRAM at the write address when WEN is High. The setup times of the write address, write
enables, and write data are minimal with respect to the write clock. Write and read transfers are
described with timing requirements in the "SRAM Characteristics" section on page 2-66 and the
"FIFO Characteristics" section on page 2-75.
RAM Initialization
Each SRAM block can be individually initialized on power-up by means of the JTAG port using the
UJTAG mechanism (refer to the "JTAG IEEE 1532" section on page 2-232 and the Fusion SRAM/FIFO
Blocks application note). The shift register for a target block can be selected and loaded with the proper
bit configuration to enable serial loading. The 4,608 bits of data can be loaded in a single operation.
Device Architecture
2-66 Revision 4
SRAM Characteristics
Timing Waveforms
Figure 2-50 • RAM Read for Flow-Through Output. Applicable to both RAM4K9 and RAM512x18.
Figure 2-51 • RAM Read for Pipelined Output. Applicable to both RAM4K9 and RAM512x18.
CLK
[R|W]ADDR
BLK
WEN
DOUT|RD
A0A1A2
D0D1D2
tCYC
tCKH tCKL
tAS tAH
tBKS
tENS tENH
tDOH1
tBKH
Dn
tCKQ1
CLK
[R|W]ADDR
BLK
WEN
DOUT|RD
A0A1A2
D0D1
tCYC
tCKH tCKL
tAS tAH
tBKS
tENS tENH
tDOH2
tCKQ2
tBKH
Dn
Fusion Family of Mixed Signal FPGAs
Revision 4 2-67
Figure 2-52 • RAM Write, Output Retained. Applicable to both RAM4K9 and RAM512x18.
Figure 2-53 • RAM Write, Output as Write Data (WMODE = 1). Applicable to RAM4K9 Only.
tCYC
tCKH tCKL
A0A1A2
DI0DI1
tAS tAH
tBKS
tENS tENH
tDS tDH
CLK
BLK
WEN
[R|W]ADDR
DIN|WD
Dn
DOUT|RD
tBKH
D2
t
CYC
t
CKH
t
CKL
A
0
A
1
A
2
t
AS
t
AH
t
BKS
t
ENS
t
DS
t
DH
CLK
BLK
WEN
ADDR
DIN
t
BKH
DOUT
(flow-through)
DOUT
(pipelined) DI
0
DI
1
D
n
DI
0
DI
1
D
n
DI
1
DI
2
D
0
Device Architecture
2-68 Revision 4
Figure 2-54 • One Port Write / Other Port Read Same
Figure 2-55 • RAM Reset. Applicable to both RAM4K9 and RAM512x18.
A
0
A
2
A
3
A
0
A
1
A
4
CLK1
ADDR1
CLK2
ADDR2
DIN1 D
0
D
2
D
3
D
0
D
1
D
0
DOUT2
(flow-through)
DOUT2
(Pipelined)
t
CKQ2
t
CKQ1
t
WRO
t
AS
t
AH
t
DS
t
DH
t
AS
t
AH
D
n
D
n
CLK
RESET
DOUT|RD Dn
tCYC
tCKH tCKL
tRSTBQ
Dm
Fusion Family of Mixed Signal FPGAs
Revision 4 2-69
Timing Characteristics
Table 2-31 • RAM4K9
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tAS Address setup time 0.25 0.28 0.33 ns
tAH Address hold time 0.00 0.00 0.00 ns
tENS REN, WEN setup time 0.14 0.16 0.19 ns
tENH REN, WEN hold time 0.10 0.11 0.13 ns
tBKS BLK setup time 0.23 0.27 0.31 ns
tBKH BL hold time 0.02 0.02 0.02 ns
tDS Input data (DIN) setup time 0.18 0.21 0.25 ns
tDH Input data (DIN) hold time 0.00 0.00 0.00 ns
tCKQ1 Clock High to new data valid on DOUT (output retained, WMODE = 0) 1.79 2.03 2.39 ns
Clock High to new data valid on DOUT (flow-through, WMODE = 1) 2.36 2.68 3.15 ns
tCKQ2 Clock High to new data valid on DOUT (pipelined) 0.89 1.02 1.20 ns
tC2CWWH1Address collision clk-to-clk delay for reliable write after write on same
address—Applicable to Rising Edge
0.30 0.26 0.23 ns
tC2CRWH1Address collision clk-to-clk delay for reliable read access after write on
same address—Applicable to Opening Edge
0.45 0.38 0.34 ns
tC2CWRH1Address collision clk-to-clk delay for reliable write access after read on
same address— Applicable to Opening Edge
0.49 0.42 0.37 ns
tRSTBQ RESET Low to data out Low on DOUT (flow-through) 0.92 1.05 1.23 ns
RESET Low to Data Out Low on DOUT (pipelined) 0.92 1.05 1.23 ns
tREMRSTB RESET removal 0.29 0.33 0.38 ns
tRECRSTB RESET recovery 1.50 1.71 2.01 ns
tMPWRSTB RESET minimum pulse width 0.21 0.24 0.29 ns
tCYC Clock cycle time 3.23 3.68 4.32 ns
FMAX Maximum frequency 310 272 231 MHz
Notes:
1. For more information, refer to the application note Simultaneous Read-Write Operations in Dual-Port SRAM for Flash-
Based cSoCs and FPGAs.
2. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Device Architecture
2-70 Revision 4
Table 2-32 • RAM512X18
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description 2 –1 Std. Units
tAS Address setup time 0.25 0.28 0.33 ns
tAH Address hold time 0.00 0.00 0.00 ns
tENS REN, WEN setup time 0.09 0.10 0.12 ns
tENH REN, WEN hold time 0.06 0.07 0.08 ns
tDS Input data (WD) setup time 0.18 0.21 0.25 ns
tDH Input data (WD) hold time 0.00 0.00 0.00 ns
tCKQ1 Clock High to new data valid on RD (output retained) 2.16 2.46 2.89 ns
tCKQ2 Clock High to new data valid on RD (pipelined) 0.90 1.02 1.20 ns
tC2CRWH1Address collision clk-to-clk delay for reliable read access after write on
same address—Applicable to Opening Edge
0.50 0.43 0.38 ns
tC2CWRH1Address collision clk-to-clk delay for reliable write access after read on
same address— Applicable to Opening Edge
0.59 0.50 0.44 ns
tRSTBQ1 RESET Low to data out Low on RD (flow-through) 0.92 1.05 1.23 ns
RESET Low to data out Low on RD (pipelined) 0.92 1.05 1.23 ns
tREMRSTB RESET removal 0.29 0.33 0.38 ns
tRECRSTB RESET recovery 1.50 1.71 2.01 ns
tMPWRSTB RESET minimum pulse width 0.21 0.24 0.29 ns
tCYC Clock cycle time 3.23 3.68 4.32 ns
FMAX Maximum frequency 310 272 231 MHz
Notes:
1. For more information, refer to the application note Simultaneous Read-Write Operations in Dual-Port SRAM for Flash-
Based cSoCs and FPGAs.
2. For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-71
FIFO4K18 Description
Figure 2-56 • FIFO4KX18
FIFO4K18
RW2 RD17
RW1 RD16
RW0
WW2
WW1
WW0 RD0
ESTOP
FSTOP FULL
AFULL
EMPTY
AFVAL11
AEMPTY
AFVAL10
AFVAL0
AEVAL11
AEVAL10
AEVAL0
REN
RBLK
RCLK
WEN
WBLK
WCLK
RPIPE
WD17
WD16
WD0
RESET
Device Architecture
2-72 Revision 4
The following signals are used to configure the FIFO4K18 memory element:
WW and RW
These signals enable the FIFO to be configured in one of the five allowable aspect ratios (Tab l e 2 - 33 ).
WBLK and RBLK
These signals are active low and will enable the respective ports when Low. When the RBLK signal is
High, the corresponding port’s outputs hold the previous value.
WEN and REN
Read and write enables. WEN is active low and REN is active high by default. These signals can be
configured as active high or low.
WCLK and RCLK
These are the clock signals for the synchronous read and write operations. These can be driven
independently or with the same driver.
RPIPE
This signal is used to specify pipelined read on the output. A Low on RPIPE indicates a nonpipelined
read, and the data appears on the output in the same clock cycle. A High indicates a pipelined read, and
data appears on the output in the next clock cycle.
RESET
This active low signal resets the output to zero when asserted. It resets the FIFO counters. It also sets all
the RD pins Low, the FULL and AFULL pins Low, and the EMPTY and AEMPTY pins High (Ta b l e 2- 34 ).
WD
This is the input data bus and is 18 bits wide. Not all 18 bits are valid in all configurations. When a data
width less than 18 is specified, unused higher-order signals must be grounded (Table 2-34).
RD
This is the output data bus and is 18 bits wide. Not all 18 bits are valid in all configurations. Like the WD
bus, high-order bits become unusable if the data width is less than 18. The output data on unused pins is
undefined (Ta b l e 2 - 3 4).
ESTOP, FSTOP
ESTOP is used to stop the FIFO read counter from further counting once the FIFO is empty (i.e., the
EMPTY flag goes High). A High on this signal inhibits the counting.
Table 2-33 • Aspect Ratio Settings for WW[2:0]
WW2, WW1, WW0 RW2, RW1, RW0 D×W
000 000 4k×1
001 001 2k×2
010 010 1k×4
011 011 512×9
100 100 256×18
101, 110, 111 101, 110, 111 Reserved
Table 2-34 • Input Data Signal Usage for Different Aspect Ratios
D×W WD/RD Unused
4k×1 WD[17:1], RD[17:1]
2k×2 WD[17:2], RD[17:2]
1k×4 WD[17:4], RD[17:4]
512×9 WD[17:9], RD[17:9]
256×18
Fusion Family of Mixed Signal FPGAs
Revision 4 2-73
FSTOP is used to stop the FIFO write counter from further counting once the FIFO is full (i.e., the FULL
flag goes High). A High on this signal inhibits the counting.
For more information on these signals, refer to the "ESTOP and FSTOP Usage" section on page 2-73.
FULL, EMPTY
When the FIFO is full and no more data can be written, the FULL flag asserts High. The FULL flag is
synchronous to WCLK to inhibit writing immediately upon detection of a full condition and to prevent
overflows. Since the write address is compared to a resynchronized (and thus time-delayed) version of
the read address, the FULL flag will remain asserted until two WCLK active edges after a read operation
eliminates the full condition.
When the FIFO is empty and no more data can be read, the EMPTY flag asserts High. The EMPTY flag
is synchronous to RCLK to inhibit reading immediately upon detection of an empty condition and to
prevent underflows. Since the read address is compared to a resynchronized (and thus time-delayed)
version of the write address, the EMPTY flag will remain asserted until two RCLK active edges after a
write operation removes the empty condition.
For more information on these signals, refer to the "FIFO Flag Usage Considerations" section on
page 2-74.
AFULL, AEMPTY
These are programmable flags and will be asserted on the threshold specified by AFVAL and AEVAL,
respectively.
When the number of words stored in the FIFO reaches the amount specified by AEVAL while reading,
the AEMPTY output will go High. Likewise, when the number of words stored in the FIFO reaches the
amount specified by AFVAL while writing, the AFULL output will go High.
AFVAL, AEVAL
The AEVAL and AFVAL pins are used to specify the almost-empty and almost-full threshold values,
respectively. They are 12-bit signals. For more information on these signals, refer to "FIFO Flag
Usage Considerations" section.
ESTOP and FSTOP Usage
The ESTOP pin is used to stop the read counter from counting any further once the FIFO is empty (i.e.,
the EMPTY flag goes High). Likewise, the FSTOP pin is used to stop the write counter from counting any
further once the FIFO is full (i.e., the FULL flag goes High).
The FIFO counters in the Fusion device start the count at 0, reach the maximum depth for the
configuration (e.g., 511 for a 512×9 configuration), and then restart at 0. An example application for the
ESTOP, where the read counter keeps counting, would be writing to the FIFO once and reading the same
content over and over without doing another write.
Device Architecture
2-74 Revision 4
FIFO Flag Usage Considerations
The AEVAL and AFVAL pins are used to specify the 12-bit AEMPTY and AFULL threshold values,
respectively. The FIFO contains separate 12-bit write address (WADDR) and read address (RADDR)
counters. WADDR is incremented every time a write operation is performed, and RADDR is incremented
every time a read operation is performed. Whenever the difference between WADDR and RADDR is
greater than or equal to AFVAL, the AFULL output is asserted. Likewise, whenever the difference
between WADDR and RADDR is less than or equal to AEVAL, the AEMPTY output is asserted. To
handle different read and write aspect ratios, AFVAL and AEVAL are expressed in terms of total data bits
instead of total data words. When users specify AFVAL and AEVAL in terms of read or write words, the
SmartGen tool translates them into bit addresses and configures these signals automatically. SmartGen
configures the AFULL flag to assert when the write address exceeds the read address by at least a
predefined value. In a 2k×8 FIFO, for example, a value of 1,500 for AFVAL means that the AFULL flag
will be asserted after a write when the difference between the write address and the read address
reaches 1,500 (there have been at least 1500 more writes than reads). It will stay asserted until the
difference between the write and read addresses drops below 1,500.
The AEMPTY flag is asserted when the difference between the write address and the read address is
less than a predefined value. In the example above, a value of 200 for AEVAL means that the AEMPTY
flag will be asserted when a read causes the difference between the write address and the read address
to drop to 200. It will stay asserted until that difference rises above 200. Note that the FIFO can be
configured with different read and write widths; in this case, the AFVAL setting is based on the number of
write data entries and the AEVAL setting is based on the number of read data entries. For aspect ratios of
512×9 and 256×18, only 4,096 bits can be addressed by the 12 bits of AFVAL and AEVAL. The number
of words must be multiplied by 8 and 16, instead of 9 and 18. The SmartGen tool automatically uses the
proper values. To avoid halfwords being written or read, which could happen if different read and write
aspect ratios are specified, the FIFO will assert FULL or EMPTY as soon as at least a minimum of one
word cannot be written or read. For example, if a two-bit word is written and a four-bit word is being read,
the FIFO will remain in the empty state when the first word is written. This occurs even if the FIFO is not
completely empty, because in this case, a complete word cannot be read. The same is applicable in the
full state. If a four-bit word is written and a two-bit word is read, the FIFO is full and one word is read. The
FULL flag will remain asserted because a complete word cannot be written at this point.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-75
FIFO Characteristics
Timing Waveforms
Figure 2-57 • FIFO Read
Figure 2-58 • FIFO Write
t
ENS
t
ENH
t
CKQ1
t
CKQ2
t
CYC
D
0
D
1
D
n
D
n
D
0
D
2
D
1
t
BKS
t
BKH
RCLK
RBLK
REN
RD
(flow-through)
RD
(pipelined)
WCLK
WEN
WD
t
ENS
t
ENH
t
DS
t
DH
t
CYC
DI
0
DI
1
t
BKH
t
BKS
WBLK
Device Architecture
2-76 Revision 4
Figure 2-59 • FIFO Reset
Figure 2-60 • FIFO EMPTY Flag and AEMPTY Flag Assertion
MATCH (A0)
tMPWRSTB
tRSTFG
tRSTCK
tRSTAF
RCLK/
WCLK
RESET
EF
AEF
WA/RA
(Address Counter)
tRSTFG
tRSTAF
FF
AFF
RCLK
NO MATCH NO MATCH Dist = AEF_TH MATCH (EMPTY)
t
CKAF
t
RCKEF
EF
AEF
t
CYC
WA/RA
(Address Counter)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-77
Figure 2-61 • FIFO FULL and AFULL Flag Assertion
Figure 2-62 • FIFO EMPTY Flag and AEMPTY Flag Deassertion
Figure 2-63 • FIFO FULL Flag and AFULL Flag Deassertion
NO MATCH NO MATCH Dist = AFF_TH MATCH (FULL)
t
CKAF
t
WCKFF
t
CYC
WCLK
FF
AFF
WA/RA
(Address Counter)
WCLK
WA/RA
(Address Counter) MATCH
(EMPTY) NO MATCH NO MATCH NO MATCH Dist = AEF_TH + 1
NO MATCH
RCLK
EF
1st rising
edge
after 1st
write
2nd rising
edge
after 1st
write
t
RCKEF
t
CKAF
AEF
RCLK
WA/RA
(Address Counter) MATCH (FULL) NO MATCH NO MATCH NO MATCH Dist = AFF_TH – 1NO MATCH
WCLK
FF
1st Rising
Edge
After 1st
Read
1st Rising
Edge
After 2nd
Read
t
WCKF
t
CKAF
AFF
Device Architecture
2-78 Revision 4
Timing Characteristics
Table 2-35 • FIFO
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tENS REN, WEN Setup time 1.34 1.52 1.79 ns
tENH REN, WEN Hold time 0.00 0.00 0.00 ns
tBKS BLK Setup time 0.19 0.22 0.26 ns
tBKH BLK Hold time 0.00 0.00 0.00 ns
tDS Input data (WD) Setup time 0.18 0.21 0.25 ns
tDH Input data (WD) Hold time 0.00 0.00 0.00 ns
tCKQ1 Clock High to New Data Valid on RD (flow-through) 2.17 2.47 2.90 ns
tCKQ2 Clock High to New Data Valid on RD (pipelined) 0.94 1.07 1.26 ns
tRCKEF RCLK High to Empty Flag Valid 1.72 1.96 2.30 ns
tWCKFF WCLK High to Full Flag Valid 1.63 1.86 2.18 ns
tCKAF Clock High to Almost Empty/Full Flag Valid 6.19 7.05 8.29 ns
tRSTFG RESET Low to Empty/Full Flag Valid 1.69 1.93 2.27 ns
tRSTAF RESET Low to Almost-Empty/Full Flag Valid 6.13 6.98 8.20 ns
tRSTBQ RESET Low to Data out Low on RD (flow-through) 0.92 1.05 1.23 ns
RESET Low to Data out Low on RD (pipelined) 0.92 1.05 1.23 ns
tREMRSTB RESET Removal 0.29 0.33 0.38 ns
tRECRSTB RESET Recovery 1.50 1.71 2.01 ns
tMPWRSTB RESET Minimum Pulse Width 0.21 0.24 0.29 ns
tCYC Clock Cycle time 3.23 3.68 4.32 ns
FMAX Maximum Frequency for FIFO 310 272 231 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-79
Analog Block
With the Fusion family, Microsemi has introduced the world's first mixed-mode FPGA solution.
Supporting a robust analog peripheral mix, Fusion devices will support a wide variety of applications. It is
this Analog Block that separates Fusion from all other FPGA solutions on the market today.
By combining both flash and high-speed CMOS processes in a single chip, these devices offer the best
of both worlds. The high-performance CMOS is used for building RAM resources. These high-
performance structures support device operation up to 350 MHz. Additionally, the advanced Microsemi
0.13 µm flash process incorporates high-voltage transistors and a high-isolation, triple-well process. Both
of these are suited for the flash-based programmable logic and nonvolatile memory structures.
High-voltage transistors support the integration of analog technology in several ways. They aid in noise
immunity so that the analog portions of the chip can be better isolated from the digital portions,
increasing analog accuracy. Because they support high voltages, Microsemi flash FPGAs can be
connected directly to high-voltage input signals, eliminating the need for external resistor divider
networks, reducing component count, and increasing accuracy. By supporting higher internal voltages,
the Microsemi advanced flash process enables high dynamic range on analog circuitry, increasing
precision and signal–noise ratio. Microsemi flash FPGAs also drive high-voltage outputs, eliminating the
need for external level shifters and drivers.
The unique triple-well process enables the integration of high-performance analog features with
increased noise immunity and better isolation. By increasing the efficiency of analog design, the triple-
well process also enables a smaller overall design size, reducing die size and cost.
The Analog Block consists of the Analog Quad I/O structure, RTC (for details refer to the "Real-Time
Counter System" section on page 2-33), ADC, and ACM. All of these elements are combined in the
single Analog Block macro, with which the user implements this functionality (Figure 2-64).
The Analog Block needs to be reset/reinitialized after the core powers up or the device is programmed.
An external reset/initialize signal, which can come from the internal voltage regulator when it powers up,
must be applied.
Device Architecture
2-80 Revision 4
Figure 2-64 • Analog Block Macro
VAREF
ADCGNDREF
AV0
AC0
AT0
AV9
AC9
AT9
ATRETURN01
ATRETURN9
DENAV0
DENAC0
DAVOUT0
DACOUT0
DATOUT0
DACOUT9
DAVOUT9
DATOUT9
AG1
AG0
AG9
DENAT0
DENAV0
DENAC0
DENAT0
CMSTB0
CSMTB9
GDON0
GDON9
TMSTB0
TMSTB9
MODE[3:0]
TVC[7:0]
STC[7:0]
CHNUMBER[4:0]
TMSTINT
ADCSTART
VAREFSEL
PWRDWN
ADCRESET
BUSY
CALIBRATE
DATAVALID
SAMPLE
RESULT[11:0]
RTCMATCH
RTCXTLMODE
RTCXTLSEL
RTCPSMMATCH
RTCCLK
SYSCLK
ACMWEN ACMRDATA[7:0]
ACMRESET
ACMWDATA
ACMADDR
ACMCLK
AB
Fusion Family of Mixed Signal FPGAs
Revision 4 2-81
Table 2-36 describes each pin in the Analog Block. Each function within the Analog Block will be
explained in detail in the following sections.
Table 2-36 • Analog Block Pin Description
Signal Name
Number
of Bits Direction Function
Location of
Details
VAREF 1 Input/Output Voltage reference for ADC ADC
ADCGNDREF 1 Input External ground reference ADC
MODE[3:0] 4 Input ADC operating mode ADC
SYSCLK 1 Input External system clock
TVC[7:0] 8 Input Clock divide control ADC
STC[7:0] 8 Input Sample time control ADC
ADCSTART 1 Input Start of conversion ADC
PWRDWN 1 Input ADC comparator power-down if 1.
When asserted, the ADC will stop
functioning, and the digital portion of
the analog block will continue
operating. This may result in invalid
status flags from the analog block.
Therefore, Microsemi does not
recommend asserting the PWRDWN
pin.
ADC
ADCRESET 1 Input ADC resets and disables Analog Quad
– active high
ADC
BUSY 1 Output 1 – Running conversion ADC
CALIBRATE 1 Output 1 – Power-up calibration ADC
DATAVALID 1 Output 1 – Valid conversion result ADC
RESULT[11:0] 12 Output Conversion result ADC
TMSTBINT 1 Input Internal temp. monitor strobe ADC
SAMPLE 1 Output 1 – An analog signal is actively being
sampled (stays high during signal
acquisition only)
0 – No analog signal is being sampled
ADC
VAREFSEL 1 Input 0 = Output internal voltage reference
(2.56 V) to VAREF
1 = Input external voltage reference
from VAREF and ADCGNDREF
ADC
CHNUMBER[4:0] 5 Input Analog input channel select Input
multiplexer
ACMCLK 1 Input ACM clock ACM
ACMWEN 1 Input ACM write enable – active high ACM
ACMRESET 1 Input ACM reset – active low ACM
ACMWDATA[7:0] 8 Input ACM write data ACM
ACMRDATA[7:0] 8 Output ACM read data ACM
ACMADDR[7:0] 8 Input ACM address ACM
CMSTB0 to CMSTB9 10 Input Current monitor strobe – 1 per quad,
active high
Analog Quad
Device Architecture
2-82 Revision 4
GDON0 to GDON9 10 Input Control to power MOS – 1 per quad Analog Quad
TMSTB0 to TMSTB9 10 Input Temperature monitor strobe – 1 per
quad; active high
Analog Quad
DAVOUT0, DACOUT0, DATOUT0
to
DAVOUT9, DACOUT9, DATOUT9
30 Output Digital outputs – 3 per quad Analog Quad
DENAV0, DENAC0, DENAT0 to
DENAV9, DENAC9, DENAT9
30 Input Digital input enables – 3 per quad Analog Quad
AV0 1 Input Analog Quad 0 Analog Quad
AC0 1 Input Analog Quad
AG0 1 Output Analog Quad
AT0 1 Input Analog Quad
ATRETURN01 1 Input Temperature monitor return shared by
Analog Quads 0 and 1
Analog Quad
AV1 1 Input Analog Quad 1 Analog Quad
AC1 1 Input Analog Quad
AG1 1 Output Analog Quad
AT1 1 Input Analog Quad
AV2 1 Input Analog Quad 2 Analog Quad
AC2 1 Input Analog Quad
AG2 1 Output Analog Quad
AT2 1 Input Analog Quad
ATRETURN23 1 Input Temperature monitor return shared by
Analog Quads 2 and 3
Analog Quad
AV3 1 Input Analog Quad 3 Analog Quad
AC3 1 Input Analog Quad
AG3 1 Output Analog Quad
AT3 1 Input Analog Quad
AV4 1 Input Analog Quad 4 Analog Quad
AC4 1 Input Analog Quad
AG4 1 Output Analog Quad
AT4 1 Input Analog Quad
ATRETURN45 1 Input Temperature monitor return shared by
Analog Quads 4 and 5
Analog Quad
AV5 1 Input Analog Quad 5 Analog Quad
AC5 1 Input Analog Quad
AG5 1 Output Analog Quad
AT5 1 Input Analog Quad
AV6 1 Input Analog Quad 6 Analog Quad
AC6 1 Input Analog Quad
Table 2-36 • Analog Block Pin Description (continued)
Signal Name
Number
of Bits Direction Function
Location of
Details
Fusion Family of Mixed Signal FPGAs
Revision 4 2-83
Analog Quad
With the Fusion family, Microsemi introduces the Analog Quad, shown in Figure 2-65 on page 2-84, as
the basic analog I/O structure. The Analog Quad is a four-channel system used to precondition a set of
analog signals before sending it to the ADC for conversion into a digital signal. To maximize the
usefulness of the Analog Quad, the analog input signals can also be configured as LVTTL digital input
signals. The Analog Quad is divided into four sections.
The first section is called the Voltage Monitor Block, and its input pin is named AV. It contains a two-
channel analog multiplexer that allows an incoming analog signal to be routed directly to the ADC or
allows the signal to be routed to a prescaler circuit before being sent to the ADC. The prescaler can be
configured to accept analog signals between –12 V and 0 or between 0 and +12 V. The prescaler circuit
scales the voltage applied to the ADC input pad such that it is compatible with the ADC input voltage
range. The AV pin can also be used as a digital input pin.
The second section of the Analog Quad is called the Current Monitor Block. Its input pin is named AC.
The Current Monitor Block contains all the same functions as the Voltage Monitor Block with one
addition, which is a current monitoring function. A small external current sensing resistor (typically less
than 1 ) is connected between the AV and AC pins and is in series with a power source. The Current
Monitor Block contains a current monitor circuit that converts the current through the external resistor to
a voltage that can then be read using the ADC.
AG6 1 Output Analog Quad
AT6 1 Input Analog Quad
ATRETURN67 1 Input Temperature monitor return shared by
Analog Quads 6 and 7
Analog Quad
AV7 1 Input Analog Quad 7 Analog Quad
AC7 1 Input Analog Quad
AG7 1 Output Analog Quad
AT7 1 Input Analog Quad
AV8 1 Input Analog Quad 8 Analog Quad
AC8 1 Input Analog Quad
AG8 1 Output Analog Quad
AT8 1 Input Analog Quad
ATRETURN89 1 Input Temperature monitor return shared by
Analog Quads 8 and 9
Analog Quad
AV9 1 Input Analog Quad 9 Analog Quad
AC9 1 Input Analog Quad
AG9 1 Output Analog Quad
AT9 1 Input Analog Quad
RTCMATCH 1 Output MATCH RTC
RTCPSMMATCH 1 Output MATCH connected to VRPSM RTC
RTCXTLMODE[1:0] 2 Output Drives XTLOSC RTCMODE[1:0] pins RTC
RTCXTLSEL 1 Output Drives XTLOSC MODESEL pin RTC
RTCCLK 1 Input RTC clock input RTC
Table 2-36 • Analog Block Pin Description (continued)
Signal Name
Number
of Bits Direction Function
Location of
Details
Device Architecture
2-84 Revision 4
The third part of the Analog Quad is called the Gate Driver Block, and its output pin is named AG. This
section is used to drive an external FET. There are two modes available: a High Current Drive mode and
a Current Source Control mode. Both negative and positive voltage polarities are available, and in the
current source control mode, four different current levels are available.
The fourth section of the Analog Quad is called the Temperature Monitor Block, and its input pin name is
AT. This block is similar to the Voltage Monitor Block, except that it has an additional function: it can be
used to monitor the temperature of an external diode-connected transistor. It has a modified prescaler
and is limited to positive voltages only.
The Analog Quad can be configured during design time by Libero SoC; however, the ACM can be used
to change the parameters of any of these I/Os during runtime. This type of change is referred to as a
context switch. The Analog Quad is a modular structure that is replicated to generate the analog I/O
resources. Each Fusion device supports between 5 and 10 Analog Quads.
The analog pads are numbered to clearly identify both the type of pad (voltage, current, gate driver, or
temperature pad) and its corresponding Analog Quad (AV0, AC0, AG0, AT0, AV1, …, AC9, AG9, and
AT9). There are three types of input pads (AVx, ACx, and ATx) and one type of analog output pad (AGx).
Since there can be up to 10 Analog Quads on a device, there can be a maximum of 30 analog input pads
and 10 analog output pads.
Figure 2-65 • Analog Quad
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Prescaler Prescaler Prescaler
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor/Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-85
Voltage Monitor
The Fusion Analog Quad offers a robust set of voltage-monitoring capabilities unique in the FPGA
industry. The Analog Quad comprises three analog input pads— Analog Voltage (AV), Analog Current
(AC), and Analog Temperature (AT)—and a single gate driver output pad, Analog Gate (AG). There are
many common characteristics among the analog input pads. Each analog input can be configured to
connect directly to the input MUX of the ADC. When configured in this manner (Figure 2-66), there will be
no prescaling of the input signal. Care must be taken in this mode not to drive the ADC into saturation by
applying an input voltage greater than the reference voltage. The internal reference voltage of the ADC is
2.56 V. Optionally, an external reference can be supplied by the user. The external reference can be a
maximum of 3.3 V DC.
Figure 2-66 • Analog Quad Direct Connect
Prescaler Prescaler Prescaler
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
Device Architecture
2-86 Revision 4
The Analog Quad offers a wide variety of prescaling options to enable the ADC to resolve the input
signals. Figure 2-67 shows the path through the Analog Quad for a signal that is to be prescaled prior to
conversion. The ADC internal reference voltage and the prescaler factors were selected to make both
prescaling and postscaling of the signals easy binary calculations (refer to Table 2-57 on page 2-133 for
details). When an analog input pad is configured with a prescaler, there will be a 1 M resistor to ground.
This occurs even when the device is in power-down mode. In low power standby or sleep mode (VCC is
OFF, VCC33A is ON, VCCI is ON) or when the resource is not used, analog inputs are pulled down to
ground through a 1 M resistor. The gate driver output is floating (or tristated), and there is no extra
current on VCC33A.
These scaling factors hold true whether the particular pad is configured to accept a positive or negative
voltage. Note that whereas the AV and AC pads support the same prescaling factors, the AT pad
supports a reduced set of prescaling factors and supports positive voltages only.
Typical scaling factors are given in Table 2-57 on page 2-133, and the gain error (which contributes to the
minimum and maximum) is in Table 2-49 on page 2-120.
Figure 2-67 • Analog Quad Prescaler Input Configuration
Prescaler Prescaler Prescaler
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-87
Terminology
BW – Bandwidth
BW is a range of frequencies that a Channel can handle.
Channel
A channel is define as an analog input configured as one of the Prescaler range shown in Table 2-57 on
page 2-133. The channel includes the Prescaler circuit and the ADC.
Channel Gain
Channel Gain is a measured of the deviation of the actual slope from the ideal slope. The slope is
measured from the 20% and 80% point.
EQ 1
Channel Gain Error
Channel Gain Error is a deviation from the ideal slope of the transfer function. The Prescaler Gain Error
is expressed as the percent difference between the actual and ideal, as shown in EQ 2.
EQ 2
Channel Input Offset Error
Channel Offset error is measured as the input voltage that causes the transition from zero to a count of
one. An Ideal Prescaler will have offset equal to ½ of LSB voltage. Offset error is a positive or negative
when the first transition point is higher or lower than ideal. Offset error is expressed in LSB or input
voltage.
Total Channel Error
Total Channel Error is defined as the total error measured compared to the ideal value. Total Channel
Error is the sum of gain error and offset error combined. Figure 2-68 shows how Total Channel Error is
measured.
Total Channel Error is defined as the difference between the actual ADC output and ideal ADC output. In
the example shown in Figure 2-68, the Total Channel Error would be a negative number.
Figure 2-68 • Total Channel Error Example
Gain Gainactual
Gainideal
-------------------------
=
ErrorGain (1-Gain) 100%=
ADC Output Code
Ideal Output
Input Voltage to Prescaler
Total C hannel Error
Channel Gain
Actual Output
Channel Input
Offset Error
}
Device Architecture
2-88 Revision 4
Direct Digital Input
The AV, AC, and AT pads can also be configured as high-voltage digital inputs (Figure 2-69). As these
pads are 12 V–tolerant, the digital input can also be up to 12 V. However, the frequency at which these
pads can operate is limited to 10 MHz.
To enable one of these analog input pads to operate as a digital input, its corresponding Digital Input
Enable (DENAxy) pin on the Analog Block must be pulled High, where x is either V, C, or T (for AV, AC,
or AT pads, respectively) and y is in the range 0 to 9, corresponding to the appropriate Analog Quad.
When the pad is configured as a digital input, the signal will come out of the Analog Block macro on the
appropriate DAxOUTy pin, where x represents the pad type (V for AV pad, C for AC pad, or T for AT pad)
and y represents the appropriate Analog Quad number. Example: If the AT pad in Analog Quad 5 is
configured as a digital input, it will come out on the DATOUT5 pin of the Analog Block macro.
Figure 2-69 • Analog Quad Direct Digital Input Configuration
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
PrescalerPrescalerPrescaler
Fusion Family of Mixed Signal FPGAs
Revision 4 2-89
Current Monitor
The Fusion Analog Quad is an excellent element for voltage- and current-monitoring applications. In
addition to supporting the same functionality offered by the AV pad, the AC pad can be configured to
monitor current across an external sense resistor (Figure 2-70). To support this current monitor function,
a differential amplifier with 10x gain passes the amplified voltage drop between the AV and AC pads to
the ADC. The amplifier enables the user to use very small resistor values, thereby limiting any impact on
the circuit. This function of the AC pad does not limit AV pad operation. The AV pad can still be
configured for use as a direct voltage input or scaled through the AV prescaler independently of it’s use
as an input to the AC pad’s differential amplifier.
Figure 2-70 • Analog Quad Current Monitor Configuration
PrescalerPrescalerPrescaler
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Power
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
Device Architecture
2-90 Revision 4
To initiate a current measurement, the appropriate Current Monitor Strobe (CMSTB) signal on the AB
macro must be asserted low for at least tCMSLO in order to discharge the previous measurement. Then
CMSTB must be asserted high for at least tCMSET prior to asserting the ADCSTART signal. The CMSTB
must remain high until after the SAMPLE signal is de-asserted by the AB macro. Note that the minimum
sample time cannot be less than tCMSHI. Figure 2-71 shows the timing diagram of CMSTB in relationship
with the ADC control signals.
Figure 2-72 illustrates positive current monitor operation. The differential voltage between AV and AC
goes into the 10× amplifier and is then converted by the ADC. For example, a current of 1.5 A is drawn
from a 10 V supply and is measured by the voltage drop across a 0.050 sense resistor, The voltage
drop is amplified by ten times by the amplifier and then measured by the ADC. The 1.5 A current creates
a differential voltage across the sense resistor of 75 mV. This becomes 750 mV after amplification. Thus,
the ADC measures a current of 1.5 A as 750 mV. Using an ADC with 8-bit resolution and VAREF of 2.56
V, the ADC result is decimal 75. EQ 3 shows how to compute the current from the ADC result.
EQ 3
where
I is the current flowing through the sense resistor
ADC is the result from the ADC
VAREF is the Reference voltage
N is the number of bits
Rsense is the resistance of the sense resistor
Figure 2-71 • Timing Diagram for Current Monitor Strobe
VADC
t
CMSET
CMSTBx
ADCSTART can be asserted
after this point to start ADC
sampling.
tCMSHI
ADCSTART
t
CMSLO
IADC VAREF
10 2N
Rsense
=
Fusion Family of Mixed Signal FPGAs
Revision 4 2-91
Care must be taken when choosing the right resistor for current measurement application. Note that
because of the 10× amplification, the maximum measurable difference between the AV and AC pads is
VAREF / 10. A larger AV-to-AC voltage drop will result in ADC saturation; that is, the digital code put out by
the ADC will stay fixed at the full scale value. Therefore, the user must select the external sense resistor
appropriately. Table 2-38 shows recommended resistor values for different current measurement ranges.
When choosing resistor values for a system, there is a trade-off between measurement accuracy and
power consumption. Choosing a large resistor will increase the voltage drop and hence increase
accuracy of the measurement; however the larger voltage drop dissipates more power (P = I2 × R).
The Current Monitor is a unipolar system, meaning that the differential voltage swing must be from 0 V to
VAREF/10. Therefore, the Current Monitor only supports differential voltage where |VAV-VAC| is greater
than 0 V. This results in the requirement that the potential of the AV pad must be larger than the potential
of the AC pad. This is straightforward for positive voltage systems. For a negative voltage system, it
means that the AV pad must be "more negative" than the AC pad. This is shown in Figure 2-73.
In this case, both the AV pad and the AC pad are configured for negative operations and the output of the
differential amplifier still falls between 0 V and VAREF as required.
Figure 2-72 • Positive Current Monitor
0-12 V
R
SENSE
I
ACx
AVx
CMSTBx
10 X
Current Monitor
VADC
to Analog MUX
(refer Table 2-3
6
for MUX chann
el
number)
Device Architecture
2-92 Revision 4
Terminology
Accuracy
The accuracy of Fusion Current Monitor is ±2 mV minimum plus 5% of the differential voltage at the
input. The input accuracy can be translated to error at the ADC output by using EQ 4. The 10 V/V gain is
the gain of the Current Monitor Circuit, as described in the "Current Monitor" section on page 2-89. For 8-
bit mode, N = 8, VAREF= 2.56 V, zero differential voltage between AV and AC, the Error (EADC) is equal to
2 LSBs.
EQ 4
where
N is the number of bits
VAREF is the Reference voltage
VAV is the voltage at AV pad
VAC is the voltage at AC pad
Table 2-37 • Recommended Resistor for Different Current Range Measurement
Current Range Recommended Minimum Resistor Value (Ohms)
> 5 mA – 10 mA 10 – 20
> 10 mA – 20 mA 5 – 10
> 20 mA – 50 mA 2.5 – 5
> 50 mA – 100 mA 1 – 2
> 100 mA – 200 mA 0.5 – 1
> 200 mA – 500 mA 0.3 – 0.5
> 500 mA – 1 A 0.1 – 0.2
> 1 A – 2 A 0.05 – 0.1
> 2 A – 4 A 0.025 – 0.05
> 4 A – 8 A 0.0125 – 0.025
> 8 A – 12 A 0.00625 – 0.02
Figure 2-73 • Negative Current Monitor
I
RSENSE
0 to
–10.5 V
AVx ACx
CMSTBx
10 X VADC
Current Monitor
to Analog MUX
(see Table 2-36
for MUXchannel
number)
EADC 2mV 0.05 VAV VAC
+10VV 2N
VAREF
-----------------
=
Fusion Family of Mixed Signal FPGAs
Revision 4 2-93
Gate Driver
The Fusion Analog Quad includes a Gate Driver connected to the Quad's AG pin (Figure 2-74).
Designed to work with external p- or n-channel MOSFETs, the Gate driver is a configurable current sink
or source and requires an external pull-up or pull-down resistor. The AG supports 4 selectable gate drive
levels: 1 µA, 3 µA, 10 µA, and 30 µA (Figure 2-75 on page 2-94). The AG also supports a High Current
Drive mode in which it can sink 20 mA; in this mode the switching rate is approximately 1.3 MHz with
100 ns turn-on time and 600 ns turn-off time. Modeled on an open-drain-style output, it does not output a
voltage level without an appropriate pull-up or pull-down resistor. If 1 V is forced on the drain, the current
sinking/sourcing will exceed the ability of the transistor, and the device could be damaged.
The AG pad is turned on via the corresponding GDONx pin in the Analog Block macro, where x is the
number of the corresponding Analog Quad for the AG pad to be enabled (GDON0 to GDON9).
The gate-to-source voltage (Vgs) of the external MOSFET is limited to the programmable drive current
times the external pull-up or pull-down resistor value (EQ 5).
Vgs Ig × (Rpullup or Rpulldown)
EQ 5
The rate at which the gate voltage of the external MOSFET slews is determined by the current, Ig,
sourced or sunk by the AG pin and the gate-to-source capacitance, CGS, of the external MOSFET. As an
approximation, the slew rate is given by EQ 6.
dv/dt = Ig / CGS
EQ 6
Figure 2-74 • Gate Driver
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Power Line Side Load Side
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip R
pullup
From FPGA
(GDONx)
PrescalerPrescalerPrescaler
Device Architecture
2-94 Revision 4
CGS is not a fixed capacitance but, depending on the circuitry connected to its drain terminal, can vary
significantly during the course of a turn-on or turn-off transient. Thus, EQ 6 on page 2-93 can only be
used for a first-order estimate of the switching speed of the external MOSFET.
Figure 2-75 • Gate Driver Example
AG
High
Current
High
Current
1 μA3 μA 10 μA 30 μA
1 μA3 μA 10 μA 30 μA
Fusion Family of Mixed Signal FPGAs
Revision 4 2-95
Temperature Monitor
The final pin in the Analog Quad is the Analog Temperature (AT) pin. The AT pin is used to implement an
accurate temperature monitor in conjunction with an external diode-connected bipolar transistor
(Figure 2-76). For improved temperature measurement accuracy, it is important to use the ATRTN pin for
the return path of the current sourced by the AT pin. Each ATRTN pin is shared between two adjacent
Analog Quads. Additionally, if not used for temperature monitoring, the AT pin can provide functionality
similar to that of the AV pad. However, in this mode only positive voltages can be applied to the AT pin,
and only two prescaler factors are available (16 V and 4 V ranges—refer to Table 2-57 on page 2-133).
Figure 2-76 • Temperature Monitor Quad
Analog Quad
AV AC AT
Voltage
Monitor Block
Current
Monitor Block
AG
Digital
Input
Power
MOSFET
Gate Driver
Current
Monitor / Instr
Amplifier
Temperature
Monitor
Digital
Input
Digital
Input
Pads
To Analog MUX To Analog MUX To Analog MUX
To FPGA
(DAVOUTx)
To FPGA
(DACOUTx)
To FPGA
(DATOUTx)
On-Chip
Gate
Driver
Temperature
Monitor Block
Off-Chip
From FPGA
(GDONx)
Prescaler
PrescalerPrescaler
ATRTN
Discrete
Bipolar
Transistor
Device Architecture
2-96 Revision 4
Fusion uses a remote diode as a temperature sensor. The Fusion Temperature Monitor uses a
differential input; the AT pin and ATRTN (AT Return) pin are the differential inputs to the Temperature
Monitor. There is one Temperature Monitor in each Quad. A simplified block diagram is shown in
Figure 2-77.
The Fusion approach to measuring temperature is forcing two different currents through the diode with a
ratio of 10:1. The switch that controls the different currents is controlled by the Temperature Monitor
Strobe signal, TMSTB. Setting TMSTB to '1' will initiate a Temperature reading. The TMSTB should
remain '1' until the ADC finishes sampling the voltage from the Temperature Monitor. The minimum
sample time for the Temperature Monitor cannot be less than the minimum strobe high time minus the
setup time. Figure 2-78 shows the timing diagram.
Note: When the IEEE 1149.1 Boundary Scan EXTEST instruction is executed, the AG pad drive
strength ceases and becomes a 1 µA sink into the Fusion device.
Figure 2-77 • Block Diagram for Temperature Monitor Circuit
Figure 2-78 • Timing Diagram for the Temperature Monitor Strobe Signal
TMSTBx
VDD33A
ATRTNxy
ATx
12.5 X
V
to Analog MUX
(refer Table 2-36
for MUX Channel
Number)
VADC
100
μA
10
μA
+
+
VADC
TMSTBx
ADC should start
sampling at this point
ADCSTART
tTMSLO
tTMSHI
tTMSSET
Fusion Family of Mixed Signal FPGAs
Revision 4 2-97
The diode’s voltage is measured at each current level and the temperature is calculated based on EQ 7.
EQ 7
where
ITMSLO is the current when the Temperature Strobe is Low, typically 100 µA
ITMSHI is the current when the Temperature Strobe is High, typically 10 µA
VTMSLO is diode voltage while Temperature Strobe is Low
VTMSHI is diode voltage while Temperature Strobe is High
n is the non-ideality factor of the diode-connected transistor. It is typically 1.004 for the Microsemi-
recommended transistor type 2N3904.
K = 1.3806 x 10-23 J/K is the Boltzman constant
Q = 1.602 x 10-19 C is the charge of a proton
When ITMSLO / ITMSHI = 10, the equation can be simplified as shown in EQ 8.
EQ 8
In the Fusion TMB, the ideality factor n for 2N3904 is 1.004 and V is amplified 12.5 times by an internal
amplifier; hence the voltage before entering the ADC is as given in EQ 9.
EQ 9
This means the temperature to voltage relationship is 2.5 mV per degree Kelvin. The unique design of
Fusion has made the Temperature Monitor System simple for the user. When the 10-bit mode ADC is
used, each LSB represents 1 degree Kelvin, as shown in EQ 10. That is, e. 25°C is equal to 293°K and is
represented by decimal 293 counts from the ADC.
EQ 10
If 8-bit mode is used for the ADC resolution, each LSB represents 4 degrees Kelvin; however, the
resolution remains as 1 degree Kelvin per LSB, even for 12-bit mode, due to the Temperature Monitor
design. An example of the temperature data format for 10-bit mode is shown in Tab le 2 - 3 8 .
Table 2-38 • Temperature Data Format
Temperature Temperature (K)
Digital Output
(ADC 10-bit mode)
–40°C 233 00 1110 1001
–20°C 253 00 1111 1101
0°C 273 01 0001 0001
1°C 274 01 0001 0010
10 °C 283 01 0001 1011
25°C 298 01 0010 1010
50 °C 323 01 0100 0011
85 °C 358 01 0110 0110
VTMSLO VTMSHI
nkT
q
-------lnITMSLO
ITMSHI
-----------------


=
VV
TMSLO VTMSHI
1.986 10 4
nT==
VADC V12.52.5 mV KT==
1K2.5 mV 210
2.56 V
-----------------
1 LSB==
Device Architecture
2-98 Revision 4
Terminology
Resolution
Resolution defines the smallest temperature change Fusion Temperature Monitor can resolve. For ADC
configured as 8-bit mode, each LSB represents 4°C, and 1°C per LSB for 10-bit mode. With 12-bit mode,
the Temperature Monitor can still only resolve 1°C due to Temperature Monitor design.
Offset
The Fusion Temperature Monitor has a systematic offset (Table 2-49 on page 2-120), excluding error due
to board resistance and ideality factor of the external diode. Microsemi provides an IP block (CalibIP) that
is required in order to mitigate the systematic temperature offset. For further details on CalibIP, refer to
the "Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion
FPGA Fabric User's Guide.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-99
Analog-to-Digital Converter Block
At the heart of the Fusion analog system is a programmable Successive Approximation Register (SAR)
ADC. The ADC can support 8-, 10-, or 12-bit modes of operation. In 12-bit mode, the ADC can resolve
500 ksps. All results are MSB-justified in the ADC. The input to the ADC is a large 32:1 analog input
multiplexer. A simplified block diagram of the Analog Quads, analog input multiplexer, and ADC is shown
in Figure 2-79. The ADC offers multiple self-calibrating modes to ensure consistent high performance
both at power-up and during runtime.
Figure 2-79 • ADC Block Diagram
ADC
12
Analog MUX
(32 to 1)
Temperature
Monitor
Pads
Internal Diode
Digital Output to FPGA
AV0
AC0
AG0
AT0
AV1
AC1
AG1
AT1
AV2
AC2
AG2
AT2
AV3
AC3
AG3
AT3
AV4
AC4
AG4
AT4
AV5
AC5
AG5
AT5
AV6
AC6
AG6
AT6
AV7
AC7
AG7
AT7
AV8
AC8
AG8
AT8
AV9
AC9
AG9
AT9
ATRETURN89
ATRETURN67
ATRETURN45
ATRETURN23
ATRETURN01
Analog
Quad 0
Analog
Quad 4
Analog
Quad 5
Analog
Quad 6
Analog
Quad 7
Analog
Quad 8
Analog
Quad 9
Analog
Quad 3
Analog
Quad 2
Analog
Quad 1
V
CC
(1.5 V)
0
1
31
These are hardwired
connections within
Analog Quad.
CHNUMBER[4:0]
Device Architecture
2-100 Revision 4
ADC Description
The Fusion ADC is a 12-bit SAR ADC. It offers a wide variety of features for different use models.
Figure 2-80 shows a block diagram of the Fusion ADC.
Configurable resolution: 8-bit, 10-bit, and 12-bit mode
DNL: 0.6 LSB for 10-bit mode
INL: 0.4 LSB for 10-bit mode
No missing code
Internal VAREF = 2.56 V
Maximum Sample Rate = 600 Ksps
Power-up calibration and dynamic calibration after every sample to compensate for temperature
drift over time
ADC Theory of Operation
An analog-to-digital converter is used to capture discrete samples of a continuous analog voltage and
provide a discrete binary representation of the signal. Analog-to-digital converters are generally
characterized in three ways:
Input voltage range
Resolution
Bandwidth or conversion rate
The input voltage range of an ADC is determined by its reference voltage (VREF). Fusion devices
include an internal 2.56 V reference, or the user can supply an external reference of up to 3.3 V. The
following examples use the internal 2.56 V reference, so the full-scale input range of the ADC is 0 to
2.56 V.
The resolution (LSB) of the ADC is a function of the number of binary bits in the converter. The ADC
approximates the value of the input voltage using 2n steps, where n is the number of bits in the converter.
Each step therefore represents VREF÷ 2n volts. In the case of the Fusion ADC configured for 12-bit
operation, the LSB is 2.56 V / 4096 = 0.625 mV.
Finally, bandwidth is an indication of the maximum number of conversions the ADC can perform each
second. The bandwidth of an ADC is constrained by its architecture and several key performance
characteristics.
Figure 2-80 ADC Simplified Block Diagram
TVCSYSCLK ADCCLK
Signals from
Analog Quads
CHNUMBER
SAR ADC
STC MODE
RESULT
DATAVALID
BUSY
STATUS
SAMPLE
CALIBRATE
VAREF
Analog
MUX
32 12
Fusion Family of Mixed Signal FPGAs
Revision 4 2-101
There are several popular ADC architectures, each with advantages and limitations. The analog-to-digital
converter in Fusion devices is a switched-capacitor Successive Approximation Register (SAR) ADC. It
supports 8-, 10-, and 12-bit modes of operation with a cumulative sample rate up to 600 k samples per
second (ksps). Built-in bandgap circuitry offers 1% internal voltage reference accuracy or an external
reference voltage can be used.
As shown in Figure 2-81, a SAR ADC contains N capacitors with binary-weighted values.
To begin a conversion, all of the capacitors are quickly discharged. Then VIN is applied to all the
capacitors for a period of time (acquisition time) during which the capacitors are charged to a value very
close to VIN. Then all of the capacitors are switched to ground, and thus –VIN is applied across the
comparator. Now the conversion process begins. First, C is switched to VREF. Because of the binary
weighting of the capacitors, the voltage at the input of the comparator is then shown by EQ 11.
Voltage at input of comparator = –VIN + VREF / 2
EQ 11
If VIN is greater than VREF / 2, the output of the comparator is 1; otherwise, the comparator output is 0.
A register is clocked to retain this value as the MSB of the result. Next, if the MSB is 0, C is switched
back to ground; otherwise, it remains connected to VREF, and C / 2 is connected to VREF. The result at
the comparator input is now either –VIN + VREF / 4 or –VIN + 3 VREF / 4 (depending on the state of the
MSB), and the comparator output now indicates the value of the next most significant bit. This bit is
likewise registered, and the process continues for each subsequent bit until a conversion is completed.
The conversion process requires some acquisition time plus N + 1 ADC clock cycles to complete.
Figure 2-81 • Example SAR ADC Architecture
Comparator
C C / 2 C / 4
C / 2N–2 C / 2N–1
VREF
VIN
Device Architecture
2-102 Revision 4
This process results in a binary approximation of VIN. Generally, there is a fixed interval T, the sampling
period, between the samples. The inverse of the sampling period is often referred to as the sampling
frequency fS = 1 / T. The combined effect is illustrated in Figure 2-82.
Figure 2-82 demonstrates that if the signal changes faster than the sampling rate can accommodate, or if
the actual value of VIN falls between counts in the result, this information is lost during the conversion.
There are several techniques that can be used to address these issues.
First, the sampling rate must be chosen to provide enough samples to adequately represent the input
signal. Based on the Nyquist-Shannon Sampling Theorem, the minimum sampling rate must be at least
twice the frequency of the highest frequency component in the target signal (Nyquist Frequency). For
example, to recreate the frequency content of an audio signal with up to 22 KHz bandwidth, the user
must sample it at a minimum of 44 ksps. However, as shown in Figure 2-82, significant post-processing
of the data is required to interpolate the value of the waveform during the time between each sample.
Similarly, to re-create the amplitude variation of a signal, the signal must be sampled with adequate
resolution. Continuing with the audio example, the dynamic range of the human ear (the ratio of the
amplitude of the threshold of hearing to the threshold of pain) is generally accepted to be 135 dB, and the
dynamic range of a typical symphony orchestra performance is around 85 dB. Most commercial
recording media provide about 96 dB of dynamic range using 16-bit sample resolution. But 16-bit fidelity
does not necessarily mean that you need a 16-bit ADC. As long as the input is sampled at or above the
Nyquist Frequency, post-processing techniques can be used to interpolate intermediate values and
reconstruct the original input signal to within desired tolerances.
If sophisticated digital signal processing (DSP) capabilities are available, the best results are obtained by
implementing a reconstruction filter, which is used to interpolate many intermediate values with higher
resolution than the original data. Interpolating many intermediate values increases the effective number
of samples, and higher resolution increases the effective number of bits in the sample. In many cases,
however, it is not cost-effective or necessary to implement such a sophisticated reconstruction algorithm.
For applications that do not require extremely fine reproduction of the input signal, alternative methods
can enhance digital sampling results with relatively simple post-processing. The details of such
techniques are out of the scope of this chapter; refer to the Improving ADC Results through
Oversampling and Post-Processing of Data white paper for more information.
Figure 2-82 • Conversion Example
T
LSB
Fusion Family of Mixed Signal FPGAs
Revision 4 2-103
ADC Terminology
Conversion Time
Conversion time is the interval between the release of the hold state (imposed by the input circuitry of a
track-and-hold) and the instant at which the voltage on the sampling capacitor settles to within one LSB
of a new input value.
DNL – Differential Non-Linearity
For an ideal ADC, the analog-input levels that trigger any two successive output codes should differ by
one LSB (DNL = 0). Any deviation from one LSB in defined as DNL (Figure 2-83).
ENOB – Effective Number of Bits
ENOB specifies the dynamic performance of an ADC at a specific input frequency and sampling rate. An
ideal ADC’s error consists only of quantization of noise. As the input frequency increases, the overall
noise (particularly in the distortion components) also increases, thereby reducing the ENOB and SINAD
(also see “Signal-to-Noise and Distortion Ratio (SINAD)”.) ENOB for a full-scale, sinusoidal input
waveform is computed using EQ 12.
EQ 12
FS Error – Full-Scale Error
Full-scale error is the difference between the actual value that triggers that transition to full-scale and the
ideal analog full-scale transition value. Full-scale error equals offset error plus gain error.
Figure 2-83 • Differential Non-Linearity (DNL)
ADC Output Code
Input Voltage to Prescaler
Error = –0.5 LSB
Error = +1 LSB
Ideal Output
Actual Output
ENOB SINAD 1.76
6.02
-------------------------------------
=
Device Architecture
2-104 Revision 4
Gain Error
The gain error of an ADC indicates how well the slope of an actual transfer function matches the slope of
the ideal transfer function. Gain error is usually expressed in LSB or as a percent of full-scale (%FSR).
Gain error is the full-scale error minus the offset error (Figure 2-84).
Gain Error Drift
Gain-error drift is the variation in gain error due to a change in ambient temperature, typically expressed
in ppm/°C.
Figure 2-84 • Gain Error
ADC Output Code
Input Voltage to Prescaler
Ideal Output
Actual Output
Gain = 2 LSB
1...11
0...00
FS
Voltage
Fusion Family of Mixed Signal FPGAs
Revision 4 2-105
INL – Integral Non-Linearity
INL is the deviation of an actual transfer function from a straight line. After nullifying offset and gain
errors, the straight line is either a best-fit straight line or a line drawn between the end points of the
transfer function (Figure 2-85).
LSB – Least Significant Bit
In a binary number, the LSB is the least weighted bit in the group. Typically, the LSB is the furthest right
bit. For an ADC, the weight of an LSB equals the full-scale voltage range of the converter divided by 2N,
where N is the converter’s resolution.
EQ 13 shows the calculation for a 10-bit ADC with a unipolar full-scale voltage of 2.56 V:
1 LSB = (2.56 V / 210) = 2.5 mV
EQ 13
No Missing Codes
An ADC has no missing codes if it produces all possible digital codes in response to a ramp signal
applied to the analog input.
Offset Error
Offset error indicates how well the actual transfer function matches the ideal transfer function at a single
point. For an ideal ADC, the first transition occurs at 0.5 LSB above zero. The offset voltage is measured
by applying an analog input such that the ADC outputs all zeroes and increases until the first transition
occurs (Figure 2-86 on page 2-106).
Figure 2-85 • Integral Non-Linearity (INL)
ADC Output Code
Input Voltage to Prescaler
INL = +0.5 LSB
INL = +1 LSB
Ideal Output
Actual Output
Device Architecture
2-106 Revision 4
Resolution
ADC resolution is the number of bits used to represent an analog input signal. To more accurately
replicate the analog signal, resolution needs to be increased.
Sampling Rate
Sampling rate or sample frequency, specified in samples per second (sps), is the rate at which an ADC
acquires (samples) the analog input.
SNR – Signal-to-Noise Ratio
SNR is the ratio of the amplitude of the desired signal to the amplitude of the noise signals at a given
point in time. For a waveform perfectly reconstructed from digital samples, the theoretical maximum SNR
(EQ 14) is the ratio of the full-scale analog input (RMS value) to the RMS quantization error (residual
error). The ideal, theoretical minimum ADC noise is caused by quantization error only and results directly
from the ADC’s resolution (N bits):
EQ 14
SINAD – Signal-to-Noise and Distortion
SINAD is the ratio of the rms amplitude to the mean value of the root-sum-square of the all other spectral
components, including harmonics, but excluding DC. SINAD is a good indication of the overall dynamic
performance of an ADC because it includes all components which make up noise and distortion.
Total Harmonic Distortion
THD measures the distortion content of a signal, and is specified in decibels relative to the carrier (dBc).
THD is the ratio of the RMS sum of the selected harmonics of the input signal to the fundamental itself.
Only harmonics within the Nyquist limit are included in the measurement.
Figure 2-86 • Offset Error
ADC Output Code
Input Voltage to Prescaler
Ideal Output
Offset Error = 1.5 LSB
Actual Output
0...00
0...01
SNRdB[MAX] 6.02dB N1.76dB
+=
Fusion Family of Mixed Signal FPGAs
Revision 4 2-107
TUE – Total Unadjusted Error
TUE is a comprehensive specification that includes linearity errors, gain error, and offset error. It is the
worst-case deviation from the ideal device performance. TUE is a static specification (Figure 2-87).
ADC Operation
Once the ADC has powered up and been released from reset, ADCRESET, the ADC will initiate a
calibration routine designed to provide optimal ADC performance. The Fusion ADC offers a robust
calibration scheme to reduce integrated offset and linearity errors. The offset and linearity errors of the
main capacitor array are compensated for with an 8-bit calibration capacitor array. The offset/linearity
error calibration is carried out in two ways. First, a power-up calibration is carried out when the ADC
comes out of reset. This is initiated by the CALIBRATE output of the Analog Block macro and is a fixed
number of ADC_CLK cycles (3,840 cycles), as shown in Figure 2-89 on page 2-114. In this mode, the
linearity and offset errors of the capacitors are calibrated.
To further compensate for drift and temperature-dependent effects, every conversion is followed by post-
calibration of either the offset or a bit of the main capacitor array. The post-calibration ensures that, over
time and with temperature, the ADC remains consistent.
After both calibration and the setting of the appropriate configurations, as explained above, the ADC is
ready for operation. Setting the ADCSTART signal high for one clock period will initiate the sample and
conversion of the analog signal on the channel as configured by CHNUMBER[4:0]. The status signals
SAMPLE and BUSY will show when the ADC is sampling and converting (Figure 2-91 on page 2-115).
Both SAMPLE and BUSY will initially go high. After the ADC has sampled and held the analog signal,
SAMPLE will go low. After the entire operation has completed and the analog signal is converted, BUSY
will go low and DATAVALID will go high. This indicates that the digital result is available on the
RESULT[11:0] pins.
DATAVALID will remain high until a subsequent ADC_START is issued. The DATAVALID goes low on the
rising edge of SYSCLK as shown in Figure 2-90 on page 2-114. The RESULT signals will be kept
constant until the ADC finishes the subsequent sample. The next sampled RESULT will be available
when DATAVALID goes high again. It is ideal to read the RESULT when DATAVALID is '1'. The RESULT
is latched and remains unchanged until the next DATAVLAID rising edge.
Figure 2-87 • Total Unadjusted Error (TUE)
ADC Output Code
Input Voltage to Prescaler
IDEAL OUTPUT
TUE = ±0.5 LSB
Device Architecture
2-108 Revision 4
ADC Input Multiplexer
At the input to the Fusion ADC is a 32:1 multiplexer. Of the 32 input channels, up to 30 are user
definable. Two of these channels are hardwired internally. Channel 31 connects to an internal
temperature diode so the temperature of the Fusion device itself can be monitored. Channel 0 is wired to
the FPGA’s 1.5 V VCC supply, enabling the Fusion device to monitor its own power supply. Doing this
internally makes it unnecessary to use an analog I/O to support these functions. The balance of the MUX
inputs are connected to Analog Quads (see the "Analog Quad" section on page 2-83). Tab le 2 - 4 0 defines
which Analog Quad inputs are associated with which specific analog MUX channels. The number of
Analog Quads present is device-dependent; refer to the family list in the "Fusion Family" table on page I
of this datasheet for the number of quads per device. Regardless of the number of quads populated in a
device, the internal connections to both VCC and the internal temperature diode remain on Channels 0
and 31, respectively. To sample the internal temperature monitor, it must be strobed (similar to the AT
pads). The TMSTBINT pin on the Analog Block macro is the control for strobing the internal temperature
measurement diode.
To determine which channel is selected for conversion, there is a five-pin interface on the Analog Block,
CHNUMBER[4:0], defined in Ta b l e 2- 39 .
Table 2-40 shows the correlation between the analog MUX input channels and the analog input pins.
Table 2-39 • Channel Selection
Channel Number CHNUMBER[4:0]
000000
100001
200010
300011
.
.
.
.
.
.
30 11110
31 11111
Table 2-40 • Analog MUX Channels
Analog MUX Channel Signal Analog Quad Number
0 Vcc_analog
1 AV0 Analog Quad 0
2AC0
3AT0
4 AV1 Analog Quad 1
5AC1
6AT1
7 AV2 Analog Quad 2
8AC2
9AT2
10 AV3 Analog Quad 3
11 AC3
12 AT3
13 AV4 Analog Quad 4
14 AC4
15 AT4
Fusion Family of Mixed Signal FPGAs
Revision 4 2-109
The ADC can be powered down independently of the FPGA core, as an additional control or for power-
saving considerations, via the PWRDWN pin of the Analog Block. The PWRDWN pin controls only the
comparators in the ADC.
ADC Modes
The Fusion ADC can be configured to operate in 8-, 10-, or 12-bit modes, power-down after conversion,
and dynamic calibration. This is controlled by MODE[3:0], as defined in Table 2-41 on page 2-109.
The output of the ADC is the RESULT[11:0] signal. In 8-bit mode, the Most Significant 8 Bits
RESULT[11:4] are used as the ADC value and the Least Significant 4 Bits RESULT[3:0] are logical '0's.
In 10-bit mode, RESULT[11:2] are used the ADC value and RESULT[1:0] are logical 0s.
Integrated Voltage Reference
The Fusion device has an integrated on-chip 2.56 V reference voltage for the ADC. The value of this
reference voltage was chosen to make the prescaling and postscaling factors for the prescaler blocks
change in a binary fashion. However, if desired, an external reference voltage of up to 3.3 V can be
16 AV5 Analog Quad 5
17 AC5
18 AT5
19 AV6 Analog Quad 6
20 AC6
21 AT6
22 AV7 Analog Quad 7
23 AC7
24 AT7
25 AV8 Analog Quad 8
26 AC8
27 AT8
28 AV9 Analog Quad 9
29 AC9
30 AT9
31 Internal temperature
monitor
Table 2-41 • Mode Bits Function
Name Bits Function
MODE 3 0 – Internal calibration after every conversion; two ADCCLK cycles are used
after the conversion.
1 – No calibration after every conversion
MODE 2 0 – Power-down after conversion
1 – No Power-down after conversion
MODE 1:0 00 – 10-bit
01 – 12-bit
10 – 8-bit
11 – Unused
Table 2-40 • Analog MUX Channels (continued)
Analog MUX Channel Signal Analog Quad Number
Device Architecture
2-110 Revision 4
connected between the VAREF and ADCGNDREF pins. The VAREFSEL control pin is used to select the
reference voltage.
ADC Clock
The speed of the ADC depends on its internal clock, ADCCLK, which is not accessible to users. The
ADCCLK is derived from SYSCLK. Input signal TVC[7:0], Time Divider Control, determines the speed of
the ADCCLK in relationship to SYSCLK, based on EQ 15.
EQ 15
TVC: Time Divider Control (0–255)
tADCCLK is the period of ADCCLK, and must be between 0.5 MHz and 10 MHz
tSYSCLK is the period of SYSCLK
The frequency of ADCCLK, fADCCLK, must be within 0.5 Hz to 10 MHz.
The inputs to the ADC are synchronized to SYSCLK. A conversion is initiated by asserting the
ADCSTART signal on a rising edge of SYSCLK. Figure 2-90 on page 2-114 and Figure 2-91 on
page 2-115 show the timing diagram for the ADC.
Acquisition Time or Sample Time Control
Acquisition time (tSAMPLE) specifies how long an analog input signal has to charge the internal capacitor
array. Figure 2-88 shows a simplified internal input sampling mechanism of a SAR ADC.
The internal impedance (ZINAD), external source resistance (RSOURCE), and sample capacitor (CINAD)
form a simple RC network. As a result, the accuracy of the ADC can be affected if the ADC is given
insufficient time to charge the capacitor. To resolve this problem, you can either reduce the source
resistance or increase the sampling time by changing the acquisition time using the STC signal.
EQ 16 through EQ 18 can be used to calculate the acquisition time required for a given input. The STC
signal gives the number of sample periods in ADCCLK for the acquisition time of the desired signal. If the
actual acquisition time is higher than the STC value, the settling time error can affect the accuracy of the
ADC, because the sampling capacitor is only partially charged within the given sampling cycle. Example
acquisition times are given in Table 2-44 and Tab l e 2 - 45 . When controlling the sample time for the ADC
Table 2-42 • VAREF Bit Function
Name Bit Function
VAREF 0 Reference voltage selection
0 – Internal voltage reference selected. VAREF pin outputs 2.56 V.
1 – Input external voltage reference from VAREF and ADCGNDREF
Table 2-43 • TVC Bits Function
Name Bits Function
TVC [7:0] SYSCLK divider control
Figure 2-88 • Simplified Sample and Hold Circuitry
tADCCLK 41TVC+tSYSCLK
=
Sample and Hold
ZINAD
CINAD
Rsource
Fusion Family of Mixed Signal FPGAs
Revision 4 2-111
along with the use of the active bipolar prescaler, current monitor, or temperature monitor, the minimum
sample time(s) for each must be obeyed. EQ 19 can be used to determine the appropriate value of STC.
You can calculate the minimum actual acquisition time by using EQ 16:
VOUT = VIN(1 – e–t/RC)
EQ 16
For 0.5 LSB gain error, VOUT should be replaced with (VIN –(0.5 × LSB Value)):
(VIN – 0.5 × LSB Value) = VIN(1 – e–t/RC)
EQ 17
where VIN is the ADC reference voltage (VREF)
Solving EQ 17:
t = RC x ln (VIN / (0.5 x LSB Value))
EQ 18
where R = ZINAD + RSOURCE and C = CINAD.
Calculate the value of STC by using EQ 19.
tSAMPLE = (2 + STC) x (1 / ADCCLK) or tSAMPLE = (2 + STC) x (ADC Clock Period)
EQ 19
where ADCCLK = ADC clock frequency in MHz.
tSAMPLE = 0.449 µs from bit resolution in Table 2-44.
ADC Clock frequency = 10 MHz or a 100 ns period.
STC = (tSAMPLE / (1 / 10 MHz)) – 2 = 4.49 – 2 = 2.49.
You must round up to 3 to accommodate the minimum sample time.
Sample Phase
A conversion is performed in three phases. In the first phase, the analog input voltage is sampled on the
input capacitor. This phase is called sample phase. During the sample phase, the output signals BUSY
and SAMPLE change from '0' to '1', indicating the ADC is busy and sampling the analog signal. The
sample time can be controlled by input signals STC[7:0]. The sample time can be calculated by EQ 20.
When controlling the sample time for the ADC along with the use of Prescaler or Current Monitor or
Temperature Monitor, the minimum sample time for each must be obeyed. Refer to Tab l e 2- 46 o n
page 2-112 and the "Acquisition Time or Sample Time Control" section on page 2-110
EQ 20
STC: Sample Time Control value (0–255)
tSAMPLE is the sample time
Table 2-44 • Acquisition Time Example with VAREF = 2.56 V
VIN = 2.56V, R = 4K (RSOURCE ~ 0), C = 18 pF
Resolution LSB Value (mV) Min. Sample/Hold Time for 0.5 LSB (µs)
8 10 0.449
10 2.5 0.549
12 0.625 0.649
Table 2-45 • Acquisition Time Example with VAREF = 3.3 V
VIN = 3.3V, R = 4K (RSOURCE ~ 0), C = 18 pF
Resolution LSB Value (mV) Min. Sample/Hold time for 0.5 LSB (µs)
8 12.891 0.449
10 3.223 0.549
12 0.806 0.649
tsample 2STC+tADCCLK
=
Device Architecture
2-112 Revision 4
Sample time is computed based on the period of ADCCLK.
Distribution Phase
The second phase is called the distribution phase. During distribution phase, the ADC computes the
equivalent digital value from the value stored in the input capacitor. In this phase, the output signal
SAMPLE goes back to '0', indicating the sample is completed; but the BUSY signal remains '1', indicating
the ADC is still busy for distribution. The distribution time depends strictly on the number of bits. If the
ADC is configured as a 10-bit ADC, then 10 ADCCLK cycles are needed. EQ 8 describes the distribution
time.
EQ 21
N: Number of bits
Post-Calibration Phase
The last phase is the post-calibration phase. This is an optional phase. The post-calibration phase takes
two ADCCLK cycles. The output BUSY signal will remain '1' until the post-calibration phase is completed.
If the post-calibration phase is skipped, then the BUSY signal goes to '0' after distribution phase. As soon
as BUSY signal goes to '0', the DATAVALID signal goes to '1', indicating the digital result is available on
the RESULT output signals. DATAVAILD will remain '1' until the next ADCSTART is asserted. Microsemi
recommends enabling post-calibration to compensate for drift and temperature-dependent effects. This
ensures that the ADC remains consistent over time and with temperature. The post-calibration phase is
enabled by bit 3 of the Mode register. EQ 9 describes the post-calibration time.
EQ 22
MODE[3]: Bit 3 of the Mode register, described in Table 2-41 on page 2-109.
The calculation for the conversion time for the ADC is summarized in EQ 23.
tconv = tsync_read + tsample + tdistrib + tpost-cal + tsync_write
EQ 23
tconv: conversion time
tsync_read: maximum time for a signal to synchronize with SYSCLK. For calculation purposes, the
worst case is a period of SYSCLK, tSYSCLK.
tsample: Sample time
tdistrib: Distribution time
tpost-cal: Post-calibration time
tsync_write: Maximum time for a signal to synchronize with SYSCLK. For calculation purposes, the
worst case is a period of SYSCLK, tSYSCLK.
Intra-Conversion
Performing a conversion during power-up calibration is possible but should be avoided, since the
performance is not guaranteed, as shown in Table 2-49 on page 2-120. This is described as intra-
conversion. Figure 2-92 on page 2-115 shows intra-conversion (conversion that starts during power-up
calibration).
Injected Conversion
A conversion can be interrupted by another conversion. Before the current conversion is finished, a
second conversion can be started by issuing a pulse on signal ADCSTART. When a second conversion
is issued before the current conversion is completed, the current conversion would be dropped and the
ADC would start the second conversion on the rising edge of the SYSCLK. This is known as injected
conversion. Since the ADC is synchronous, the minimum time to issue a second conversion is two clock
cycles of SYSCLK after the previous one. Figure 2-93 on page 2-116 shows injected conversion
Table 2-46 • STC Bits Function
Name Bits Function
STC [7:0] Sample time control
tdistrib Nt
ADCCLK
=
tpost-cal MODE 3 2t
ADCCLK
=
Fusion Family of Mixed Signal FPGAs
Revision 4 2-113
(conversion that starts before a previously started conversion is finished). The total time for
calibration still remains 3,840 ADCCLK cycles.
ADC Example
This example shows how to choose the correct settings to achieve the fastest sample time in 10-bit mode
for a system that runs at 66 MHz. Assume the acquisition times defined in Table 2-44 on page 2-111 for
10-bit mode, which gives 0.549 µs as a minimum hold time.
The period of SYSCLK: tSYSCLK = 1/66 MHz = 0.015 µs
Choosing TVC between 1 and 33 will meet the maximum and minimum period for the ADCCLK
requirement. A higher TVC leads to a higher ADCCLK period.
The minimum TVC is chosen so that tdistrib and tpost-cal can be run faster. The period of ADCCLK with a
TVC of 1 can be computed by EQ 24.
EQ 24
The STC value can now be computed by using the minimum sample/hold time from Table 2-44 on
page 2-111, as shown in EQ 25.
EQ 25
You must round up to 3 to accommodate the minimum sample time requirement. The actual sample time,
tsample, with an STC of 3, is now equal to 0.6 µs, as shown in EQ 26
EQ 26
Microsemi recommends post-calibration for temperature drift over time, so post-calibration is enabled.
The post-calibration time, tpost-cal, can be computed by EQ 27. The post-calibration time is 0.24 µs.
EQ 27
The distribution time, tdistrib, is equal to 1.2 µs and can be computed as shown in EQ 28 (N is number of
bits, referring back to EQ 8 on page 2-97).
EQ 28
The total conversion time can now be summated, as shown in EQ 29 (referring to EQ 23 on page 2-112).
tsync_read + tsample + tdistrib + tpost-cal + tsync_write = (0.015 + 0.60 + 1.2 + 0.24 + 0.015) µs = 2.07 µs
EQ 29
The optimal setting for the system running at 66 MHz with an ADC for 10-bit mode chosen is shown in
Table 2-47:
Table 2-47 • Optimal Setting at 66 MHz in 10-Bit Mode
TVC[7:0] = 1 = 0x01
STC[7:0] = 3 = 0x03
MODE[3:0] = b'0100 = 0x4*
Note: No power-down after every conversion is chosen in this case; however, if the application is
power-sensitive, the MODE[2] can be set to '0', as described above, and it will not affect any
performance.
tADCCLK 41TVC+tSYSCLK
411+0.015 µs0.12 µs===
STC tsample
tADCCLK
-------------------- 20.549 µs
0.12 µs
-----------------------24.575 22.575== ==
tsample 2STC+tADCCLK
23+tADCCLK
5 0.12 µs0.6 µs====
tpost-cal 2t
ADCCLK
0.24 µs==
tdistrib Nt
ADCCLK
10 0.121.2 µs===
Device Architecture
2-114 Revision 4
Timing Diagrams
Note: *Refer to EQ 15 on page 2-110 for the calculation on the period of ADCCLK, tADCCLK.
Figure 2-89 • Power-Up Calibration Status Signal Timing Diagram
Figure 2-90 • Input Setup Time
SYSCLK
ADCRESET
CALIBRATE
tREMCLR
tCK2QCAL tCK2QCAL
TVC[7:0]
tSUTVC tHDTVC
tCAL = 3,840 tADCCLK*
tRECCLR
SYSCLK
ADCSTART
t
MINSYSCLK
t
MPWSYSCLK
tHDADCSTART
tSUADCSTART
MODE[3:0]
TVC[7:0]
STC[7:0]
VAREF
C
HNUMBER[7:0]
tSUMODE
tSUTVC
tSUSTC
tSUCHNUM
tSUVAREFSEL
tHDMODE
tHDTVC
tHDSTC
tHDVAREFSEL
tHDCHNUM
Fusion Family of Mixed Signal FPGAs
Revision 4 2-115
Standard Conversion
Intra-Conversion
Notes:
1. Refer to EQ 20 on page 2-111 for the calculation on the sample time, tSAMPLE.
2. See EQ 23 on page 2-112 for calculation of the conversion time, tCONV.
3. Minimum time to issue an ADCSTART after DATAVALID is 1 SYSCLK period
Figure 2-91 • Standard Conversion Status Signal Timing Diagram
SYSCLK
ADCSTART
BUSY
SAMPLE
DATAVALID
t
HDADCSTART
t
SUADCSTART
t
CK2QBUSY
t
CK2QSAMPLE
t
CK2QVAL
t
SAMPLE
1
t
CONV
2
ADC_RESULT[11:0]
t
CLK2RESULT
1st Sample Result
t
CK2QVAL
2nd Sample Result
t
DATA2START
3
Note: *tCONV represents the conversion time of the second conversion. See EQ 23 on page 2-112 for calculation of the
conversion time, tCONV.
Figure 2-92 • Intra-Conversion Timing Diagram
SYSCLK
ADCSTART
BUSY
SAMPLE
DATAVALID
t
CK2QSAMPLE
t
CK2QSAMPLE
t
CK2QVAL
t
CONV
*
t
CLR2QVAL
t
CK2QBUSY
ADCRESET
CALIBRATE
t
CK2QCAL
t
CK2QCAL
Interrupts Power-Up Calibration Resumes Power-Up Calibration
Device Architecture
2-116 Revision 4
Injected Conversion
Note: *See EQ 23 on page 2-112 for calculation on the conversion time, tCONV.
Figure 2-93 • Injected Conversion Timing Diagram
SYSCLK
ADCSTART
BUSY
SAMPLE
DATAVALID
t
CK2QSAMPLE
t
CK2QVAL
t
CONV
*
1st Conversion
1st Start 2nd Start
1st Conversion Cancelled,
2nd Conversion
t
CK2QVAL
t
CK2QBUSY
t
CK2QSAMPLE
Fusion Family of Mixed Signal FPGAs
Revision 4 2-117
ADC Interface Timing
Table 2-48 • ADC Interface Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tSUMODE Mode Pin Setup Time 0.56 0.64 0.75 ns
tHDMODE Mode Pin Hold Time 0.26 0.29 0.34 ns
tSUTVC Clock Divide Control (TVC) Setup Time 0.68 0.77 0.90 ns
tHDTVC Clock Divide Control (TVC) Hold Time 0.32 0.36 0.43 ns
tSUSTC Sample Time Control (STC) Setup Time 1.58 1.79 2.11 ns
tHDSTC Sample Time Control (STC) Hold Time 1.27 1.45 1.71 ns
tSUVAREFSEL Voltage Reference Select (VAREFSEL) Setup Time 0.00 0.00 0.00 ns
tHDVAREFSEL Voltage Reference Select (VAREFSEL) Hold Time 0.67 0.76 0.89 ns
tSUCHNUM Channel Select (CHNUMBER) Setup Time 0.90 1.03 1.21 ns
tHDCHNUM Channel Select (CHNUMBER) Hold Time 0.00 0.00 0.00 ns
tSUADCSTART Start of Conversion (ADCSTART) Setup Time 0.75 0.85 1.00 ns
tHDADCSTART Start of Conversion (ADCSTART) Hold Time 0.43 0.49 0.57 ns
tCK2QBUSY Busy Clock-to-Q 1.33 1.51 1.78 ns
tCK2QCAL Power-Up Calibration Clock-to-Q 0.63 0.71 0.84 ns
tCK2QVAL Valid Conversion Result Clock-to-Q 3.12 3.55 4.17 ns
tCK2QSAMPLE Sample Clock-to-Q 0.22 0.25 0.30 ns
tCK2QRESULT Conversion Result Clock-to-Q 2.53 2.89 3.39 ns
tCLR2QBUSY Busy Clear-to-Q 2.06 2.35 2.76 ns
tCLR2QCAL Power-Up Calibration Clear-to-Q 2.15 2.45 2.88 ns
tCLR2QVAL Valid Conversion Result Clear-to-Q 2.41 2.74 3.22 ns
tCLR2QSAMPLE Sample Clear-to-Q 2.17 2.48 2.91 ns
tCLR2QRESULT Conversion result Clear-to-Q 2.25 2.56 3.01 ns
tRECCLR Recovery Time of Clear 0.00 0.00 0.00 ns
tREMCLR Removal Time of Clear 0.63 0.72 0.84 ns
tMPWSYSCLK Clock Minimum Pulse Width for the ADC 4.00 4.00 4.00 ns
tFMAXSYSCLK Clock Maximum Frequency for the ADC 100.00 100.00 100.00 MHz
Device Architecture
2-118 Revision 4
Typical Performance Characteristics
Figure 2-94 • Temperature Error
Figure 2-95 • Effect of External Sensor Capacitance
0
0.5
1
1.5
2
2.5
3
3.5
40 10 60 110
Temperature Errror vs. Die Temperature
Temperature Error (°C)
Temperature (°C)
Temperature Error vs. Interconnect Capacitance
-7
-6
-5
-4
-3
-2
-1
0
1
0 500 1000 1500 2000
Capacitance (pF )
Temperature Error (°C)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-119
Figure 2-96 • Temperature Reading Noise When Averaging is Used
0
2
4
6
8
10
12
Temperature Reading Noise RMS vs. Averaging
Number of Averages
Noise RMS (°C)
1 10 100 1000 10000
Device Architecture
2-120 Revision 4
Analog System Characteristics
Table 2-49 • Analog Channel Specifications
Commercial Temperature Range Conditions, TJ = 85°C (unless noted otherwise),
Typical: VCC33A = 3.3 V, VCC = 1.5 V
Parameter Description Condition Min. Typ. Max. Units
Voltage Monitor Using Analog Pads AV, AC and AT (using prescaler)
Input Voltage
(Prescaler)
Refer to Table 3-2 on page 3-3
VINAP Uncalibrated Gain and
Offset Errors
Refer to Table 2-51 on
page 2-125
Calibrated Gain and
Offset Errors
Refer to Table 2-52 on
page 2-126
Bandwidth1 100 KHz
Input Resistance Refer to Table 3-3 on page 3-4
Scaling Factor Prescaler modes (Table 2-57 on
page 2-133)
Sample Time 10 µs
Current Monitor Using Analog Pads AV and AC
VRSM1Maximum Differential
Input Voltage
VAREF / 10 mV
Resolution Refer to "Current Monitor"
section
Common Mode Range 10.5 to +12 V
CMRR Common Mode
Rejection Ratio
DC – 1 KHz 60 dB
1 KHz - 10 KHz 50 dB
> 10 KHz 30 dB
tCMSHI Strobe High time ADC
conv.
time
200 µs
tCMSHI Strobe Low time 5 µs
tCMSHI Settling time 0.02 µs
Accuracy Input differential voltage > 50 mV –2 –(0.05 x
VRSM) to +2 +
(0.05 x VRSM)
mV
Notes:
1. VRSM is the maximum voltage drop across the current sense resistor.
2. Analog inputs used as digital inputs can tolerate the same voltage limits as the corresponding analog pad. There is no
reliability concern on digital inputs as long as VIND does not exceed these limits.
3. VIND is limited to VCC33A + 0.2 to allow reaching 10 MHz input frequency.
4. An averaging of 1,024 samples (LPF setting in Analog System Builder) is required and the maximum capacitance
allowed across the AT pins is 500 pF.
5. The temperature offset is a fixed positive value.
6. The high current mode has a maximum power limit of 20 mW. Appropriate current limit resistors must be used, based on
voltage on the pad.
7. When using SmartGen Analog System Builder, CalibIP is required to obtain 0 offset. For further details on CalibIP, refer
to the "Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion FPGA Fabric User’s
Guide.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-121
Temperature Monitor Using Analog Pad AT
External
Temperature
Monitor
(external diode
2N3904,
TJ = 25°C)4
Resolution 8-bit ADC 4 °C
10-bit ADC 1 °C
12-bit ADC 0.25 °C
Systematic Offset5AFS090 uncalibrated7C
AFS090, AFS250, calibrated7C
AFS250, AFS600, AFS1500,
uncalibrated7
11 °C
AFS600, AFS1500, calibrated7C
Accuracy ±3 ±5 °C
External Sensor Source
Current
High level, TMSTBx = 0 10 µA
Low level, TMSTBx = 1 100 µA
Max Capacitance on AT
pad
1.3 nF
Internal
Temperature
Monitor
Resolution 8-bit ADC 4 °C
10-bit ADC 1 °C
12-bit ADC 0.25 °C
Systematic Offset5AFS090 uncalibrated7C
AFS090, AFS250, calibrated7C
AFS250, AFS600, AFS1500
uncalibrated7
11 °C
AFS600, AFS1500 calibrated7C
Accuracy ±3 ±5 °C
tTMSHI Strobe High time 10 105 µs
tTMSLO Strobe Low time 5 µs
tTMSSET Settling time 5 µs
Table 2-49 • Analog Channel Specifications (continued)
Commercial Temperature Range Conditions, TJ = 85°C (unless noted otherwise),
Typical: VCC33A = 3.3 V, VCC = 1.5 V
Parameter Description Condition Min. Typ. Max. Units
Notes:
1. VRSM is the maximum voltage drop across the current sense resistor.
2. Analog inputs used as digital inputs can tolerate the same voltage limits as the corresponding analog pad. There is no
reliability concern on digital inputs as long as VIND does not exceed these limits.
3. VIND is limited to VCC33A + 0.2 to allow reaching 10 MHz input frequency.
4. An averaging of 1,024 samples (LPF setting in Analog System Builder) is required and the maximum capacitance
allowed across the AT pins is 500 pF.
5. The temperature offset is a fixed positive value.
6. The high current mode has a maximum power limit of 20 mW. Appropriate current limit resistors must be used, based on
voltage on the pad.
7. When using SmartGen Analog System Builder, CalibIP is required to obtain 0 offset. For further details on CalibIP, refer
to the "Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion FPGA Fabric User’s
Guide.
Device Architecture
2-122 Revision 4
Digital Input using Analog Pads AV, AC and AT
VIND2,3 Input Voltage Refer to Table 3-2 on page 3-3
VHYSDIN Hysteresis 0.3 V
VIHDIN Input High 1.2 V
VILDIN Input Low 0.9 V
VMPWDIN Minimum Pulse With 50 ns
FDIN Maximum Frequency 10 MHz
ISTBDIN Input Leakage Current 2 µA
IDYNDIN Dynamic Current 20 µA
tINDIN Input Delay 10 ns
Gate Driver Output Using Analog Pad AG
VG Voltage Range Refer to Table 3-2 on page 3-3
IG Output Current Drive High Current Mode6 at 1.0 V ±20 mA
Low Current Mode: ±1 µA 0.8 1.0 1.3 µA
Low Current Mode: ±3 µA 2.0 2.7 3.3 µA
Low Current Mode: ± 10 µA 7.4 9.0 11.5 µA
Low Current Mode: ± 30 µA 21.0 27.0 32.0 µA
IOFFG Maximum Off Current 100 nA
FGMaximum switching rate High Current Mode6 at 1.0 V, 1
k resistive load
1.3 MHz
Low Current Mode:
±1 µA, 3 M resistive load
3KHz
Low Current Mode:
±3 µA, 1 M resistive load
7KHz
Low Current Mode:
±10 µA, 300 k resistive load
25 KHz
Low Current Mode:
±30 µA, 105 k resistive load
78 KHz
Table 2-49 • Analog Channel Specifications (continued)
Commercial Temperature Range Conditions, TJ = 85°C (unless noted otherwise),
Typical: VCC33A = 3.3 V, VCC = 1.5 V
Parameter Description Condition Min. Typ. Max. Units
Notes:
1. VRSM is the maximum voltage drop across the current sense resistor.
2. Analog inputs used as digital inputs can tolerate the same voltage limits as the corresponding analog pad. There is no
reliability concern on digital inputs as long as VIND does not exceed these limits.
3. VIND is limited to VCC33A + 0.2 to allow reaching 10 MHz input frequency.
4. An averaging of 1,024 samples (LPF setting in Analog System Builder) is required and the maximum capacitance
allowed across the AT pins is 500 pF.
5. The temperature offset is a fixed positive value.
6. The high current mode has a maximum power limit of 20 mW. Appropriate current limit resistors must be used, based on
voltage on the pad.
7. When using SmartGen Analog System Builder, CalibIP is required to obtain 0 offset. For further details on CalibIP, refer
to the "Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion FPGA Fabric User’s
Guide.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-123
Table 2-50 • ADC Characteristics in Direct Input Mode
Commercial Temperature Range Conditions, TJ = 85°C (unless noted otherwise),
Typical: VCC33A = 3.3 V, VCC = 1.5 V
Parameter Description Condition Min. Typ. Max. Units
Direct Input using Analog Pad AV, AC, AT
VINADC Input Voltage (Direct Input) Refer to Table 3-2 on
page 3-3
CINADC Input Capacitance Channel not selected 7 pF
Channel selected but not
sampling
8pF
Channel selected and
sampling
18 pF
ZINADC Input Impedance 8-bit mode 2 k
10-bit mode 2 k
12-bit mode 2 k
Analog Reference Voltage VAREF
VAREF Accuracy TJ = 25°C 2.537 2.56 2.583 V
Temperature Drift of
Internal Reference
65 ppm / °C
External Reference 2.527 VCC33A + 0.05 V
ADC Accuracy (using external reference) 1,2
DC Accuracy
TUE Total Unadjusted Error 8-bit mode 0.29 LSB
10-bit mode 0.72 LSB
12-bit mode 1.8 LSB
INL Integral Non-Linearity 8-bit mode 0.20 0.25 LSB
10-bit mode 0.32 0.43 LSB
12-bit mode 1.71 1.80 LSB
DNL Differential Non-Linearity
(no missing code)
8-bit mode 0.20 0.24 LSB
10-bit mode 0.60 0.65 LSB
12-bit mode 2.40 2.48 LSB
Offset Error 8-bit mode 0.01 0.17 LSB
10-bit mode 0.05 0.20 LSB
12-bit mode 0.20 0.40 LSB
Gain Error 8-bit mode 0.0004 0.003 LSB
10-bit mode 0.002 0.011 LSB
12-bit mode 0.007 0.044 LSB
Gain Error (with internal
reference)
All modes 2 % FSR
Notes:
1. Accuracy of the external reference is 2.56 V ± 4.6 mV.
2. Data is based on characterization.
3. The sample rate is time-shared among active analog inputs.
Device Architecture
2-124 Revision 4
Dynamic Performance
SNR Signal-to-Noise Ratio 8-bit mode 48.0 49.5 dB
10-bit mode 58.0 60.0 dB
12-bit mode 62.9 64.5 dB
SINAD Signal-to-Noise Distortion 8-bit mode 47.6 49.5 dB
10-bit mode 57.4 59.8 dB
12-bit mode 62.0 64.2 dB
THD Total Harmonic
Distortion
8-bit mode 74.4 –63.0 dBc
10-bit mode –78.3 –63.0 dBc
12-bit mode –77.9 –64.4 dBc
ENOB Effective Number of Bits 8-bit mode 7.6 7.9 bits
10-bit mode 9.5 9.6 bits
12-bit mode 10.0 10.4 bits
Conversion Rate
Conversion Time 8-bit mode 1.7 µs
10-bit mode 1.8 µs
12-bit mode 2 µs
Sample Rate 8-bit mode 600 Ksps
10-bit mode 550 Ksps
12-bit mode 500 Ksps
Table 2-50 • ADC Characteristics in Direct Input Mode (continued)
Commercial Temperature Range Conditions, TJ = 85°C (unless noted otherwise),
Typical: VCC33A = 3.3 V, VCC = 1.5 V
Parameter Description Condition Min. Typ. Max. Units
Notes:
1. Accuracy of the external reference is 2.56 V ± 4.6 mV.
2. Data is based on characterization.
3. The sample rate is time-shared among active analog inputs.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-125
Table 2-51 • Uncalibrated Analog Channel Accuracy*
Worst-Case Industrial Conditions, TJ = 85°C
Total Channel
Error (LSB)
Channel Input Offset
Error (LSB)
Channel Input Offset
Error (mV)
Channel Gain Error
(%FSR)
Analog
Pad
Prescaler
Range (V)
Neg.
Max. Med.
Pos.
Max.
Neg
Max Med.
Pos.
Max.
Neg.
Max. Med.
Pos.
Max. Min. Typ. Max.
Positive Range ADC in 10-Bit Mode
AV, AC 16 –22 –2 12 –11 2 14 –169 –32 224 3 0 –3
8 –40 –5 17 –11 –5 21 –87 –40 166 2 0 –4
4 –45 –9 24 –16 –11 36 –63 –43 144 2 0 –4
2 –70 –19 33 –33 –20 66 –66 –39 131 2 0 –4
1 –25 –7 5 –11 –3 26 –11 –3 26 3 –1 –3
0.5 –41 –12 8 –12 –7 38 –6 –4 19 3 –1 –3
0.25 –53 14 19 –20 –14 40 –5 –3 10 5 0 –4
0.125 –89 –29 24 –40 –28 88 –5 –4 11 7 0 5
AT 16 –3 9 15 –4 0 4 –64 5 64 1 0 –1
4 –10 2 15 –11 –2 11 –44 –8 44 1 0 –1
Negative Range ADC in 10-Bit Mode
AV, AC 16 –35 –10 9 –24 6 9 –383 –96 148 5 –1 –6
8 –65 –19 12 –34 –12 9 –268 –99 75 5 –1 –5
4 –86 –28 21 –64 –24 19 –254 –96 76 5 –1 –6
2 –136 –53 37 –115 –42 39 –230 –83 78 6 –2 –7
1 –98 –35 8 –39 8 15 –39 –8 15 10 –3 –10
0.5 –121 –46 7 –54 –14 18 –27 –7 9 10 –4 –11
0.25 –149 –49 19 –72 –16 40 –18 –4 10 14 –4 –12
0.125 –188 –67 38 –112 –27 56 –14 –3 7 16 –5 –14
Note: *Channel Accuracy includes prescaler and ADC accuracies. For 12-bit mode, multiply the LSB count by 4. For
8-bit mode, divide the LSB count by 4. Gain remains the same.
Device Architecture
2-126 Revision 4
Table 2-52 • Calibrated Analog Channel Accuracy 1,2,3
Worst-Case Industrial Conditions, TJ = 85°C
Condition Total Channel Error (LSB)
Analog
Pad Prescaler Range (V) Input Voltage4 (V) Negative Max. Median Positive Max.
Positive Range ADC in 10-Bit Mode
AV, AC 16 0.300 to 12.0 6 1 6
8 0.250 to 8.00 –6 0 6
4 0.200 to 4.00 –7 –1 7
2 0.150 to 2.00 –7 0 7
1 0.050 to 1.00 –6 –1 6
AT 16 0.300 to 16.0 –5 0 5
4 0.100 to 4.00 –7 –1 7
Negative Range ADC in 10-Bit Mode
AV, AC 16 0.400 to –10.5 –7 1 9
8 –0.350 to –8.00 –7 –1 7
4 –0.300 to –4.00 –7 –2 9
2 –0.250 to –2.00 –7 –2 7
1 –0.050 to –1.00 –16 –1 20
Notes:
1. Channel Accuracy includes prescaler and ADC accuracies. For 12-bit mode, multiply the LSB count by 4. For 8-bit
mode, divide the LSB count by 4. Overall accuracy remains the same.
2. Requires enabling Analog Calibration using SmartGen Analog System Builder. For further details, refer to the
"Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion FPGA Fabric User’s Guide.
3. Calibrated with two-point calibration methodology, using 20% and 80% full-scale points.
4. The lower limit of the input voltage is determined by the prescaler input offset.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-127
Examples
Calculating Accuracy for an Uncalibrated Analog Channel
Formula
For a given prescaler range, EQ 30 gives the output voltage.
Output Voltage = (Channel Output Offset in V) + (Input Voltage x Channel Gain)
EQ 30
where
Channel Output offset in V = Channel Input offset in LSBs x Equivalent voltage per LSB
Channel Gain Factor = 1+ (% Channel Gain / 100)
Example
Input Voltage = 5 V
Chosen Prescaler range = 8 V range
Refer to Table 2-51 on page 2-125.
Max. Output Voltage = (Max Positive input offset) + (Input Voltage x Max Positive Channel Gain)
Max. Positive input offset = (21 LSB) x (8 mV per LSB in 10-bit mode)
Max. Positive input offset = 166 mV
Max. Positive Gain Error = +3%
Max. Positive Channel Gain = 1 + (+3% / 100)
Max. Positive Channel Gain = 1.03
Max. Output Voltage = (166 mV) + (5 V x 1.03)
Max. Output Voltage = 5.316 V
Table 2-53 • Analog Channel Accuracy: Monitoring Standard Positive Voltages
Typical Conditions, TA = 25°C
Input Voltage
(V)
Calibrated Typical Error per Positive Prescaler Setting 1 (%FSR)
Direct ADC 2,3
(%FSR)
16 V (AT)
16 V (12 V)
(AV/AC)
8 V
(AV/AC) 4 V (AT)
4 V
(AV/AC)
2 V
(AV/AC)
1 V
(AV/AC) VAREF = 2.56 V
15 1
14 1
12 1 1
5221
3.3 2 2 1 1 1
2.5 3 2 1 1 1 1
1.8 4 4 1 1 1 1 1
1.5 5 5 2 2 2 1 1
1.2 7 6 2 2 2 1 1
0.9 9 9 4 3 3 1 1 1
Notes:
1. Requires enabling Analog Calibration using SmartGen Analog System Builder. For further details, refer to the
"Temperature, Voltage, and Current Calibration in Fusion FPGAs" chapter of the Fusion FPGA Fabric User’s Guide.
2. Direct ADC mode using an external VAREF of 2.56V±4.6mV, without Analog Calibration macro.
3. For input greater than 2.56 V, the ADC output will saturate. A higher VAREF or prescaler usage is recommended.
Device Architecture
2-128 Revision 4
Similarly,
Min. Output Voltage = (Max. Negative input offset) + (Input Voltage x Max. Negative Channel Gain)
= (–88 mV) + (5 V x 0.96) = 4.712 V
Calculating Accuracy for a Calibrated Analog Channel
Formula
For a given prescaler range, EQ 31 gives the output voltage.
Output Voltage = Channel Error in V + Input Voltage
EQ 31
where
Channel Error in V = Total Channel Error in LSBs x Equivalent voltage per LSB
Example
Input Voltage = 5 V
Chosen Prescaler range = 8 V range
Refer to Table 2-52 on page 2-126.
Max. Output Voltage = Max. Positive Channel Error in V + Input Voltage
Max. Positive Channel Error in V = (6 LSB) × (8 mV per LSB in 10-bit mode) = 48 mV
Max. Output Voltage = 48 mV + 5 V = 5.048 V
Similarly,
Min. Output Voltage = Max. Negative Channel Error in V + Input Voltage = (–48 mV) + 5 V = 4.952 V
Calculating LSBs from a Given Error Budget
Formula
For a given prescaler range,
LSB count = ± (Input Voltage × Required % error) / (Equivalent voltage per LSB)
Example
Input Voltage = 3.3 V
Required error margin= 1%
Refer to Table 2-52 on page 2-126.
Equivalent voltage per LSB = 16 mV for a 16V prescaler, with ADC in 10-bit mode
LSB Count = ± (5.0 V × 1%) / (0.016)
LSB Count = ± 3.125
Equivalent voltage per LSB = 8 mV for an 8 V prescaler, with ADC in 10-bit mode
LSB Count = ± (5.0 V × 1%) / (0.008)
LSB Count = ± 6.25
The 8 V prescaler satisfies the calculated LSB count accuracy requirement (see Tab l e 2- 52 on
page 2-126).
Fusion Family of Mixed Signal FPGAs
Revision 4 2-129
Analog Configuration MUX
The ACM is the interface between the FPGA, the Analog Block configurations, and the real-time counter.
Microsemi Libero SoC will generate IP that will load and configure the Analog Block via the ACM.
However, users are not limited to using the Libero SoC IP. This section provides a detailed description of
the ACM's register map, truth tables for proper configuration of the Analog Block and RTC, as well as
timing waveforms so users can access and control the ACM directly from their designs.
The Analog Block contains four 8-bit latches per Analog Quad that are initialized through the ACM.
These latches act as configuration bits for Analog Quads. The ACM block runs from the core voltage
supply (1.5 V).
Access to the ACM is achieved via 8-bit address and data busses with enables. The pin list is provided in
Table 2-36 on page 2-81. The ACM clock speed is limited to a maximum of 10 MHz, more than sufficient
to handle the low-bandwidth requirements of configuring the Analog Block and the RTC (sub-block of the
Analog Block).
Table 2-54 decodes the ACM address space and maps it to the corresponding Analog Quad and
configuration byte for that quad.
Table 2-54 ACM Address Decode Table for Analog Quad
ACMADDR [7:0] in
Decimal Name Description
Associated
Peripheral
0 Analog Quad
1 AQ0 Byte 0 Analog Quad
2 AQ0 Byte 1 Analog Quad
3 AQ0 Byte 2 Analog Quad
4 AQ0 Byte 3 Analog Quad
5 AQ1 Byte 0 Analog Quad
.
.
.
.
.
.
.
.
.
Analog Quad
36 AQ8 Byte 3 Analog Quad
37 AQ9 Byte 0 Analog Quad
38 AQ9 Byte 1 Analog Quad
39 AQ9 Byte 2 Analog Quad
40 AQ9 Byte 3 Analog Quad
41 Undefined Analog Quad
.
.
.
.
.
.
Undefined Analog Quad
63 Undefined RTC
64 COUNTER0 Counter bits 7:0 RTC
65 COUNTER1 Counter bits 15:8 RTC
66 COUNTER2 Counter bits 23:16 RTC
67 COUNTER3 Counter bits 31:24 RTC
68 COUNTER4 Counter bits 39:32 RTC
72 MATCHREG0 Match register bits 7:0 RTC
73 MATCHREG1 Match register bits 15:8 RTC
Device Architecture
2-130 Revision 4
ACM Characteristics1
74 MATCHREG2 Match register bits 23:16 RTC
75 MATCHREG3 Match register bits 31:24 RTC
76 MATCHREG4 Match register bits 39:32 RTC
80 MATCHBITS0 Individual match bits 7:0 RTC
81 MATCHBITS1 Individual match bits 15:8 RTC
82 MATCHBITS2 Individual match bits 23:16 RTC
83 MATCHBITS3 Individual match bits 31:24 RTC
84 MATCHBITS4 Individual match bits 39:32 RTC
88 CTRL_STAT Control (write) / Status (read) register
bits 7:0
RTC
Note: ACMADDR bytes 1 to 40 pertain to the Analog Quads; bytes 64 to 89 pertain to the RTC.
1. When addressing the RTC addresses (i.e., ACMADDR 64 to 89), there is no timing generator, and the rc_osc, byte_en, and
aq_wen signals have no impact.
Table 2-54 ACM Address Decode Table for Analog Quad (continued)
ACMADDR [7:0] in
Decimal Name Description
Associated
Peripheral
Figure 2-97 • ACM Write Waveform
Figure 2-98 • ACM Read Waveform
D1
A1
t
SUEACM
t
HEACM
t
SUDACM
t
HDACM
t
SUAACM
t
HAACM
A0
D0
ACMCLK
ACMWEN
ACMWDATA
ACMADDRESS
A0 A1
RD0 RD1
t
MPWCLKACM
t
CLKQACM
ACMCLK
ACMADDRESS
ACMRDATA
Fusion Family of Mixed Signal FPGAs
Revision 4 2-131
Timing Characteristics
Table 2-55 • Analog Configuration Multiplexer (ACM) Timing
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tCLKQACM Clock-to-Q of the ACM 19.73 22.48 26.42 ns
tSUDACM Data Setup time for the ACM 4.39 5.00 5.88 ns
tHDACM Data Hold time for the ACM 0.00 0.00 0.00 ns
tSUAACM Address Setup time for the ACM 4.73 5.38 6.33 ns
tHAACM Address Hold time for the ACM 0.00 0.00 0.00 ns
tSUEACM Enable Setup time for the ACM 3.93 4.48 5.27 ns
tHEACM Enable Hold time for the ACM 0.00 0.00 0.00 ns
tMPWARACM Asynchronous Reset Minimum Pulse Width for the
ACM
10.00 10.00 10.00 ns
tREMARACM Asynchronous Reset Removal time for the ACM 12.98 14.79 17.38 ns
tRECARACM Asynchronous Reset Recovery time for the ACM 12.98 14.79 17.38 ns
tMPWCLKACM Clock Minimum Pulse Width for the ACM 45.00 45.00 45.00 ns
tFMAXCLKACM lock Maximum Frequency for the ACM 10.00 10.00 10.00 MHz
Device Architecture
2-132 Revision 4
Analog Quad ACM Description
Table 2-56 maps out the ACM space associated with configuration of the Analog Quads within the
Analog Block. Table 2-56 shows the byte assignment within each quad and the function of each bit within
each byte. Subsequent tables will explain each bit setting and how it corresponds to a particular
configuration. After 3.3 V and 1.5 V are applied to Fusion, Analog Quad configuration registers are
loaded with default settings until the initialization and configuration state machine changes them to user-
defined settings.
Table 2-56 • Analog Quad ACM Byte Assignment
Byte Bit Signal (Bx) Function Default Setting
Byte 0
(AV)
0 B0[0] Scaling factor control – prescaler Highest voltage range
1 B0[1]
2 B0[2]
3 B0[3] Analog MUX select Prescaler
4 B0[4] Current monitor switch Off
5 B0[5] Direct analog input switch Off
6 B0[6] Selects V-pad polarity Positive
7 B0[7] Prescaler op amp mode Power-down
Byte 1
(AC)
0 B1[0] Scaling factor control – prescaler Highest voltage range
1 B1[1]
2 B1[2]
3 B1[3] Analog MUX select Prescaler
4 B1[4]
5 B1[5] Direct analog input switch Off
6 B1[6] Selects C-pad polarity Positive
7 B1[7] Prescaler op amp mode Power-down
Byte 2
(AG)
0 B2[0] Internal chip temperature monitor * Off
1 B2[1] Spare
2 B2[2] Current drive control Lowest current
3 B2[3]
4 B2[4] Spare
5 B2[5] Spare
6 B2[6] Selects G-pad polarity Positive
7 B2[7] Selects low/high drive Low drive
Byte 3
(AT)
0 B3[0] Scaling factor control – prescaler Highest voltage range
1 B3[1]
2 B3[2]
3 B3[3] Analog MUX select Prescaler
4 B3[4]
5 B3[5] Direct analog input switch Off
6 B3[6]
7 B3[7] Prescaler op amp mode Power-down
Note: *For the internal temperature monitor to function, Bit 0 of Byte 2 for all 10 Quads must be set.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-133
Table 2-57 details the settings available to control the prescaler values of the AV, AC, and AT pins. Note
that the AT pin has a reduced number of available prescaler values.
Table 2-58 details the settings available to control the MUX within each of the AV, AC, and AT circuits.
This MUX determines whether the signal routed to the ADC is the direct analog input, prescaled signal,
or output of either the Current Monitor Block or the Temperature Monitor Block.
Table 2-59 details the settings available to control the Direct Analog Input switch for the AV, AC, and AT
pins.
Table 2-60 details the settings available to control the polarity of the signals coming to the AV, AC, and AT
pins. Note that the only valid setting for the AT pin is logic 0 to support positive voltages.
Table 2-57 • Prescaler Control Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3)
Control Lines
Bx[2:0]
Scaling
Factor, Pad to
ADC Input
LSB for an
8-Bit
Conversion1
(mV)
LSB for a
10-Bit
Conversion1
(mV)
LSB for a
12-Bit
Conversion1
(mV)
Full-Scale
Voltage in
10-Bit
Mode2Range Name
000 30.15625 64 16 4 16.368 V 16 V
001 0.3125 32 8 2 8.184 V 8 V
010 30.625 16 4 1 4.092 V 4 V
011 1.25 8 2 0.5 2.046 V 2 V
100 2.5 4 1 0.25 1.023 V 1 V
101 5.0 2 0.5 0.125 0.5115 V 0.5 V
110 10.0 1 0.25 0.0625 0.25575 V 0.25 V
111 20.0 0.5 0.125 0.03125 0.127875 V 0.125 V
Notes:
1. LSB voltage equivalences assume VAREF = 2.56 V.
2. Full Scale voltage for n-bit mode: ((2^n) - 1) x (LSB for a n-bit Conversion)
3. These are the only valid ranges for the Temperature Monitor Block Prescaler.
Table 2-58 • Analog Multiplexer Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3)
Control Lines Bx[4] Control Lines Bx[3] ADC Connected To
0 0 Prescaler
0 1 Direct input
1 0 Current amplifier temperature monitor
1 1 Not valid
Table 2-59 • Direct Analog Input Switch Control Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3)
Control Lines Bx[5] Direct Input Switch
0 Off
1 On
Table 2-60 • Voltage Polarity Control Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3)*
Control Lines Bx[6] Input Signal Polarity
0 Positive
1 Negative
Note: *The B3[6] signal for the AT pad should be kept at logic 0 to accept only positive voltages.
Device Architecture
2-134 Revision 4
Table 2-61 details the settings available to either power down or enable the prescaler associated with the
analog inputs AV, AC, and AT.
Table 2-62 details the settings available to enable the Current Monitor Block associated with the AC pin.
Table 2-63 details the settings available to configure the drive strength of the gate drive when not in high-
drive mode.
Table 2-64 details the settings available to set the polarity of the gate driver (either p-channel- or
n-channel-type devices).
Table 2-65 details the settings available to turn on the Gate Driver and set whether high-drive mode is on
or off.
Table 2-66 details the settings available to turn on and off the chip internal temperature monitor.
Note: For the internal temperature monitor to function, Bit 0 of Byte 2 for all 10 Quads must be set.
Table 2-61 • Prescaler Op Amp Power-Down Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3)
Control Lines Bx[7] Prescaler Op Amp
0 Power-down
1 Operational
Table 2-62 • Current Monitor Input Switch Control Truth Table—AV (x = 0)
Control Lines B0[4] Current Monitor Input Switch
0 Off
1 On
Table 2-63 • Low-Drive Gate Driver Current Truth Table (AG)
Control Lines B2[3] Control Lines B2[2] Current (µA)
0 0 1
0 1 3
1 0 10
1 1 30
Table 2-64 Gate Driver Polarity Truth Table (AG)
Control Lines B2[6] Gate Driver Polarity
0 Positive
1 Negative
Table 2-65 • Gate Driver Control Truth Table (AG)
Control Lines B2[7] GDON Gate Driver
0 0 Off
0 1 Low drive on
1 0 Off
1 1 High drive on
Table 2-66 • Internal Temperature Monitor Control Truth Table
Control Lines B2[0] PDTMB Chip Internal Temperature Monitor
00Off
11On
Fusion Family of Mixed Signal FPGAs
Revision 4 2-135
User I/Os
Introduction
Fusion devices feature a flexible I/O structure, supporting a range of mixed voltages (1.5 V, 1.8 V, 2.5 V,
and 3.3 V) through a bank-selectable voltage. Table 2-68, Ta b l e 2- 69 , Ta b le 2 -7 0 , and Table 2-71 on
page 2-138 show the voltages and the compatible I/O standards. I/Os provide programmable slew rates,
drive strengths, weak pull-up, and weak pull-down circuits. 3.3 V PCI and 3.3 V PCI-X are 5 V–tolerant.
See the "5 V Input Tolerance" section on page 2-147 for possible implementations of 5 V tolerance.
All I/Os are in a known state during power-up, and any power-up sequence is allowed without current
impact. Refer to the "I/O Power-Up and Supply Voltage Thresholds for Power-On Reset (Commercial
and Industrial)" section on page 3-5 for more information. In low power standby or sleep mode (VCC is
OFF, VCC33A is ON, VCCI is ON) or when the resource is not used, digital inputs are tristated, digital
outputs are tristated, and digital bibufs (input/output) are tristated.
I/O Tile
The Fusion I/O tile provides a flexible, programmable structure for implementing a large number of I/O
standards. In addition, the registers available in the I/O tile in selected I/O banks can be used to support
high-performance register inputs and outputs, with register enable if desired (Figure 2-99 on
page 2-136). The registers can also be used to support the JESD-79C DDR standard within the I/O
structure (see the "Double Data Rate (DDR) Support" section on page 2-142 for more information).
As depicted in Figure 2-100 on page 2-141, all I/O registers share one CLR port. The output register and
output enable register share one CLK port. Refer to the "I/O Registers" section on page 2-141 for more
information.
I/O Banks and I/O Standards Compatibility
The digital I/Os are grouped into I/O voltage banks. There are three digital I/O banks on the AFS090 and
AFS250 devices and four digital I/O banks on the AFS600 and AFS1500 devices. Figure 2-113 on
page 2-161 and Figure 2-114 on page 2-162 show the bank configuration by device. The north side of
the I/O in the AFS600 and AFS1500 devices comprises two banks of Pro I/Os. The Pro I/Os support a
wide number of voltage-referenced I/O standards in addition to the multitude of single-ended and
differential I/O standards common throughout all Microsemi digital I/Os. Each I/O voltage bank has
dedicated I/O supply and ground voltages (VCCI/GNDQ for input buffers and VCCI/GND for output
buffers). Because of these dedicated supplies, only I/Os with compatible standards can be assigned to
the same I/O voltage bank. Table 2-69 and Table 2-70 on page 2-137 show the required voltage
compatibility values for each of these voltages.
For more information about I/O and global assignments to I/O banks, refer to the specific pin table of the
device in the "Package Pin Assignments" on page 4-1 and the "User I/O Naming Convention" section on
page 2-161.
Each Pro I/O bank is divided into minibanks. Any user I/O in a VREF minibank (a minibank is the region
of scope of a VREF pin) can be configured as a VREF pin (Figure 2-99 on page 2-136). Only one VREF
pin is needed to control the entire VREF minibank. The location and scope of the VREF minibanks can
be determined by the I/O name. For details, see the "User I/O Naming Convention" section on
page 2-161.
Table 2-70 on page 2-137 shows the I/O standards supported by Fusion devices and the corresponding
voltage levels.
I/O standards are compatible if the following are true:
Their VCCI values are identical.
If both of the standards need a VREF, their VREF values must be identical (Pro I/O only).
Device Architecture
2-136 Revision 4
Figure 2-99 • Fusion Pro I/O Bank Detail Showing VREF Minibanks (north side ofAFS600 and AFS1500)
Table 2-67 • I/O Standards Supported by Bank Type
I/O Bank Single-Ended I/O Standards
Differential I/O
Standards Voltage-Referenced
Hot-
Swap
Standard I/O LVTTL/LVCMOS 3.3 V, LVCMOS
2.5 V / 1.8 V / 1.5 V, LVCMOS
2.5/5.0 V
–– Yes
Advanced I/O LVTTL/LVCMOS 3.3 V, LVCMOS
2.5 V / 1.8 V / 1.5 V, LVCMOS
2.5/5.0 V, 3.3 V PCI / 3.3 V PCI-
X
LVPECL and
LVDS
––
Pro I/O LVTTL/LVCMOS 3.3 V, LVCMOS
2.5 V / 1.8 V / 1.5 V, LVCMOS
2.5/5.0 V, 3.3 V PCI / 3.3 V PCI-
X
LVPECL and
LVDS
GTL+ 2.5 V / 3.3 V, GTL 2.5 V / 3.3 V,
HSTL Class I and II, SSTL2 Class I
and II, SSTL3 Class I and II
Yes
Bank 1
Bank 0
I/O
I/O
GND
I/O
I/O
I/O
I/O
GND
I/O
I/O
I/O Pad
If needed, the VREF for a given
minibank can be provided by
any I/O within the minibank.
CCC CCC CCC
Up to five VREF
minibanks within
an I/O bank
VREF signal scope is
between 8 and 18 I/Os.
Common VREF
signal for all I/Os
in VREF minibanks
VCCI
VCC
VCCI
VCC
Fusion Family of Mixed Signal FPGAs
Revision 4 2-137
Table 2-68 • I/O Bank Support by Device
I/O Bank AFS090 AFS250 AFS600 AFS1500
Standard I/O N N
Advanced I/O E, W E, W E, W E, W
Pro I/O N N
Analog QuadSSSS
Note: E = East side of the device
W = West side of the device
N = North side of the device
S = South side of the device
Table 2-69 • Fusion VCCI Voltages and Compatible Standards
VCCI (typical) Compatible Standards
3.3 V LVTTL/LVCMOS 3.3, PCI 3.3, SSTL3 (Class I and II),* GTL+ 3.3, GTL 3.3,* LVPECL
2.5 V LVCMOS 2.5, LVCMOS 2.5/5.0, SSTL2 (Class I and II),* GTL+ 2.5,* GTL 2.5,* LVDS, BLVDS, M-
LVDS
1.8 V LVCMOS 1.8
1.5 V LVCMOS 1.5, HSTL (Class I),* HSTL (Class II)*
Note: *I/O standard supported by Pro I/O banks.
Table 2-70 • Fusion VREF Voltages and Compatible Standards*
VREF (typical) Compatible Standards
1.5 V SSTL3 (Class I and II)
1.25 V SSTL2 (Class I and II)
1.0 V GTL+ 2.5, GTL+ 3.3
0.8 V GTL 2.5, GTL 3.3
0.75 V HSTL (Class I), HSTL (Class II)
Note: *I/O standards supported by Pro I/O banks.
Device Architecture
2-138 Revision 4
Table 2-71 • Fusion Standard and Advanced I/O Features
I/O Bank Voltage (typical)
Minibank Voltage (typical)
LVTTL/LVCMOS 3.3 V
LVCMOS 2.5 V
LVCMOS 1.8 V
LVCMOS 1.5 V
3.3 V PCI / PCI-X
GTL + (3.3 V)
GTL + (2.5 V)
GTL (3.3 V)
GTL (2.5 V)
HSTL Class I and II (1.5 V)
SSTL2 Class I and II (2.5 V)
SSTL3 Class I and II (3.3 V)
LVDS (2.5 V ± 5%)
LVPECL (3.3 V)
3.3 V
0.80 V
1.00 V
1.50 V
2.5 V
0.80 V
1.00 V
1.25 V
1.8 V
1.5 V
0.75 V
Note: White box: Allowable I/O standard combinations
Gray box: Illegal I/O standard combinations
Fusion Family of Mixed Signal FPGAs
Revision 4 2-139
Features Supported on Pro I/Os
Table 2-72 lists all features supported by transmitter/receiver for single-ended and differential I/Os.
Table 2-72 • Fusion Pro I/O Features
Feature Description
Single-ended and voltage-
referenced transmitter
features
Hot insertion in every mode except PCI or 5 V input tolerant (these modes use
clamp diodes and do not allow hot insertion)
Activation of hot insertion (disabling the clamp diode) is selectable by I/Os.
Weak pull-up and pull-down
Two slew rates
Skew between output buffer enable/disable time: 2 ns delay (rising edge) and
0 ns delay (falling edge); see "Selectable Skew between Output Buffer
Enable/Disable Time" on page 2-152 for more information
• Five drive strengths
5 V–tolerant receiver ("5 V Input Tolerance" section on page 2-147)
LVTTL/LVCMOS 3.3 V outputs compatible with 5 V TTL inputs ("5 V Output
Tolerance" section on page 2-151)
• High performance (Table 2-76 on page 2-146)
Single-ended receiver features Schmitt trigger option
• ESD protection
Programmable delay: 0 ns if bypassed, 0.625 ns with '000' setting, 6.575 ns
with '111' setting, 0.85-ns intermediate delay increments (at 25°C, 1.5 V)
• High performance (Table 2-76 on page 2-146)
Separate ground planes, GND/GNDQ, for input buffers only to avoid output-
induced noise in the input circuitry
Voltage-referenced differential
receiver features
Programmable Delay: 0 ns if bypassed, 0.625 ns with '000' setting, 6.575 ns
with '111' setting, 0.85-ns intermediate delay increments (at 25°C, 1.5 V)
• High performance (Table 2-76 on page 2-146)
Separate ground planes, GND/GNDQ, for input buffers only to avoid output-
induced noise in the input circuitry
CMOS-style LVDS, BLVDS,
M-LVDS, or LVPECL
transmitter
Two I/Os and external resistors are used to provide a CMOS-style LVDS,
BLVDS, M-LVDS, or LVPECL transmitter solution.
Activation of hot insertion (disabling the clamp diode) is selectable by I/Os.
Weak pull-up and pull-down
• Fast slew rate
LVDS/LVPECL differential
receiver features
• ESD protection
• High performance (Table 2-76 on page 2-146)
Programmable delay: 0.625 ns with '000' setting, 6.575 ns with '111' setting,
0.85-ns intermediate delay increments (at 25°C, 1.5 V)
Separate input buffer ground and power planes to avoid output-induced noise
in the input circuitry
Device Architecture
2-140 Revision 4
Table 2-73 • Maximum I/O Frequency for Single-Ended, Voltage-Referenced, and Differential I/Os;
All I/O Bank Types (maximum drive strength and high slew selected)
Specification Performance Up To
LVTTL/LVCMOS 3.3 V 200 MHz
LVCMOS 2.5 V 250 MHz
LVCMOS 1.8 V 200 MHz
LVCMOS 1.5 V 130 MHz
PCI 200 MHz
PCI-X 200 MHz
HSTL-I 300 MHz
HSTL-II 300 MHz
SSTL2-I 300 MHz
SSTL2-II 300 MHz
SSTL3-I 300 MHz
SSTL3-II 300 MHz
GTL+ 3.3 V 300 MHz
GTL+ 2.5 V 300 MHz
GTL 3.3 V 300 MHz
GTL 2.5 V 300 MHz
LVDS 350 MHz
LVPECL 300 MHz
Fusion Family of Mixed Signal FPGAs
Revision 4 2-141
I/O Registers
Each I/O module contains several input, output, and enable registers. Refer to Figure 2-100 for a
simplified representation of the I/O block.
The number of input registers is selected by a set of switches (not shown in Figure 2-100) between
registers to implement single or differential data transmission to and from the FPGA core. The Designer
software sets these switches for the user.
A common CLR/PRE signal is employed by all I/O registers when I/O register combining is used. Input
register 2 does not have a CLR/PRE pin, as this register is used for DDR implementation. The I/O
register combining must satisfy some rules.
Note: Fusion I/Os have registers to support DDR functionality (see the "Double Data Rate (DDR) Support" section on
page 2-142 for more information).
Figure 2-100 • I/O Block Logical Representation
Input
Reg
E = Enable Pin
A
Y
PAD
12
3
4
5
6
OCE
ICE
ICE
Input
Reg
Input
Reg
CLR/PRE
CLR/PRE
CLR/PRE
CLR/PRE
CLR/PRE
Pull-Up/Down
Resistor Control
Signal Drive Strength
and Slew-Rate Control
Output
Reg
Output
Reg
To FPGA Core
From FPGA Core
Output
Enable
Reg
OCE
I/O / CLR or I/O / PRE / OCE
I/O / Q0
I/O / Q1
I/O / ICLK
I/O / D0
I/O / D1 / ICE
I/O / OCLK
I/O / OE
Device Architecture
2-142 Revision 4
Double Data Rate (DDR) Support
Fusion Pro I/Os support 350 MHz DDR inputs and outputs. In DDR mode, new data is present on every
transition of the clock signal. Clock and data lines have identical bandwidths and signal integrity
requirements, making it very efficient for implementing very high-speed systems.
DDR interfaces can be implemented using HSTL, SSTL, LVDS, and LVPECL I/O standards. In addition,
high-speed DDR interfaces can be implemented using LVDS I/O.
Input Support for DDR
The basic structure to support a DDR input is shown in Figure 2-101. Three input registers are used to
capture incoming data, which is presented to the core on each rising edge of the I/O register clock.
Each I/O tile on Fusion devices supports DDR inputs.
Output Support for DDR
The basic DDR output structure is shown in Figure 2-102 on page 2-143. New data is presented to the
output every half clock cycle. Note: DDR macros and I/O registers do not require additional routing. The
combiner automatically recognizes the DDR macro and pushes its registers to the I/O register area at the
edge of the chip. The routing delay from the I/O registers to the I/O buffers is already taken into account
in the DDR macro.
Refer to the application note Using DDR for Fusion Devices for more information.
Figure 2-101 • DDR Input Register Support in Fusion Devices
Input DDR
Data
CLK
CLKBUF
INBUF
Out_QF
(to core)
FF2
FF1
INBUF
CLR
DDR_IN
E
A
B
C
D
Out_QR
(to core)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-143
Figure 2-102 • DDR Output Support in Fusion Devices
Data_F
(from core)
CLK
CLKBUF
Out
FF2
INBUF
CLR
DDR_OUT
FF1
0
1
A
B
D
E
C
C
B
OUTBUF
Data_R
(from core)
Device Architecture
2-144 Revision 4
Hot-Swap Support
Hot-swapping (also called hot plugging) is the operation of hot insertion or hot removal of a card in (or
from) a powered-up system. The levels of hot-swap support and examples of related applications are
described in Tab l e 2- 74 . The I/Os also need to be configured in hot insertion mode if hot plugging
compliance is required.
Table 2-74 • Levels of Hot-Swap Support
Hot
Swapping
Level Description
Power
Applied
to Device Bus State
Card
Ground
Connection
Device
Circuitry
Connected
to Bus Pins
Example of
Application with
Cards that Contain
Fusion Devices
Compliance of
Fusion Devices
1 Cold-swap No System and card with
Microsemi FPGA chip
are powered down,
then card gets
plugged into system,
then power supplies
are turned on for
system but not for
FPGA on card.
Compliant I/Os
can but do not
have to be set to
hot insertion
mode.
2 Hot-swap
while reset
Yes Held in
reset state
Must be made
and
maintained for
1 ms before,
during, and
after insertion/
removal
In PCI hot plug
specification, reset
control circuitry
isolates the card
busses until the card
supplies are at their
nominal operating
levels and stable.
Compliant I/Os
can but do not
have to be set to
hot insertion
mode.
3 Hot-swap
while bus
idle
Yes Held idle
(no ongoing
I/O
processes
during
insertion/re
moval)
Same as
Level 2
Must remain
glitch-free
during
power-up or
power-down
Board bus shared
with card bus is
"frozen," and there is
no toggling activity on
bus. It is critical that
the logic states set on
the bus signal do not
get disturbed during
card
insertion/removal.
Compliant with
cards with two
levels of staging.
I/Os have to be
set to hot
insertion mode.
4 Hot-swap on
an active
bus
Yes Bus may
have active
I/O
processes
ongoing,
but device
being
inserted or
removed
must be
idle.
Same as
Level 2
Same as
Level 3
There is activity on
the system bus, and it
is critical that the logic
states set on the bus
signal do not get
disturbed during card
insertion/removal.
Compliant with
cards with two
levels of staging.
I/Os have to be
set to hot
insertion mode.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-145
For Fusion devices requiring Level 3 and/or Level 4 compliance, the board drivers connected to Fusion
I/Os need to have 10 k (or lower) output drive resistance at hot insertion, and 1 k (or lower) output
drive resistance at hot removal. This is the resistance of the transmitter sending a signal to the Fusion
I/O, and no additional resistance is needed on the board. If that cannot be assured, three levels of
staging can be used to meet Level 3 and/or Level 4 compliance. Cards with two levels of staging should
have the following sequence:
1. Grounds
2. Powers, I/Os, other pins
Cold-Sparing Support
Cold-sparing means that a subsystem with no power applied (usually a circuit board) is electrically
connected to the system that is in operation. This means that all input buffers of the subsystem must
present very high input impedance with no power applied so as not to disturb the operating portion of the
system.
Pro I/O banks and standard I/O banks fully support cold-sparing.
For Pro I/O banks, standards such as PCI that require I/O clamp diodes, can also achieve cold-sparing
compliance, since clamp diodes get disconnected internally when the supplies are at 0 V.
For Advanced I/O banks, since the I/O clamp diode is always active, cold-sparing can be accomplished
either by employing a bus switch to isolate the device I/Os from the rest of the system or by driving each
advanced I/O pin to 0 V.
If Standard I/O banks are used in applications requiring cold-sparing, a discharge path from the power
supply to ground should be provided. This can be done with a discharge resistor or a switched resistor.
This is necessary because the standard I/O buffers do not have built-in I/O clamp diodes.
If a resistor is chosen, the resistor value must be calculated based on decoupling capacitance on a given
power supply on the board (this decoupling capacitor is in parallel with the resistor). The RC time
constant should ensure full discharge of supplies before cold-sparing functionality is required. The
resistor is necessary to ensure that the power pins are discharged to ground every time there is an
interruption of power to the device.
I/O cold-sparing may add additional current if the pin is configured with either a pull-up or pull down
resistor and driven in the opposite direction. A small static current is induced on each IO pin when the pin
is driven to a voltage opposite to the weak pull resistor. The current is equal to the voltage drop across
the input pin divided by the pull resistor. Please refer to Table 2-95 on page 2-172, Table 2-96 on
page 2-172, and Table 2-97 on page 2-174 for the specific pull resistor value for the corresponding I/O
standard.
For example, assuming an LVTTL 3.3 V input pin is configured with a weak Pull-up resistor, a current will
flow through the pull-up resistor if the input pin is driven low. For an LVTTL 3.3 V, pull-up resistor is ~45
k and the resulting current is equal to 3.3 V / 45 k = 73 µA for the I/O pin. This is true also when a
weak pull-down is chosen and the input pin is driven high. Avoiding this current can be done by driving
the input low when a weak pull-down resistor is used, and driving it high when a weak pull-up resistor is
used.
In Active and Static modes, this current draw can occur in the following cases:
Input buffers with pull-up, driven low
Input buffers with pull-down, driven high
Bidirectional buffers with pull-up, driven low
Bidirectional buffers with pull-down, driven high
Output buffers with pull-up, driven low
Output buffers with pull-down, driven high
Tristate buffers with pull-up, driven low
Tristate buffers with pull-down, driven high
Device Architecture
2-146 Revision 4
Electrostatic Discharge (ESD) Protection
Fusion devices are tested per JEDEC Standard JESD22-A114-B.
Fusion devices contain clamp diodes at every I/O, global, and power pad. Clamp diodes protect all
device pads against damage from ESD as well as from excessive voltage transients.
Each I/O has two clamp diodes. One diode has its positive (P) side connected to the pad and its negative
(N) side connected to VCCI. The second diode has its P side connected to GND and its N side
connected to the pad. During operation, these diodes are normally biased in the Off state, except when
transient voltage is significantly above VCCI or below GND levels.
By selecting the appropriate I/O configuration, the diode is turned on or off. Refer to Ta b l e 2- 75 and
Table 2-76 on page 2-146 for more information about I/O standards and the clamp diode.
The second diode is always connected to the pad, regardless of the I/O configuration selected.
Table 2-75 • Fusion Standard and Advanced I/O – Hot-Swap and 5 V Input Tolerance Capabilities
I/O Assignment
Clamp Diode Hot Insertion 5 V Input Tolerance 1
Input
Buffer
Output
Buffer
Standard
I/O
Advanced
I/O
Standard
I/O
Advanced
I/O
Standard
I/O
Advanced
I/O
3.3 V LVTTL/LVCMOS No Yes Yes No Yes1Yes1Enabled/Disabled
3.3 V PCI, 3.3 V PCI-X N/A Yes N/A No N/A Yes1Enabled/Disabled
LVCMOS 2.5 V No Yes Yes No No No Enabled/Disabled
LVCMOS 2.5 V / 5.0 V N/A Yes N/A No N/A Yes2Enabled/Disabled
LVCMOS 1.8 V No Yes Yes No No No Enabled/Disabled
LVCMOS 1.5 V No Yes Yes No No No Enabled/Disabled
Differential,
LVDS/BLVDS/M-
LVDS/ LVPECL 3
N/A Yes N/A No N/A No Enabled/Disabled
Notes:
1. Can be implemented with an external IDT bus switch, resistor divider, or Zener with resistor.
2. Can be implemented with an external resistor and an internal clamp diode.
3. Bidirectional LVPECL buffers are not supported. I/Os can be configured as either input buffers or output buffers.
Table 2-76 • Fusion Pro I/O – Hot-Swap and 5 V Input Tolerance Capabilities
I/O Assignment
Clamp
Diode
Hot
Insertion
5 V Input
Tolerance Input Buffer Output Buffer
3.3 V LVTTL/LVCMOS No Yes Yes1Enabled/Disabled
3.3 V PCI, 3.3 V PCI-X Yes No Yes1Enabled/Disabled
LVCMOS 2.5 V 3No Yes No Enabled/Disabled
LVCMOS 2.5 V / 5.0 V 3Yes No Yes2Enabled/Disabled
LVCMOS 1.8 V No Yes No Enabled/Disabled
LVCMOS 1.5 V No Yes No Enabled/Disabled
Voltage-Referenced Input Buffer No Yes No Enabled/Disabled
Differential, LVDS/BLVDS/M-LVDS/LVPECL4No Yes No Enabled/Disabled
Notes:
1. Can be implemented with an external IDT bus switch, resistor divider, or Zener with resistor.
2. Can be implemented with an external resistor and an internal clamp diode.
3. In the SmartGen, FlashROM, Flash Memory System Builder, and Analog System Builder User's Guide, select the
LVCMOS5 macro for the LVCMOS 2.5 V / 5.0 V I/O standard or the LVCMOS25 macro for the LVCMOS 2.5 V I/O
standard.
4. Bidirectional LVPECL buffers are not supported. I/Os can be configured as either input buffers or output buffers.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-147
5 V Input Tolerance
I/Os can support 5 V input tolerance when LVTTL 3.3 V, LVCMOS 3.3 V, LVCMOS 2.5 V / 5 V, and
LVCMOS 2.5 V configurations are used (see Table 2-77 on page 2-150 for more details). There are four
recommended solutions (see Figure 2-103 to Figure 2-106 on page 2-149 for details of board and macro
setups) to achieve 5 V receiver tolerance. All the solutions meet a common requirement of limiting the
voltage at the input to 3.6 V or less. In fact, the I/O absolute maximum voltage rating is 3.6 V, and any
voltage above 3.6 V may cause long-term gate oxide failures.
Solution 1
The board-level design needs to ensure that the reflected waveform at the pad does not exceed the limits
provided in Table 3-4 on page 3-4. This is a long-term reliability requirement.
This scheme will also work for a 3.3 V PCI / PCI-X configuration, but the internal diode should not be
used for clamping, and the voltage must be limited by the two external resistors, as explained below.
Relying on the diode clamping would create an excessive pad DC voltage of 3.3 V + 0.7 V = 4 V.
The following are some examples of possible resistor values (based on a simplified simulation model
with no line effects and 10 transmitter output resistance, where Rtx_out_high = (VCCI VOH) / IOH,
Rtx_out_low = VOL / IOL).
Example 1 (high speed, high current):
Rtx_out_high = Rtx_out_low = 10
R1 = 36 (±5%), P(r1)min = 0.069
R2 = 82 (±5%), P(r2)min = 0.158
Imax_tx = 5.5 V / (82 * 0.95 + 36 * 0.95 + 10) = 45.04 mA
tRISE =t
FALL = 0.85 ns at C_pad_load = 10 pF (includes up to 25% safety margin)
tRISE =t
FALL = 4 ns at C_pad_load = 50 pF (includes up to 25% safety margin)
Example 2 (low–medium speed, medium current):
Rtx_out_high = Rtx_out_low = 10
R1 = 220 (±5%), P(r1)min = 0.018
R2 = 390 (±5%), P(r2)min = 0.032
Imax_tx = 5.5 V / (220 * 0.95 + 390 * 0.95 + 10) = 9.17 mA
tRISE =t
FALL = 4 ns at C_pad_load = 10 pF (includes up to 25% safety margin)
tRISE =t
FALL = 20 ns at C_pad_load = 50 pF (includes up to 25% safety margin)
Other values of resistors are also allowed as long as the resistors are sized appropriately to limit the
voltage at the receiving end to 2.5 V < Vin(rx) < 3.6 V when the transmitter sends a logic 1. This range of
Vin_dc(rx) must be assured for any combination of transmitter supply (5 V ± 0.5 V), transmitter output
resistance, and board resistor tolerances.
Device Architecture
2-148 Revision 4
Temporary overshoots are allowed according to Table 3-4 on page 3-4.
Solution 2
The board-level design must ensure that the reflected waveform at the pad does not exceed limits
provided in Table 3-4 on page 3-4. This is a long-term reliability requirement.
This scheme will also work for a 3.3 V PCI/PCI-X configuration, but the internal diode should not be used
for clamping, and the voltage must be limited by the external resistors and Zener, as shown in Figure 2-
104. Relying on the diode clamping would create an excessive pad DC voltage of 3.3 V + 0.7 V = 4 V.
Figure 2-103 • Solution 1
Figure 2-104 • Solution 2
On-ChipOff-Chip
Solution 1
5.5 V 3.3 V
Requires two board resistors,
LVCMOS 3.3 V I/Os
Fusion I/O Input
Rext1
Rext2
Solution 2
5.5 V 3.3 V
Requires one board resistor, one
Zener 3.3 V diode, LVCMOS 3.3 V I/Os
Fusion I/O Input
Rext1
Zener
3.3 V
On-ChipOff-Chip
Fusion Family of Mixed Signal FPGAs
Revision 4 2-149
Solution 3
The board-level design must ensure that the reflected waveform at the pad does not exceed limits
provided in Table 3-4 on page 3-4. This is a long-term reliability requirement.
This scheme will also work for a 3.3 V PCI/PCIX configuration, but the internal diode should not be used
for clamping, and the voltage must be limited by the bus switch, as shown in Figure 2-105. Relying on the
diode clamping would create an excessive pad DC voltage of 3.3 V + 0.7 V = 4 V.
Solution 4
Figure 2-105 • Solution 3
Figure 2-106 • Solution 4
Solution 3
Requires a bus switch on the board,
LVTTL/LVCMOS 3.3 V I/Os.
Fusion I/O Input
3.3 V
5.5 V
5.5 V
Bus
Switch
IDTQS32X23
On-ChipOff-Chip
Solution 4
2.5 V On-Chip
Clamp
Diode
Requires one board resistor.
Available for LVCMOS 2.5 V / 5.0 V.
On-ChipOff-Chip
5.5 V 2.5 V
Fusion I/O Input
Rext1
Device Architecture
2-150 Revision 4
Table 2-77 • Comparison Table for 5 V–Compliant Receiver Scheme
Schem
e Board Components Speed Current Limitations
1 Two resistors Low to high1Limited by transmitter's drive strength
2 Resistor and Zener 3.3 V Medium Limited by transmitter's drive strength
3 Bus switch High N/A
4 Minimum resistor value2
R = 47 at TJ = 70°C
R = 150 at TJ = 85°C
R = 420 at TJ = 100°C
Medium Maximum diode current at 100% duty cycle, signal constantly
at '1'
52.7 mA at TJ =70°C / 10-year lifetime
16.5 mA at TJ = 85°C / 10-year lifetime
5.9 mA at TJ = 100°C / 10-year lifetime
For duty cycles other than 100%, the currents can be
increased by a factor = 1 / (duty cycle).
Example: 20% duty cycle at 70°C
Maximum current = (1 / 0.2) * 52.7 mA = 5 * 52.7 mA = 263.5
mA
Notes:
1. Speed and current consumption increase as the board resistance values decrease.
2. Resistor values ensure I/O diode long-term reliability.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-151
5 V Output Tolerance
Fusion I/Os must be set to 3.3 V LVTTL or 3.3 V LVCMOS mode to reliably drive 5 V TTL receivers. It is
also critical that there be NO external I/O pull-up resistor to 5 V, since this resistor would pull the I/O pad
voltage beyond the 3.6 V absolute maximum value and consequently cause damage to the I/O.
When set to 3.3 V LVTTL or 3.3 V LVCMOS mode, Fusion I/Os can directly drive signals into 5 V TTL
receivers. In fact, VOL = 0.4 V and VOH = 2.4 V in both 3.3 V LVTTL and 3.3 V LVCMOS modes exceed
the VIL = 0.8 V and VIH = 2 V level requirements of 5 V TTL receivers. Therefore, level '1' and level '0'
will be recognized correctly by 5 V TTL receivers.
Simultaneously Switching Outputs and PCB Layout
Simultaneously switching outputs (SSOs) can produce signal integrity problems on adjacent
signals that are not part of the SSO bus. Both inductive and capacitive coupling parasitics of bond
wires inside packages and of traces on PCBs will transfer noise from SSO busses onto signals
adjacent to those busses. Additionally, SSOs can produce ground bounce noise and VCCI dip
noise. These two noise types are caused by rapidly changing currents through GND and VCCI
package pin inductances during switching activities:
Ground bounce noise voltage = L(GND) * di/dt
VCCI dip noise voltage = L(VCCI) * di/dt
Any group of four or more input pins switching on the same clock edge is considered an SSO bus. The
shielding should be done both on the board and inside the package unless otherwise described.
In-package shielding can be achieved in several ways; the required shielding will vary depending on
whether pins next to SSO bus are LVTTL/LVCMOS inputs, LVTTL/LVCMOS outputs, or
GTL/SSTL/HSTL/LVDS/LVPECL inputs and outputs. Board traces in the vicinity of the SSO bus have to
be adequately shielded from mutual coupling and inductive noise that can be generated by the SSO bus.
Also, noise generated by the SSO bus needs to be reduced inside the package.
PCBs perform an important function in feeding stable supply voltages to the IC and, at the same time,
maintaining signal integrity between devices.
Key issues that need to considered are as follows:
Power and ground plane design and decoupling network design
Transmission line reflections and terminations
Device Architecture
2-152 Revision 4
Selectable Skew between Output Buffer Enable/Disable Time
The configurable skew block is used to delay the output buffer assertion (enable) without affecting
deassertion (disable) time.
Figure 2-107 • Block Diagram of Output Enable Path
Figure 2-108 • Timing Diagram (option1: bypasses skew circuit)
Figure 2-109 • Timing Diagram (option 2: enables skew circuit)
ENABLE (OUT)
Skew Circuit
Output Enable
(from FPGA core)
I/O Output
Buffers
ENABLE (IN)
MUX
Skew Select
ENABLE (IN)
ENABLE (OUT)
Less than
0.1 ns
Less than
0.1 ns
ENABLE (IN)
ENABLE (OUT)
1.2 ns
(typical)
Less than
0.1 ns
Fusion Family of Mixed Signal FPGAs
Revision 4 2-153
At the system level, the skew circuit can be used in applications where transmission activities on
bidirectional data lines need to be coordinated. This circuit, when selected, provides a timing margin that
can prevent bus contention and subsequent data loss or transmitter overstress due to transmitter-to-
transmitter current shorts. Figure 2-110 presents an example of the skew circuit implementation in a
bidirectional communication system. Figure 2-111 shows how bus contention is created, and Figure 2-
112 on page 2-154 shows how it can be avoided with the skew circuit.
Figure 2-110 • Example of Implementation of Skew Circuits in Bidirectional Transmission Systems Using
Fusion Devices
Figure 2-111 • Timing Diagram (bypasses skew circuit)
Transmitter 1: Fusion I/O Transmitter 2: Generic I/O
ENABLE(t2)
EN(b1) EN(b2)
EN(r1)
ENABLE(t1)
Bidirectional Data Bus
Transmitter
ENABLE/
DISABLE
Skew or
Bypass
Skew
Routing
Delay (t1)
Routing
Delay (t2)
EN (b1)
EN (b2)
ENABLE (r1)
Transmitter 1: ON
ENABLE (t2)
Transmitter 2: ON
ENABLE (t1)
Bus
Contention
Transmitter 1: OFF Transmitter 1: OFF
Transmitter 2: OFF
Device Architecture
2-154 Revision 4
Weak Pull-Up and Weak Pull-Down Resistors
Fusion devices support optional weak pull-up and pull-down resistors for each I/O pin. When the I/O is
pulled up, it is connected to the VCCI of its corresponding I/O bank. When it is pulled down, it is
connected to GND. Refer to Table 2-97 on page 2-174 for more information.
Slew Rate Control and Drive Strength
Fusion devices support output slew rate control: high and low. The high slew rate option is recommended
to minimize the propagation delay. This high-speed option may introduce noise into the system if
appropriate signal integrity measures are not adopted. Selecting a low slew rate reduces this kind of
noise but adds some delays in the system. Low slew rate is recommended when bus transients are
expected. Drive strength should also be selected according to the design requirements and noise
immunity of the system.
The output slew rate and multiple drive strength controls are available in LVTTL/LVCMOS 3.3 V,
LVCMOS 2.5 V, LVCMOS 2.5 V / 5.0 V input, LVCMOS 1.8 V, and LVCMOS 1.5 V. All other I/O
standards have a high output slew rate by default.
For Fusion slew rate and drive strength specifications, refer to the appropriate I/O bank table:
Fusion Standard I/O (Table 2-78 on page 2-155)
Fusion Advanced I/O (Table 2-79 on page 2-155)
Fusion Pro I/O (Table 2-80 on page 2-155)
Table 2-83 on page 2-158 lists the default values for the above selectable I/O attributes as well as those
that are preset for each I/O standard.
Figure 2-112 • Timing Diagram (with skew circuit selected)
EN (b1)
EN (b2)
Transmitter 1: ON
ENABLE (t2)
Transmitter 2: ON Transmitter 2: OFF
ENABLE (t1)
Result: No Bus Contention
Transmitter 1: OFF Transmitter 1: OFF
Fusion Family of Mixed Signal FPGAs
Revision 4 2-155
Refer to Table 2-78, Table 2-79, and Table 2-80 on page 2-155 for SLEW and OUT_DRIVE settings.
Table 2-81 on page 2-156 and Table 2-82 on page 2-157 list the I/O default attributes. Table 2-83 on
page 2-158 lists the voltages for the supported I/O standards.
Table 2-78 • Fusion Standard I/O Standards—OUT_DRIVE Settings
I/O Standards
OUT_DRIVE (mA)
2468 Slew
LVTTL/LVCMOS 3.3 V 3333
High Low
LVCMOS 2.5 V 3333
High Low
LVCMOS 1.8 V 33 High Low
LVCMOS 1.5 V 3 High Low
Table 2-79 • Fusion Advanced I/O Standards—SLEW and OUT_DRIVE Settings
I/O Standards
OUT_DRIVE (mA)
2 4 6 8 12 16 Slew
LVTTL/LVCMOS 3.3 V 3333 3 3
High Low
LVCMOS 2.5 V 33333 – High Low
LVCMOS 1.8 V 3333 – – High Low
LVCMOS 1.5 V 33– – High Low
Table 2-80 • Fusion Pro I/O Standards—SLEW and OUT_DRIVE Settings
I/O Standards
OUT_DRIVE (mA)
Slew2 4 6 8 12 16 24
LVTTL/LVCMOS 3.3 V 333 3 3 3 3
High Low
LVCMOS 2.5 V 333 3 3 3 3
High Low
LVCMOS 2.5 V/5.0 V 333 3 3 3 3
High Low
LVCMOS 1.8 V 333 3 3 3 High Low
LVCMOS 1.5 V 333 3 3 High Low
Device Architecture
2-156 Revision 4
Table 2-81 • Fusion Pro I/O Default Attributes
I/O Standards
SLEW
(output only)
OUT_DRIVE
(output only)
SKEW (tribuf and bibuf only)
RES_PULL
OUT_LOAD (output only)
COMBINE_REGISTER
IN_DELAY (input only)
IN_DELAY_VAL (input only)
SCHMITT_TRIGGER (input only)
LVTTL/LVCMO
S 3.3 V
Refer to the following
tables for more
information:
Table 2-78 on page 2-155
Table 2-79 on page 2-155
Table 2-80 on page 2-155
Refer to the following
tables for more
information:
Table 2-78 on page 2-155
Table 2-79 on page 2-155
Table 2-80 on page 2-155
Off None 35 pF Off 0 Off
LVCMOS 2.5 V Off None 35 pF Off 0 Off
LVCMOS
2.5/5.0 V
Off None 35 pF Off 0 Off
LVCMOS 1.8 V Off None 35 pF Off 0 Off
LVCMOS 1.5 V Off None 35 pF Off 0 Off
PCI (3.3 V) Off None 10 pF Off 0 Off
PCI-X (3.3 V) Off None 10 pF Off 0 Off
GTL+ (3.3 V) Off None 10 pF Off 0 Off
GTL+ (2.5 V) Off None 10 pF Off 0 Off
GTL (3.3 V) Off None 10 pF Off 0 Off
GTL (2.5 V) Off None 10 pF Off 0 Off
HSTL Class I Off None 20 pF Off 0 Off
HSTL Class II Off None 20 pF Off 0 Off
SSTL2
Class I and II
Off None 30 pF Off 0 Off
SSTL3
Class I and II
Off None 30 pF Off 0 Off
LVDS, BLVDS,
M-LVDS
Off None 0 pF Off 0 Off
LVPECL Off None 0 pF Off 0 Off
Fusion Family of Mixed Signal FPGAs
Revision 4 2-157
Table 2-82 • Advanced I/O Default Attributes
I/O Standards SLEW (output only) OUT_DRIVE (output only)
SKEW (tribuf and bibuf only)
RES_PULL
OUT_LOAD (output only)
COMBINE_REGISTER
LVTTL/LVCMOS 3.3 V Refer to the following
tables for more
information:
Table 2-78 on page 2-155
Table 2-79 on page 2-155
Table 2-80 on page 2-155
Refer to the following tables
for more information:
Table 2-78 on page 2-155
Table 2-79 on page 2-155
Table 2-80 on page 2-155
Off None 35 pF
LVCMOS 2.5 V Off None 35 pF
LVCMOS 2.5/5.0 V Off None 35 pF
LVCMOS 1.8 V Off None 35 pF
LVCMOS 1.5 V Off None 35 pF
PCI (3.3 V) Off None 10 pF
PCI-X (3.3 V) Off None 10 pF
LVDS, BLVDS, M-LVDS Off None
LVPECL Off None – –
Device Architecture
2-158 Revision 4
Table 2-83 • Fusion Pro I/O Supported Standards and Corresponding VREF and VTT Voltages
I/O Standard
Input/Output Supply
Voltage (VCCI_TYP)
Input Reference Voltage
(VREF_TYP)
Board Termination Voltage
(VTT_TYP)
LVTTL/LVCMOS 3.3 V 3.30 V
LVCMOS 2.5 V 2.50 V
LVCMOS 2.5 V / 5.0 V
Input
2.50 V
LVCMOS 1.8 V 1.80 V
LVCMOS 1.5 V 1.50 V
PCI 3.3 V 3.30 V
PCI-X 3.3 V 3.30 V
GTL+ 3.3 V 3.30 V 1.00 V 1.50 V
GTL+ 2.5 V 2.50 V 1.00 V 1.50 V
GTL 3.3 V 3.30 V 0.80 V 1.20 V
GTL 2.5 V 2.50 V 0.80 V 1.20 V
HSTL Class I 1.50 V 0.75 V 0.75 V
HSTL Class II 1.50 V 0.75 V 0.75 V
SSTL3 Class I 3.30 V 1.50 V 1.50 V
SSTL3 Class II 3.30 V 1.50 V 1.50 V
SSTL2 Class I 2.50 V 1.25 V 1.25 V
SSTL2 Class II 2.50 V 1.25 V 1.25 V
LVDS, BLVDS, M-LVDS 2.50 V
LVPECL 3.30 V
Fusion Family of Mixed Signal FPGAs
Revision 4 2-159
I/O Software Support
In the Fusion development software, default settings have been defined for the various I/O standards
supported. Changes can be made to the default settings via the use of attributes; however, not all I/O
attributes are applicable for all I/O standards. Tab l e 2- 84 and Ta b l e 2 - 8 5 list the valid I/O attributes that
can be manipulated by the user for each I/O standard.
Single-ended I/O standards in Fusion support up to five different drive strengths.
Table 2-84 • Fusion Standard and Advanced I/O Attributes vs. I/O Standard Applications
I/O Standards
SLEW
(output
only)
OUT_DRIVE
(output only)
SKEW
(all macros
with OE)* RES_PULL
OUT_LOAD
(output only) COMBINE_REGISTER
LVTTL/LVCMOS 3.3 V 33 3 3 3 3
LVCMOS 2.5 V 33 3 3 3 3
LVCMOS 2.5/5.0 V 33 3 3 3 3
LVCMOS 1.8 V 33 3 3 3 3
LVCMOS 1.5 V 33 3 3 3 3
PCI (3.3 V) 333
PCI-X (3.3 V) 3333
LVDS, BLVDS, M-LVDS 33
LVPECL 3
Note: *This feature does not apply to the standard I/O banks, which are the north I/O banks of AFS090 and AFS250
devices
Device Architecture
2-160 Revision 4
Table 2-85 • Fusion Pro I/O Attributes vs. I/O Standard Applications
I/O Standards
SLEW (output only)
OUT_DRIVE (output only)
SKEW (all macros with OE)
RES_PULL
OUT_LOAD (output only)
COMBINE_REGISTER
IN_DELAY (input only)
IN_DELAY_VAL (input only)
SCHMITT_TRIGGER (input only)
HOT_SWAPPABLE
LVTTL/LVCMOS 3.3 V 33 3 3333333
LVCMOS 2.5 V 33 33333333
LVCMOS 2.5/5.0 V 33 3 3333333
LVCMOS 1.8 V 33 33333333
LVCMOS 1.5 V 33 33333333
PCI (3.3 V) 33333
PCI-X (3.3 V) 333333
GTL+ (3.3 V) 333333
GTL+ (2.5 V) 333333
GTL (3.3 V) 333333
GTL (2.5 V) 333333
HSTL Class I 333333
HSTL Class II 333333
SSTL2 Class I and II 333333
SSTL3 Class I and II 333333
LVDS, BLVDS, M-LVDS 33333
LVPECL 33 3 3
Fusion Family of Mixed Signal FPGAs
Revision 4 2-161
User I/O Naming Convention
Due to the comprehensive and flexible nature of Fusion device user I/Os, a naming scheme is used to
show the details of the I/O (Figure 2-113 on page 2-161 and Figure 2-114 on page 2-162). The name
identifies to which I/O bank it belongs, as well as the pairing and pin polarity for differential I/Os.
I/O Nomenclature = Gmn/IOuxwByVz
Gmn is only used for I/Os that also have CCC access—i.e., global pins.
G = Global
m = Global pin location associated with each CCC on the device: A (northwest corner), B (northeast corner), C
(east middle), D (southeast corner), E (southwest corner), and F (west middle).
n = Global input MUX and pin number of the associated Global location m, either A0, A1, A2, B0, B1, B2, C0, C1,
or C2. Figure 2-22 on page 2-27 shows the three input pins per clock source MUX at CCC location m.
u = I/O pair number in the bank, starting at 00 from the northwest I/O bank and proceeding in a clockwise
direction.
x = P (Positive) or N (Negative) for differential pairs, or R (Regular – single-ended) for the I/Os that support single-
ended and voltage-referenced I/O standards only. U (Positive-LVDS only) or V (Negative-LVDS only) restrict
the I/O differential pair from being selected as an LVPECL pair.
w = D (Differential Pair), P (Pair), or S (Single-Ended). D (Differential Pair) if both members of the pair are bonded
out to adjacent pins or are separated only by one GND or NC pin; P (Pair) if both members of the pair are
bonded out but do not meet the adjacency requirement; or S (Single-Ended) if the I/O pair is not bonded out.
For Differential (D) pairs, adjacency for ball grid packages means only vertical or horizontal. Diagonal
adjacency does not meet the requirements for a true differential pair.
B = Bank
y = Bank number (0–3). The Bank number starts at 0 from the northwest I/O bank and proceeds in a clockwise
direction.
V = Reference voltage
z = Minibank number
Figure 2-113 • Naming Conventions of Fusion Devices with Three Digital I/O Banks
CCC
"A"
CCC
"E"
CCC/PLL
"F"
CCC
"B"
CCC
"D"
CCC
"C"
AFS090
Standard I/O Bank
Analog Quads
Advanced I/O Bank
Advanced I/O Bank
AFS250
Bank 3
Bank 3
Bank 1
Bank 1
Bank 2 (analog)
Bank 0
Device Architecture
2-162 Revision 4
Figure 2-114 • Naming Conventions of Fusion Devices with Four I/O Banks
AFS600
AFS1500
Bank 4
Bank 4
Bank 2
Bank 2
Bank 3 (analog)
Bank 0 Bank 1
CCC
"A"
CCC
"E"
CCC/PLL
"F"
CCC
"B"
CCC
"D"
CCC/PLL
"C"
Pro I/O Bank
Analog Quads
Advnaced I/O Bank
Advanced I/O Bank
Fusion Family of Mixed Signal FPGAs
Revision 4 2-163
User I/O Characteristics
Timing Model
Figure 2-115 • Timing Model
Operating Conditions: –2 Speed, Commercial Temperature Range (TJ=70°C),
Worst-Case VCC = 1.425 V
DQ
Y
Y
DQ
DQ DQ
Y
Combinational Cell
Combinational Cell
Combinational Cell
Register Cell Register Cell
I/O Module
(Non-Registered)
LVPECL (Pro IO banks)
LVPECL
(Pro IO Banks)
LVDS,
BLVDS,
M-LVDS (Pro IO Banks)
GTL+ 3.3 V
Y
Combinational Cell
Y
Combinational Cell
Y
Combinational Cell
LVTTL/LVCMOS 3.3 V (Pro I/O banks)
Output drive strength = 24 mA
High slew rate
LVCMOS 1.5 V (Pro IO banks)
Output drive strength = 12 mA
High slew
LVTTL/LVCMOS 3.3 V (Pro I/O banks)
Output drive strength = 12 mA
High slew rate
IInput LVTTL/LVCMOS
3.3 V (Pro IO banks)
Input LVTTL/LVCMOS
3.3 V (Pro IO banks)
Input LVTTL/LVCMOS
3.3 V (Pro IO banks)
I/O Module
(Non-Registered)
I/O Module
(Non-Registered)
I/O Module
(Non-Registered)
I/O Module
(Registered)
I/O Module
(Registered)
I/O Module
(Non-Registered)
t
PD
= 0.56 ns t
PD
= 0.49 ns
t
Dp
= 1.60 ns
t
PD
= 0.87 ns t
DP
= 2.74 ns
t
PD
= 0.51 ns
t
PD
= 0.47 ns
t
PD
= 0.47 ns
t
OCLKQ
= 0.59 ns
t
OSUD
= 0.31 ns
t
PY
= 0.90 ns
t
DP
= 1.53 ns
t
DP
= 3.30 ns
t
DP
= 2.39 ns
t
CLKQ
= 0.55 ns
t
SUD
= 0.43 ns
t
PY
= 0.90 ns
t
CLKQ
= 0.55 ns
t
SUD
= 0.43 ns
t
PY
= 1.36 ns
t
PY
= 0.90 ns
t
PY
= 1.22 ns
t
ICLKQ
= 0.24 ns
t
ISUD
= 0.26 ns
Device Architecture
2-164 Revision 4
Figure 2-116 • Input Buffer Timing Model and Delays (example)
tPY = MAX(tPY (R), tPY (F))
tPYs = MAX(tPYS (R), tPYS (F))
tDIN = MAX(tDIN (R), tDIN (F))
tPY
(R)
PAD
Y
Vtrip
GND tPY
(F)
Vtrip
50%
50%
VIH
VCC
VIL
tPYS
(R)
tPYS
(F)
tDIN
(R)
DIN
GND tDIN
(F)
50%50%
VCC
PAD Y
tPY
tPYS
D
CLK
Q
I/O interface
DIN
tDIN
To Array
Fusion Family of Mixed Signal FPGAs
Revision 4 2-165
Figure 2-117 • Output Buffer Model and Delays (example)
tDP
(R)
PAD VOL
tDP
(F)
Vtrip
Vtrip
VOH
VCC
D50% 50%
VCC
0 V
DOUT 50% 50% 0 V
tDOUT
(R)
tDOUT
(F)
From Array
PAD
tDP
Std
Load
D
CLK
Q
I/O Interface
DOUT
D
tDOUT
tDP = MAX(tDP(R), tDP(F))
tDOUT = MAX(tDOUT(R), tDOUT(F))
Device Architecture
2-166 Revision 4
Figure 2-118 • Tristate Output Buffer Timing Model and Delays (example)
D
CLK
Q
D
CLK
Q
10% VCCI
tZL
V
trip
50%
tHZ
90% VCCI
tZH
V
trip
50% 50% t
LZ
50%
EOUT
PAD
D
E50%
t
EOUT (R)
50%
t
EOUT (F)
PAD
DOUT
EOUT
D
I/O Interface
E
t
EOUT
t
ZLS
V
trip
50%
t
ZHS
V
trip
50%
EOUT
PAD
D
E50% 50%
t
EOUT (R)
t
EOUT (F)
50%
VCC
VCC
VCC
VCCI
VCC
VCC
VCC
VOH
VOL
VOL
t
ZL
, t
ZH
, t
HZ
, t
LZ
, t
ZLS
, t
ZHS
t
EOUT
= MAX(t
EOUT
(R). t
EOUT
(F))
Fusion Family of Mixed Signal FPGAs
Revision 4 2-167
Overview of I/O Performance
Summary of I/O DC Input and Output Levels – Default I/O Software Settings
Table 2-86 • Summary of Maximum and Minimum DC Input and Output Levels Applicable to Commercial and
Industrial Conditions
Applicable to Pro I/Os
I/O Standard
Drive
Strength
Slew
Rate
VIL VIH VOL VOH IOL IOH
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
3.3 V LVTTL /
3.3 V LVCMOS
12 mA High –0.3 0.8 2 3.6 0.4 2.4 12 12
2.5 V LVCMOS 12 mA High –0.3 0.7 1.7 3.6 0.7 1.7 12 12
1.8 V LVCMOS 12 mA High –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI 0.45 12 12
1.5 V LVCMOS 12 mA High –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 12 12
3.3 V PCI Per PCI Specification
3.3 V PCI-X Per PCI-X Specification
3.3 V GTL 20 mA2 High –0.3 VREF – 0.05 VREF + 0.05 3.6 0.4 20 20
2.5 V GTL 20 mA2 High –0.3 VREF – 0.05 VREF + 0.05 3.6 0.4 20 20
3.3 V GTL+ 35 mA High –0.3 VREF – 0.1 VREF + 0.1 3.6 0.6 35 35
2.5 V GTL+ 33 mA High –0.3 VREF – 0.1 VREF + 0.1 3.6 0.6 33 33
HSTL (I) 8 mA High –0.3 VREF – 0.1 VREF + 0.1 3.6 0.4 VCCI – 0.4 8 8
HSTL (II) 15 mA2 High –0.3 VREF – 0.1 VREF + 0.1 3.6 0.4 VCCI 0.4 15 15
SSTL2 (I) 15 mA High –0.3 VREF – 0.2 VREF + 0.2 3.6 0.54 VCCI 0.62 15 15
SSTL2 (II) 18 mA High –0.3 VREF – 0.2 VREF + 0.2 3.6 0.35 VCCI 0.43 18 18
SSTL3 (I) 14 mA High –0.3 VREF 0.2 VREF + 0.2 3.6 0.7 VCCI – 1.1 14 14
SSTL3 (II) 21 mA High –0.3 VREF 0.2 VREF + 0.2 3.6 0.5 VCCI – 0.9 21 21
Notes:
1. Currents are measured at 85°C junction temperature.
2. Output drive strength is below JEDEC specification.
3. Output slew rate can be extracted by the IBIS models.
Table 2-87 • Summary of Maximum and Minimum DC Input and Output Levels Applicable to Commercial and
Industrial Conditions
Applicable to Advanced I/Os
I/O Standard
Drive
Strength
Slew
Rate
VIL VIH VOL VOH IOL IOH
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
3.3 V LVTTL /
3.3 V LVCMOS
12 mA High –0.3 0.8 2 3.6 0.4 2.4 12 12
2.5 V LVCMOS 12 mA High –0.3 0.7 1.7 2.7 0.7 1.7 12 12
1.8 V LVCMOS 12 mA High –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 12 12
1.5 V LVCMOS 12 mA High –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 12 12
3.3 V PCI Per PCI specifications
3.3 V PCI-X Per PCI-X specifications
Note: Currents are measured at 85°C junction temperature.
Device Architecture
2-168 Revision 4
Table 2-88 • Summary of Maximum and Minimum DC Input and Output Levels Applicable to Commercial and
Industrial Conditions
Applicable to Standard I/Os
I/O Standard
Drive
Strength
Slew
Rate
VIL VIH VOL VOH IOL IOH
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
3.3 V LVTTL /
3.3 V LVCMOS
8 mA High –0.3 0.8 2 3.6 0.4 2.4 8 8
2.5 V LVCMOS 8 mA High –0.3 0.7 1.7 3.6 0.7 1.7 8 8
1.8 V LVCMOS 4 mA High –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 4 4
1.5 V LVCMOS 2 mA High –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 2 2
Note: Currents are measured at 85°C junction temperature.
Table 2-89 • Summary of Maximum and Minimum DC Input Levels Applicable to Commercial and Industrial
Conditions
Applicable to All I/O Bank Types
DC I/O Standards
Commercial1Industrial2
IIL3IIH4IIL3IIH4
µA µA µA µA
3.3 V LVTTL / 3.3 V LVCMOS 10 10 15 15
2.5 V LVCMOS 10 10 15 15
1.8 V LVCMOS 10 10 15 15
1.5 V LVCMOS 10 10 15 15
3.3 V PCI 10 10 15 15
3.3 V PCI-X 10 10 15 15
3.3 V GTL 10 10 15 15
2.5 V GTL 10 10 15 15
3.3 V GTL+ 10 10 15 15
2.5 V GTL+ 10 10 15 15
HSTL (I) 10 10 15 15
HSTL (II) 10 10 15 15
SSTL2 (I) 10 10 15 15
SSTL2 (II) 10 10 15 15
SSTL3 (I) 10 10 15 15
SSTL3 (II) 10 10 15 15
Notes:
1. Commercial range (0°C < TJ < 85°C)
2. Industrial range (–40°C < TJ < 100°C)
3. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
4. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-169
Summary of I/O Timing Characteristics – Default I/O Software Settings
Table 2-90 • Summary of AC Measuring Points
Applicable to All I/O Bank Types
Standard
Input Reference Voltage
(VREF_TYP)
Board Termination Voltage
(VTT_REF)
Measuring Trip Point
(Vtrip)
3.3 V LVTTL / 3.3 V LVCMOS 1.4 V
2.5 V LVCMOS 1.2 V
1.8 V LVCMOS 0.90 V
1.5 V LVCMOS 0.75 V
3.3 V PCI 0.285 * VCCI (RR)
0.615 * VCCI (FF))
3.3 V PCI-X 0.285 * VCCI (RR)
0.615 * VCCI (FF)
3.3 V GTL 0.8 V 1.2 V VREF
2.5 V GTL 0.8 V 1.2 V VREF
3.3 V GTL+ 1.0 V 1.5 V VREF
2.5 V GTL+ 1.0 V 1.5 V VREF
HSTL (I) 0.75 V 0.75 V VREF
HSTL (II) 0.75 V 0.75 V VREF
SSTL2 (I) 1.25 V 1.25 V VREF
SSTL2 (II) 1.25 V 1.25 V VREF
SSTL3 (I) 1.5 V 1.485 V VREF
SSTL3 (II) 1.5 V 1.485 V VREF
LVDS Cross point
LVPECL Cross point
Table 2-91 • I/O AC Parameter Definitions
Parameter Definition
tDP Data to Pad delay through the Output Buffer
tPY Pad to Data delay through the Input Buffer with Schmitt trigger disabled
tDOUT Data to Output Buffer delay through the I/O interface
tEOUT Enable to Output Buffer Tristate Control delay through the I/O interface
tDIN Input Buffer to Data delay through the I/O interface
tPYS Pad to Data delay through the Input Buffer with Schmitt trigger enabled
tHZ Enable to Pad delay through the Output Buffer—High to Z
tZH Enable to Pad delay through the Output Buffer—Z to High
tLZ Enable to Pad delay through the Output Buffer—Low to Z
tZL Enable to Pad delay through the Output Buffer—Z to Low
tZHS Enable to Pad delay through the Output Buffer with delayed enable—Z to High
tZLS Enable to Pad delay through the Output Buffer with delayed enable—Z to Low
Device Architecture
2-170 Revision 4
Table 2-92 • Summary of I/O Timing Characteristics – Software Default Settings
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = I/O Standard Dependent
Applicable to Pro I/Os
I/O Standard
Drive Strength (mA)
Slew Rate
Capacitive Load (pF)
External Resistor (Ohm)
t DOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
tZLS
tZHS
Units
3.3 V LVTTL/
3.3 V LVCMOS
12 mA High 35 0.49 2.74 0.03 0.90 1.17 0.32 2.79 2.14 2.45 2.70 4.46 3.81 ns
2.5 V LVCMOS 12 mA High 35 0.49 2.80 0.03 1.13 1.24 0.32 2.85 2.61 2.51 2.61 4.52 4.28 ns
1.8 V LVCMOS 12 mA High 35 0.49 2.83 0.03 1.08 1.42 0.32 2.89 2.31 2.79 3.16 4.56 3.98 ns
1.5 V LVCMOS 12 mA High 35 0.49 3.30 0.03 1.27 1.60 0.32 3.36 2.70 2.96 3.27 5.03 4.37 ns
3.3 V PCI Per
PCI
spec
High 10 25 20.49 2.09 0.03 0.78 1.25 0.32 2.13 1.49 2.45 2.70 3.80 3.16 ns
3.3 V PCI-X Per
PCI-X
spec
High 10 25 20.49 2.09 0.03 0.77 1.17 0.32 2.13 1.49 2.45 2.70 3.80 3.16 ns
3.3 V GTL 20 mA High 10 25 0.49 1.55 0.03 2.19 0.32 1.52 1.55 0.00 0.00 3.19 3.22 ns
2.5 V GTL 20 mA High 10 25 0.49 1.59 0.03 1.83 0.32 1.61 1.59 0.00 0.00 3.28 3.26 ns
3.3 V GTL+ 35 mA High 10 25 0.49 1.53 0.03 1.19 0.32 1.56 1.53 0.00 0.00 3.23 3.20 ns
2.5 V GTL+ 33 mA High 10 25 0.49 1.65 0.03 1.13 0.32 1.68 1.57 0.00 0.00 3.35 3.24 ns
HSTL (I) 8 mA High 20 50 0.49 2.37 0.03 1.59 0.32 2.42 2.35 0.00 0.00 4.09 4.02 ns
HSTL (II) 15 mA High 20 25 0.49 2.26 0.03 1.59 0.32 2.30 2.03 0.00 0.00 3.97 3.70 ns
SSTL2 (I) 17 mA High 30 50 0.49 1.59 0.03 1.00 0.32 1.62 1.38 0.00 0.00 3.29 3.05 ns
SSTL2 (II) 21 mA High 30 25 0.49 1.62 0.03 1.00 0.32 1.65 1.32 0.00 0.00 3.32 2.99 ns
SSTL3 (I) 16 mA High 30 50 0.49 1.72 0.03 0.93 0.32 1.75 1.37 0.00 0.00 3.42 3.04 ns
SSTL3 (II) 24 mA High 30 25 0.49 1.54 0.03 0.93 0.32 1.57 1.25 0.00 0.00 3.24 2.92 ns
LVDS 24 mA High 0.49 1.57 0.03 1.36 ns
LVPECL 24 mA High 0.49 1.60 0.03 1.22 ns
Notes:
1. For specific junction temperature and voltage-supply levels, refer to Table 3-6 on page 3-7 for derating values.
2. Resistance is used to measure I/O propagation delays as defined in PCI specifications. See Figure 2-123 on page 2-200
for connectivity. This resistor is not required during normal operation.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-171
Table 2-93 • Summary of I/O Timing Characteristics – Software Default Settings
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = I/O Standard Dependent
Applicable to Advanced I/Os
I/O Standard
Drive Strength (mA)
Slew Rate
Capacitive Load (pF)
External Resistor (Ohm)
t DOUT
tDP
tDIN
tPY
tEOUT
tZL
tZH
tLZ
tHZ
tZLS
tZHS
Units
3.3 V LVTTL/
3.3 V LVCMOS
12 mA High 35 pF 0.49 2.64 0.03 0.90 0.32 2.69 2.11 2.40 2.68 4.36 3.78 ns
2.5 V LVCMOS 12 mA High 35 pF 0.49 2.66 0.03 0.98 0.32 2.71 2.56 2.47 2.57 4.38 4.23 ns
1.8 V LVCMOS 12 mA High 35 pF 0.49 2.64 0.03 0.91 0.32 2.69 2.27 2.76 3.05 4.36 3.94 ns
1.5 V LVCMOS 12 mA High 35 pF 0.49 3.05 0.03 1.07 0.32 3.10 2.67 2.95 3.14 4.77 4.34 ns
3.3 V PCI Per PCI
spec
High 10 pF 25 20.49 2.00 0.03 0.65 0.32 2.04 1.46 2.40 2.68 3.71 3.13 ns
3.3 V PCI-X Per PCI-X
spec
High 10 pF 25 20.49 2.00 0.03 0.62 0.32 2.04 1.46 2.40 2.68 3.71 3.13 ns
LVDS 24 mA High 0.49 1.37 0.03 1.20 N/A N/A N/A N/A N/A N/A N/A ns
LVPECL 24 mA High 0.49 1.34 0.03 1.05 N/A N/A N/A N/A N/A N/A N/A ns
Notes:
1. For specific junction temperature and voltage-supply levels, refer to Table 3-6 on page 3-7 for derating values.
2. Resistance is used to measure I/O propagation delays as defined in PCI specifications. See Figure 2-123 on page 2-200
for connectivity. This resistor is not required during normal operation.
Table 2-94 • Summary of I/O Timing Characteristics – Software Default Settings
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = I/O Standard Dependent
Applicable to Standard I/Os
I/O Standard
Drive Strength (mA)
Slew Rate
Capacitive Load (pF)
External Resistor (Ohm)
t DOUT
tDP
tDIN
tPY
tEOUT
tZL
tZH
tLZ
tHZ
Units
3.3 V LVTTL/
3.3 V LVCMOS
8 mA High 35 pF 0.49 3.29 0.03 0.75 0.32 3.36 2.80 1.79 2.01 ns
2.5 V LVCMOS 8 mA High 35pF 0.49 3.56 0.03 0.96 0.32 3.40 3.56 1.78 1.91 ns
1.8 V LVCMOS 4 mA High 35pF 0.49 4.74 0.03 0.90 0.32 4.02 4.74 1.80 1.85 ns
1.5 V LVCMOS 2 mA High 35pF 0.49 5.71 0.03 1.06 0.32 4.71 5.71 1.83 1.83 ns
Note: For specific junction temperature and voltage-supply levels, refer to Table 3-6 on page 3-7 for derating values.
Device Architecture
2-172 Revision 4
Detailed I/O DC Characteristics
Table 2-95 • Input Capacitance
Symbol Definition Conditions Min. Max. Units
CIN Input capacitance VIN = 0, f = 1.0 MHz 8 pF
CINCLK Input capacitance on the clock pin VIN = 0, f = 1.0 MHz 8 pF
Table 2-96 • I/O Output Buffer Maximum Resistances 1
Standard Drive Strength
RPULL-DOWN
(ohms) 2
RPULL-UP
(ohms) 3
Applicable to Pro I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 4 mA 100 300
8 mA 50 150
12 mA 25 75
16 mA 17 50
24 mA 11 33
2.5 V LVCMOS 4 mA 100 200
8 mA 50 100
12 mA 25 50
16 mA 20 40
24 mA 11 22
1.8 V LVCMOS 2 mA 200 225
4 mA 100 112
6 mA 50 56
8 mA 50 56
12 mA 20 22
16 mA 20 22
1.5 V LVCMOS 2 mA 200 224
4 mA 100 112
6 mA 67 75
8 mA 33 37
12 mA 33 37
3.3 V PCI/PCI-X Per PCI/PCI-X specification 25 75
3.3 V GTL 20 mA 11
2.5 V GTL 20 mA 14
3.3 V GTL+ 35 mA 12
2.5 V GTL+ 33 mA 15
Notes:
1. These maximum values are provided for informational reasons only. Minimum output buffer resistance values depend
on VCC, drive strength selection, temperature, and process. For board design considerations and detailed output buffer
resistances, use the corresponding IBIS models located on the Microsemi SoC Products Group website:
http://www.microsemi.com/soc/techdocs/models/ibis.html.
2. R(PULL-DOWN-MAX) = VOLspec / IOLspec
3. R(PULL-UP-MAX) = (VCCImax – VOHspec) / IOHspec
Fusion Family of Mixed Signal FPGAs
Revision 4 2-173
HSTL (I) 8 mA 50 50
HSTL (II) 15 mA 25 25
SSTL2 (I) 17 mA 27 31
SSTL2 (II) 21 mA 13 15
SSTL3 (I) 16 mA 44 69
SSTL3 (II) 24 mA 18 32
Applicable to Advanced I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 2 mA 100 300
4 mA 100 300
6 mA 50 150
8 mA 50 150
12 mA 25 75
16 mA 17 50
24 mA 11 33
2.5 V LVCMOS 2 mA 100 200
4 mA 100 200
6 mA 50 100
8 mA 50 100
12 mA 25 50
16 mA 20 40
24 mA 11 22
1.8 V LVCMOS 2 mA 200 225
4 mA 100 112
6 mA 50 56
8 mA 50 56
12 mA 20 22
16 mA 20 22
1.5 V LVCMOS 2 mA 200 224
4 mA 100 112
6 mA 67 75
8 mA 33 37
12 mA 33 37
3.3 V PCI/PCI-X Per PCI/PCI-X specification 25 75
Table 2-96 • I/O Output Buffer Maximum Resistances 1 (continued)
Standard Drive Strength
RPULL-DOWN
(ohms) 2
RPULL-UP
(ohms) 3
Notes:
1. These maximum values are provided for informational reasons only. Minimum output buffer resistance values depend
on VCC, drive strength selection, temperature, and process. For board design considerations and detailed output buffer
resistances, use the corresponding IBIS models located on the Microsemi SoC Products Group website:
http://www.microsemi.com/soc/techdocs/models/ibis.html.
2. R(PULL-DOWN-MAX) = VOLspec / IOLspec
3. R(PULL-UP-MAX) = (VCCImax – VOHspec) / IOHspec
Device Architecture
2-174 Revision 4
Applicable to Standard I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 2 mA 100 300
4 mA 100 300
6 mA 50 150
8 mA 50 150
2.5 V LVCMOS 2 mA 100 200
4 mA 100 200
6 mA 50 100
8 mA 50 100
1.8 V LVCMOS 2 mA 200 225
4 mA 100 112
1.5 V LVCMOS 2 mA 200 224
Table 2-97 • I/O Weak Pull-Up/Pull-Down Resistances
Minimum and Maximum Weak Pull-Up/Pull-Down Resistance Values
VCCI
R(WEAK PULL-UP)1
(ohms)
R(WEAK PULL-DOWN)2
(ohms)
Min. Max. Min. Max.
3.3 V 10 k 45 k 10 k 45 k
2.5 V 11 k 55 k 12 k 74 k
1.8 V 18 k 70 k 17 k 110 k
1.5 V 19 k 90 k 19 k 140 k
Notes:
1. R(WEAK PULL-UP-MAX) = (VCCImax – VOHspec) / IWEAK PULL-UP-MIN
2. R(WEAK PULL-DOWN-MAX) = VOLspec / IWEAK PULL-DOWN-MIN
Table 2-96 • I/O Output Buffer Maximum Resistances 1 (continued)
Standard Drive Strength
RPULL-DOWN
(ohms) 2
RPULL-UP
(ohms) 3
Notes:
1. These maximum values are provided for informational reasons only. Minimum output buffer resistance values depend
on VCC, drive strength selection, temperature, and process. For board design considerations and detailed output buffer
resistances, use the corresponding IBIS models located on the Microsemi SoC Products Group website:
http://www.microsemi.com/soc/techdocs/models/ibis.html.
2. R(PULL-DOWN-MAX) = VOLspec / IOLspec
3. R(PULL-UP-MAX) = (VCCImax – VOHspec) / IOHspec
Fusion Family of Mixed Signal FPGAs
Revision 4 2-175
Table 2-98 • I/O Short Currents IOSH/IOSL
Drive Strength IOSH (mA)* IOSL (mA)*
Applicable to Pro I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 4 mA 25 27
8 mA 51 54
12 mA 103 109
16 mA 132 127
24 mA 268 181
2.5 V LVCMOS 4 mA 16 18
8 mA 32 37
12 mA 65 74
16 mA 83 87
24 mA 169 124
1.8 V LVCMOS 2 mA 9 11
4 mA 17 22
6 mA 35 44
8 mA 45 51
12 mA 91 74
16 mA 91 74
1.5 V LVCMOS 2 mA 13 16
4 mA 25 33
6 mA 32 39
8 mA 66 55
12 mA 66 55
Applicable to Advanced I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 2 mA 25 27
4 mA 25 27
6 mA 51 54
8 mA 51 54
12 mA 103 109
16 mA 132 127
24 mA 268 181
3.3 V LVCMOS 2 mA 25 27
4 mA 25 27
6 mA 51 54
8 mA 51 54
12 mA 103 109
16 mA 132 127
24 mA 268 181
Note: *TJ = 100°C
Device Architecture
2-176 Revision 4
The length of time an I/O can withstand IOSH/IOSL events depends on the junction temperature. The
reliability data below is based on a 3.3 V, 36 mA I/O setting, which is the worst case for this type of
analysis.
For example, at 100°C, the short current condition would have to be sustained for more than six months
to cause a reliability concern. The I/O design does not contain any short circuit protection, but such
protection would only be needed in extremely prolonged stress conditions.
2.5 V LVCMOS 2 mA 16 18
4 mA 16 18
6 mA 32 37
8 mA 32 37
12 mA 65 74
16 mA 83 87
24 mA 169 124
1.8 V LVCMOS 2 mA 9 11
4 mA 17 22
6 mA 35 44
8 mA 45 51
12 mA 91 74
16 mA 91 74
1.5 V LVCMOS 2 mA 13 16
4 mA 25 33
6 mA 32 39
8 mA 66 55
12 mA 66 55
3.3 V PCI/PCI-X Per PCI/PCI-X
specification
103 109
Applicable to Standard I/O Banks
3.3 V LVTTL / 3.3 V LVCMOS 2 mA 25 27
4 mA 25 27
6 mA 51 54
8 mA 51 54
2.5 V LVCMOS 2 mA 16 18
4 mA 16 18
6 mA 32 37
8 mA 32 37
1.8 V LVCMOS 2 mA 9 11
4 mA 17 22
1.5 V LVCMOS 2 mA 13 16
Table 2-98 • I/O Short Currents IOSH/IOSL (continued)
Drive Strength IOSH (mA)* IOSL (mA)*
Note: *TJ = 100°C
Fusion Family of Mixed Signal FPGAs
Revision 4 2-177
Table 2-99 • Short Current Event Duration before Failure
Temperature Time before Failure
–40°C >20 years
0°C >20 years
25°C >20 years
70°C 5 years
85°C 2 years
100°C 6 months
Table 2-100 • Schmitt Trigger Input Hysteresis
Hysteresis Voltage Value (typ.) for Schmitt Mode Input Buffers
Input Buffer Configuration Hysteresis Value (typ.)
3.3 V LVTTL/LVCMOS/PCI/PCI-X (Schmitt trigger mode) 240 mV
2.5 V LVCMOS (Schmitt trigger mode) 140 mV
1.8 V LVCMOS (Schmitt trigger mode) 80 mV
1.5 V LVCMOS (Schmitt trigger mode) 60 mV
Table 2-101 • I/O Input Rise Time, Fall Time, and Related I/O Reliability
Input Buffer Input Rise/Fall Time (min.) Input Rise/Fall Time (max.) Reliability
LVTTL/LVCMOS (Schmitt trigger
disabled)
No requirement 10 ns* 20 years (100°C)
LVTTL/LVCMOS (Schmitt trigger
enabled)
No requirement No requirement, but input
noise voltage cannot exceed
Schmitt hysteresis
20 years (100°C)
HSTL/SSTL/GTL No requirement 10 ns* 10 years (100°C)
LVDS/BLVDS/M-LVDS/LVPECL No requirement 10 ns* 10 years (100°C)
Note: *The maximum input rise/fall time is related only to the noise induced into the input buffer trace. If the noise is
low, the rise time and fall time of input buffers, when Schmitt trigger is disabled, can be increased beyond the
maximum value. The longer the rise/fall times, the more susceptible the input signal is to the board noise.
Microsemi recommends signal integrity evaluation/characterization of the system to ensure there is no excessive
noise coupling into input signals.
Device Architecture
2-178 Revision 4
Single-Ended I/O Characteristics
3.3 V LVTTL / 3.3 V LVCMOS
Low-Voltage Transistor–Transistor Logic is a general-purpose standard (EIA/JESD) for 3.3 V
applications. It uses an LVTTL input buffer and push-pull output buffer. The 3.3 V LVCMOS standard is
supported as part of the 3.3 V LVTTL support.
Table 2-102 • Minimum and Maximum DC Input and Output Levels
3.3 V LVTTL /
3.3 V LVCMOS VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
Applicable to Pro I/O Banks
4 mA –0.3 0.8 2 3.6 0.4 2.4 4 4 27 25 10 10
8 mA –0.3 0.8 2 3.6 0.4 2.4 8 8 54 51 10 10
12 mA –0.3 0.8 23.6 0.4 2.4 12 12 109 103 10 10
16 mA –0.3 0.8 2 3.6 0.4 2.4 16 16 127 132 10 10
24 mA –0.3 0.8 2 3.6 0.4 2.4 24 24 181 268 10 10
Applicable to Advanced I/O Banks
2 mA –0.3 0.8 2 3.6 0.4 2.4 2 2 27 25 10 10
4 mA –0.3 0.8 2 3.6 0.4 2.4 4 4 27 25 10 10
6 mA –0.3 0.8 2 3.6 0.4 2.4 6 6 54 51 10 10
8 mA –0.3 0.8 2 3.6 0.4 2.4 8 8 54 51 10 10
12 mA –0.3 0.8 23.6 0.4 2.4 12 12 109 103 10 10
16 mA –0.3 0.8 2 3.6 0.4 2.4 16 16 127 132 10 10
24 mA –0.3 0.8 2 3.6 0.4 2.4 24 24 181 268 10 10
Applicable to Standard I/O Banks
2 mA –0.3 0.8 2 3.6 0.4 2.4 2 2 27 25 10 10
4 mA –0.3 0.8 2 3.6 0.4 2.4 4 4 27 25 10 10
6 mA –0.3 0.8 2 3.6 0.4 2.4 6 6 54 51 10 10
8 mA –0.3 0.8 23.6 0.4 2.4 8 8 54 51 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
Figure 2-119 • AC Loading
Table 2-103 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) CLOAD (pF)
03.31.435
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
Test Point
Enable Path
Data Path 35 pF
R = 1 k R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
Fusion Family of Mixed Signal FPGAs
Revision 4 2-179
Timing Characteristics
Table 2-104 • 3.3 V LVTTL / 3.3 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Pro I/Os
Drive
Strength
Spee
d
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
4 mA Std. 0.66 11.01 0.04 1.20 1.57 0.43 11.21 9.05 2.69 2.44 13.45 11.29 ns
–1 0.56 9.36 0.04 1.02 1.33 0.36 9.54 7.70 2.29 2.08 11.44 9.60 ns
–2 0.49 8.22 0.03 0.90 1.17 0.32 8.37 6.76 2.01 1.82 10.04 8.43 ns
8 mA Std. 0.66 7.86 0.04 1.20 1.57 0.43 8.01 6.44 3.04 3.06 10.24 8.68 ns
–1 0.56 6.69 0.04 1.02 1.33 0.36 6.81 5.48 2.58 2.61 8.71 7.38 ns
–2 0.49 5.87 0.03 0.90 1.17 0.32 5.98 4.81 2.27 2.29 7.65 6.48 ns
12 mA Std. 0.66 6.03 0.04 1.20 1.57 0.43 6.14 5.02 3.28 3.47 8.37 7.26 ns
–1 0.56 5.13 0.04 1.02 1.33 0.36 5.22 4.27 2.79 2.95 7.12 6.17 ns
–2 0.49 4.50 0.03 0.90 1.17 0.32 4.58 3.75 2.45 2.59 6.25 5.42 ns
16 mA Std. 0.66 5.62 0.04 1.20 1.57 0.43 5.72 4.72 3.32 3.58 7.96 6.96 ns
–1 0.56 4.78 0.04 1.02 1.33 0.36 4.87 4.02 2.83 3.04 6.77 5.92 ns
–2 0.49 4.20 0.03 0.90 1.17 0.32 4.27 3.53 2.48 2.67 5.94 5.20 ns
24 mA Std. 0.66 5.24 0.04 1.20 1.57 0.43 5.34 4.69 3.39 3.96 7.58 6.93 ns
–1 0.56 4.46 0.04 1.02 1.33 0.36 4.54 3.99 2.88 3.37 6.44 5.89 ns
–2 0.49 3.92 0.03 0.90 1.17 0.32 3.99 3.50 2.53 2.96 5.66 5.17 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-180 Revision 4
Table 2-105 • 3.3 V LVTTL / 3.3 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS
tEOU
TtZL tZH tLZ tHZ tZLS tZHS
Units
4 mA Std. 0.66 7.88 0.04 1.20 1.57 0.43 8.03 6.70 2.69 2.59 10.26 8.94 ns
–1 0.56 6.71 0.04 1.02 1.33 0.36 6.83 5.70 2.29 2.20 8.73 7.60 ns
–2 0.49 5.89 0.03 0.90 1.17 0.32 6.00 5.01 2.01 1.93 7.67 6.67 ns
8 mA Std. 0.66 5.08 0.04 1.20 1.57 0.43 5.17 4.14 3.05 3.21 7.41 6.38 ns
–1 0.56 4.32 0.04 1.02 1.33 0.36 4.40 3.52 2.59 2.73 6.30 5.43 ns
–2 0.49 3.79 0.03 0.90 1.17 0.32 3.86 3.09 2.28 2.40 5.53 4.76 ns
12 mA Std. 0.66 3.67 0.04 1.20 1.57 0.43 3.74 2.87 3.28 3.61 5.97 5.11 ns
–1 0.56 3.12 0.04 1.02 1.33 0.36 3.18 2.44 2.79 3.07 5.08 4.34 ns
–2 0.49 2.74 0.03 0.90 1.17 0.32 2.79 2.14 2.45 2.70 4.46 3.81 ns
16 mA Std. 0.66 3.46 0.04 1.20 1.57 0.43 3.53 2.61 3.33 3.72 5.76 4.84 ns
–1 0.56 2.95 0.04 1.02 1.33 0.36 3.00 2.22 2.83 3.17 4.90 4.12 ns
–2 0.49 2.59 0.03 0.90 1.17 0.32 2.63 1.95 2.49 2.78 4.30 3.62 ns
24 mA Std. 0.66 3.21 0.04 1.20 1.57 0.43 3.27 2.16 3.39 4.13 5.50 4.39 ns
–1 0.56 2.73 0.04 1.02 1.33 0.36 2.78 1.83 2.88 3.51 4.68 3.74 ns
–2 0.49 2.39 0.03 0.90 1.17 0.32 2.44 1.61 2.53 3.08 4.11 3.28 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-181
Table 2-106 • 3.3 V LVTTL / 3.3 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
4 mA Std. 0.66 10.26 0.04 1.20 0.43 10.45 8.90 2.64 2.46 12.68 11.13 ns
–1 0.56 8.72 0.04 1.02 0.36 8.89 7.57 2.25 2.09 10.79 9.47 ns
–2 0.49 7.66 0.03 0.90 0.32 7.80 6.64 1.98 1.83 9.47 8.31 ns
8 mA Std. 0.66 7.27 0.04 1.20 0.43 7.41 6.28 2.98 3.04 9.65 8.52 ns
–1 0.56 6.19 0.04 1.02 0.36 6.30 5.35 2.54 2.59 8.20 7.25 ns
–2 0.49 5.43 0.03 0.90 0.32 5.53 4.69 2.23 2.27 7.20 6.36 ns
12 mA Std. 0.66 5.58 0.04 1.20 0.43 5.68 4.87 3.21 3.42 7.92 7.11 ns
–1 0.56 4.75 0.04 1.02 0.36 4.84 4.14 2.73 2.91 6.74 6.05 ns
–2 0.49 4.17 0.03 0.90 0.32 4.24 3.64 2.39 2.55 5.91 5.31 ns
16 mA Std. 0.66 5.21 0.04 1.20 0.43 5.30 4.56 3.26 3.51 7.54 6.80 ns
–1 0.56 4.43 0.04 1.02 0.36 4.51 3.88 2.77 2.99 6.41 5.79 ns
–2 0.49 3.89 0.03 0.90 0.32 3.96 3.41 2.43 2.62 5.63 5.08 ns
24 mA Std. 0.66 4.85 0.04 1.20 0.43 4.94 4.54 3.32 3.88 7.18 6.78 ns
–1 0.56 4.13 0.04 1.02 0.36 4.20 3.87 2.82 3.30 6.10 5.77 ns
–2 0.49 3.62 0.03 0.90 0.32 3.69 3.39 2.48 2.90 5.36 5.06 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-182 Revision 4
Table 2-107 • 3.3 V LVTTL / 3.3 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
4 mA Std. 0.66 7.66 0.04 1.20 0.43 7.80 6.59 2.65 2.61 10.03 8.82 ns
–1 0.56 6.51 0.04 1.02 0.36 6.63 5.60 2.25 2.22 8.54 7.51 ns
–2 0.49 5.72 0.03 0.90 0.32 5.82 4.92 1.98 1.95 7.49 6.59 ns
8 mA Std. 0.66 4.91 0.04 1.20 0.43 5.00 4.07 2.99 3.20 7.23 6.31 ns
–1 0.56 4.17 0.04 1.02 0.36 4.25 3.46 2.54 2.73 6.15 5.36 ns
–2 0.49 3.66 0.03 0.90 0.32 3.73 3.04 2.23 2.39 5.40 4.71 ns
12 mA Std. 0.66 3.53 0.04 1.20 0.43 3.60 2.82 3.21 3.58 5.83 5.06 ns
–1 0.56 3.00 0.04 1.02 0.36 3.06 2.40 2.73 3.05 4.96 4.30 ns
–2 0.49 2.64 0.03 0.90 0.32 2.69 2.11 2.40 2.68 4.36 3.78 ns
16 mA Std. 0.66 3.33 0.04 1.20 0.43 3.39 2.56 3.26 3.68 5.63 4.80 ns
–1 0.56 2.83 0.04 1.02 0.36 2.89 2.18 2.77 3.13 4.79 4.08 ns
–2 0.49 2.49 0.03 0.90 0.32 2.53 1.91 2.44 2.75 4.20 3.58 ns
24 mA Std. 0.66 3.08 0.04 1.20 0.43 3.13 2.12 3.32 4.06 5.37 4.35 ns
–1 0.56 2.62 0.04 1.02 0.36 2.66 1.80 2.83 3.45 4.57 3.70 ns
–2 0.49 2.30 0.03 0.90 0.32 2.34 1.58 2.48 3.03 4.01 3.25 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Table 2-108 • 3.3 V LVTTL / 3.3 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 9.46 0.04 1.00 0.43 9.64 8.54 2.07 2.04 ns
–1 0.56 8.05 0.04 0.85 0.36 8.20 7.27 1.76 1.73 ns
–2 0.49 7.07 0.03 0.75 0.32 7.20 6.38 1.55 1.52 ns
4 mA Std. 0.66 9.46 0.04 1.00 0.43 9.64 8.54 2.07 2.04 ns
–1 0.56 8.05 0.04 0.85 0.36 8.20 7.27 1.76 1.73 ns
–2 0.49 7.07 0.03 0.75 0.32 7.20 6.38 1.55 1.52 ns
6 mA Std. 0.66 6.57 0.04 1.00 0.43 6.69 5.98 2.40 2.57 ns
–1 0.56 5.59 0.04 0.85 0.36 5.69 5.09 2.04 2.19 ns
–2 0.49 4.91 0.03 0.75 0.32 5.00 4.47 1.79 1.92 ns
8 mA Std. 0.66 6.57 0.04 1.00 0.43 6.69 5.98 2.40 2.57 ns
–1 0.56 5.59 0.04 0.85 0.36 5.69 5.09 2.04 2.19 ns
–2 0.49 4.91 0.03 0.75 0.32 5.00 4.47 1.79 1.92 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-183
Table 2-109 • 3.3 V LVTTL / 3.3 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 7.07 0.04 1.00 0.43 7.20 6.23 2.07 2.15 ns
–1 0.56 6.01 0.04 0.85 0.36 6.12 5.30 1.76 1.83 ns
–2 20.49 5.28 0.03 0.75 0.32 5.37 4.65 1.55 1.60 ns
4 mA Std. 0.66 7.07 0.04 1.00 0.43 7.20 6.23 2.07 2.15 ns
–1 0.56 6.01 0.04 0.85 0.36 6.12 5.30 1.76 1.83 ns
–2 0.49 5.28 0.03 0.75 0.32 5.37 4.65 1.55 1.60 ns
6 mA Std. 0.66 4.41 0.04 1.00 0.43 4.49 3.75 2.39 2.69 ns
–1 0.56 3.75 0.04 0.85 0.36 3.82 3.19 2.04 2.29 ns
–2 0.49 3.29 0.03 0.75 0.32 3.36 2.80 1.79 2.01 ns
8 mA Std. 0.66 4.41 0.04 1.00 0.43 4.49 3.75 2.39 2.69 ns
–1 0.56 3.75 0.04 0.85 0.36 3.82 3.19 2.04 2.29 ns
–2 0.49 3.29 0.03 0.75 0.32 3.36 2.80 1.79 2.01 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3 - 7 on
page 3-9.
Device Architecture
2-184 Revision 4
2.5 V LVCMOS
Low-Voltage CMOS for 2.5 V is an extension of the LVCMOS standard (JESD8-5) used for general-
purpose 2.5 V applications.
Table 2-110 • Minimum and Maximum DC Input and Output Levels
2.5 V
LVCMOS VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
Applicable to Pro I/O Banks
4 mA –0.3 0.7 1.7 3.6 0.7 1.7 4 4 18 16 10 10
8 mA –0.3 0.7 1.7 3.6 0.7 1.7 8 8 37 32 10 10
12 mA –0.3 0.7 1.7 3.6 0.7 1.7 12 12 74 65 10 10
16 mA –0.3 0.7 1.7 3.6 0.7 1.7 16 16 87 83 10 10
24 mA –0.3 0.7 1.7 3.6 0.7 1.7 24 24 124 169 10 10
Applicable to Advanced I/O Banks
2 mA –0.3 0.7 1.7 2.7 0.7 1.7 2 2 18 16 10 10
4 mA –0.3 0.7 1.7 2.7 0.7 1.7 4 4 18 16 10 10
6 mA –0.3 0.7 1.7 2.7 0.7 1.7 6 6 37 32 10 10
8 mA –0.3 0.7 1.7 2.7 0.7 1.7 8 8 37 32 10 10
12 mA –0.3 0.7 1.7 2.7 0.7 1.7 12 12 74 65 10 10
16 mA –0.3 0.7 1.7 2.7 0.7 1.7 16 16 87 83 10 10
24 mA –0.3 0.7 1.7 2.7 0.7 1.7 24 24 124 169 10 10
Applicable to Standard I/O Banks
2 mA –0.3 0.7 1.7 3.6 0.7 1.7 2 2 18 16 10 10
4 mA –0.3 0.7 1.7 3.6 0.7 1.7 4 4 18 16 10 10
6 mA –0.3 0.7 1.7 3.6 0.7 1.7 6 6 37 32 10 10
8 mA –0.3 0.7 1.7 3.6 0.7 1.7 8 8 37 32 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
Figure 2-120 • AC Loading
Table 2-111 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) CLOAD (pF)
02.51.235
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
Test Point
Enable Path
Data Path 35 pF
R = 1 k R to VCCI for t
LZ
/ t
ZL
/ t
ZLS
R to GND for t
HZ
/ t
ZH
/ t
ZHS
35 pF for t
ZH
/ t
ZHS
/ t
ZL
/ t
ZLS
35 pF for t
HZ
/ t
LZ
Fusion Family of Mixed Signal FPGAs
Revision 4 2-185
Timing Characteristics
Table 2-112 • 2.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS
Units
4 mA Std. 0.60 12.00 0.04 1.51 1.66 0.43 12.23 11.61 2.72 2.20 14.46 13.85 ns
–1 0.51 10.21 0.04 1.29 1.41 0.36 10.40 9.88 2.31 1.87 12.30 11.78 ns
–2 0.45 8.96 0.03 1.13 1.24 0.32 9.13 8.67 2.03 1.64 10.80 10.34 ns
8 mA Std. 0.60 8.73 0.04 1.51 1.66 0.43 8.89 8.01 3.10 2.93 11.13 10.25 ns
–1 0.51 7.43 0.04 1.29 1.41 0.36 7.57 6.82 2.64 2.49 9.47 8.72 ns
–2 0.45 6.52 0.03 1.13 1.24 0.32 6.64 5.98 2.32 2.19 8.31 7.65 ns
12 mA Std. 0.66 6.77 0.04 1.51 1.66 0.43 6.90 6.11 3.37 3.39 9.14 8.34 ns
–1 0.56 5.76 0.04 1.29 1.41 0.36 5.87 5.20 2.86 2.89 7.77 7.10 ns
–2 0.49 5.06 0.03 1.13 1.24 0.32 5.15 4.56 2.51 2.53 6.82 6.23 ns
16 mA Std. 0.66 6.31 0.04 1.51 1.66 0.43 6.42 5.73 3.42 3.52 8.66 7.96 ns
–1 0.56 5.37 0.04 1.29 1.41 0.36 5.46 4.87 2.91 3.00 7.37 6.77 ns
–2 0.49 4.71 0.03 1.13 1.24 0.32 4.80 4.28 2.56 2.63 6.47 5.95 ns
24 mA Std. 0.66 5.93 0.04 1.51 1.66 0.43 6.04 5.70 3.49 4.00 8.28 7.94 ns
–1 0.56 5.05 0.04 1.29 1.41 0.36 5.14 4.85 2.97 3.40 7.04 6.75 ns
–2 0.49 4.43 0.03 1.13 1.24 0.32 4.51 4.26 2.61 2.99 6.18 5.93 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-186 Revision 4
Table 2-113 • 2.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS
Units
4 mA Std. 0.60 8.82 0.04 1.51 1.66 0.43 8.13 8.82 2.72 2.29 10.37 11.05 ns
–1 0.51 7.50 0.04 1.29 1.41 0.36 6.92 7.50 2.31 1.95 8.82 9.40 ns
–2 0.45 6.58 0.03 1.13 1.24 0.32 6.07 6.58 2.03 1.71 7.74 8.25 ns
8 mA Std. 0.60 5.27 0.04 1.51 1.66 0.43 5.27 5.27 3.10 3.03 7.50 7.51 ns
–1 0.51 4.48 0.04 1.29 1.41 0.36 4.48 4.48 2.64 2.58 6.38 6.38 ns
–2 0.45 3.94 0.03 1.13 1.24 0.32 3.93 3.94 2.32 2.26 5.60 5.61 ns
12 mA Std. 0.66 3.74 0.04 1.51 1.66 0.43 3.81 3.49 3.37 3.49 6.05 5.73 ns
–1 0.56 3.18 0.04 1.29 1.41 0.36 3.24 2.97 2.86 2.97 5.15 4.87 ns
–2 0.49 2.80 0.03 1.13 1.24 0.32 2.85 2.61 2.51 2.61 4.52 4.28 ns
16 mA Std. 0.66 3.53 0.04 1.51 1.66 0.43 3.59 3.12 3.42 3.62 5.83 5.35 ns
–1 0.56 3.00 0.04 1.29 1.41 0.36 3.06 2.65 2.91 3.08 4.96 4.55 ns
–2 0.49 2.63 0.03 1.13 1.24 0.32 2.68 2.33 2.56 2.71 4.35 4.00 ns
24 mA Std. 0.66 3.26 0.04 1.51 1.66 0.43 3.32 2.48 3.49 4.11 5.56 4.72 ns
–1 0.56 2.77 0.04 1.29 1.41 0.36 2.83 2.11 2.97 3.49 4.73 4.01 ns
–2 0.49 2.44 0.03 1.13 1.24 0.32 2.48 1.85 2.61 3.07 4.15 3.52 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-187
Table 2-114 • 2.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
4 mA Std. 0.66 11.40 0.04 1.31 0.43 11.22 11.40 2.68 2.20 13.45 13.63 ns
–1 0.56 9.69 0.04 1.11 0.36 9.54 9.69 2.28 1.88 11.44 11.60 ns
–2 0.49 8.51 0.03 0.98 0.32 8.38 8.51 2.00 1.65 10.05 10.18 ns
8 mA Std. 0.66 7.96 0.04 1.31 0.43 8.11 7.81 3.05 2.89 10.34 10.05 ns
–1 0.56 6.77 0.04 1.11 0.36 6.90 6.65 2.59 2.46 8.80 8.55 ns
–2 0.49 5.94 0.03 0.98 0.32 6.05 5.84 2.28 2.16 7.72 7.50 ns
12 mA Std. 0.66 6.18 0.04 1.31 0.43 6.29 5.92 3.30 3.32 8.53 8.15 ns
–1 0.56 5.26 0.04 1.11 0.36 5.35 5.03 2.81 2.83 7.26 6.94 ns
–2 0.49 4.61 0.03 0.98 0.32 4.70 4.42 2.47 2.48 6.37 6.09 ns
16 mA Std. 0.66 6.18 0.04 1.31 0.43 6.29 5.92 3.30 3.32 8.53 8.15 ns
–1 0.56 5.26 0.04 1.11 0.36 5.35 5.03 2.81 2.83 7.26 6.94 ns
–2 0.49 4.61 0.03 0.98 0.32 4.70 4.42 2.47 2.48 6.37 6.09 ns
24 mA Std. 0.66 6.18 0.04 1.31 0.43 6.29 5.92 3.30 3.32 8.53 8.15 ns
–1 0.56 5.26 0.04 1.11 0.36 5.35 5.03 2.81 2.83 7.26 6.94 ns
–2 0.49 4.61 0.03 0.98 0.32 4.70 4.42 2.47 2.48 6.37 6.09 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-188 Revision 4
Table 2-115 • 2.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
4 mA Std. 0.66 8.66 0.04 1.31 0.43 7.83 8.66 2.68 2.30 10.07 10.90 ns
–1 0.56 7.37 0.04 1.11 0.36 6.66 7.37 2.28 1.96 8.56 9.27 ns
–2 0.49 6.47 0.03 0.98 0.32 5.85 6.47 2.00 1.72 7.52 8.14 ns
8 mA Std. 0.66 5.17 0.04 1.31 0.43 5.04 5.17 3.05 3.00 7.27 7.40 ns
–1 0.56 4.39 0.04 1.11 0.36 4.28 4.39 2.59 2.55 6.19 6.30 ns
–2 0.49 3.86 0.03 0.98 0.32 3.76 3.86 2.28 2.24 5.43 5.53 ns
12 mA Std. 0.66 3.56 0.04 1.31 0.43 3.63 3.43 3.30 3.44 5.86 5.67 ns
–1 0.56 3.03 0.04 1.11 0.36 3.08 2.92 2.81 2.92 4.99 4.82 ns
–2 0.49 2.66 0.03 0.98 0.32 2.71 2.56 2.47 2.57 4.38 4.23 ns
16 mA Std. 0.66 3.35 0.04 1.31 0.43 3.41 3.06 3.36 3.55 5.65 5.30 ns
–1 0.56 2.85 0.04 1.11 0.36 2.90 2.60 2.86 3.02 4.81 4.51 ns
–2 0.49 2.50 0.03 0.98 0.32 2.55 2.29 2.51 2.65 4.22 3.96 ns
24 mA Std. 0.66 3.56 0.04 1.31 0.43 3.63 3.43 3.30 3.44 5.86 5.67 ns
–1 0.56 3.03 0.04 1.11 0.36 3.08 2.92 2.81 2.92 4.99 4.82 ns
–2 0.49 2.66 0.03 0.98 0.32 2.71 2.56 2.47 2.57 4.38 4.23 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Tab le 3- 7 on
page 3-9.
Table 2-116 • 2.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 11.00 0.04 1.29 0.43 10.37 11.00 2.03 1.83 ns
–1 0.56 9.35 0.04 1.10 0.36 8.83 9.35 1.73 1.56 ns
–2 0.49 8.21 0.03 0.96 0.32 7.75 8.21 1.52 1.37 ns
4 mA Std. 0.66 11.00 0.04 1.29 0.43 10.37 11.00 2.03 1.83 ns
–1 0.56 9.35 0.04 1.10 0.36 8.83 9.35 1.73 1.56 ns
–2 0.49 8.21 0.03 0.96 0.32 7.75 8.21 1.52 1.37 ns
6 mA Std. 0.66 7.50 0.04 1.29 0.43 7.36 7.50 2.39 2.46 ns
–1 0.56 6.38 0.04 1.10 0.36 6.26 6.38 2.03 2.10 ns
–2 0.49 5.60 0.03 0.96 0.32 5.49 5.60 1.78 1.84 ns
8 mA Std. 0.66 7.50 0.04 1.29 0.43 7.36 7.50 2.39 2.46 ns
–1 0.56 6.38 0.04 1.10 0.36 6.26 6.38 2.03 2.10 ns
–2 0.49 5.60 0.03 0.96 0.32 5.49 5.60 1.78 1.84 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-189
Table 2-117 • 2.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 8.20 0.04 1.29 0.43 7.24 8.20 2.03 1.91 ns
–1 0.56 6.98 0.04 1.10 0.36 6.16 6.98 1.73 1.62 ns
–2 0.49 6.13 0.03 0.96 0.32 5.41 6.13 1.52 1.43 ns
4 mA Std. 0.66 8.20 0.04 1.29 0.43 7.24 8.20 2.03 1.91 ns
–1 0.56 6.98 0.04 1.10 0.36 6.16 6.98 1.73 1.62 ns
–2 0.49 6.13 0.03 0.96 0.32 5.41 6.13 1.52 1.43 ns
6 mA Std. 0.66 4.77 0.04 1.29 0.43 4.55 4.77 2.38 2.55 ns
–1 0.56 4.05 0.04 1.10 0.36 3.87 4.05 2.03 2.17 ns
–2 0.49 3.56 0.03 0.96 0.32 3.40 3.56 1.78 1.91 ns
8 mA Std. 0.66 4.77 0.04 1.29 0.43 4.55 4.77 2.38 2.55 ns
–1 0.56 4.05 0.04 1.10 0.36 3.87 4.05 2.03 2.17 ns
–2 0.49 3.56 0.03 0.96 0.32 3.40 3.56 1.78 1.91 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-190 Revision 4
1.8 V LVCMOS
Low-Voltage CMOS for 1.8 V is an extension of the LVCMOS standard (JESD8-5) used for general-
purpose 1.8 V applications. It uses a 1.8 V input buffer and push-pull output buffer.
Table 2-118 • Minimum and Maximum DC Input and Output Levels
1.8 V
LVCMOS VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
Applicable to Pro I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 2 2 11 9 10 10
4 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 4 4 22 17 10 10
6 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 6 6 44 35 10 10
8 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 8 8 51 45 10 10
12 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 12 12 74 91 10 10
16 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 16 16 74 91 10 10
Applicable to Advanced I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 2 2 11 9 10 10
4 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 4 4 22 17 10 10
6 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 6 6 44 35 10 10
8 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 8 8 51 45 10 10
12 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 12 12 74 91 10 10
16 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.9 0.45 VCCI – 0.45 16 16 74 91 10 10
Applicable to Standard I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 2 2 11 9 10 10
4 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.45 VCCI – 0.45 4 4 22 17 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
Figure 2-121 • AC Loading
Table 2-119 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input Low (V) Measuring Point* (V) VREF (typ.) (V) CLOAD (pF)
01.80.935
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
Test Point
Enable Path
Data Path 35 pF
R = 1 k R to VCCI for t
LZ
/ t
ZL
/ t
ZLS
R to GND for t
HZ
/ t
ZH
/ t
ZHS
35 pF for t
ZH
/ t
ZHS
/ t
ZL
/ t
ZLS
35 pF for t
HZ
/ t
LZ
Fusion Family of Mixed Signal FPGAs
Revision 4 2-191
Timing Characteristics
Table 2-120 • 1.8 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS
Units
2 mA Std. 0.66 15.84 0.04 1.45 1.91 0.43 15.65 15.84 2.78 1.58 17.89 18.07 ns
–1 0.56 13.47 0.04 1.23 1.62 0.36 13.31 13.47 2.37 1.35 15.22 15.37 ns
–2 0.49 11.83 0.03 1.08 1.42 0.32 11.69 11.83 2.08 1.18 13.36 13.50 ns
4 mA Std. 0.66 11.39 0.04 1.45 1.91 0.43 11.60 10.76 3.26 2.77 13.84 12.99 ns
–1 0.56 9.69 0.04 1.23 1.62 0.36 9.87 9.15 2.77 2.36 11.77 11.05 ns
–2 0.49 8.51 0.03 1.08 1.42 0.32 8.66 8.03 2.43 2.07 10.33 9.70 ns
8 mA Std. 0.66 8.97 0.04 1.45 1.91 0.43 9.14 8.10 3.57 3.36 11.37 10.33 ns
–1 0.56 7.63 0.04 1.23 1.62 0.36 7.77 6.89 3.04 2.86 9.67 8.79 ns
–2 0.49 6.70 0.03 1.08 1.42 0.32 6.82 6.05 2.66 2.51 8.49 7.72 ns
12 mA Std. 0.66 8.35 0.04 1.45 1.91 0.43 8.50 7.59 3.64 3.52 10.74 9.82 ns
–1 0.56 7.10 0.04 1.23 1.62 0.36 7.23 6.45 3.10 3.00 9.14 8.35 ns
–2 0.49 6.24 0.03 1.08 1.42 0.32 6.35 5.66 2.72 2.63 8.02 7.33 ns
16 mA Std. 0.66 7.94 0.04 1.45 1.91 0.43 8.09 7.56 3.74 4.11 10.32 9.80 ns
–1 0.56 6.75 0.04 1.23 1.62 0.36 6.88 6.43 3.18 3.49 8.78 8.33 ns
–2 0.49 5.93 0.03 1.08 1.42 0.32 6.04 5.65 2.79 3.07 7.71 7.32 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-192 Revision 4
Table 2-121 • 1.8 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS
Units
2 mA Std. 0.66 12.10 0.04 1.45 1.91 0.43 9.59 12.10 2.78 1.64 11.83 14.34 ns
–1 0.56 10.30 0.04 1.23 1.62 0.36 8.16 10.30 2.37 1.39 10.06 12.20 ns
–2 0.49 9.04 0.03 1.08 1.42 0.32 7.16 9.04 2.08 1.22 8.83 10.71 ns
4 mA Std. 0.66 7.05 0.04 1.45 1.91 0.43 6.20 7.05 3.25 2.86 8.44 9.29 ns
–1 0.56 6.00 0.04 1.23 1.62 0.36 5.28 6.00 2.76 2.44 7.18 7.90 ns
–2 0.49 5.27 0.03 1.08 1.42 0.32 4.63 5.27 2.43 2.14 6.30 6.94 ns
8 mA Std. 0.66 4.52 0.04 1.45 1.91 0.43 4.47 4.52 3.57 3.47 6.70 6.76 ns
–1 0.56 3.85 0.04 1.23 1.62 0.36 3.80 3.85 3.04 2.95 5.70 5.75 ns
–2 0.49 3.38 0.03 1.08 1.42 0.32 3.33 3.38 2.66 2.59 5.00 5.05 ns
12 mA Std. 0.66 4.12 0.04 1.45 1.91 0.43 4.20 3.99 3.63 3.62 6.43 6.23 ns
–1 0.56 3.51 0.04 1.23 1.62 0.36 3.57 3.40 3.09 3.08 5.47 5.30 ns
–2 0.49 3.08 0.03 1.08 1.42 0.32 3.14 2.98 2.71 2.71 4.81 4.65 ns
16 mA Std. 0.66 3.80 0.04 1.45 1.91 0.43 3.87 3.09 3.73 4.24 6.10 5.32 ns
–1 0.56 3.23 0.04 1.23 1.62 0.36 3.29 2.63 3.18 3.60 5.19 4.53 ns
–2 0.49 2.83 0.03 1.08 1.42 0.32 2.89 2.31 2.79 3.16 4.56 3.98 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Ta ble 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-193
Table 2-122 • 1.8 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
2 mA Std. 0.66 15.53 0.04 1.31 0.43 14.11 15.53 2.78 1.60 16.35 17.77 ns
–1 0.56 13.21 0.04 1.11 0.36 12.01 13.21 2.36 1.36 13.91 15.11 ns
–22 0.49 11.60 0.03 0.98 0.32 10.54 11.60 2.07 1.19 12.21 13.27 ns
4 mA Std. 0.66 10.48 0.04 1.31 0.43 10.41 10.48 3.23 2.73 12.65 12.71 ns
–1 0.56 8.91 0.04 1.11 0.36 8.86 8.91 2.75 2.33 10.76 10.81 ns
–2 0.49 7.82 0.03 0.98 0.32 7.77 7.82 2.41 2.04 9.44 9.49 ns
8 mA Std. 0.66 8.05 0.04 1.31 0.43 8.20 7.84 3.54 3.27 10.43 10.08 ns
–1 0.56 6.85 0.04 1.11 0.36 6.97 6.67 3.01 2.78 8.88 8.57 ns
–2 0.49 6.01 0.03 0.98 0.32 6.12 5.86 2.64 2.44 7.79 7.53 ns
12 mA Std. 0.66 7.50 0.04 1.31 0.43 7.64 7.30 3.61 3.41 9.88 9.53 ns
–1 0.56 6.38 0.04 1.11 0.36 6.50 6.21 3.07 2.90 8.40 8.11 ns
–2 0.49 5.60 0.03 0.98 0.32 5.71 5.45 2.69 2.55 7.38 7.12 ns
16 mA Std. 0.66 7.29 0.04 1.31 0.43 7.23 7.29 3.71 3.95 9.47 9.53 ns
–1 0.56 6.20 0.04 1.11 0.36 6.15 6.20 3.15 3.36 8.06 8.11 ns
–2 0.49 5.45 0.03 0.98 0.32 5.40 5.45 2.77 2.95 7.07 7.12 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-194 Revision 4
Table 2-123 • 1.8 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
2 mA Std. 0.66 11.86 0.04 1.22 0.43 9.14 11.86 2.77 1.66 11.37 14.10 ns
–1 0.56 10.09 0.04 1.04 0.36 7.77 10.09 2.36 1.41 9.67 11.99 ns
–2 0.49 8.86 0.03 0.91 0.32 6.82 8.86 2.07 1.24 8.49 10.53 ns
4 mA Std. 0.66 6.91 0.04 1.22 0.43 5.86 6.91 3.22 2.84 8.10 9.15 ns
–1 0.56 5.88 0.04 1.04 0.36 4.99 5.88 2.74 2.41 6.89 7.78 ns
–2 0.49 5.16 0.03 0.91 0.32 4.38 5.16 2.41 2.12 6.05 6.83 ns
8 mA Std. 0.66 4.45 0.04 1.22 0.43 4.18 4.45 3.53 3.38 6.42 6.68 ns
–1 0.56 3.78 0.04 1.04 0.36 3.56 3.78 3.00 2.88 5.46 5.69 ns
–2 0.49 3.32 0.03 0.91 0.32 3.12 3.32 2.64 2.53 4.79 4.99 ns
12 mA Std. 0.66 3.92 0.04 1.22 0.43 3.93 3.92 3.60 3.52 6.16 6.16 ns
–1 0.56 3.34 0.04 1.04 0.36 3.34 3.34 3.06 3.00 5.24 5.24 ns
–2 0.49 2.93 0.03 0.91 0.32 2.93 2.93 2.69 2.63 4.60 4.60 ns
16 mA Std. 0.66 3.53 0.04 1.22 0.43 3.60 3.04 3.70 4.08 5.84 5.28 ns
–1 0.56 3.01 0.04 1.04 0.36 3.06 2.59 3.15 3.47 4.96 4.49 ns
–2 0.49 2.64 0.03 0.91 0.32 2.69 2.27 2.76 3.05 4.36 3.94 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Tab le 3- 7 on
page 3-9.
Table 2-124 • 1.8 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 15.01 0.04 1.20 0.43 13.15 15.01 1.99 1.99 ns
–1 0.56 12.77 0.04 1.02 0.36 11.19 12.77 1.70 1.70 ns
–2 0.49 11.21 0.03 0.90 0.32 9.82 11.21 1.49 1.49 ns
4 mA Std. 0.66 10.10 0.04 1.20 0.43 9.55 10.10 2.41 2.37 ns
–1 0.56 8.59 0.04 1.02 0.36 8.13 8.59 2.05 2.02 ns
–2 0.49 7.54 0.03 0.90 0.32 7.13 7.54 1.80 1.77 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-195
Table 2-125 • 1.8 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.7 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 11.21 0.04 1.20 0.43 8.53 11.21 1.99 1.21 ns
–1 0.56 9.54 0.04 1.02 0.36 7.26 9.54 1.69 1.03 ns
–2 0.49 8.37 0.03 0.90 0.32 6.37 8.37 1.49 0.90 ns
4 mA Std. 0.66 6.34 0.04 1.20 0.43 5.38 6.34 2.41 2.48 ns
–1 0.56 5.40 0.04 1.02 0.36 4.58 5.40 2.05 2.11 ns
–2 0.49 4.74 0.03 0.90 0.32 4.02 4.74 1.80 1.85 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-196 Revision 4
1.5 V LVCMOS (JESD8-11)
Low-Voltage CMOS for 1.5 V is an extension of the LVCMOS standard (JESD8-5) used for general-
purpose 1.5 V applications. It uses a 1.5 V input buffer and push-pull output buffer.
Table 2-126 • Minimum and Maximum DC Input and Output Levels
1.5 V
LVCMOS VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
Applicable to Pro I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 2 2 16 13 10 10
4 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 4 4 33 25 10 10
6 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 6 6 39 32 10 10
8 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 8 8 55 66 10 10
12 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 12 12 55 66 10 10
Applicable to Advanced I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 2 2 16 13 10 10
4 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 4 4 33 25 10 10
6 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 6 6 39 32 10 10
8 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 8 8 55 66 10 10
12 mA –0.3 0.35 * VCCI 0.65 * VCCI 1.575 0.25 * VCCI 0.75 * VCCI 12 12 55 66 10 10
Applicable to Pro I/O Banks
2 mA –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI 2 2 16 13 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
Figure 2-122 • AC Loading
Table 2-127 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) CLOAD (pF)
0 1.5 0.75 35
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
Test Point
Enable Path
Data Path 35 pF
R = 1 k R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
Fusion Family of Mixed Signal FPGAs
Revision 4 2-197
Timing Characteristics
Table 2-128 • 1.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
2 mA Std. 0.66 14.11 0.04 1.70 2.14 0.43 14.37 13.14 3.40 2.68 16.61 15.37 ns
–1 0.56 12.00 0.04 1.44 1.82 0.36 12.22 11.17 2.90 2.28 14.13 13.08 ns
–2 0.49 10.54 0.03 1.27 1.60 0.32 10.73 9.81 2.54 2.00 12.40 11.48 ns
4 mA Std. 0.66 11.23 0.04 1.70 2.14 0.43 11.44 9.87 3.77 3.36 13.68 12.10 ns
–1 0.56 9.55 0.04 1.44 1.82 0.36 9.73 8.39 3.21 2.86 11.63 10.29 ns
–2 0.49 8.39 0.03 1.27 1.60 0.32 8.54 7.37 2.81 2.51 10.21 9.04 ns
8 mA Std. 0.66 10.45 0.04 1.70 2.14 0.43 10.65 9.24 3.84 3.55 12.88 11.48 ns
–1 0.56 8.89 0.04 1.44 1.82 0.36 9.06 7.86 3.27 3.02 10.96 9.76 ns
–2 0.49 7.81 0.03 1.27 1.60 0.32 7.95 6.90 2.87 2.65 9.62 8.57 ns
12 mA Std. 0.66 10.02 0.04 1.70 2.14 0.43 10.20 9.23 3.97 4.22 12.44 11.47 ns
–1 0.56 8.52 0.04 1.44 1.82 0.36 8.68 7.85 3.38 3.59 10.58 9.75 ns
–2 0.49 7.48 0.03 1.27 1.60 0.32 7.62 6.89 2.97 3.15 9.29 8.56 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on page 3-9.
Table 2-129 • 1.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Pro I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tPYS
tEOU
TtZL tZH tLZ tHZ tZLS tZHS
Units
2 mA Std. 0.66 8.53 0.04 1.70 2.14 0.43 7.26 8.53 3.39 2.79 9.50 10.77 ns
–1 0.56 7.26 0.04 1.44 1.82 0.36 6.18 7.26 2.89 2.37 8.08 9.16 ns
–2 0.49 6.37 0.03 1.27 1.60 0.32 5.42 6.37 2.53 2.08 7.09 8.04 ns
4 mA Std. 0.66 5.41 0.04 1.70 2.14 0.43 5.22 5.41 3.75 3.48 7.45 7.65 ns
–1 0.56 4.60 0.04 1.44 1.82 0.36 4.44 4.60 3.19 2.96 6.34 6.50 ns
–2 0.49 4.04 0.03 1.27 1.60 0.32 3.89 4.04 2.80 2.60 5.56 5.71 ns
8 mA Std. 0.66 4.80 0.04 1.70 2.14 0.43 4.89 4.75 3.83 3.67 7.13 6.98 ns
–1 0.56 4.09 0.04 1.44 1.82 0.36 4.16 4.04 3.26 3.12 6.06 5.94 ns
–2 0.49 3.59 0.03 1.27 1.60 0.32 3.65 3.54 2.86 2.74 5.32 5.21 ns
12 mA Std. 0.66 4.42 0.04 1.70 2.14 0.43 4.50 3.62 3.96 4.37 6.74 5.86 ns
–1 0.56 3.76 0.04 1.44 1.82 0.36 3.83 3.08 3.37 3.72 5.73 4.98 ns
–2 0.49 3.30 0.03 1.27 1.60 0.32 3.36 2.70 2.96 3.27 5.03 4.37 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Ta ble 3-7 on
page 3-9.
Device Architecture
2-198 Revision 4
Table 2-130 • 1.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
2 mA Std. 0.66 12.78 0.04 1.31 0.43 12.81 12.78 3.40 2.64 15.05 15.02 ns
–1 0.56 10.87 0.04 1.11 0.36 10.90 10.87 2.89 2.25 12.80 12.78 ns
–2 0.49 9.55 0.03 0.98 0.32 9.57 9.55 2.54 1.97 11.24 11.22 ns
4 mA Std. 0.66 10.01 0.04 1.31 0.43 10.19 9.55 3.75 3.27 12.43 11.78 ns
–1 0.56 8.51 0.04 1.11 0.36 8.67 8.12 3.19 2.78 10.57 10.02 ns
–2 0.49 7.47 0.03 0.98 0.32 7.61 7.13 2.80 2.44 9.28 8.80 ns
8 mA Std. 0.66 9.33 0.04 1.31 0.43 9.51 8.89 3.83 3.43 11.74 11.13 ns
–1 0.56 7.94 0.04 1.11 0.36 8.09 7.56 3.26 2.92 9.99 9.47 ns
–2 0.49 6.97 0.03 0.98 0.32 7.10 6.64 2.86 2.56 8.77 8.31 ns
12 mA Std. 0.66 8.91 0.04 1.31 0.43 9.07 8.89 3.95 4.05 11.31 11.13 ns
–1 0.56 7.58 0.04 1.11 0.36 7.72 7.57 3.36 3.44 9.62 9.47 ns
–2 0.49 6.65 0.03 0.98 0.32 6.78 6.64 2.95 3.02 8.45 8.31 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Table 2-131 • 1.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Advanced I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
2 mA Std. 0.66 8.36 0.04 1.44 0.43 6.82 8.36 3.39 2.77 9.06 10.60 ns
–1 0.56 7.11 0.04 1.22 0.36 5.80 7.11 2.88 2.35 7.71 9.02 ns
–2 0.49 6.24 0.03 1.07 0.32 5.10 6.24 2.53 2.06 6.76 7.91 ns
4 mA Std. 0.66 5.31 0.04 1.44 0.43 4.85 5.31 3.74 3.40 7.09 7.55 ns
–1 0.56 4.52 0.04 1.22 0.36 4.13 4.52 3.18 2.89 6.03 6.42 ns
–2 0.49 3.97 0.03 1.07 0.32 3.62 3.97 2.79 2.54 5.29 5.64 ns
8 mA Std. 0.66 4.67 0.04 1.44 0.43 4.55 4.67 3.82 3.56 6.78 6.90 ns
–1 0.56 3.97 0.04 1.22 0.36 3.87 3.97 3.25 3.03 5.77 5.87 ns
–2 0.49 3.49 0.03 1.07 0.32 3.40 3.49 2.85 2.66 5.07 5.16 ns
12 mA Std. 0.66 4.08 0.04 1.44 0.43 4.15 3.58 3.94 4.20 6.39 5.81 ns
–1 0.56 3.47 0.04 1.22 0.36 3.53 3.04 3.36 3.58 5.44 4.95 ns
–2 0.49 3.05 0.03 1.07 0.32 3.10 2.67 2.95 3.14 4.77 4.34 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Tab le 3- 7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-199
Table 2-132 • 1.5 V LVCMOS Low Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 12.33 0.04 1.42 0.43 11.79 12.33 2.45 2.32 ns
–1 0.56 10.49 0.04 1.21 0.36 10.03 10.49 2.08 1.98 ns
–2 0.49 9.21 0.03 1.06 0.32 8.81 9.21 1.83 1.73 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Table 2-133 • 1.5 V LVCMOS High Slew
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V
Applicable to Standard I/Os
Drive
Strength
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ Units
2 mA Std. 0.66 7.65 0.04 1.42 0.43 6.31 7.65 2.45 2.45 ns
–1 0.56 6.50 0.04 1.21 0.36 5.37 6.50 2.08 2.08 ns
–2 0.49 5.71 0.03 1.06 0.32 4.71 5.71 1.83 1.83 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3 - 7 on
page 3-9.
Device Architecture
2-200 Revision 4
3.3 V PCI, 3.3 V PCI-X
The Peripheral Component Interface for 3.3 V standard specifies support for 33 MHz and 66 MHz PCI
Bus applications.
AC loadings are defined per the PCI/PCI-X specifications for the datapath; Microsemi loadings for enable
path characterization are described in Figure 2-123.
AC loadings are defined per PCI/PCI-X specifications for the data path; Microsemi loading for tristate is
described in Table 2-135.
Table 2-134 • Minimum and Maximum DC Input and Output Levels
3.3 V PCI/PCI-X VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
Per PCI
specification
Per PCI curves 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-123 AC Loading
Test Point
Enable Path
R = 1 k
Test Point
Data Path
R = 25 R to VCCI for tDP (F)
R to GND for tDP (R) R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
10 pF for tZH / tZHS / tZL / tZLS
10 pF for tHZ / tLZ
Table 2-135 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) CLOAD (pF)
0 3.3 0.285 * VCCI for tDP(R)
0.615 * VCCI for tDP(F)
–10
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-201
Timing Characteristics
Table 2-136 • 3.3 V PCI/PCI-X
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Pro I/Os
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.81 0.04 1.05 1.67 0.43 2.86 2.00 3.28 3.61 5.09 4.23 ns
–1 0.56 2.39 0.04 0.89 1.42 0.36 2.43 1.70 2.79 3.07 4.33 3.60 ns
–2 0.49 2.09 0.03 0.78 1.25 0.32 2.13 1.49 2.45 2.70 3.80 3.16 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Table 2-137 • 3.3 V PCI/PCI-X
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Advanced I/Os
Speed
Grade tDOUT tDP tDIN tPY tPYS tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.68 0.04 0.86 0.43 2.73 1.95 3.21 3.58 4.97 4.19 0.66 ns
–1 0.56 2.28 0.04 0.73 0.36 2.32 1.66 2.73 3.05 4.22 3.56 0.56 ns
–2 0.49 2.00 0.03 0.65 0.32 2.04 1.46 2.40 2.68 3.71 3.13 0.49 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-202 Revision 4
Voltage Referenced I/O Characteristics
3.3 V GTL
Gunning Transceiver Logic is a high-speed bus standard (JESD8-3). It provides a differential amplifier
input buffer and an open-drain output buffer. The VCCI pin should be connected to 3.3 V.
Timing Characteristics
Table 2-138 • Minimum and Maximum DC Input and Output Levels
3.3 V GTL VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
20 mA3–0.3 VREF – 0.05 VREF + 0.05 3.6 0.4 20 20 181 268 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-124 • AC Loading
Table 2-139 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.05 VREF + 0.05 0.8 0.8 1.2 10
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
10 pF
25
GTL
VTT
Table 2-140 • 3.3 V GTL
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V, VREF = 0.8 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.08 0.04 2.93 0.43 2.04 2.08 4.27 4.31 ns
–1 0.56 1.77 0.04 2.50 0.36 1.73 1.77 3.63 3.67 ns
–2 0.49 1.55 0.03 2.19 0.32 1.52 1.55 3.19 3.22 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-203
2.5 V GTL
Gunning Transceiver Logic is a high-speed bus standard (JESD8-3). It provides a differential amplifier
input buffer and an open-drain output buffer. The VCCI pin should be connected to 2.5 V.
Timing Characteristics
Table 2-141 • Minimum and Maximum DC Input and Output Levels
2.5 GTL VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
20 mA3–0.3 VREF – 0.05 VREF + 0.05 3.6 0.4 20 20 124 169 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-125 AC Loading
Table 2-142 AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.05 VREF + 0.05 0.8 0.8 1.2 10
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
10 pF
25
GTL
VTT
Table 2-143 • 2.5 V GTL
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V, VREF = 0.8 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.13 0.04 2.46 0.43 2.16 2.13 4.40 4.36 ns
–1 0.56 1.81 0.04 2.09 0.36 1.84 1.81 3.74 3.71 ns
–2 0.49 1.59 0.03 1.83 0.32 1.61 1.59 3.28 3.26 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Ta ble 3- 7 on
page 3-9.
Device Architecture
2-204 Revision 4
3.3 V GTL+
Gunning Transceiver Logic Plus is a high-speed bus standard (JESD8-3). It provides a differential
amplifier input buffer and an open-drain output buffer. The VCCI pin should be connected to 3.3 V.
Timing Characteristics
Table 2-144 • Minimum and Maximum DC Input and Output Levels
3.3 V GTL+ VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
35 mA –0.3 VREF – 0.1 VREF + 0.1 3.6 0.6 35 35 181 268 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-126 AC Loading
Table 2-145 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.1 VREF + 0.1 1.0 1.0 1.5 10
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
10 pF
25
GTL+
VTT
Table 2-146 • 3.3 V GTL+
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V, VREF = 1.0 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.06 0.04 1.59 0.43 2.09 2.06 4.33 4.29 ns
–1 0.56 1.75 0.04 1.35 0.36 1.78 1.75 3.68 3.65 ns
–2 0.49 1.53 0.03 1.19 0.32 1.56 1.53 3.23 3.20 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-205
2.5 V GTL+
Gunning Transceiver Logic Plus is a high-speed bus standard (JESD8-3). It provides a differential
amplifier input buffer and an open-drain output buffer. The VCCI pin should be connected to 2.5 V.
Timing Characteristics
Table 2-147 • Minimum and Maximum DC Input and Output Levels
2.5 V
GTL+ VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
33 mA –0.3 VREF – 0.1 VREF + 0.1 3.6 0.6 33 33 124 169 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-127 • AC Loading
Table 2-148 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.1 VREF + 0.1 1.0 1.0 1.5 10
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
10 pF
25
GTL+
VTT
Table 2-149 • 2.5 V GTL+
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V, VREF = 1.0 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.21 0.04 1.51 0.43 2.25 2.10 4.48 4.34 ns
–1 0.56 1.88 0.04 1.29 0.36 1.91 1.79 3.81 3.69 ns
–2 0.49 1.65 0.03 1.13 0.32 1.68 1.57 3.35 4.34 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-206 Revision 4
HSTL Class I
High-Speed Transceiver Logic is a general-purpose high-speed 1.5 V bus standard (EIA/JESD8-6).
Fusion devices support Class I. This provides a differential amplifier input buffer and a push-pull output
buffer.
Timing Characteristics
Table 2-150 • Minimum and Maximum DC Input and Output Levels
HSTL
Class I VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
8 mA –0.3 VREF – 0.1 VREF + 0.1 3.6 0.4 VCCI – 0.4 8 8 39 32 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-128 • AC Loading
Table 2-151 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.1 VREF + 0.1 0.75 0.75 0.75 20
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
T
est Point 20 p
F
50
HSTL
Class I
VTT
Table 2-152 • HSTL Class I
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V, VREF = 0.75 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 3.18 0.04 2.12 0.43 3.24 3.14 5.47 5.38 ns
–1 0.56 2.70 0.04 1.81 0.36 2.75 2.67 4.66 4.58 ns
–2 0.49 2.37 0.03 1.59 0.32 2.42 2.35 4.09 4.02 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-207
HSTL Class II
High-Speed Transceiver Logic is a general-purpose high-speed 1.5 V bus standard (EIA/JESD8-6).
Fusion devices support Class II. This provides a differential amplifier input buffer and a push-pull output
buffer.
Timing Characteristics
Table 2-153 • Minimum and Maximum DC Input and Output Levels
HSTL Class II VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
15 mA3–0.3 VREF – 0.1 VREF + 0.1 3.6 0.4 VCCI – 0.4 15 15 55 66 10 10
Note:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Output drive strength is below JEDEC specification.
Figure 2-129 • AC Loading
Table 2-154 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.1 VREF + 0.1 0.75 0.75 0.75 20
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
20 pF
25
HSTL
Class II
VTT
Table 2-155 • HSTL Class II
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 1.4 V, VREF = 0.75 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 3.02 0.04 2.12 0.43 3.08 2.71 5.32 4.95 ns
–1 0.56 2.57 0.04 1.81 0.36 2.62 2.31 4.52 4.21 ns
–2 0.49 2.26 0.03 1.59 0.32 2.30 2.03 3.97 3.70 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-208 Revision 4
SSTL2 Class I
Stub-Speed Terminated Logic for 2.5 V memory bus standard (JESD8-9). Fusion devices support Class
I. This provides a differential amplifier input buffer and a push-pull output buffer.
Timing Characteristics
Table 2-156 • Minimum and Maximum DC Input and Output Levels
SSTL2 Class I VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
15 mA –0.3 VREF – 0.2 VREF + 0.2 3.6 0.54 VCCI – 0.62 15 15 87 83 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-130 • AC Loading
Table 2-157 AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.2 VREF + 0.2 1.25 1.25 1.25 30
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
30 pF
50
25
SSTL2
Class I
VTT
Table 2-158 • SSTL 2 Class I
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V, VREF = 1.25 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.13 0.04 1.33 0.43 2.17 1.85 4.40 4.08 ns
–1 0.56 1.81 0.04 1.14 0.36 1.84 1.57 3.74 3.47 ns
–2 0.49 1.59 0.03 1.00 0.32 1.62 1.38 3.29 3.05 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-209
SSTL2 Class II
Stub-Speed Terminated Logic for 2.5 V memory bus standard (JESD8-9). Fusion devices support Class
II. This provides a differential amplifier input buffer and a push-pull output buffer.
Timing Characteristics
Table 2-159 • Minimum and Maximum DC Input and Output Levels
SSTL2 Class II VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
18 mA –0.3 VREF – 0.2 VREF + 0.2 3.6 0.35 VCCI – 0.43 18 18 124 169 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-131 • AC Loading
Table 2-160 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.2 VREF + 0.2 1.25 1.25 1.25 30
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
30 pF
25
25
SSTL2
Class II
VTT
Table 2-161 • SSTL 2 Class II
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V, VREF = 1.25 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.17 0.04 1.33 0.43 2.21 1.77 4.44 4.01 ns
–1 0.56 1.84 0.04 1.14 0.36 1.88 1.51 3.78 3.41 ns
–2 0.49 1.62 0.03 1.00 0.32 1.65 1.32 3.32 2.99 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-210 Revision 4
SSTL3 Class I
Stub-Speed Terminated Logic for 3.3 V memory bus standard (JESD8-8). Fusion devices support Class
I. This provides a differential amplifier input buffer and a push-pull output buffer.
Timing Characteristics
Table 2-162 • Minimum and Maximum DC Input and Output Levels
SSTL3 Class I VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive
Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
14 mA –0.3 VREF – 0.2 VREF + 0.2 3.6 0.7 VCCI – 1.1 14 14 54 51 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-132 • AC Loading
Table 2-163 AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.2 VREF + 0.2 1.5 1.5 1.485 30
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
30 pF
50
25
SSTL3
Class I
VTT
Table 2-164 • SSTL3 Class I
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V, VREF = 1.5 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.31 0.04 1.25 0.43 2.35 1.84 4.59 4.07 ns
–1 0.56 1.96 0.04 1.06 0.36 2.00 1.56 3.90 3.46 ns
–2 0.49 1.72 0.03 0.93 0.32 1.75 1.37 3.42 3.04 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-211
SSTL3 Class II
Stub-Speed Terminated Logic for 3.3 V memory bus standard (JESD8-8). Fusion devices support Class
II. This provides a differential amplifier input buffer and a push-pull output buffer.
Timing Characteristics
Table 2-165 • Minimum and Maximum DC Input and Output Levels
SSTL3 Class II VIL VIH VOL VOH IOL IOH IOSL IOSH IIL1IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
VmAmA
Max.
mA3
Max.
mA3µA4µA4
21 mA –0.3 VREF – 0.2 VREF + 0.2 3.6 0.5 VCCI – 0.9 21 21 109 103 10 10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
Figure 2-133 • AC Loading
Table 2-166 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V) VTT (typ.) (V) CLOAD (pF)
VREF – 0.2 VREF + 0.2 1.5 1.5 1.485 30
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Test Point
30 pF
25
25
SSTL3
Class II
VTT
Table 2-167 • SSTL3- Class II
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V, VREF = 1.5 V
Speed
Grade tDOUT tDP tDIN tPY tEOUT tZL tZH tLZ tHZ tZLS tZHS Units
Std. 0.66 2.07 0.04 1.25 0.43 2.10 1.67 4.34 3.91 ns
–1 0.56 1.76 0.04 1.06 0.36 1.79 1.42 3.69 3.32 ns
–2 0.49 1.54 0.03 0.93 0.32 1.57 1.25 3.24 2.92 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-212 Revision 4
Differential I/O Characteristics
Configuration of the I/O modules as a differential pair is handled by the Microsemi Designer
software when the user instantiates a differential I/O macro in the design.
Differential I/Os can also be used in conjunction with the embedded Input Register (InReg), Output
Register (OutReg), Enable Register (EnReg), and Double Data Rate (DDR). However, there is no
support for bidirectional I/Os or tristates with these standards.
LVDS
Low-Voltage Differential Signal (ANSI/TIA/EIA-644) is a high-speed differential I/O standard. It requires
that one data bit be carried through two signal lines, so two pins are needed. It also requires external
resistor termination.
The full implementation of the LVDS transmitter and receiver is shown in an example in Figure 2-134.
The building blocks of the LVDS transmitter–receiver are one transmitter macro, one receiver macro,
three board resistors at the transmitter end, and one resistor at the receiver end. The values for the three
driver resistors are different from those used in the LVPECL implementation because the output standard
specifications are different.
Figure 2-134 • LVDS Circuit Diagram and Board-Level Implementation
Table 2-168 • Minimum and Maximum DC Input and Output Levels
DC Parameter Description Min. Typ. Max. Units
VCCI Supply Voltage 2.375 2.5 2.625 V
VOL Output Low Voltage 0.9 1.075 1.25 V
VOH Input High Voltage 1.25 1.425 1.6 V
IOL 1Output Low Voltage 0.65 0.91 1.16 mA
IOH 1Output High Voltage 0.65 0.91 1.16 mA
VI Input Voltage 0 2.925 V
IIL 2,3 Input Low Voltage 10 A
IIH 2,4 Input High Voltage 10 A
VODIFF Differential Output Voltage 250 350 450 mV
VOCM Output Common Mode Voltage 1.125 1.25 1.375 V
VICM Input Common Mode Voltage 0.05 1.25 2.35 V
VIDIFF Input Differential Voltage 100 350 mV
Notes:
1. IOL/IOH defined by VODIFF/(Resistor Network)
2. Currents are measured at 85°C junction temperature.
3. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
4. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
140 100
ZO = 50
ZO = 50
165
165
+
P
N
P
N
INBUF_LVDS
OUTBUF_LVDS
FPGA FPGA
Bourns Part Number: CAT16-LV4F12
Fusion Family of Mixed Signal FPGAs
Revision 4 2-213
Timing Characteristics
BLVDS/M-LVDS
Bus LVDS (BLVDS) and Multipoint LVDS (M-LVDS) specifications extend the existing LVDS standard to
high-performance multipoint bus applications. Multidrop and multipoint bus configurations can contain
any combination of drivers, receivers, and transceivers. Microsemi LVDS drivers provide the higher drive
current required by BLVDS and M-LVDS to accommodate the loading. The driver requires series
terminations for better signal quality and to control voltage swing. Termination is also required at both
ends of the bus, since the driver can be located anywhere on the bus. These configurations can be
implemented using TRIBUF_LVDS and BIBUF_LVDS macros along with appropriate terminations.
Multipoint designs using Microsemi LVDS macros can achieve up to 200 MHz with a maximum of 20
loads. A sample application is given in Figure 2-135. The input and output buffer delays are available in
the LVDS section in Table 2-171.
Example: For a bus consisting of 20 equidistant loads, the following terminations provide the required
differential voltage, in worst-case industrial operating conditions at the farthest receiver: RS=60 and
RT=70, given Z0=50 (2") and Zstub =50 (~1.5").
Table 2-169 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V)
1.075 1.325 Cross point
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
Table 2-170 • LVDS
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 2.3 V
Applicable to Pro I/Os
Speed Grade tDOUT tDP tDIN tPY Units
Std. 0.66 2.10 0.04 1.82 ns
–1 0.56 1.79 0.04 1.55 ns
–2 0.49 1.57 0.03 1.36 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Figure 2-135 • BLVDS/M-LVDS Multipoint Application Using LVDS I/O Buffers
...
R
T
R
T
BIBUF_LVDS
R
+
-
T
+
-
R
+
-
T
+
-
D
+
-
EN EN EN EN EN
Receiver Transceiver Receiver TransceiverDriver
R
S
R
S
R
S
R
S
R
S
R
S
R
S
R
S
R
S
R
S
Z
stub
Z
stub
Z
stub
Z
stub
Z
stub
Z
stub
Z
stub
Z
stub
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Z
0
Device Architecture
2-214 Revision 4
LVPECL
Low-Voltage Positive Emitter-Coupled Logic (LVPECL) is another differential I/O standard. It requires
that one data bit be carried through two signal lines. Like LVDS, two pins are needed. It also requires
external resistor termination.
The full implementation of the LVDS transmitter and receiver is shown in an example in Figure 2-136.
The building blocks of the LVPECL transmitter–receiver are one transmitter macro, one receiver macro,
three board resistors at the transmitter end, and one resistor at the receiver end. The values for the three
driver resistors are different from those used in the LVDS implementation because the output standard
specifications are different.
Timing Characteristics
Figure 2-136 • LVPECL Circuit Diagram and Board-Level Implementation
Table 2-171 • Minimum and Maximum DC Input and Output Levels
DC Parameter Description Min. Max. Min. Max. Min. Max. Units
VCCI Supply Voltage 3.0 3.3 3.6 V
VOL Output Low Voltage 0.96 1.27 1.06 1.43 1.30 1.57 V
VOH Output High Voltage 1.8 2.11 1.92 2.28 2.13 2.41 V
VIL, VIH Input Low, Input High Voltages 0 3.6 0 3.6 0 3.6 V
VODIFF Differential Output Voltage 0.625 0.97 0.625 0.97 0.625 0.97 V
VOCM Output Common Mode Voltage 1.762 1.98 1.762 1.98 1.762 1.98 V
VICM Input Common Mode Voltage 1.01 2.57 1.01 2.57 1.01 2.57 V
VIDIFF Input Differential Voltage 300 300 300 mV
Table 2-172 • AC Waveforms, Measuring Points, and Capacitive Loads
Input Low (V) Input High (V) Measuring Point* (V) VREF (typ.) (V)
1.64 1.94 Cross point
Note: *Measuring point = Vtrip. See Table 2-90 on page 2-169 for a complete table of trip points.
187 W 100
ZO = 50
ZO = 50
100
100
+
P
N
P
N
INBUF_LVPECL
OUTBUF_LVPECL
FPGA FPGA
Bourns Part Number: CAT16-PC4F12
Table 2-173 LVPECL
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V,
Worst-Case VCCI = 3.0 V
Applicable to Pro I/Os
Speed Grade tDOUT tDP tDIN tPY Units
Std. 0.66 2.14 0.04 1.63 ns
–1 0.56 1.82 0.04 1.39 ns
–2 0.49 1.60 0.03 1.22 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-215
I/O Register Specifications
Fully Registered I/O Buffers with Synchronous Enable and Asynchronous Preset
Figure 2-137 • Timing Model of Registered I/O Buffers with Synchronous Enable and Asynchronous Preset
INBUF
INBUF INBUF
TRIBUF
CLKBUF
INBUF
INBUF
CLKBUF
Data Input I/O Register with:
Active High Enable
Active High Preset
Positive Edge Triggered
Data Output Register and
Enable Output Register with:
Active High Enable
Active High Preset
Postive Edge Triggered
Pad Out
CLK
Enable
Preset
Data_out
Data
X
X
X
X
X
X
X
X
X
X
X
X
X
X
EOUT
DOUT
Enable
CLK
DQ
DFN1E1P1
PRE
DQ
DFN1E1P1
PRE
DQ
DFN1E1P1
PRE
D_Enable
A
B
C
D
EE
E
EF
G
H
I
J
L
K
YCore
Array
Device Architecture
2-216 Revision 4
Table 2-174 • Parameter Definitions and Measuring Nodes
Parameter
Name Parameter Definition
Measuring Nodes
(from, to)*
tOCLKQ Clock-to-Q of the Output Data Register H, DOUT
tOSUD Data Setup Time for the Output Data Register F, H
tOHD Data Hold Time for the Output Data Register F, H
tOSUE Enable Setup Time for the Output Data Register G, H
tOHE Enable Hold Time for the Output Data Register G, H
tOPRE2Q Asynchronous Preset-to-Q of the Output Data Register L,DOUT
tOREMPRE Asynchronous Preset Removal Time for the Output Data Register L, H
tORECPRE Asynchronous Preset Recovery Time for the Output Data Register L, H
tOECLKQ Clock-to-Q of the Output Enable Register H, EOUT
tOESUD Data Setup Time for the Output Enable Register J, H
tOEHD Data Hold Time for the Output Enable Register J, H
tOESUE Enable Setup Time for the Output Enable Register K, H
tOEHE Enable Hold Time for the Output Enable Register K, H
tOEPRE2Q Asynchronous Preset-to-Q of the Output Enable Register I, EOUT
tOEREMPRE Asynchronous Preset Removal Time for the Output Enable Register I, H
tOERECPRE Asynchronous Preset Recovery Time for the Output Enable Register I, H
tICLKQ Clock-to-Q of the Input Data Register A, E
tISUD Data Setup Time for the Input Data Register C, A
tIHD Data Hold Time for the Input Data Register C, A
tISUE Enable Setup Time for the Input Data Register B, A
tIHE Enable Hold Time for the Input Data Register B, A
tIPRE2Q Asynchronous Preset-to-Q of the Input Data Register D, E
tIREMPRE Asynchronous Preset Removal Time for the Input Data Register D, A
tIRECPRE Asynchronous Preset Recovery Time for the Input Data Register D, A
Note: *See Figure 2-137 on page 2-215 for more information.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-217
Fully Registered I/O Buffers with Synchronous Enable and Asynchronous Clear
Figure 2-138 • Timing Model of the Registered I/O Buffers with Synchronous Enable and Asynchronous Clear
Core
Array
Data Input I/O Register with
Active High Enable
Active High Clear
Positive Edge Triggered Data Output Register and
Enable Output Register with
Active High Enable
Active High Clear
Positive Edge Triggered
Enable
CLK
Pad Out
CLK
Enable
CLR
Data_out
Data
Y
AA
EOUT
DOUT
DQ
DFN1E1C1
E
CLR
DQ
DFN1E1C1
E
CLR
DQ
DFN1E1C1
E
CLR
D_Enable
BB
CC
DD
EE
FF
GG
LL
HH
JJ
KK
CLKBUF
INBUF
INBUF
TRIBUF
INBUF INBUF CLKBUF
INBUF
Device Architecture
2-218 Revision 4
Table 2-175 • Parameter Definitions and Measuring Nodes
Parameter Name Parameter Definition
Measuring Nodes
(from, to)*
tOCLKQ Clock-to-Q of the Output Data Register HH, DOUT
tOSUD Data Setup Time for the Output Data Register FF, HH
tOHD Data Hold Time for the Output Data Register FF, HH
tOSUE Enable Setup Time for the Output Data Register GG, HH
tOHE Enable Hold Time for the Output Data Register GG, HH
tOCLR2Q Asynchronous Clear-to-Q of the Output Data Register LL, DOUT
tOREMCLR Asynchronous Clear Removal Time for the Output Data Register LL, HH
tORECCLR Asynchronous Clear Recovery Time for the Output Data Register LL, HH
tOECLKQ Clock-to-Q of the Output Enable Register HH, EOUT
tOESUD Data Setup Time for the Output Enable Register JJ, HH
tOEHD Data Hold Time for the Output Enable Register JJ, HH
tOESUE Enable Setup Time for the Output Enable Register KK, HH
tOEHE Enable Hold Time for the Output Enable Register KK, HH
tOECLR2Q Asynchronous Clear-to-Q of the Output Enable Register II, EOUT
tOEREMCLR Asynchronous Clear Removal Time for the Output Enable Register II, HH
tOERECCLR Asynchronous Clear Recovery Time for the Output Enable Register II, HH
tICLKQ Clock-to-Q of the Input Data Register AA, EE
tISUD Data Setup Time for the Input Data Register CC, AA
tIHD Data Hold Time for the Input Data Register CC, AA
tISUE Enable Setup Time for the Input Data Register BB, AA
tIHE Enable Hold Time for the Input Data Register BB, AA
tICLR2Q Asynchronous Clear-to-Q of the Input Data Register DD, EE
tIREMCLR Asynchronous Clear Removal Time for the Input Data Register DD, AA
tIRECCLR Asynchronous Clear Recovery Time for the Input Data Register DD, AA
Note: *See Figure 2-138 on page 2-217 for more information.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-219
Input Register
Timing Characteristics
Figure 2-139 • Input Register Timing Diagram
50%
Preset
Clear
Out_1
CLK
Data
Enable
t
ISUE
50%
50%
t
ISUD
t
IHD
50% 50%
t
ICLKQ
10
t
IHE
t
IRECPRE
t
IREMPRE
t
IRECCLR
t
IREMCLR
t
IWCLR
t
IWPRE
t
IPRE2Q
t
ICLR2Q
t
ICKMPWH
t
ICKMPWL
50% 50%
50% 50% 50%
50% 50%
50% 50% 50% 50% 50% 50%
50%
Table 2-176 • Input Data Register Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tICLKQ Clock-to-Q of the Input Data Register 0.24 0.27 0.32 ns
tISUD Data Setup Time for the Input Data Register 0.26 0.30 0.35 ns
tIHD Data Hold Time for the Input Data Register 0.00 0.00 0.00 ns
tISUE Enable Setup Time for the Input Data Register 0.37 0.42 0.50 ns
tIHE Enable Hold Time for the Input Data Register 0.00 0.00 0.00 ns
tICLR2Q Asynchronous Clear-to-Q of the Input Data Register 0.45 0.52 0.61 ns
tIPRE2Q Asynchronous Preset-to-Q of the Input Data Register 0.45 0.52 0.61 ns
tIREMCLR Asynchronous Clear Removal Time for the Input Data Register 0.00 0.00 0.00 ns
tIRECCLR Asynchronous Clear Recovery Time for the Input Data Register 0.22 0.25 0.30 ns
tIREMPRE Asynchronous Preset Removal Time for the Input Data Register 0.00 0.00 0.00 ns
tIRECPRE Asynchronous Preset Recovery Time for the Input Data Register 0.22 0.25 0.30 ns
tIWCLR Asynchronous Clear Minimum Pulse Width for the Input Data Register 0.22 0.25 0.30 ns
tIWPRE Asynchronous Preset Minimum Pulse Width for the Input Data Register 0.22 0.25 0.30 ns
tICKMPWH Clock Minimum Pulse Width High for the Input Data Register 0.36 0.41 0.48 ns
tICKMPWL Clock Minimum Pulse Width Low for the Input Data Register 0.32 0.37 0.43 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-220 Revision 4
Output Register
Timing Characteristics
Figure 2-140 Output Register Timing Diagram
Preset
Clear
DOUT
CLK
Data_out
Enable
t
OSUE
50%
50%
t
OSUD
t
OHD
50% 50%
t
OCLKQ
10
t
OHE
t
ORECPRE
t
OREMPRE
t
ORECCLR
t
OREMCLR
t
OWCLR
t
OWPRE
t
OPRE2Q
t
OCLR2Q
t
OCKMPWH
t
OCKMPWL
50% 50%
50% 50% 50%
50% 50%
50% 50% 50% 50% 50% 50%
50%
50%
Table 2-177 • Output Data Register Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tOCLKQ Clock-to-Q of the Output Data Register 0.59 0.67 0.79 ns
tOSUD Data Setup Time for the Output Data Register 0.31 0.36 0.42 ns
tOHD Data Hold Time for the Output Data Register 0.00 0.00 0.00 ns
tOSUE Enable Setup Time for the Output Data Register 0.44 0.50 0.59 ns
tOHE Enable Hold Time for the Output Data Register 0.00 0.00 0.00 ns
tOCLR2Q Asynchronous Clear-to-Q of the Output Data Register 0.80 0.91 1.07 ns
tOPRE2Q Asynchronous Preset-to-Q of the Output Data Register 0.80 0.91 1.07 ns
tOREMCLR Asynchronous Clear Removal Time for the Output Data Register 0.00 0.00 0.00 ns
tORECCLR Asynchronous Clear Recovery Time for the Output Data Register 0.22 0.25 0.30 ns
tOREMPRE Asynchronous Preset Removal Time for the Output Data Register 0.00 0.00 0.00 ns
tORECPRE Asynchronous Preset Recovery Time for the Output Data Register 0.22 0.25 0.30 ns
tOWCLR Asynchronous Clear Minimum Pulse Width for the Output Data Register 0.22 0.25 0.30 ns
tOWPRE Asynchronous Preset Minimum Pulse Width for the Output Data
Register
0.22 0.25 0.30 ns
tOCKMPWH Clock Minimum Pulse Width High for the Output Data Register 0.36 0.41 0.48 ns
tOCKMPWL Clock Minimum Pulse Width Low for the Output Data Register 0.32 0.37 0.43 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-221
Output Enable Register
Timing Characteristics
Figure 2-141 • Output Enable Register Timing Diagram
50%
Preset
Clear
EOUT
CLK
D_Enable
Enable
t
OESUE
50%
50%
t
OESUD
t
OEHD
50% 50%
t
OECLKQ
10
t
OEHE
t
OERECPRE
t
OEREMPRE
t
OERECCLR
t
OEREMCLR
t
OEWCLR
t
OEWPRE
t
OEPRE2Q
t
OECLR2Q
t
OECKMPWH
t
OECKMPWL
50% 50%
50% 50% 50%
50% 50%
50% 50% 50% 50% 50% 50%
50%
Table 2-178 • Output Enable Register Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tOECLKQ Clock-to-Q of the Output Enable Register 0.44 0.51 0.59 ns
tOESUD Data Setup Time for the Output Enable Register 0.31 0.36 0.42 ns
tOEHD Data Hold Time for the Output Enable Register 0.00 0.00 0.00 ns
tOESUE Enable Setup Time for the Output Enable Register 0.44 0.50 0.58 ns
tOEHE Enable Hold Time for the Output Enable Register 0.00 0.00 0.00 ns
tOECLR2Q Asynchronous Clear-to-Q of the Output Enable Register 0.67 0.76 0.89 ns
tOEPRE2Q Asynchronous Preset-to-Q of the Output Enable Register 0.67 0.76 0.89 ns
tOEREMCLR Asynchronous Clear Removal Time for the Output Enable Register 0.00 0.00 0.00 ns
tOERECCLR Asynchronous Clear Recovery Time for the Output Enable Register 0.22 0.25 0.30 ns
tOEREMPRE Asynchronous Preset Removal Time for the Output Enable Register 0.00 0.00 0.00 ns
tOERECPRE Asynchronous Preset Recovery Time for the Output Enable Register 0.22 0.25 0.30 ns
tOEWCLR Asynchronous Clear Minimum Pulse Width for the Output Enable
Register
0.22 0.25 0.30 ns
tOEWPRE Asynchronous Preset Minimum Pulse Width for the Output Enable
Register
0.22 0.25 0.30 ns
tOECKMPWH Clock Minimum Pulse Width High for the Output Enable Register 0.36 0.41 0.48 ns
tOECKMPWL Clock Minimum Pulse Width Low for the Output Enable Register 0.32 0.37 0.43 ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-222 Revision 4
DDR Module Specifications
Input DDR Module
Figure 2-142 • Input DDR Timing Model
Table 2-179 • Parameter Definitions
Parameter Name Parameter Definition Measuring Nodes (from, to)
tDDRICLKQ1 Clock-to-Out Out_QR B, D
tDDRICLKQ2 Clock-to-Out Out_QF B, E
tDDRISUD Data Setup Time of DDR Input A, B
tDDRIHD Data Hold Time of DDR Input A, B
tDDRICLR2Q1 Clear-to-Out Out_QR C, D
tDDRICLR2Q2 Clear-to-Out Out_QF C, E
tDDRIREMCLR Clear Removal C, B
tDDRIRECCLR Clear Recovery C, B
Input DDR
Data
CLK
CLKBUF
INBUF
Out_QF
(to core)
FF2
FF1
INBUF
CLR
DDR_IN
E
A
B
C
D
Out_QR
(to core)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-223
Timing Characteristics
Figure 2-143 • Input DDR Timing Diagram
t
DDRICLR2Q2
t
DDRIREMCLR
t
DDRIRECCLR
t
DDRICLR2Q1
12 3 4 5 6 7 8 9
CLK
Data
CLR
Out_QR
Out_QF
t
DDRICLKQ1
246
357
t
DDRIHD
t
DDRISUD
t
DDRICLKQ2
Table 2-180 • Input DDR Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tDDRICLKQ1 Clock-to-Out Out_QR for Input DDR 0.39 0.44 0.52 ns
tDDRICLKQ2 Clock-to-Out Out_QF for Input DDR 0.27 0.31 0.37 ns
tDDRISUD Data Setup for Input DDR 0.28 0.32 0.38 ns
tDDRIHD Data Hold for Input DDR 0.00 0.00 0.00 ns
tDDRICLR2Q1 Asynchronous Clear-to-Out Out_QR for Input DDR 0.57 0.65 0.76 ns
tDDRICLR2Q2 Asynchronous Clear-to-Out Out_QF for Input DDR 0.46 0.53 0.62 ns
tDDRIREMCLR Asynchronous Clear Removal Time for Input DDR 0.00 0.00 0.00 ns
tDDRIRECCLR Asynchronous Clear Recovery Time for Input DDR 0.22 0.25 0.30 ns
tDDRIWCLR Asynchronous Clear Minimum Pulse Width for Input DDR 0.22 0.25 0.30 ns
tDDRICKMPWH Clock Minimum Pulse Width High for Input DDR 0.36 0.41 0.48 ns
tDDRICKMPWL Clock Minimum Pulse Width Low for Input DDR 0.32 0.37 0.43 ns
FDDRIMAX Maximum Frequency for Input DDR 1404 1232 1048 MHz
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-224 Revision 4
Output DDR
Figure 2-144 • Output DDR Timing Model
Table 2-181 • Parameter Definitions
Parameter Name Parameter Definition Measuring Nodes (From, To)
tDDROCLKQ Clock-to-Out B, E
tDDROCLR2Q Asynchronous Clear-to-Out C, E
tDDROREMCLR Clear Removal C, B
tDDRORECCLR Clear Recovery C, B
tDDROSUD1 Data Setup Data_F A, B
tDDROSUD2 Data Setup Data_R D, B
tDDROHD1 Data Hold Data_F A, B
tDDROHD2 Data Hold Data_R D, B
Data_F
(from core)
CLK
CLKBUF
Out
FF2
INBUF
CLR
DDR_OUT
FF1
0
1
A
B
D
E
C
C
B
OUTBUF
Data_R
(from core)
Fusion Family of Mixed Signal FPGAs
Revision 4 2-225
Timing Characteristics
Figure 2-145 • Output DDR Timing Diagram
Table 2-182 • Output DDR Propagation Delays
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tDDROCLKQ Clock-to-Out of DDR for Output DDR 0.70 0.80 0.94 ns
tDDROSUD1 Data_F Data Setup for Output DDR 0.38 0.43 0.51 ns
tDDROSUD2 Data_R Data Setup for Output DDR 0.38 0.43 0.51 ns
tDDROHD1 Data_F Data Hold for Output DDR 0.00 0.00 0.00 ns
tDDROHD2 Data_R Data Hold for Output DDR 0.00 0.00 0.00 ns
tDDROCLR2Q Asynchronous Clear-to-Out for Output DDR 0.80 0.91 1.07 ns
tDDROREMCLR Asynchronous Clear Removal Time for Output DDR 0.00 0.00 0.00 ns
tDDRORECCLR Asynchronous Clear Recovery Time for Output DDR 0.22 0.25 0.30 ns
tDDROWCLR1 Asynchronous Clear Minimum Pulse Width for Output DDR 0.22 0.25 0.30 ns
tDDROCKMPWH Clock Minimum Pulse Width High for the Output DDR 0.36 0.41 0.48 ns
tDDROCKMPWL Clock Minimum Pulse Width Low for the Output DDR 0.32 0.37 0.43 ns
FDDOMAX Maximum Frequency for the Output DDR 1404 1232 1048 MHz
Note: For the derating values at specific junction temperature and voltage supply levels, refer to Table 3-7 on
page 3-9.
Device Architecture
2-226 Revision 4
Pin Descriptions
Supply Pins
GND Ground
Ground supply voltage to the core, I/O outputs, and I/O logic.
GNDQ Ground (quiet)
Quiet ground supply voltage to input buffers of I/O banks. Within the package, the GNDQ plane is
decoupled from the simultaneous switching noise originated from the output buffer ground domain. This
minimizes the noise transfer within the package and improves input signal integrity. GNDQ needs to
always be connected on the board to GND. Note: In FG256, FG484, and FG676 packages, GNDQ and
GND pins are connected within the package and are labeled as GND pins in the respective package pin
assignment tables.
ADCGNDREF Analog Reference Ground
Analog ground reference used by the ADC. This pad should be connected to a quiet analog ground.
GNDA Ground (analog)
Quiet ground supply voltage to the Analog Block of Fusion devices. The use of a separate analog ground
helps isolate the analog functionality of the Fusion device from any digital switching noise. A 0.2 V
maximum differential voltage between GND and GNDA/GNDQ should apply to system implementation.
GNDAQ Ground (analog quiet)
Quiet ground supply voltage to the analog I/O of Fusion devices. The use of a separate analog ground
helps isolate the analog functionality of the Fusion device from any digital switching noise. A 0.2 V
maximum differential voltage between GND and GNDA/GNDQ should apply to system implementation.
Note: In FG256, FG484, and FG676 packages, GNDAQ and GNDA pins are connected within the
package and are labeled as GNDA pins in the respective package pin assignment tables.
GNDNVM Flash Memory Ground
Ground supply used by the Fusion device's flash memory block module(s).
GNDOSC Oscillator Ground
Ground supply for both integrated RC oscillator and crystal oscillator circuit.
VCC15A Analog Power Supply (1.5 V)
1.5 V clean analog power supply input for use by the 1.5 V portion of the analog circuitry.
VCC33A Analog Power Supply (3.3 V)
3.3 V clean analog power supply input for use by the 3.3 V portion of the analog circuitry.
VCC33N Negative 3.3 V Output
This is the –3.3 V output from the voltage converter. A 2.2 µF capacitor must be connected from this pin
to ground.
VCC33PMP Analog Power Supply (3.3 V)
3.3 V clean analog power supply input for use by the analog charge pump. To avoid high current draw,
VCC33PMP should be powered up simultaneously with or after VCC33A.
VCCNVM Flash Memory Block Power Supply (1.5 V)
1.5 V power supply input used by the Fusion device's flash memory block module(s). To avoid high
current draw, VCC should be powered up before or simultaneously with VCCNVM.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-227
VCCOSC Oscillator Power Supply (3.3 V)
Power supply for both integrated RC oscillator and crystal oscillator circuit. The internal 100 MHz
oscillator, powered by the VCCOSC pin, is needed for device programming, operation of the VDDN33
pump, and eNVM operation. VCCOSC is off only when VCCA is off. VCCOSC must be powered
whenever the Fusion device needs to function.
VCC Core Supply Voltage
Supply voltage to the FPGA core, nominally 1.5 V. VCC is also required for powering the JTAG state
machine, in addition to VJTAG. Even when a Fusion device is in bypass mode in a JTAG chain of
interconnected devices, both VCC and VJTAG must remain powered to allow JTAG signals to pass
through the Fusion device.
VCCIBx I/O Supply Voltage
Supply voltage to the bank's I/O output buffers and I/O logic. Bx is the I/O bank number. There are either
four (AFS090 and AFS250) or five (AFS600 and AFS1500) I/O banks on the Fusion devices plus a
dedicated VJTAG bank.
Each bank can have a separate VCCI connection. All I/Os in a bank will run off the same VCCIBx supply.
VCCI can be 1.5 V, 1.8 V, 2.5 V, or 3.3 V, nominal voltage. Unused I/O banks should have their
corresponding VCCI pins tied to GND.
VCCPLA/B PLL Supply Voltage
Supply voltage to analog PLL, nominally 1.5 V, where A and B refer to the PLL. AFS090 and AFS250
each have a single PLL. The AFS600 and AFS1500 devices each have two PLLs. Microsemi
recommends tying VCCPLX to VCC and using proper filtering circuits to decouple VCC noise from PLL.
If unused, VCCPLA/B should be tied to GND.
VCOMPLA/B Ground for West and East PLL
VCOMPLA is the ground of the west PLL (CCC location F) and VCOMPLB is the ground of the east PLL
(CCC location C).
VJTAG JTAG Supply Voltage
Fusion devices have a separate bank for the dedicated JTAG pins. The JTAG pins can be run at any
voltage from 1.5 V to 3.3 V (nominal). Isolating the JTAG power supply in a separate I/O bank gives
greater flexibility in supply selection and simplifies power supply and PCB design. If the JTAG interface is
neither used nor planned to be used, the VJTAG pin together with the TRST pin could be tied to GND. It
should be noted that VCC is required to be powered for JTAG operation; VJTAG alone is insufficient. If a
Fusion device is in a JTAG chain of interconnected boards and it is desired to power down the board
containing the Fusion device, this may be done provided both VJTAG and VCC to the Fusion part remain
powered; otherwise, JTAG signals will not be able to transition the Fusion device, even in bypass mode.
VPUMP Programming Supply Voltage
Fusion devices support single-voltage ISP programming of the configuration flash and FlashROM. For
programming, VPUMP should be in the 3.3 V +/-5% range. During normal device operation, VPUMP can
be left floating or can be tied to any voltage between 0 V and 3.6 V.
When the VPUMP pin is tied to ground, it shuts off the charge pump circuitry, resulting in no sources of
oscillation from the charge pump circuitry.
For proper programming, 0.01 µF and 0.33 µF capacitors (both rated at 16 V) are to be connected in
parallel across VPUMP and GND, and positioned as close to the FPGA pins as possible.
Device Architecture
2-228 Revision 4
User-Defined Supply Pins
VREF I/O Voltage Reference
Reference voltage for I/O minibanks. Both AFS600 and AFS1500 (north bank only) support Microsemi
Pro I/O. These I/O banks support voltage reference standard I/O. The VREF pins are configured by the
user from regular I/Os, and any I/O in a bank, except JTAG I/Os, can be designated as the voltage
reference I/O. Only certain I/O standards require a voltage reference—HSTL (I) and (II), SSTL2 (I) and
(II), SSTL3 (I) and (II), and GTL/GTL+. One VREF pin can support the number of I/Os available in its
minibank.
VAREF Analog Reference Voltage
The Fusion device can be configured to generate a 2.56 V internal reference voltage that can be used by
the ADC. While using the internal reference, the reference voltage is output on the VAREF pin for use as
a system reference. If a different reference voltage is required, it can be supplied by an external source
and applied to this pin. The valid range of values that can be supplied to the ADC is 1.0 V to 3.3 V. When
VAREF is internally generated by the Fusion device, a bypass capacitor must be connected from this pin
to ground. The value of the bypass capacitor should be between 3.3 µF and 22 µF, which is based on the
needs of the individual designs. The choice of the capacitor value has an impact on the settling time it
takes the VAREF signal to reach the required specification of 2.56 V to initiate valid conversions by the
ADC. If the lower capacitor value is chosen, the settling time required for VAREF to achieve 2.56 V will
be shorter than when selecting the larger capacitor value. The above range of capacitor values supports
the accuracy specification of the ADC, which is detailed in the datasheet. Designers choosing the smaller
capacitor value will not obtain as much margin in the accuracy as that achieved with a larger capacitor
value. Depending on the capacitor value selected in the Analog System Builder, a tool in Libero SoC, an
automatic delay circuit will be generated using logic tiles available within the FPGA to ensure that VAREF
has achieved the 2.56 V value. Microsemi recommends customers use 10 µF as the value of the bypass
capacitor. Designers choosing to use an external VAREF need to ensure that a stable and clean VAREF
source is supplied to the VAREF pin before initiating conversions by the ADC. Designers should also
make sure that the ADCRESET signal is deasserted before initiating valid conversions.2
If the user connects VAREF to external 3.3 V on their board, the internal VAREF driving OpAmp tries to
bring the pin down to the nominal 2.56 V until the device is programmed and up/functional. Under this
scenario, it is recommended to connect an external 3.3 V supply through a ~1 KOhm resistor to limit
current, along with placing a 10-100nF capacitor between VAREF and GNDA.
User Pins
I/O User Input/Output
The I/O pin functions as an input, output, tristate, or bidirectional buffer. Input and output signal levels are
compatible with the I/O standard selected. Unused I/O pins are configured as inputs with pull-up
resistors.
During programming, I/Os become tristated and weakly pulled up to VCCI. With the VCCI and VCC
supplies continuously powered up, when the device transitions from programming to operating mode, the
I/Os get instantly configured to the desired user configuration.
Unused I/Os are configured as follows:
Output buffer is disabled (with tristate value of high impedance)
Input buffer is disabled (with tristate value of high impedance)
Weak pull-up is programmed
Axy Analog Input/Output
Analog I/O pin, where x is the analog pad type (C = current pad, G = Gate driver pad, T = Temperature
pad, V = Voltage pad) and y is the Analog Quad number (0 to 9). There is a minimum 1 M to ground on
AV, AC, and AT. This pin can be left floating when it is unused.
2. The ADC is functional with an external reference down to 1V, however to meet the performance parameters highlighted in the
datasheet refer to the VAREF specification in Table 3-2 on page 3-3.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-229
ATRTNxTemperature Monitor Return
AT returns are the returns for the temperature sensors. The cathode terminal of the external diodes
should be connected to these pins. There is one analog return pin for every two Analog Quads. The x in
the ATRTNx designator indicates the quad pairing (x= 0 for AQ1 and AQ2, x= 1 for AQ2 and AQ3, ...,
x= 4 for AQ8 and AQ9). The signals that drive these pins are called out as ATRETURNxy in the software
(where x and y refer to the quads that share the return signal). ATRTN is internally connected to ground.
It can be left floating when it is unused. The maximum capacitance allowed across the AT pins is 500 pF.
GL Globals
GL I/Os have access to certain clock conditioning circuitry (and the PLL) and/or have direct access to the
global network (spines). Additionally, the global I/Os can be used as Pro I/Os since they have identical
capabilities. Unused GL pins are configured as inputs with pull-up resistors. See more detailed
descriptions of global I/O connectivity in the "Clock Conditioning Circuits" section on page 2-23.
Refer to the "User I/O Naming Convention" section on page 2-161 for a description of naming of global
pins.
JTAG Pins
Fusion devices have a separate bank for the dedicated JTAG pins. The JTAG pins can be run at any
voltage from 1.5 V to 3.3 V (nominal). VCC must also be powered for the JTAG state machine to operate,
even if the device is in bypass mode; VJTAG alone is insufficient. Both VJTAG and VCC to the Fusion
part must be supplied to allow JTAG signals to transition the Fusion device.
Isolating the JTAG power supply in a separate I/O bank gives greater flexibility with supply selection and
simplifies power supply and PCB design. If the JTAG interface is neither used nor planned to be used,
the VJTAG pin together with the TRST pin could be tied to GND.
TCK Test Clock
Test clock input for JTAG boundary scan, ISP, and UJTAG. The TCK pin does not have an internal pull-
up/-down resistor. If JTAG is not used, Microsemi recommends tying off TCK to GND or VJTAG through
a resistor placed close to the FPGA pin. This prevents JTAG operation in case TMS enters an undesired
state.
Note that to operate at all VJTAG voltages, 500 to 1 k will satisfy the requirements. Refer to
Table 2-183 for more information.
TDI Test Data Input
Serial input for JTAG boundary scan, ISP, and UJTAG usage. There is an internal weak pull-up resistor
on the TDI pin.
TDO Test Data Output
Serial output for JTAG boundary scan, ISP, and UJTAG usage.
Table 2-183 • Recommended Tie-Off Values for the TCK and TRST Pins
VJTAG Tie-Off Resistance2, 3
VJTAG at 3.3 V 200 to 1 k
VJTAG at 2.5 V 200 to 1 k
VJTAG at 1.8 V 500 to 1 k
VJTAG at 1.5 V 500 to 1 k
Notes:
1. Equivalent parallel resistance if more than one device is on JTAG chain.
2. The TCK pin can be pulled up/down.
3. The TRST pin can only be pulled down.
Device Architecture
2-230 Revision 4
TMS Test Mode Select
The TMS pin controls the use of the IEEE1532 boundary scan pins (TCK, TDI, TDO, TRST). There is an
internal weak pull-up resistor on the TMS pin.
TRST Boundary Scan Reset Pin
The TRST pin functions as an active low input to asynchronously initialize (or reset) the boundary scan
circuitry. There is an internal weak pull-up resistor on the TRST pin. If JTAG is not used, an external pull-
down resistor could be included to ensure the TAP is held in reset mode. The resistor values must be
chosen from Table 2-183 and must satisfy the parallel resistance value requirement. The values in
Table 2-183 correspond to the resistor recommended when a single device is used and to the equivalent
parallel resistor when multiple devices are connected via a JTAG chain.
In critical applications, an upset in the JTAG circuit could allow entering an undesired JTAG state. In such
cases, Microsemi recommends tying off TRST to GND through a resistor placed close to the FPGA pin.
Note that to operate at all VJTAG voltages, 500 to 1 k will satisfy the requirements.
Special Function Pins
NC No Connect
This pin is not connected to circuitry within the device. These pins can be driven to any voltage or can be
left floating with no effect on the operation of the device.
DC Don't Connect
This pin should not be connected to any signals on the PCB. These pins should be left unconnected.
NCAP Negative Capacitor
Negative Capacitor is where the negative terminal of the charge pump capacitor is connected. A
capacitor, with a 2.2 µF recommended value, is required to connect between PCAP and NCAP.
PCAP Positive Capacitor
Positive Capacitor is where the positive terminal of the charge pump capacitor is connected. A capacitor,
with a 2.2 µF recommended value, is required to connect between PCAP and NCAP.
PUB Push Button
Push button is the connection for the external momentary switch used to turn on the 1.5 V voltage
regulator and can be floating if not used.
PTBASE Pass Transistor Base
Pass Transistor Base is the control signal of the voltage regulator. This pin should be connected to the
base of the external pass transistor used with the 1.5 V internal voltage regulator and can be floating if
not used.
PTEM Pass Transistor Emitter
Pass Transistor Emitter is the feedback input of the voltage regulator.
This pin should be connected to the emitter of the external pass transistor used with the 1.5 V internal
voltage regulator and can be floating if not used.
XTAL1 Crystal Oscillator Circuit Input
Input to crystal oscillator circuit. Pin for connecting external crystal, ceramic resonator, RC network, or
external clock input. When using an external crystal or ceramic oscillator, external capacitors are also
recommended (Please refer to the crystal oscillator manufacturer for proper capacitor value).
If using external RC network or clock input, XTAL1 should be used and XTAL2 left unconnected. In the
case where the Crystal Oscillator block is not used, the XTAL1 pin should be connected to GND and the
XTAL2 pin should be left floating.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-231
XTAL2 Crystal Oscillator Circuit Input
Input to crystal oscillator circuit. Pin for connecting external crystal, ceramic resonator, RC network, or
external clock input. When using an external crystal or ceramic oscillator, external capacitors are also
recommended (Please refer to the crystal oscillator manufacturer for proper capacitor value).
If using external RC network or clock input, XTAL1 should be used and XTAL2 left unconnected. In the
case where the Crystal Oscillator block is not used, the XTAL1 pin should be connected to GND and the
XTAL2 pin should be left floating.
Security
Fusion devices have a built-in 128-bit AES decryption core. The decryption core facilitates highly secure,
in-system programming of the FPGA core array fabric and the FlashROM. The FlashROM and the FPGA
core fabric can be programmed independently from each other, allowing the FlashROM to be updated
without the need for change to the FPGA core fabric. The AES master key is stored in on-chip nonvolatile
memory (flash). The AES master key can be preloaded into parts in a security-protected programming
environment (such as the Microsemi in-house programming center), and then "blank" parts can be
shipped to an untrusted programming or manufacturing center for final personalization with an AES-
encrypted bitstream. Late stage product changes or personalization can be implemented easily and with
high level security by simply sending a STAPL file with AES-encrypted data. Highly secure remote field
updates over public networks (such as the Internet) are possible by sending and programming a STAPL
file with AES-encrypted data. For more information, refer to the Fusion Security application note.
128-Bit AES Decryption
The 128-bit AES standard (FIPS-197) block cipher is the National Institute of Standards and Technology
(NIST) replacement for DES (Data Encryption Standard FIPS46-2). AES has been designed to protect
sensitive government information well into the 21st century. It replaces the aging DES, which NIST
adopted in 1977 as a Federal Information Processing Standard used by federal agencies to protect
sensitive, unclassified information. The 128-bit AES standard has 3.4 × 1038 possible 128-bit key
variants, and it has been estimated that it would take 1,000 trillion years to crack 128-bit AES cipher text
using exhaustive techniques. Keys are stored (protected with security) in Fusion devices in nonvolatile
flash memory. All programming files sent to the device can be authenticated by the part prior to
programming to ensure that bad programming data is not loaded into the part that may possibly damage
it. All programming verification is performed on-chip, ensuring that the contents of Fusion devices remain
as secure as possible.
AES decryption can also be used on the 1,024-bit FlashROM to allow for remote updates of the
FlashROM contents. This allows for easy support of subscription model products and protects them with
measures designed to provide the highest level of security available. See the application note Fusion
Security for more details.
AES for Flash Memory
AES decryption can also be used on the flash memory blocks. This provides the best available security
during update of the flash memory blocks. During runtime, the encrypted data can be clocked in via the
JTAG interface. The data can be passed through the internal AES decryption engine, and the decrypted
data can then be stored in the flash memory block.
Programming
Programming can be performed using various programming tools, such as Silicon Sculptor II (BP Micro
Systems) or FlashPro3 (Microsemi).
The user can generate STP programming files from the Designer software and can use these files to
program a device.
Fusion devices can be programmed in-system. During programming, VCCOSC is needed in order to
power the internal 100 MHz oscillator. This oscillator is used as a source for the 20 MHz oscillator that is
used to drive the charge pump for programming.
Device Architecture
2-232 Revision 4
ISP
Fusion devices support IEEE 1532 ISP via JTAG and require a single VPUMP voltage of 3.3 V during
programming. In addition, programming via a microcontroller in a target system can be achieved. Refer to
the standard or the "In-System Programming (ISP) of Microsemi's Low Power Flash Devices Using
FlashPro4/3/3X" chapter of the Fusion FPGA Fabric User’s Guide for more details.
JTAG IEEE 1532
Programming with IEEE 1532
Fusion devices support the JTAG-based IEEE1532 standard for ISP. As part of this support, when a
Fusion device is in an unprogrammed state, all user I/O pins are disabled. This is achieved by keeping
the global IO_EN signal deactivated, which also has the effect of disabling the input buffers.
Consequently, the SAMPLE instruction will have no effect while the Fusion device is in this
unprogrammed state—different behavior from that of the ProASICPLUS® device family. This is done
because SAMPLE is defined in the IEEE1532 specification as a noninvasive instruction. If the input
buffers were to be enabled by SAMPLE temporarily turning on the I/Os, then it would not truly be a
noninvasive instruction. Refer to the standard or the "In-System Programming (ISP) of Microsemi's Low
Power Flash Devices Using FlashPro4/3/3X" chapter of the Fusion FPGA Fabric User’s Guide for more
details.
Boundary Scan
Fusion devices are compatible with IEEE Standard 1149.1, which defines a hardware architecture and
the set of mechanisms for boundary scan testing. The basic Fusion boundary scan logic circuit is
composed of the test access port (TAP) controller, test data registers, and instruction register (Figure 2-
146 on page 2-233). This circuit supports all mandatory IEEE 1149.1 instructions (EXTEST,
SAMPLE/PRELOAD, and BYPASS) and the optional IDCODE instruction (Table 2-185 on page 2-233).
Each test section is accessed through the TAP, which has five associated pins: TCK (test clock input),
TDI, TDO (test data input and output), TMS (test mode selector), and TRST (test reset input). TMS, TDI,
and TRST are equipped with pull-up resistors to ensure proper operation when no input data is supplied
to them. These pins are dedicated for boundary scan test usage. Refer to the "JTAG Pins" section on
page 2-229 for pull-up/-down recommendations for TDO and TCK pins. The TAP controller is a 4-bit state
machine (16 states) that operates as shown in Figure 2-146 on page 2-233. The 1s and 0s represent the
values that must be present on TMS at a rising edge of TCK for the given state transition to occur. IR and
DR indicate that the instruction register or the data register is operating in that state.
The TAP controller receives two control inputs (TMS and TCK) and generates control and clock signals
for the rest of the test logic architecture. On power-up, the TAP controller enters the Test-Logic-Reset
state. To guarantee a reset of the controller from any of the possible states, TMS must remain High for
five TCK cycles. The TRST pin can also be used to asynchronously place the TAP controller in the Test-
Logic-Reset state.
Fusion devices support three types of test data registers: bypass, device identification, and boundary
scan. The bypass register is selected when no other register needs to be accessed in a device. This
speeds up test data transfer to other devices in a test data path. The 32-bit device identification register
is a shift register with four fields (LSB, ID number, part number, and version). The boundary scan register
observes and controls the state of each I/O pin. Each I/O cell has three boundary scan register cells,
each with a serial-in, serial-out, parallel-in, and parallel-out pin.
The serial pins are used to serially connect all the boundary scan register cells in a device into a
boundary scan register chain, which starts at the TDI pin and ends at the TDO pin. The parallel ports are
Table 2-184 • TRST and TCK Pull-Down Recommendations
VJTAG Tie-Off Resistance*
VJTAG at 3.3 V 200 to 1 k
VJTAG at 2.5 V 200 to 1 k
VJTAG at 1.8 V 500 to 1 k
VJTAG at 1.5 V 500 to 1 k
Note: *Equivalent parallel resistance if more than one device is on JTAG chain.
Fusion Family of Mixed Signal FPGAs
Revision 4 2-233
connected to the internal core logic I/O tile and the input, output, and control ports of an I/O buffer to
capture and load data into the register to control or observe the logic state of each I/O.
Figure 2-146 • Boundary Scan Chain in Fusion
Table 2-185 • Boundary Scan Opcodes
Hex Opcode
EXTEST 00
HIGHZ 07
USERCODE 0E
SAMPLE/PRELOAD 01
IDCODE 0F
CLAMP 05
BYPASS FF
Device
Logic
TDI
TCK
TMS
TRST
TDO
I/OI/OI/O I/OI/O
I/OI/OI/O I/OI/O
I/O
I/O
I/O
I/O
Bypass Register
Instruction
Register
TAP
Controller
Test Data
Registers
IEEE 1532 Characteristics
JTAG timing delays do not include JTAG I/Os. To obtain complete JTAG timing, add I/O buffer delays to
the corresponding standard selected; refer to the I/O timing characteristics in the "User I/Os" section on
page 2-135 for more details.
Timing Characteristics
Table 2-186 • JTAG 1532
Commercial Temperature Range Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter Description –2 –1 Std. Units
tDISU Test Data Input Setup Time 0.50 0.57 0.67 ns
tDIHD Test Data Input Hold Time 1.00 1.13 1.33 ns
tTMSSU Test Mode Select Setup Time 0.50 0.57 0.67 ns
tTMDHD Test Mode Select Hold Time 1.00 1.13 1.33 ns
tTCK2Q Clock to Q (data out) 6.00 6.80 8.00 ns
tRSTB2Q Reset to Q (data out) 20.00 22.67 26.67 ns
FTCKMAX TCK Maximum Frequency 25.00 22.00 19.00 MHz
tTRSTREM ResetB Removal Time 0.00 0.00 0.00 ns
tTRSTREC ResetB Recovery Time 0.20 0.23 0.27 ns
tTRSTMPW ResetB Minimum Pulse TBD TBD TBD ns
Note: For the derating values at specific junction temperature and voltage supply levels, refer to
Table 3-7 on page 3-9.
Revision 4 3-1
3 – DC and Power Characteristics
General Specifications
Operating Conditions
Stresses beyond those listed in Tab le 3 -1 may cause permanent damage to the device.
Exposure to absolute maximum rated conditions for extended periods may affect device reliability.
Devices should not be operated outside the recommended operating ranges specified in Table 3-2 on
page 3-3.
Table 3-1 • Absolute Maximum Ratings
Symbol Parameter Commercial Industrial Units
VCC DC core supply voltage –0.3 to 1.65 –0.3 to 1.65 V
VJTAG JTAG DC voltage –0.3 to 3.75 –0.3 to 3.75 V
VPUMP Programming voltage –0.3 to 3.75 0.3 to 3.75 V
VCCPLL Analog power supply (PLL) –0.3 to 1.65 –0.3 to 1.65 V
VCCI DC I/O output buffer supply voltage –0.3 to 3.75 –0.3 to 3.75 V
VI I/O input voltage 1–0.3 V to 3.6 V (when I/O hot insertion mode is
enabled)
–0.3 V to (VCCI + 1 V) or 3.6 V, whichever
voltage is lower (when I/O hot-insertion mode is
disabled)
V
VCC33A +3.3 V power supply –0.3 to 3.75 2–0.3 to 3.75 2V
VCC33PMP +3.3 V power supply –0.3 to 3.75 2–0.3 to 3.75 2V
VAREF Voltage reference for ADC –0.3 to 3.75 –0.3 to 3.75 V
VCC15A Digital power supply for the analog system –0.3 to 1.65 –0.3 to 1.65 V
VCCNVM Embedded flash power supply –0.3 to 1.65 0.3 to 1.65 V
VCCOSC Oscillator power supply –0.3 to 3.75 –0.3 to 3.75 V
Notes:
1. The device should be operated within the limits specified by the datasheet. During transitions, the input signal may
undershoot or overshoot according to the limits shown in Table 3-4 on page 3-4.
2. Analog data not valid beyond 3.65 V.
3. The high current mode has a maximum power limit of 20 mW. Appropriate current limit resistors must be used, based on
voltage on the pad.
4. For flash programming and retention maximum limits, refer to Table 3-5 on page 3-5. For recommended operating limits
refer to Table 3-2 on page 3-3.
DC and Power Characteristics
3-2 Revision 4
AV, AC Unpowered, ADC reset asserted or
unconfigured
–11.0 to 12.6 –11.0 to 12.0 V
Analog input (+16 V to +2 V prescaler range) –0.4 to 12.6 –0.4 to 12.0 V
Analog input (+1 V to +0.125 V prescaler
range)
–0.4 to 3.75 0.4 to 3.75 V
Analog input (–16 V to –2 V prescaler range) –11.0 to 0.4 –11.0 to 0.4 V
Analog input (–1 V to –0.125 V prescaler
range)
–3.75 to 0.4 –3.75 to 0.4 V
Analog input (direct input to ADC) –0.4 to 3.75 –0.4 to 3.75 V
Digital input –0.4 to 12.6 –0.4 to 12.0 V
AG Unpowered, ADC reset asserted or
unconfigured
–11.0 to 12.6 –11.0 to 12.0 V
Low Current Mode (1 µA, 3 µA, 10 µA, 30 µA) –0.4 to 12.6 –0.4 to 12.0 V
Low Current Mode (–1 µA, –3 µA, –10 µA, –30
µA)
–11.0 to 0.4 –11.0 to 0.4 V
High Current Mode 3–11.0 to 12.6 –11.0 to 12.0 V
AT Unpowered, ADC reset asserted or
unconfigured
–0.4 to 16.0 –0.4 to 15.0 V
Analog input (+16 V, 4 V prescaler range) –0.4 to 16.0 –0.4 to 15.0 V
Analog input (direct input to ADC) –0.4 to 3.75 –0.4 to 3.75 V
Digital input –0.4 to 16.0 –0.4 to 15.0 V
TSTG 4Storage temperature –65 to +150 °C
TJ4Junction temperature +125 °C
Table 3-1 • Absolute Maximum Ratings (continued)
Symbol Parameter Commercial Industrial Units
Notes:
1. The device should be operated within the limits specified by the datasheet. During transitions, the input signal may
undershoot or overshoot according to the limits shown in Table 3-4 on page 3-4.
2. Analog data not valid beyond 3.65 V.
3. The high current mode has a maximum power limit of 20 mW. Appropriate current limit resistors must be used, based on
voltage on the pad.
4. For flash programming and retention maximum limits, refer to Table 3-5 on page 3-5. For recommended operating limits
refer to Table 3-2 on page 3-3.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-3
Table 3-2 • Recommended Operating Conditions1
Symbol Parameter2Commercial Industrial Units
TJJunction temperature 0 to +85 –40 to +100 °C
VCC 1.5 V DC core supply voltage 1.425 to 1.575 1.425 to 1.575 V
VJTAG JTAG DC voltage 1.4 to 3.6 1.4 to 3.6 V
VPUMP Programming voltage Programming mode33.15 to 3.45 3.15 to 3.45 V
Operation40 to 3.6 0 to 3.6 V
VCCPLL Analog power supply (PLL) 1.425 to 1.575 1.425 to 1.575 V
VCCI 1.5 V DC supply voltage 1.425 to 1.575 1.425 to 1.575 V
1.8 V DC supply voltage 1.7 to 1.9 1.7 to 1.9 V
2.5 V DC supply voltage 2.3 to 2.7 2.3 to 2.7 V
3.3 V DC supply voltage 3.0 to 3.6 3.0 to 3.6 V
LVDS differential I/O 2.375 to 2.625 2.375 to 2.625 V
LVPECL differential I/O 3.0 to 3.6 3.0 to 3.6 V
VCC33A +3.3 V power supply 2.97 to 3.63 2.97 to 3.63 V
VCC33PMP +3.3 V power supply 2.97 to 3.63 2.97 to 3.63 V
VAREF Voltage reference for ADC 2.527 to 2.593 2.527 to 2.593 V
VCC15A 5Digital power supply for the analog system 1.425 to 1.575 1.425 to 1.575 V
VCCNVM Embedded flash power supply 1.425 to 1.575 1.425 to 1.575 V
VCCOSC Oscillator power supply 2.97 to 3.63 2.97 to 3.63 V
AV, AC 6Unpowered, ADC reset asserted or unconfigured –10.5 to 12.0 –10.5 to 11.6 V
Analog input (+16 V to +2 V prescaler range) –0.3 to 12.0 –0.3 to 11.6 V
Analog input (+1 V to + 0.125 V prescaler range) –0.3 to 3.6 –0.3 to 3.6 V
Analog input (–16 V to –2 V prescaler range) –10.5 to 0.3 –10.5 to 0.3 V
Analog input (–1 V to –0.125 V prescaler range) –3.6 to 0.3 –3.6 to 0.3 V
Analog input (direct input to ADC) –0.3 to 3.6 –0.3 to 3.6 V
Digital input –0.3 to 12.0 –0.3 to 11.6 V
AG 6Unpowered, ADC reset asserted or unconfigured –10.5 to 12.0 –10.5 to 11.6 V
Low Current Mode (1 µA, 3 µA, 10 µA, 30 µA) –0.3 to 12.0 –0.3 to 11.6 V
Low Current Mode (–1 µA, –3 µA, –10 µA, –30 µA) –10.5 to 0.3 –10.5 to 0.3 V
High Current Mode 7–10.5 to 12.0 –10.5 to 11.6 V
AT 6Unpowered, ADC reset asserted or unconfigured –0.3 to 15.5 –0.3 to 14.5 V
Analog input (+16 V, +4 V prescaler range) –0.3 to 15.5 –0.3 to 14.5 V
Analog input (direct input to ADC) –0.3 to 3.6 –0.3 to 3.6 V
Digital input –0.3 to 15.5 –0.3 to 14.5 V
Notes:
1. The ranges given here are for power supplies only. The recommended input voltage ranges specific to each I/O
standard are given in Table 2-85 on page 2-160.
2. All parameters representing voltages are measured with respect to GND unless otherwise specified.
3. The programming temperature range supported is Tambient = 0°C to 85°C.
4. VPUMP can be left floating during normal operation (not programming mode).
5. Violating the VCC15A recommended voltage supply during an embedded flash program cycle can corrupt the page being
programmed.
6. The input voltage may overshoot by up to 500 mV above the Recommended Maximum (150 mV in Direct mode),
provided the duration of the overshoot is less than 50% of the operating lifetime of the device.
7. The AG pad should also conform to the limits as specified in Table 2-48 on page 2-117.
DC and Power Characteristics
3-4 Revision 4
Table 3-3 • Input Resistance of Analog Pads
Pads Pad Configuration Prescaler Range Input Resistance to Ground
AV, AC Analog Input (direct input to ADC) 2 k (typical)
> 10 M
Analog Input (positive prescaler) +16 V to +2 V 1 M (typical)
+1 V to +0.125 V > 10 M
Analog Input (negative prescaler) –16 V to –2 V 1 M (typical)
–1 V to –0.125 V > 10 M
Digital input +16 V to +2 V 1 M (typical)
Current monitor +16 V to +2 V 1 M (typical)
–16 V to –2 V 1 M (typical)
AT Analog Input (direct input to ADC) 1 M (typical)
Analog Input (positive prescaler) +16 V, +4 V 1 M (typical)
Digital input +16 V, +4 V 1 M (typical)
Temperature monitor +16 V, +4 V > 10 M
Table 3-4 • Overshoot and Undershoot Limits 1
VCCI
Average VCCI–GND Overshoot or Undershoot
Duration as a Percentage of Clock Cycle2
Maximum Overshoot/
Undershoot2
2.7 V or less 10% 1.4 V
5% 1.49 V
3.0 V 10% 1.1 V
5% 1.19 V
3.3 V 10% 0.79 V
5% 0.88 V
3.6 V 10% 0.45 V
5% 0.54 V
Notes:
1. Based on reliability requirements at a junction temperature of 85°C.
2. The duration is allowed at one cycle out of six clock cycle. If the overshoot/undershoot occurs at one out of two cycles,
the maximum overshoot/undershoot has to be reduced by 0.15 V.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-5
I/O Power-Up and Supply Voltage Thresholds for Power-On Reset
(Commercial and Industrial)
Sophisticated power-up management circuitry is designed into every Fusion device. These circuits
ensure easy transition from the powered off state to the powered up state of the device. The many
different supplies can power up in any sequence with minimized current spikes or surges. In addition, the
I/O will be in a known state through the power-up sequence. The basic principle is shown in Figure 3-1
on page 3-6.
There are five regions to consider during power-up.
Fusion I/Os are activated only if ALL of the following three conditions are met:
1. VCC and VCCI are above the minimum specified trip points (Figure 3-1).
2. VCCI > VCC – 0.75 V (typical).
3. Chip is in the operating mode.
VCCI Trip Point:
Ramping up: 0.6 V < trip_point_up < 1.2 V
Ramping down: 0.5 V < trip_point_down < 1.1 V
VCC Trip Point:
Ramping up: 0.6 V < trip_point_up < 1.1 V
Ramping down: 0.5 V < trip_point_down < 1 V
VCC and VCCI ramp-up trip points are about 100 mV higher than ramp-down trip points. This specifically
built-in hysteresis prevents undesirable power-up oscillations and current surges. Note the following:
During programming, I/Os become tristated and weakly pulled up to VCCI.
JTAG supply, PLL power supplies, and charge pump VPUMP supply have no influence on I/O
behavior.
Internal Power-Up Activation Sequence
1. Core
2. Input buffers
3. Output buffers, after 200 ns delay from input buffer activation
PLL Behavior at Brownout Condition
Microsemi recommends using monotonic power supplies or voltage regulators to ensure proper power-
up behavior. Power ramp-up should be monotonic at least until VCC and VCCPLX exceed brownout
activation levels. The VCC activation level is specified as 1.1 V worst-case (see Figure 3-1 on page 3-6
for more details).
When PLL power supply voltage and/or VCC levels drop below the VCC brownout levels
(0.75 V ± 0.25 V), the PLL output lock signal goes low and/or the output clock is lost.
Table 3-5 • FPGA Programming, Storage, and Operating Limits
Product
Grade
Storage
Temperature Element
Grade Programming
Cycles Retention
Commercial Min. TJ = 0°C FPGA/FlashROM 500 20 years
Max. TJ = 85°C Embedded Flash < 1,000 20 years
< 10,000 10 years
< 15,000 5 years
Industrial Min. TJ = –40°C FPGA/FlashROM 500 20 years
Max. TJ = 100°C Embedded Flash < 1,000 20 years
< 10,000 10 years
< 15,000 5 years
DC and Power Characteristics
3-6 Revision 4
Figure 3-1 I/O State as a Function of VCCI and VCC Voltage Levels
Region 1: I/O buffers are OFF
Region 2: I/O buffers are ON.
I/Os are functional (except differential inputs)
but slower because VCCI / VCC are below
specification. For the same reason, input
buffers do not meet VIH / VIL levels, and
output buffers do not meet VOH / VOL levels.
Min VCCI datasheet specification
voltage at a selected I/O
standard; i.e., 1.425 V or 1.7 V
or 2.3 V or 3.0 V
VCC
VCC = 1.425 V
Region 1: I/O Buffers are OFF
Activation trip point:
Va = 0.85 V ± 0.25 V
Deactivation trip point:
Vd = 0.75 V ± 0.25 V
Activation trip point:
Va = 0.9 V ±0.3 V
Deactivation trip point:
Vd = 0.8 V ± 0.3 V
VCC = 1.575 V
Region 5: I/O buffers are ON
and power supplies are within
specification.
I/Os meet the entire datasheet
and timer specifications for
speed, VIH / VIL, VOH VOL, etc.
Region 4: I/O
buffers are ON.
I/Os are functional
(except differential inputs)
but slower because VCCI is
below specification. For the
same reason, input buffers do not
meet VIH / VIL levels, and output
buffers do not meet VOH / VOL levels.
Where VT can be from 0.58 V to 0.9 V (typically 0.75 V)
VCC = VCCI + VT
VCCI
Region 3: I/O buffers are ON.
I/Os are functional; I/O DC
specifications are met,
but I/Os are slower because
the VCC is below specification
Fusion Family of Mixed Signal FPGAs
Revision 4 3-7
Thermal Characteristics
Introduction
The temperature variable in the Microsemi Designer software refers to the junction temperature, not the
ambient, case, or board temperatures. This is an important distinction because dynamic and static power
consumption will cause the chip's junction temperature to be higher than the ambient, case, or board
temperatures. EQ 1 through EQ 3 give the relationship between thermal resistance, temperature
gradient, and power.
EQ 1
EQ 2
EQ 3
where
JA = Junction-to-air thermal resistance
JB = Junction-to-board thermal resistance
JC = Junction-to-case thermal resistance
TJ= Junction temperature
TA= Ambient temperature
TB= Board temperature (measured 1.0 mm away from the
package edge)
TC= Case temperature
P = Total power dissipated by the device
JA
TJA
P
------------------
=
JB
TJTB
P
-------------------
=
JC
TJTC
P
-------------------
=
Table 3-6 • Package Thermal Resistance
Product
JA
JC JB UnitsStill Air 1.0 m/s 2.5 m/s
AFS090-QN108 34.5 30.0 27.7 8.1 16.7 °C/W
AFS090-QN180 33.3 27.6 25.7 9.2 21.2 °C/W
AFS250-QN180 32.2 26.5 24.7 5.7 15.0 °C/W
AFS250-PQ208 42.1 38.4 37 20.5 36.3 °C/W
AFS600-PQ208 23.9 21.3 20.48 6.1 16.5 °C/W
AFS090-FG256 37.7 33.9 32.2 11.5 29.7 °C/W
AFS250-FG256 33.7 30.0 28.3 9.3 24.8 °C/W
AFS600-FG256 28.9 25.2 23.5 6.8 19.9 °C/W
AFS1500-FG256 23.3 19.6 18.0 4.3 14.2 °C/W
AFS600-FG484 21.8 18.2 16.7 7.7 16.8 °C/W
AFS1500-FG484 21.6 16.8 15.2 5.6 14.9 °C/W
AFS1500-FG676 TBD TBD TBD TBD TBD °C/W
DC and Power Characteristics
3-8 Revision 4
Theta-JA
Junction-to-ambient thermal resistance (JA) is determined under standard conditions specified by
JEDEC (JESD-51), but it has little relevance in actual performance of the product. It should be used with
caution but is useful for comparing the thermal performance of one package to another.
A sample calculation showing the maximum power dissipation allowed for the AFS600-FG484 package
under forced convection of 1.0 m/s and 75°C ambient temperature is as follows:
EQ 4
where
EQ 5
The power consumption of a device can be calculated using the Microsemi power calculator. The
device's power consumption must be lower than the calculated maximum power dissipation by the
package. If the power consumption is higher than the device's maximum allowable power dissipation, a
heat sink can be attached on top of the case, or the airflow inside the system must be increased.
Theta-JB
Junction-to-board thermal resistance (JB) measures the ability of the package to dissipate heat from the
surface of the chip to the PCB. As defined by the JEDEC (JESD-51) standard, the thermal resistance
from junction to board uses an isothermal ring cold plate zone concept. The ring cold plate is simply a
means to generate an isothermal boundary condition at the perimeter. The cold plate is mounted on a
JEDEC standard board with a minimum distance of 5.0 mm away from the package edge.
Theta-JC
Junction-to-case thermal resistance (JC) measures the ability of a device to dissipate heat from the
surface of the chip to the top or bottom surface of the package. It is applicable for packages used with
external heat sinks. Constant temperature is applied to the surface in consideration and acts as a
boundary condition. This only applies to situations where all or nearly all of the heat is dissipated through
the surface in consideration.
Calculation for Heat Sink
For example, in a design implemented in an AFS600-FG484 package with 2.5 m/s airflow, the power
consumption value using the power calculator is 3.00 W. The user-dependent Ta and Tj are given as
follows:
From the datasheet:
EQ 6
JA = 19.00°C/W (taken from Table 3-6 on page 3-7).
TA= 75.00°C
TJ= 100.00°C
TA= 70.00°C
JA = 17.00°C/W
JC = 8.28°C/W
Maximum Power Allowed TJ(MAX) TA(MAX)
JA
---------------------------------------------
=
Maximum Power Allowed 100.00°C 75.00°C
19.00°C/W
---------------------------------------------------- 1.3 W==
PTJTA
JA
-------------------100°C 70°C
17.00 W
------------------------------------1.76 W== =
Fusion Family of Mixed Signal FPGAs
Revision 4 3-9
The 1.76 W power is less than the required 3.00 W. The design therefore requires a heat sink, or the
airflow where the device is mounted should be increased. The design's total junction-to-air thermal
resistance requirement can be estimated by EQ 7:
EQ 7
Determining the heat sink's thermal performance proceeds as follows:
EQ 8
where
EQ 9
A heat sink with a thermal resistance of 5.01°C/W or better should be used. Thermal resistance of heat
sinks is a function of airflow. The heat sink performance can be significantly improved with increased
airflow.
Carefully estimating thermal resistance is important in the long-term reliability of an Microsemi FPGA.
Design engineers should always correlate the power consumption of the device with the maximum
allowable power dissipation of the package selected for that device.
Note: The junction-to-air and junction-to-board thermal resistances are based on JEDEC standard
(JESD-51) and assumptions made in building the model. It may not be realized in actual application and
therefore should be used with a degree of caution. Junction-to-case thermal resistance assumes that all
power is dissipated through the case.
Temperature and Voltage Derating Factors
JA = 0.37°C/W
= Thermal resistance of the interface material between
the case and the heat sink, usually provided by the
thermal interface manufacturer
SA = Thermal resistance of the heat sink in °C/W
Table 3-7 • Temperature and Voltage Derating Factors for Timing Delays
(normalized to TJ = 70°C, Worst-Case VCC = 1.425 V)
Array Voltage
VCC (V)
Junction Temperature (°C)
–40°C 0°C 25°C 70°C 85°C 100°C
1.425 0.88 0.93 0.95 1.00 1.02 1.05
1.500 0.83 0.88 0.90 0.95 0.96 0.99
1.575 0.80 0.85 0.87 0.91 0.93 0.96
ja(total)
TJTA
P
-------------------100°C 70°C
3.00 W
------------------------------------10.00°C/W== =
JA(TOTAL) JC CS SA
++=
SA JA(TOTAL) JC
CS
=
SA 13.33°C/W 8.28°C/W0.37°C/W5.01°C/W==
DC and Power Characteristics
3-10 Revision 4
Calculating Power Dissipation
Quiescent Supply Current
Table 3-8 • AFS1500 Quiescent Supply Current Characteristics
Parameter Description Conditions Temp. Min. Typ. Max. Unit
ICC11.5 V quiescent current Operational standby4,
VCC = 1.575 V
TJ=25°C 20 40 mA
TJ=85°C 32 65 mA
TJ= 100°C 59 120 mA
Standby mode5 or Sleep mode6,
VCC = 0 V
00µA
ICC3323.3 V analog supplies
current
Operational standby4,
VCC33 = 3.63 V
TJ=25°C 9.8 13 mA
TJ= 85°C 10.7 14 mA
TJ= 100°C 10.8 15 mA
Operational standby, only Analog
Quad and –3.3 V output ON,
VCC33 = 3.63 V
TJ=25°C 0.31 2 mA
TJ=85°C 0.35 2 mA
TJ= 100°C 0.45 2 mA
Standby mode5, VCC33 = 3.63 V TJ= 25°C 2.9 3.6 mA
TJ=85°C 2.9 4 mA
TJ= 100°C 3.3 6 mA
Sleep mode6, VCC33 = 3.63 V TJ=25°C 17 19 µA
TJ=85°C 18 20 µA
TJ= 100°C 24 25 µA
ICCI3I/O quiescent current Operational standby4,
Standby mode, and Sleep Mode6,
VCCIx = 3.63 V
TJ= 25°C 417 649 µA
TJ= 85°C 417 649 µA
TJ= 100°C 417 649 µA
Notes:
1. ICC is the 1.5 V power supplies, ICC and ICC15A.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, ICCI2, and ICCI4.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-11
IJTAG JTAG I/O quiescent
current
Operational standby4,
VJTAG = 3.63 V
TJ= 25°C 80 100 µA
TJ= 85°C 80 100 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep mode6,
VJTAG = 0 V
00µA
IPP Programming supply
current
Non-programming mode,
VPUMP = 3.63 V
TJ=25°C 39 80 µA
TJ=85°C 40 80 µA
TJ= 100°C 40 80 µA
Standby mode5 or Sleep mode6,
VPUMP = 0 V
00µA
ICCNVM Embedded NVM
current
Reset asserted, VCCNVM = 1.575 V TJ= 25°C 50 150 µA
TJ=85°C 50 150 µA
TJ= 100°C 50 150 µA
ICCPLL 1.5 V PLL quiescent
current
Operational standby
, VCCPLL = 1.575 V
TJ= 25°C 130 200 µA
TJ= 85°C 130 200 µA
TJ= 100°C 130 200 µA
Table 3-8 • AFS1500 Quiescent Supply Current Characteristics (continued)
Parameter Description Conditions Temp. Min. Typ. Max. Unit
Notes:
1. ICC is the 1.5 V power supplies, ICC and ICC15A.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, ICCI2, and ICCI4.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
DC and Power Characteristics
3-12 Revision 4
Table 3-9 • AFS600 Quiescent Supply Current Characteristics
Parameter Description Conditions Temp. Min Typ Max Unit
ICC11.5 V quiescent current Operational standby4,
VCC = 1.575 V
TJ=25°C 13 25 mA
TJ=85°C 20 45 mA
TJ=100°C 25 75 mA
Standby mode5 or Sleep
mode6, VCC = 0 V
00µA
ICC3323.3 V analog supplies
current
Operational standby4,
VCC33 = 3.63 V
TJ= 25°C 9.8 13 mA
TJ= 85°C 10.7 14 mA
TJ= 100°C 10.8 15 mA
Operational standby,
only Analog Quad and –3.3 V
output ON, VCC33 = 3.63 V
TJ=25°C 0.31 2 mA
TJ=85°C 0.35 2 mA
TJ= 100°C 0.45 2 mA
Standby mode5,
VCC33 = 3.63 V
TJ= 25°C 2.8 3.6 mA
TJ=85°C 2.9 4 mA
TJ= 100°C 3.5 6 mA
Sleep mode6, VCC33 = 3.63 V TJ=25°C 17 19 µA
TJ=85°C 18 20 µA
TJ= 100°C 24 25 µA
ICCI3I/O quiescent current Operational standby4,
VCCIx = 3.63 V
TJ= 25°C 417 648 µA
TJ= 85°C 417 648 µA
TJ= 100°C 417 649 µA
IJTAG JTAG I/O quiescent current Operational standby4,
VJTAG = 3.63 V
TJ= 25°C 80 100 µA
TJ= 85°C 80 100 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep
mode6, VJTAG = 0 V
00µA
Notes:
1. ICC is the 1.5 V power supplies, ICC and ICC15A.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, ICCI2, and ICCI4.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-13
IPP Programming supply
current
Non-programming mode,
VPUMP = 3.63 V
TJ=25°C 36 80 µA
TJ=85°C 36 80 µA
TJ= 100°C 36 80 µA
Standby mode5 or Sleep
mode6, VPUMP = 0 V
00µA
ICCNVM Embedded NVM current Reset asserted,
VCCNVM = 1.575 V
TJ=25°C 22 80 µA
TJ=85°C 24 80 µA
TJ= 100°C 25 80 µA
ICCPLL 1.5 V PLL quiescent current Operational standby,
VCCPLL = 1.575 V
TJ= 25°C 130 200 µA
TJ= 85°C 130 200 µA
TJ= 100°C 130 200 µA
Table 3-9 • AFS600 Quiescent Supply Current Characteristics (continued)
Parameter Description Conditions Temp. Min Typ Max Unit
Notes:
1. ICC is the 1.5 V power supplies, ICC and ICC15A.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, ICCI2, and ICCI4.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
DC and Power Characteristics
3-14 Revision 4
Table 3-10 • AFS250 Quiescent Supply Current Characteristics
Parameter Description Conditions Temp. Min Typ Max Unit
ICC11.5 V quiescent current Operational standby4,
VCC = 1.575 V
TJ= 25°C 4.8 10 mA
TJ= 85°C 8.2 30 mA
TJ= 100°C 15 50 mA
Standby mode5 or Sleep
mode6, VCC = 0 V
00µA
ICC3323.3 V analog supplies
current
Operational standby4,
VCC33 = 3.63 V
TJ= 25°C 9.8 13 mA
TJ= 85°C 9.8 14 mA
TJ= 100°C 10.8 15 mA
Operational standby, only
Analog Quad and –3.3 V
output ON, VCC33 = 3.63 V
TJ=25°C 0.29 2 mA
TJ=85°C 0.31 2 mA
TJ= 100°C 0.45 2 mA
Standby mode5, VCC33 = 3.63V TJ= 25°C 2.9 3.0 mA
TJ= 85°C 2.9 3.1 mA
TJ= 100°C 3.5 6 mA
Sleep mode6, VCC33 = 3.63 V TJ=25°C 19 18 µA
TJ=85°C 19 20 µA
TJ= 100°C 24 25 µA
ICCI3I/O quiescent current Operational standby6,
VCCIx = 3.63 V
TJ= 25°C 266 437 µA
TJ= 85°C 266 437 µA
TJ= 100°C 266 437 µA
IJTAG JTAG I/O quiescent current Operational standby4,
VJTAG = 3.63 V
TJ= 25°C 80 100 µA
TJ= 85°C 80 100 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep
mode6, VJTAG = 0 V
00µA
Notes:
1. ICC is the 1.5 V power supplies, ICC, ICCPLL, ICC15A, ICCNVM.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, and ICCI2.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTA G = VPUMP = 0 V.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-15
IPP Programming supply
current
Non-programming mode,
VPUMP = 3.63 V
TJ=25°C 37 80 µA
TJ=85°C 37 80 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep
mode6, VPUMP = 0 V
00µA
ICCNVM Embedded NVM current Reset asserted,
VCCNVM = 1.575 V
TJ=25°C 10 40 µA
TJ=85°C 14 40 µA
TJ= 100°C 14 40 µA
ICCPLL 1.5 V PLL quiescent current Operational standby,
VCCPLL = 1.575 V
TJ= 25°C 65 100 µA
TJ= 85°C 65 100 µA
TJ= 100°C 65 100 µA
Table 3-10 • AFS250 Quiescent Supply Current Characteristics (continued)
Parameter Description Conditions Temp. Min Typ Max Unit
Notes:
1. ICC is the 1.5 V power supplies, ICC, ICCPLL, ICC15A, ICCNVM.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, and ICCI2.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTA G = VPUMP = 0 V.
DC and Power Characteristics
3-16 Revision 4
Table 3-11 • AFS090 Quiescent Supply Current Characteristics
Parameter Description Conditions Temp. Min Typ Max Unit
ICC11.5 V quiescent current Operational standby4,
VCC = 1.575 V
TJ= 25°C 5 7.5 mA
TJ= 85°C 6.5 20 mA
TJ= 100°C 14 48 mA
Standby mode5 or Sleep
mode6, VCC = 0 V
00µA
ICC3323.3 V analog supplies
current
Operational standby4,
VCC33 = 3.63 V
TJ= 25°C 9.8 12 mA
TJ= 85°C 9.8 12 mA
TJ= 100°C 10.7 15 mA
Operational standby, only
Analog Quad and –3.3 V
output ON, VCC33 = 3.63 V
TJ=25°C 0.30 2 mA
TJ=85°C 0.30 2 mA
TJ= 100°C 0.45 2 mA
Standby mode5,
VCC33 = 3.63 V
TJ= 25°C 2.9 2.9 mA
TJ= 85°C 2.9 3.0 mA
TJ= 100°C 3.5 6 mA
Sleep mode6, VCC33 = 3.63 V TJ= 25°C 17 18 µA
TJ=85°C 18 20 µA
TJ= 100°C 24 25 µA
ICCI3I/O quiescent current Operational standby6,
VCCIx = 3.63 V
TJ= 25°C 260 437 µA
TJ= 85°C 260 437 µA
TJ= 100°C 260 437 µA
IJTAG JTAG I/O quiescent current Operational standby4,
VJTAG = 3.63 V
TJ= 25°C 80 100 µA
TJ= 85°C 80 100 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep
mode6, VJTAG = 0 V
00µA
IPP Programming supply
current
Non-programming mode,
VPUMP = 3.63 V
TJ=25°C 37 80 µA
TJ=85°C 37 80 µA
TJ= 100°C 80 100 µA
Standby mode5 or Sleep
mode6, VPUMP = 0 V
00µA
Notes:
1. ICC is the 1.5 V power supplies, ICC, ICCPLL, ICC15A, ICCNVM.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, and ICCI2.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-17
ICCNVM Embedded NVM current Reset asserted,
VCCNVM = 1.575 V
TJ=25°C 10 40 µA
TJ=85°C 14 40 µA
TJ= 100°C 14 40 µA
ICCPLL 1.5 V PLL quiescent current Operational standby,
VCCPLL = 1.575 V
TJ= 25°C 65 100 µA
TJ= 85°C 65 100 µA
TJ= 100°C 65 100 µA
Table 3-11 • AFS090 Quiescent Supply Current Characteristics (continued)
Parameter Description Conditions Temp. Min Typ Max Unit
Notes:
1. ICC is the 1.5 V power supplies, ICC, ICCPLL, ICC15A, ICCNVM.
2. ICC33A includes ICC33A, ICC33PMP, and ICCOSC.
3. ICCI includes all ICCI0, ICCI1, and ICCI2.
4. Operational standby is when the Fusion device is powered up, all blocks are used, no I/O is toggling, Voltage Regulator is
loaded with 200 mA, VCC33PMP is ON, XTAL is ON, and ADC is ON.
5. XTAL is configured as high gain, VCC = VJTAG = VPUMP = 0 V.
6. Sleep Mode, VCC = VJTAG = VPUMP = 0 V.
DC and Power Characteristics
3-18 Revision 4
Power per I/O Pin
Table 3-12 • Summary of I/O Input Buffer Power (per pin)—Default I/O Software Settings
VCCI (V)
Static Power
PDC7 (mW)1
Dynamic Power
PAC9 (µW/MHz)2
Applicable to Pro I/O Banks
Single-Ended
3.3 V LVTTL/LVCMOS 3.3 17.39
3.3 V LVTTL/LVCMOS – Schmitt trigger 3.3 25.51
2.5 V LVCMOS 2.5 5.76
2.5 V LVCMOS – Schmitt trigger 2.5 7.16
1.8 V LVCMOS 1.8 2.72
1.8 V LVCMOS – Schmitt trigger 1.8 2.80
1.5 V LVCMOS (JESD8-11) 1.5 2.08
1.5 V LVCMOS (JESD8-11) – Schmitt trigger 1.5 2.00
3.3 V PCI 3.3 18.82
3.3 V PCI – Schmitt trigger 3.3 20.12
3.3 V PCI-X 3.3 18.82
3.3 V PCI-X – Schmitt trigger 3.3 20.12
Voltage-Referenced
3.3 V GTL 3.3 2.90 8.23
2.5 V GTL 2.5 2.13 4.78
3.3 V GTL+ 3.3 2.81 4.14
2.5 V GTL+ 2.5 2.57 3.71
HSTL (I) 1.5 0.17 2.03
HSTL (II) 1.5 0.17 2.03
SSTL2 (I) 2.5 1.38 4.48
SSTL2 (II) 2.5 1.38 4.48
SSTL3 (I) 3.3 3.21 9.26
SSTL3 (II) 3.3 3.21 9.26
Differential
LVDS 2.5 2.26 1.50
LVPECL 3.3 5.71 2.17
Notes:
1. PDC7 is the static power (where applicable) measured on VCCI.
2. PAC9 is the total dynamic power measured on VCC and VCCI.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-19
Applicable to Advanced I/O Banks
Single-Ended
3.3 V LVTTL/LVCMOS 3.3 16.69
2.5 V LVCMOS 2.5 5.12
1.8 V LVCMOS 1.8 2.13
1.5 V LVCMOS (JESD8-11) 1.5 1.45
3.3 V PCI 3.3 18.11
3.3 V PCI-X 3.3 18.11
Differential
LVDS 2.5 2.26 1.20
LVPECL 3.3 5.72 1.87
Applicable to Standard I/O Banks
3.3 V LVTTL/LVCMOS 3.3 16.79
2.5 V LVCMOS 2.5 5.19
1.8 V LVCMOS 1.8 2.18
1.5 V LVCMOS (JESD8-11) 1.5 1.52
Table 3-12 • Summary of I/O Input Buffer Power (per pin)—Default I/O Software Settings (continued)
VCCI (V)
Static Power
PDC7 (mW)1
Dynamic Power
PAC9 (µW/MHz)2
Notes:
1. PDC7 is the static power (where applicable) measured on VCCI.
2. PAC9 is the total dynamic power measured on VCC and VCCI.
DC and Power Characteristics
3-20 Revision 4
Table 3-13 • Summary of I/O Output Buffer Power (per pin)—Default I/O Software Settings1
CLOAD (pF) VCCI (V)
Static Power
PDC8 (mW)2
Dynamic Power
PAC10 (µW/MHz)3
Applicable to Pro I/O Banks
Single-Ended
3.3 V LVTTL/LVCMOS 35 3.3 474.70
2.5 V LVCMOS 35 2.5 270.73
1.8 V LVCMOS 35 1.8 151.78
1.5 V LVCMOS (JESD8-11) 35 1.5 104.55
3.3 V PCI 10 3.3 204.61
3.3 V PCI-X 10 3.3 204.61
Voltage-Referenced
3.3 V GTL 10 3.3 24.08
2.5 V GTL 10 2.5 13.52
3.3 V GTL+ 10 3.3 24.10
2.5 V GTL+ 10 2.5 13.54
HSTL (I) 20 1.5 7.08 26.22
HSTL (II) 20 1.5 13.88 27.22
SSTL2 (I) 30 2.5 16.69 105.56
SSTL2 (II) 30 2.5 25.91 116.60
SSTL3 (I) 30 3.3 26.02 114.87
SSTL3 (II) 30 3.3 42.21 131.76
Differential
LVDS 2.5 7.70 89.62
LVPECL 3.3 19.42 168.02
Applicable to Advanced I/O Banks
Single-Ended
3.3 V LVTTL / 3.3 V LVCMOS 35 3.3 468.67
2.5 V LVCMOS 35 2.5 267.48
1.8 V LVCMOS 35 1.8 149.46
1.5 V LVCMOS (JESD8-11) 35 1.5 103.12
3.3 V PCI 10 3.3 201.02
3.3 V PCI-X 10 3.3 201.02
Notes:
1. Dynamic power consumption is given for standard load and software-default drive strength and output slew.
2. PDC8 is the static power (where applicable) measured on VCCI.
3. PAC10 is the total dynamic power measured on VCC and VCCI.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-21
Differential
LVDS 2.5 7.74 88.92
LVPECL 3.3 19.54 166.52
Applicable to Standard I/O Banks
Single-Ended
3.3 V LVTTL / 3.3 V LVCMOS 35 3.3 431.08
2.5 V LVCMOS 35 2.5 247.36
1.8 V LVCMOS 35 1.8 128.46
1.5 V LVCMOS (JESD8-11) 35 1.5 89.46
Table 3-13 • Summary of I/O Output Buffer Power (per pin)—Default I/O Software Settings1 (continued)
CLOAD (pF) VCCI (V)
Static Power
PDC8 (mW)2
Dynamic Power
PAC10 (µW/MHz)3
Notes:
1. Dynamic power consumption is given for standard load and software-default drive strength and output slew.
2. PDC8 is the static power (where applicable) measured on VCCI.
3. PAC10 is the total dynamic power measured on VCC and VCCI.
DC and Power Characteristics
3-22 Revision 4
Dynamic Power Consumption of Various Internal Resources
Table 3-14 • Different Components Contributing to the Dynamic Power Consumption in Fusion Devices
Parameter Definition
Power Supply
Device-Specific
Dynamic Contributions
UnitsName Setting AFS1500 AFS600 AFS250 AFS090
PAC1 Clock contribution of a Global
Rib
VCC 1.5 V 14.5 12.8 11 11 µW/MHz
PAC2 Clock contribution of a Global
Spine
VCC 1.5 V 2.5 1.9 1.6 0.8 µW/MHz
PAC3 Clock contribution of a VersaTile
row
VCC 1.5 V 0.81 µW/MHz
PAC4 Clock contribution of a VersaTile
used as a sequential module
VCC 1.5 V 0.11 µW/MHz
PAC5 First contribution of a VersaTile
used as a sequential module
VCC 1.5 V 0.07 µW/MHz
PAC6 Second contribution of a
VersaTile used as a sequential
module
VCC 1.5 V 0.29 µW/MHz
PAC7 Contribution of a VersaTile used
as a combinatorial module
VCC 1.5 V 0.29 µW/MHz
PAC8 Average contribution of a routing
net
VCC 1.5 V 0.70 µW/MHz
PAC9 Contribution of an I/O input pin
(standard dependent)
VCCI See Table 3-12 on page 3-18
PAC10 Contribution of an I/O output pin
(standard dependent)
VCCI See Table 3-13 on page 3-20
PAC11 Average contribution of a RAM
block during a read operation
VCC 1.5 V 25 µW/MHz
PAC12 Average contribution of a RAM
block during a write operation
VCC 1.5 V 30 µW/MHz
PAC13 Dynamic Contribution for PLL VCC 1.5 V 2.6 µW/MHz
PAC15 Contribution of NVM block during
a read operation (F < 33MHz)
VCC 1.5 V 358 µW/MHz
PAC16 1st contribution of NVM block
during a read operation (F > 33
MHz)
VCC 1.5 V 12.88 mW
PAC17 2nd contribution of NVM block
during a read operation (F > 33
MHz)
VCC 1.5 V 4.8 µW/MHz
PAC18 Crystal Oscillator contribution VCC33A 3.3 V 0.63 mW
PAC19 RC Oscillator contribution VCC33A 3.3 V 3.3 mW
PAC20 Analog Block dynamic power
contribution of ADC
VCC 1.5 V 3 mW
Fusion Family of Mixed Signal FPGAs
Revision 4 3-23
Static Power Consumption of Various Internal Resources
Power Calculation Methodology
This section describes a simplified method to estimate power consumption of an application. For more
accurate and detailed power estimations, use the SmartPower tool in the Libero SoC software.
The power calculation methodology described below uses the following variables:
The number of PLLs as well as the number and the frequency of each output clock generated
The number of combinatorial and sequential cells used in the design
The internal clock frequencies
The number and the standard of I/O pins used in the design
The number of RAM blocks used in the design
The number of NVM blocks used in the design
The number of Analog Quads used in the design
Toggle rates of I/O pins as well as VersaTiles—guidelines are provided in Table 3-16 on
page 3-27.
Enable rates of output buffers—guidelines are provided for typical applications in Table 3-17 on
page 3-27.
Read rate and write rate to the RAM—guidelines are provided for typical applications in
Table 3-17 on page 3-27.
Read rate to the NVM blocks
The calculation should be repeated for each clock domain defined in the design.
Table 3-15 • Different Components Contributing to the Static Power Consumption in Fusion Devices
Parameter Definition
Power
Supply
Device-Specific Static Contributions
UnitsAFS1500 AFS600 AFS250 AFS090
PDC1 Core static power contribution in
operating mode
VCC 1.5 V 18 7.5 4.50 3.00 mW
PDC2 Device static power contribution in
standby mode
VCC33A 3.3 V 0.66 mW
PDC3 Device static power contribution in
sleep mode
VCC33A 3.3 V 0.03 mW
PDC4 NVM static power contribution VCC 1.5 V 1.19 mW
PDC5 Analog Block static power
contribution of ADC
VCC33A 3.3 V 8.25 mW
PDC6 Analog Block static power
contribution per Quad
VCC33A 3.3 V 3.3 mW
PDC7 Static contribution per input pin –
standard dependent contribution
VCCI See Table 3-12 on page 3-18
PDC8 Static contribution per input pin –
standard dependent contribution
VCCI See Table 3-13 on page 3-20
PDC9 Static contribution for PLL VCC 1.5 V 2.55 mW
DC and Power Characteristics
3-24 Revision 4
Methodology
Total Power Consumption—PTOTAL
Operating Mode, Standby Mode, and Sleep Mode
PTOTAL = PSTAT + PDYN
PSTAT is the total static power consumption.
PDYN is the total dynamic power consumption.
Total Static Power Consumption—PSTAT
Operating Mode
PSTAT = PDC1 + (NNVM-BLOCKS * PDC4) + PDC5+ (NQUADS * PDC6) + (NINPUTS * PDC7) +
(NOUTPUTS * PDC8) + (NPLLS * PDC9)
NNVM-BLOCKS is the number of NVM blocks available in the device.
NQUADS is the number of Analog Quads used in the design.
NINPUTS is the number of I/O input buffers used in the design.
NOUTPUTS is the number of I/O output buffers used in the design.
NPLLS is the number of PLLs available in the device.
Standby Mode
PSTAT = PDC2
Sleep Mode
PSTAT = PDC3
Total Dynamic Power Consumption—PDYN
Operating Mode
PDYN = PCLOCK + PS-CELL + PC-CELL + PNET + PINPUTS + POUTPUTS + PMEMORY + PPLL + PNVM+
PXTL-OSC + PRC-OSC + PAB
Standby Mode
PDYN = PXTL-OSC
Sleep Mode
PDYN = 0 W
Global Clock Dynamic Contribution—PCLOCK
Operating Mode
PCLOCK = (PAC1 + NSPINE * PAC2 + NROW * PAC3 + NS-CELL * PAC4) * FCLK
NSPINE is the number of global spines used in the user design—guidelines are provided in the
"Spine Architecture" section of the Global Resources chapter in the Fusion and Extended
Temperature Fusion FPGA Fabric User's Guide.
NROW is the number of VersaTile rows used in the design—guidelines are provided in the "Spine
Architecture" section of the Global Resources chapter in the Fusion and Extended Temperature
Fusion FPGA Fabric User's Guide.
FCLK is the global clock signal frequency.
NS-CELL is the number of VersaTiles used as sequential modules in the design.
Standby Mode and Sleep Mode
PCLOCK = 0 W
Sequential Cells Dynamic Contribution—PS-CELL
Operating Mode
Fusion Family of Mixed Signal FPGAs
Revision 4 3-25
PS-CELL = NS-CELL * (PAC5 + (1 / 2) * PAC6) * FCLK
NS-CELL is the number of VersaTiles used as sequential modules in the design. When a multi-tile
sequential cell is used, it should be accounted for as 1.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 3-16 on page 3-27.
FCLK is the global clock signal frequency.
Standby Mode and Sleep Mode
PS-CELL = 0 W
Combinatorial Cells Dynamic Contribution—PC-CELL
Operating Mode
PC-CELL = NC-CELL* (1 / 2) * PAC7 * FCLK
NC-CELL is the number of VersaTiles used as combinatorial modules in the design.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 3-16 on page 3-27.
FCLK is the global clock signal frequency.
Standby Mode and Sleep Mode
PC-CELL = 0 W
Routing Net Dynamic Contribution—PNET
Operating Mode
PNET = (NS-CELL + NC-CELL) * (1 / 2) * PAC8 * FCLK
NS-CELL is the number VersaTiles used as sequential modules in the design.
NC-CELL is the number of VersaTiles used as combinatorial modules in the design.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 3-16 on page 3-27.
FCLK is the global clock signal frequency.
Standby Mode and Sleep Mode
PNET = 0 W
I/O Input Buffer Dynamic Contribution—PINPUTS
Operating Mode
PINPUTS = NINPUTS * (2 / 2) * PAC9 * FCLK
NINPUTS is the number of I/O input buffers used in the design.
2 is the I/O buffer toggle rate—guidelines are provided in Table 3-16 on page 3-27.
FCLK is the global clock signal frequency.
Standby Mode and Sleep Mode
PINPUTS = 0 W
I/O Output Buffer Dynamic Contribution—POUTPUTS
Operating Mode
POUTPUTS = NOUTPUTS * (2 / 2) * 1 * PAC10 * FCLK
NOUTPUTS is the number of I/O output buffers used in the design.
2 is the I/O buffer toggle rate—guidelines are provided in Table 3-16 on page 3-27.
1 is the I/O buffer enable rate—guidelines are provided in Table 3-17 on page 3-27.
FCLK is the global clock signal frequency.
Standby Mode and Sleep Mode
POUTPUTS = 0 W
DC and Power Characteristics
3-26 Revision 4
RAM Dynamic Contribution—PMEMORY
Operating Mode
PMEMORY = (NBLOCKS * PAC11 * 2 * FREAD-CLOCK) + (NBLOCKS * PAC12 * 3 * FWRITE-CLOCK)
NBLOCKS is the number of RAM blocks used in the design.
FREAD-CLOCK is the memory read clock frequency.
2 is the RAM enable rate for read operations—guidelines are provided in Table 3-17 on
page 3-27.
3 the RAM enable rate for write operations—guidelines are provided in Table 3-17 on page 3-27.
FWRITE-CLOCK is the memory write clock frequency.
Standby Mode and Sleep Mode
PMEMORY = 0 W
PLL/CCC Dynamic Contribution—PPLL
Operating Mode
PPLL = PAC13 * FCLKOUT
FCLKIN is the input clock frequency.
FCLKOUT is the output clock frequency.1
Standby Mode and Sleep Mode
PPLL = 0 W
Nonvolatile Memory Dynamic Contribution—PNVM
Operating Mode
The NVM dynamic power consumption is a piecewise linear function of frequency.
PNVM = NNVM-BLOCKS * 4 * PAC15 * FREAD-NVM when FREAD-NVM 33 MHz,
PNVM = NNVM-BLOCKS * 4 *(PAC16 + PAC17 * FREAD-NVM when FREAD-NVM > 33 MHz
NNVM-BLOCKS is the number of NVM blocks used in the design (2 inAFS600).
4 is the NVM enable rate for read operations. Default is 0 (NVM mainly in idle state).
FREAD-NVM is the NVM read clock frequency.
Standby Mode and Sleep Mode
PNVM = 0 W
Crystal Oscillator Dynamic Contribution—PXTL-OSC
Operating Mode
PXTL-OSC = PAC18
Standby Mode
PXTL-OSC = PAC18
Sleep Mode
PXTL-OSC = 0 W
1. The PLL dynamic contribution depends on the input clock frequency, the number of output clock signals generated by the
PLL, and the frequency of each output clock. If a PLL is used to generate more than one output clock, include each output
clock in the formula output clock by adding its corresponding contribution (PAC14 * FCLKOUT product) to the total PLL
contribution.
Fusion Family of Mixed Signal FPGAs
Revision 4 3-27
RC Oscillator Dynamic Contribution—PRC-OSC
Operating Mode
PRC-OSC = PAC19
Standby Mode and Sleep Mode
PRC-OSC = 0 W
Analog System Dynamic Contribution—PAB
Operating Mode
PAB = PAC20
Standby Mode and Sleep Mode
PAB = 0 W
Guidelines
Toggle Rate Definition
A toggle rate defines the frequency of a net or logic element relative to a clock. It is a percentage. If the
toggle rate of a net is 100%, this means that the net switches at half the clock frequency. Below are some
examples:
The average toggle rate of a shift register is 100%, as all flip-flop outputs toggle at half of the clock
frequency.
The average toggle rate of an 8-bit counter is 25%:
Bit 0 (LSB) = 100%
Bit 1 = 50%
Bit 2 = 25%
–…
Bit 7 (MSB) = 0.78125%
Average toggle rate = (100% + 50% + 25% + 12.5% + . . . 0.78125%) / 8.
Enable Rate Definition
Output enable rate is the average percentage of time during which tristate outputs are enabled. When
non-tristate output buffers are used, the enable rate should be 100%.
Table 3-16 • Toggle Rate Guidelines Recommended for Power Calculation
Component Definition Guideline
1 Toggle rate of VersaTile outputs 10%
2 I/O buffer toggle rate 10%
Table 3-17 • Enable Rate Guidelines Recommended for Power Calculation
Component Definition Guideline
1 I/O output buffer enable rate 100%
2 RAM enable rate for read operations 12.5%
3RAM enable rate for write operations 12.5%
4 NVM enable rate for read operations 0%
DC and Power Characteristics
3-28 Revision 4
Example of Power Calculation
This example considers a shift register with 5,000 storage tiles, including a counter and memory that
stores analog information. The shift register is clocked at 50 MHz and stores and reads information from
a RAM.
The device used is a commercial AFS600 device operating in typical conditions.
The calculation below uses the power calculation methodology previously presented and shows how to
determine the dynamic and static power consumption of resources used in the application.
Also included in the example is the calculation of power consumption in operating, standby, and sleep
modes to illustrate the benefit of power-saving modes.
Global Clock Contribution—PCLOCK
FCLK = 50 MHz
Number of sequential VersaTiles: NS-CELL = 5,000
Estimated number of Spines: NSPINES = 5
Estimated number of Rows: NROW = 313
Operating Mode
PCLOCK = (PAC1 + NSPINE * PAC2 + NROW * PAC3 + NS-CELL * PAC4) * FCLK
PCLOCK = (0.0128 + 5 * 0.0019 + 313 * 0.00081 + 5,000 * 0.00011) * 50
PCLOCK = 41.28 mW
Standby Mode and Sleep Mode
PCLOCK = 0 W
Logic—Sequential Cells, Combinational Cells, and Routing Net Contributions—PS-CELL,
PC-CELL, and PNET
FCLK = 50 MHz
Number of sequential VersaTiles: NS-CELL = 5,000
Number of combinatorial VersaTiles: NC-CELL = 6,000
Estimated toggle rate of VersaTile outputs: 1 = 0.1 (10%)
Operating Mode
PS-CELL = NS-CELL * (PAC5+ (1 / 2) * PAC6) * FCLK
PS-CELL = 5,000 * (0.00007 + (0.1 / 2) * 0.00029) * 50
PS-CELL = 21.13 mW
PC-CELL = NC-CELL* (1 / 2) * PAC7 * FCLK
PC-CELL = 6,000 * (0.1 / 2) * 0.00029 * 50
PC-CELL = 4.35 mW
PNET = (NS-CELL + NC-CELL) * (1 / 2) * PAC8 * FCLK
PNET = (5,000 + 6,000) * (0.1 / 2) * 0.0007 * 50
PNET = 19.25 mW
PLOGIC = PS-CELL + PC-CELL + PNET
PLOGIC = 21.13 mW + 4.35 mW + 19.25 mW
PLOGIC = 44.73 mW
Standby Mode and Sleep Mode
Fusion Family of Mixed Signal FPGAs
Revision 4 3-29
PS-CELL = 0 W
PC-CELL = 0 W
PNET = 0 W
PLOGIC = 0 W
I/O Input and Output Buffer Contribution—PI/O
This example uses LVTTL 3.3 V I/O cells. The output buffers are 12 mA–capable, configured with high
output slew and driving a 35 pF output load.
FCLK = 50 MHz
Number of input pins used: NINPUTS = 30
Number of output pins used: NOUTPUTS = 40
Estimated I/O buffer toggle rate: 2 = 0.1 (10%)
Estimated IO buffer enable rate: 1 = 1 (100%)
Operating Mode
PINPUTS = NINPUTS * (2 / 2) * PAC9 * FCLK
PINPUTS = 30 * (0.1 / 2) * 0.01739 * 50
PINPUTS = 1.30 mW
POUTPUTS = NOUTPUTS * (2 / 2) * 1 * PAC10 * FCLK
POUTPUTS = 40 * (0.1 / 2) * 1 * 0.4747 * 50
POUTPUTS = 47.47 mW
PI/O = PINPUTS + POUTPUTS
PI/O = 1.30 mW + 47.47 mW
PI/O = 48.77 mW
Standby Mode and Sleep Mode
PINPUTS = 0 W
POUTPUTS = 0 W
PI/O = 0 W
RAM Contribution—PMEMORY
Frequency of Read Clock: FREAD-CLOCK = 10 MHz
Frequency of Write Clock: FWRITE-CLOCK = 10 MHz
Number of RAM blocks: NBLOCKS = 20
Estimated RAM Read Enable Rate: 2 = 0.125 (12.5%)
Estimated RAM Write Enable Rate: 3 = 0.125 (12.5%)
Operating Mode
PMEMORY = (NBLOCKS * PAC11 * 2 * FREAD-CLOCK) + (NBLOCKS * PAC12 * 3 * FWRITE-CLOCK)
PMEMORY = (20 * 0.025 * 0.125 * 10) + (20 * 0.030 * 0.125 * 10)
PMEMORY = 1.38 mW
Standby Mode and Sleep Mode
PMEMORY = 0 W
DC and Power Characteristics
3-30 Revision 4
PLL/CCC Contribution—PPLL
PLL is not used in this application.
PPLL = 0 W
Nonvolatile Memory—PNVM
Nonvolatile memory is not used in this application.
PNVM = 0 W
Crystal Oscillator—PXTL-OSC
The application utilizes standby mode. The crystal oscillator is assumed to be active.
Operating Mode
PXTL-OSC = PAC18
PXTL-OSC = 0.63 mW
Standby Mode
PXTL-OSC = PAC18
PXTL-OSC = 0.63 mW
Sleep Mode
PXTL-OSC = 0 W
RC Oscillator—PRC-OSC
Operating Mode
PRC-OSC = PAC19
PRC-OSC = 3.30 mW
Standby Mode and Sleep Mode
PRC-OSC = 0 W
Analog System—PAB
Number of Quads used: NQUADS = 4
Operating Mode
PAB = PAC20
PAB = 3.00 mW
Standby Mode and Sleep Mode
PAB = 0 W
Total Dynamic Power Consumption—PDYN
Operating Mode
PDYN = PCLOCK + PS-CELL + PC-CELL + PNET + PINPUTS + POUTPUTS + PMEMORY + PPLL + PNVM+
PXTL-OSC + PRC-OSC + PAB
PDYN = 41.28 mW + 21.1 mW + 4.35 mW + 19.25 mW + 1.30 mW + 47.47 mW + 1.38 mW + 0 + 0 +
0.63 mW + 3.30 mW + 3.00 mW
PDYN = 143.06 mW
Standby Mode
PDYN = PXTL-OSC
PDYN = 0.63 mW
Sleep Mode
PDYN = 0 W
Fusion Family of Mixed Signal FPGAs
Revision 4 3-31
Total Static Power Consumption—PSTAT
Number of Quads used: NQUADS = 4
Number of NVM blocks available (AFS600): NNVM-BLOCKS = 2
Number of input pins used: NINPUTS = 30
Number of output pins used: NOUTPUTS = 40
Operating Mode
PSTAT = PDC1 + (NNVM-BLOCKS * PDC4) + PDC5 + (NQUADS * PDC6) + (NINPUTS * PDC7) +
(NOUTPUTS * PDC8)
PSTAT = 7.50 mW + (2 * 1.19 mW) + 8.25 mW + (4 * 3.30 mW) + (30 * 0.00) + (40 * 0.00)
PSTAT = 31.33 mW
Standby Mode
PSTAT = PDC2
PSTAT = 0.03 mW
Sleep Mode
PSTAT = PDC3
PSTAT = 0.03 mW
Total Power Consumption—PTOTAL
In operating mode, the total power consumption of the device is 174.39 mW:
PTOTAL = PSTAT + PDYN
PTOTAL = 143.06 mW + 31.33 mW
PTOTAL = 174.39 mW
In standby mode, the total power consumption of the device is limited to 0.66 mW:
PTOTAL = PSTAT + PDYN
PTOTAL = 0.03 mW + 0.63 mW
PTOTAL = 0.66 mW
In sleep mode, the total power consumption of the device drops as low as 0.03 mW:
PTOTAL = PSTAT + PDYN
PTOTAL = 0.03 mW
DC and Power Characteristics
3-32 Revision 4
Power Consumption
Table 3-18 • Power Consumption
Parameter Description Condition Min. Typical Max. Units
Crystal Oscillator
ISTBXTAL Standby Current of Crystal
Oscillator
10 µA
IDYNXTAL Operating Current RC 0.6 mA
0.032–0.2 0.19 mA
0.2–2.0 0.6 mA
2.0–20.0 0.6 mA
RC Oscillator
IDYNRC Operating Current 1 mA
ACM
Operating Current (fixed
clock)
200 µA/MHz
Operating Current (user
clock)
30 µA
NVM System
NVM Array Operating Power Idle 795 µA
Read
operation
See
Table 3-15 on
page 3-23.
See
Table 3-15 on
page 3-23.
Erase 900 µA
Write 900 µA
PNVMCTRL NVM Controller Operating
Power
20 µW/MHz
Revision 4 4-1
4 – Package Pin Assignments
QN108
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/default.aspx.
Note: The die attach paddle center of the package is tied to ground (GND).
A1
B41 B52
A44 A56
B26 B14
A28 A15
A14
B1
B13
A43
A29
B40
B27
Pin A1 Mark
Package Pin Assignments
4-2 Revision 4
QN108
Pin Number AFS090 Function
A1 NC
A2 GNDQ
A3 GAA2/IO52PDB3V0
A4 GND
A5 GFA1/IO47PDB3V0
A6 GEB1/IO45PDB3V0
A7 VCCOSC
A8 XTAL2
A9 GEA1/IO44PPB3V0
A10 GEA0/IO44NPB3V0
A11 GEB2/IO42PDB3V0
A12 VCCNVM
A13 VCC15A
A14 PCAP
A15 NC
A16 GNDA
A17 AV0
A18 AG0
A19 ATRTN0
A20 AT1
A21 AC1
A22 AV2
A23 AG2
A24 AT2
A25 AT3
A26 AC3
A27 GNDAQ
A28 ADCGNDREF
A29 NC
A30 GNDA
A31 PTEM
A32 GNDNVM
A33 VPUMP
A34 TCK
A35 TMS
A36 TRST
A37 GDB1/IO39PSB1V0
A38 GDC1/IO38PDB1V0
A39 GND
A40 GCB1/IO35PDB1V0
A41 GCB2/IO33PDB1V0
A42 GBA2/IO31PDB1V0
A43 NC
A44 GBA1/IO30RSB0V0
A45 GBB1/IO28RSB0V0
A46 GND
A47 VCC
A48 GBC1/IO26RSB0V0
A49 IO21RSB0V0
A50 IO19RSB0V0
A51 IO09RSB0V0
A52 GAC0/IO04RSB0V0
A53 VCCIB0
A54 GND
A55 GAB0/IO02RSB0V0
A56 GAA0/IO00RSB0V0
B1 VCOMPLA
B2 VCCIB3
B3 GAB2/IO52NDB3V0
B4 VCCIB3
B5 GFA0/IO47NDB3V0
B6 GEB0/IO45NDB3V0
B7 XTAL1
B8 GNDOSC
B9 GEC2/IO43PSB3V0
B10 GEA2/IO42NDB3V0
B11 VCC
B12 GNDNVM
B13 NCAP
B14 VCC33PMP
B15 VCC33N
B16 GNDAQ
B17 AC0
B18 AT0
B19 AG1
B20 AV1
QN108
Pin Number AFS090 Function
B21 AC2
B22 ATRTN1
B23 AG3
B24 AV3
B25 VCC33A
B26 VAREF
B27 PUB
B28 VCC33A
B29 PTBASE
B30 VCCNVM
B31 VCC
B32 TDI
B33 TDO
B34 VJTAG
B35 GDC0/IO38NDB1V
0
B36 VCCIB1
B37 GCB0/IO35NDB1V0
B38 GCC2/IO33NDB1V
0
B39 GBB2/IO31NDB1V0
B40 VCCIB1
B41 GNDQ
B42 GBA0/IO29RSB0V0
B43 VCCIB0
B44 GBB0/IO27RSB0V0
B45 GBC0/IO25RSB0V0
B46 IO20RSB0V0
B47 IO10RSB0V0
B48 GAC1/IO05RSB0V0
B49 GAB1/IO03RSB0V0
B50 VCC
B51 GAA1/IO01RSB0V0
B52 VCCPLA
QN108
Pin Number AFS090 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-3
QN180
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/default.aspx.
Note: The die attach paddle center of the package is tied to ground (GND).
A1
B1
C1
A16
B15
C14
A48
Pin A1 Mark
Optional Corner
Pad (4X)
A49 A64
A32 A17
B45
B46 B60
B30 B16
C42
C43 C56
C28 C15
A33 B31
C29
D4
D3
D1
D2
Package Pin Assignments
4-4 Revision 4
QN180
Pin Number AFS090 Function AFS250 Function
A1 GNDQ GNDQ
A2 VCCIB3 VCCIB3
A3 GAB2/IO52NDB3V0 IO74NDB3V0
A4 GFA2/IO51NDB3V0 IO71NDB3V0
A5 GFC2/IO50NDB3V0 IO69NPB3V0
A6 VCCIB3 VCCIB3
A7 GFA1/IO47PPB3V0 GFB1/IO67PPB3V0
A8 GEB0/IO45NDB3V0 NC
A9 XTAL1 XTAL1
A10 GNDOSC GNDOSC
A11 GEC2/IO43PPB3V0 GEA1/IO61PPB3V0
A12 IO43NPB3V0 GEA0/IO61NPB3V0
A13 NC VCCIB3
A14 GNDNVM GNDNVM
A15 PCAP PCAP
A16 VCC33PMP VCC33PMP
A17 NC NC
A18 AV0 AV0
A19 AG0 AG0
A20 ATRTN0 ATRTN0
A21 AG1 AG1
A22 AC1 AC1
A23 AV2 AV2
A24 AT2 AT2
A25 AT3 AT3
A26 AC3 AC3
A27 AV4 AV4
A28 AC4 AC4
A29 AT4 AT4
A30 NC AG5
A31 NC AV5
A32 ADCGNDREF ADCGNDREF
A33 VCC33A VCC33A
A34 GNDA GNDA
A35 PTBASE PTBASE
A36 VCCNVM VCCNVM
A37 VPUMP VPUMP
A38 TDI TDI
A39 TDO TDO
A40 VJTAG VJTAG
A41 GDB1/IO39PPB1V0 GDA1/IO54PPB1V0
A42 GDC1/IO38PDB1V0 GDB1/IO53PDB1V0
A43 VCC VCC
A44 GCB0/IO35NPB1V0 GCB0/IO48NPB1V0
A45 GCC1/IO34PDB1V0 GCC1/IO47PDB1V0
A46 VCCIB1 VCCIB1
A47 GBC2/IO32PPB1V0 GBB2/IO41PPB1V0
A48 VCCIB1 VCCIB1
A49 NC NC
A50 GBA0/IO29RSB0V0 GBB1/IO37RSB0V0
A51 VCCIB0 VCCIB0
A52 GBB0/IO27RSB0V0 GBC0/IO34RSB0V0
A53 GBC1/IO26RSB0V0 IO33RSB0V0
A54 IO24RSB0V0 IO29RSB0V0
A55 IO21RSB0V0 IO26RSB0V0
A56 VCCIB0 VCCIB0
A57 IO15RSB0V0 IO21RSB0V0
A58 IO10RSB0V0 IO13RSB0V0
A59 IO07RSB0V0 IO10RSB0V0
A60 GAC0/IO04RSB0V0 IO06RSB0V0
A61 GAB1/IO03RSB0V0 GAC1/IO05RSB0V0
A62 VCC VCC
A63 GAA1/IO01RSB0V0 GAB0/IO02RSB0V0
A64 NC NC
B1 VCOMPLA VCOMPLA
B2 GAA2/IO52PDB3V0 GAC2/IO74PDB3V0
B3 GAC2/IO51PDB3V0 GFA2/IO71PDB3V0
B4 GFB2/IO50PDB3V0 GFB2/IO70PSB3V0
B5 VCC VCC
B6 GFC0/IO49NDB3V0 GFC0/IO68NDB3V0
B7 GEB1/IO45PDB3V0 NC
B8 VCCOSC VCCOSC
QN180
Pin Number AFS090 Function AFS250 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-5
B9 XTAL2 XTAL2
B10 GEA0/IO44NDB3V0 GFA0/IO66NDB3V0
B11 GEB2/IO42PDB3V0 IO60NDB3V0
B12 VCC VCC
B13 VCCNVM VCCNVM
B14 VCC15A VCC15A
B15 NCAP NCAP
B16 VCC33N VCC33N
B17 GNDAQ GNDAQ
B18 AC0 AC0
B19 AT0 AT0
B20 AT1 AT1
B21 AV1 AV1
B22 AC2 AC2
B23 ATRTN1 ATRTN1
B24 AG3 AG3
B25 AV3 AV3
B26 AG4 AG4
B27 ATRTN2 ATRTN2
B28 NC AC5
B29 VCC33A VCC33A
B30 VAREF VAREF
B31 PUB PUB
B32 PTEM PTEM
B33 GNDNVM GNDNVM
B34 VCC VCC
B35 TCK TCK
B36 TMS TMS
B37 TRST TRST
B38 GDB2/IO41PSB1V0 GDA2/IO55PSB1V0
B39 GDC0/IO38NDB1V0 GDB0/IO53NDB1V0
B40 VCCIB1 VCCIB1
B41 GCA1/IO36PDB1V0 GCA1/IO49PDB1V0
B42 GCC0/IO34NDB1V0 GCC0/IO47NDB1V0
B43 GCB2/IO33PSB1V0 GBC2/IO42PSB1V0
B44 VCC VCC
QN180
Pin Number AFS090 Function AFS250 Function
B45 GBA2/IO31PDB1V0 GBA2/IO40PDB1V0
B46 GNDQ GNDQ
B47 GBA1/IO30RSB0V0 GBA0/IO38RSB0V0
B48 GBB1/IO28RSB0V0 GBC1/IO35RSB0V0
B49 VCC VCC
B50 GBC0/IO25RSB0V0 IO31RSB0V0
B51 IO23RSB0V0 IO28RSB0V0
B52 IO20RSB0V0 IO25RSB0V0
B53 VCC VCC
B54 IO11RSB0V0 IO14RSB0V0
B55 IO08RSB0V0 IO11RSB0V0
B56 GAC1/IO05RSB0V0 IO08RSB0V0
B57 VCCIB0 VCCIB0
B58 GAB0/IO02RSB0V0 GAC0/IO04RSB0V0
B59 GAA0/IO00RSB0V0 GAA1/IO01RSB0V0
B60 VCCPLA VCCPLA
C1 NC NC
C2 NC VCCIB3
C3 GND GND
C4 NC GFC2/IO69PPB3V0
C5 GFC1/IO49PDB3V0 GFC1/IO68PDB3V0
C6 GFA0/IO47NPB3V0 GFB0/IO67NPB3V0
C7 VCCIB3 NC
C8 GND GND
C9 GEA1/IO44PDB3V0 GFA1/IO66PDB3V0
C10 GEA2/IO42NDB3V0 GEC2/IO60PDB3V0
C11 NC GEA2/IO58PSB3V0
C12 NC NC
C13 GND GND
C14 NC NC
C15 NC NC
C16 GNDA GNDA
C17 NC NC
C18 NC NC
C19 NC NC
C20 NC NC
QN180
Pin Number AFS090 Function AFS250 Function
Package Pin Assignments
4-6 Revision 4
C21 AG2 AG2
C22 NC NC
C23 NC NC
C24 NC NC
C25 NC AT5
C26 GNDAQ GNDAQ
C27 NC NC
C28 NC NC
C29 NC NC
C30 NC NC
C31 GND GND
C32 NC NC
C33 NC NC
C34 NC NC
C35 GND GND
C36 GDB0/IO39NPB1V0 GDA0/IO54NPB1V0
C37 GDA1/IO37NSB1V0 GDC0/IO52NSB1V0
C38 GCA0/IO36NDB1V0 GCA0/IO49NDB1V0
C39 GCB1/IO35PPB1V0 GCB1/IO48PPB1V0
C40 GND GND
C41 GCA2/IO32NPB1V0 IO41NPB1V0
C42 GBB2/IO31NDB1V0 IO40NDB1V0
C43 NC NC
C44 NC GBA1/IO39RSB0V0
C45 NC GBB0/IO36RSB0V0
C46 GND GND
C47 NC IO30RSB0V0
C48 IO22RSB0V0 IO27RSB0V0
C49 GND GND
C50 IO13RSB0V0 IO16RSB0V0
C51 IO09RSB0V0 IO12RSB0V0
C52 IO06RSB0V0 IO09RSB0V0
C53 GND GND
C54 NC GAB1/IO03RSB0V0
C55 NC GAA0/IO00RSB0V0
C56 NC NC
QN180
Pin Number AFS090 Function AFS250 Function
D1 NC NC
D2 NC NC
D3 NC NC
D4 NC NC
QN180
Pin Number AFS090 Function AFS250 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-7
PQ208
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/default.aspx.
208-Pin PQFP
1208
Package Pin Assignments
4-8 Revision 4
PQ208
Pin
Number AFS250 Function AFS600 Function
1 VCCPLA VCCPLA
2 VCOMPLA VCOMPLA
3 GNDQ GAA2/IO85PDB4V0
4 VCCIB3 IO85NDB4V0
5 GAA2/IO76PDB3V0 GAB2/IO84PDB4V0
6 IO76NDB3V0 IO84NDB4V0
7 GAB2/IO75PDB3V0 GAC2/IO83PDB4V0
8 IO75NDB3V0 IO83NDB4V0
9NCIO77PDB4V0
10 NC IO77NDB4V0
11 VCC IO76PDB4V0
12 GND IO76NDB4V0
13 VCCIB3 VCC
14 IO72PDB3V0 GND
15 IO72NDB3V0 VCCIB4
16 GFA2/IO71PDB3V0 GFA2/IO75PDB4V0
17 IO71NDB3V0 IO75NDB4V0
18 GFB2/IO70PDB3V0 GFC2/IO73PDB4V0
19 IO70NDB3V0 IO73NDB4V0
20 GFC2/IO69PDB3V0 VCCOSC
21 IO69NDB3V0 XTAL1
22 VCC XTAL2
23 GND GNDOSC
24 VCCIB3 GFC1/IO72PDB4V0
25 GFC1/IO68PDB3V0 GFC0/IO72NDB4V0
26 GFC0/IO68NDB3V0 GFB1/IO71PDB4V0
27 GFB1/IO67PDB3V0 GFB0/IO71NDB4V0
28 GFB0/IO67NDB3V0 GFA1/IO70PDB4V0
29 VCCOSC GFA0/IO70NDB4V0
30 XTAL1 IO69PDB4V0
31 XTAL2 IO69NDB4V0
32 GNDOSC VCC
33 GEB1/IO62PDB3V0 GND
34 GEB0/IO62NDB3V0 VCCIB4
35 GEA1/IO61PDB3V0 GEC1/IO63PDB4V0
36 GEA0/IO61NDB3V0 GEC0/IO63NDB4V0
37 GEC2/IO60PDB3V0 GEB1/IO62PDB4V0
38 IO60NDB3V0 GEB0/IO62NDB4V0
39 GND GEA1/IO61PDB4V0
40 VCCIB3 GEA0/IO61NDB4V0
41 GEB2/IO59PDB3V0 GEC2/IO60PDB4V0
42 IO59NDB3V0 IO60NDB4V0
43 GEA2/IO58PDB3V0 VCCIB4
44 IO58NDB3V0 GNDQ
45 VCC VCC
45 VCC VCC
46 VCCNVM VCCNVM
47 GNDNVM GNDNVM
48 GND GND
49 VCC15A VCC15A
50 PCAP PCAP
51 NCAP NCAP
52 VCC33PMP VCC33PMP
53 VCC33N VCC33N
54 GNDA GNDA
55 GNDAQ GNDAQ
56 NC AV0
57 NC AC0
58 NC AG0
59 NC AT0
60 NC ATRTN0
61 NC AT1
62 NC AG1
63 NC AC1
64 NC AV1
65 AV0 AV2
66 AC0 AC2
67 AG0 AG2
68 AT0 AT2
69 ATRTN0 ATRTN1
70 AT1 AT3
71 AG1 AG3
72 AC1 AC3
73 AV1 AV3
PQ208
Pin
Number AFS250 Function AFS600 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-9
74 AV2 AV4
75 AC2 AC4
76 AG2 AG4
77 AT2 AT4
78 ATRTN1 ATRTN2
79 AT3 AT5
80 AG3 AG5
81 AC3 AC5
82 AV3 AV5
83 AV4 AV6
84 AC4 AC6
85 AG4 AG6
86 AT4 AT6
87 ATRTN2 ATRTN3
88 AT5 AT7
89 AG5 AG7
90 AC5 AC7
91 AV5 AV7
92 NC AV8
93 NC AC8
94 NC AG8
95 NC AT8
96 NC ATRTN4
97 NC AT9
98 NC AG9
99 NC AC9
100 NC AV9
101 GNDAQ GNDAQ
102 VCC33A VCC33A
103 ADCGNDREF ADCGNDREF
104 VAREF VAREF
105 PUB PUB
106 VCC33A VCC33A
107 GNDA GNDA
108 PTEM PTEM
109 PTBASE PTBASE
110 GNDNVM GNDNVM
PQ208
Pin
Number AFS250 Function AFS600 Function
111 VCCNVM VCCNVM
112 VCC VCC
112 VCC VCC
113 VPUMP VPUMP
114 GNDQ NC
115 VCCIB1 TCK
116 TCK TDI
117 TDI TMS
118 TMS TDO
119 TDO TRST
120 TRST VJTAG
121 VJTAG IO57NDB2V0
122 IO57NDB1V0 GDC2/IO57PDB2V0
123 GDC2/IO57PDB1V0 IO56NDB2V0
124 IO56NDB1V0 GDB2/IO56PDB2V0
125 GDB2/IO56PDB1V0 IO55NDB2V0
126 VCCIB1 GDA2/IO55PDB2V0
127 GND GDA0/IO54NDB2V0
128 IO55NDB1V0 GDA1/IO54PDB2V0
129 GDA2/IO55PDB1V0 VCCIB2
130 GDA0/IO54NDB1V0 GND
131 GDA1/IO54PDB1V0 VCC
132 GDB0/IO53NDB1V0 GCA0/IO45NDB2V0
133 GDB1/IO53PDB1V0 GCA1/IO45PDB2V0
134 GDC0/IO52NDB1V0 GCB0/IO44NDB2V0
135 GDC1/IO52PDB1V0 GCB1/IO44PDB2V0
136 IO51NSB1V0 GCC0/IO43NDB2V
0
137 VCCIB1 GCC1/IO43PDB2V0
138 GND IO42NDB2V0
139 VCC IO42PDB2V0
140 IO50NDB1V0 IO41NDB2V0
141 IO50PDB1V0 GCC2/IO41PDB2V0
142 GCA0/IO49NDB1V0 VCCIB2
143 GCA1/IO49PDB1V0 GND
144 GCB0/IO48NDB1V0 VCC
145 GCB1/IO48PDB1V0 IO40NDB2V0
146 GCC0/IO47NDB1V0 GCB2/IO40PDB2V0
PQ208
Pin
Number AFS250 Function AFS600 Function
Package Pin Assignments
4-10 Revision 4
147 GCC1/IO47PDB1V0 IO39NDB2V0
148 IO42NDB1V0 GCA2/IO39PDB2V0
149 GBC2/IO42PDB1V0 IO31NDB2V0
150 VCCIB1 GBB2/IO31PDB2V0
151 GND IO30NDB2V0
152 VCC GBA2/IO30PDB2V0
153 IO41NDB1V0 VCCIB2
154 GBB2/IO41PDB1V0 GNDQ
155 IO40NDB1V0 VCOMPLB
156 GBA2/IO40PDB1V0 VCCPLB
157 GBA1/IO39RSB0V0 VCCIB1
158 GBA0/IO38RSB0V0 GNDQ
159 GBB1/IO37RSB0V0 GBB1/IO27PPB1V1
160 GBB0/IO36RSB0V0 GBA1/IO28PPB1V1
161 GBC1/IO35RSB0V0 GBB0/IO27NPB1V1
162 VCCIB0 GBA0/IO28NPB1V1
163 GND VCCIB1
164 VCC GND
165 GBC0/IO34RSB0V0 VCC
166 IO33RSB0V0 GBC1/IO26PDB1V1
167 IO32RSB0V0 GBC0/IO26NDB1V1
168 IO31RSB0V0 IO24PPB1V1
169 IO30RSB0V0 IO23PPB1V1
170 IO29RSB0V0 IO24NPB1V1
171 IO28RSB0V0 IO23NPB1V1
172 IO27RSB0V0 IO22PPB1V0
173 IO26RSB0V0 IO21PPB1V0
174 IO25RSB0V0 IO22NPB1V0
175 VCCIB0 IO21NPB1V0
176 GND IO20PSB1V0
177 VCC IO19PSB1V0
178 IO24RSB0V0 IO14NSB0V1
179 IO23RSB0V0 IO12PDB0V1
180 IO22RSB0V0 IO12NDB0V1
181 IO21RSB0V0 VCCIB0
182 IO20RSB0V0 GND
183 IO19RSB0V0 VCC
PQ208
Pin
Number AFS250 Function AFS600 Function
184 IO18RSB0V0 IO10PPB0V1
185 IO17RSB0V0 IO09PPB0V1
186 IO16RSB0V0 IO10NPB0V1
187 IO15RSB0V0 IO09NPB0V1
188 VCCIB0 IO08PPB0V1
189 GND IO07PPB0V1
190 VCC IO08NPB0V1
191 IO14RSB0V0 IO07NPB0V1
192 IO13RSB0V0 IO06PPB0V0
193 IO12RSB0V0 IO05PPB0V0
194 IO11RSB0V0 IO06NPB0V0
195 IO10RSB0V0 IO04PPB0V0
196 IO09RSB0V0 IO05NPB0V0
197 IO08RSB0V0 IO04NPB0V0
198 IO07RSB0V0 GAC1/IO03PDB0V0
199 IO06RSB0V0 GAC0/IO03NDB0V0
200 GAC1/IO05RSB0V0 VCCIB0
201 VCCIB0 GND
202 GND VCC
203 VCC GAB1/IO02PDB0V0
204 GAC0/IO04RSB0V0 GAB0/IO02NDB0V0
205 GAB1/IO03RSB0V0 GAA1/IO01PDB0V0
206 GAB0/IO02RSB0V0 GAA0/IO01NDB0V0
207 GAA1/IO01RSB0V0 GNDQ
208 GAA0/IO00RSB0V0 VCCIB0
PQ208
Pin
Number AFS250 Function AFS600 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-11
FG256
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/default.aspx.
1
3
5
791113
15 246
8
101214
16
C
E
G
J
L
N
R
D
F
H
K
M
P
T
B
A
A1 Ball Pad Corner
Package Pin Assignments
4-12 Revision 4
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
A1GNDGNDGNDGND
A2 VCCIB0 VCCIB0 VCCIB0 VCCIB0
A3 GAB0/IO02RSB0V0 GAA0/IO00RSB0V0 GAA0/IO01NDB0V0 GAA0/IO01NDB0V0
A4 GAB1/IO03RSB0V0 GAA1/IO01RSB0V0 GAA1/IO01PDB0V0 GAA1/IO01PDB0V0
A5GNDGNDGNDGND
A6 IO07RSB0V0 IO11RSB0V0 IO10PDB0V1 IO07PDB0V1
A7 IO10RSB0V0 IO14RSB0V0 IO12PDB0V1 IO13PDB0V2
A8 IO11RSB0V0 IO15RSB0V0 IO12NDB0V1 IO13NDB0V2
A9 IO16RSB0V0 IO24RSB0V0 IO22NDB1V0 IO24NDB1V0
A10 IO17RSB0V0 IO25RSB0V0 IO22PDB1V0 IO24PDB1V0
A11 IO18RSB0V0 IO26RSB0V0 IO24NDB1V1 IO29NDB1V1
A12 GND GND GND GND
A13 GBC0/IO25RSB0V0 GBA0/IO38RSB0V0 GBA0/IO28NDB1V1 GBA0/IO42NDB1V2
A14 GBA0/IO29RSB0V0 IO32RSB0V0 IO29NDB1V1 IO43NDB1V2
A15 VCCIB0 VCCIB0 VCCIB1 VCCIB1
A16 GND GND GND GND
B1 VCOMPLA VCOMPLA VCOMPLA VCOMPLA
B2 VCCPLA VCCPLA VCCPLA VCCPLA
B3 GAA0/IO00RSB0V0 IO07RSB0V0 IO00NDB0V0 IO00NDB0V0
B4 GAA1/IO01RSB0V0 IO06RSB0V0 IO00PDB0V0 IO00PDB0V0
B5 NC GAB1/IO03RSB0V0 GAB1/IO02PPB0V0 GAB1/IO02PPB0V0
B6 IO06RSB0V0 IO10RSB0V0 IO10NDB0V1 IO07NDB0V1
B7 VCCIB0 VCCIB0 VCCIB0 VCCIB0
B8 IO12RSB0V0 IO16RSB0V0 IO18NDB1V0 IO22NDB1V0
B9 IO13RSB0V0 IO17RSB0V0 IO18PDB1V0 IO22PDB1V0
B10 VCCIB0 VCCIB0 VCCIB1 VCCIB1
B11 IO19RSB0V0 IO27RSB0V0 IO24PDB1V1 IO29PDB1V1
B12 GBB0/IO27RSB0V0 GBC0/IO34RSB0V0 GBC0/IO26NPB1V1 GBC0/IO40NPB1V2
B13 GBC1/IO26RSB0V0 GBA1/IO39RSB0V0 GBA1/IO28PDB1V1 GBA1/IO42PDB1V2
B14 GBA1/IO30RSB0V0 IO33RSB0V0 IO29PDB1V1 IO43PDB1V2
B15 NC NC VCCPLB VCCPLB
B16 NC NC VCOMPLB VCOMPLB
C1 VCCIB3 VCCIB3 VCCIB4 VCCIB4
C2 GND GND GND GND
C3 VCCIB3 VCCIB3 VCCIB4 VCCIB4
C4 NC NC VCCIB0 VCCIB0
C5 VCCIB0 VCCIB0 VCCIB0 VCCIB0
C6 GAC1/IO05RSB0V0 GAC1/IO05RSB0V0 GAC1/IO03PDB0V0 GAC1/IO03PDB0V0
Fusion Family of Mixed Signal FPGAs
Revision 4 4-13
C7 IO09RSB0V0 IO12RSB0V0 IO06NDB0V0 IO09NDB0V1
C8 IO14RSB0V0 IO22RSB0V0 IO16PDB1V0 IO23PDB1V0
C9 IO15RSB0V0 IO23RSB0V0 IO16NDB1V0 IO23NDB1V0
C10 IO22RSB0V0 IO30RSB0V0 IO25NDB1V1 IO31NDB1V1
C11 IO20RSB0V0 IO31RSB0V0 IO25PDB1V1 IO31PDB1V1
C12 VCCIB0 VCCIB0 VCCIB1 VCCIB1
C13 GBB1/IO28RSB0V0 GBC1/IO35RSB0V0 GBC1/IO26PPB1V1 GBC1/IO40PPB1V2
C14 VCCIB1 VCCIB1 VCCIB2 VCCIB2
C15 GND GND GND GND
C16 VCCIB1 VCCIB1 VCCIB2 VCCIB2
D1 GFC2/IO50NPB3V0 IO75NDB3V0 IO84NDB4V0 IO124NDB4V0
D2 GFA2/IO51NDB3V0 GAB2/IO75PDB3V0 GAB2/IO84PDB4V0 GAB2/IO124PDB4V0
D3 GAC2/IO51PDB3V0 IO76NDB3V0 IO85NDB4V0 IO125NDB4V0
D4 GAA2/IO52PDB3V0 GAA2/IO76PDB3V0 GAA2/IO85PDB4V0 GAA2/IO125PDB4V0
D5 GAB2/IO52NDB3V0 GAB0/IO02RSB0V0 GAB0/IO02NPB0V0 GAB0/IO02NPB0V0
D6 GAC0/IO04RSB0V0 GAC0/IO04RSB0V0 GAC0/IO03NDB0V0 GAC0/IO03NDB0V0
D7 IO08RSB0V0 IO13RSB0V0 IO06PDB0V0 IO09PDB0V1
D8 NC IO20RSB0V0 IO14NDB0V1 IO15NDB0V2
D9 NC IO21RSB0V0 IO14PDB0V1 IO15PDB0V2
D10 IO21RSB0V0 IO28RSB0V0 IO23PDB1V1 IO37PDB1V2
D11 IO23RSB0V0 GBB0/IO36RSB0V0 GBB0/IO27NDB1V1 GBB0/IO41NDB1V2
D12 NC NC VCCIB1 VCCIB1
D13 GBA2/IO31PDB1V0 GBA2/IO40PDB1V0 GBA2/IO30PDB2V0 GBA2/IO44PDB2V0
D14 GBB2/IO31NDB1V0 IO40NDB1V0 IO30NDB2V0 IO44NDB2V0
D15 GBC2/IO32PDB1V0 GBB2/IO41PDB1V0 GBB2/IO31PDB2V0 GBB2/IO45PDB2V0
D16 GCA2/IO32NDB1V0 IO41NDB1V0 IO31NDB2V0 IO45NDB2V0
E1GNDGNDGNDGND
E2 GFB0/IO48NPB3V0 IO73NDB3V0 IO81NDB4V0 IO118NDB4V0
E3 GFB2/IO50PPB3V0 IO73PDB3V0 IO81PDB4V0 IO118PDB4V0
E4 VCCIB3 VCCIB3 VCCIB4 VCCIB4
E5 NC IO74NPB3V0 IO83NPB4V0 IO123NPB4V0
E6 NC IO08RSB0V0 IO04NPB0V0 IO05NPB0V1
E7GNDGNDGNDGND
E8 NC IO18RSB0V0 IO08PDB0V1 IO11PDB0V1
E9 NC NC IO20NDB1V0 IO27NDB1V1
E10 GND GND GND GND
E11 IO24RSB0V0 GBB1/IO37RSB0V0 GBB1/IO27PDB1V1 GBB1/IO41PDB1V2
E12 NC IO50PPB1V0 IO33PSB2V0 IO48PSB2V0
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Package Pin Assignments
4-14 Revision 4
E13 VCCIB1 VCCIB1 VCCIB2 VCCIB2
E14 GCC2/IO33NDB1V0 IO42NDB1V0 IO32NDB2V0 IO46NDB2V0
E15 GCB2/IO33PDB1V0 GBC2/IO42PDB1V0 GBC2/IO32PDB2V0 GBC2/IO46PDB2V0
E16 GND GND GND GND
F1 NC NC IO79NDB4V0 IO111NDB4V0
F2 NC NC IO79PDB4V0 IO111PDB4V0
F3 GFB1/IO48PPB3V0 IO72NDB3V0 IO76NDB4V0 IO112NDB4V0
F4 GFC0/IO49NDB3V0 IO72PDB3V0 IO76PDB4V0 IO112PDB4V0
F5 NC NC IO82PSB4V0 IO120PSB4V0
F6 GFC1/IO49PDB3V0 GAC2/IO74PPB3V0 GAC2/IO83PPB4V0 GAC2/IO123PPB4V0
F7 NC IO09RSB0V0 IO04PPB0V0 IO05PPB0V1
F8 NC IO19RSB0V0 IO08NDB0V1 IO11NDB0V1
F9 NC NC IO20PDB1V0 IO27PDB1V1
F10 NC IO29RSB0V0 IO23NDB1V1 IO37NDB1V2
F11 NC IO43NDB1V0 IO36NDB2V0 IO50NDB2V0
F12 NC IO43PDB1V0 IO36PDB2V0 IO50PDB2V0
F13 NC IO44NDB1V0 IO39NDB2V0 IO59NDB2V0
F14 NC GCA2/IO44PDB1V0 GCA2/IO39PDB2V0 GCA2/IO59PDB2V0
F15 GCC1/IO34PDB1V0 GCB2/IO45PDB1V0 GCB2/IO40PDB2V0 GCB2/IO60PDB2V0
F16 GCC0/IO34NDB1V0 IO45NDB1V0 IO40NDB2V0 IO60NDB2V0
G1 GEC0/IO46NPB3V0 IO70NPB3V0 IO74NPB4V0 IO109NPB4V0
G2 VCCIB3 VCCIB3 VCCIB4 VCCIB4
G3 GEC1/IO46PPB3V0 GFB2/IO70PPB3V0 GFB2/IO74PPB4V0 GFB2/IO109PPB4V0
G4 GFA1/IO47PDB3V0 GFA2/IO71PDB3V0 GFA2/IO75PDB4V0 GFA2/IO110PDB4V0
G5 GND GND GND GND
G6 GFA0/IO47NDB3V0 IO71NDB3V0 IO75NDB4V0 IO110NDB4V0
G7 GND GND GND GND
G8 VCC VCC VCC VCC
G9 GND GND GND GND
G10 VCC VCC VCC VCC
G11 GDA1/IO37NDB1V0 GCC0/IO47NDB1V0 GCC0/IO43NDB2V0 GCC0/IO62NDB2V0
G12 GND GND GND GND
G13 IO37PDB1V0 GCC1/IO47PDB1V0 GCC1/IO43PDB2V0 GCC1/IO62PDB2V0
G14 GCB0/IO35NPB1V0 IO46NPB1V0 IO41NPB2V0 IO61NPB2V0
G15 VCCIB1 VCCIB1 VCCIB2 VCCIB2
G16 GCB1/IO35PPB1V0 GCC2/IO46PPB1V0 GCC2/IO41PPB2V0 GCC2/IO61PPB2V0
H1 GEB1/IO45PDB3V0 GFC2/IO69PDB3V0 GFC2/IO73PDB4V0 GFC2/IO108PDB4V0
H2 GEB0/IO45NDB3V0 IO69NDB3V0 IO73NDB4V0 IO108NDB4V0
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-15
H3 XTAL2 XTAL2 XTAL2 XTAL2
H4 XTAL1 XTAL1 XTAL1 XTAL1
H5 GNDOSC GNDOSC GNDOSC GNDOSC
H6 VCCOSC VCCOSC VCCOSC VCCOSC
H7 VCC VCC VCC VCC
H8 GND GND GND GND
H9 VCC VCC VCC VCC
H10 GND GND GND GND
H11 GDC0/IO38NDB1V0 IO51NDB1V0 IO47NDB2V0 IO69NDB2V0
H12 GDC1/IO38PDB1V0 IO51PDB1V0 IO47PDB2V0 IO69PDB2V0
H13 GDB1/IO39PDB1V0 GCA1/IO49PDB1V0 GCA1/IO45PDB2V0 GCA1/IO64PDB2V0
H14 GDB0/IO39NDB1V0 GCA0/IO49NDB1V0 GCA0/IO45NDB2V0 GCA0/IO64NDB2V0
H15 GCA0/IO36NDB1V0 GCB0/IO48NDB1V0 GCB0/IO44NDB2V0 GCB0/IO63NDB2V0
H16 GCA1/IO36PDB1V0 GCB1/IO48PDB1V0 GCB1/IO44PDB2V0 GCB1/IO63PDB2V0
J1 GEA0/IO44NDB3V0 GFA0/IO66NDB3V0 GFA0/IO70NDB4V0 GFA0/IO105NDB4V0
J2 GEA1/IO44PDB3V0 GFA1/IO66PDB3V0 GFA1/IO70PDB4V0 GFA1/IO105PDB4V0
J3 IO43NDB3V0 GFB0/IO67NDB3V0 GFB0/IO71NDB4V0 GFB0/IO106NDB4V0
J4 GEC2/IO43PDB3V0 GFB1/IO67PDB3V0 GFB1/IO71PDB4V0 GFB1/IO106PDB4V0
J5 NC GFC0/IO68NDB3V0 GFC0/IO72NDB4V0 GFC0/IO107NDB4V0
J6 NC GFC1/IO68PDB3V0 GFC1/IO72PDB4V0 GFC1/IO107PDB4V0
J7GNDGNDGNDGND
J8 VCC VCC VCC VCC
J9GNDGNDGNDGND
J10 VCC VCC VCC VCC
J11 GDC2/IO41NPB1V0 IO56NPB1V0 IO56NPB2V0 IO83NPB2V0
J12 NC GDB0/IO53NPB1V0 GDB0/IO53NPB2V0 GDB0/IO80NPB2V0
J13 NC GDA1/IO54PDB1V0 GDA1/IO54PDB2V0 GDA1/IO81PDB2V0
J14 GDA0/IO40PDB1V0 GDC1/IO52PPB1V0 GDC1/IO52PPB2V0 GDC1/IO79PPB2V0
J15 NC IO50NPB1V0 IO51NSB2V0 IO77NSB2V0
J16 GDA2/IO40NDB1V0 GDC0/IO52NPB1V0 GDC0/IO52NPB2V0 GDC0/IO79NPB2V0
K1 NC IO65NPB3V0 IO67NPB4V0 IO92NPB4V0
K2 VCCIB3 VCCIB3 VCCIB4 VCCIB4
K3 NC IO65PPB3V0 IO67PPB4V0 IO92PPB4V0
K4 NC IO64PDB3V0 IO65PDB4V0 IO96PDB4V0
K5GNDGNDGNDGND
K6 NC IO64NDB3V0 IO65NDB4V0 IO96NDB4V0
K7 VCC VCC VCC VCC
K8GNDGNDGNDGND
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Package Pin Assignments
4-16 Revision 4
K9 VCC VCC VCC VCC
K10 GND GND GND GND
K11 NC GDC2/IO57PPB1V0 GDC2/IO57PPB2V0 GDC2/IO84PPB2V0
K12 GND GND GND GND
K13 NC GDA0/IO54NDB1V0 GDA0/IO54NDB2V0 GDA0/IO81NDB2V0
K14 NC GDA2/IO55PPB1V0 GDA2/IO55PPB2V0 GDA2/IO82PPB2V0
K15 VCCIB1 VCCIB1 VCCIB2 VCCIB2
K16 NC GDB1/IO53PPB1V0 GDB1/IO53PPB2V0 GDB1/IO80PPB2V0
L1 NC GEC1/IO63PDB3V0 GEC1/IO63PDB4V0 GEC1/IO90PDB4V0
L2 NC GEC0/IO63NDB3V0 GEC0/IO63NDB4V0 GEC0/IO90NDB4V0
L3 NC GEB1/IO62PDB3V0 GEB1/IO62PDB4V0 GEB1/IO89PDB4V0
L4 NC GEB0/IO62NDB3V0 GEB0/IO62NDB4V0 GEB0/IO89NDB4V0
L5 NC IO60NDB3V0 IO60NDB4V0 IO87NDB4V0
L6 NC GEC2/IO60PDB3V0 GEC2/IO60PDB4V0 GEC2/IO87PDB4V0
L7 GNDA GNDA GNDA GNDA
L8AC0AC0AC2AC2
L9 AV2 AV2 AV4 AV4
L10AC3AC3AC5AC5
L11 PTEM PTEM PTEM PTEM
L12 TDO TDO TDO TDO
L13 VJTAG VJTAG VJTAG VJTAG
L14 NC IO57NPB1V0 IO57NPB2V0 IO84NPB2V0
L15 GDB2/IO41PPB1V0 GDB2/IO56PPB1V0 GDB2/IO56PPB2V0 GDB2/IO83PPB2V0
L16 NC IO55NPB1V0 IO55NPB2V0 IO82NPB2V0
M1GNDGNDGNDGND
M2 NC GEA1/IO61PDB3V0 GEA1/IO61PDB4V0 GEA1/IO88PDB4V0
M3 NC GEA0/IO61NDB3V0 GEA0/IO61NDB4V0 GEA0/IO88NDB4V0
M4 VCCIB3 VCCIB3 VCCIB4 VCCIB4
M5 NC IO58NPB3V0 IO58NPB4V0 IO85NPB4V0
M6 NC NC AV0 AV0
M7 NC NC AC1 AC1
M8 AG1 AG1 AG3 AG3
M9AC2AC2AC4AC4
M10 AC4 AC4 AC6 AC6
M11 NC AG5 AG7 AG7
M12 VPUMP VPUMP VPUMP VPUMP
M13 VCCIB1 VCCIB1 VCCIB2 VCCIB2
M14 TMS TMS TMS TMS
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-17
M15 TRST TRST TRST TRST
M16 GND GND GND GND
N1 GEB2/IO42PDB3V0 GEB2/IO59PDB3V0 GEB2/IO59PDB4V0 GEB2/IO86PDB4V0
N2 GEA2/IO42NDB3V0 IO59NDB3V0 IO59NDB4V0 IO86NDB4V0
N3 NC GEA2/IO58PPB3V0 GEA2/IO58PPB4V0 GEA2/IO85PPB4V0
N4 VCC33PMP VCC33PMP VCC33PMP VCC33PMP
N5 VCC15A VCC15A VCC15A VCC15A
N6 NC NC AG0 AG0
N7 AC1 AC1 AC3 AC3
N8 AG3 AG3 AG5 AG5
N9 AV3 AV3 AV5 AV5
N10 AG4 AG4 AG6 AG6
N11 NC NC AC8 AC8
N12 GNDA GNDA GNDA GNDA
N13 VCC33A VCC33A VCC33A VCC33A
N14 VCCNVM VCCNVM VCCNVM VCCNVM
N15 TCK TCK TCK TCK
N16 TDI TDI TDI TDI
P1 VCCNVM VCCNVM VCCNVM VCCNVM
P2 GNDNVM GNDNVM GNDNVM GNDNVM
P3 GNDA GNDA GNDA GNDA
P4 NC NC AC0 AC0
P5 NC NC AG1 AG1
P6 NC NC AV1 AV1
P7 AG0 AG0 AG2 AG2
P8 AG2 AG2 AG4 AG4
P9 GNDA GNDA GNDA GNDA
P10 NC AC5 AC7 AC7
P11 NC NC AV8 AV8
P12 NC NC AG8 AG8
P13 NC NC AV9 AV9
P14 ADCGNDREF ADCGNDREF ADCGNDREF ADCGNDREF
P15 PTBASE PTBASE PTBASE PTBASE
P16 GNDNVM GNDNVM GNDNVM GNDNVM
R1 VCCIB3 VCCIB3 VCCIB4 VCCIB4
R2 PCAP PCAP PCAP PCAP
R3 NC NC AT1 AT1
R4 NC NC AT0 AT0
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Package Pin Assignments
4-18 Revision 4
R5 AV0 AV0 AV2 AV2
R6 AT0 AT0 AT2 AT2
R7 AV1 AV1 AV3 AV3
R8 AT3 AT3 AT5 AT5
R9 AV4 AV4 AV6 AV6
R10 NC AT5 AT7 AT7
R11 NC AV5 AV7 AV7
R12 NC NC AT9 AT9
R13 NC NC AG9 AG9
R14 NC NC AC9 AC9
R15 PUB PUB PUB PUB
R16 VCCIB1 VCCIB1 VCCIB2 VCCIB2
T1GNDGNDGNDGND
T2 NCAP NCAP NCAP NCAP
T3 VCC33N VCC33N VCC33N VCC33N
T4 NC NC ATRTN0 ATRTN0
T5 AT1 AT1 AT3 AT3
T6 ATRTN0 ATRTN0 ATRTN1 ATRTN1
T7 AT2 AT2 AT4 AT4
T8 ATRTN1 ATRTN1 ATRTN2 ATRTN2
T9 AT4 AT4 AT6 AT6
T10 ATRTN2 ATRTN2 ATRTN3 ATRTN3
T11 NC NC AT8 AT8
T12 NC NC ATRTN4 ATRTN4
T13 GNDA GNDA GNDA GNDA
T14 VCC33A VCC33A VCC33A VCC33A
T15 VAREF VAREF VAREF VAREF
T16 GND GND GND GND
FG256
Pin Number AFS090 Function AFS250 Function AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-19
FG484
Note
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AA
AB
12345678910111213141516171819202122
A1 Ball Pad Corner
Package Pin Assignments
4-20 Revision 4
FG484
Pin
Number AFS600 Function AFS1500 Function
A1 GND GND
A2 VCC NC
A3 GAA1/IO01PDB0V0 GAA1/IO01PDB0V0
A4 GAB0/IO02NDB0V0 GAB0/IO02NDB0V0
A5 GAB1/IO02PDB0V0 GAB1/IO02PDB0V0
A6 IO07NDB0V1 IO07NDB0V1
A7 IO07PDB0V1 IO07PDB0V1
A8 IO10PDB0V1 IO09PDB0V1
A9 IO14NDB0V1 IO13NDB0V2
A10 IO14PDB0V1 IO13PDB0V2
A11 IO17PDB1V0 IO24PDB1V0
A12 IO18PDB1V0 IO26PDB1V0
A13 IO19NDB1V0 IO27NDB1V1
A14 IO19PDB1V0 IO27PDB1V1
A15 IO24NDB1V1 IO35NDB1V2
A16 IO24PDB1V1 IO35PDB1V2
A17 GBC0/IO26NDB1V1 GBC0/IO40NDB1V2
A18 GBA0/IO28NDB1V1 GBA0/IO42NDB1V2
A19 IO29NDB1V1 IO43NDB1V2
A20 IO29PDB1V1 IO43PDB1V2
A21 VCC NC
A22 GND GND
AA1 VCC NC
AA2 GND GND
AA3 VCCIB4 VCCIB4
AA4 VCCIB4 VCCIB4
AA5 PCAP PCAP
AA6 AG0 AG0
AA7 GNDA GNDA
AA8 AG1 AG1
AA9 AG2 AG2
AA10 GNDA GNDA
AA11 AG3 AG3
AA12 AG6 AG6
AA13 GNDA GNDA
AA14 AG7 AG7
AA15 AG8 AG8
AA16 GNDA GNDA
AA17 AG9 AG9
AA18 VAREF VAREF
AA19 VCCIB2 VCCIB2
AA20 PTEM PTEM
AA21 GND GND
AA22 VCC NC
AB1 GND GND
AB2 VCC NC
AB3 NC IO94NSB4V0
AB4 GND GND
AB5 VCC33N VCC33N
AB6 AT0 AT0
AB7 ATRTN0 ATRTN0
AB8 AT1 AT1
AB9 AT2 AT2
AB10 ATRTN1 ATRTN1
AB11 AT3 AT3
AB12 AT6 AT6
AB13 ATRTN3 ATRTN3
AB14 AT7 AT7
AB15 AT8 AT8
AB16 ATRTN4 ATRTN4
AB17 AT9 AT9
AB18 VCC33A VCC33A
AB19 GND GND
AB20 NC IO76NPB2V0
AB21 VCC NC
AB22 GND GND
B1 VCC NC
B2 GND GND
B3 GAA0/IO01NDB0V0 GAA0/IO01NDB0V0
B4 GND GND
FG484
Pin
Number AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-21
B5 IO05NDB0V0 IO04NDB0V0
B6 IO05PDB0V0 IO04PDB0V0
B7 GND GND
B8 IO10NDB0V1 IO09NDB0V1
B9 IO13PDB0V1 IO11PDB0V1
B10 GND GND
B11 IO17NDB1V0 IO24NDB1V0
B12 IO18NDB1V0 IO26NDB1V0
B13 GND GND
B14 IO21NDB1V0 IO31NDB1V1
B15 IO21PDB1V0 IO31PDB1V1
B16 GND GND
B17 GBC1/IO26PDB1V1 GBC1/IO40PDB1V2
B18 GBA1/IO28PDB1V1 GBA1/IO42PDB1V2
B19 GND GND
B20 VCCPLB VCCPLB
B21 GND GND
B22 VCC NC
C1 IO82PDB4V0 IO121PDB4V0
C2 NC IO122PSB4V0
C3 IO00NDB0V0 IO00NDB0V0
C4 IO00PDB0V0 IO00PDB0V0
C5 VCCIB0 VCCIB0
C6 IO06NDB0V0 IO05NDB0V1
C7 IO06PDB0V0 IO05PDB0V1
C8 VCCIB0 VCCIB0
C9 IO13NDB0V1 IO11NDB0V1
C10 IO11PDB0V1 IO14PDB0V2
C11 VCCIB0 VCCIB0
C12 VCCIB1 VCCIB1
C13 IO20NDB1V0 IO29NDB1V1
C14 IO20PDB1V0 IO29PDB1V1
C15 VCCIB1 VCCIB1
C16 IO25NDB1V1 IO37NDB1V2
C17 GBB0/IO27NDB1V1 GBB0/IO41NDB1V2
FG484
Pin
Number AFS600 Function AFS1500 Function
C18 VCCIB1 VCCIB1
C19 VCOMPLB VCOMPLB
C20 GBA2/IO30PDB2V0 GBA2/IO44PDB2V0
C21 NC IO48PSB2V0
C22 GBB2/IO31PDB2V0 GBB2/IO45PDB2V0
D1 IO82NDB4V0 IO121NDB4V0
D2 GND GND
D3 IO83NDB4V0 IO123NDB4V0
D4 GAC2/IO83PDB4V0 GAC2/IO123PDB4V0
D5 GAA2/IO85PDB4V0 GAA2/IO125PDB4V0
D6 GAC0/IO03NDB0V0 GAC0/IO03NDB0V0
D7 GAC1/IO03PDB0V0 GAC1/IO03PDB0V0
D8 IO09NDB0V1 IO10NDB0V1
D9 IO09PDB0V1 IO10PDB0V1
D10 IO11NDB0V1 IO14NDB0V2
D11 IO16NDB1V0 IO23NDB1V0
D12 IO16PDB1V0 IO23PDB1V0
D13 NC IO32NPB1V1
D14 IO23NDB1V1 IO34NDB1V1
D15 IO23PDB1V1 IO34PDB1V1
D16 IO25PDB1V1 IO37PDB1V2
D17 GBB1/IO27PDB1V1 GBB1/IO41PDB1V2
D18 VCCIB2 VCCIB2
D19 NC IO47PPB2V0
D20 IO30NDB2V0 IO44NDB2V0
D21 GND GND
D22 IO31NDB2V0 IO45NDB2V0
E1 IO81NDB4V0 IO120NDB4V0
E2 IO81PDB4V0 IO120PDB4V0
E3 VCCIB4 VCCIB4
E4 GAB2/IO84PDB4V0 GAB2/IO124PDB4V0
E5 IO85NDB4V0 IO125NDB4V0
E6 GND GND
E7 VCCIB0 VCCIB0
E8 NC IO08NDB0V1
FG484
Pin
Number AFS600 Function AFS1500 Function
Package Pin Assignments
4-22 Revision 4
E9 NC IO08PDB0V1
E10 GND GND
E11 IO15NDB1V0 IO22NDB1V0
E12 IO15PDB1V0 IO22PDB1V0
E13 GND GND
E14 NC IO32PPB1V1
E15 NC IO36NPB1V2
E16 VCCIB1 VCCIB1
E17 GND GND
E18 NC IO47NPB2V0
E19 IO33PDB2V0 IO49PDB2V0
E20 VCCIB2 VCCIB2
E21 IO32NDB2V0 IO46NDB2V0
E22 GBC2/IO32PDB2V0 GBC2/IO46PDB2V0
F1 IO80NDB4V0 IO118NDB4V0
F2 IO80PDB4V0 IO118PDB4V0
F3 NC IO119NSB4V0
F4 IO84NDB4V0 IO124NDB4V0
F5 GND GND
F6 VCOMPLA VCOMPLA
F7 VCCPLA VCCPLA
F8 VCCIB0 VCCIB0
F9 IO08NDB0V1 IO12NDB0V1
F10 IO08PDB0V1 IO12PDB0V1
F11 VCCIB0 VCCIB0
F12 VCCIB1 VCCIB1
F13 IO22NDB1V0 IO30NDB1V1
F14 IO22PDB1V0 IO30PDB1V1
F15 VCCIB1 VCCIB1
F16 NC IO36PPB1V2
F17 NC IO38NPB1V2
F18 GND GND
F19 IO33NDB2V0 IO49NDB2V0
F20 IO34PDB2V0 IO50PDB2V0
F21 IO34NDB2V0 IO50NDB2V0
FG484
Pin
Number AFS600 Function AFS1500 Function
F22 IO35PDB2V0 IO51PDB2V0
G1 IO77PDB4V0 IO115PDB4V0
G2 GND GND
G3 IO78NDB4V0 IO116NDB4V0
G4 IO78PDB4V0 IO116PDB4V0
G5 VCCIB4 VCCIB4
G6 NC IO117PDB4V0
G7 VCCIB4 VCCIB4
G8 GND GND
G9 IO04NDB0V0 IO06NDB0V1
G10 IO04PDB0V0 IO06PDB0V1
G11 IO12NDB0V1 IO16NDB0V2
G12 IO12PDB0V1 IO16PDB0V2
G13 NC IO28NDB1V1
G14 NC IO28PDB1V1
G15 GND GND
G16 NC IO38PPB1V2
G17 NC IO53PDB2V0
G18 VCCIB2 VCCIB2
G19 IO36PDB2V0 IO52PDB2V0
G20 IO36NDB2V0 IO52NDB2V0
G21 GND GND
G22 IO35NDB2V0 IO51NDB2V0
H1 IO77NDB4V0 IO115NDB4V0
H2 IO76PDB4V0 IO113PDB4V0
H3 VCCIB4 VCCIB4
H4 IO79NDB4V0 IO114NDB4V0
H5 IO79PDB4V0 IO114PDB4V0
H6 NC IO117NDB4V0
H7 GND GND
H8 VCC VCC
H9 VCCIB0 VCCIB0
H10 GND GND
H11 VCCIB0 VCCIB0
H12 VCCIB1 VCCIB1
FG484
Pin
Number AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-23
H13 GND GND
H14 VCCIB1 VCCIB1
H15 GND GND
H16 GND GND
H17 NC IO53NDB2V0
H18 IO38PDB2V0 IO57PDB2V0
H19 GCA2/IO39PDB2V0 GCA2/IO59PDB2V0
H20 VCCIB2 VCCIB2
H21 IO37NDB2V0 IO54NDB2V0
H22 IO37PDB2V0 IO54PDB2V0
J1 NC IO112PPB4V0
J2 IO76NDB4V0 IO113NDB4V0
J3 GFB2/IO74PDB4V0 GFB2/IO109PDB4V0
J4 GFA2/IO75PDB4V0 GFA2/IO110PDB4V0
J5 NC IO112NPB4V0
J6 NC IO104PDB4V0
J7 NC IO111PDB4V0
J8 VCCIB4 VCCIB4
J9 GND GND
J10 VCC VCC
J11 GND GND
J12 VCC VCC
J13 GND GND
J14 VCC VCC
J15 VCCIB2 VCCIB2
J16 GCB2/IO40PDB2V0 GCB2/IO60PDB2V0
J17 NC IO58NDB2V0
J18 IO38NDB2V0 IO57NDB2V0
J19 IO39NDB2V0 IO59NDB2V0
J20 GCC2/IO41PDB2V0 GCC2/IO61PDB2V0
J21 NC IO55PSB2V0
J22 IO42PDB2V0 IO56PDB2V0
K1 GFC2/IO73PDB4V0 GFC2/IO108PDB4V0
K2 GND GND
K3 IO74NDB4V0 IO109NDB4V0
FG484
Pin
Number AFS600 Function AFS1500 Function
K4 IO75NDB4V0 IO110NDB4V0
K5 GND GND
K6 NC IO104NDB4V0
K7 NC IO111NDB4V0
K8 GND GND
K9 VCC VCC
K10 GND GND
K11 VCC VCC
K12 GND GND
K13 VCC VCC
K14 GND GND
K15 GND GND
K16 IO40NDB2V0 IO60NDB2V0
K17 NC IO58PDB2V0
K18 GND GND
K19 NC IO68NPB2V0
K20 IO41NDB2V0 IO61NDB2V0
K21 GND GND
K22 IO42NDB2V0 IO56NDB2V0
L1 IO73NDB4V0 IO108NDB4V0
L2 VCCOSC VCCOSC
L3 VCCIB4 VCCIB4
L4 XTAL2 XTAL2
L5 GFC1/IO72PDB4V0 GFC1/IO107PDB4V0
L6 VCCIB4 VCCIB4
L7 GFB1/IO71PDB4V0 GFB1/IO106PDB4V0
L8 VCCIB4 VCCIB4
L9 GND GND
L10 VCC VCC
L11 GND GND
L12 VCC VCC
L13 GND GND
L14 VCC VCC
L15 VCCIB2 VCCIB2
L16 IO48PDB2V0 IO70PDB2V0
FG484
Pin
Number AFS600 Function AFS1500 Function
Package Pin Assignments
4-24 Revision 4
L17 VCCIB2 VCCIB2
L18 IO46PDB2V0 IO69PDB2V0
L19 GCA1/IO45PDB2V0 GCA1/IO64PDB2V0
L20 VCCIB2 VCCIB2
L21 GCC0/IO43NDB2V0 GCC0/IO62NDB2V0
L22 GCC1/IO43PDB2V0 GCC1/IO62PDB2V0
M1 NC IO103PDB4V0
M2 XTAL1 XTAL1
M3 VCCIB4 VCCIB4
M4 GNDOSC GNDOSC
M5 GFC0/IO72NDB4V0 GFC0/IO107NDB4V0
M6 VCCIB4 VCCIB4
M7 GFB0/IO71NDB4V0 GFB0/IO106NDB4V0
M8 VCCIB4 VCCIB4
M9 VCC VCC
M10 GND GND
M11 VCC VCC
M12 GND GND
M13 VCC VCC
M14 GND GND
M15 VCCIB2 VCCIB2
M16 IO48NDB2V0 IO70NDB2V0
M17 VCCIB2 VCCIB2
M18 IO46NDB2V0 IO69NDB2V0
M19 GCA0/IO45NDB2V0 GCA0/IO64NDB2V0
M20 VCCIB2 VCCIB2
M21 GCB0/IO44NDB2V0 GCB0/IO63NDB2V0
M22 GCB1/IO44PDB2V0 GCB1/IO63PDB2V0
N1 NC IO103NDB4V0
N2 GND GND
N3 IO68PDB4V0 IO101PDB4V0
N4 NC IO100NPB4V0
N5 GND GND
N6 NC IO99PDB4V0
N7 NC IO97PDB4V0
FG484
Pin
Number AFS600 Function AFS1500 Function
N8 GND GND
N9 GND GND
N10 VCC VCC
N11 GND GND
N12 VCC VCC
N13 GND GND
N14 VCC VCC
N15 GND GND
N16 GDB2/IO56PDB2V0 GDB2/IO83PDB2V0
N17 NC IO78PDB2V0
N18 GND GND
N19 IO47NDB2V0 IO72NDB2V0
N20 IO47PDB2V0 IO72PDB2V0
N21 GND GND
N22 IO49PDB2V0 IO71PDB2V0
P1 GFA1/IO70PDB4V0 GFA1/IO105PDB4V0
P2 GFA0/IO70NDB4V0 GFA0/IO105NDB4V0
P3 IO68NDB4V0 IO101NDB4V0
P4 IO65PDB4V0 IO96PDB4V0
P5 IO65NDB4V0 IO96NDB4V0
P6 NC IO99NDB4V0
P7 NC IO97NDB4V0
P8 VCCIB4 VCCIB4
P9 VCC VCC
P10 GND GND
P11 VCC VCC
P12 GND GND
P13 VCC VCC
P14 GND GND
P15 VCCIB2 VCCIB2
P16 IO56NDB2V0 IO83NDB2V0
P17 NC IO78NDB2V0
P18 GDA1/IO54PDB2V0 GDA1/IO81PDB2V0
P19 GDB1/IO53PDB2V0 GDB1/IO80PDB2V0
P20 IO51NDB2V0 IO73NDB2V0
FG484
Pin
Number AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-25
P21 IO51PDB2V0 IO73PDB2V0
P22 IO49NDB2V0 IO71NDB2V0
R1 IO69PDB4V0 IO102PDB4V0
R2 IO69NDB4V0 IO102NDB4V0
R3 VCCIB4 VCCIB4
R4 IO64PDB4V0 IO91PDB4V0
R5 IO64NDB4V0 IO91NDB4V0
R6 NC IO92PDB4V0
R7 GND GND
R8 GND GND
R9 VCC33A VCC33A
R10 GNDA GNDA
R11 VCC33A VCC33A
R12 GNDA GNDA
R13 VCC33A VCC33A
R14 GNDA GNDA
R15 VCC VCC
R16 GND GND
R17 NC IO74NDB2V0
R18 GDA0/IO54NDB2V0 GDA0/IO81NDB2V0
R19 GDB0/IO53NDB2V0 GDB0/IO80NDB2V0
R20 VCCIB2 VCCIB2
R21 IO50NDB2V0 IO75NDB2V0
R22 IO50PDB2V0 IO75PDB2V0
T1 NC IO100PPB4V0
T2 GND GND
T3 IO66PDB4V0 IO95PDB4V0
T4 IO66NDB4V0 IO95NDB4V0
T5 VCCIB4 VCCIB4
T6 NC IO92NDB4V0
T7 GNDNVM GNDNVM
T8 GNDA GNDA
T9 NC NC
T10 AV4 AV4
T11 NC NC
FG484
Pin
Number AFS600 Function AFS1500 Function
T12 AV5 AV5
T13 AC5 AC5
T14 NC NC
T15 GNDA GNDA
T16 NC IO77PPB2V0
T17 NC IO74PDB2V0
T18 VCCIB2 VCCIB2
T19 IO55NDB2V0 IO82NDB2V0
T20 GDA2/IO55PDB2V0 GDA2/IO82PDB2V0
T21 GND GND
T22 GDC1/IO52PDB2V0 GDC1/IO79PDB2V0
U1 IO67PDB4V0 IO98PDB4V0
U2 IO67NDB4V0 IO98NDB4V0
U3 GEC1/IO63PDB4V0 GEC1/IO90PDB4V0
U4 GEC0/IO63NDB4V0 GEC0/IO90NDB4V0
U5 GND GND
U6 VCCNVM VCCNVM
U7 VCCIB4 VCCIB4
U8 VCC15A VCC15A
U9 GNDA GNDA
U10 AC4 AC4
U11 VCC33A VCC33A
U12 GNDA GNDA
U13 AG5 AG5
U14 GNDA GNDA
U15 PUB PUB
U16 VCCIB2 VCCIB2
U17 TDI TDI
U18 GND GND
U19 IO57NDB2V0 IO84NDB2V0
U20 GDC2/IO57PDB2V0 GDC2/IO84PDB2V0
U21 NC IO77NPB2V0
U22 GDC0/IO52NDB2V0 GDC0/IO79NDB2V0
V1 GEB1/IO62PDB4V0 GEB1/IO89PDB4V0
V2 GEB0/IO62NDB4V0 GEB0/IO89NDB4V0
FG484
Pin
Number AFS600 Function AFS1500 Function
Package Pin Assignments
4-26 Revision 4
V3 VCCIB4 VCCIB4
V4 GEA1/IO61PDB4V0 GEA1/IO88PDB4V0
V5 GEA0/IO61NDB4V0 GEA0/IO88NDB4V0
V6 GND GND
V7 VCC33PMP VCC33PMP
V8 NC NC
V9 VCC33A VCC33A
V10 AG4 AG4
V11 AT4 AT4
V12 ATRTN2 ATRTN2
V13 AT5 AT5
V14 VCC33A VCC33A
V15 NC NC
V16 VCC33A VCC33A
V17 GND GND
V18 TMS TMS
V19 VJTAG VJTAG
V20 VCCIB2 VCCIB2
V21 TRST TRST
V22 TDO TDO
W1 NC IO93PDB4V0
W2 GND GND
W3 NC IO93NDB4V0
W4 GEB2/IO59PDB4V0 GEB2/IO86PDB4V0
W5 IO59NDB4V0 IO86NDB4V0
W6 AV0 AV0
W7 GNDA GNDA
W8 AV1 AV1
W9 AV2 AV2
W10 GNDA GNDA
W11 AV3 AV3
W12 AV6 AV6
W13 GNDA GNDA
W14 AV7 AV7
W15 AV8 AV8
FG484
Pin
Number AFS600 Function AFS1500 Function
W16 GNDA GNDA
W17 AV9 AV9
W18 VCCIB2 VCCIB2
W19 NC IO68PPB2V0
W20 TCK TCK
W21 GND GND
W22 NC IO76PPB2V0
Y1 GEC2/IO60PDB4V0 GEC2/IO87PDB4V0
Y2 IO60NDB4V0 IO87NDB4V0
Y3 GEA2/IO58PDB4V0 GEA2/IO85PDB4V0
Y4 IO58NDB4V0 IO85NDB4V0
Y5 NCAP NCAP
Y6 AC0 AC0
Y7 VCC33A VCC33A
Y8 AC1 AC1
Y9 AC2 AC2
Y10 VCC33A VCC33A
Y11 AC3 AC3
Y12 AC6 AC6
Y13 VCC33A VCC33A
Y14 AC7 AC7
Y15 AC8 AC8
Y16 VCC33A VCC33A
Y17 AC9 AC9
Y18 ADCGNDREF ADCGNDREF
Y19 PTBASE PTBASE
Y20 GNDNVM GNDNVM
Y21 VCCNVM VCCNVM
Y22 VPUMP VPUMP
FG484
Pin
Number AFS600 Function AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-27
FG676
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/default.aspx.
A1 Ball Pad Corner
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
1234567891011121314151617181920212223242526
Package Pin Assignments
4-28 Revision 4
FG676
Pin Number AFS1500 Function
A1 NC
A2 GND
A3 NC
A4 NC
A5 GND
A6 NC
A7 NC
A8 GND
A9 IO17NDB0V2
A10 IO17PDB0V2
A11 GND
A12 IO18NDB0V2
A13 IO18PDB0V2
A14 IO20NDB0V2
A15 IO20PDB0V2
A16 GND
A17 IO21PDB0V2
A18 IO21NDB0V2
A19 GND
A20 IO39NDB1V2
A21 IO39PDB1V2
A22 GND
A23 NC
A24 NC
A25 GND
A26 NC
AA1 NC
AA2 VCCIB4
AA3 IO93PDB4V0
AA4 GND
AA5 IO93NDB4V0
AA6 GEB2/IO86PDB4V0
AA7 IO86NDB4V0
AA8 AV0
AA9 GNDA
AA10 AV1
AA11 AV2
AA12 GNDA
AA13 AV3
AA14 AV6
AA15 GNDA
AA16 AV7
AA17 AV8
AA18 GNDA
AA19 AV9
AA20 VCCIB2
AA21 IO68PPB2V0
AA22 TCK
AA23 GND
AA24 IO76PPB2V0
AA25 VCCIB2
AA26 NC
AB1 GND
AB2 NC
AB3 GEC2/IO87PDB4V0
AB4 IO87NDB4V0
AB5 GEA2/IO85PDB4V0
AB6 IO85NDB4V0
AB7 NCAP
AB8 AC0
AB9 VCC33A
AB10 AC1
AB11 AC2
AB12 VCC33A
AB13 AC3
AB14 AC6
AB15 VCC33A
AB16 AC7
AB17 AC8
AB18 VCC33A
AB19 AC9
AB20 ADCGNDREF
FG676
Pin Number AFS1500 Function
AB21 PTBASE
AB22 GNDNVM
AB23 VCCNVM
AB24 VPUMP
AB25 NC
AB26 GND
AC1 NC
AC2 NC
AC3 NC
AC4 GND
AC5 VCCIB4
AC6 VCCIB4
AC7 PCAP
AC8 AG0
AC9 GNDA
AC10 AG1
AC11 AG2
AC12 GNDA
AC13 AG3
AC14 AG6
AC15 GNDA
AC16 AG7
AC17 AG8
AC18 GNDA
AC19 AG9
AC20 VAREF
AC21 VCCIB2
AC22 PTEM
AC23 GND
AC24 NC
AC25 NC
AC26 NC
AD1 NC
AD2 NC
AD3 GND
AD4 NC
FG676
Pin Number AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-29
AD5 IO94NPB4V0
AD6 GND
AD7 VCC33N
AD8 AT0
AD9 ATRTN0
AD10 AT1
AD11 AT2
AD12 ATRTN1
AD13 AT3
AD14 AT6
AD15 ATRTN3
AD16 AT7
AD17 AT8
AD18 ATRTN4
AD19 AT9
AD20 VCC33A
AD21 GND
AD22 IO76NPB2V0
AD23 NC
AD24 GND
AD25 NC
AD26 NC
AE1 GND
AE2 GND
AE3 NC
AE4 NC
AE5 NC
AE6 NC
AE7 NC
AE8 NC
AE9 GNDA
AE10 NC
AE11 NC
AE12 GNDA
AE13 NC
AE14 NC
FG676
Pin Number AFS1500 Function
AE15 GNDA
AE16 NC
AE17 NC
AE18 GNDA
AE19 NC
AE20 NC
AE21 NC
AE22 NC
AE23 NC
AE24 NC
AE25 GND
AE26 GND
AF1 NC
AF2 GND
AF3 NC
AF4 NC
AF5 NC
AF6 NC
AF7 NC
AF8 NC
AF9 VCC33A
AF10 NC
AF11 NC
AF12 VCC33A
AF13 NC
AF14 NC
AF15 VCC33A
AF16 NC
AF17 NC
AF18 VCC33A
AF19 NC
AF20 NC
AF21 NC
AF22 NC
AF23 NC
AF24 NC
FG676
Pin Number AFS1500 Function
AF25 GND
AF26 NC
B1 GND
B2 GND
B3 NC
B4 NC
B5 NC
B6 VCCIB0
B7 NC
B8 NC
B9 VCCIB0
B10 IO15NDB0V2
B11 IO15PDB0V2
B12 VCCIB0
B13 IO19NDB0V2
B14 IO19PDB0V2
B15 VCCIB1
B16 IO25NDB1V0
B17 IO25PDB1V0
B18 VCCIB1
B19 IO33NDB1V1
B20 IO33PDB1V1
B21 VCCIB1
B22 NC
B23 NC
B24 NC
B25 GND
B26 GND
C1 NC
C2 NC
C3 GND
C4 NC
C5 GAA1/IO01PDB0V0
C6 GAB0/IO02NDB0V0
C7 GAB1/IO02PDB0V0
C8 IO07NDB0V1
FG676
Pin Number AFS1500 Function
Package Pin Assignments
4-30 Revision 4
C9 IO07PDB0V1
C10 IO09PDB0V1
C11 IO13NDB0V2
C12 IO13PDB0V2
C13 IO24PDB1V0
C14 IO26PDB1V0
C15 IO27NDB1V1
C16 IO27PDB1V1
C17 IO35NDB1V2
C18 IO35PDB1V2
C19 GBC0/IO40NDB1V2
C20 GBA0/IO42NDB1V2
C21 IO43NDB1V2
C22 IO43PDB1V2
C23 NC
C24 GND
C25 NC
C26 NC
D1 NC
D2 NC
D3 NC
D4 GND
D5 GAA0/IO01NDB0V0
D6 GND
D7 IO04NDB0V0
D8 IO04PDB0V0
D9 GND
D10 IO09NDB0V1
D11 IO11PDB0V1
D12 GND
D13 IO24NDB1V0
D14 IO26NDB1V0
D15 GND
D16 IO31NDB1V1
D17 IO31PDB1V1
D18 GND
FG676
Pin Number AFS1500 Function
D19 GBC1/IO40PDB1V2
D20 GBA1/IO42PDB1V2
D21 GND
D22 VCCPLB
D23 GND
D24 NC
D25 NC
D26 NC
E1 GND
E2 IO122NPB4V0
E3 IO121PDB4V0
E4 IO122PPB4V0
E5 IO00NDB0V0
E6 IO00PDB0V0
E7 VCCIB0
E8 IO05NDB0V1
E9 IO05PDB0V1
E10 VCCIB0
E11 IO11NDB0V1
E12 IO14PDB0V2
E13 VCCIB0
E14 VCCIB1
E15 IO29NDB1V1
E16 IO29PDB1V1
E17 VCCIB1
E18 IO37NDB1V2
E19 GBB0/IO41NDB1V2
E20 VCCIB1
E21 VCOMPLB
E22 GBA2/IO44PDB2V0
E23 IO48PPB2V0
E24 GBB2/IO45PDB2V0
E25 NC
E26 GND
F1 NC
F2 VCCIB4
FG676
Pin Number AFS1500 Function
F3 IO121NDB4V0
F4 GND
F5 IO123NDB4V0
F6 GAC2/IO123PDB4V0
F7 GAA2/IO125PDB4V0
F8 GAC0/IO03NDB0V0
F9 GAC1/IO03PDB0V0
F10 IO10NDB0V1
F11 IO10PDB0V1
F12 IO14NDB0V2
F13 IO23NDB1V0
F14 IO23PDB1V0
F15 IO32NPB1V1
F16 IO34NDB1V1
F17 IO34PDB1V1
F18 IO37PDB1V2
F19 GBB1/IO41PDB1V2
F20 VCCIB2
F21 IO47PPB2V0
F22 IO44NDB2V0
F23 GND
F24 IO45NDB2V0
F25 VCCIB2
F26 NC
G1 NC
G2 IO119PPB4V0
G3 IO120NDB4V0
G4 IO120PDB4V0
G5 VCCIB4
G6 GAB2/IO124PDB4V0
G7 IO125NDB4V0
G8 GND
G9 VCCIB0
G10 IO08NDB0V1
G11 IO08PDB0V1
G12 GND
FG676
Pin Number AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-31
G13 IO22NDB1V0
G14 IO22PDB1V0
G15 GND
G16 IO32PPB1V1
G17 IO36NPB1V2
G18 VCCIB1
G19 GND
G20 IO47NPB2V0
G21 IO49PDB2V0
G22 VCCIB2
G23 IO46NDB2V0
G24 GBC2/IO46PDB2V0
G25 IO48NPB2V0
G26 NC
H1 GND
H2 NC
H3 IO118NDB4V0
H4 IO118PDB4V0
H5 IO119NPB4V0
H6 IO124NDB4V0
H7 GND
H8 VCOMPLA
H9 VCCPLA
H10 VCCIB0
H11 IO12NDB0V1
H12 IO12PDB0V1
H13 VCCIB0
H14 VCCIB1
H15 IO30NDB1V1
H16 IO30PDB1V1
H17 VCCIB1
H18 IO36PPB1V2
H19 IO38NPB1V2
H20 GND
H21 IO49NDB2V0
H22 IO50PDB2V0
FG676
Pin Number AFS1500 Function
H23 IO50NDB2V0
H24 IO51PDB2V0
H25 NC
H26 GND
J1 NC
J2 VCCIB4
J3 IO115PDB4V0
J4 GND
J5 IO116NDB4V0
J6 IO116PDB4V0
J7 VCCIB4
J8 IO117PDB4V0
J9 VCCIB4
J10 GND
J11 IO06NDB0V1
J12 IO06PDB0V1
J13 IO16NDB0V2
J14 IO16PDB0V2
J15 IO28NDB1V1
J16 IO28PDB1V1
J17 GND
J18 IO38PPB1V2
J19 IO53PDB2V0
J20 VCCIB2
J21 IO52PDB2V0
J22 IO52NDB2V0
J23 GND
J24 IO51NDB2V0
J25 VCCIB2
J26 NC
K1 NC
K2 NC
K3 IO115NDB4V0
K4 IO113PDB4V0
K5 VCCIB4
K6 IO114NDB4V0
FG676
Pin Number AFS1500 Function
K7 IO114PDB4V0
K8 IO117NDB4V0
K9 GND
K10 VCC
K11 VCCIB0
K12 GND
K13 VCCIB0
K14 VCCIB1
K15 GND
K16 VCCIB1
K17 GND
K18 GND
K19 IO53NDB2V0
K20 IO57PDB2V0
K21 GCA2/IO59PDB2V0
K22 VCCIB2
K23 IO54NDB2V0
K24 IO54PDB2V0
K25 NC
K26 NC
L1 GND
L2 NC
L3 IO112PPB4V0
L4 IO113NDB4V0
L5 GFB2/IO109PDB4V0
L6 GFA2/IO110PDB4V0
L7 IO112NPB4V0
L8 IO104PDB4V0
L9 IO111PDB4V0
L10 VCCIB4
L11 GND
L12 VCC
L13 GND
L14 VCC
L15 GND
L16 VCC
FG676
Pin Number AFS1500 Function
Package Pin Assignments
4-32 Revision 4
L17 VCCIB2
L18 GCB2/IO60PDB2V0
L19 IO58NDB2V0
L20 IO57NDB2V0
L21 IO59NDB2V0
L22 GCC2/IO61PDB2V0
L23 IO55PPB2V0
L24 IO56PDB2V0
L25 IO55NPB2V0
L26 GND
M1 NC
M2 VCCIB4
M3 GFC2/IO108PDB4V0
M4 GND
M5 IO109NDB4V0
M6 IO110NDB4V0
M7 GND
M8 IO104NDB4V0
M9 IO111NDB4V0
M10 GND
M11 VCC
M12 GND
M13 VCC
M14 GND
M15 VCC
M16 GND
M17 GND
M18 IO60NDB2V0
M19 IO58PDB2V0
M20 GND
M21 IO68NPB2V0
M22 IO61NDB2V0
M23 GND
M24 IO56NDB2V0
M25 VCCIB2
M26 IO65PDB2V0
FG676
Pin Number AFS1500 Function
N1 NC
N2 NC
N3 IO108NDB4V0
N4 VCCOSC
N5 VCCIB4
N6 XTAL2
N7 GFC1/IO107PDB4V0
N8 VCCIB4
N9 GFB1/IO106PDB4V0
N10 VCCIB4
N11 GND
N12 VCC
N13 GND
N14 VCC
N15 GND
N16 VCC
N17 VCCIB2
N18 IO70PDB2V0
N19 VCCIB2
N20 IO69PDB2V0
N21 GCA1/IO64PDB2V0
N22 VCCIB2
N23 GCC0/IO62NDB2V0
N24 GCC1/IO62PDB2V0
N25 IO66PDB2V0
N26 IO65NDB2V0
P1 NC
P2 NC
P3 IO103PDB4V0
P4 XTAL1
P5 VCCIB4
P6 GNDOSC
P7 GFC0/IO107NDB4V0
P8 VCCIB4
P9 GFB0/IO106NDB4V0
P10 VCCIB4
FG676
Pin Number AFS1500 Function
P11 VCC
P12 GND
P13 VCC
P14 GND
P15 VCC
P16 GND
P17 VCCIB2
P18 IO70NDB2V0
P19 VCCIB2
P20 IO69NDB2V0
P21 GCA0/IO64NDB2V0
P22 VCCIB2
P23 GCB0/IO63NDB2V0
P24 GCB1/IO63PDB2V0
P25 IO66NDB2V0
P26 IO67PDB2V0
R1 NC
R2 VCCIB4
R3 IO103NDB4V0
R4 GND
R5 IO101PDB4V0
R6 IO100NPB4V0
R7 GND
R8 IO99PDB4V0
R9 IO97PDB4V0
R10 GND
R11 GND
R12 VCC
R13 GND
R14 VCC
R15 GND
R16 VCC
R17 GND
R18 GDB2/IO83PDB2V0
R19 IO78PDB2V0
R20 GND
FG676
Pin Number AFS1500 Function
Fusion Family of Mixed Signal FPGAs
Revision 4 4-33
R21 IO72NDB2V0
R22 IO72PDB2V0
R23 GND
R24 IO71PDB2V0
R25 VCCIB2
R26 IO67NDB2V0
T1 GND
T2 NC
T3 GFA1/IO105PDB4V0
T4 GFA0/IO105NDB4V0
T5 IO101NDB4V0
T6 IO96PDB4V0
T7 IO96NDB4V0
T8 IO99NDB4V0
T9 IO97NDB4V0
T10 VCCIB4
T11 VCC
T12 GND
T13 VCC
T14 GND
T15 VCC
T16 GND
T17 VCCIB2
T18 IO83NDB2V0
T19 IO78NDB2V0
T20 GDA1/IO81PDB2V0
T21 GDB1/IO80PDB2V0
T22 IO73NDB2V0
T23 IO73PDB2V0
T24 IO71NDB2V0
T25 NC
T26 GND
U1 NC
U2 NC
U3 IO102PDB4V0
U4 IO102NDB4V0
FG676
Pin Number AFS1500 Function
U5 VCCIB4
U6 IO91PDB4V0
U7 IO91NDB4V0
U8 IO92PDB4V0
U9 GND
U10 GND
U11 VCC33A
U12 GNDA
U13 VCC33A
U14 GNDA
U15 VCC33A
U16 GNDA
U17 VCC
U18 GND
U19 IO74NDB2V0
U20 GDA0/IO81NDB2V0
U21 GDB0/IO80NDB2V0
U22 VCCIB2
U23 IO75NDB2V0
U24 IO75PDB2V0
U25 NC
U26 NC
V1 NC
V2 VCCIB4
V3 IO100PPB4V0
V4 GND
V5 IO95PDB4V0
V6 IO95NDB4V0
V7 VCCIB4
V8 IO92NDB4V0
V9 GNDNVM
V10 GNDA
V11 NC
V12 AV4
V13 NC
V14 AV5
FG676
Pin Number AFS1500 Function
V15 AC5
V16 NC
V17 GNDA
V18 IO77PPB2V0
V19 IO74PDB2V0
V20 VCCIB2
V21 IO82NDB2V0
V22 GDA2/IO82PDB2V0
V23 GND
V24 GDC1/IO79PDB2V0
V25 VCCIB2
V26 NC
W1 GND
W2 IO94PPB4V0
W3 IO98PDB4V0
W4 IO98NDB4V0
W5 GEC1/IO90PDB4V0
W6 GEC0/IO90NDB4V0
W7 GND
W8 VCCNVM
W9 VCCIB4
W10 VCC15A
W11 GNDA
W12 AC4
W13 VCC33A
W14 GNDA
W15 AG5
W16 GNDA
W17 PUB
W18 VCCIB2
W19 TDI
W20 GND
W21 IO84NDB2V0
W22 GDC2/IO84PDB2V0
W23 IO77NPB2V0
W24 GDC0/IO79NDB2V0
FG676
Pin Number AFS1500 Function
Package Pin Assignments
4-34 Revision 4
W25 NC
W26 GND
Y1 NC
Y2 NC
Y3 GEB1/IO89PDB4V0
Y4 GEB0/IO89NDB4V0
Y5 VCCIB4
Y6 GEA1/IO88PDB4V0
Y7 GEA0/IO88NDB4V0
Y8 GND
Y9 VCC33PMP
Y10 NC
Y11 VCC33A
Y12 AG4
Y13 AT4
Y14 ATRTN2
Y15 AT5
Y16 VCC33A
Y17 NC
Y18 VCC33A
Y19 GND
Y20 TMS
Y21 VJTAG
Y22 VCCIB2
Y23 TRST
Y24 TDO
Y25 NC
Y26 NC
FG676
Pin Number AFS1500 Function
Revision 4 5-1
5 – Datasheet Information
List of Changes
The following table lists critical changes that were made in each revision of the Fusion datasheet.
Revision Changes Page
Revision 4
(January 2013)
The "Product Ordering Codes" section has been updated to mention "Y" as "Blank"
mentioning "Device Does Not Include License to Implement IP Based on the
Cryptography Research, Inc. (CRI) Patent Portfolio" (SAR 43177).
III
The note in Table 2-12 • Fusion CCC/PLL Specification referring the reader to
SmartGen was revised to refer instead to the online help associated with the core
(SAR 42563).
2-30
Table 2-49 • Analog Channel Specifications was modified to update the uncalibrated
offset values (AFS250) of the external and internal temperature monitors (SAR
43134).
2-120
In Table 2-57 • Prescaler Control Truth Table—AV (x = 0), AC (x = 1), and AT (x = 3),
changed the column heading from 'Full-Scale Voltage' to 'Full Scale Voltage in 10-Bit
Mode', and added and updated Notes as required (SAR 20812).
2-133
The values for the Speed Grade (-1 and Std.) for FDDRIMAX (Table 2-180 • Input
DDR Propagation Delays) and values for the Speed Grade (-2 and Std.) for
FDDOMAX (Table 2-182 • Output DDR Propagation Delays) had been inadvertently
interchanged. This has been rectified (SAR 38514).
2-223,
2-225
Added description about what happens if a user connects VAREF to an external 3.3
V on their board to the "VAREF Analog Reference Voltage" section (SAR 35188).
2-228
Added a note to Table 3-2 • Recommended Operating Conditions1 (SAR 43429):
The programming temperature range supported is Tambient = 0°C to 85°C.
3-3
Added the Package Thermal details for AFS600-PQ208 and AFS250-PQ208 to
Table 3-6 • Package Thermal Resistance (SAR 37816). Deleted the Die Size column
from the table (SAR 43503).
3-7
Libero Integrated Design Environment (IDE) was changed to Libero System-on-Chip
(SoC) throughout the document (SAR 42495).
Live at Power-Up (LAPU) has been replaced with ’Instant On’.
NA
Revision 3
(August 2012)
Microblade U1AFS250 and U1AFS1500 devices were added to the product tables. IIV
A sentence pertaining to the analog I/Os was added to the "Specifying I/O States
During Programming" section (SAR 34831).
1-8
The "RC Oscillator" section was revised to correct a sentence that did not
differentiate accuracy for commercial and industrial temperature ranges, which is
given in Table 2-9 • Electrical Characteristics of RC Oscillator (SAR 33722).
2-20
Figure 2-57 • FIFO Read and Figure 2-58 • FIFO Write are new (SAR 34840). 2-75
The first paragraph of the "Offset" section was removed; it was intended to be
replaced by the paragraph following it (SAR 22647).
2-98
IOL and IOH values for 3.3 V GTL+ and 2.5 V GTL+ were corrected in Table 2-86 •
Summary of Maximum and Minimum DC Input and Output Levels Applicable to
Commercial and Industrial Conditions (SAR 39813).
2-167
Datasheet Information
5-2 Revision 4
Revision 3
(continued)
The drive strength, IOL, and IOH for 3.3 V GTL and 2.5 V GTL were changed from
25 mA to 20 mA in the following tables (SAR 37373):
Table 2-86 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions,
Table 2-92 • Summary of I/O Timing Characteristics – Software Default Settings
Table 2-96 • I/O Output Buffer Maximum Resistances 1
Table 2-138 • Minimum and Maximum DC Input and Output Levels
Table 2-141 • Minimum and Maximum DC Input and Output Levels
2-167
2-170
2-172
2-202
2-203
The following sentence was deleted from the "2.5 V LVCMOS" section (SAR 34800):
"It uses a 5 V–tolerant input buffer and push-pull output buffer."
2-184
Corrected the inadvertent error in maximum values for LVPECL VIH and VIL and
revised them to "3.6" in Table 2-171 • Minimum and Maximum DC Input and Output
Levels, making these consistent with Table 3-1 • Absolute Maximum Ratings, and
Table 3-4 • Overshoot and Undershoot Limits 1 (SAR 37687).
2-214
The maximum frequency for global clock parameter was removed from Tab l e 2- 5
AFS1500 Global Resource Timing through Table 2-8 • AFS090 Global Resource
Timing because a frequency on the global is only an indication of what the global
network can do. There are other limiters such as the SRAM, I/Os, and PLL.
SmartTime software should be used to determine the design frequency (SAR
36955).
2-17 to
2-18
Revision 2
(March 2012)
The phrase "without debug" was removed from the "Soft ARM Cortex-M1 Fusion
Devices (M1)" section (SAR 21390).
I
The "In-System Programming (ISP) and Security" section, "Security" section, "Flash
Advantages" section, and "Security" section were revised to clarify that although no
existing security measures can give an absolute guarantee, Microsemi FPGAs
implement the best security available in the industry (SAR 34679).
I, 1-2,
2-231
The Y security option and Licensed DPA Logo was added to the "Product Ordering
Codes" section. The trademarked Licensed DPA Logo identifies that a product is
covered by a DPA counter-measures license from Cryptography Research (SAR
34721).
III
The "Specifying I/O States During Programming" section is new (SAR 34693). 1-8
The following information was added before Figure 2-17 • XTLOSC Macro:
In the case where the Crystal Oscillator block is not used, the XTAL1 pin should be
connected to GND and the XTAL2 pin should be left floating (SAR 24119).
2-21
Table 2-12 • Fusion CCC/PLL Specification was updated. A note was added
indicating that when the CCC/PLL core is generated by Microsemi core generator
software, not all delay values of the specified delay increments are available (SAR
34814).
2-30
A note was added to Figure 2-27 • Real-Time Counter System (not all the signals are
shown for the AB macro) stating that the user is only required to instantiate the
VRPSM macro if the user wishes to specify PUPO behavior of the voltage regulator
to be different from the default, or employ user logic to shut the voltage regulator off
(SAR 21773).
2-33
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-3
Revision 2
(continued)
VPUMP was incorrectly represented as VPP in several places. This was corrected to
VPUMP in the "Standby and Sleep Mode Circuit Implementation" section and
Table 3-8 • AFS1500 Quiescent Supply Current Characteristics through Table 3-11 •
AFS090 Quiescent Supply Current Characteristics (21963).
2-34, 3-10
Additional information was added to the Flash Memory Block "Write Operation"
section, including an explanation of the fact that a copy-page operation takes no less
than 55 cycles (SAR 26338).
2-47
The "FlashROM" section was revised to refer to Figure 2-46 • FlashROM Timing
Diagram and Table 2-26 • FlashROM Access Time rather than stating 20 MHz as the
maximum FlashROM access clock and 10 ns as the time interval for D0 to become
valid or invalid (SAR 22105).
2-56, 2-57
The following figures were deleted (SAR 29991). Reference was made to a new
application note, Simultaneous Read-Write Operations in Dual-Port SRAM for Flash-
Based cSoCs and FPGAs, which covers these cases in detail (SAR 34862).
Figure 2-55 • Write Access after Write onto Same Address
Figure 2-56 • Read Access after Write onto Same Address
Figure 2-57 • Write Access after Read onto Same Address
The port names in the SRAM "Timing Waveforms", "Timing Characteristics", SRAM
tables, Figure 2-55 • RAM Reset. Applicable to both RAM4K9 and RAM512x18., and
the FIFO "Timing Characteristics" tables were revised to ensure consistency with the
software names (SAR 35753).
2-66,
2-69,
2-68, 2-78
In several places throughout the datasheet, GNDREF was corrected to
ADCGNDREF (SAR 20783):
Figure 2-64 • Analog Block Macro
Table 2-36 • Analog Block Pin Description
"ADC Operation" section
2-80
2-81
2-107
The following note was added below Figure 2-78 • Timing Diagram for the
Temperature Monitor Strobe Signal:
When the IEEE 1149.1 Boundary Scan EXTEST instruction is executed, the AG pad
drive strength ceases and becomes a 1 µA sink into the Fusion device. (SAR
24796).
2-96
The "Analog-to-Digital Converter Block" section was extensively revised,
reorganizing the information and adding the "ADC Theory of Operation" section and
"Acquisition Time or Sample Time Control" section. The "ADC Example" section was
reworked and corrected (SAR 20577).
2-99
Table 2-49 • Analog Channel Specifications was modified to include calibrated and
uncalibrated values for offset (AFS090 and AFS250) for the external and internal
temperature monitors. The "Offset" section was revised accordingly and now
references Table 2-49 • Analog Channel Specifications (SARs 22647, 27015).
2-98,
2-120
The "Intra-Conversion" section and "Injected Conversion" section had definitions
incorrectly interchanged and have been corrected. Figure 2-92 • Intra-Conversion
Timing Diagram and Figure 2-93 • Injected Conversion Timing Diagram were also
incorrectly interchanged and have been replaced correctly. Reference in the figure
notes to EQ 10 has been corrected to EQ 23 (SAR 20547).
2-112,
2-115,
2-116
The prescalar range for the 'Analog Input (direct input to ADC)" configurations was
removed as inapplicable for direct inputs. The input resistance for direct inputs is
covered in Table 2-50 • ADC Characteristics in Direct Input Mode (SAR 31201).
2-123
Revision Changes Page
Datasheet Information
5-4 Revision 4
Revision 2
(continued)
The "Examples" for calibrating accuracy for ADC channels were revised and
corrected to make them consistent with terminology in the associated tables (SARs
36791, 36773).
2-127
A note was added to Table 2-56 • Analog Quad ACM Byte Assignment and the
introductory text for Table 2-66 • Internal Temperature Monitor Control Truth Table,
stating that for the internal temperature monitor to function, Bit 0 of Byte 2 for all 10
Quads must be set (SAR 34418).
2-132,
2-134
tDOUT was corrected to tDIN in Figure 2-116 • Input Buffer Timing Model and Delays
(example) (SAR 37115).
2-164
The formulas in the table notes for Table 2-97 • I/O Weak Pull-Up/Pull-Down
Resistances were corrected (SAR 34751).
2-174
The AC Loading figures in the "Single-Ended I/O Characteristics" section were
updated to match tables in the "Summary of I/O Timing Characteristics – Default I/O
Software Settings" section (SAR 34877).
2-178
The following notes were removed from Table 2-168 • Minimum and Maximum DC
Input and Output Levels (SAR 34808):
±5%
Differential input voltage = ±350 mV
2-212
An incomplete, duplicate sentence was removed from the end of the "GNDAQ
Ground (analog quiet)" pin description (SAR 30185).
2-226
Information about configuration of unused I/Os was added to the "User Pins" section
(SAR 32642).
2-228
The following information was added to the pin description for "XTAL1 Crystal
Oscillator Circuit Input" and "XTAL2 Crystal Oscillator Circuit Input" (SAR 24119).
2-230
The input resistance to ground value in Table 3-3 • Input Resistance of Analog Pads
for Analog Input (direct input to ADC), was corrected from 1 M (typical) to 2 k
(typical) (SAR 34371).
3-4
The Storage Temperature column in Table 3-5 • FPGA Programming, Storage, and
Operating Limits stated Min. TJ twice for commercial and industrial product grades
and has been corrected to Min. TJ and Max. TJ (SAR 29416).
3-5
The reference to guidelines for global spines and VersaTile rows, given in the
"Global Clock Dynamic Contribution—PCLOCK" section, was corrected to the
"Spine Architecture" section of the Global Resources chapter in the Fusion
FPGA Fabric User's Guide (SAR 34741).
3-24
Package names used in the "Package Pin Assignments" section were revised to
match standards given in Package Mechanical Drawings (SAR 36612).
4-1
July 2010 The versioning system for datasheets has been changed. Datasheets are assigned
a revision number that increments each time the datasheet is revised. The "Fusion
Device Status" table indicates the status for each device in the device family.
N/A
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-5
v2.0, Revision 1
(July 2009)
The MicroBlade and Fusion datasheets have been combined. Pigeon Point
information is new.
CoreMP7 support was removed since it is no longer offered.
–F was removed from the datasheet since it is no longer offered.
The operating temperature was changed from ambient to junction to better reflect
actual conditions of operations.
Commercial: 0°C to 85°C
Industrial: –40°C to 100°C
The version number category was changed from Preliminary to Production, which
means the datasheet contains information based on final characterization. The
version number changed from Preliminary v1.7 to v2.0.
N/A
The "Integrated Analog Blocks and Analog I/Os" section was updated to include a
reference to the "Analog System Characteristics" section in the Device Architecture
chapter of the datasheet, which includes Table 2-46 • Analog Channel Specifications
and specific voltage data.
1-4
The phrase "Commercial-Case Conditions" in timing table titles was changed to
"Commercial Temperature Range Conditions."
N/A
The "Crystal Oscillator" section was updated significantly. Please review carefully. 2-21
The "Real-Time Counter (part of AB macro)" section was updated significantly.
Please review carefully.
2-35
There was a typo in Table 2-19 • Flash Memory Block Pin Names for the
ERASEPAGE description; it was the same as DISCARDPAGE. As as a result, the
ERASEPAGE description was updated.
2-42
The tFMAXCLKNVM parameter was updated in Table 2-25 • Flash Memory Block
Timing.
2-54
Table 2-31 • RAM4K9 and Table 2-32 • RAM512X18 were updated. 2-69
In Table 2-36 • Analog Block Pin Description, the Function description for PWRDWN
was changed from "Comparator power-down if 1"
to
"ADC comparator power-down if 1. When asserted, the ADC will stop functioning,
and the digital portion of the analog block will continue operating. This may result in
invalid status flags from the analog block. Therefore, Microsemi does not
recommend asserting the PWRDWN pin."
2-81
Figure 2-75 • Gate Driver Example was updated. 2-94
The "ADC Operation" section was updated. Please review carefully. 2-107
Figure 2-92 • Intra-Conversion Timing Diagram and Figure 2-93 • Injected
Conversion Timing Diagram are new.
2-116
The "Typical Performance Characteristics" section is new. 2-118
Table 2-49 • Analog Channel Specifications was significantly updated. 2-120
Table 2-50 • ADC Characteristics in Direct Input Mode was significantly updated. 2-123
In Table 2-52 • Calibrated Analog Channel Accuracy 1,2,3, note 2 was updated. 2-126
In Table 2-53 • Analog Channel Accuracy: Monitoring Standard Positive Voltages,
note 1 was updated.
2-127
In Table 2-54 ACM Address Decode Table for Analog Quad, bit 89 was removed. 2-129
Revision Changes Page
Datasheet Information
5-6 Revision 4
v2.0, Revision 1
(continued)
The data in the 2.5 V LCMOS and LVCMOS 2.5 V / 5.0 V rows were updated in
Table 2-75 • Fusion Standard and Advanced I/O – Hot-Swap and 5 V Input Tolerance
Capabilities.
2-146
In Table 2-78 • Fusion Standard I/O Standards—OUT_DRIVE Settings, LVCMOS
1.5 V, for OUT_DRIVE 2, was changed from a dash to a check mark.
2-155
The "VCC15A Analog Power Supply (1.5 V)" definition was changed from "A 1.5 V
analog power supply input should be used to provide this input" to "1.5 V clean
analog power supply input for use by the 1.5 V portion of the analog circuitry."
2-226
In the "VCC33PMP Analog Power Supply (3.3 V)" pin description, the following text
was changed from "VCC33PMP should be powered up before or simultaneously
with VCC33A" to "VCC33PMP should be powered up simultaneously with or after
VCC33A."
2-226
The "VCCOSC Oscillator Power Supply (3.3 V)" section was updated to include
information about when to power the pin.
2-227
In the "128-Bit AES Decryption" section, FIPS-192 was incorrect and changed to
FIPS-197.
2-231
The note in Table 2-84 • Fusion Standard and Advanced I/O Attributes vs. I/O
Standard Applications was updated.
2-159
For 1.5 V LVCMOS, the VIL and VIH parameters, 0.30 * VCCI was changed to 0.35 *
VCCI and 0.70 * VCCI was changed to 0.65 * VCCI in Table 2-86 • Summary of
Maximum and Minimum DC Input and Output Levels Applicable to Commercial and
Industrial Conditions, Table 2-87 • Summary of Maximum and Minimum DC Input
and Output Levels Applicable to Commercial and Industrial Conditions, and
Table 2-88 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions.
In Table 2-87 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions, the VIH max column was
updated.
2-167 to
2-168
Table 2-89 • Summary of Maximum and Minimum DC Input Levels Applicable to
Commercial and Industrial Conditions was updated to include notes 3 and 4. The
temperature ranges were also updated in notes 1 and 2.
2-168
The titles in Table 2-92 • Summary of I/O Timing Characteristics – Software Default
Settings to Table 2-94 • Summary of I/O Timing Characteristics – Software Default
Settings were updated to "VCCI = I/O Standard Dependent."
2-170 to
2-171
Below Table 2-98 • I/O Short Currents IOSH/IOSL, the paragraph was updated to
change 110°C to 100°C and three months was changed to six months.
2-175
Table 2-99 • Short Current Event Duration before Failure was updated to remove
110°C data.
2-177
In Table 2-101 • I/O Input Rise Time, Fall Time, and Related I/O Reliability,
LVTTL/LVCMOS rows were changed from 110°C to 100°C.
2-177
VCC33PMP was added to Table 3-1 • Absolute Maximum Ratings. In addition,
conditions for AV, AC, AG, and AT were also updated.
3-1
VCC33PMP was added to Table 3-2 • Recommended Operating Conditions1. In
addition, conditions for AV, AC, AG, and AT were also updated.
3-3
Table 3-5 • FPGA Programming, Storage, and Operating Limits was updated to
include new data and the temperature ranges were changed. The notes were
removed from the table.
3-5
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-7
v2.0, Revision 1
(continued)
Table 3-6 • Package Thermal Resistance was updated to include new data. 3-7
In EQ 4 to EQ 6, the junction temperature was changed from 110°C to 100°C. 3-8 to 3-8
Table 3-8 • AFS1500 Quiescent Supply Current Characteristics through Table 3-11 •
AFS090 Quiescent Supply Current Characteristics are new and have replaced the
Quiescent Supply Current Characteristics (IDDQ) table.
3-10 to
3-16
In Table 3-14 • Different Components Contributing to the Dynamic Power
Consumption in Fusion Devices, the power supply for PAC9 and PAC10 were
changed from VMV/VCC to VCCI.
3-22
In Table 3-15 • Different Components Contributing to the Static Power Consumption
in Fusion Devices, the power supply for PDC7 and PDC8 were changed from
VMV/VCC to VCCI. PDC1 was updated from TBD to 18.
3-23
The "QN108" table was updated to remove the duplicates of pins B12 and B34. 4-2
Preliminary v1.7
(October 2008)
The version number category was changed from Advance to Preliminary, which
means the datasheet contains information based on simulation and/or initial
characterization. The information is believed to be correct, but changes are possible.
For the VIL and VIH parameters, 0.30 * VCCI was changed to 0.35 * VCCI and 0.70
* VCCI was changed to 0.65 * VCCI in Table 2-126 • Minimum and Maximum DC
Input and Output Levels.
2-196
The version number category was changed from Advance to Preliminary, which
means the datasheet contains information based on simulation and/or initial
characterization. The information is believed to be correct, but changes are possible.
N/A
The following updates were made to Table 2-141 • Minimum and Maximum DC Input
and Output Levels:
Temperature Digital Output
213 00 1111 1101
283 01 0001 1011
358 01 0110 0110 – only the digital output was updated.
Temperature 358 remains in the temperature column.
2-203
In Advance v1.2, the "VAREF Analog Reference Voltage" pin description was
significantly updated but the change was not noted in the change table.
2-228
Advance v1.6
(August 2008)
The title of the datasheet changed from Actel Programmable System Chips to Actel
Fusion Mixed Signal FPGAs. In addition, all instances of programmable system chip
were changed to mixed signal FPGA.
N/A
The references to the Peripherals User’s Guide in the "No-Glitch MUX (NGMUX)"
section and "Voltage Regulator Power Supply Monitor (VRPSM)" section were
changed to Fusion Handbook.
2-32, 2-42
Advance v1.5
(July 2008)
The following bullet was updated from High-Voltage Input Tolerance: ±12 V to High-
Voltage Input Tolerance: 10.5 V to 12 V.
I
The following bullet was updated from Programmable 1, 3, 10, 30 µA and 25 mA
Drive Strengths to Programmable 1, 3, 10, 30 µA and 20 mA Drive Strengths.
I
Revision Changes Page
Datasheet Information
5-8 Revision 4
Advance v1.5
(continued)
This bullet was added to the "Integrated A/D Converter (ADC) and Analog I/O"
section: ADC Accuracy is Better than 1%
I
In the "Integrated Analog Blocks and Analog I/Os" section, ±4 LSB was changed to
0.72. The following sentence was deleted:
The input range for voltage signals is from –12 V to +12 V with full-scale output
values from 0.125 V to 16 V.
In addition, 2°C was changed to 3°C:
"One analog input in each quad can be connected to an external temperature
monitor diode and achieves detection accuracy of ±3ºC."
The following sentence was deleted:
The input range for voltage signals is from –12 V to +12 V with full-scale output
values from 0.125 V to 16 V.
1-4
The title of the datasheet changed from Actel Programmable System Chips to Actel
Fusion Mixed Signal FPGAs. In addition, all instances of programmable system chip
were changed to mixed signal FPGA.
N/A
Advance v1.4
(July 2008)
In Table 3-8 · Quiescent Supply Current Characteristics (IDDQ)1, footnote
references were updated for IDC2 and IDC3.
Footnote 3 and 4 were updated and footnote 5 is new.
3-11
Advance v1.3
(July 2008)
The "ADC Description" section was significantly updated. Please review carefully. 2-102
Advance v1.2
(May 2008)
Table 2-25 • Flash Memory Block Timing was significantly updated. 2-55
The "VAREF Analog Reference Voltage" pin description section was significantly
update. Please review it carefully.
2-226
Table 2-45 • ADC Interface Timing was significantly updated. 2-110
Table 2-56 • Direct Analog Input Switch Control Truth Table—AV (x = 0), AC (x = 1),
and AT (x = 3) was significantly updated.
2-131
The following sentence was deleted from the "Voltage Monitor" section:
The Analog Quad inputs are tolerant up to 12 V + 10%.
2-86
The "180-Pin QFN" figure was updated. D1 to D4 are new and the figure was
changed to bottom view. The note below the figure is new.
3-3
Advance v1.1
(May 2008)
The following text was incorrect and therefore deleted:
VCC33A Analog Power Filter
Analog power pin for the analog power supply low-pass filter. An external 100 pF
capacitor should be connected between this pin and ground.
There is still a description of VCC33A on page 2-224.
2-204
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-9
Advance v1.0
(January 2008)
All Timing Characteristics tables were updated. For the Differential I/O Standards,
the Standard I/O support tables are new.
N/A
Table 2-3 • Array Coordinates was updated to change the max x and y values 2-9
Table 2-12 • Fusion CCC/PLL Specification was updated. 2-31
A note was added to Table 2-16 · RTC ACM Memory Map.2-37
A reference to the Peripheral’s User’s Guide was added to the "Voltage Regulator
Power Supply Monitor (VRPSM)" section.
2-42
In Table 2-25 • Flash Memory Block Timing, the commercial conditions were
updated.
2-55
In Table 2-26 • FlashROM Access Time, the commercial conditions were missing
and have been added below the title of the table.
2-58
In Table 2-36 • Analog Block Pin Description, the function description was updated
for the ADCRESET.
2-82
In the "Voltage Monitor" section, the following sentence originally had ± 10% and it
was changed to +10%.
The Analog Quad inputs are tolerant up to 12 V + 10%.
In addition, this statement was deleted from the datasheet:
Each I/O will draw power when connected to power (3 mA at 3 V).
2-86
The "Terminology" section is new. 2-88
The "Current Monitor" section was significantly updated. Figure 2-72 • Timing
Diagram for Current Monitor Strobe to Figure 2-74 • Negative Current Monitor and
Table 2-37 • Recommended Resistor for Different Current Range Measurement are
new.
2-90
The "ADC Description" section was updated to add the "Terminology" section.2-93
In the "Gate Driver" section, 25 mA was changed to 20 mA and 1.5 MHz was
changed to 1.3 MHz. In addition, the following sentence was deleted:
The maximum AG pad switching frequency is 1.25 MHz.
2-94
The "Temperature Monitor" section was updated to rewrite most of the text and add
Figure 2-78, Figure 2-79, and Table 2-38 • Temperature Data Format.
2-96
In Table 2-38 • Temperature Data Format, the temperature K column was changed
for 85°C from 538 to 358.
2-98
In Table 2-45 • ADC Interface Timing, "Typical-Case" was changed to "Worst-Case." 2-110
The "ADC Interface Timing" section is new. 2-110
Table 2-46 • Analog Channel Specifications was updated. 2-118
The "VCC15A Analog Power Supply (1.5 V)" section was updated. 2-224
The "VCCPLA/B PLL Supply Voltage" section is new. 2-225
In "VCCNVM Flash Memory Block Power Supply (1.5 V)" section, supply was
changed to supply input.
2-224
The "VCCPLA/B PLL Supply Voltage" pin description was updated to include the
following statement:
Actel recommends tying VCCPLX to VCC and using proper filtering circuits to
decouple VCC noise from PLL.
2-225
The "VCOMPLA/B Ground for West and East PLL" section was updated. 2-225
Revision Changes Page
Datasheet Information
5-10 Revision 4
Advance 1.0
(continued)
In Table 2-47 • ADC Characteristics in Direct Input Mode, the commercial conditions
were updated and note 2 is new.
2-121
The VCC33ACAP signal name was changed to "XTAL1 Crystal Oscillator Circuit
Input".
2-228
Table 2-48 • Uncalibrated Analog Channel Accuracy* is new. 2-123
Table 2-49 • Calibrated Analog Channel Accuracy 1,2,3 is new. 2-124
Table 2-50 • Analog Channel Accuracy: Monitoring Standard Positive Voltages is
new.
2-125
In Table 2-57 • Voltage Polarity Control Truth Table—AV (x = 0), AC (x = 1), and AT
(x = 3)*, the following I/O Bank names were changed:
Hot-Swap changed to Standard
LVDS changed to Advanced
2-131
In Table 2-58 • Prescaler Op Amp Power-Down Truth Table—AV (x = 0), AC (x = 1),
and AT (x = 3), the following I/O Bank names were changed:
Hot-Swap changed to Standard
LVDS changed to Advanced
2-132
In the title of Table 2-64 • I/O Standards Supported by Bank Type, LVDS I/O was
changed to Advanced I/O.
2-134
The title was changed from "Fusion Standard, LVDS, and Standard plus Hot-Swap
I/O" to Table 2-68 • Fusion Standard and Advanced I/O Features. In addition, the
table headings were all updated. The heading used to be Standard and LVDS I/O
and was changed to Advanced I/O. Standard Hot-Swap was changed to just
Standard.
2-136
This sentence was deleted from the "Slew Rate Control and Drive Strength" section:
The Standard hot-swap I/Os do not support slew rate control. In addition, these
references were changed:
• From: Fusion hot-swap I/O (Table 2-69 on page 2-122) To: Fusion Standard I/O
• From: Fusion LVDS I/O (Table 2-70 on page 2-122) To: Fusion Advanced I/O
2-152
The "Cold-Sparing Support" section was significantly updated. 2-143
In the title of Table 2-75 • Fusion Standard I/O Standards—OUT_DRIVE Settings,
Hot-Swap was changed to Standard.
2-153
In the title of Table 2-76 • Fusion Advanced I/O Standards—SLEW and OUT_DRIVE
Settings, LVDS was changed to Advanced.
2-153
In the title of Table 2-81 • Fusion Standard and Advanced I/O Attributes vs. I/O
Standard Applications, LVDS was changed to Advanced.
2-157
In Figure 2-111 • Naming Conventions of Fusion Devices with Three Digital I/O
Banks and Figure 2-112 • Naming Conventions of Fusion Devices with Four I/O
Banks the following names were changed:
Hot-Swap changed to Standard
LVDS changed to Advanced
2-160
The Figure 2-113 • Timing Model was updated. 2-161
In the notes for Table 2-86 • Summary of Maximum and Minimum DC Input Levels
Applicable to Commercial and Industrial Conditions, TJ was changed to TA.
2-166
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-11
Advance v1.0
(continued)
This change table states that in the "208-Pin PQFP" table listed under the Advance
v0.8 changes, the AFS090 device had a pin change. That is incorrect. Pin 102 was
updated for AFS250 and AFS600. The function name changed from VCC33ACAP to
VCC33A.
3-8
Advance v0.9
(October 2007)
In the "Package I/Os: Single-/Double-Ended (Analog)" table, the
AFS1500/M7AFS1500 I/O counts were updated for the following devices:
FG484: 223/109
FG676: 252/126
II
In the "108-Pin QFN" table, the function changed from VCC33ACAP to VCC33A for the
following pin:
B25
3-2
In the "180-Pin QFN" table, the function changed from VCC33ACAP to VCC33A for the
following pins:
AFS090: B29
AFS250: B29
3-4
In the "208-Pin PQFP" table, the function changed from VCC33ACAP to VCC33A for the
following pins:
AFS090: 102
AFS250: 102
3-8
In the "256-Pin FBGA" table, the function changed from VCC33ACAP to VCC33A for the
following pins:
AFS090: T14
AFS250: T14
AFS600: T14
AFS1500: T14
3-12
Advance v0.9
(continued)
In the "484-Pin FBGA" table, the function changed from VCC33ACAP to VCC33A for the
following pins:
AFS600: AB18
AFS1500: AB18
3-20
In the "676-Pin FBGA" table, the function changed from VCC33ACAP to VCC33A for the
following pins:
AFS1500: AD20
3-28
Advance v0.8
(June 2007)
Figure 2-16 • Fusion Clocking Options and the "RC Oscillator" section were updated
to change GND_OSC and VCC_OSC to GNDOSC and VCCOSC.
2-20, 2-21
Figure 2-19 • Fusion CCC Options: Global Buffers with the PLL Macro was updated
to change the positions of OADIVRST and OADIVHALF, and a note was added.
2-25
The "Crystal Oscillator" section was updated to include information about controlling
and enabling/disabling the crystal oscillator.
2-22
Table 2-11 · Electrical Characteristics of the Crystal Oscillator was updated to
change the typical value of IDYNXTAL for 0.032–0.2 MHz to 0.19.
2-24
The "1.5 V Voltage Regulator" section was updated to add "or floating" in the
paragraph stating that an external pull-down is required on TRST to power down the
VR.
2-41
The "1.5 V Voltage Regulator" section was updated to include information on
powering down with the VR.
2-41
Revision Changes Page
Datasheet Information
5-12 Revision 4
Advance v0.8
(continued)
This sentence was updated in the "No-Glitch MUX (NGMUX)" section to delete GLA:
The GLMUXCFG[1:0] configuration bits determine the source of the CLK inputs (i.e.,
internal signal or GLC).
2-32
In Table 2-13 • NGMUX Configuration and Selection Table, 10 and 11 were deleted. 2-32
The method to enable sleep mode was updated for bit 0 in Table 2-16 • RTC
Control/Status Register.
2-38
S2 was changed to D2 in Figure 2-39 • Read Waveform (Pipe Mode, 32-bit access)
for RD[31:0] was updated.
2-51
The definitions for bits 2 and 3 were updated in Table 2-24 • Page Status Bit
Definition.
2-52
Figure 2-46 • FlashROM Timing Diagram was updated. 2-58
Table 2-26 • FlashROM Access Time is new. 2-58
Figure 2-55 • Write Access After Write onto Same Address, Figure 2-56 Read
Access After Write onto Same Address, and Figure 2-57 • Write Access After Read
onto Same Address are new.
2-68
2-70
Table 2-31 • RAM4K9 and Table 2-32 • RAM512X18 were updated. 2-71, 2-72
The VAREF and SAMPLE functions were updated in Table 2-36 • Analog Block Pin
Description.
2-82
The title of Figure 2-72 • Timing Diagram for Current Monitor Strobe was updated to
add the word "positive."
2-91
The "Gate Driver" section was updated to give information about the switching rate
in High Current Drive mode.
2-94
The "ADC Description" section was updated to include information about the
SAMPLE and BUSY signals and the maximum frequencies for SYSCLK and
ADCCLK. EQ 2 was updated to add parentheses around the entire expression in the
denominator.
2-102
Table 2-46 · Analog Channel Specifications and Table 2-47 · ADC Characteristics in
Direct Input Mode were updated.
2-118,
2-121
The note was removed from Table 2-55 • Analog Multiplexer Truth Table—AV (x = 0),
AC (x = 1), and AT (x = 3).
2-131
Table 2-63 • Internal Temperature Monitor Control Truth Table is new. 2-132
The "Cold-Sparing Support" section was updated to add information about cases
where current draw can occur.
2-143
Figure 2-104 • Solution 4 was updated. 2-147
Table 2-75 • Fusion Standard I/O Standards—OUT_DRIVE Settings was updated. 2-153
The "GNDA Ground (analog)" section and "GNDAQ Ground (analog quiet)" section
were updated to add information about maximum differential voltage.
2-224
The "VAREF Analog Reference Voltage" section and "VPUMP Programming Supply
Voltage" section were updated.
2-226
The "VCCPLA/B PLL Supply Voltage" section was updated to include information
about the east and west PLLs.
2-225
The VCOMPLF pin description was deleted. N/A
The "Axy Analog Input/Output" section was updated with information about
grounding and floating the pin.
2-226
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-13
Advance v0.8
(continued)
The voltage range in the "VPUMP Programming Supply Voltage" section was
updated. The parenthetical reference to "pulled up" was removed from the
statement, "VPUMP can be left floating or can be tied (pulled up) to any voltage
between 0 V and 3.6 V."
2-225
The "ATRTNx Temperature Monitor Return" section was updated with information
about grounding and floating the pin.
2-226
The following text was deleted from the "VREF I/O Voltage Reference" section: (all
digital I/O).
2-225
The "NCAP Negative Capacitor" section and "PCAP Positive Capacitor" section
were updated to include information about the type of capacitor that is required to
connect the two.
2-228
1 µF was changed to 100 pF in the "XTAL1 Crystal Oscillator Circuit Input".2-228
The "Programming" section was updated to include information about VCCOSC.2-229
The VMV pins have now been tied internally with the VCCI pins. N/A
The AFS090"108-Pin QFN" table was updated. 3-2
The AFS090 and AFS250 devices were updated in the "108-Pin QFN" table.3-2
The AFS250 device was updated in the "208-Pin PQFP" table.3-8
The AFS600 device was updated in the "208-Pin PQFP" table.3-8
The AFS090, AFS250, AFS600, and AFS1500 devices were updated in the "256-Pin
FBGA" table.
3-12
The AFS600 and AFS1500 devices were updated in the "484-Pin FBGA" table.3-20
Advance v0.7
(January 2007)
The AFS600 device was updated in the "676-Pin FBGA" table.3-28
The AFS1500 digital I/O count was updated in the "Fusion Family" table.I
The AFS1500 digital I/O count was updated in the "Package I/Os: Single-/Double-
Ended (Analog)" table.
II
Advance v0.6
(October 2006)
The second paragraph of the "PLL Macro" section was updated to include
information about POWERDOWN.
2-30
The description for bit 0 was updated in Table 2-17 · RTC Control/Status Register.2-38
3.9 was changed to 7.8 in the "Crystal Oscillator (Xtal Osc)" section.2-40.
All function descriptions in Table 2-18 · Signals for VRPSM Macro.2-42
In Table 2-19 • Flash Memory Block Pin Names, the RD[31:0] description was
updated.
2-43
The "RESET" section was updated. 2-61
The "RESET" section was updated. 2-64
Table 2-35 • FIFO was updated. 2-79
The VAREF function description was updated in Table 2-36 • Analog Block Pin
Description.
2-82
The "Voltage Monitor" section was updated to include information about low power
mode and sleep mode.
2-86
The text in the "Current Monitor" section was changed from 2 mV to 1 mV. 2-90
The "Gate Driver" section was updated to include information about forcing 1 V on
the drain.
2-94
Revision Changes Page
Datasheet Information
5-14 Revision 4
Advance v0.6
(continued)
The "Analog-to-Digital Converter Block" section was updated with the following
statement:
"All results are MSB justified in the ADC."
2-99
The information about the ADCSTART signal was updated in the "ADC Description"
section.
2-102
Table 2-46 · Analog Channel Specifications was updated. 2-118
Table 2-47 · ADC Characteristics in Direct Input Mode was updated. 2-121
Table 2-51 ACM Address Decode Table for Analog Quad was updated. 2-127
In Table 2-53 • Analog Quad ACM Byte Assignment, the Function and Default
Setting for Bit 6 in Byte 3 was updated.
2-130
The "Introduction" section was updated to include information about digital inputs,
outputs, and bibufs.
2-133
In Table 2-69 • Fusion Pro I/O Features, the programmable delay descriptions were
updated for the following features:
Single-ended receiver
Voltage-referenced differential receiver
LVDS/LVPECL differential receiver features
2-137
The "User I/O Naming Convention" section was updated to include "V" and "z"
descriptions
2-159
The "VCC33PMP Analog Power Supply (3.3 V)" section was updated to include
information about avoiding high current draw.
2-224
The "VCCNVM Flash Memory Block Power Supply (1.5 V)" section was updated to
include information about avoiding high current draw.
2-224
The "VMVx I/O Supply Voltage (quiet)" section was updated to include this
statement: VMV and VCCI must be connected to the same power supply and VCCI
pins within a given I/O bank.
2-185
The "PUB Push Button" section was updated to include information about leaving
the pin floating if it is not used.
2-228
The "PTBASE Pass Transistor Base" section was updated to include information
about leaving the pin floating if it is not used.
2-228
The "PTEM Pass Transistor Emitter" section was updated to include information
about leaving the pin floating if it is not used.
2-228
The heading was incorrect in the "208-Pin PQFP" table. It should be AFS250 and not
AFS090.
3-8
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-15
Advance v0.5
(June 2006)
The low power modes of operation were updated and clarified. N/A
The AFS1500 digital I/O count was updated in Table 1 Fusion Family.i
The AFS1500 digital I/O count was updated in the "Package I/Os: Single-/Double-
Ended (Analog)" table.
ii
The "Voltage Regulator Power Supply Monitor (VRPSM)" was updated. 2-36
Figure 2-45 FlashROM Timing Diagram was updated. 2-53
The "256-Pin FBGA" table for the AFS1500 is new. 3-12
Advance v0.4
(April 2006)
The G was moved in the "Product Ordering Codes" section.III
Advance v0.3
(April 2006)
The "Features and Benefits" section was updated. I
The "Fusion Family" table was updated. I
The "Package I/Os: Single-/Double-Ended (Analog)" table was updated. II
The "Product Ordering Codes" table was updated. III
The "Temperature Grade Offerings" table was updated. IV
The "General Description" section was updated to include ARM information. 1-1
Figure 2-46 • FlashROM Timing Diagram was updated. 2-58
The "FlashROM" section was updated. 2-57
The "RESET" section was updated. 2-61
The "RESET" section was updated. 2-64
Figure 2-27 · Real-Time Counter System was updated. 2-35
Table 2-19 • Flash Memory Block Pin Names was updated. 2-43
Figure 2-33 • Flash Memory Block Diagram was updated to include AUX block
information.
2-45
Figure 2-34 • Flash Memory Block Organization was updated to include AUX block
information.
2-46
The note in the "Program Operation" section was updated. 2-48
Figure 2-76 • Gate Driver Example was updated. 2-95
The "Analog Quad ACM Description" section was updated. 2-130
Information about the maximum pad input frequency was added to the "Gate Driver"
section.
2-94
Figure 2-65 • Analog Block Macro was updated. 2-81
Figure 2-65 • Analog Block Macro was updated. 2-81
The "Analog Quad" section was updated. 2-84
The "Voltage Monitor" section was updated. 2-86
The "Direct Digital Input" section was updated. 2-89
The "Current Monitor" section was updated. 2-90
Information about the maximum pad input frequency was added to the "Gate Driver"
section.
2-94
Revision Changes Page
Datasheet Information
5-16 Revision 4
Advance v0.3
(continued)
The "Temperature Monitor" section was updated. 2-96
EQ 2 is new. 2-103
The "ADC Description" section was updated. 2-102
Figure 2-16 • Fusion Clocking Options was updated. 2-20
Table 2-46 · Analog Channel Specifications was updated. 2-118
The notes in Table 2-72 • Fusion Standard and Advanced I/O – Hot-Swap and 5 V
Input Tolerance Capabilities were updated.
2-144
The "Simultaneously Switching Outputs and PCB Layout" section is new. 2-149
LVPECL and LVDS were updated in Table 2-81 • Fusion Standard and Advanced I/O
Attributes vs. I/O Standard Applications.
2-157
LVPECL and LVDS were updated in Table 2-82 • Fusion Pro I/O Attributes vs. I/O
Standard Applications.
2-158
The "Timing Model" was updated. 2-161
All voltage-referenced Minimum and Maximum DC Input and Output Level tables
were updated.
N/A
All Timing Characteristic tables were updated N/A
Table 2-83 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions was updated.
2-165
Table 2-79 Summary of I/O Timing Characteristics – Software Default Settings
was updated.
2-134
Table 2-93 • I/O Output Buffer Maximum Resistances 1 was updated. 2-171
The "BLVDS/M-LVDS" section is new. BLVDS and M-LVDS are two new I/O
standards included in the datasheet.
2-211
The "CoreMP7 and Cortex-M1 Software Tools" section is new. 2-257
Table 2-83 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions was updated.
2-165
Table 2-79 Summary of I/O Timing Characteristics – Software Default Settings
was updated.
2-134
Table 2-93 • I/O Output Buffer Maximum Resistances 1 was updated. 2-171
The "BLVDS/M-LVDS" section is new. BLVDS and M-LVDS are two new I/O
standards included in the datasheet.
2-211
The "108-Pin QFN" table for the AFS090 device is new. 3-2
The "180-Pin QFN" table for the AFS090 device is new. 3-4
The "208-Pin PQFP" table for the AFS090 device is new. 3-8
The "256-Pin FBGA" table for the AFS090 device is new. 3-12
The "256-Pin FBGA" table for the AFS250 device is new. 3-12
Revision Changes Page
Fusion Family of Mixed Signal FPGAs
Revision 4 5-17
Datasheet Categories
Categories
In order to provide the latest information to designers, some datasheet parameters are published before
data has been fully characterized from silicon devices. The data provided for a given device, as
highlighted in the "Fusion Device Status" table, is designated as either "Product Brief," "Advance,"
"Preliminary," or "Production." The definitions of these categories are as follows:
Product Brief
The product brief is a summarized version of a datasheet (advance or production) and contains general
product information. This document gives an overview of specific device and family information.
Advance
This version contains initial estimated information based on simulation, other products, devices, or speed
grades. This information can be used as estimates, but not for production. This label only applies to the
DC and Switching Characteristics chapter of the datasheet and will only be used when the data has not
been fully characterized.
Preliminary
The datasheet contains information based on simulation and/or initial characterization. The information is
believed to be correct, but changes are possible.
Production
This version contains information that is considered to be final.
Export Administration Regulations (EAR)
The products described in this document are subject to the Export Administration Regulations (EAR).
They could require an approved export license prior to export from the United States. An export includes
release of product or disclosure of technology to a foreign national inside or outside the United States.
Safety Critical, Life Support, and High-Reliability Applications
Policy
The products described in this advance status document may not have completed the Microsemi
qualification process. Products may be amended or enhanced during the product introduction and
qualification process, resulting in changes in device functionality or performance. It is the responsibility of
each customer to ensure the fitness of any product (but especially a new product) for a particular
purpose, including appropriateness for safety-critical, life-support, and other high-reliability applications.
Consult the Microsemi SoC Products Group Terms and Conditions for specific liability exclusions relating
to life-support applications. A reliability report covering all of the SoC Products Group’s products is
available at http://www.microsemi.com/soc/documents/ORT_Report.pdf. Microsemi also offers a variety
of enhanced qualification and lot acceptance screening procedures. Contact your local sales office for
additional reliability information.
51700092-4/01.13
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Microsemi Corporation (NASDAQ: MSCC) offers a comprehensive portfolio of semiconductor
solutions for: aerospace, defense and security; enterprise and communications; and industrial
and alternative energy markets. Products include high-performance, high-reliability analog and
RF devices, mixed signal and RF integrated circuits, customizable SoCs, FPGAs, and
complete subsystems. Microsemi is headquartered in Aliso Viejo, Calif. Learn more at
www.microsemi.com.
Microsemi Corporate Headquarters
One Enterprise, Aliso Viejo CA 92656 USA
Within the USA: +1 (949) 380-6100
Sales: +1 (949) 380-6136
Fax: +1 (949) 215-4996