LatticeXP Family Data Sheet
DS1001 Version 05.1, November 2007
July 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 1-1 DS1001 Introduction_01.5
Features
Non-volatile, Infinitely Reconfigurable
Instant-on – powers up in microseconds
No external configuration memory
Excellent design security, no bit stream to
intercept
Reconfigure SRAM based logic in milliseconds
SRAM and non-volatile memory programmable
through system configuration and JTAG ports
Sleep Mode
Allows up to 1000x static current reduction
TransFR™ Reconfiguration (TFR)
In-field logic update while system operates
Extensive Density and Package Options
3.1K to 19.7K LUT4s
62 to 340 I/Os
Density migration supported
Embedded and Distributed Memory
54 Kbits to 396 Kbits sysMEM™ Embedded
Block RAM
Up to 79 Kbits distributed RAM
Flexible memory resources:
Distributed and block memory
Flexible I/O Buffer
Programmable sysIO™ buffer supports wide
range of interfaces:
LVCMOS 3.3/2.5/1.8/1.5/1.2
LVTTL
SSTL 18 Class I
SSTL 3/2 Class I, II
HSTL15 Class I, III
HSTL 18 Class I, II, III
PCI
LVDS, Bus-LVDS, LVPECL, RSDS
Dedicated DDR Memory Support
Implements interface up to DDR333 (166MHz)
sysCLOCK™ PLLs
Up to 4 analog PLLs per device
Clock multiply, divide and phase shifting
System Level Support
IEEE Standard 1149.1 Boundary Scan, plus
ispTRACY™ internal logic analyzer capability
Onboard oscillator for configuration
Devices operate with 3.3V, 2.5V, 1.8V or 1.2V
power supply
Table 1-1. LatticeXP Family Selection Guide
Device LFXP3 LFXP6 LFXP10 LFXP15 LFXP20
PFU/PFF Rows 16 24 32 40 44
PFU/PFF Columns 2430384856
PFU/PFF (Total) 384 720 1216 1932 2464
LUTs (K) 3 6 101520
Distributed RAM (KBits)1223396179
EBR SRAM (KBits) 54 72 216 324 396
EBR SRAM Blocks 6 8 24 36 44
VCC Voltage 1.2/1.8/2.5/3.3V 1.2/1.8/2.5/3.3V 1.2/1.8/2.5/3.3V 1.2/1.8/2.5/3.3V 1.2/1.8/2.5/3.3V
PLLs 22444
Max. I/O 136 188 244 300 340
Packages and I/O Combinations:
100-pin TQFP (14 x 14 mm) 62
144-pin TQFP (20 x 20 mm) 100 100
208-pin PQFP (28 x 28 mm) 136 142
256-ball fpBGA (17 x 17 mm) 188 188 188 188
388-ball fpBGA (23 x 23 mm) 244 268 268
484-ball fpBGA (23 x 23 mm) 300 340
LatticeXP Family Data Sheet
Introduction
Introduction
Lattice Semiconductor LatticeXP Family Data Sheet
1-2
Introduction
The LatticeXP family of FPGA devices combine logic gates, embedded memory and high performance I/Os in a
single architecture that is both non-volatile and infinitely reconfigurable to support cost-effective system designs.
The re-programmable non-volatile technology used in the LatticeXP family is the next generation ispXP™ technol-
ogy. With this technology, expensive external configuration memories are not required and designs are secured
from unauthorized read-back. In addition, instant-on capability allows for easy interfacing in many applications.
The ispLEVER® design tool from Lattice allows large complex designs to be efficiently implemented using the Lat-
ticeXP family of FPGA devices. Synthesis library support for LatticeXP is available for popular logic synthesis tools.
The ispLEVER tool uses the synthesis tool output along with the constraints from its floor planning tools to place
and route the design in the LatticeXP device. The ispLEVER tool extracts the timing from the routing and back-
annotates it into the design for timing verification.
Lattice provides many pre-designed IP (Intellectual Property) ispLeverCORE™ modules for the LatticeXP family.
By using these IPs as standardized blocks, designers are free to concentrate on the unique aspects of their design,
increasing their productivity.
July 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 2-1 DS1001 Architecture_02.0
Architecture Overview
The LatticeXP architecture contains an array of logic blocks surrounded by Programmable I/O Cells (PIC). Inter-
spersed between the rows of logic blocks are rows of sysMEM Embedded Block RAM (EBR) as shown in Figure 2-
1.
On the left and right sides of the PFU array, there are Non-volatile Memory Blocks. In configuration mode this non-
volatile memory is programmed via the IEEE 1149.1 TAP port or the sysCONFIG™ peripheral port. On power up,
the configuration data is transferred from the Non-volatile Memory Blocks to the configuration SRAM. With this
technology, expensive external configuration memories are not required and designs are secured from unauthor-
ized read-back. This transfer of data from non-volatile memory to configuration SRAM via wide busses happens in
microseconds, providing an “instant-on” capability that allows easy interfacing in many applications.
There are two kinds of logic blocks, the Programmable Functional Unit (PFU) and Programmable Functional unit
without RAM/ROM (PFF). The PFU contains the building blocks for logic, arithmetic, RAM, ROM and register func-
tions. The PFF block contains building blocks for logic, arithmetic and ROM functions. Both PFU and PFF blocks
are optimized for flexibility, allowing complex designs to be implemented quickly and efficiently. Logic Blocks are
arranged in a two-dimensional array. Only one type of block is used per row. The PFU blocks are used on the out-
side rows. The rest of the core consists of rows of PFF blocks interspersed with rows of PFU blocks. For every
three rows of PFF blocks there is a row of PFU blocks.
Each PIC block encompasses two PIOs (PIO pairs) with their respective sysIO interfaces. PIO pairs on the left and
right edges of the device can be configured as LVDS transmit/receive pairs. sysMEM EBRs are large dedicated fast
memory blocks. They can be configured as RAM or ROM.
The PFU, PFF, PIC and EBR Blocks are arranged in a two-dimensional grid with rows and columns as shown in
Figure 2-1. The blocks are connected with many vertical and horizontal routing channel resources. The place and
route software tool automatically allocates these routing resources.
At the end of the rows containing the sysMEM Blocks are the sysCLOCK Phase Locked Loop (PLL) Blocks. These
PLLs have multiply, divide and phase shifting capability; they are used to manage the phase relationship of the
clocks. The LatticeXP architecture provides up to four PLLs per device.
Every device in the family has a JTAG Port with internal Logic Analyzer (ispTRACY) capability. The sysCONFIG
port which allows for serial or parallel device configuration. The LatticeXP devices are available for operation from
3.3V, 2.5V, 1.8V and 1.2V power supplies, providing easy integration into the overall system.
LatticeXP Family Data Sheet
Architecture
2-2
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-1. LatticeXP Top Level Block Diagram
PFU and PFF Blocks
The core of the LatticeXP devices consists of PFU and PFF blocks. The PFUs can be programmed to perform
Logic, Arithmetic, Distributed RAM and Distributed ROM functions. PFF blocks can be programmed to perform
Logic, Arithmetic and ROM functions. Except where necessary, the remainder of the data sheet will use the term
PFU to refer to both PFU and PFF blocks.
Each PFU block consists of four interconnected slices, numbered 0-3 as shown in Figure 2-2. All the interconnec-
tions to and from PFU blocks are from routing. There are 53 inputs and 25 outputs associated with each PFU block.
Figure 2-2. PFU Diagram
Programmable I/O Cell
(PIC) includes sysIO
Interface
Non-volatile Memory
sysCONFIG Programming
Port (includes dedicated
and dual use pins)
Programmable
Functional Unit (PFU)
sysCLOCK PLL
PFF (PFU without
RAM)
JTAG Port
sysMEM Embedded
Block RAM (EBR)
Slice 0
LUT4 &
CARRY
LUT4 &
CARRY
FF/
Latch
D
FF/
Latch
D
Slice 1
LUT4 &
CARRY
LUT4 &
CARRY
Slice 2
LUT4 &
CARRY
LUT4 &
CARRY
From
Routing
To
Routing
Slice 3
LUT4 &
CARRY
LUT4 &
CARRY
FF/
Latch
D
FF/
Latch
D
FF/
Latch
D
FF/
Latch
D
FF/
Latch
D
FF/
Latch
D
2-3
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Slice
Each slice contains two LUT4 lookup tables feeding two registers (programmed to be in FF or Latch mode), and
some associated logic that allows the LUTs to be combined to perform functions such as LUT5, LUT6, LUT7 and
LUT8. There is control logic to perform set/reset functions (programmable as synchronous/asynchronous), clock
select, chip-select and wider RAM/ROM functions. Figure 2-3 shows an overview of the internal logic of the slice.
The registers in the slice can be configured for positive/negative and edge/level clocks.
There are 14 input signals: 13 signals from routing and one from the carry-chain (from adjacent slice or PFU).
There are 7 outputs: 6 to routing and one to carry-chain (to adjacent PFU). Table 2-1 lists the signals associated
with each slice.
Figure 2-3. Slice Diagram
LUT4 &
CARRY
LUT4 &
CARRY
Slice
A0
B0
C0
D0
FF/
Latch
OFX0
F0
Q0
A1
B1
C1
D1
CI
CI
CO
CO
F
SUM
CE
CLK
LSR
FF/
Latch
OFX1
F1
Q1
F
SUM
D
D
M1
To / From
Different slice / PFU Fast Carry Out (FCO)
To / From
Different slice / PFU Fast Carry In (FCI)
LUT
Expansion
Mux
M0
OFX0
From
Routing
To
Routing
Control Signals
selected and
inverted per
slice in routing
Note: Some interslice signals
are not shown.
2-4
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Table 2-1. Slice Signal Descriptions
Modes of Operation
Each Slice is capable of four modes of operation: Logic, Ripple, RAM and ROM. The Slice in the PFF is capable of
all modes except RAM. Table 2-2 lists the modes and the capability of the Slice blocks.
Table 2-2. Slice Modes
Logic Mode: In this mode, the LUTs in each Slice are configured as 4-input combinatorial lookup tables. A LUT4
can have 16 possible input combinations. Any logic function with four inputs can be generated by programming this
lookup table. Since there are two LUT4s per Slice, a LUT5 can be constructed within one Slice. Larger lookup
tables such as LUT6, LUT7 and LUT8 can be constructed by concatenating other Slices.
Ripple Mode: Ripple mode allows the efficient implementation of small arithmetic functions. In ripple mode, the fol-
lowing functions can be implemented by each Slice:
Addition 2-bit
Subtraction 2-bit
Add/Subtract 2-bit using dynamic control
Up counter 2-bit
Down counter 2-bit
Ripple mode multiplier building block
Comparator functions of A and B inputs
- A greater-than-or-equal-to B
- A not-equal-to B
- A less-than-or-equal-to B
Two additional signals: Carry Generate and Carry Propagate are generated per Slice in this mode, allowing fast
arithmetic functions to be constructed by concatenating Slices.
RAM Mode: In this mode, distributed RAM can be constructed using each LUT block as a 16x1-bit memory.
Through the combination of LUTs and Slices, a variety of different memories can be constructed.
Function Type Signal Names Description
Input Data signal A0, B0, C0, D0 Inputs to LUT4
Input Data signal A1, B1, C1, D1 Inputs to LUT4
Input Multi-purpose M0 Multipurpose Input
Input Multi-purpose M1 Multipurpose Input
Input Control signal CE Clock Enable
Input Control signal LSR Local Set/Reset
Input Control signal CLK System Clock
Input Inter-PFU signal FCIN Fast Carry In1
Output Data signals F0, F1 LUT4 output register bypass signals
Output Data signals Q0, Q1 Register Outputs
Output Data signals OFX0 Output of a LUT5 MUX
Output Data signals OFX1 Output of a LUT6, LUT7, LUT82 MUX depending on the slice
Output Inter-PFU signal FCO For the right most PFU the fast carry chain output1
1. See Figure 2-2 for connection details.
2. Requires two PFUs.
Logic Ripple RAM ROM
PFU Slice LUT 4x2 or LUT 5x1 2-bit Arithmetic Unit SP 16x2 ROM 16x1 x 2
PFF Slice LUT 4x2 or LUT 5x1 2-bit Arithmetic Unit N/A ROM 16x1 x 2
2-5
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
The Lattice design tools support the creation of a variety of different size memories. Where appropriate, the soft-
ware will construct these using distributed memory primitives that represent the capabilities of the PFU. Table 2-3
shows the number of Slices required to implement different distributed RAM primitives. Figure 2-4 shows the dis-
tributed memory primitive block diagrams. Dual port memories involve the pairing of two Slices, one Slice functions
as the read-write port. The other companion Slice supports the read-only port. For more information on RAM mode
in LatticeXP devices, please see details of additional technical documentation at the end of this data sheet.
Table 2-3. Number of Slices Required for Implementing Distributed RAM
Figure 2-4. Distributed Memory Primitives
ROM Mode: The ROM mode uses the same principal as the RAM modes, but without the Write port. Pre-loading is
accomplished through the programming interface during configuration.
PFU Modes of Operation
Slices can be combined within a PFU to form larger functions. Table 2-4 tabulates these modes and documents the
functionality possible at the PFU level.
SPR16x2 DPR16x2
Number of Slices 1 2
Note: SPR = Single Port RAM, DPR = Dual Port RAM
DO1
DO0
DI0
DI1
AD0
AD1
AD2
AD3
WRE
CK
DO0
AD0
AD1
AD2
AD3
DPR16x2SPR16x2
ROM16x1
RDO1
RDO0
DI0
DI1
WCK
WRE WDO1
WDO0
WAD0
WAD1
WAD2
WAD3
RAD0
RAD1
RAD2
RAD3
2-6
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Table 2-4. PFU Modes of Operation
Routing
There are many resources provided in the LatticeXP devices to route signals individually or as buses with related
control signals. The routing resources consist of switching circuitry, buffers and metal interconnect (routing) seg-
ments.
The inter-PFU connections are made with x1 (spans two PFU), x2 (spans three PFU) and x6 (spans seven PFU).
The x1 and x2 connections provide fast and efficient connections in horizontal, vertical and diagonal directions. The
x2 and x6 resources are buffered allowing both short and long connections routing between PFUs.
The ispLEVER design tool takes the output of the synthesis tool and places and routes the design. Generally, the
place and route tool is completely automatic, although an interactive routing editor is available to optimize the
design.
Clock Distribution Network
The clock inputs are selected from external I/O, the sysCLOCK™ PLLs or routing. These clock inputs are fed
through the chip via a clock distribution system.
Primary Clock Sources
LatticeXP devices derive clocks from three primary sources: PLL outputs, dedicated clock inputs and routing. Lat-
ticeXP devices have two to four sysCLOCK PLLs, located on the left and right sides of the device. There are four
dedicated clock inputs, one on each side of the device. Figure 2-5 shows the 20 primary clock sources.
Logic Ripple RAM1ROM
LUT 4x8 or
MUX 2x1 x 8 2-bit Add x 4 SPR16x2 x 4
DPR16x2 x 2 ROM16x1 x 8
LUT 5x4 or
MUX 4x1 x 4 2-bit Sub x 4 SPR16x4 x 2
DPR16x4 x 1 ROM16x2 x 4
LUT 6x 2 or
MUX 8x1 x 2 2-bit Counter x 4 SPR16x8 x 1 ROM16x4 x 2
LUT 7x1 or
MUX 16x1 x 1 2-bit Comp x 4 ROM16x8 x 1
1. These modes are not available in PFF blocks
2-7
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-5. Primary Clock Sources
Secondary Clock Sources
LatticeXP devices have four secondary clock resources per quadrant. The secondary clock branches are tapped at
every PFU. These secondary clock networks can also be used for controls and high fanout data. These secondary
clocks are derived from four clock input pads and 16 routing signals as shown in Figure 2-6.
From Routing Clock Input From Routing
PLL Input
Clock Input
PLL Input
PLL Input
Clock Input
PLL Input
From Routing Clock Input From Routing
PLL
PLL
PLL
PLL
20 Primary Clock Sources
To Quadrant Clock Selection
Note: Smaller devices have two PLLs.
2-8
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-6. Secondary Clock Sources
Clock Routing
The clock routing structure in LatticeXP devices consists of four Primary Clock lines and a Secondary Clock net-
work per quadrant. The primary clocks are generated from MUXs located in each quadrant. Figure 2-7 shows this
clock routing. The four secondary clocks are generated from MUXs located in each quadrant as shown in Figure 2-
8. Each slice derives its clock from the primary clock lines, secondary clock lines and routing as shown in Figure 2-
9.
Figure 2-7. Per Quadrant Primary Clock Selection
20 Secondary Clock Sources
To Quadrant Clock Selection
From Routing
From Routing
Clock Input Clock Input
From Routing
From Routing
From Routing
From Routing
From Routing
From Routing
From
Routing
From
Routing
From
Routing
Clock
Input
Clock
Input
From
Routing
From
Routing
From
Routing
From
Routing
From
Routing
4 Primary Clocks (CLK0, CLK1, CLK2, CLK3) per Quadrant
20 Primary Clock Sources: 12 PLLs + 4 PIOs + 4 Routing1
DCS
2
DCS
2
1. Smaller devices have fewer PLL related lines.
2. Dynamic clock select.
2-9
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-8. Per Quadrant Secondary Clock Selection
Figure 2-9. Slice Clock Selection
sysCLOCK Phase Locked Loops (PLLs)
The PLL clock input, from pin or routing, feeds into an input clock divider. There are three sources of feedback sig-
nals to the feedback divider: from CLKOP (PLL internal), from clock net (CLKOP or CLKOS) or from a user clock
(PIN or logic). There is a PLL_LOCK signal to indicate that VCO has locked on to the input clock signal. Figure 2-
10 shows the sysCLOCK PLL diagram.
The setup and hold times of the device can be improved by programming a delay in the feedback or input path of
the PLL which will advance or delay the output clock with reference to the input clock. This delay can be either pro-
grammed during configuration or can be adjusted dynamically. In dynamic mode, the PLL may lose lock after
adjustment and not relock until the tLOCK parameter has been satisfied. Additionally, the phase and duty cycle block
allows the user to adjust the phase and duty cycle of the CLKOS output.
The sysCLOCK PLLs provide the ability to synthesize clock frequencies. Each PLL has four dividers associated
with it: input clock divider, feedback divider, post scalar divider and secondary clock divider. The input clock divider
is used to divide the input clock signal, while the feedback divider is used to multiply the input clock signal. The post
scalar divider allows the VCO to operate at higher frequencies than the clock output, thereby increasing the fre-
quency range. The secondary divider is used to derive lower frequency outputs.
4 Secondary Clocks per Quadrant
20 Secondary Clock Feedlines : 4 Clock Input Pads + 16 Routing Signals
2-10
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-10. PLL Diagram
Figure 2-11 shows the available macros for the PLL. Table 2-11 provides signal description of the PLL Block.
Figure 2-11. PLL Primitive
Table 2-5. PLL Signal Descriptions
Signal I/O Description
CLKI I Clock input from external pin or routing
CLKFB I PLL feedback input from CLKOP (PLL internal), from clock net (CLKOP) or from a user clock
(PIN or logic)
RST I “1” to reset input clock divider
CLKOS O PLL output clock to clock tree (phase shifted/duty cycle changed)
CLKOP O PLL output clock to clock tree (No phase shift)
CLKOK O PLL output to clock tree through secondary clock divider
LOCK O “1” indicates PLL LOCK to CLKI
DDAMODE I Dynamic Delay Enable. “1” Pin control (dynamic), “0”: Fuse Control (static)
DDAIZR I Dynamic Delay Zero. “1”: delay = 0, “0”: delay = on
DDAILAG I Dynamic Delay Lag/Lead. “1”: Lag, “0”: Lead
DDAIDEL[2:0] I Dynamic Delay Input
DDAOZR O Dynamic Delay Zero Output
DDAOLAG O Dynamic Delay Lag/Lead Output
DDAODEL[2:0] O Dynamic Delay Output
VCO CLKOS
CLKOK
LOCK
RST
CLKFB
from CLKOP
(PLL internal),
from clock net
(CLKOP) or
from a user
clock (PIN or logic)
Dynamic Delay Adjustment
Input Clock
Divider
(CLKI)
Feedback
Divider
(CLKFB)
Post Scalar
Divider
(CLKOP)
Phase/Duty
Select
Secondary
Clock
Divider
(CLKOK)
Delay
Adjust
Voltage
Controlled
Oscillator
CLKI
(from routing or
external pin)
CLKOP
EPLLB CLKOP
CLKI
CLKFB LOCK
EHXPLLB
CLKOS
CLKI
CLKFB CLKOK
LOCK
RST CLKOP
DDAIZR
DDAILAG
DDA MODE
DDAIDEL[2:0]
DDAOZR
DDAOLAG
DDAODEL[2:0]
2-11
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
For more information on the PLL, please see details of additional technical documentation at the end of this data
sheet.
Dynamic Clock Select (DCS)
The DCS is a global clock buffer with smart multiplexer functions. It takes two independent input clock sources and
outputs a clock signal without any glitches or runt pulses. This is achieved irrespective of where the select signal is
toggled. There are eight DCS blocks per device, located in pairs at the center of each side. Figure 2-12 illustrates
the DCS Block Macro.
Figure 2-12. DCS Block Primitive
Figure 2-13 shows timing waveforms of the default DCS operating mode. The DCS block can be programmed to
other modes. For more information on the DCS, please see details of additional technical documentation at the end
of this data sheet.
Figure 2-13. DCS Waveforms
sysMEM Memory
The LatticeXP family of devices contain a number of sysMEM Embedded Block RAM (EBR). The EBR consists of
a 9-Kbit RAM, with dedicated input and output registers.
sysMEM Memory Block
The sysMEM block can implement single port, dual port or pseudo dual port memories. Each block can be used in
a variety of depths and widths as shown in Table 2-6.
DCS
CLK0
DCSOUT
CLK1
SEL
CLK0
SEL
DCSOUT
CLK1
2-12
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Table 2-6. sysMEM Block Configurations
Bus Size Matching
All of the multi-port memory modes support different widths on each of the ports. The RAM bits are mapped LSB
word 0 to MSB word 0, LSB word 1 to MSB word 1 and so on. Although the word size and number of words for
each port varies, this mapping scheme applies to each port.
RAM Initialization and ROM Operation
If desired, the contents of the RAM can be pre-loaded during device configuration. By preloading the RAM block
during the chip configuration cycle and disabling the write controls, the sysMEM block can also be utilized as a
ROM.
Memory Cascading
Larger and deeper blocks of RAMs can be created using EBR sysMEM Blocks. Typically, the Lattice design tools
cascade memory transparently, based on specific design inputs.
Single, Dual and Pseudo-Dual Port Modes
Figure 2-14 shows the four basic memory configurations and their input/output names. In all the sysMEM RAM
modes the input data and address for the ports are registered at the input of the memory array. The output data of
the memory is optionally registered at the output.
Memory Mode Configurations
Single Port
8,192 x 1
4,096 x 2
2,048 x 4
1,024 x 9
512 x 18
256 x 36
True Dual Port
8,192 x 1
4,096 x 2
2,048 x 4
1,024 x 9
512 x 18
Pseudo Dual Port
8,192 x 1
4,096 x 2
2,048 x 4
1,024 x 9
512 x 18
256 x 36
2-13
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-14. sysMEM Memory Primitives
The EBR memory supports three forms of write behavior for single port or dual port operation:
1. Normal – data on the output appears only during read cycle. During a write cycle, the data (at the current
address) does not appear on the output. This mode is supported for all data widths.
2. Write Through -þa copy of the input data appears at the output of the same port during a write cycle.þThis
mode is supported for all data widths.
3. Read-Before-Write – when new data is being written, the old content of the address appears at the output.
This mode is supported for x9, x18 and x36 data widths.
Memory Core Reset
The memory array in the EBR utilizes latches at the A and B output ports. These latches can be reset asynchro-
nously. RSTA and RSTB are local signals, which reset the output latches associated with Port A and Port B respec-
tively. The Global Reset (GSRN) signal resets both ports. The output data latches and associated resets for both
ports are as shown in Figure 2-15.
EBR
AD[12:0]
DI[35:0]
CLK
CE
RST
WE
CS[2:0]
DO[35:0]
Single Port RAM
EBR
True Dual Port RAM
Pseudo-Dual Port RAM
ROM
AD[12:0]
CLK
CE DO[35:0]
RST
CS[2:0]
EBR
EBR
ADA[12:0]
DIA[17:0]
CLKA
CEA
RSTA
WEA
CSA[2:0]
DOA[17:0]
ADB[12:0]
DIB[17:0]
CLKB
CEB
RSTB
WEB
CSB[2:0]
DOB[17:0]
ADW[12:0]
DI[35:0]
CLKW
CEW
ADR[12:0]
DO[35:0]
CER
CLKR
WE
RST
CS[2:0]
2-14
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-15. Memory Core Reset
For further information on sysMEM EBR block, see the details of additional technical documentation at the end of
this data sheet.
EBR Asynchronous Reset
EBR asynchronous reset or GSR (if used) can only be applied if all clock enables are low for a clock cycle before the
reset is applied and released a clock cycle after the reset is released, as shown in Figure 2-16. The GSR input to the
EBR is always asynchronous.
Figure 2-16. EBR Asynchronous Reset (Including GSR) Timing Diagram
If all clock enables remain enabled, the EBR asynchronous reset or GSR may only be applied and released after
the EBR read and write clock inputs are in a steady state condition for a minimum of 1/fMAX (EBR clock). The reset
release must adhere to the EBR synchronous reset setup time before the next active read or write clock edge.
If an EBR is pre-loaded during configuration, the GSR input must be disabled or the release of the GSR during
device Wake Up must occur before the release of the device I/Os becoming active.
These instructions apply to all EBR RAM and ROM implementations.
Note that there are no reset restrictions if the EBR synchronous reset is used and the EBR GSR input is disabled.
Programmable I/O Cells (PICs)
Each PIC contains two PIOs connected to their respective sysIO Buffers which are then connected to the PADs as
shown in Figure 2-17. The PIO Block supplies the output data (DO) and the Tri-state control signal (TO) to sysIO
buffer, and receives input from the buffer.
Q
SET
D
L
CLR
Output Data
Latches
Memory Core
Port A[17:0]
Q
SET
D
Port B[17:0]
RSTB
GSRN
Programmable Disable
RSTA
L
CLR
Reset
Clock
Clock
Enable
2-15
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-17. PIC Diagram
In the LatticeXP family, seven PIOs or four (3.5) PICs are grouped together to provide two LVDS differential pairs,
one PIC pair and one single I/O, as shown in Figure 2-18.
Two adjacent PIOs can be joined to provide a differential I/O pair (labeled as “T” and “C”). The PAD Labels “T” and
“C” distinguish the two PIOs. Only the PIO pairs on the left and right edges of the device can be configured as
LVDS transmit/receive pairs.
One of every 14 PIOs (a group of 8 PICs) contains a delay element to facilitate the generation of DQS signals as
shown in Figure 2-19. The DQS signal feeds the DQS bus which spans the set of 13 PIOs (8 PICs). The DQS sig-
nal from the bus is used to strobe the DDR data from the memory into input register blocks. This interface is
designed for memories that support one DQS strobe per eight bits of data.
The exact DQS pins are shown in a dual function in the Logic Signal Connections table in this data sheet. Addi-
tional detail is provided in the Signal Descriptions table in this data sheet.
PIO B
PADA
"T"
PADB “C”
OPOS0
ONEG0
OPOS1
ONEG1
TD
INCK
INDD
INFF
IPOS0
IPOS1
CLK
CE
LSR
GSRN
CLKO
CLKI
CEO
CEI
PIO A
sysIO
Buffer
Control
Muxes
LSR
GSR
DQS
DDRCLKPOL
IOLD0
IOLT0
D0
DDRCLK
DI
IPOS1
IPOS0
INCK
INDD
INFF
D0
D1
TD
D1
DO
Tristate
Register Block
(2 Flip Flops)
Output
Register Block
(2 Flip Flops)
DDRCLK
Input
Register Block
(5 Flip Flops)
2-16
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-18. Group of Seven PIOs
Figure 2-19. DQS Routing
PIO
The PIO contains four blocks: an input register block, output register block, tristate register block and a control logic
block. These blocks contain registers for both single data rate (SDR) and double data rate (DDR) operation along
with the necessary clock and selection logic. Programmable delay lines used to shift incoming clock and data sig-
nals are also included in these blocks.
Input Register Block
The input register block contains delay elements and registers that can be used to condition signals before they are
passed to the device core. Figure 2-20 shows the diagram of the input register block.
Input signals are fed from the sysIO buffer to the input register block (as signal DI). If desired the input signal can
bypass the register and delay elements and be used directly as a combinatorial signal (INDD), a clock (INCK) and
PIO A
PIO B
PIO A
PIO B
PIO A
PIO A
PIO B
PADA “T”
PADB “C”
LVDS Pair
PADA “T”
PADB “C”
PADA “T”
PADB “C”
LVDS Pair
PADA “T”
Four PICs
One PIO Pair
PIO A
PIO B
PADA “T”
PADB “C”
PIO B
PIO A
Assigned DQS Pin
DQS
sysIO
Buffer
LVDS Pair
LVDS Pair
PIO A
PIO B
PADA “T”
PADB “C”
PIO A
PIO B
PADA “T”
PADB “C”
LVDS Pair
PIO A PADA “T”
PIO B
PADA “T”
PADB “C”
PADB “C”
PIO A
PIO B
PADA “T”
PADB “C”
PIO A
PIO B
PADA “T”
PADB “C”
LVDS Pair
Delay
2-17
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
in selected blocks the input to the DQS delay block. If one of the bypass options is not chosen, the signal first
passes through an optional delay block. This delay, if selected, ensures no positive input-register hold-time require-
ment when using a global clock.
The input block allows two modes of operation. In the single data rate (SDR) the data is registered, by one of the
registers in the single data rate sync register block, with the system clock. In the DDR Mode two registers are used
to sample the data on the positive and negative edges of the DQS signal creating two data streams, D0 and D2.
These two data streams are synchronized with the system clock before entering the core. Further discussion on
this topic is in the DDR Memory section of this data sheet.
Figure 2-21 shows the input register waveforms for DDR operation and Figure 2-22 shows the design tool primi-
tives. The SDR/SYNC registers have reset and clock enable available.
The signal DDRCLKPOL controls the polarity of the clock used in the synchronization registers. It ensures ade-
quate timing when data is transferred from the DQS to the system clock domain. For further discussion of this topic,
see the DDR memory section of this data sheet.
Figure 2-20. Input Register Diagram
DQ
DQ
DQ
D-Type
Fixed Delay
To Routing
DI
(From sysIO
Buffer)
DQS Delayed
(From DQS
Bus)
CLK0
(From Routing)
DDRCLKPOL
(From DDR Polarity
Control Bus)
INCK
INDD
Delay Block
DDR Registers
D-Type D-Type
DQ
DQ
D-Type
/LATCH
/LATCH
D-Type
IPOS0
IPOS1
SDR & Sync
Registers
D0
D2
D1
2-18
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-21. Input Register DDR Waveforms
Figure 2-22. INDDRXB Primitive
Output Register Block
The output register block provides the ability to register signals from the core of the device before they are passed
to the sysIO buffers. The block contains a register for SDR operation that is combined with an additional latch for
DDR operation. Figure 2-23 shows the diagram of the Output Register Block.
In SDR mode, ONEG0 feeds one of the flip-flops that then feeds the output. The flip-flop can be configured as a D-
type or as a latch. In DDR mode, ONEG0 is fed into one register on the positive edge of the clock and OPOS0 is
latched. A multiplexer running off the same clock selects the correct register for feeding to the output (D0).
Figure 2-24 shows the design tool DDR primitives. The SDR output register has reset and clock enable available.
The additional register for DDR operation does not have reset or clock enable available.
ABCDE F
BD
DI
(In DDR Mode)
D0
D2
DQS
AC
DQS
Delayed
IDDRXB
LSR QA
D
ECLK
QB
DDRCLKPOL
SCLK
CE
2-19
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-23. Output Register Block
Figure 2-24. ODDRXB Primitive
Tristate Register Block
The tristate register block provides the ability to register tri-state control signals from the core of the device before
they are passed to the sysIO buffers. The block contains a register for SDR operation and an additional latch for
DDR operation. Figure 2-25 shows the diagram of the Tristate Register Block.
In SDR mode, ONEG1 feeds one of the flip-flops that then feeds the output. The flip-flop can be configured a D-
type or latch. In DDR mode, ONEG1 is fed into one register on the positive edge of the clock and OPOS1 is
latched. A multiplexer running off the same clock selects the correct register for feeding to the output (D0).
DQ
DQ
D-Type
ONEG0
From
Routing
CLK1
*Latch is transparent when input is low.
Programmed
Control
DO
OPOS0
OUTDDN
/LATCH
LATCH
LE*
0
1
0
1
To sysIO
Buffer
ODDRXB
LSR
Q
DB
CLK
DA
2-20
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-25. Tristate Register Block
Control Logic Block
The control logic block allows the selection and modification of control signals for use in the PIO block. A clock is
selected from one of the clock signals provided from the general purpose routing and a DQS signal provided from
the programmable DQS pin. The clock can optionally be inverted.
The clock enable and local reset signals are selected from the routing and optionally inverted. The global tristate
signal is passed through this block.
DDR Memory Support
Implementing high performance DDR memory interfaces requires dedicated DDR register structures in the input
(for read operations) and in the output (for write operations). As indicated in the PIO Logic section, the LatticeXP
devices provide this capability. In addition to these registers, the LatticeXP devices contain two elements to simplify
the design of input structures for read operations: the DQS delay block and polarity control logic.
DLL Calibrated DQS Delay Block
Source Synchronous interfaces generally require the input clock to be adjusted in order to correctly capture data at
the input register. For most interfaces a PLL is used for this adjustment, however in DDR memories the clock
(referred to as DQS) is not free running so this approach cannot be used. The DQS Delay block provides the
required clock alignment for DDR memory interfaces.
The DQS signal (selected PIOs only) feeds from the PAD through a DQS delay element to a dedicated DQS routing
resource. The DQS signal also feeds the polarity control logic which controls the polarity of the clock to the sync
registers in the input register blocks. Figures 2-26 and 2-27 show how the polarity control logic are routed to the
PIOs.
The temperature, voltage and process variations of the DQS delay block are compensated by a set of calibration
(6-bit bus) signals from two DLLs on opposite sides of the device. Each DLL compensates DQS Delays in its half of
the device as shown in Figure 2-27. The DLL loop is compensated for temperature, voltage and process variations
by the system clock and feedback loop.
D
LE*
Q
DQ
D-Type
ONEG1
CLK1
Programmed
Control
TO
OPOS1
OUTDDN
/LATCH
LATCH
0
1
0
1
From
Routing To sysIO
Buffer
TD
*Latch is transparent when input is low.
2-21
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-26. DQS Local Bus
Figure 2-27. DLL Calibration Bus and DQS/DQS Transition Distribution
DI
CLKI
CEI
PIO
GSR
DQS
Input
Register Block
( 5 Flip Flops)
To Sync.
Reg.
DQS To DDR
Reg.
DQS
Strobe
PAD
DDR
Datain
PAD
sysIO
Buffer
DI
sysIO
Buffer
PIO
DQSDEL
Polarity Control
Logic
DQS
Calibration Bus
from DLL
Delay
Control
Bus
Polarity
Control
Bus
DQS
Bus
DLL
DLL
Polarity Control Signal Bus
DQS Signal Bus
Delay Control Bus
2-22
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Polarity Control Logic
In a typical DDR Memory interface design, the phase relation between the incoming delayed DQS strobe and the
internal system Clock (during the READ cycle) is unknown.
The LatticeXP family contains dedicated circuits to transfer data between these domains. To prevent setup and
hold violations at the domain transfer between DQS (delayed) and the system Clock a clock polarity selector is
used. This changes the edge on which the data is registered in the synchronizing registers in the input register
block. This requires evaluation at the start of the each READ cycle for the correct clock polarity.
Prior to the READ operation in DDR memories DQS is in tristate (pulled by termination). The DDR memory device
drives DQS low at the start of the preamble state. A dedicated circuit detects this transition. This signal is used to
control the polarity of the clock to the synchronizing registers.
sysIO Buffer
Each I/O is associated with a flexible buffer referred to as a sysIO buffer. These buffers are arranged around the
periphery of the device in eight groups referred to as Banks. The sysIO buffers allow users to implement the wide
variety of standards that are found in today’s systems including LVCMOS, SSTL, HSTL, LVDS and LVPECL.
sysIO Buffer Banks
LatticeXP devices have eight sysIO buffer banks; each is capable of supporting multiple I/O standards. Each sysIO
bank has its own I/O supply voltage (VCCIO), and two voltage references VREF1 and VREF2 resources allowing each
bank to be completely independent from each other. Figure 2-28 shows the eight banks and their associated sup-
plies.
In the LatticeXP devices, single-ended output buffers and ratioed input buffers (LVTTL, LVCMOS, PCI and PCI-X) are
powered using VCCIO. LVTTL, LVCMOS33, LVCMOS25 and LVCMOS12 can also be set as a fixed threshold input
independent of VCCIO. In addition to the bank VCCIO supplies, the LatticeXP devices have a VCC core logic power sup-
ply, and a VCCAUX supply that power all differential and referenced buffers.
Each bank can support up to two separate VREF voltages, VREF1 and VREF2 that set the threshold for the refer-
enced input buffers. In the LatticeXP devices, a dedicated pin in a bank can be configured to be a reference voltage
supply pin. Each I/O is individually configurable based on the bank’s supply and reference voltages.
2-23
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-28. LatticeXP Banks
LatticeXP devices contain two types of sysIO buffer pairs.
1. Top and Bottom sysIO Buffer Pair (Single-Ended Outputs Only)
The sysIO buffer pairs in the top and bottom banks of the device consist of two single-ended output drivers and
two sets of single-ended input buffers (both ratioed and referenced). The referenced input buffer can also be
configured as a differential input.
The two pads in the pair are described as “true” and “comp”, where the true pad is associated with the positive
side of the differential input buffer and the comp (complementary) pad is associated with the negative side of
the differential input buffer.
Only the I/Os on the top and bottom banks have PCI clamps. Note that the PCI clamp is enabled after VCC,
VCCAUX and VCCIO are at valid operating levels and the device has been configured.
2. Left and Right sysIO Buffer Pair (Differential and Single-Ended Outputs)
The sysIO buffer pairs in the left and right banks of the device consist of two single-ended output drivers, two
sets of single-ended input buffers (both ratioed and referenced) and one differential output driver. The refer-
enced input buffer can also be configured as a differential input. In these banks the two pads in the pair are
described as “true” and “comp”, where the true pad is associated with the positive side of the differential I/O,
and the comp (complementary) pad is associated with the negative side of the differential I/O.
Select I/Os in the left and right banks have LVDS differential output drivers. Refer to the Logic Signal Connec-
tions tables for more information.
VREF1(2)
GND
Bank 2
VCCIO2
V
REF2(2)
VREF1(3)
GND
Bank 3
VCCIO3
VREF2(3)
VREF1(7)
GND
Bank 7
VCCIO7
VREF2(7)
VREF1(6)
GND
Note: N and M are the maximum number of I/Os per bank.
Bank 6
VCCIO6
VREF2(6)
V
REF1(5)
GND
Bank 5
V
CCIO5
V
REF2(5)
V
REF1(4)
GND
Bank 4
V
CCIO4
V
REF2(4)
V
REF1(0)
GND
Bank 0
V
CCIO0
V
REF2(0)
V
REF1(1)
GND
Bank 1
V
CCIO1
V
REF2(1)
1
M
1
M
1
M
1
M
1N
1N
1N
1N
2-24
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Typical I/O Behavior During Power-up
The internal power-on-reset (POR) signal is deactivated when VCC and VCCAUX have reached satisfactory levels.
After the POR signal is deactivated, the FPGA core logic becomes active. It is the user’s responsibility to ensure
that all other VCCIO banks are active with valid input logic levels to properly control the output logic states of all the
I/O banks that are critical to the application. The default configuration of the I/O pins in a blank device is tri-state
with a weak pull-up to VCCIO. The I/O pins will not take on the user configuration until VCC, VCCAUX and VCCIO
have reached satisfactory levels at which time the I/Os will take on the user-configured settings.
The VCC and VCCAUX supply the power to the FPGA core fabric, whereas the VCCIO supplies power to the I/O buf-
fers. In order to simplify system design while providing consistent and predictable I/O behavior, it is recommended
that the I/O buffers be powered-up prior to the FPGA core fabric. VCCIO supplies should be powered up before or
together with the VCC and VCCAUX supplies.
Supported Standards
The LatticeXP sysIO buffer supports both single-ended and differential standards. Single-ended standards can be
further subdivided into LVCMOS, LVTTL and other standards. The buffers support the LVTTL, LVCMOS 1.2, 1.5,
1.8, 2.5 and 3.3V standards. In the LVCMOS and LVTTL modes, the buffer has individually configurable options for
drive strength, bus maintenance (weak pull-up, weak pull-down, or a bus-keeper latch) and open drain. Other sin-
gle-ended standards supported include SSTL and HSTL. Differential standards supported include LVDS, BLVDS,
LVPECL, differential SSTL and differential HSTL. Tables 2-7 and 2-8 show the I/O standards (together with their
supply and reference voltages) supported by the LatticeXP devices. For further information on utilizing the sysIO
buffer to support a variety of standards please see the details of additional technical documentation at the end of
this data sheet.
Table 2-7. Supported Input Standards
Input Standard VREF (Nom.) VCCIO1 (Nom.)
Single Ended Interfaces
LVTTL
LVCMOS332——
LVCMOS252——
LVCMOS18 1.8
LVCMOS15 1.5
LVCMOS122——
PCI 3.3
HSTL18 Class I, II 0.9
HSTL18 Class III 1.08
HSTL15 Class I 0.75
HSTL15 Class III 0.9
SSTL3 Class I, II 1.5
SSTL2 Class I, II 1.25
SSTL18 Class I 0.9
Differential Interfaces
Differential SSTL18 Class I
Differential SSTL2 Class I, II
Differential SSTL3 Class I, II
Differential HSTL15 Class I, III
Differential HSTL18 Class I, II, III
LVDS, LVPECL
BLVDS
1. When not specified VCCIO can be set anywhere in the valid operating range.
2. JTAG inputs do not have a fixed threshold option and always follow VCCJ.
2-25
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Table 2-8. Supported Output Standards
Hot Socketing
The LatticeXP devices have been carefully designed to ensure predictable behavior during power-up and power-
down. Power supplies can be sequenced in any order. During power up and power-down sequences, the I/Os
remain in tristate until the power supply voltage is high enough to ensure reliable operation. In addition, leakage
into I/O pins is controlled to within specified limits, which allows easy integration with the rest of the system.
These capabilities make the LatticeXP ideal for many multiple power supply and hot-swap applications.
Sleep Mode
The LatticeXP “C” devices (VCC = 1.8/2.5/3.3V) have a sleep mode that allows standby current to be reduced by up
to three orders of magnitude during periods of system inactivity. Entry and exit to Sleep Mode is controlled by the
SLEEPN pin.
During Sleep Mode, the FPGA logic is non-operational, registers and EBR contents are not maintained and I/Os
are tri-stated. Do not enter Sleep Mode during device programming or configuration operation. In Sleep Mode,
power supplies can be maintained in their normal operating range, eliminating the need for external switching of
power supplies. Table 2-9 compares the characteristics of Normal, Off and Sleep Modes.
Output Standard Drive VCCIO (Nom.)
Single-ended Interfaces
LVTTL 4mA, 8mA, 12mA, 16mA, 20mA 3.3
LVCMOS33 4mA, 8mA, 12mA 16mA, 20mA 3.3
LVCMOS25 4mA, 8mA, 12mA 16mA, 20mA 2.5
LVCMOS18 4mA, 8mA, 12mA 16mA 1.8
LVCMOS15 4mA, 8mA 1.5
LVCMOS12 2mA, 6mA 1.2
LVCMOS33, Open Drain 4mA, 8mA, 12mA 16mA, 20mA
LVCMOS25, Open Drain 4mA, 8mA, 12mA 16mA, 20mA
LVCMOS18, Open Drain 4mA, 8mA, 12mA 16mA
LVCMOS15, Open Drain 4mA, 8mA
LVCMOS12, Open Drain 2mA. 6mA
PCI33 N/A 3.3
HSTL18 Class I, II, III N/A 1.8
HSTL15 Class I, III N/A 1.5
SSTL3 Class I, II N/A 3.3
SSTL2 Class I, II N/A 2.5
SSTL18 Class I N/A 1.8
Differential Interfaces
Differential SSTL3, Class I, II N/A 3.3
Differential SSTL2, Class I, II N/A 2.5
Differential SSTL18, Class I N/A 1.8
Differential HSTL18, Class I, II, III N/A 1.8
Differential HSTL15, Class I, III N/A 1.5
LVDS N/A 2.5
BLVDS1N/A 2.5
LVPECL1N/A 3.3
1. Emulated with external resistors.
2-26
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Table 2-9. Characteristics of Normal, Off and Sleep Modes
SLEEPN Pin Characteristics
The SLEEPN pin behaves as an LVCMOS input with the voltage standard appropriate to the VCC supply for the
device. This pin also has a weak pull-up typically in the order of 10µA along with a Schmidt trigger and glitch filter
to prevent false triggering. An external pull-up to VCC is recommended when Sleep Mode is not used to ensure the
device stays in normal operation mode. Typically the device enters Sleep Mode several hundred ns after SLEEPN
is held at a valid low and restarts normal operation as specified in the Sleep Mode Timing table. The AC and DC
specifications portion of this data sheet show a detailed timing diagram.
Configuration and Testing
The following section describes the configuration and testing features of the LatticeXP family of devices.
IEEE 1149.1-Compliant Boundary Scan Testability
All LatticeXP devices have boundary scan cells that are accessed through an IEEE 1149.1 compliant test access
port (TAP). This allows functional testing of the circuit board, on which the device is mounted, through a serial scan
path that can access all critical logic nodes. Internal registers are linked internally, allowing test data to be shifted in
and loaded directly onto test nodes, or test data to be captured and shifted out for verification. The test access port
consists of dedicated I/Os: TDI, TDO, TCK and TMS. The test access port has its own supply voltage VCCJ and can
operate with LVCMOS3.3, 2.5, 1.8, 1.5 and 1.2 standards.
For more details on boundary scan test, please see information regarding additional technical documentation at
the end of this data sheet.
Device Configuration
All LatticeXP devices contain two possible ports that can be used for device configuration and programming. The
test access port (TAP), which supports serial configuration, and the sysCONFIG port that supports both byte-wide
and serial configuration.
The non-volatile memory in the LatticeXP can be configured in three different modes:
In sysCONFIG mode via the sysCONFIG port. Note this can also be done in background mode.
In 1532 mode via the 1149.1 port.
In background mode via the 1149.1 port. This allows the device to be operated while reprogramming takes
place.
The SRAM configuration memory can be configured in three different ways:
At power-up via the on-chip non-volatile memory.
In 1532 mode via the 1149.1 port SRAM direct configuration.
In sysCONFIG mode via the sysCONFIG port SRAM direct configuration.
Characteristic Normal Off Sleep
SLEEPN Pin High Low
Static Icc Typical <100mA 0 Typical <100uA
I/O Leakage <10µA <1mA <10µA
Power Supplies VCC/VCCIO/VCCAUX Normal Range Off Normal Range
Logic Operation User Defined Non Operational Non operational
I/O Operation User Defined Tri-state Tri-state
JTAG and Programming circuitry Operational Non-operational Non-operational
EBR Contents and Registers Maintained Non-maintained Non-maintained
2-27
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 2-29 provides a pictorial representation of the different programming ports and modes available in the Lattic-
eXP devices.
On power-up, the FPGA SRAM is ready to be configured with the sysCONFIG port active. The IEEE 1149.1 serial
mode can be activated any time after power-up by sending the appropriate command through the TAP port.
Leave Alone I/O
When using 1532 mode for non-volatile memory programming, users may specify I/Os as high, low, tristated or
held at current value. This provides excellent flexibility for implementing systems where reprogramming occurs on-
the-fly.
TransFR (Transparent Field Reconfiguration)
TransFR (TFR) is a unique Lattice technology that allows users to update their logic in the field without interrupting
system operation using a single ispVM command. See Lattice technical note #TN1087, Minimizing System Inter-
ruption During Configuration Using TransFR Technology, for details.
Security
The LatticeXP devices contain security bits that, when set, prevent the readback of the SRAM configuration and
non-volatile memory spaces. Once set, the only way to clear security bits is to erase the memory space.
For more information on device configuration, please see details of additional technical documentation at the end
of this data sheet.
Figure 2-29. ispXP Block Diagram
Internal Logic Analyzer Capability (ispTRACY)
All LatticeXP devices support an internal logic analyzer diagnostic feature. The diagnostic features provide capabil-
ities similar to an external logic analyzer, such as programmable event and trigger condition and deep trace mem-
ory. This feature is enabled by Lattice’s ispTRACY. The ispTRACY utility is added into the user design at compile
time.
For more information on ispTRACY, please see information regarding additional technical documentation at the
end of this data sheet.
Oscillator
Every LatticeXP device has an internal CMOS oscillator which is used to derive a master serial clock for configura-
tion. The oscillator and the master serial clock run continuously in the configuration mode. The default value of the
ISP 1149.1 TAP Port sysCONFIG Peripherial Port
BACKGND 1532 sysCONFIG
SRAM
Memory Space
Memory Space
Configure in milliseconds
Program in seconds
Download in microseconds
Power-up
Refresh
Port
Mode
Memory Space
2-28
Architecture
Lattice Semiconductor LatticeXP Family Data Sheet
master serial clock is 2.5MHz. Table 2-10 lists all the available Master Serial Clock frequencies. When a different
Master Serial Clock is selected during the design process, the following sequence takes place:
1. User selects a different Master Serial Clock frequency for configuration.
2. During configuration the device starts with the default (2.5MHz) Master Serial Clock frequency.
3. The clock configuration settings are contained in the early configuration bit stream.
4. The Master Serial Clock frequency changes to the selected frequency once the clock configuration bits are
received.
For further information on the use of this oscillator for configuration, please see details of additional technical docu-
mentation at the end of this data sheet.
Table 2-10. Selectable Master Serial Clock (CCLK) Frequencies During Configuration
Density Shifting
The LatticeXP family has been designed to ensure that different density devices in the same package have the
same pin-out. Furthermore, the architecture ensures a high success rate when performing design migration from
lower density parts to higher density parts. In many cases, it is also possible to shift a lower utilization design tar-
geted for a high-density device to a lower density device. However, the exact details of the final resource utilization
will impact the likely success in each case.
CCLK (MHz) CCLK (MHz) CCLK (MHz)
2.5113 45
4.3 15 51
5.4 20 55
6.9 26 60
8.1 30 130
9.2 34
10.0 41
1. Default
November 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 3-1 DS1001 DC and Switching_02.7
Recommended Operating Conditions3
Absolute Maximum Ratings1, 2, 3, 4
1. Stress above those listed under the “Absolute Maximum Ratings” may cause permanent damage to the device. Functional operation of the
device at these or any other conditions outside of those indicated in the operational sections of this specification is not implied.
2. Compliance with the Lattice Thermal Management document is required.
3. All voltages referenced to GND.
4. All chip grounds are connected together to a common package GND plane.
XPE (1.2V) XPC (1.8V/2.5V/3.3V)
Supply Voltage VCC . . . . . . . . . . . . . . . . . . . . . . . . -0.5 to 1.32V . . . . . . . . . . . . . . . -0.5 to 3.75V
Supply Voltage VCCP . . . . . . . . . . . . . . . . . . . . . . . -0.5 to 1.32V . . . . . . . . . . . . . . . -0.5 to 3.75V
Supply Voltage VCCAUX . . . . . . . . . . . . . . . . . . . . . -0.5 to 3.75V . . . . . . . . . . . . . . . -0.5 to 3.75V
Supply Voltage VCCJ . . . . . . . . . . . . . . . . . . . . . . . -0.5 to 3.75V . . . . . . . . . . . . . . . -0.5 to 3.75V
Output Supply Voltage VCCIO . . . . . . . . . . . . . . . . -0.5 to 3.75V . . . . . . . . . . . . . . . -0.5 to 3.75V
I/O Tristate Voltage Applied5 . . . . . . . . . . . . . . . . . -0.5 to 3.75V . . . . . . . . . . . . . . . -0.5 to 3.75V
Dedicated Input Voltage Applied 5. . . . . . . . . . . . . -0.5 to 3.75V . . . . . . . . . . . . . . . -0.5 to 4.25V
Storage Temperature (Ambient) . . . . . . . . . . . . . . -65 to 150°C . . . . . . . . . . . . . . . -65 to 150°C
Junction Temp. (Tj) . . . . . . . . . . . . . . . . . . . . . . . . . . +125°C . . . . . . . . . . . . . . . . . . . +125°C
5. Overshoot and undershoot of -2V to (VIHMAX + 2) volts is permitted for a duration of <20ns.
Symbol Parameter Min. Max. Units
VCC
Core Supply Voltage for 1.2V Devices 1.14 1.26 V
Core Supply Voltage for 1.8V/2.5V/3.3V Devices 1.71 3.465 V
VCCP
Supply Voltage for PLL for 1.2V Devices 1.14 1.26 V
Supply Voltage for PLL for 1.8V/2.5V/3.3V Devices 1.71 3.465 V
VCCAUX4Auxiliary Supply Voltage 3.135 3.465 V
VCCIO1, 2 I/O Driver Supply Voltage 1.14 3.465 V
VCCJ1Supply Voltage for IEEE 1149.1 Test Access Port 1.14 3.465 V
tJCOM Junction Temperature, Commercial Operation 0 85 C
tJIND Junction Temperature, Industrial Operation -40 100 C
tJFLASHCOM Junction Temperature, Flash Programming, Commercial 0 85 C
tJFLASHIND Junction Temperature, Flash Programming, Industrial 0 85 C
1. If VCCIO or VCCJ is set to 3.3V, they must be connected to the same power supply as VCCAUX. For the XPE devices (1.2V VCC), if VCCIO or
VCCJ is set to 1.2V, they must be connected to the same power supply as VCC.
2. See recommended voltages by I/O standard in subsequent table.
3. The system designer must ensure that the FPGA design stays within the specified junction temperature and package thermal capabilities of
the device based on the expected operating frequency, activity factor and environment conditions of the system.
4. VCCAUX ramp rate must not exceed 30mV/µs during power up when transitioning between 0V and 3.3V.
LatticeXP Family Data Sheet
DC and Switching Characteristics
3-2
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Hot Socketing Specifications1, 2, 3, 4, 5, 6
1. Insensitive to sequence of VCC, VCCAUX and VCCIO. However, assumes monotonic rise/fall rates for VCC, VCCAUX and VCCIO.
2. 0 VCC VCC (MAX) or 0 VCCAUX VCCAUX (MAX).
3. 0 VCCIO VCCIO (MAX) for top and bottom I/O banks.
4. 0.2 VCCIO VCCIO (MAX) for left and right I/O banks.
5. IDK is additive to IPU, IPW or IBH.
6. LVCMOS and LVTTL only.
Symbol Parameter Condition Min. Typ. Max. Units
IDK Input or I/O Leakage Current 0 VIN VIH (MAX.) +/-1000 µA
3-3
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
DC Electrical Characteristics
Over Recommended Operating Conditions
Supply Current (Sleep Mode)1, 2, 3
Symbol Parameter Condition Min. Typ. Max. Units
IIL, IIH1, 2, 4 Input or I/O Leakage 0 VIN (VCCIO - 0.2V) 10 µA
(VCCIO - 0.2V) < VIN 3.6V 40 µA
IPU I/O Active Pull-up Current 0 VIN 0.7 VCCIO -30 -150 µA
IPD I/O Active Pull-down Current VIL (MAX) VIN VIH (MAX) 30 150 µA
IBHLS Bus Hold Low sustaining current VIN = VIL (MAX) 30 µA
IBHHS Bus Hold High sustaining current VIN = 0.7VCCIO -30 µA
IBHLO Bus Hold Low Overdrive current 0 VIN VIH (MAX) 150 µA
IBHHO Bus Hold High Overdrive current 0 VIN VIH (MAX) -150 µA
VBHT Bus Hold trip Points 0 VIN VIH (MAX) VIL (MAX) VIH (MIN) V
C1 I/O Capacitance3VCCIO = 3.3V, 2.5V, 1.8V, 1.5V, 1.2V,
VCC = 1.2V, VIO = 0 to VIH (MAX) —8pf
C2 Dedicated Input Capacitance3VCCIO = 3.3V, 2.5V, 1.8V, 1.5V, 1.2V,
VCC = 1.2V, VIO = 0 to VIH (MAX) —8pf
1. Input or I/O leakage current is measured with the pin configured as an input or as an I/O with the output driver tri-stated. It is not measured
with the output driver active. Bus maintenance circuits are disabled.
2. Not applicable to SLEEPN/TOE pin.
3. TA 25°C, f = 1.0MHz
4. When VIH is higher than VCCIO, a transient current typically of 30ns in duration or less with a peak current of 6mA can be expected on the
high-to-low transition.
Symbol Parameter Device Typ.4Max Units
ICC Core Power Supply
LFXP3C 12 65 µA
LFXP6C 14 75 µA
LFXP10C 16 85 µA
LFXP15C 18 95 µA
LFXP20C 20 105 µA
ICCP PLL Power Supply (per PLL) All LFXP ‘C’ Devices 1 5 µA
ICCAUX Auxiliary Power Supply
LFXP3C 2 90 µA
LFXP6C 2 100 µA
LFXP10C 2 110 µA
LFXP15C 3 120 µA
LFXP20C 4 130 µA
ICCIO Bank Power Supply5
LFXP3C 2 20 µA
LFXP6C 2 22 µA
LFXP10C 2 24 µA
LFXP15C 3 27 µA
LFXP20C 4 30 µA
ICCJ VCCJ Power Supply All LFXP ‘C’ Devices 1 5 µA
1. Assumes all inputs are configured as LVCMOS and held at the VCCIO or GND.
2. Frequency 0MHz.
3. User pattern: blank.
4. TA=25°C, power supplies at nominal voltage.
5. Per bank.
3-4
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Supply Current (Standby)1, 2, 3, 4
Over Recommended Operating Conditions
Symbol Parameter Device Typ.5Units
ICC Core Power Supply
LFXP3E 15 mA
LFXP6E 20 mA
LFXP10E 35 mA
LFXP15E 45 mA
LFXP20E 55 mA
LFXP3C 35 mA
LFXP6C 40 mA
LFXP10C 70 mA
LFXP15C 80 mA
LFXP20C 90 mA
ICCP PLL Power Supply
(per PLL) All 8 mA
ICCAUX Auxiliary Power Supply
VCCAUX = 3.3V
LFXP3E/C 22 mA
LFXP6E/C 22 mA
LFXP10E/C 30 mA
LFXP15E/C 30 mA
LFXP20E/C 30 mA
ICCIO Bank Power Supply6All 2 mA
ICCJ VCCJ Power Supply All 1 mA
1. For further information on supply current, please see details of additional technical documentation at the end of this data sheet.
2. Assumes all outputs are tristated, all inputs are configured as LVCMOS and held at the VCCIO or GND.
3. Frequency 0MHz.
4. User pattern: blank.
5. TA=25°C, power supplies at nominal voltage.
6. Per bank.
3-5
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Initialization Supply Current1, 2, 3, 4, 5, 6
Over Recommended Operating Conditions
Symbol Parameter Device Typ.7Units
ICC Core Power Supply
LFXP3E 40 mA
LFXP6E 50 mA
LFXP10E 110 mA
LFXP15E 140 mA
LFXP20E 250 mA
LFXP3C 60 mA
LFXP6C 70 mA
LFXP10C 150 mA
LFXP15C 180 mA
LFXP20C 290 mA
ICCAUX Auxiliary Power Supply
VCCAUX = 3.3V
LFXP3E/C 50 mA
LFXP6E/C 60 mA
LFXP10E/C 90 mA
LFXP15 /C 110 mA
LFXP20E/C 130 mA
ICCJ VCCJ Power Supply All 2 mA
1. Until DONE signal is active.
2. For further information on supply current, please see details of additional technical documentation at the end of this data sheet.
3. Assumes all outputs are tristated, all inputs are configured as LVCMOS and held at the VCCIO or GND.
4. Frequency 0MHz.
5. Typical user pattern.
6. Assume normal bypass capacitor/decoupling capacitor across the supply.
7. TA=25°C, power supplies at nominal voltage.
3-6
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Programming and Erase Flash Supply Current1, 2, 3, 4, 5
Symbol Parameter Device Typ.6 Units
ICC Core Power Supply
LFXP3E 30 mA
LFXP6E 40 mA
LFXP10E 50 mA
LFXP15E 60 mA
LFXP20E 70 mA
LFXP3C 50 mA
LFXP6C 60 mA
LFXP10C 90 mA
LFXP15C 100 mA
LFXP20C 110 mA
ICCAUX Auxiliary Power Supply
VCCAUX = 3.3V
LFXP3E/C 50 mA
LFXP6E/C 60 mA
LFXP10E/C 90 mA
LFXP15E/C 110 mA
LFXP20E/C 130 mA
ICCJ VCCJ Power Supply7All 2 mA
1. For further information on supply current, please see details of additional technical documentation at the end of this data sheet.
2. Assumes all outputs are tristated, all inputs are configured as LVCMOS and held at the VCCIO or GND.
3. Blank user pattern; typical Flash pattern.
4. Bypass or decoupling capacitor across the supply.
5. JTAG programming is at 1MHz.
6. TA=25°C, power supplies at nominal voltage.
7. When programming via JTAG.
3-7
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
sysIO Recommended Operating Conditions
VCCIO VREF (V)
Standard Min. Typ. Max. Min. Typ. Max.
LVCMOS 3.3 3.135 3.3 3.465
LVCMOS 2.5 2.375 2.5 2.625
LVCMOS 1.8 1.71 1.8 1.89
LVCMOS 1.5 1.425 1.5 1.575
LVCMOS 1.2 1.14 1.2 1.26
LVTTL 3.135 3.3 3.465
PCI33 3.135 3.3 3.465
SSTL18 Class I 1.71 1.8 1.89 0.833 0.9 0.969
SSTL2 Class I, II 2.375 2.5 2.625 1.15 1.25 1.35
SSTL3 Class I, II 3.135 3.3 3.465 1.3 1.5 1.7
HSTL15 Class I 1.425 1.5 1.575 0.68 0.75 0.9
HSTL15 Class III 1.425 1.5 1.575 0.9
HSTL 18 Class I, II 1.71 1.8 1.89 0.9
HSTL 18 Class III 1.71 1.8 1.89 1.08
LVDS 2.375 2.5 2.625
LVPECL13.135 3.3 3.465
BLVDS12.375 2.5 2.625
1. Inputs on chip. Outputs are implemented with the addition of external resistors.
3-8
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
sysIO Single-Ended DC Electrical Characteristics
Input/Output
Standard
VIL VIH VOL Max.
(V)
VOH Min.
(V)
IOL
(mA)
IOH
(mA)Min. (V) Max. (V) Min. (V) Max. (V)
LVCMOS 3.3 -0.3 0.8 2.0 3.6 0.4 VCCIO - 0.4 20, 16, 12,
8, 4 -20, -16, -12,
-8, -4
0.2 VCCIO - 0.2 0.1 -0.1
LVTTL -0.3 0.8 2.0 3.6 0.4 VCCIO - 0.4 20, 16, 12,
8, 4 -20, -16, -12,
-8, -4
0.2 VCCIO - 0.2 0.1 -0.1
LVCMOS 2.5 -0.3 0.7 1.7 3.6 0.4 VCCIO - 0.4 20, 16, 12,
8, 4 -20, -16, -12,
-8, -4
0.2 VCCIO - 0.2 0.1 -0.1
LVCMOS 1.8 -0.3 0.35VCCIO 0.65VCCIO 3.6 0.4 VCCIO - 0.4 16, 12, 8, 4 -16, -12, -8, -4
0.2 VCCIO - 0.2 0.1 -0.1
LVCMOS 1.5 -0.3 0.35VCCIO 0.65VCCIO 3.6 0.4 VCCIO - 0.4 8, 4 -8, -4
0.2 VCCIO - 0.2 0.1 -0.1
LVCMOS 1.2
(“C” Version) -0.3 0.42 0.78 3.6 0.4 VCCIO - 0.4 6, 2 -6, -2
0.2 VCCIO - 0.2 0.1 -0.1
LVCMOS 1.2
(“E” Version) -0.3 0.35VCC 0.65VCC 3.6 0.4 VCCIO - 0.4 6, 2 -6, -2
0.2 VCCIO - 0.2 0.1 -0.1
PCI -0.3 0.3VCCIO 0.5VCCIO 3.6 0.1VCCIO 0.9VCCIO 1.5 -0.5
SSTL3 class I -0.3 VREF - 0.2 VREF + 0.2 3.6 0.7 VCCIO - 1.1 8 -8
SSTL3 class II -0.3 VREF - 0.2 VREF + 0.2 3.6 0.5 VCCIO - 0.9 16 -16
SSTL2 class I -0.3 VREF - 0.18 VREF + 0.18 3.6 0.54 VCCIO - 0.62 7.6 -7.6
SSTL2 class II -0.3 VREF - 0.18 VREF + 0.18 3.6 0.35 VCCIO - 0.43 15.2 -15.2
SSTL18 class I -0.3 VREF - 0.125 VREF + 0.125 3.6 0.4 VCCIO - 0.4 6.7 -6.7
HSTL15 class I -0.3 VREF - 0.1 VREF + 0.1 3.6 0.4 VCCIO - 0.4 8 -8
HSTL15 class III -0.3 VREF - 0.1 VREF + 0.1 3.6 0.4 VCCIO - 0.4 24 -8
HSTL18 class I -0.3 VREF - 0.1 VREF + 0.1 3.6 0.4 VCCIO - 0.4 9.6 -9.6
HSTL18 class II -0.3 VREF - 0.1 VREF + 0.1 3.6 0.4 VCCIO - 0.4 16 -16
HSTL18 class III -0.3 VREF - 0.1 VREF + 0.1 3.6 0.4 VCCIO - 0.4 24 -8
1. The average DC current drawn by I/Os between GND connections, or between the last GND in an I/O bank and the end of an I/O bank, as
shown in the logic signal connections table shall not exceed n * 8mA. Where n is the number of I/Os between bank GND connections or
between the last GND in a bank and the end of a bank.
3-9
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
sysIO Differential Electrical Characteristics
LVD S
Over Recommended Operating Conditions
Parameter
Symbol Parameter Description Test Conditions Min. Typ. Max. Units
VINP, VINM Input Voltage 0 2.4 V
VTHD Differential Input Threshold +/-100 mV
VCM Input Common Mode Voltage
100mV VTHD VTHD/2 1.2 1.8 V
200mV VTHD VTHD/2 1.2 1.9 V
350mV VTHD VTHD/2 1.2 2.0 V
IIN Input current Power on or power off +/-10 µA
VOH Output high voltage for VOP or VOM RT = 100 ohms 1.38 1.60 V
VOL Output low voltage for VOP or VOM RT = 100 ohms 0.9V 1.03 V
VOD Output voltage differential (VOP - VOM), RT = 100 ohms 250 350 450 mV
VOD Change in VOD between high and
low ——50mV
VOS Output voltage offset (VOP - VOM)/2, RT = 100 ohms 1.125 1.25 1.375 V
VOS Change in VOS between H and L 50 mV
IOSD Output short circuit current VOD = 0V Driver outputs
shorted —— 6mA
3-10
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Differential HSTL and SSTL
Differential HSTL and SSTL outputs are implemented as a pair of complementary single-ended outputs. All allow-
able single-ended output classes (class I and class II) are supported in this mode.
LVDS25E
The top and bottom side of LatticeXP devices support LVDS outputs via emulated complementary LVCMOS out-
puts in conjunction with a parallel resistor across the driver outputs. The scheme shown in Figure 3-1 is one possi-
ble solution for point-to-point signals.
Figure 3-1. LVDS25E Output Termination Example
Table 3-1. LVDS25E DC Conditions
Over Recommended Operating Conditions
BLVDS
The LatticeXP devices support BLVDS standard. This standard is emulated using complementary LVCMOS out-
puts in conjunction with a parallel external resistor across the driver outputs. BLVDS is intended for use when multi-
drop and bi-directional multi-point differential signaling is required. The scheme shown in Figure 3-2 is one possible
solution for bi-directional multi-point differential signals.
Parameter Description Typical Units
VOH Output high voltage 1.43 V
VOL Output low voltage 1.07 V
VOD Output differential voltage 0.35 V
VCM Output common mode voltage 1.25 V
ZBACK Back impedance 100 ohms
IDC DC output current 3.66 mA
+
-
Bourns
CAT16-LV4F12
RS=165 ohms
(±1%)
RS=165 ohms
(±1%)
RD = 140 ohms
(±1%)
RD = 100 ohms
(±1%)
OFF-chip
Transmission line, Zo = 100 ohm differential
VCCIO = 2.5V (±5%)
VCCIO = 2.5V (±5%)
ON-chip OFF-chip ON-chip
3-11
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 3-2. BLVDS Multi-point Output Example
Table 3-2. BLVDS DC Conditions1
Over Recommended Operating Conditions
Typical
Symbol Description Zo = 45 Zo = 90 Units
ZOUT Output impedance 100 100 ohms
RTLEFT Left end termination 45 90 ohms
RTRIGHT Right end termination 45 90 ohms
VOH Output high voltage 1.375 1.48 V
VOL Output low voltage 1.125 1.02 V
VOD Output differential voltage 0.25 0.46 V
VCM Output common mode voltage 1.25 1.25 V
IDC DC output current 11.2 10.2 mA
1. For input buffer, see LVDS table.
Heavily loaded backplane, effective Zo ~ 45 to 90 ohms differential
100100
2.5V
2.5V
+
-
100100
2.5V
2.5V
+
-
100
100
2.5V
2.5V
+
-
100
100
2.5V
2.5V
+
-
. . .
45-90 ohms, +/- 1%45-90 ohms, +/- 1%
+
-
+
-
. . .
-%
3-12
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
LVPECL
The LatticeXP devices support differential LVPECL standard. This standard is emulated using complementary
LVCMOS outputs in conjunction with a parallel resistor across the driver outputs. The LVPECL input standard is
supported by the LVDS differential input buffer. The scheme shown in Figure 3-3 is one possible solution for point-
to-point signals.
Figure 3-3. Differential LVPECL
Table 3-3. LVPECL DC Conditions1
Over Recommended Operating Conditions
For further information on LVPECL, BLVDS and other differential interfaces please see details of additional techni-
cal documentation at the end of the data sheet.
RSDS
The LatticeXP devices support differential RSDS standard. This standard is emulated using complementary LVC-
MOS outputs in conjunction with a parallel resistor across the driver outputs. The RSDS input standard is sup-
ported by the LVDS differential input buffer. The scheme shown in Figure 3-4 is one possible solution for RSDS
standard implementation. Use LVDS25E mode with suggested resistors for RSDS operation. Resistor values in
Figure 3-4 are industry standard values for 1% resistors.
Symbol Description Typical Units
ZOUT Output impedance 100 ohms
RPDriver parallel resistor 187 ohms
RSDriver series resistor 100 ohms
RTReceiver termination 100 ohms
VOH Output high voltage 2.03 V
VOL Output low voltage 1.27 V
VOD Output differential voltage 0.76 V
VCM Output common mode voltage 1.65 V
ZBACK Back impedance 85.7 ohms
IDC DC output current 12.7 mA
1. For input buffer, see LVDS table.
Transmission line, Zo = 100 ohm differential
RS= 100 ohms
= 100 ohms
= 187 ohms
= 100 ohms
RS
RPRT
Off-chip
3.3V
3.3V
+
-
3-13
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 3-4. RSDS (Reduced Swing Differential Standard)
Table 3-4. RSDS DC Conditions
Parameter Description Typical Units
ZOUT Output impedance 20 ohms
RSDriver series resistor 300 ohms
RPDriver parallel resistor 121 ohms
RTReceiver termination 100 ohms
VOH Output high voltage 1.35 V
VOL Output low voltage 1.15 V
VOD Output differential voltage 0.20 V
VCM Output common mode voltage 1.25 V
ZBACK Back impedance 101.5 ohms
IDC DC output current 3.66 mA
R
S
R
S
R
P
R
T
On-chip
Emulated
RSDS Buffer
VCCIO = 2.5V
VCCIO = 2.5V
Zo = 100
+
-
Off-chip
3-14
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Typical Building Block Function Performance1
Pin-to-Pin Performance (LVCMOS25 12 mA Drive)
Register to Register Performance
Function -5 Timing Units
Basic Functions
16-bit decoder 6.1 ns
32-bit decoder 7.3 ns
64-bit decoder 8.2 ns
4:1 MUX 4.9 ns
8:1 MUX 5.3 ns
16:1 MUX 5.7 ns
32:1 MUX 6.3 ns
Function -5 Timing Units
Basic Functions
16-bit decoder 351 MHz
32-bit decoder 248 MHz
64-bit decoder 237 MHz
4:1 MUX 590 MHz
8:1 MUX 523 MHz
16:1 MUX 434 MHz
32:1 MUX 355 MHz
8-bit adder 343 MHz
16-bit adder 292 MHz
64-bit adder 130 MHz
16-bit counter 388 MHz
32-bit counter 295 MHz
64-bit counter 200 MHz
64-bit accumulator 164 MHz
Embedded Memory Functions
Single Port RAM 256x36 bits 254 MHz
True-Dual Port RAM 512x18 bits 254 MHz
Distributed Memory Functions
16x2 SP RAM 434 MHz
64x2 SP RAM 332 MHz
128x4 SP RAM 235 MHz
32x2 PDP RAM 322 MHz
64x4 PDP RAM 291 MHz
1. These timing numbers were generated using the ispLEVER design tool. Exact performance may vary with design and tool version. The tool
uses internal parameters that have been characterized but are not tested on every device.
Timing v.F0.11
3-15
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Derating Logic Timing
Logic timing provided in the following sections of this data sheet and in the ispLEVER design tools are worst case
numbers in the operating range. Actual delays at nominal temperature and voltage for best-case process can be
much better than the values given in the tables. The ispLEVER design tool from Lattice can provide logic timing
numbers at a particular temperature and voltage.
3-16
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
LatticeXP External Switching Characteristics
Over Recommended Operating Conditions
Parameter Description Device
-5 -4 -3
UnitsMin. Max. Min. Max. Min. Max.
General I/O Pin Parameters (Using Primary Clock without PLL)1
tCO Clock to Output - PIO Output Register
LFXP3 5.12 6.12 7.43 ns
LFXP6 5.30 6.34 7.69 ns
LFXP10 5.52 6.60 8.00 ns
LFXP15 5.72 6.84 8.29 ns
LFXP20 5.97 7.14 8.65 ns
tSU Clock to Data Setup - PIO Input Register
LFXP3 -0.40 -0.28 -0.16 ns
LFXP6 -0.33 -0.32 -0.30 ns
LFXP10 -0.61 -0.71 -0.81 ns
LFXP15 -0.71 -0.77 -0.87 ns
LFXP20 -0.95 -1.14 -1.35 ns
tHClock to Data Hold - PIO Input Register
LFXP3 2.10 2.50 2.98 ns
LFXP6 2.28 2.72 3.24 ns
LFXP10 3.02 3.51 3.71 ns
LFXP15 2.70 3.22 3.85 ns
LFXP20 2.95 3.52 4.21 ns
tSU_DEL Clock to Data Setup - PIO Input Register
with Input Data Delay
LFXP3 2.38 2.49 2.66 ns
LFXP6 2.92 3.18 3.42 ns
LFXP10 2.72 2.75 2.84 ns
LFXP15 2.99 3.13 3.18 ns
LFXP20 4.47 4.56 4.80 ns
tH_DEL Clock to Data Hold - PIO Input Register with
Input Data Delay
LFXP3 -0.70 -0.80 -0.92 ns
LFXP6 -0.47 -0.38 -0.31 ns
LFXP10 -0.60 -0.47 -0.32 ns
LFXP15 -1.05 -0.98 -1.01 ns
LFXP20 -0.80 -0.58 -0.31 ns
fMAX_IO Clock Frequency of I/O and PFU Register All 400 360 320 MHz
DDR I/O Pin Parameters2
tDVADQ Data Valid After DQS (DDR Read) All 0.19 0.19 0.19 UI
tDVEDQ Data Hold After DQS (DDR Read) All 0.67 0.67 0.67 UI
tDQVBS Data Valid Before DQS All 0.20 0.20 0.20 UI
tDQVAS Data Valid After DQS All 0.20 0.20 0.20 UI
fMAX_DDR DDR Clock Frequency All 95 166 95 133 95 100 MHz
Primary and Secondary Clocks
fMAX_PRI Frequency for Primary Clock Tree All 450 412 375 MHz
tW_PRI Clock Pulse Width for Primary Clock All 1.19 1.19 1.19 ns
tSKEW_PRI Primary Clock Skew within an I/O Bank LFXP3/6/10/15 250 300 350 ps
LFXP20 300 350 400 ps
1. General timing numbers based on LVCMOS 2.5, 12mA.
2. DDR timing numbers based on SSTL I/O.
Timing v.F0.11
3-17
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 3-5. DDR Timings
t
DQVAS
t
DQVBS
DQ and DQS Write Timings
t
DQS
DQ
DQS
DQ
DVEDQ
t
DVADQ
DQ and DQS Read Timings
3-18
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
LatticeXP Internal Timing Parameters1
Over Recommended Operating Conditions
Parameter Description
-5 -4 -3
UnitsMin. Max. Min. Max. Min. Max.
PFU/PFF Logic Mode Timing
tLUT4_PFU LUT4 Delay (A to D Inputs to F Output) 0.28 0.34 0.40 ns
tLUT6_PFU LUT6 Delay (A to D Inputs to OFX Output) 0.44 0.53 0.63 ns
tLSR_PFU Set/Reset to Output of PFU 0.90 1.08 1.29 ns
tSUM_PFU Clock to Mux (M0,M1) Input Setup Time 0.13 0.15 0.19 ns
tHM_PFU Clock to Mux (M0,M1) Input Hold Time -0.04 -0.03 -0.03 ns
tSUD_PFU Clock to D Input Setup Time 0.13 0.16 0.19 ns
tHD_PFU Clock to D Input Hold Time -0.03 -0.02 -0.02 ns
tCK2Q_PFU Clock to Q Delay, D-type Register Configuration 0.40 0.48 0.58 ns
tLE2Q_PFU Clock to Q Delay Latch Configuration 0.53 0.64 0.76 ns
tLD2Q_PFU D to Q Throughput Delay when Latch is Enabled 0.55 0.66 0.79 ns
PFU Dual Port Memory Mode Timing
tCORAM_PFU Clock to Output 0.40 0.48 0.58 ns
tSUDATA_PFU Data Setup Time -0.18 -0.14 -0.11 ns
tHDATA_PFU Data Hold Time 0.28 0.34 0.40 ns
tSUADDR_PFU Address Setup Time -0.46 -0.37 -0.30 ns
tHADDR_PFU Address Hold Time 0.71 0.85 1.02 ns
tSUWREN_PFU Write/Read Enable Setup Time -0.22 -0.17 -0.14 ns
tHWREN_PFU Write/Read Enable Hold Time 0.33 0.40 0.48 ns
PIC Timing
PIO Input/Output Buffer Timing
tIN_PIO Input Buffer Delay 0.62 0.72 0.85 ns
tOUT_PIO Output Buffer Delay 2.12 2.54 3.05 ns
IOLOGIC Input/Output Timing
tSUI_PIO Input Register Setup Time (Data Before Clock) 1.35 1.83 2.37 ns
tHI_PIO Input Register Hold Time (Data After Clock) 0.05 0.05 0.05 ns
tCOO_PIO Output Register Clock to Output Delay 0.36 0.44 0.52 ns
tSUCE_PIO Input Register Clock Enable Setup Time -0.09 -0.07 -0.06 ns
tHCE_PIO Input Register Clock Enable Hold Time 0.13 0.16 0.19 ns
tSULSR_PIO Set/Reset Setup Time 0.19 0.23 0.28 ns
tHLSR_PIO Set/Reset Hold Time -0.14 -0.11 -0.09 ns
EBR Timing
tCO_EBR Clock to Output from Address or Data 4.01 4.81 5.78 ns
tCOO_EBR Clock to Output from EBR Output Register 0.81 0.97 1.17 ns
tSUDATA_EBR Setup Data to EBR Memory -0.26 -0.21 -0.17 ns
tHDATA_EBR Hold Data to EBR Memory 0.41 0.49 0.59 ns
tSUADDR_EBR Setup Address to EBR Memory -0.26 -0.21 -0.17 ns
tHADDR_EBR Hold Address to EBR Memory 0.41 0.49 0.59 ns
tSUWREN_EBR Setup Write/Read Enable to EBR Memory -0.17 -0.13 -0.11 ns
tHWREN_EBR Hold Write/Read Enable to EBR Memory 0.26 0.31 0.37 ns
tSUCE_EBR Clock Enable Setup Time to EBR Output Register 0.19 0.23 0.28 ns
tHCE_EBR Clock Enable Hold Time to EBR Output Register -0.13 -0.10 -0.08 ns
3-19
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
tRSTO_EBR Reset To Output Delay Time from EBR Output
Register 1.61 1.94 2.32 ns
PLL Parameters
tRSTREC Reset Recovery to Rising Clock 1.00 1.00 1.00 ns
tRSTSU Reset Signal Setup Time 1.00 1.00 1.00 ns
1. Internal parameters are characterized but not tested on every device.
Timing v.F0.11
LatticeXP Internal Timing Parameters1 (Continued)
Over Recommended Operating Conditions
Parameter Description
-5 -4 -3
UnitsMin. Max. Min. Max. Min. Max.
3-20
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Timing Diagrams
PFU Timing Diagrams
Figure 3-6. Slice Single/Dual Port Write Cycle Timing
Figure 3-7. Slice Single /Dual Port Read Cycle Timing
CK
D
WRE
D
DI[1:0]
DO[1:0]
AD
AD[3:0]
Old Data
WRE
D
DO[1:0]
AD
AD[3:0]
Old Data
3-21
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
EBR Memory Timing Diagrams
Figure 3-8. Read Mode (Normal)
Note: Input data and address are registered at the positive edge of the clock and output data appears after the positive of the clock.
Figure 3-9. Read Mode with Input and Output Registers
A0 A1 A0 A1
D0 D1
DOA
A0
t
ACCESS
t
ACCESS
t
SU
t
H
D0 D1 D0
DIA
ADA
WEA
CSA
CLKA
A0 A1 A0 A0
D0 D1
D0
D0DOA
output is only updated during a read cycle
A1
D1
D0 D1
Mem(n) data from previous read
Mem(n) data from previous read
DIA
ADA
WEA
CSA
CLKA
DOA
DOA
(Registered)
tSU tH
tACCESS tACCESS
3-22
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Figure 3-10. Read Before Write (SP Read/Write on Port A, Input Registers Only)
Note: Input data and address are registered at the positive edge of the clock and output data appears after the positive of the clock.
Figure 3-11. Write Through (SP Read/Write On Port A, Input Registers Only)
Note: Input data and address are registered at the positive edge of the clock and output data appears after the positive of the clock.
A0 A1 A0 A1
D0 D1
D2
DOA
A0
D2 D3 D1
old A0 Data old A1 Data D0 D1
DIA
ADA
WEA
CSA
CLKA
tSU tH
tACCESS tACCESS tACCESS tACCESS tACCESS
A0 A1 A0
D0 D1
D4
tSU
tACCESS tACCESS tACCESS
tH
D2 D3 D4
D0 D1 D2
Data from Prev Read
or Write
Three consecutive writes to A0
D3
DOA
DIA
ADA
WEA
CSA
CLKA
tACCESS
3-23
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
LatticeXP Family Timing Adders1
Over Recommended Operating Conditions
Buffer Type Description -5 -4 -3 Units
Input Adjusters
LVDS25E LVDS 2.5 Emulated 0.5 0.5 0.5 ns
LVDS25 LVDS 0.4 0.4 0.4 ns
BLVDS25 BLVDS 0.5 0.5 0.5 ns
LVPECL33 LVPECL 0.6 0.6 0.6 ns
HSTL18_I HSTL_18 class I 0.4 0.4 0.4 ns
HSTL18_II HSTL_18 class II 0.4 0.4 0.4 ns
HSTL18_III HSTL_18 class III 0.4 0.4 0.4 ns
HSTL18D_I Differential HSTL 18 class I 0.4 0.4 0.4 ns
HSTL18D_II Differential HSTL 18 class II 0.4 0.4 0.4 ns
HSTL18D_III Differential HSTL 18 class III 0.4 0.4 0.4 ns
HSTL15_I HSTL_15 class I 0.5 0.5 0.5 ns
HSTL15_III HSTL_15 class III 0.5 0.5 0.5 ns
HSTL15D_I Differential HSTL 15 class I 0.5 0.5 0.5 ns
HSTL15D_III Differential HSTL 15 class III 0.5 0.5 0.5 ns
SSTL33_I SSTL_3 class I 0.6 0.6 0.6 ns
SSTL33_II SSTL_3 class II 0.6 0.6 0.6 ns
SSTL33D_I Differential SSTL_3 class I 0.6 0.6 0.6 ns
SSTL33D_II Differential SSTL_3 class II 0.6 0.6 0.6 ns
SSTL25_I SSTL_2 class I 0.5 0.5 0.5 ns
SSTL25_II SSTL_2 class II 0.5 0.5 0.5 ns
SSTL25D_I Differential SSTL_2 class I 0.5 0.5 0.5 ns
SSTL25D_II Differential SSTL_2 class II 0.5 0.5 0.5 ns
SSTL18_I SSTL_18 class I 0.5 0.5 0.5 ns
SSTL18D_I Differential SSTL_18 class I 0.5 0.5 0.5 ns
LVTTL33 LVTTL 0.2 0.2 0.2 ns
LVCMOS33 LVCMOS 3.3 0.2 0.2 0.2 ns
LVCMOS25 LVCMOS 2.5 0.0 0.0 0.0 ns
LVCMOS18 LVCMOS 1.8 0.1 0.1 0.1 ns
LVCMOS15 LVCMOS 1.5 0.1 0.1 0.1 ns
LVCMOS12 LVCMOS 1.2 0.1 0.1 0.1 ns
PCI33 PCI 0.2 0.2 0.2 ns
Output Adjusters
LVDS25E LVDS 2.5 Emulated 0.3 0.3 0.3 ns
LVDS25 LVDS 2.5 0.3 0.3 0.3 ns
BLVDS25 BLVDS 2.5 0.3 0.3 0.3 ns
LVPECL33 LVPECL 3.3 0.1 0.1 0.1 ns
HSTL18_I HSTL_18 class I 0.1 0.1 0.1 ns
HSTL18_II HSTL_18 class II 0.1 0.1 0.1 ns
HSTL18_III HSTL_18 class III 0.2 0.2 0.2 ns
HSTL18D_I Differential HSTL 18 class I 0.1 0.1 0.1 ns
HSTL18D_II Differential HSTL 18 class II -0.1 -0.1 -0.1 ns
HSTL18D_III Differential HSTL 18 class III 0.2 0.2 0.2 ns
3-24
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
HSTL15_I HSTL_15 class I 0.2 0.2 0.2 ns
HSTL15_III HSTL_15 class III 0.2 0.2 0.2 ns
HSTL15D_I Differential HSTL 15 class I 0.2 0.2 0.2 ns
HSTL15D_III Differential HSTL 15 class III 0.2 0.2 0.2 ns
SSTL33_I SSTL_3 class I 0.1 0.1 0.1 ns
SSTL33_II SSTL_3 class II 0.3 0.3 0.3 ns
SSTL33D_I Differential SSTL_3 class I 0.1 0.1 0.1 ns
SSTL33D_II Differential SSTL_3 class II 0.3 0.3 0.3 ns
SSTL25_I SSTL_2 class I -0.1 -0.1 -0.1 ns
SSTL25_II SSTL_2 class II 0.3 0.3 0.3 ns
SSTL25D_I Differential SSTL_2 class I -0.1 -0.1 -0.1 ns
SSTL25D_II Differential SSTL_2 class II 0.3 0.3 0.3 ns
SSTL18_I SSTL_1.8 class I 0.1 0.1 0.1 ns
SSTL18D_I Differential SSTL_1.8 class I 0.1 0.1 0.1 ns
LVTTL33_4mA LVTTL 4mA drive 0.8 0.8 0.8 ns
LVTTL33_8mA LVTTL 8mA drive 0.5 0.5 0.5 ns
LVTTL33_12mA LVTTL 12mA drive 0.3 0.3 0.3 ns
LVTTL33_16mA LVTTL 16mA drive 0.4 0.4 0.4 ns
LVTTL33_20mA LVTTL 20mA drive 0.3 0.3 0.3 ns
LVCMOS33_2mA LVCMOS 3.3 2mA drive 0.8 0.8 0.8 ns
LVCMOS33_4mA LVCMOS 3.3 4mA drive 0.8 0.8 0.8 ns
LVCMOS33_8mA LVCMOS 3.3 8mA drive 0.5 0.5 0.5 ns
LVCMOS33_12mA LVCMOS 3.3 12mA drive 0.3 0.3 0.3 ns
LVCMOS33_16mA LVCMOS 3.3 16mA drive 0.4 0.4 0.4 ns
LVCMOS33_20mA LVCMOS 3.3 20mA drive 0.3 0.3 0.3 ns
LVCMOS25_2mA LVCMOS 2.5 2mA drive 0.7 0.7 0.7 ns
LVCMOS25_4mA LVCMOS 2.5 4mA drive 0.7 0.7 0.7 ns
LVCMOS25_8mA LVCMOS 2.5 8mA drive 0.4 0.4 0.4 ns
LVCMOS25_12mA LVCMOS 2.5 12mA drive 0.0 0.0 0.0 ns
LVCMOS25_16mA LVCMOS 2.5 16mA drive 0.2 0.2 0.2 ns
LVCMOS25_20mA LVCMOS 2.5 20mA drive 0.4 0.4 0.4 ns
LVCMOS18_2mA LVCMOS 1.8 2mA drive 0.6 0.6 0.6 ns
LVCMOS18_4mA LVCMOS 1.8 4mA drive 0.6 0.6 0.6 ns
LVCMOS18_8mA LVCMOS 1.8 8mA drive 0.4 0.4 0.4 ns
LVCMOS18_12mA LVCMOS 1.8 12mA drive 0.2 0.2 0.2 ns
LVCMOS18_16mA LVCMOS 1.8 16mA drive 0.2 0.2 0.2 ns
LVCMOS15_2mA LVCMOS 1.5 2mA drive 0.6 0.6 0.6 ns
LVCMOS15_4mA LVCMOS 1.5 4mA drive 0.6 0.6 0.6 ns
LVCMOS15_8mA LVCMOS 1.5 8mA drive 0.2 0.2 0.2 ns
LVCMOS12_2mA LVCMOS 1.2 2mA drive 0.4 0.4 0.4 ns
LVCMOS12_6mA LVCMOS 1.2 6mA drive 0.4 0.4 0.4 ns
PCI33 PCI33 0.3 0.3 0.3 ns
1. General timing numbers based on LVCMOS 2.5, 12mA.
Timing v.F0.11
LatticeXP Family Timing Adders1 (Continued)
Over Recommended Operating Conditions
Buffer Type Description -5 -4 -3 Units
3-25
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
sysCLOCK PLL Timing
Over Recommended Operating Conditions
LatticeXP “C” Sleep Mode Timing
Parameter Descriptions Conditions Min. Typ. Max. Units
fIN Input Clock Frequency (CLKI, CLKFB) 25 375 MHz
fOUT Output Clock Frequency (CLKOP, CLKOS) 25 375 MHz
fOUT2 K-Divider Output Frequency (CLKOK) 0.195 187.5 MHz
fVCO PLL VCO Frequency 375 750 MHz
fPFD Phase Detector Input Frequency 25 MHz
AC Characteristics
tDT Output Clock Duty Cycle Default duty cycle elected3 45 50 55 %
tPH4Output Phase Accuracy 0.05 UI
tOPJIT1 Output Clock Period Jitter fOUT Š 100MHz +/- 125 ps
fOUT < 100MHz 0.02 UIPP
tSK Input Clock to Output Clock Skew Divider ratio = integer +/- 200 ps
tWOutput Clock Pulse Width At 90% or 10%3 1—ns
tLOCK2 PLL Lock-in Time 150 us
tPA Programmable Delay Unit 100 250 400 ps
tIPJIT Input Clock Period Jitter +/- 200 ps
tFBKDLY External Feedback Delay 10 ns
tHI Input Clock High Time 90% to 90% 0.5 ns
tLO Input Clock Low Time 10% to 10% 0.5 ns
tRST RST Pulse Width 10 ns
1. Jitter sample is taken over 10,000 samples of the primary PLL output with clean reference clock.
2. Output clock is valid after tLOCK for PLL reset and dynamic delay adjustment.
3. Using LVDS output buffers.
4. As compared to CLKOP output.
Timing v.F0.11
Parameter Descriptions Min. Typ. Max. Units
tPWRDN SLEEPN Low to I/O Tristate 20 32 ns
tPWRUP SLEEPN High to Power Up
LFXP3 1.4 2.1 ms
LFXP6 1.7 2.4 ms
LFXP10 1.1 1.8 ms
LFXP15 1.4 2.1 ms
LFXP20 1.7 2.4 ms
tWSLEEPN SLEEPN Pulse Width to Initiate Sleep Mode 400 ns
tWAWAKE SLEEPN Pulse Rejection 120 ns
SLEEPN
t
PWRUP
Sleep Mode
t
PWRDN
I/O
3-26
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
LatticeXP sysCONFIG Port Timing Specifications
Over Recommended Operating Conditions
Parameter Description Min. Max. Units
sysCONFIG Byte Data Flow
tSUCBDI Byte D[0:7] Setup Time to CCLK 7 ns
tHCBDI Byte D[0:7] Hold Time to CCLK 3 ns
tCODO Clock to Dout in Flowthrough Mode 12 ns
tSUCS CS[0:1] Setup Time to CCLK 7 ns
tHCS CS[0:1] Hold Time to CCLK 2 ns
tSUWD Write Signal Setup Time to CCLK 7 ns
tHWD Write Signal Hold Time to CCLK 2 ns
tDCB CCLK to BUSY Delay Time 12 ns
tCORD Clock to Out for Read Data 12 ns
sysCONFIG Byte Slave Clocking
tBSCH Byte Slave Clock Minimum High Pulse 6 ns
tBSCL Byte Slave Clock Minimum Low Pulse 8 ns
tBSCYC Byte Slave Clock Cycle Time 15 ns
sysCONFIG Serial (Bit) Data Flow
tSUSCDI DI (Data In) Setup Time to CCLK 7 ns
tHSCDI DI (Data In) Hold Time to CCLK 2 ns
tCODO Clock to Dout in Flowthrough Mode 12 ns
sysCONFIG Serial Slave Clocking
tSSCH Serial Slave Clock Minimum High Pulse 6 ns
tSSCL Serial Slave Clock Minimum Low Pulse 6 ns
sysCONFIG POR, Initialization and Wake Up
tICFG Minimum Vcc to INIT High 50 ms
tVMC Time from tICFG to Valid Master Clock 2 us
tPRGMRJ Program Pin Pulse Rejection 7 ns
tPRGM2PROGRAMN Low Time to Start Configuration 25 ns
tDINIT INIT Low Time 1 ms
tDPPINIT Delay Time from PROGRAMN Low to INIT Low 37 ns
tDINITD Delay Time from PROGRAMN Low to DONE Low 37 ns
tIODISS User I/O Disable from PROGRAMN Low 25 ns
tIOENSS User I/O Enabled Time from CCLK Edge During Wake-up Sequence 25 ns
tMWC Additional Wake Master Clock Signals after Done Pin High 120 cycles
Configuration Master Clock (CCLK)
Frequency1Selected
Value -
30%
Selected
Value +
30% MHz
Duty Cycle 40 60 %
1. See Table 2-10 for available CCLK frequencies.
2. The threshold level for PROGRAMN, as well as for CFG[1] and CFG[0], is determined by VCC, such that the threshold = VCC/2.
Timing v.F0.11
3-27
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Flash Download Time
JTAG Port Timing Specifications
Over Recommended Operating Conditions
Figure 3-12. JTAG Port Timing Waveforms
Symbol Parameter Min. Typ. Max. Units
tREFRESH
PROGRAMN Low-to-
High. Transition to Done
High.
LFXP3 1.1 1.7 ms
LFXP6 1.4 2.0 ms
LFXP10 0.9 1.5 ms
LFXP15 1.1 1.7 ms
LFXP20 1.3 1.9 ms
Symbol Parameter Min. Max. Units
fMAX —25 MHz
tBTCP TCK [BSCAN] clock pulse width 40 ns
tBTCPH TCK [BSCAN] clock pulse width high 20 ns
tBTCPL TCK [BSCAN] clock pulse width low 20 ns
tBTS TCK [BSCAN] setup time 10 ns
tBTH TCK [BSCAN] hold time 8 ns
tBTRF TCK [BSCAN] rise/fall time 50 ns
tBTCO TAP controller falling edge of clock to valid output 10 ns
tBTCODIS TAP controller falling edge of clock to valid disable 10 ns
tBTCOEN TAP controller falling edge of clock to valid enable 10 ns
tBTCRS BSCAN test capture register setup time 8 ns
tBTCRH BSCAN test capture register hold time 25 ns
tBUTCO BSCAN test update register, falling edge of clock to valid output 25 ns
tBTUODIS BSCAN test update register, falling edge of clock to valid disable 25 ns
tBTUPOEN BSCAN test update register, falling edge of clock to valid enable 25 ns
Timing v.F0.11
TMS
TDI
TCK
TDO
Data to be
captured
from I/O
Data to be
driven out
to I/O
ataD dilaVataD dilaV
ataD dilaVataD dilaV
Data Captured
t
BTCPH
t
BTCPL
t
BTCOEN
t
BTCRS
t
BTUPOEN
t
BUTCO
t
BTUODIS
t
BTCRH
t
BTCO
t
BTCODIS
t
BTS
t
BTH
t
BTCP
3-28
DC and Switching Characteristics
Lattice Semiconductor LatticeXP Family Data Sheet
Switching Test Conditions
Figure 3-13 shows the output test load that is used for AC testing. The specific values for resistance, capacitance,
voltage, and other test conditions are shown in Figure 3-5.
Figure 3-13. Output Test Load, LVTTL and LVCMOS Standards
Table 3-5. Test Fixture Required Components, Non-Terminated Interfaces
Test Condition R1CLTiming Ref. VT
LVTTL and other LVCMOS settings (L -> H, H -> L) 0pF
LVCMOS 3.3 = 1.5V
LVCMOS 2.5 = VCCIO/2
LVCMOS 1.8 = VCCIO/2
LVCMOS 1.5 = VCCIO/2
LVCMOS 1.2 = VCCIO/2
LVCMOS 2.5 I/O (Z -> H)
188 0pF
VCCIO/2 VOL
LVCMOS 2.5 I/O (Z -> L) VCCIO/2 VOH
LVCMOS 2.5 I/O (H -> Z) VOH - 0.15 VOL
LVCMOS 2.5 I/O (L -> Z) VOL + 0.15 VOH
Note: Output test conditions for all other interfaces are determined by the respective standards.
DUT
VT
R1
CL
Test Poi nt
November 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 4-1 DS1001 Pinouts_02.5
Signal Descriptions
Signal Name I/O Descriptions
General Purpose
P[Edge] [Row/Column Number*]_[A/B] I/O
[Edge] indicates the edge of the device on which the pad is located. Valid
edge designations are L (Left), B (Bottom), R (Right), T (Top).
[Row/Column Number] indicates the PFU row or the column of the device on
which the PIC exists. When Edge is T (Top) or (Bottom), only need to specify
Row Number. When Edge is L (Left) or R (Right), only need to specify Col-
umn Number.
[A/B] indicates the PIO within the PIC to which the pad is connected.
Some of these user programmable pins are shared with special function pins.
These pin when not used as special purpose pins can be programmed as I/
Os for user logic.
During configuration, the user-programmable I/Os are tri-stated with an inter-
nal pull-up resistor enabled. If any pin is not used (or not bonded to a pack-
age pin), it is also tri-stated with an internal pull-up resistor enabled after
configuration.
GSRN I Global RESET signal. (Active low). Any I/O pin can be configured to be
GSRN.
NC No connect.
GND GND - Ground. Dedicated Pins.
VCC VCC - The power supply pins for core logic. Dedicated Pins.
VCCAUX VCCAUX - The Auxiliary power supply pin. It powers all the differential and ref-
erenced input buffers. Dedicated Pins.
VCCP0 Voltage supply pins for ULM0PLL (and LLM1PLL1).
VCCP1 Voltage supply pins for URM0PLL (and LRM1PLL1).
GNDP0 Ground pins for ULM0PLL (and LLM1PLL1).
GNDP1 Ground pins for URM0PLL (and LRM1PLL1).
VCCIOx —V
CCIO - The power supply pins for I/O bank x. Dedicated Pins.
VREF1(x), VREF2(x)
Reference supply pins for I/O bank x. Pre-determined pins in each bank are
assigned as VREF inputs. When not used, they may be used as I/O pins.
PLL and Clock Functions (Used as user programmable I/O pins when not in use for PLL or clock pins)
[LOC][num]_PLL[T, C]_IN_A Reference clock (PLL) input Pads: ULM, LLM, URM, LRM, num = row from
center, T = true and C = complement, index A, B, C...at each side.
[LOC][num]_PLL[T, C]_FB_A Optional feedback (PLL) input Pads: ULM, LLM, URM, LRM, num = row from
center, T = true and C = complement, index A, B, C...at each side.
PCLK[T, C]_[n:0]_[3:0] — Primary Clock Pads, T = true and C = complement, n per side, indexed by
bank and 0,1, 2, 3 within bank.
[LOC]DQS[num] DQS input Pads: T (Top), R (Right), B (Bottom), L (Left), DQS, num = Ball
function number. Any pad can be configured to be DQS output.
LatticeXP Family Data Sheet
Pinout Information
4-2
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Test and Programming (Dedicated pins. Pull-up is enabled on input pins during configuration.)
TMS I Test Mode Select input, used to control the 1149.1 state machine.
TCK I Test Clock input pin, used to clock the 1149.1 state machine.
TDI I
Test Data in pin, used to load data into device using 1149.1 state machine.
After power-up, this TAP port can be activated for configuration by sending
appropriate command. (Note: once a configuration port is selected it is
locked. Another configuration port cannot be selected until the power-up
sequence).
TDO O Output pin -Test Data out pin used to shift data out of device using 1149.1.
VCCJ —V
CCJ - The power supply pin for JTAG Test Access Port.
Configuration Pads (used during sysCONFIG)
CFG[1:0] I Mode pins used to specify configuration modes values latched on rising edge
of INITN. During configuration, a pull-up is enabled.
INITN I/O Open Drain pin - Indicates the FPGA is ready to be configured. During con-
figuration, a pull-up is enabled. If CFG1 and CFG0 are high (SDM) then this
pin is pulled low.
PROGRAMN I Initiates configuration sequence when asserted low. This pin always has an
active pull-up.
DONE I/O Open Drain pin - Indicates that the configuration sequence is complete, and
the startup sequence is in progress.
CCLK I/O Configuration Clock for configuring an FPGA in sysCONFIG mode.
BUSY I/O Generally not used. After configuration it is a user-programmable I/O pin.
CSN I sysCONFIG chip select (Active low). During configuration, a pull-up is
enabled. After configuration it is user a programmable I/O pin.
CS1N I sysCONFIG chip select (Active Low). During configuration, a pull-up is
enabled. After configuration it is user programmable I/O pin
WRITEN I Write Data on Parallel port (Active low). After configuration it is a user pro-
grammable I/O pin
D[7:0] I/O sysCONFIG Port Data I/O. After configuration these are user programmable
I/O pins.
DOUT, CSON O Output for serial configuration data (rising edge of CCLK) when using sys-
CONFIG port. After configuration, it is a user-programmable I/O pin.
DI I Input for serial configuration data (clocked with CCLK) when using sysCON-
FIG port. During configuration, a pull-up is enabled. After configuration it is a
user-programmable I/O pin.
SLEEPN2I
Sleep Mode pin - Active low sleep pin.þ When this pin is held high, the device
operates normally.þ When driven low, the device moves into Sleep Mode
after a specified time.This pin has a weak internal pull-up, but when not used
an external pull-up to VCC is recommended.
TOE3ITest Output Enable tri-states all I/O pins when driven low. This pin has a
weak internal pull-up, but when not used an external pull-up to VCC is recom-
mended.
1. Applies toþ LFXP10, LFXP15 and LFXP20 only.
2. Applies to LFXP “C” devices only.
3. Applies to LFXP “E” devices only.
Signal Descriptions (Cont.)
Signal Name I/O Descriptions
4-3
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
PICs and DDR Data (DQ) Pins Associated with the DDR Strobe (DQS) Pin
PICs Associated
with DQS Strobe PIO within PIC Polarity
DDR Strobe (DQS)
and Data (DQ) Pins
P[Edge] [n-4] ATrueDQ
B Complement DQ
P[Edge] [n-3] ATrueDQ
B Complement DQ
P[Edge] [n-2] ATrueDQ
B Complement DQ
P[Edge] [n-1] ATrueDQ
P[Edge] [n] B Complement DQ
P[Edge] [n+1] A True [Edge]DQSn
B Complement DQ
P[Edge] [n+2] ATrueDQ
B Complement DQ
P[Edge] [n+3] ATrueDQ
B Complement DQ
Notes:
1. “n” is a row/column PIC number.
2. The DDR interface is designed for memories that support one DQS strobe per eight bits of data. In some packages, all the potential DDR
data (DQ) pins may not be available.
3. The definition of the PIC numbering is provided in the Signal Names column of the Signal Descriptions table in this data sheet.
4-4
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Pin Information Summary1
XP3 XP6
Pin Type 100 TQFP 144 TQFP 208 PQFP 144 TQFP 208 PQFP 256 fpBGA
Single Ended User I/O 62 100 136 100 142 188
Differential Pair User I/O219 35 56 35 58 80
Configuration Dedicated 111111111111
Muxed 141414141414
TAP 555555
Dedicated (total without supplies) 666666
VCC 248488
VCCAUX 222224
VCCPLL 222222
VCCIO
Bank0 112122
Bank1 112122
Bank2 112122
Bank3 112122
Bank4 122222
Bank5 112122
Bank6 112122
Bank7 112122
GND 101324132424
GNDPLL 222222
NC 006000
Single Ended/Differential
I/O per Bank2
Bank0 8/2 12/3 20/8 12/3 20/8 26/11
Bank1 9/0 12/2 18/6 12/2 18/6 26/11
Bank2 8/3 12/5 14/6 12/5 17/7 21/9
Bank3 6/2 13/5 14/6 13/5 14/6 21/9
Bank4 5/2 14/6 21/9 14/6 21/9 26/11
Bank5 12/4 12/4 21/9 12/4 21/9 26/11
Bank6 4/2 13/5 14/6 13/5 17/7 21/9
Bank7 10/4 12/5 14/6 12/5 14/6 21/9
VCCJ 111111
1. During configuration the user-programmable I/Os are tri-stated with an internal pull-up resistor enabled. If any pin is not used (or not
bonded to a package pin), it is also tri-stated with an internal pull-up resistor enabled after configuration.
2. The differential I/O per bank includes both dedicated LVDS and emulated LVDS pin pairs. Please see the Logic Signal Connections table
for more information.
4-5
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Pin Information Summary1 (Cont.)
XP10 XP15 XP20
Pin Type 256 fpBGA 388 fpBGA 256 fpBGA 388 fpBGA 484 fpBGA 256 fpBGA 388 fpBGA 484 fpBGA
Single Ended User I/O 188 244 188 268 300 188 268 340
Differential Pair User I/O276 104 76 112 128 76 112 144
Configuration Dedicated1111111111111111
Muxed1414141414141414
TAP 55555555
Dedicated
(total without supplies) 66666666
VCC 8148142881428
VCCAUX 4444124412
VCCPLL 22222222
VCCIO
Bank025254254
Bank125254254
Bank224244244
Bank324244244
Bank425254254
Bank525254254
Bank624244244
Bank724244244
GND 2450245056245056
GNDPLL 22222222
NC 0240 0400 0 0
Single Ended/
Differential I/O
per Bank2
Bank0 26/11 33/14 26/11 39/16 40/17 26/11 39/16 47/20
Bank1 26/11 33/14 26/11 39/16 40/17 26/11 39/16 47/20
Bank2 21/8 28/12 21/8 28/12 35/15 21/8 28/12 38/16
Bank3 21/8 28/12 21/8 28/12 35/15 21/8 28/12 38/16
Bank4 26/11 33/14 26/11 39/16 40/17 26/11 39/16 47/20
Bank5 26/11 33/14 26/11 39/16 40/17 26/11 39/16 47/20
Bank6 21/8 28/12 21/8 28/12 35/15 21/8 28/12 38/16
Bank7 21/8 28/12 21/8 28/12 35/15 21/8 28/12 38/16
VCCJ 11111111
1. During configuration the user-programmable I/Os are tri-stated with an internal pull-up resistor enabled. If any pin is not used (or not bonded
to a package pin), it is also tri-stated with an internal pull-up resistor enabled after configuration.
2. The differential I/O per bank includes both dedicated LVDS and emulated LVDS pin pairs. Please see the Logic Signal Connections table for
more information.
4-6
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Power Supply and NC Connections
Signals 100 TQFP 144 TQFP 208 PQFP 256 fpBGA 388 fpBGA 484 fpBGA
VCC 28, 77 14, 39, 73, 112 19, 35, 53, 80, 107,
151, 158, 182 D4, D13, E5, E12,
M5, M12, N4, N13 H9, J8, J15, K8,
K15, L8, L15, M8,
M15, N8, N15, P8,
P15, R9
F10, F13, G9, G10,
G13, G14, H8,
H15, J7, J16, K6,
K7, K16, K17, N6,
N7, N16, N17, P7,
P16, R8, R15, T9,
T10, T13, T14,
U10, U13
VCCIO0 94 133 189, 199 F7, F8 G8, G9, G10, G11,
H8 F11, G11, H10,
H11
VCCIO1 82 119 167, 177 F9, F10 G12, G13, G14,
G15, H15 F12, G12, H12,
H13
VCCIO2 65 98 140, 149 G11, H11 H16, J16, K16, L16 K15, L15, L16, L17
VCCIO3 58 88 115, 125 J11, K11 M16, N16, P16,
R16 M15, M16, M17,
N15
VCCIO4 47 61, 68 87, 97 L9, L10 R15, T12, T13,
T14, T15 R12, R13, T12,
U12
VCCIO5 38 49 64, 74 L7, L8 R8, T8, T9, T10,
T11 R10, R11, T11,
U11
VCCIO6 22 21 28, 41 J6, K6 M7, N7, P7, R7 M6, M7, M8, N8
VCCIO7 7 8 13, 23 G6, H6 H7, J7, K7, L7 K8, L6, L7, L8
VCCJ 73 108 154 D16 E20 E20
VCCP0 17 19 25 H4 M2 L5
VCCP1 60 91 128 J12 M21 L18
VCCAUX 25, 71 36, 106 50, 152 E4, E13, M4, M13 G7, G16, T7, T16 G7, G8, G15, G16,
H7, H16, R7, R16,
T7, T8, T15, T16
GND110, 18, 21, 33, 43,
44, 52, 59, 68, 84,
90, 99
3, 11, 20, 28, 44,
54, 56, 64, 75, 85,
90, 101, 121, 127,
136
5, 7, 16, 26, 38, 47,
49, 59, 69, 79, 82,
92, 106, 109, 118,
121, 127, 130, 135,
143, 163, 172, 181,
184, 194, 207
A1, A16, F6, F11,
G7, G8, G9, G10,
H5, H7, H8, H9,
H10, J7, J8, J9,
J10, J13, K7, K8,
K9, K10, L6, L11,
T1, T16
A1, A22, H10, H11,
H12, H13, H14, J9,
J10, J11, J12, J13,
J14, K9, K10, K11,
K12, K13, K14, L9,
L10, L11, L12, L13,
L14, M9, M10,
M11, M12, M13,
M14, N1, N9, N10,
N11, N12, N13,
N14, N22, P9, P10,
P11, P12, P13,
P14, R10, R11,
R12, R13, R14,
AB1, AB22
A1, A2, A21, A22,
B1, B22, H9, H14,
J8, J9, J10, J11,
J12, J13, J14, J15,
K9, K10, K11, K12,
K13, K14, L9, L10,
L11, L12, L13, L14,
M9, M10, M11,
M12, M13, M14,
M20, N2, N9, N10,
N11, N12, N13,
N14, P8, P9, P10,
P11, P12, P13,
P14, P15, R9, R14,
AA1, AA22, AB1,
AB2, AB21, AB22
NC2 XP3: 27, 33, 34,
129, 133, 134 XP10: C2, C15,
C16, C17, D4, D5,
D6, D7, D16, D17,
E4, E19, W3, W4,
W7, W17, W18,
W19, W20, Y3,
Y15, Y16, AA1,
AA2
XP15: B21, C4, C5,
C6, C18, C19, C20,
C21, D6, D18, E4,
E6, E18, F6, L1,
L19, L20, M1, M2,
M19, M21, N1,
N21, N22, P1, P2,
U5, U6, U17, U18,
V5, V6, V17, V18,
W17, W18, W19,
Y3, Y4, Y5
1. All grounds must be electrically connected at the board level.
2. NC pins should not be connected to any active signals, VCC or GND.
4-7
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP3 Logic Signal Connections: 100 TQFP
Pin Number Pin Function Bank Differential Dual Function
1CFG10 - -
2DONE0 - -
3PROGRAMN7 - -
4 CCLK 7 - -
5 PL3A 7 T LUM0_PLLT_FB_A
6 PL3B 7 C LUM0_PLLC_FB_A
7 VCCIO7 7 - -
8 PL5A 7 - VREF1_7
9 PL6B 7 - VREF2_7
10 GNDIO7 7 - -
11 PL7A 7 T3DQS
12 PL7B 7 C3-
13 PL8A 7 T LUM0_PLLT_IN_A
14 PL8B 7 C LUM0_PLLC_IN_A
15 PL9A 7 T3-
16 PL9B 7 C3-
17 VCCP0 - - -
18GNDP0---
19 PL12A 6 T PCLKT6_0
20 PL12B 6 C PCLKC6_0
21 GNDIO6 6 - -
22 VCCIO6 6 - -
23 PL18A 6 T3-
24 PL18B 6 C3-
25 VCCAUX - - -
26 SLEEPN1/TOE2---
27 INITN 5 - -
28VCC---
29 PB2B 5 - VREF1_5
30 PB5B 5 - VREF2_5
31 PB8A 5 T -
32 PB8B 5 C -
33 GNDIO5 5 - -
34 PB9A 5 - -
35 PB10B 5 - -
36 PB11A 5 T DQS
37 PB11B 5 C -
38 VCCIO5 5 - -
39 PB12A 5 T -
40 PB12B 5 C -
41 PB13A 5 T -
42 PB13B 5 C -
43GND---
4-8
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
44 GNDIO4 4 - -
45 PB15A 4 T PCLKT4_0
46 PB15B 4 C PCLKC4_0
47 VCCIO4 4 - -
48 PB19A 4 T DQS
49 PB19B 4 C VREF1_4
50 PB24A 4 - VREF2_4
51 PR18B 3 C3-
52 GNDIO3 3 - -
53 PR18A 3 T3-
54 PR15B 3 - VREF1_3
55 PR14A 3 - VREF2_3
56 PR13B 3 C -
57 PR13A 3 T -
58 VCCIO3 3 - -
59GNDP1---
60 VCCP1 - - -
61 PR9B 2 C PCLKC2_0
62 PR9A 2 T PCLKT2_0
63 PR8B 2 C RUM0_PLLC_IN_A
64 PR8A 2 T RUM0_PLLT_IN_A
65 VCCIO2 2 - -
66 PR6B 2 - VREF1_2
67 PR5A 2 - VREF2_2
68 GNDIO2 2 - -
69 PR3B 2 C RUM0_PLLC_FB_A
70 PR3A 2 T RUM0_PLLT_FB_A
71 VCCAUX - - -
72TDO---
73VCCJ---
74TDI---
75TMS---
76TCK---
77VCC---
78 PT24A 1 - -
79 PT23A 1 - D0
80 PT22B 1 - D1
81 PT21A 1 - D2
82 VCCIO1 1 - -
83 PT20B 1 - D3
84 GNDIO1 1 - -
85 PT17A 1 - D4
86 PT16A 1 - D5
87 PT15B 1 - D6
LFXP3 Logic Signal Connections: 100 TQFP (Cont.)
Pin Number Pin Function Bank Differential Dual Function
4-9
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
88 PT14B 1 - D7
89 PT13B 0 C BUSY
90 GNDIO0 0 - -
91 PT13A 0 T CS1N
92 PT12B 0 C PCLKC0_0
93 PT12A 0 T PCLKT0_0
94 VCCIO0 0 - -
95 PT9A 0 - DOUT
96 PT8A 0 - WRITEN
97 PT6A 0 - DI
98 PT5A 0 - CSN
99GND---
100 CFG0 0 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP3 Logic Signal Connections: 100 TQFP (Cont.)
Pin Number Pin Function Bank Differential Dual Function
4-10
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP3 & LFXP6 Logic Signal Connections: 144 TQFP
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
1 PROGRAMN 7 - - PROGRAMN 7 - -
2 CCLK 7 - - CCLK 7 - -
3GND--- GND---
4 PL2A 7 T3- PL2A 7 T3-
5 PL2B 7 C3- PL2B 7 C3-
6 PL3A 7 T LUM0_PLLT_FB_A PL3A 7 T LUM0_PLLT_FB_A
7 PL3B 7 C LUM0_PLLC_FB_A PL3B 7 C LUM0_PLLC_FB_A
8 VCCIO7 7 - - VCCIO7 7 - -
9 PL5A 7 - VREF1_7 PL5A 7 - VREF1_7
10 PL6B 7 - VREF2_7 PL6B 7 - VREF2_7
11 GNDIO7 7 - - GNDIO7 7 - -
12 PL7A 7 T3DQS PL7A 7 T3DQS
13 PL7B 7 C3- PL7B 7 C3-
14 VCC --- VCC---
15 PL8A 7 T LUM0_PLLT_IN_A PL8A 7 T LUM0_PLLT_IN_A
16 PL8B 7 C LUM0_PLLC_IN_A PL8B 7 C LUM0_PLLC_IN_A
17 PL9A 7 T3- PL9A 7 T3-
18 PL9B 7 C3- PL9B 7 C3-
19 VCCP0 - - - VCCP0 - - -
20 GNDP0 - - - GNDP0 - - -
21 VCCIO6 6 - - VCCIO6 6 - -
22 PL11A 6 T3- PL16A 6 T3-
23 PL11B 6 C3- PL16B 6 C3-
24 PL12A 6 T PCLKT6_0 PL17A 6 T PCLKT6_0
25 PL12B 6 C PCLKC6_0 PL17B 6 C PCLKC6_0
26 PL13A 6 T3- PL18A 6 T3-
27 PL13B 6 C3- PL18B 6 C3-
28 GNDIO6 6 - - GNDIO6 6 - -
29 PL14A 6 - VREF1_6 PL22A 6 - VREF1_6
30 PL15B 6 - VREF2_6 PL23B 6 - VREF2_6
31 PL16A 6 T3DQS PL24A 6 T3DQS
32 PL16B 6 C3- PL24B 6 C3-
33 PL17A 6 -- PL25A 6 - -
34 PL18A 6 T3- PL26A 6 T3-
35 PL18B 6 C3- PL26B 6 C3-
36 VCCAUX -- - VCCAUX ---
37 SLEEPN1/TOE2- - - SLEEPN1/TOE2-- -
38 INITN 5 - - INITN 5 - -
39 VCC --- VCC---
40 PB2B 5 - VREF1_5 PB5B 5 - VREF1_5
41 PB5B 5 -VREF2_5 PB8B 5 - VREF2_5
42 PB7A 5 T - PB10A 5 T -
43 PB7B 5 C - PB10B 5 C -
44 GNDIO5 5 - - GNDIO5 5 - -
45 PB9A 5 - - PB12A 5 - -
46 PB10B 5 - - PB13B 5 - -
4-11
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
47 PB11A 5 T DQS PB14A 5 T DQS
48 PB11B 5 C - PB14B 5 C -
49 VCCIO5 5 - - VCCIO5 5 - -
50 PB12A 5 T - PB15A 5 T -
51 PB12B 5 C - PB15B 5 C -
52 PB13A 5 T - PB16A 5 T -
53 PB13B 5 C - PB16B 5 C -
54 GND --- GND---
55 PB14A 4 T - PB17A 4 T -
56 GNDIO4 4 - - GNDIO4 4 - -
57 PB14B 4 C - PB17B 4 C -
58 PB15A 4 T PCLKT4_0 PB18A 4 T PCLKT4_0
59 PB15B 4 C PCLKC4_0 PB18B 4 C PCLKC4_0
60 PB16A 4 T - PB19A 4 T -
61 VCCIO4 4 - - VCCIO4 4 - -
62 PB16B 4 C - PB19B 4 C -
63 PB19A 4 T DQS PB22A 4 T DQS
64 GNDIO4 4 - - GNDIO4 4 - -
65 PB19B 4 C VREF1_4 PB22B 4 C VREF1_4
66 PB20A 4 T - PB23A 4 T -
67 PB20B 4 C - PB23B 4 C -
68 VCCIO4 4 - - VCCIO4 4 - -
69 PB22A 4 --PB25A4- -
70 PB24A 4 T VREF2_4 PB27A 4 T VREF2_4
71 PB24B 4 C - PB27B 4 C -
72 PB25A 4 - - PB28A 4 - -
73 VCC --- VCC---
74 PR18B 3 C3- PR26B 3 C3-
75 GNDIO3 3 - - GNDIO3 3 - -
76 PR18A 3 T3- PR26A 3 T3-
77 PR17B 3 C - PR25B 3 C -
78 PR17A 3 T - PR25A 3 T -
79 PR16B 3 C3- PR24B 3 C3-
80 PR16A 3 T3DQS PR24A 3 T3DQS
81 PR15B 3 - VREF1_3 PR23B 3 - VREF1_3
82 PR14A 3 - VREF2_3 PR22A 3 - VREF2_3
83 PR13B 3 C - PR21B 3 C3-
84 PR13A 3 T - PR21A 3 T3-
85 GND --- GND---
86 PR12A 3 -- PR20A 3 - -
87 PR11B 3 C - PR19B 3 C3-
88 VCCIO3 3 - - VCCIO3 3 - -
89 PR11A 3 T - PR19A 3 T3-
90 GNDP1 - - - GNDP1 - - -
91 VCCP1 - - - VCCP1 - - -
92 PR9B 2 C PCLKC2_0 PR12B 2 C PCLKC2_0
LFXP3 & LFXP6 Logic Signal Connections: 144 TQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-12
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
93 PR9A 2 T PCLKT2_0 PR12A 2 T PCLKT2_0
94 PR8B 2 C RUM0_PLLC_IN_A PR8B 2 C RUM0_PLLC_IN_A
95 PR8A 2 T RUM0_PLLT_IN_A PR8A 2 T RUM0_PLLT_IN_A
96 PR7B 2 C3-PR7B2C
3-
97 PR7A 2 T3DQS PR7A 2 T3DQS
98 VCCIO2 2 - - VCCIO2 2 - -
99 PR6B 2 - VREF1_2 PR6B 2 - VREF1_2
100 PR5A 2 - VREF2_2 PR5A 2 - VREF2_2
101 GNDIO2 2 - - GNDIO2 2 - -
102 PR3B 2 C RUM0_PLLC_FB_A PR3B 2 C RUM0_PLLC_FB_A
103 PR3A 2 T RUM0_PLLT_FB_A PR3A 2 T RUM0_PLLT_FB_A
104 PR2B 2 C3-PR2B2C
3-
105 PR2A 2 T3-PR2A2T
3-
106 VCCAUX -- - VCCAUX ---
107 TDO - - - TDO - - -
108 VCCJ -- - VCCJ ---
109 TDI --- TDI---
110 TMS --- TMS---
111 TCK --- TCK---
112 VCC --- VCC---
113 PT25A 1 - VREF1_1 PT28A 1 - VREF1_1
114 PT24A 1 -- PT27A 1 - -
115 PT23A 1 - D0 PT26A 1 - D0
116 PT22B 1 C D1 PT25B 1 C D1
117 PT22A 1 T VREF2_1 PT25A 1 T VREF2_1
118 PT21A 1 - D2 PT24A 1 - D2
119 VCCIO1 1 - - VCCIO1 1 - -
120 PT20B 1 -D3 PT23B 1 - D3
121 GNDIO1 1 --GNDIO11- -
122 PT17A 1 -D4 PT20A 1 - D4
123 PT16A 1 -D5 PT19A 1 - D5
124 PT15B 1 C D6 PT18B 1 C D6
125 PT15A 1 T - PT18A 1 T -
126 PT14B 1 - D7 PT17B 1 - D7
127 GND --- GND---
128 PT13B 0 C BUSY PT16B 0 C BUSY
129 PT13A 0 T CS1N PT16A 0 T CS1N
130 PT12B 0 C PCLKC0_0 PT15B 0 C PCLKC0_0
131 PT12A 0 T PCLKT0_0 PT15A 0 T PCLKT0_0
132 PT11B 0 C - PT14B 0 C -
133 VCCIO0 0 - - VCCIO0 0 - -
134 PT11A 0 T DQS PT14A 0 T DQS
135 PT9A 0 - DOUT PT12A 0 - DOUT
136 GNDIO0 0 - - GNDIO0 0 - -
137 PT8A 0 - WRITEN PT11A 0 - WRITEN
138 PT7A 0 - VREF1_0 PT10A 0 - VREF1_0
LFXP3 & LFXP6 Logic Signal Connections: 144 TQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-13
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
139 PT6A 0 - DI PT9A 0 - DI
140 PT5A 0 - CSN PT8A 0 - CSN
141 PT3B 0 - VREF2_0 PT6B 0 - VREF2_0
142CFG00- - CFG00- -
143CFG10- - CFG10- -
144 DONE 0 - - DONE 0 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP3 & LFXP6 Logic Signal Connections: 144 TQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-14
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP3 & LFXP6 Logic Signal Connections: 208 PQFP
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
1CFG10- - CFG10- -
2 DONE 0 - - DONE 0 - -
3 PROGRAMN 7 - - PROGRAMN 7 - -
4CCLK7--CCLK7--
5GND --- GND---
6 PL2A 7 T3- PL2A 7 T3-
7 GNDIO7 7 - - GNDIO7 7 - -
8 PL2B 7 C3- PL2B 7 C3-
9 PL3A 7 T LUM0_PLLT_FB_A PL3A 7 T LUM0_PLLT_FB_A
10 PL3B 7 C LUM0_PLLC_FB_A PL3B 7 C LUM0_PLLC_FB_A
11 PL4A 7 T3- PL4A 7 T3-
12 PL4B 7 C3- PL4B 7 C3-
13 VCCIO7 7 - - VCCIO7 7 - -
14 PL5A 7 - VREF1_7 PL5A 7 - VREF1_7
15 PL6B 7 - VREF2_7 PL6B 7 - VREF2_7
16 GNDIO7 7 - - GNDIO7 7 - -
17 PL7A 7 T3DQS PL7A 7 T3DQS
18 PL7B 7 C3- PL7B 7 C3-
19 VCC --- VCC---
20 PL8A 7 T LUM0_PLLT_IN_A PL8A 7 T LUM0_PLLT_IN_A
21 PL8B 7 C LUM0_PLLC_IN_A PL8B 7 C LUM0_PLLC_IN_A
22 PL9A 7 T3- PL9A 7 T3-
23 VCCIO7 7 - - VCCIO7 7 - -
24 PL9B 7 C3- PL9B 7 C3-
25 VCCP0 - - - VCCP0 - - -
26 GNDP0 - - - GNDP0 - - -
27 NC - - - PL15B 6 - -
28 VCCIO6 6 - - VCCIO6 6 - -
29 PL11A 6 T3- PL16A 6 T3-
30 PL11B 6 C3- PL16B 6 C3-
31 PL12A 6 T PCLKT6_0 PL17A 6 T PCLKT6_0
32 PL12B 6 C PCLKC6_0 PL17B 6 C PCLKC6_0
33 NC - - - PL18A 6 T3-
34 NC - - - PL18B 6 C3-
35 VCC --- VCC---
36 PL13A 6 T3- PL21A 6 T3-
37 PL13B 6 C3- PL21B 6 C3-
38 GNDIO6 6 - - GNDIO6 6 - -
39 PL14A 6 - VREF1_6 PL22A 6 - VREF1_6
40 PL15B 6 - VREF2_6 PL23B 6 - VREF2_6
41 VCCIO6 6 - - VCCIO6 6 - -
42 PL16A 6 T3DQS PL24A 6 T3DQS
43 PL16B 6 C3- PL24B 6 C3-
44 PL17A 6 T - PL25A 6 T -
45 PL17B 6 C - PL25B 6 C -
46 PL18A 6 T3- PL26A 6 T3-
4-15
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
47 GNDIO6 6 - - GNDIO6 6 - -
48 PL18B 6 C3- PL26B 6 C3-
49 GND --- GND---
50 VCCAUX ---VCCAUX---
51 SLEEPN1/TOE2- - - SLEEPN1/TOE2-- -
52 INITN 5 - - INITN 5 - -
53 VCC --- VCC---
54 PB2B 5 - VREF1_5 PB5B 5 - VREF1_5
55 PB3A 5 T - PB6A 5 T DQS
56 PB3B 5 C - PB6B 5 C -
57 PB4A 5 T - PB7A 5 T -
58 PB4B 5 C - PB7B 5 C -
59 GNDIO5 5 - - GNDIO5 5 - -
60 PB5A 5 T - PB8A 5 T -
61 PB5B 5 C VREF2_5 PB8B 5 C VREF2_5
62 PB6A 5 T - PB9A 5 T -
63 PB6B 5 C - PB9B 5 C -
64 VCCIO5 5 - - VCCIO5 5 - -
65 PB7A 5 T - PB10A 5 T -
66 PB7B 5 C - PB10B 5 C -
67 PB8A 5 T - PB11A 5 T -
68 PB8B 5 C - PB11B 5 C -
69 GNDIO5 5 - - GNDIO5 5 - -
70 PB9A 5 - - PB12A 5 - -
71 PB10B 5 - - PB13B 5 - -
72 PB11A 5 T DQS PB14A 5 T DQS
73 PB11B 5 C - PB14B 5 C -
74 VCCIO5 5 - - VCCIO5 5 - -
75 PB12A 5 T - PB15A 5 T -
76 PB12B 5 C - PB15B 5 C -
77 PB13A 5 T - PB16A 5 T -
78 PB13B 5 C - PB16B 5 C -
79 GND --- GND---
80 VCC --- VCC---
81 PB14A 4 T - PB17A 4 T -
82 GNDIO4 4 - - GNDIO4 4 - -
83 PB14B 4 C - PB17B 4 C -
84 PB15A 4 T PCLKT4_0 PB18A 4 T PCLKT4_0
85 PB15B 4 C PCLKC4_0 PB18B 4 C PCLKC4_0
86 PB16A 4 T - PB19A 4 T -
87 VCCIO4 4 - - VCCIO4 4 - -
88 PB16B 4 C - PB19B 4 C -
89 PB17A 4 - - PB20A 4 - -
90 PB18B 4 - - PB21B 4 - -
91 PB19A 4 T DQS PB22A 4 T DQS
92 GNDIO4 4 - - GNDIO4 4 - -
LFXP3 & LFXP6 Logic Signal Connections: 208 PQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-16
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
93 PB19B 4 C VREF1_4 PB22B 4 C VREF1_4
94 PB20A 4 T - PB23A 4 T -
95 PB20B 4 C - PB23B 4 C -
96 PB21A 4 T - PB24A 4 T -
97 VCCIO4 4 - - VCCIO4 4 - -
98 PB21B 4 C - PB24B 4 C -
99 PB22A 4 T - PB25A 4 T -
100 PB22B 4 C - PB25B 4 C -
101 PB23A 4 T - PB26A 4 T -
102 PB23B 4 C - PB26B 4 C -
103 PB24A 4 T VREF2_4 PB27A 4 - VREF2_4
104 PB24B 4 C - PB30A 4 T DQS
105 PB25A 4 - - PB30B 4 C -
106 GND --- GND---
107 VCC --- VCC---
108 PR18B 3 C3- PR26B 3 C3-
109 GNDIO3 3 - - GNDIO3 3 - -
110 PR18A 3 T3- PR26A 3 T3-
111 PR17B 3 C - PR25B 3 C -
112 PR17A 3 T - PR25A 3 T -
113 PR16B 3 C3- PR24B 3 C3-
114 PR16A 3 T3DQS PR24A 3 T3DQS
115 VCCIO3 3 - - VCCIO3 3 - -
116 PR15B 3 - VREF1_3 PR23B 3 - VREF1_3
117 PR14A 3 - VREF2_3 PR22A 3 - VREF2_3
118 GNDIO3 3 - - GNDIO3 3 - -
119 PR13B 3 C - PR21B 3 C3-
120 PR13A 3 T - PR21A 3 T3-
121 GND --- GND---
122 PR12B 3 C - PR20B 3 C -
123 PR12A 3 T - PR20A 3 T -
124 PR11B 3 C - PR19B 3 C3-
125 VCCIO3 3 - - VCCIO3 3 - -
126 PR11A 3 T - PR19A 3 T3-
127 GNDP1 - - - GNDP1 - - -
128 VCCP1 - - - VCCP1 - - -
129 NC - - - PR13A 2 - -
130 GND --- GND---
131 PR9B 2 C PCLKC2_0 PR12B 2 C PCLKC2_0
132 PR9A 2 T PCLKT2_0 PR12A 2 T PCLKT2_0
133 NC - - - PR11B 2 C3-
134 NC - - - PR11A 2 T3-
135 GNDIO2 2 - - GNDIO2 2 - -
136 PR8B 2 C RUM0_PLLC_IN_A PR8B 2 C RUM0_PLLC_IN_A
137 PR8A 2 T RUM0_PLLT_IN_A PR8A 2 T RUM0_PLLT_IN_A
138 PR7B 2 C3-PR7B2C
3-
LFXP3 & LFXP6 Logic Signal Connections: 208 PQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-17
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
139 PR7A 2 T3DQS PR7A 2 T3DQS
140 VCCIO2 2 - - VCCIO2 2 - -
141 PR6B 2 - VREF1_2 PR6B 2 - VREF1_2
142 PR5A 2 - VREF2_2 PR5A 2 - VREF2_2
143 GNDIO2 2 - - GNDIO2 2 - -
144 PR4B 2 C3-PR4B2C
3-
145 PR4A 2 T3-PR4A2T
3-
146 PR3B 2 C RUM0_PLLC_FB_A PR3B 2 C RUM0_PLLC_FB_A
147 PR3A 2 T RUM0_PLLT_FB_A PR3A 2 T RUM0_PLLT_FB_A
148 PR2B 2 C3-PR2B2C
3-
149 VCCIO2 2 - - VCCIO2 2 - -
150 PR2A 2 T3-PR2A2T
3-
151 VCC --- VCC---
152 VCCAUX ---VCCAUX---
153TDO-- - TDO-- -
154 VCCJ -- - VCCJ ---
155 TDI --- TDI---
156 TMS --- TMS---
157 TCK --- TCK---
158 VCC --- VCC---
159 PT25A 1 - VREF1_1 PT28A 1 - VREF1_1
160 PT24B 1 C - PT27B 1 C -
161 PT24A 1 T - PT27A 1 T -
162 PT23A 1 - D0 PT26A 1 - D0
163 GNDIO1 1 - - GNDIO1 1 - -
164 PT22B 1 C D1 PT25B 1 C D1
165 PT22A 1 T VREF2_1 PT25A 1 T VREF2_1
166 PT21A 1 - D2 PT24A 1 - D2
167 VCCIO1 1 - - VCCIO1 1 - -
168 PT20B 1 C D3 PT23B 1 C D3
169 PT20A 1 T - PT23A 1 T -
170 PT19B 1 C - PT22B 1 C -
171 PT19A 1 T DQS PT22A 1 T DQS
172 GNDIO1 1 - - GNDIO1 1 - -
173 PT18B 1 - - PT21B 1 - -
174 PT17A 1 - D4 PT20A 1 - D4
175 PT16B 1 C - PT19B 1 C -
176 PT16A 1 T D5 PT19A 1 T D5
177 VCCIO1 1 - - VCCIO1 1 - -
178 PT15B 1 C D6 PT18B 1 C D6
179 PT15A 1 T - PT18A 1 T -
180 PT14B 1 - D7 PT17B 1 - D7
181 GND --- GND---
182 VCC --- VCC---
183 PT13B 0 C BUSY PT16B 0 C BUSY
184 GNDIO0 0 - - GNDIO0 0 - -
LFXP3 & LFXP6 Logic Signal Connections: 208 PQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-18
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
185 PT13A 0 T CS1N PT16A 0 T CS1N
186 PT12B 0 C PCLKC0_0 PT15B 0 C PCLKC0_0
187 PT12A 0 T PCLKT0_0 PT15A 0 T PCLKT0_0
188 PT11B 0 C - PT14B 0 C -
189 VCCIO0 0 - - VCCIO0 0 - -
190 PT11A 0 T DQS PT14A 0 T DQS
191 PT10B 0 - - PT13B 0 - -
192 PT9A 0 - DOUT PT12A 0 - DOUT
193 PT8B 0 C - PT11B 0 C -
194 GNDIO0 0 - - GNDIO0 0 - -
195 PT8A 0 T WRITEN PT11A 0 T WRITEN
196 PT7B 0 C - PT10B 0 C -
197 PT7A 0 T VREF1_0 PT10A 0 T VREF1_0
198 PT6B 0 C - PT9B 0 C -
199 VCCIO0 0 - - VCCIO0 0 - -
200 PT6A 0 T DI PT9A 0 T DI
201 PT5B 0 C - PT8B 0 C -
202 PT5A 0 T CSN PT8A 0 T CSN
203 PT4B 0 C - PT7B 0 C -
204 PT4A 0 T - PT7A 0 T -
205 PT3B 0 - VREF2_0 PT6B 0 - VREF2_0
206 PT2B 0 - - PT5B 0 - -
207 GND --- GND---
208 CFG0 0 - - CFG0 0 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP3 & LFXP6 Logic Signal Connections: 208 PQFP (Cont.)
Pin
Number
LFXP3 LFXP6
Pin Function Bank Differential Dual Function Pin Function Bank Differential Dual Function
4-19
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
C2 PROGRAMN 7 - - PROGRAMN 7 - -
C1 CCLK 7 - - CCLK 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
D2 PL3A 7 T LUM0_PLLT_FB_A PL3A 7 T LUM0_PLLT_FB_A
D3 PL3B 7 C LUM0_PLLC_FB_A PL3B 7 C LUM0_PLLC_FB_A
D1 PL2A 7 T3- PL5A 7 - -
E2 PL5A 7 - VREF1_7 PL6B 7 - VREF1_7
- GNDIO7 7 - - GNDIO7 7 - -
E1 PL7A 7 T3DQS PL7A 7 T3DQS
F1 PL7B 7 C3- PL7B 7 C3-
E3 PL12A 7 T - PL8A 7 T -
F4 PL12B 7 C - PL8B 7 C -
F3 PL4A 7 T3- PL9A 7 T3-
F2 PL4B 7 C3- PL9B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - -
G1 PL2B 7 C3- PL11B 7 - -
G3 PL8A 7 T LUM0_PLLT_IN_A PL12A 7 T LUM0_PLLT_IN_A
G2 PL8B 7 C LUM0_PLLC_IN_A PL12B 7 C LUM0_PLLC_IN_A
H1 PL9A 7 T3- PL13A 7 T3-
H2 PL9B 7 C3- PL13B 7 C3-
G4 PL6B 7 - VREF2_7 PL14A 7 - VREF2_7
G5 PL14A 7 - - PL15B 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
J1 PL11A 7 T3- PL16A 7 T3DQS
J2 PL11B 7 C3- PL16B 7 C3-
H3 PL13A 7 T3- PL18A 7 T3-
J3 PL13B 7 C3- PL18B 7 C3-
H4 VCCP0 - - - VCCP0 - - -
H5 GNDP0 - - - GNDP0 - - -
K1 PL17A 6 T PCLKT6_0 PL20A 6 T PCLKT6_0
K2 PL17B 6 C PCLKC6_0 PL20B 6 C PCLKC6_0
- GNDIO6 6 - - GNDIO6 6 - -
J4 PL15B 6 - - PL22A 6 - -
J5 PL22A 6 - VREF1_6 PL23B 6 - VREF1_6
L1 PL16A 6 T3- PL24A 6 T3DQS
L2 PL16B 6 C3- PL24B 6 C3-
M1 PL18A 6 T3- PL25A 6 T LLM0_PLLT_IN_A
M2 PL18B 6 C3- PL25B 6 C LLM0_PLLC_IN_A
K3 PL19A 6 T3- PL26A 6 T3-
- GNDIO6 6 - - GNDIO6 6 - -
L3 PL19B 6 C3- PL26B 6 C3-
L4 PL21A 6 T3- PL28A 6 - -
4-20
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
K4 PL20A 6 T - PL29A 6 T -
K5 PL20B 6 C - PL29B 6 C -
- GNDIO6 6 - - GNDIO6 6 - -
N1 PL23B 6 - VREF2_6 PL31A 6 - VREF2_6
N2 PL21B 6 C3- PL32B 6 - -
P1 PL24A 6 T3DQS PL33A 6 T3DQS
P2 PL24B 6 C3- PL33B 6 C3-
L5 PL25A 6 T - PL34A 6 T LLM0_PLLT_FB_A
M6 PL25B 6 C - PL34B 6 C LLM0_PLLC_FB_A
M3 PL26A 6 T3- PL35A 6 T3-
- GNDIO6 6 - - GNDIO6 6 - -
N3 PL26B 6 C3- PL35B 6 C3-
P4 SLEEPN1/TOE2- - - SLEEPN1/TOE2-- -
P3 INITN 5 - - INITN 5 - -
- GNDIO5 5 - - GNDIO5 5 - -
R4 PB2A 5 T - PB6A 5 T -
N5 PB2B 5 C - PB6B 5 C -
- GNDIO5 5 - - GNDIO5 5 - -
P5 PB5B 5 - VREF1_5 PB7A 5 T VREF1_5
R1 PB3B 5 C - PB7B 5 C -
N6 PB4A 5 - - PB8A 5 - -
M7 PB3A 5 T - PB9B 5 - -
R2 PB6A 5 T DQS PB10A 5 T DQS
T2 PB6B 5 C - PB10B 5 C -
R3 PB7A 5 T - PB11A 5 T -
T3 PB7B 5 C - PB11B 5 C -
- GNDIO5 5 - - GNDIO5 5 - -
T4 PB8A 5 T - PB12A 5 T -
R5 PB8B 5 C VREF2_5 PB12B 5 C VREF2_5
N7 PB9A 5 T - PB13A 5 T -
M8 PB9B 5 C - PB13B 5 C -
T5PB10A5T - PB14A5T -
P6 PB10B 5 C - PB14B 5 C -
T6PB11A5T - PB15A5T -
R6 PB11B 5 C - PB15B 5 C -
- GNDIO5 5 - - GNDIO5 5 - -
P7 PB12A 5 - - PB16A 5 - -
N8 PB13B 5 - - PB17B 5 - -
R7 PB14A 5 T DQS PB18A 5 T DQS
T7 PB14B 5 C - PB18B 5 C -
P8 PB15A 5 T - PB19A 5 T -
T8 PB15B 5 C - PB19B 5 C -
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-21
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
R8PB16A5T - PB20A5T -
T9 PB16B 5 C - PB20B 5 C -
R9PB17A4T - PB21A4T -
- GNDIO4 4 - - GNDIO4 4 - -
P9 PB17B 4 C - PB21B 4 C -
T10 PB18A 4 T PCLKT4_0 PB22A 4 T PCLKT4_0
T11 PB18B 4 C PCLKC4_0 PB22B 4 C PCLKC4_0
R10PB19A4T - PB23A4T -
P10 PB19B 4 C - PB23B 4 C -
N9 PB20A 4 - - PB24A 4 - -
M9 PB21B 4 - - PB25B 4 - -
R12 PB22A 4 T DQS PB26A 4 T DQS
- GNDIO4 4 - - GNDIO4 4 - -
T12 PB22B 4 C VREF1_4 PB26B 4 C VREF1_4
P13 PB23A 4 T - PB27A 4 T -
R13 PB23B 4 C - PB27B 4 C -
M11PB24A4T - PB28A4T -
N11 PB24B 4 C - PB28B 4 C -
N10PB25A4T - PB29A4T -
M10 PB25B 4 C - PB29B 4 C -
T13PB26A4T - PB30A4T -
- GNDIO4 4 - - GNDIO4 4 - -
P14 PB26B 4 C - PB30B 4 C -
R11 PB27A 4 T VREF2_4 PB31A 4 T VREF2_4
P12 PB27B 4 C - PB31B 4 C -
T14 PB28A 4 - - PB32A 4 - -
R14 PB29B 4 - - PB33B 4 - -
P11 PB30A 4 T DQS PB34A 4 T DQS
N12 PB30B 4 C - PB34B 4 C -
T15PB31A4T - PB35A4T -
- GNDIO4 4 - - GNDIO4 4 - -
R15 PB31B 4 C - PB35B 4 C -
- GNDIO3 3 - - GNDIO3 3 - -
P15 PR26B 3 C3- PR34B 3 C RLM0_PLLC_FB_A
N15 PR26A 3 T3- PR34A 3 T RLM0_PLLT_FB_A
P16 PR24B 3 C3- PR33B 3 C3-
R16 PR24A 3 T3DQS PR33A 3 T3DQS
M15 PR15B 3 - - PR32B 3 - -
N14 PR23B 3 - VREF1_3 PR31A 3 - VREF1_3
- GNDIO3 3 - - GNDIO3 3 - -
M14 PR25B 3 C - PR29B 3 C -
L13 PR25A 3 T - PR29A 3 T -
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-22
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
L15 PR21B 3 C3- PR28B 3 C3-
L14 PR21A 3 T3- PR28A 3 T3-
- GNDIO3 3 - - GNDIO3 3 - -
L12 PR17B 3 C - PR26A 3 - -
M16 PR20B 3 C - PR25B 3 C RLM0_PLLC_IN_A
N16 PR20A 3 T - PR25A 3 T RLM0_PLLT_IN_A
K14 PR19B 3 C3- PR24B 3 C3-
K15 PR19A 3 T3- PR24A 3 T3DQS
K12 PR17A 3 T - PR23B 3 - -
K13 PR22A 3 - VREF2_3 PR22A 3 - VREF2_3
- GNDIO3 3 - - GNDIO3 3 - -
L16 PR18B 3 C3- PR21B 3 C3-
K16 PR18A 3 T3- PR21A 3 T3-
J15 PR16B 3 C3- PR19B 3 C3-
J14 PR16A 3 T3- PR19A 3 T3-
J13 GNDP1 - - - GNDP1 - - -
J12 VCCP1 - - - VCCP1 - - -
- GNDIO2 2 - - GNDIO2 2 - -
J16 PR12B 2 C PCLKC2_0 PR17B 2 C PCLKC2_0
H16 PR12A 2 T PCLKT2_0 PR17A 2 T PCLKT2_0
H13 PR13B 2 C3- PR16B 2 C3-
H12 PR13A 2 T3- PR16A 2 T3DQS
H15 PR2B 2 C3- PR15B 2 - -
H14 PR6B 2 - VREF1_2 PR14A 2 - VREF1_2
- GNDIO2 2 - - GNDIO2 2 - -
G15 PR11B 2 C3- PR13B 2 C3-
G14 PR11A 2 T3- PR13A 2 T3-
G16 PR8B 2 C RUM0_PLLC_IN_A PR12B 2 C RUM0_PLLC_IN_A
F16 PR8A 2 T RUM0_PLLT_IN_A PR12A 2 T RUM0_PLLT_IN_A
G13 PR2A 2 T3- PR11B 2 - -
- GNDIO2 2 - - GNDIO2 2 - -
G12 PR9B 2 C3-PR8B2C-
F13 PR9A 2 T3-PR8A2T-
B16 PR7B 2 C3-PR7B2C
3-
C16 PR7A 2 T3DQS PR7A 2 T3DQS
F15 PR14A 2 - - PR6B 2 - -
E15 PR5A 2 - VREF2_2 PR5A 2 - VREF2_2
- GNDIO2 2 - - GNDIO2 2 - -
F14 PR4B 2 C3-PR4B2C
3-
E14 PR4A 2 T3-PR4A2T
3-
D15 PR3B 2 C RUM0_PLLC_FB_A PR3B 2 C RUM0_PLLC_FB_A
C15 PR3A 2 T RUM0_PLLT_FB_A PR3A 2 T RUM0_PLLT_FB_A
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-23
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
E16 TDO - - - TDO - - -
D16 VCCJ - - - VCCJ - - -
D14 TDI - - - TDI - - -
C14 TMS - - - TMS - - -
B14 TCK - - - TCK - - -
- GNDIO1 1 - - GNDIO1 1 - -
A15 PT31B 1 C - PT35B 1 C -
B15 PT31A 1 T - PT35A 1 T -
- GNDIO1 1 - - GNDIO1 1 - -
D12 PT28A 1 - VREF1_1 PT34B 1 C VREF1_1
C11 PT30A 1 T DQS PT34A 1 T DQS
A14 PT29B 1 - - PT33B 1 - -
B13 PT30B 1 C - PT32A 1 - -
F12 PT27B 1 C - PT31B 1 C -
E11 PT27A 1 T - PT31A 1 T -
A13 PT26B 1 C - PT30B 1 C -
C13 PT26A 1 T D0 PT30A 1 T D0
- GNDIO1 1 - - GNDIO1 1 - -
C10 PT25B 1 C D1 PT29B 1 C D1
E10 PT25A 1 T VREF2_1 PT29A 1 T VREF2_1
A12 PT24B 1 C - PT28B 1 C -
B12 PT24A 1 T D2 PT28A 1 T D2
C12 PT23B 1 C D3 PT27B 1 C D3
A11 PT23A 1 T - PT27A 1 T -
B11 PT22B 1 C - PT26B 1 C -
D11 PT22A 1 T DQS PT26A 1 T DQS
- GNDIO1 1 - - GNDIO1 1 - -
B9 PT21B 1 - - PT25B 1 - -
D9 PT20A 1 - D4 PT24A 1 - D4
A10 PT19B 1 C - PT23B 1 C -
B10 PT19A 1 T D5 PT23A 1 T D5
D10 PT18B 1 C D6 PT22B 1 C D6
A9 PT18A 1 T - PT22A 1 T -
C9 PT17B 1 C D7 PT21B 1 C D7
C8 PT17A 1 T - PT21A 1 T -
E9 PT16B 0 C BUSY PT20B 0 C BUSY
- GNDIO0 0 - - GNDIO0 0 - -
B8 PT16A 0 T CS1N PT20A 0 T CS1N
A8 PT15B 0 C PCLKC0_0 PT19B 0 C PCLKC0_0
A7 PT15A 0 T PCLKT0_0 PT19A 0 T PCLKT0_0
B7 PT14B 0 C - PT18B 0 C -
C7 PT14A 0 T DQS PT18A 0 T DQS
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-24
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
E8 PT13B 0 - - PT17B 0 - -
D8 PT12A 0 - DOUT PT16A 0 - DOUT
A6 PT11B 0 C - PT15B 0 C -
- GNDIO0 0 - - GNDIO0 0 - -
C6 PT11A 0 T WRITEN PT15A 0 T WRITEN
E7 PT10B 0 C - PT14B 0 C -
D7 PT10A 0 T VREF1_0 PT14A 0 T VREF1_0
A5 PT9B 0 C - PT13B 0 C -
B5 PT9A 0 T DI PT13A 0 T DI
A4 PT8B 0 C - PT12B 0 C -
B6 PT8A 0 T CSN PT12A 0 T CSN
E6 PT7B 0 C - PT11B 0 C -
- GNDIO0 0 - - GNDIO0 0 - -
D6 PT7A 0 T - PT11A 0 T -
D5 PT6B 0 C VREF2_0 PT10B 0 C VREF2_0
A3 PT6A 0 T DQS PT10A 0 T DQS
B3 PT5B 0 - - PT9B 0 - -
B2 PT4A 0 - - PT8A 0 - -
A2 PT3B 0 C - PT7B 0 C -
B1 PT3A 0 T - PT7A 0 T -
F5 PT2B 0 C - PT6B 0 C -
- GNDIO0 0 - - GNDIO0 0 - -
C5 PT2A 0 T - PT6A 0 T -
C4 CFG0 0 - - CFG0 0 - -
B4 CFG1 0 - - CFG1 0 - -
C3 DONE 0 - - DONE 0 - -
A1 GND - - - GND - - -
A16 GND - - - GND - - -
F11 GND - - - GND - - -
F6 GND - - - GND - - -
G10 GND - - - GND - - -
G7 GND - - - GND - - -
G8 GND - - - GND - - -
G9 GND - - - GND - - -
H10 GND - - - GND - - -
H7 GND - - - GND - - -
H8 GND - - - GND - - -
H9 GND - - - GND - - -
J10 GND - - - GND - - -
J7 GND - - - GND - - -
J8 GND - - - GND - - -
J9 GND - - - GND - - -
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-25
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
K10 GND - - - GND - - -
K7 GND - - - GND - - -
K8 GND - - - GND - - -
K9 GND - - - GND - - -
L11 GND - - - GND - - -
L6 GND - - - GND - - -
T1 GND - - - GND - - -
T16 GND - - - GND - - -
D13 VCC - - - VCC - - -
D4 VCC - - - VCC - - -
E12 VCC - - - VCC - - -
E5 VCC - - - VCC - - -
M12 VCC - - - VCC - - -
M5 VCC - - - VCC - - -
N13 VCC - - - VCC - - -
N4 VCC - - - VCC - - -
E13 VCCAUX - - - VCCAUX - - -
E4 VCCAUX - - - VCCAUX - - -
M13 VCCAUX - - - VCCAUX - - -
M4 VCCAUX - - - VCCAUX - - -
F7 VCCIO0 0 - - VCCIO0 0 - -
F8 VCCIO0 0 - - VCCIO0 0 - -
F10 VCCIO1 1 - - VCCIO1 1 - -
F9 VCCIO1 1 - - VCCIO1 1 - -
G11 VCCIO2 2 - - VCCIO2 2 - -
H11 VCCIO2 2 - - VCCIO2 2 - -
J11 VCCIO3 3 - - VCCIO3 3 - -
K11 VCCIO3 3 - - VCCIO3 3 - -
L10 VCCIO4 4 - - VCCIO4 4 - -
L9 VCCIO4 4 - - VCCIO4 4 - -
L7 VCCIO5 5 - - VCCIO5 5 - -
L8 VCCIO5 5 - - VCCIO5 5 - -
J6 VCCIO6 6 - - VCCIO6 6 - -
K6 VCCIO6 6 - - VCCIO6 6 - -
G6 VCCIO7 7 - - VCCIO7 7 - -
H6 VCCIO7 7 - - VCCIO7 7 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP6 & LFXP10 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP6 LFXP10
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-26
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
C2 PROGRAMN 7 - - PROGRAMN 7 - -
C1 CCLK 7 - - CCLK 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
D2 PL7A 7 T LUM0_PLLT_FB_A PL7A 7 T LUM0_PLLT_FB_A
D3 PL7B 7 C LUM0_PLLC_FB_A PL7B 7 C LUM0_PLLC_FB_A
D1PL9A7- - PL9A7- -
E2 PL10B 7 - VREF1_7 PL10B 7 - VREF1_7
E1 PL11A 7 T3DQS PL11A 7 T3DQS
F1 PL11B 7 C3- PL11B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - -
E3 PL12A 7 T - PL12A 7 T -
F4 PL12B 7 C - PL12B 7 C -
F3 PL13A 7 T3- PL13A 7 T3-
F2 PL13B 7 C3- PL13B 7 C3-
G1 PL15B 7 - - PL15B 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
G3 PL16A 7 T LUM0_PLLT_IN_A PL16A 7 T LUM0_PLLT_IN_A
G2 PL16B 7 C LUM0_PLLC_IN_A PL16B 7 C LUM0_PLLC_IN_A
H1 PL17A 7 T3- PL17A 7 T3-
H2 PL17B 7 C3- PL17B 7 C3-
G4 PL18A 7 - VREF2_7 PL18A 7 - VREF2_7
G5 PL19B 7 - - PL19B 7 - -
J1 PL20A 7 T3DQS PL20A 7 T3DQS
- GNDIO7 7 - - GNDIO7 7 - -
J2 PL20B 7 C3- PL20B 7 C3-
H3 PL22A 7 T3- PL22A 7 T3-
J3 PL22B 7 C3- PL22B 7 C3-
H4 VCCP0 - - - VCCP0 - - -
H5 GNDP0 - - - GNDP0 - - -
K1 PL24A 6 T PCLKT6_0 PL28A 6 T PCLKT6_0
- GNDIO6 6 - - GNDIO6 6 - -
K2 PL24B 6 C PCLKC6_0 PL28B 6 C PCLKC6_0
J4 PL26A 6 - - PL30A 6 - -
J5 PL27B 6 - VREF1_6 PL31B 6 - VREF1_6
L1 PL28A 6 T3DQS PL32A 6 T3DQS
L2 PL28B 6 C3- PL32B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
M1 PL29A 6 T LLM0_PLLT_IN_A PL33A 6 T LLM0_PLLT_IN_A
M2 PL29B 6 C LLM0_PLLC_IN_A PL33B 6 C LLM0_PLLC_IN_A
K3 PL30A 6 T3- PL34A 6 T3-
L3 PL30B 6 C3- PL34B 6 C3-
4-27
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
L4 PL32A 6 - - PL36A 6 - -
- GNDIO6 6 - - GNDIO6 6 - -
K4 PL33A 6 T - PL37A 6 T -
K5 PL33B 6 C - PL37B 6 C -
N1 PL35A 6 - VREF2_6 PL39A 6 - VREF2_6
N2 PL36B 6 - - PL40B 6 - -
P1 PL37A 6 T3DQS PL41A 6 T3DQS
P2 PL37B 6 C3- PL41B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
L5 PL38A 6 T LLM0_PLLT_FB_A PL42A 6 T LLM0_PLLT_FB_A
M6 PL38B 6 C LLM0_PLLC_FB_A PL42B 6 C LLM0_PLLC_FB_A
M3 PL39A 6 T3- PL43A 6 T3-
N3 PL39B 6 C3- PL43B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
P4 SLEEPN1/TOE2- - - SLEEPN1/TOE2-- -
P3 INITN 5 - - INITN 5 - -
- GNDIO5 5 - - GNDIO5 5 - -
- GNDIO5 5 - - GNDIO5 5 - -
- GNDIO5 5 - - GNDIO5 5 - -
R4 PB11A 5 T - PB15A 5 T -
N5 PB11B 5 C - PB15B 5 C -
P5 PB12A 5 T VREF1_5 PB16A 5 T VREF1_5
- GNDIO5 5 - - GNDIO5 5 - -
R1 PB12B 5 C - PB16B 5 C -
N6 PB13A 5 - - PB17A 5 - -
M7 PB14B 5 - - PB18B 5 - -
R2 PB15A 5 T DQS PB19A 5 T DQS
T2 PB15B 5 C - PB19B 5 C -
R3 PB16A 5 T - PB20A 5 T -
T3 PB16B 5 C - PB20B 5 C -
T4 PB17A 5 T - PB21A 5 T -
R5 PB17B 5 C VREF2_5 PB21B 5 C VREF2_5
N7 PB18A 5 T - PB22A 5 T -
- GNDIO5 5 - - GNDIO5 5 - -
M8 PB18B 5 C - PB22B 5 C -
T5 PB19A 5 T - PB23A 5 T -
P6 PB19B 5 C - PB23B 5 C -
T6 PB20A 5 T - PB24A 5 T -
R6 PB20B 5 C - PB24B 5 C -
P7 PB21A 5 - - PB25A 5 - -
N8 PB22B 5 - - PB26B 5 - -
R7 PB23A 5 T DQS PB27A 5 T DQS
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-28
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
T7 PB23B 5 C - PB27B 5 C -
- GNDIO5 5 - - GNDIO5 5 - -
P8 PB24A 5 T - PB28A 5 T -
T8 PB24B 5 C - PB28B 5 C -
R8 PB25A 5 T - PB29A 5 T -
T9 PB25B 5 C - PB29B 5 C -
R9 PB26A 4 T - PB30A 4 T -
P9 PB26B 4 C - PB30B 4 C -
T10 PB27A 4 T PCLKT4_0 PB31A 4 T PCLKT4_0
T11 PB27B 4 C PCLKC4_0 PB31B 4 C PCLKC4_0
- GNDIO4 4 - - GNDIO4 4 - -
R10 PB28A 4 T - PB32A 4 T -
P10 PB28B 4 C - PB32B 4 C -
N9 PB29A 4 - - PB33A 4 - -
M9 PB30B 4 - - PB34B 4 - -
R12 PB31A 4 T DQS PB35A 4 T DQS
T12 PB31B 4 C VREF1_4 PB35B 4 C VREF1_4
P13 PB32A 4 T - PB36A 4 T -
R13 PB32B 4 C - PB36B 4 C -
M11 PB33A 4 T - PB37A 4 T -
- GNDIO4 4 - - GNDIO4 4 - -
N11 PB33B 4 C - PB37B 4 C -
N10 PB34A 4 T - PB38A 4 T -
M10 PB34B 4 C - PB38B 4 C -
T13 PB35A 4 T - PB39A 4 T -
P14 PB35B 4 C - PB39B 4 C -
R11 PB36A 4 T VREF2_4 PB40A 4 T VREF2_4
P12 PB36B 4 C - PB40B 4 C -
T14 PB37A 4 - - PB41A 4 - -
R14 PB38B 4 - - PB42B 4 - -
- GNDIO4 4 - - GNDIO4 4 - -
P11 PB39A 4 T DQS PB43A 4 T DQS
N12 PB39B 4 C - PB43B 4 C -
T15 PB40A 4 T - PB44A 4 T -
R15 PB40B 4 C - PB44B 4 C -
- GNDIO4 4 - - GNDIO4 4 - -
- GNDIO4 4 - - GNDIO4 4 - -
- GNDIO4 4 - - GNDIO4 4 - -
- GNDIO3 3 - - GNDIO3 3 - -
- GNDIO3 3 - - GNDIO3 3 - -
P15 PR38B 3 C RLM0_PLLC_FB_A PR42B 3 C RLM0_PLLC_FB_A
N15 PR38A 3 T RLM0_PLLT_FB_A PR42A 3 T RLM0_PLLT_FB_A
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-29
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
P16 PR37B 3 C3- PR41B 3 C3-
R16 PR37A 3 T3DQS PR41A 3 T3DQS
M15 PR36B 3 - - PR40B 3 - -
N14 PR35A 3 - VREF1_3 PR39A 3 - VREF1_3
- GNDIO3 3 - - GNDIO3 3 - -
M14 PR33B 3 C - PR37B 3 C -
L13 PR33A 3 T - PR37A 3 T -
L15 PR32B 3 C3- PR36B 3 C3-
L14 PR32A 3 T3- PR36A 3 T3-
L12 PR30A 3 - - PR34A 3 - -
M16 PR29B 3 C RLM0_PLLC_IN_A PR33B 3 C RLM0_PLLC_IN_A
N16 PR29A 3 T RLM0_PLLT_IN_A PR33A 3 T RLM0_PLLT_IN_A
- GNDIO3 3 - - GNDIO3 3 - -
K14 PR28B 3 C3- PR32B 3 C3-
K15 PR28A 3 T3DQS PR32A 3 T3DQS
K12 PR27B 3 - - PR31B 3 - -
K13 PR26A 3 - VREF2_3 PR30A 3 - VREF2_3
L16 PR25B 3 C3- PR29B 3 C3-
K16 PR25A 3 T3- PR29A 3 T3-
- GNDIO3 3 - - GNDIO3 3 - -
J15 PR23B 3 C3- PR27B 3 C3-
J14 PR23A 3 T3- PR27A 3 T3-
J13 GNDP1 - - - GNDP1 - - -
J12VCCP1---VCCP1---
- GNDIO2 2 - - GNDIO2 2 - -
J16 PR21B 2 C PCLKC2_0 PR21B 2 C PCLKC2_0
H16 PR21A 2 T PCLKT2_0 PR21A 2 T PCLKT2_0
H13 PR20B 2 C3- PR20B 2 C3-
H12 PR20A 2 T3DQS PR20A 2 T3DQS
H15 PR19B 2 - - PR19B 2 - -
H14 PR18A 2 - VREF1_2 PR18A 2 - VREF1_2
- GNDIO2 2 - - GNDIO2 2 - -
G15 PR17B 2 C3- PR17B 2 C3-
G14 PR17A 2 T3- PR17A 2 T3-
G16 PR16B 2 C RUM0_PLLC_IN_A PR16B 2 C RUM0_PLLC_IN_A
F16 PR16A 2 T RUM0_PLLT_IN_A PR16A 2 T RUM0_PLLT_IN_A
G13 PR15B 2 - - PR15B 2 - -
- GNDIO2 2 - - GNDIO2 2 - -
G12 PR12B 2 C - PR12B 2 C -
F13 PR12A 2 T - PR12A 2 T -
B16 PR11B 2 C3- PR11B 2 C3-
C16 PR11A 2 T3DQS PR11A 2 T3DQS
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-30
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
- GNDIO2 2 - - GNDIO2 2 - -
F15 PR10B 2 - - PR10B 2 - -
E15 PR9A 2 - VREF2_2 PR9A 2 - VREF2_2
F14 PR8B 2 C3-PR8B2C
3-
E14 PR8A 2 T3-PR8A2T
3-
D15 PR7B 2 C RUM0_PLLC_FB_A PR7B 2 C RUM0_PLLC_FB_A
C15 PR7A 2 T RUM0_PLLT_FB_A PR7A 2 T RUM0_PLLT_FB_A
- GNDIO2 2 - - GNDIO2 2 - -
E16TDO-- - TDO-- -
D16 VCCJ - - - VCCJ - - -
D14 TDI - - - TDI - - -
C14 TMS - - - TMS - - -
B14 TCK - - - TCK - - -
- GNDIO1 1 - - GNDIO1 1 - -
- GNDIO1 1 - - GNDIO1 1 - -
- GNDIO1 1 - - GNDIO1 1 - -
A15 PT40B 1 C - PT44B 1 C -
B15 PT40A 1 T - PT44A 1 T -
D12 PT39B 1 C VREF1_1 PT43B 1 C VREF1_1
- GNDIO1 1 - - GNDIO1 1 - -
C11 PT39A 1 T DQS PT43A 1 T DQS
A14 PT38B 1 - - PT42B 1 - -
B13 PT37A 1 - - PT41A 1 - -
F12 PT36B 1 C - PT40B 1 C -
E11 PT36A 1 T - PT40A 1 T -
A13 PT35B 1 C - PT39B 1 C -
C13 PT35A 1 T D0 PT39A 1 T D0
C10 PT34B 1 C D1 PT38B 1 C D1
E10 PT34A 1 T VREF2_1 PT38A 1 T VREF2_1
A12 PT33B 1 C - PT37B 1 C -
B12 PT33A 1 T D2 PT37A 1 T D2
- GNDIO1 1 - - GNDIO1 1 - -
C12 PT32B 1 C D3 PT36B 1 C D3
A11 PT32A 1 T - PT36A 1 T -
B11 PT31B 1 C - PT35B 1 C -
D11 PT31A 1 T DQS PT35A 1 T DQS
B9 PT30B 1 - - PT34B 1 - -
D9 PT29A 1 - D4 PT33A 1 - D4
A10 PT28B 1 C - PT32B 1 C -
B10 PT28A 1 T D5 PT32A 1 T D5
- GNDIO1 1 - - GNDIO1 1 - -
D10 PT27B 1 C D6 PT31B 1 C D6
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-31
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
A9 PT27A 1 T - PT31A 1 T -
C9 PT26B 1 C D7 PT30B 1 C D7
C8 PT26A 1 T - PT30A 1 T -
E9 PT25B 0 C BUSY PT29B 0 C BUSY
- GNDIO0 0 - - GNDIO0 0 - -
B8 PT25A 0 T CS1N PT29A 0 T CS1N
A8 PT24B 0 C PCLKC0_0 PT28B 0 C PCLKC0_0
A7 PT24A 0 T PCLKT0_0 PT28A 0 T PCLKT0_0
B7 PT23B 0 C - PT27B 0 C -
C7 PT23A 0 T DQS PT27A 0 T DQS
E8 PT22B 0 - - PT26B 0 - -
D8 PT21A 0 - DOUT PT25A 0 - DOUT
A6 PT20B 0 C - PT24B 0 C -
- GNDIO0 0 - - GNDIO0 0 - -
C6 PT20A 0 T WRITEN PT24A 0 T WRITEN
E7 PT19B 0 C - PT23B 0 C -
D7 PT19A 0 T VREF1_0 PT23A 0 T VREF1_0
A5 PT18B 0 C - PT22B 0 C -
B5 PT18A 0 T DI PT22A 0 T DI
A4 PT17B 0 C - PT21B 0 C -
B6 PT17A 0 T CSN PT21A 0 T CSN
E6 PT16B 0 C - PT20B 0 C -
D6 PT16A 0 T - PT20A 0 T -
D5 PT15B 0 C VREF2_0 PT19B 0 C VREF2_0
A3 PT15A 0 T DQS PT19A 0 T DQS
B3 PT14B 0 - - PT18B 0 - -
B2 PT13A 0 - - PT17A 0 - -
- GNDIO0 0 - - GNDIO0 0 - -
A2 PT12B 0 C - PT16B 0 C -
B1 PT12A 0 T - PT16A 0 T -
F5 PT11B 0 C - PT15B 0 C -
C5 PT11A 0 T - PT15A 0 T -
- GNDIO0 0 - - GNDIO0 0 - -
- GNDIO0 0 - - GNDIO0 0 - -
- GNDIO0 0 - - GNDIO0 0 - -
C4 CFG0 0 - - CFG0 0 - -
B4 CFG1 0 - - CFG1 0 - -
C3 DONE 0 - - DONE 0 - -
A1GND---GND---
A16 GND - - - GND - - -
F11 GND - - - GND - - -
F6GND---GND---
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-32
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
G10 GND - - - GND - - -
G7 GND - - - GND - - -
G8 GND - - - GND - - -
G9 GND - - - GND - - -
H10 GND - - - GND - - -
H7GND---GND---
H8GND---GND---
H9GND---GND---
J10 GND - - - GND - - -
J7GND---GND---
J8GND---GND---
J9GND---GND---
K10 GND - - - GND - - -
K7GND---GND---
K8GND---GND---
K9GND---GND---
L11 GND - - - GND - - -
L6GND---GND---
T1GND---GND---
T16 GND - - - GND - - -
D13 VCC - - - VCC - - -
D4 VCC - - - VCC - - -
E12 VCC - - - VCC - - -
E5 VCC - - - VCC - - -
M12 VCC - - - VCC - - -
M5 VCC - - - VCC - - -
N13 VCC - - - VCC - - -
N4 VCC - - - VCC - - -
E13 VCCAUX - - - VCCAUX - - -
E4 VCCAUX - - - VCCAUX - - -
M13 VCCAUX - - - VCCAUX - - -
M4 VCCAUX - - - VCCAUX - - -
F7 VCCIO0 0 - - VCCIO0 0 - -
F8 VCCIO0 0 - - VCCIO0 0 - -
F10 VCCIO1 1 - - VCCIO1 1 - -
F9 VCCIO1 1 - - VCCIO1 1 - -
G11 VCCIO2 2 - - VCCIO2 2 - -
H11 VCCIO2 2 - - VCCIO2 2 - -
J11 VCCIO3 3 - - VCCIO3 3 - -
K11 VCCIO3 3 - - VCCIO3 3 - -
L10 VCCIO4 4 - - VCCIO4 4 - -
L9 VCCIO4 4 - - VCCIO4 4 - -
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-33
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
L7 VCCIO5 5 - - VCCIO5 5 - -
L8 VCCIO5 5 - - VCCIO5 5 - -
J6 VCCIO6 6 - - VCCIO6 6 - -
K6 VCCIO6 6 - - VCCIO6 6 - -
G6 VCCIO7 7 - - VCCIO7 7 - -
H6 VCCIO7 7 - - VCCIO7 7 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP15 & LFXP20 Logic Signal Connections: 256 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-34
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
F4 PROGRAMN 7 - - PROGRAMN 7 - - PROGRAMN 7 - -
G4 CCLK 7 - - CCLK 7 - - CCLK 7 - -
- GNDIO7 7 - - GNDIO7 7 - - GNDIO7 7 - -
D2 PL2A 7 T3-PL6A7T
3- PL6A 7 T3-
D1 PL2B 7 C3-PL6B7C
3- PL6B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - - GNDIO7 7 - -
E2 PL3A 7 T LUM0_PLLT_FB_A PL7A 7 T LUM0_PLLT_FB_A PL7A 7 T LUM0_PLLT_FB_A
E3 PL3B 7 C LUM0_PLLC_FB_A PL7B 7 C LUM0_PLLC_FB_A PL7B 7 C LUM0_PLLC_FB_A
F3 PL4A 7 T3-PL8A7T
3- PL8A 7 T3-
F2 PL4B 7 C3-PL8B7C
3- PL8B 7 C3-
H4 PL5A 7 - - PL9A 7 - - PL9A 7 - -
H3 PL6B 7 - VREF1_7 PL10B 7 - VREF1_7 PL10B 7 - VREF1_7
G3 PL7A 7 T3DQS PL11A 7 T3DQS PL11A 7 T3DQS
G2 PL7B 7 C3- PL11B 7 C3- PL11B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - - GNDIO7 7 - -
F1 PL8A 7 T - PL12A 7 T - PL12A 7 T -
E1 PL8B 7 C - PL12B 7 C - PL12B 7 C -
J4 PL9A 7 T3- PL13A 7 T3- PL13A 7 T3-
K4 PL9B 7 C3- PL13B 7 C3- PL13B 7 C3-
G1 PL11A 7 T3- PL15A 7 T3- PL15A 7 T3-
H2 PL11B 7 C3- PL15B 7 C3- PL15B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - - GNDIO7 7 - -
J2 PL12A 7 T LUM0_PLLT_IN_A PL16A 7 T LUM0_PLLT_IN_A PL16A 7 T LUM0_PLLT_IN_A
H1 PL12B 7 C LUM0_PLLC_IN_A PL16B 7 C LUM0_PLLC_IN_A PL16B 7 C LUM0_PLLC_IN_A
J1 PL13A 7 T3- PL17A 7 T3- PL17A 7 T3-
K2 PL13B 7 C3- PL17B 7 C3- PL17B 7 C3-
K3 PL14A 7 - VREF2_7 PL18A 7 - VREF2_7 PL18A 7 - VREF2_7
J3 PL15B 7 - - PL19B 7 - - PL19B 7 - -
K1 PL16A 7 T3DQS PL20A 7 T3DQS PL20A 7 T3DQS
- GNDIO7 7 - - GNDIO7 7 - - GNDIO7 7 - -
L2 PL16B 7 C3- PL20B 7 C3- PL20B 7 C3-
L3 PL17A 7 T - PL21A 7 T - PL21A 7 T -
L4 PL17B 7 C - PL21B 7 C - PL21B 7 C -
L1 PL18A 7 T3- PL22A 7 T3- PL22A 7 T3-
M1 PL18B 7 C3- PL22B 7 C3- PL22B 7 C3-
M2 VCCP0 - - - VCCP0 - - - VCCP0 - - -
N1 GNDP0 - - - GNDP0 - - - GNDP0 - - -
M3 PL19A 6 T3- PL23A 6 T3- PL27A 6 T3-
M4 PL19B 6 C3- PL23B 6 C3- PL27B 6 C3-
P1 PL20A 6 T PCLKT6_0 PL24A 6 T PCLKT6_0 PL28A 6 T PCLKT6_0
- GNDIO6 6 - - GNDIO6 6 - - GNDIO6 6 - -
N2 PL20B 6 C PCLKC6_0 PL24B 6 C PCLKC6_0 PL28B 6 C PCLKC6_0
R1 PL21A 6 T3- PL25A 6 T3- PL29A 6 T3-
P2 PL21B 6 C3- PL25B 6 C3- PL29B 6 C3-
N3 PL22A 6 - - PL26A 6 - - PL30A 6 - -
N4 PL23B 6 - VREF1_6 PL27B 6 - VREF1_6 PL31B 6 - VREF1_6
T1 PL24A 6 T3DQS PL28A 6 T3DQS PL32A 6 T3DQS
R2 PL24B 6 C3- PL28B 6 C3- PL32B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - - GNDIO6 6 - -
4-35
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
U1 PL25A 6 T LLM0_PLLT_IN_A PL29A 6 T LLM0_PLLT_IN_A PL33A 6 T LLM0_PLLT_IN_A
T2 PL25B 6 C LLM0_PLLC_IN_A PL29B 6 C LLM0_PLLC_IN_A PL33B 6 C LLM0_PLLC_IN_A
V1 PL26A 6 T3- PL30A 6 T3- PL34A 6 T3-
U2 PL26B 6 C3- PL30B 6 C3- PL34B 6 C3-
W1 PL28A 6 T3- PL32A 6 T3- PL36A 6 T3-
V2 PL28B 6 C3- PL32B 6 C3- PL36B 6 C3-
- GNDIO6 6 - - GNDIO6 - - - GNDIO6 6 - -
P3 PL29A 6 T - PL33A 6 T - PL37A 6 T -
P4 PL29B 6 C - PL33B 6 C - PL37B 6 C -
Y1 PL30A 6 T3- PL34A 6 T3- PL38A 6 T3-
W2 PL30B 6 C3- PL34B 6 C3- PL38B 6 C3-
R3 PL31A 6 - VREF2_6 PL35A 6 - VREF2_6 PL39A 6 - VREF2_6
R4 PL32B 6 - - PL36B 6 - - PL40B 6 - -
T3 PL33A 6 T3DQS PL37A 6 T3DQS PL41A 6 T3DQS
T4 PL33B 6 C3- PL37B 6 C3- PL41B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - - GNDIO6 6 - -
V4 PL34A 6 T LLM0_PLLT_FB_A PL38A 6 T LLM0_PLLT_FB_A PL42A 6 T LLM0_PLLT_FB_A
V3 PL34B 6 C LLM0_PLLC_FB_A PL38B 6 C LLM0_PLLC_FB_A PL42B 6 C LLM0_PLLC_FB_A
U4 PL35A 6 T3- PL39A 6 T3- PL43A 6 T3-
U3 PL35B 6 C3- PL39B 6 C3- PL43B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - - GNDIO6 6 - -
W5 SLEEPN1/
TOE2-- - SLEEPN1/
TOE2-- - SLEEPN1/
TOE2-- -
Y2 INITN 5 - - INITN 5 - - INITN 5 - -
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
Y3 - - - - PB3B 5 - - PB7B 5 - -
W3 - - - - PB4A 5 T - PB8A 5 T -
W4 - - - - PB4B 5 C - PB8B 5 C -
AA2 - - - - PB5A 5 - - PB9A 5 - -
AA1 - - - - PB6B 5 - - PB10B 5 - -
W6 PB2A 5 - - PB7A 5 T DQS PB11A 5 T DQS
W7 - - - - PB7B 5 C - PB11B 5 C -
Y4 PB3A 5 T - PB8A 5 T - PB12A 5 T -
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
Y5 PB3B 5 C - PB8B 5 C - PB12B 5 C -
AB2 PB4A 5 T - PB9A 5 T - PB13A 5 T -
AA3 PB4B 5 C - PB9B 5 C - PB13B 5 C -
AB3 PB5A 5 T - PB10A 5 T - PB14A 5 T -
AA4 PB5B 5 C - PB10B 5 C - PB14B 5 C -
W8 PB6A 5 T - PB11A 5 T - PB15A 5 T -
W9 PB6B 5 C - PB11B 5 C - PB15B 5 C -
AB4 PB7A 5 T VREF1_5 PB12A 5 T VREF1_5 PB16A 5 T VREF1_5
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
AA5 PB7B 5 C - PB12B 5 C - PB16B 5 C -
AB5 PB8A 5 - - PB13A 5 - - PB17A 5 - -
Y6 PB9B 5 - - PB14B 5 - - PB18B 5 - -
AA6 PB10A 5 T DQS PB15A 5 T DQS PB19A 5 T DQS
AB6 PB10B 5 C - PB15B 5 C - PB19B 5 C -
Y9 PB11A 5 T - PB16A 5 T - PB20A 5 T -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-36
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Y10 PB11B 5 C - PB16B 5 C - PB20B 5 C -
AA7 PB12A 5 T - PB17A 5 T - PB21A 5 T -
AB7 PB12B 5 C VREF2_5 PB17B 5 C VREF2_5 PB21B 5 C VREF2_5
Y7 PB13A 5 T - PB18A 5 T - PB22A 5 T -
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
AA8 PB13B 5 C - PB18B 5 C - PB22B 5 C -
AB8 PB14A 5 T - PB19A 5 T - PB23A 5 T -
Y8 PB14B 5 C - PB19B 5 C - PB23B 5 C -
AB9 PB15A 5 T - PB20A 5 T - PB24A 5 T -
AA9 PB15B 5 C - PB20B 5 C - PB24B 5 C -
W10 PB16A 5 - - PB21A 5 - - PB25A 5 - -
W11 PB17B 5 - - PB22B 5 - - PB26B 5 - -
AB10 PB18A 5 T DQS PB23A 5 T DQS PB27A 5 T DQS
AA10 PB18B 5 C - PB23B 5 C - PB27B 5 C -
- GNDIO5 5 - - GNDIO5 5 - - GNDIO5 5 - -
AA11 PB19A 5 T - PB24A 5 T - PB28A 5 T -
AB11 PB19B 5 C - PB24B 5 C - PB28B 5 C -
Y11 PB20A 5 T - PB25A 5 T - PB29A 5 T -
Y12 PB20B 5 C - PB25B 5 C - PB29B 5 C -
AB12 PB21A 4 T - PB26A 4 T - PB30A 4 T -
AA12 PB21B 4 C - PB26B 4 C - PB30B 4 C -
AB13 PB22A 4 T PCLKT4_0 PB27A 4 T PCLKT4_0 PB31A 4 T PCLKT4_0
AA13 PB22B 4 C PCLKC4_0 PB27B 4 C PCLKC4_0 PB31B 4 C PCLKC4_0
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
AA14 PB23A 4 T - PB28A 4 T - PB32A 4 T -
AB14 PB23B 4 C - PB28B 4 C - PB32B 4 C -
W12 PB24A 4 - - PB29A 4 - - PB33A 4 - -
W13 PB25B 4 - - PB30B 4 - - PB34B 4 - -
AA15 PB26A 4 T DQS PB31A 4 T DQS PB35A 4 T DQS
AB15 PB26B 4 C VREF1_4 PB31B 4 C VREF1_4 PB35B 4 C VREF1_4
AA16 PB27A 4 T - PB32A 4 T - PB36A 4 T -
AB16 PB27B 4 C - PB32B 4 C - PB36B 4 C -
Y17 PB28A 4 T - PB33A 4 T - PB37A 4 T -
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
AA17 PB28B 4 C - PB33B 4 C - PB37B 4 C -
Y13 PB29A 4 T - PB34A 4 T - PB38A 4 T -
Y14 PB29B 4 C - PB34B 4 C - PB38B 4 C -
AB17 PB30A 4 T - PB35A 4 T - PB39A 4 T -
Y18 PB30B 4 C - PB35B 4 C - PB39B 4 C -
AA18 PB31A 4 T VREF2_4 PB36A 4 T VREF2_4 PB40A 4 T VREF2_4
AB18 PB31B 4 C - PB36B 4 C - PB40B 4 C -
Y19 PB32A 4 - - PB37A 4 - - PB41A 4 - -
AB19 PB33B 4 - - PB38B 4 - - PB42B 4 - -
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
AA19 PB34A 4 T DQS PB39A 4 T DQS PB43A 4 T DQS
Y20 PB34B 4 C - PB39B 4 C - PB43B 4 C -
W14 PB35A 4 T - PB40A 4 T - PB44A 4 T -
W15 PB35B 4 C - PB40B 4 C - PB44B 4 C -
AB20 PB36A 4 T - PB41A 4 T - PB45A 4 T -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-37
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
AA20 PB36B 4 C - PB41B 4 C - PB45B 4 C -
AB21 PB37A 4 T - PB42A 4 T - PB46A 4 T -
AA21 PB37B 4 C - PB42B 4 C - PB46B 4 C -
AA22 PB38A 4 T - PB43A 4 T - PB47A 4 T -
Y21 PB38B 4 C - PB43B 4 C - PB47B 4 C -
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
W16 PB39A 4 - - PB44A 4 T - PB48A 4 T -
W17 - - - - PB44B 4 C - PB48B 4 C -
Y15 - - - - PB45A 4 - - PB49A 4 - -
Y16 - - - - PB46B 4 - - PB50B 4 - -
W19 - - - - PB47A 4 T DQS PB51A 4 T DQS
W18 - - - - PB47B 4 C - PB51B 4 C -
W20 - - - - PB48A 4 - - PB52A 4 - -
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
- GNDIO4 4 - - GNDIO4 4 - - GNDIO4 4 - -
- GNDIO3 3 - - GNDIO3 3 - - GNDIO3 3 - -
T20 PR35B 3 C3-PR39B3C
3- PR43B 3 C3-
T19 PR35A 3 T3-PR39A3T
3- PR43A 3 T3-
- GNDIO3 3 - - GNDIO3 3 - - GNDIO3 3 - -
U19 PR34B 3 C RLM0_PLLC_FB_A PR38B 3 C RLM0_PLLC_FB_A PR42B 3 C RLM0_PLLC_FB_A
U20 PR34A 3 T RLM0_PLLT_FB_A PR38A 3 T RLM0_PLLT_FB_A PR42A 3 T RLM0_PLLT_FB_A
V19 PR33B 3 C3-PR37B3C
3- PR41B 3 C3-
V20 PR33A 3 T3DQS PR37A 3 T3DQS PR41A 3 T3DQS
R19 PR32B 3 - - PR36B 3 - - PR40B 3 - -
R20 PR31A 3 - VREF1_3 PR35A 3 - VREF1_3 PR39A 3 - VREF1_3
W21 PR30B 3 C3-PR34B3C
3- PR38B 3 C3-
Y22 PR30A 3 T3-PR34A3T
3- PR38A 3 T3-
- GNDIO3 3 - - GNDIO3 3 - - GNDIO3 3 - -
P19 PR29B 3C - PR33B 3C - PR37B 3C -
P20 PR29A 3 T - PR33A 3 T - PR37A 3 T -
V21 PR28B 3 C3-PR32B3C
3- PR36B 3 C3-
W22 PR28A 3 T3-PR32A3T
3- PR36A 3 T3-
U21 PR26B 3 C3-PR30B3C
3- PR34B 3 C3-
V22 PR26A 3 T3-PR30A3T
3- PR34A 3 T3-
T21 PR25B 3 C RLM0_PLLC_IN_A PR29B 3 C RLM0_PLLC_IN_A PR33B 3 C RLM0_PLLC_IN_A
U22 PR25A 3 T RLM0_PLLT_IN_A PR29A 3 T RLM0_PLLT_IN_A PR33A 3 T RLM0_PLLT_IN_A
- GNDIO3 3 - - GNDIO3 3 - - GNDIO3 3 - -
R21 PR24B 3 C3-PR28B3C
3- PR32B 3 C3-
T22 PR24A 3 T3DQS PR28A 3 T3DQS PR32A 3 T3DQS
N19 PR23B 3 - - PR27B 3 - - PR31B 3 - -
N20 PR22A 3 - VREF2_3 PR26A 3 - VREF2_3 PR30A 3 - VREF2_3
R22 PR21B 3 C3-PR25B3C
3- PR29B 3 C3-
P22 PR21A 3 T3-PR25A3T
3- PR29A 3 T3-
P21 PR20B 3C - PR24B 3C - PR28B 3C -
N21 PR20A 3 T - PR24A 3 T - PR28A 3 T -
- GNDIO3 3 - - GNDIO3 3 - - GNDIO3 3 - -
M20 PR19B 3 C3-PR23B3C
3- PR27B 3 C3-
M19 PR19A 3 T3-PR23A3T
3- PR27A 3 T3-
N22 GNDP1 - - - GNDP1 - - - GNDP1 - - -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-38
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
M21 VCCP1 - - - VCCP1 - - - VCCP1 - - -
- GNDIO2 2 - - GNDIO2 2 - - GNDIO2 2 - -
M22 PR18B 2 C3-PR22B2C
3- PR22B 2 C3-
L22 PR18A 2 T3-PR22A2T
3- PR22A 2 T3-
K22 PR17B 2 C PCLKC2_0 PR21B 2 C PCLKC2_0 PR21B 2 C PCLKC2_0
K21 PR17A 2 T PCLKT2_0 PR21A 2 T PCLKT2_0 PR21A 2 T PCLKT2_0
L19 PR16B 2 C3-PR20B2C
3- PR20B 2 C3-
K20 PR16A 2 T3DQS PR20A 2 T3DQS PR20A 2 T3DQS
L20 PR15B 2 - - PR19B 2 - - PR19B 2 - -
L21 PR14A 2 - VREF1_2 PR18A 2 - VREF1_2 PR18A 2 - VREF1_2
- GNDIO2 2 - - GNDIO2 2 - - GNDIO2 2 - -
J22 PR13B 2 C3-PR17B2C
3- PR17B 2 C3-
J21 PR13A 2 T3-PR17A2T
3- PR17A 2 T3-
H22 PR12B 2 C RUM0_PLLC_IN_A PR16B 2 C RUM0_PLLC_IN_A PR16B 2 C RUM0_PLLC_IN_A
H21 PR12A 2 T RUM0_PLLT_IN_A PR16A 2 T RUM0_PLLT_IN_A PR16A 2 T RUM0_PLLT_IN_A
K19 PR11B 2 C3-PR15B2C
3- PR15B 2 C3-
J19 PR11A 2 T3-PR15A2T
3- PR15A 2 T3-
- GNDIO2 2 - - GNDIO2 2 - - GNDIO2 2 - -
J20 PR9B 2 C3-PR13B2C
3- PR13B 2 C3-
H20 PR9A 2 T3-PR13A2T
3- PR13A 2 T3-
H19 PR8B 2 C - PR12B 2 C - PR12B 2 C -
G19PR8A2T- PR12A2T- PR12A2T-
G22 PR7B 2 C3-PR11B2C
3- PR11B 2 C3-
G21 PR7A 2 T3DQS PR11A 2 T3DQS PR11A 2 T3DQS
- GNDIO2 2 - - GNDIO2 2 - - GNDIO2 2 - -
F20 PR6B 2 - - PR10B 2 - - PR10B 2 - -
G20 PR5A 2 - VREF2_2 PR9A 2 - VREF2_2 PR9A 2 - VREF2_2
F22 PR4B 2 C3-PR8B2C
3-PR8B2C
3-
F21 PR4A 2 T3-PR8A2T
3-PR8A2T
3-
E22 PR3B 2 C RUM0_PLLC_FB_A PR7B 2 C RUM0_PLLC_FB_A PR7B 2 C RUM0_PLLC_FB_A
E21 PR3A 2 T RUM0_PLLT_FB_A PR7A 2 T RUM0_PLLT_FB_A PR7A 2 T RUM0_PLLT_FB_A
D22 PR2B 2 C3-PR6B2C
3-PR6B2C
3-
D21 PR2A 2 T3-PR6A2T
3-PR6A2T
3-
- GNDIO2 2 - - GNDIO2 2 - - GNDIO2 2 - -
F19 TDO - - - TDO --- TDO---
E20 VCCJ -- - VCCJ -- - VCCJ ---
D20 TDI --- TDI--- TDI---
D19 TMS --- TMS--- TMS---
D18 TCK --- TCK--- TCK---
- GNDIO1 1 - - GNDIO1 1 - - GNDIO1 1 - -
E19----PT48A1--PT52A1--
D17----PT47B1C-PT51B1C-
D16 - - - - PT47A 1 T DQS PT51A 1 T DQS
C16----PT46B1--PT50B1--
C15----PT45A1--PT49A1--
C17----PT44B1C-PT48B1C-
C18 PT39A 1 - - PT44A 1 T - PT48A 1 T -
C19 PT38B 1 C - PT43B 1 C - PT47B 1 C -
- GNDIO1 1 - - GNDIO1 1 - - GNDIO1 1 - -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-39
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
C20 PT38A 1 T - PT43A 1 T - PT47A 1 T -
C21 PT37B 1 C - PT42B 1 C - PT46B 1 C -
C22 PT37A 1 T - PT42A 1 T - PT46A 1 T -
B22 PT36B 1 C - PT41B 1 C - PT45B 1 C -
A21 PT36A 1 T - PT41A 1 T - PT45A 1 T -
D15 PT35B 1 C - PT40B 1 C - PT44B 1 C -
D14 PT35A 1 T - PT40A 1 T - PT44A 1 T -
B21 PT34B 1 C VREF1_1 PT39B 1 C VREF1_1 PT43B 1 C VREF1_1
- GNDIO1 1 - - GNDIO1 1 - - GNDIO1 1 - -
A20 PT34A 1 T DQS PT39A 1 T DQS PT43A 1 T DQS
B20 PT33B 1 - - PT38B 1 - - PT42B 1 - -
A19 PT32A 1 - - PT37A 1 - - PT41A 1 - -
B19 PT31B 1 C - PT36B 1 C - PT40B 1 C -
A18 PT31A 1 T - PT36A 1 T - PT40A 1 T -
C14 PT30B 1 C - PT35B 1 C - PT39B 1 C -
C13 PT30A 1 T D0 PT35A 1 T D0 PT39A 1 T D0
B18 PT29B 1 C D1 PT34B 1 C D1 PT38B 1 C D1
A17 PT29A 1 T VREF2_1 PT34A 1 T VREF2_1 PT38A 1 T VREF2_1
B17 PT28B 1 C - PT33B 1 C - PT37B 1 C -
A16 PT28A 1 T D2 PT33A 1 T D2 PT37A 1 T D2
- GNDIO1 1 - - GNDIO1 1 - - GNDIO1 1 - -
B16 PT27B 1 C D3 PT32B 1 C D3 PT36B 1 C D3
A15 PT27A 1 T - PT32A 1 T - PT36A 1 T -
B15 PT26B 1 C - PT31B 1 C - PT35B 1 C -
A14 PT26A 1 T DQS PT31A 1 T DQS PT35A 1 T DQS
D13 PT25B 1 - - PT30B 1 - - PT34B 1 - -
D12 PT24A 1 - D4 PT29A 1 - D4 PT33A 1 - D4
B14 PT23B 1 C - PT28B 1 C - PT32B 1 C -
A13 PT23A 1 T D5 PT28A 1 T D5 PT32A 1 T D5
- GNDIO1 1 - - GNDIO1 1 - - GNDIO1 1 - -
B13 PT22B 1 C D6 PT27B 1 C D6 PT31B 1 C D6
A12 PT22A 1 T - PT27A 1 T - PT31A 1 T -
B12 PT21B 1 C D7 PT26B 1 C D7 PT30B 1 C D7
C12 PT21A 1 T - PT26A 1 T - PT30A 1 T -
C11 PT20B 0 C BUSY PT25B 0 C BUSY PT29B 0 C BUSY
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
B11 PT20A 0 T CS1N PT25A 0 T CS1N PT29A 0 T CS1N
A11 PT19B 0 C PCLKC0_0 PT24B 0 C PCLKC0_0 PT28B 0 C PCLKC0_0
A10 PT19A 0 T PCLKT0_0 PT24A 0 T PCLKT0_0 PT28A 0 T PCLKT0_0
B10 PT18B 0 C - PT23B 0 C - PT27B 0 C -
B9 PT18A 0 T DQS PT23A 0 T DQS PT27A 0 T DQS
D11 PT17B 0 - - PT22B 0 - - PT26B 0 - -
D10 PT16A 0 - DOUT PT21A 0 - DOUT PT25A 0 - DOUT
A9 PT15B 0 C - PT20B 0 C - PT24B 0 C -
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
C8 PT15A 0 T WRITEN PT20A 0 T WRITEN PT24A 0 T WRITEN
B8 PT14B 0 C - PT19B 0 C - PT23B 0 C -
A8 PT14A 0 T VREF1_0 PT19A 0 T VREF1_0 PT23A 0 T VREF1_0
C7 PT13B 0 C - PT18B 0 C - PT22B 0 C -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-40
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
A7 PT13A 0 T DI PT18A 0 T DI PT22A 0 T DI
B7 PT12B 0 C - PT17B 0 C - PT21B 0 C -
C6 PT12A 0 T CSN PT17A 0 T CSN PT21A 0 T CSN
C10 PT11B 0 C - PT16B 0 C - PT20B 0 C -
C9 PT11A 0 T - PT16A 0 T - PT20A 0 T -
A6 PT10B 0 C VREF2_0 PT15B 0 C VREF2_0 PT19B 0 C VREF2_0
B6 PT10A 0 T DQS PT15A 0 T DQS PT19A 0 T DQS
A5PT9B0--PT14B0--PT18B0--
B5PT8A0--PT13A0--PT17A0--
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
C5 PT7B 0C - PT12B 0C - PT16B 0C -
A4 PT7A 0T - PT12A 0T - PT16A 0T -
D9 PT6B 0C - PT11B 0C - PT15B 0C -
D8 PT6A 0T - PT11A 0T - PT15A 0T -
B4 PT5B 0C - PT10B 0C - PT14B 0C -
A2 PT5A 0T - PT10A 0T - PT14A 0T -
A3 PT4B 0 C - PT9B 0 C - PT13B 0 C -
B3 PT4A 0 T - PT9A 0 T - PT13A 0 T -
C4 PT3B 0 C - PT8B 0 C - PT12B 0 C -
C3 PT3A 0 T - PT8A 0 T - PT12A 0 T -
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
C2 - - - - PT7B 0C - PT11B 0C -
D3 PT2A 0 - - PT7A 0 T DQS PT11A 0 T DQS
D7 - - - - PT6B 0 - - PT10B 0 - -
D6 - - - - PT5A 0 - - PT9A 0 - -
E4 - - - - PT4B 0 C - PT8B 0 C -
D4 - - - - PT4A 0 T - PT8A 0 T -
D5 - - - - PT3B 0 - - PT7B 0 - -
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
- GNDIO0 0 - - GNDIO0 0 - - GNDIO0 0 - -
C1 CFG0 0 - - CFG0 0 - - CFG0 0 - -
B2 CFG1 0 - - CFG1 0 - - CFG1 0 - -
B1 DONE 0 - - DONE 0 - - DONE 0 - -
A1 GND-- - GND-- - GND-- -
A22GND---GND---GND---
AB1GND---GND---GND---
AB22GND---GND---GND---
H10 GND - - - GND - - - GND - - -
H11 GND - - - GND - - - GND - - -
H12 GND - - - GND - - - GND - - -
H13 GND - - - GND - - - GND - - -
H14 GND - - - GND - - - GND - - -
J10GND---GND---GND---
J11GND---GND---GND---
J12GND---GND---GND---
J13GND---GND---GND---
J14GND---GND---GND---
J9 GND-- - GND-- - GND-- -
K10GND---GND---GND---
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-41
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
K11GND---GND---GND---
K12GND---GND---GND---
K13GND---GND---GND---
K14GND---GND---GND---
K9 GND-- - GND-- - GND-- -
L10GND---GND---GND---
L11GND---GND---GND---
L12GND---GND---GND---
L13GND---GND---GND---
L14GND---GND---GND---
L9 GND-- - GND-- - GND-- -
M10GND---GND---GND---
M11GND---GND---GND---
M12GND---GND---GND---
M13GND---GND---GND---
M14GND---GND---GND---
M9GND-- - GND-- - GND-- -
N10 GND - - - GND - - - GND - - -
N11 GND - - - GND - - - GND - - -
N12 GND - - - GND - - - GND - - -
N13 GND - - - GND - - - GND - - -
N14 GND - - - GND - - - GND - - -
N9 GND-- - GND-- - GND-- -
P10GND---GND---GND---
P11GND---GND---GND---
P12GND---GND---GND---
P13GND---GND---GND---
P14GND---GND---GND---
P9 GND-- - GND-- - GND-- -
R10 GND - - - GND - - - GND - - -
R11 GND - - - GND - - - GND - - -
R12 GND - - - GND - - - GND - - -
R13 GND - - - GND - - - GND - - -
R14 GND - - - GND - - - GND - - -
H9 VCC-- - VCC-- - VCC-- -
J15 VCC - - - VCC - - - VCC - - -
J8 VCC-- - VCC-- - VCC-- -
K15 VCC - - - VCC - - - VCC - - -
K8 VCC - - - VCC - - - VCC - - -
L15 VCC - - - VCC - - - VCC - - -
L8 VCC-- - VCC-- - VCC-- -
M15 VCC - - - VCC - - - VCC - - -
M8VCC-- - VCC-- - VCC-- -
N15 VCC - - - VCC - - - VCC - - -
N8 VCC-- - VCC-- - VCC-- -
P15 VCC - - - VCC - - - VCC - - -
P8 VCC - - - VCC - - - VCC - - -
R9 VCC-- - VCC-- - VCC-- -
G16 VCCAUX - - - VCCAUX - - - VCCAUX - - -
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-42
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
G7 VCCAUX - - - VCCAUX - - - VCCAUX - - -
T16 VCCAUX - - - VCCAUX - - - VCCAUX - - -
T7 VCCAUX - - - VCCAUX - - - VCCAUX - - -
G10 VCCIO0 0 - - VCCIO0 0 - - VCCIO0 0 - -
G11 VCCIO0 0 - - VCCIO0 0 - - VCCIO0 0 - -
G8 VCCIO0 0 - - VCCIO0 0 - - VCCIO0 0 - -
G9 VCCIO0 0 - - VCCIO0 0 - - VCCIO0 0 - -
H8 VCCIO0 0 - - VCCIO0 0 - - VCCIO0 0 - -
G12 VCCIO1 1 - - VCCIO1 1 - - VCCIO1 1 - -
G13 VCCIO1 1 - - VCCIO1 1 - - VCCIO1 1 - -
G14 VCCIO1 1 - - VCCIO1 1 - - VCCIO1 1 - -
G15 VCCIO1 1 - - VCCIO1 1 - - VCCIO1 1 - -
H15 VCCIO1 1 - - VCCIO1 1 - - VCCIO1 1 - -
H16 VCCIO2 2 - - VCCIO2 2 - - VCCIO2 2 - -
J16 VCCIO2 2 - - VCCIO2 2 - - VCCIO2 2 - -
K16 VCCIO2 2 - - VCCIO2 2 - - VCCIO2 2 - -
L16 VCCIO2 2 - - VCCIO2 2 - - VCCIO2 2 - -
M16 VCCIO3 3 - - VCCIO3 3 - - VCCIO3 3 - -
N16 VCCIO3 3 - - VCCIO3 3 - - VCCIO3 3 - -
P16 VCCIO3 3 - - VCCIO3 3 - - VCCIO3 3 - -
R16 VCCIO3 3 - - VCCIO3 3 - - VCCIO3 3 - -
R15 VCCIO4 4 - - VCCIO4 4 - - VCCIO4 4 - -
T12 VCCIO4 4 - - VCCIO4 4 - - VCCIO4 4 - -
T13 VCCIO4 4 - - VCCIO4 4 - - VCCIO4 4 - -
T14 VCCIO4 4 - - VCCIO4 4 - - VCCIO4 4 - -
T15 VCCIO4 4 - - VCCIO4 4 - - VCCIO4 4 - -
R8 VCCIO5 5 - - VCCIO5 5 - - VCCIO5 5 - -
T10 VCCIO5 5 - - VCCIO5 5 - - VCCIO5 5 - -
T11 VCCIO5 5 - - VCCIO5 5 - - VCCIO5 5 - -
T8 VCCIO5 5 - - VCCIO5 5 - - VCCIO5 5 - -
T9 VCCIO5 5 - - VCCIO5 5 - - VCCIO5 5 - -
M7 VCCIO6 6 - - VCCIO6 6 - - VCCIO6 6 - -
N7 VCCIO6 6 - - VCCIO6 6 - - VCCIO6 6 - -
P7 VCCIO6 6 - - VCCIO6 6 - - VCCIO6 6 - -
R7 VCCIO6 6 - - VCCIO6 6 - - VCCIO6 6 - -
H7 VCCIO7 7 - - VCCIO7 7 - - VCCIO7 7 - -
J7 VCCIO7 7 - - VCCIO7 7 - - VCCIO7 7 - -
K7 VCCIO7 7 - - VCCIO7 7 - - VCCIO7 7 - -
L7 VCCIO7 7 - - VCCIO7 7 - - VCCIO7 7 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP10, LFXP15 & LFXP20 Logic Signal Connections: 388 fpBGA (Cont.)
Ball
Number
LFXP10 LFXP15 LFXP20
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
Ball
Function Bank Diff. Dual Function
4-43
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
F5 PROGRAMN 7 - - PROGRAMN 7 - -
E3 CCLK 7 - - CCLK 7 - -
C1 PL2B 7 - - PL2B 7 - -
- GNDIO7 7 - - GNDIO7 7 - -
G5 PL3A 7 T3-PL3A7T
3-
G6 PL3B 7 C3-PL3B7C
3-
F4 PL4A 7 T - PL4A 7 T -
F3 PL4B 7 C - PL4B 7 C -
G4 PL5A 7 T3-PL5A7T
3-
G3 PL5B 7 C3-PL5B7C
3-
D1 PL6A 7 T3-PL6A7T
3-
D2 PL6B 7 C3-PL6B7C
3-
- GNDIO7 7 - - GNDIO7 7 - -
E1 PL7A 7 T LUM0_PLLT_FB_A PL7A 7 T LUM0_PLLT_FB_A
E2 PL7B 7 C LUM0_PLLC_FB_A PL7B 7 C LUM0_PLLC_FB_A
H5 PL8A 7 T3-PL8A7T
3-
H6 PL8B 7 C3-PL8B7C
3-
H4 PL9A 7 - - PL9A 7 - -
H3 PL10B 7 - VREF1_7 PL10B 7 - VREF1_7
F1 PL11A 7 T3DQS PL11A 7 T3DQS
F2 PL11B 7 C3- PL11B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - -
J5 PL12A 7 T - PL12A 7 T -
J6 PL12B 7 C - PL12B 7 C -
G1 PL13A 7 T3- PL13A 7 T3-
G2 PL13B 7 C3- PL13B 7 C3-
J4 PL15A 7 T3- PL15A 7 T3-
J3 PL15B 7 C3- PL15B 7 C3-
- GNDIO7 7 - - GNDIO7 7 - -
H1 PL16A 7 T LUM0_PLLT_IN_A PL16A 7 T LUM0_PLLT_IN_A
H2 PL16B 7 C LUM0_PLLC_IN_A PL16B 7 C LUM0_PLLC_IN_A
J1 PL17A 7 T3- PL17A 7 T3-
J2 PL17B 7 C3- PL17B 7 C3-
K3 PL18A 7 - VREF2_7 PL18A 7 - VREF2_7
K2 PL19B 7 - - PL19B 7 - -
K4 PL20A 7 T3DQS PL20A 7 T3DQS
- GNDIO7 7 - - GNDIO7 7 - -
K5 PL20B 7 C3- PL20B 7 C3-
K1 PL21A 7 T - PL21A 7 T -
L2 PL21B 7 C - PL21B 7 C -
L4 PL22A 7 T3- PL22A 7 T3-
L3 PL22B 7 C3- PL22B 7 C3-
4-44
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
L1 - - - - PL23A 7 T3-
M1 - - - - PL23B 7 C3-
M2----PL24A7--
L5 VCCP0 - - - VCCP0 - - -
N2 GNDP0 - - - GNDP0 - - -
N1----PL25B6--
P2 - - - - PL26A 6 T3-
P1 - - - - PL26B 6 C3-
M4 PL23A 6 T3- PL27A 6 T3-
M3 PL23B 6 C3- PL27B 6 C3-
R2 PL24A 6 T PCLKT6_0 PL28A 6 T PCLKT6_0
- GNDIO6 6 - - GNDIO6 6 - -
R1 PL24B 6 C PCLKC6_0 PL28B 6 C PCLKC6_0
N3 PL25A 6 T3- PL29A 6 T3-
N4 PL25B 6 C3- PL29B 6 C3-
M5 PL26A 6 - - PL30A 6 - -
N5 PL27B 6 - VREF1_6 PL31B 6 - VREF1_6
T2 PL28A 6 T3DQS PL32A 6 T3DQS
T1 PL28B 6 C3- PL32B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
U2 PL29A 6 T LLM0_PLLT_IN_A PL33A 6 T LLM0_PLLT_IN_A
U1 PL29B 6 C LLM0_PLLC_IN_A PL33B 6 C LLM0_PLLC_IN_A
P3 PL30A 6 T3- PL34A 6 T3-
P4 PL30B 6 C3- PL34B 6 C3-
P6 PL32A 6 T3- PL36A 6 T3-
P5 PL32B 6 C3- PL36B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
V2 PL33A 6 T - PL37A 6 T -
V1 PL33B 6 C - PL37B 6 C -
W2 PL34A 6 T3- PL38A 6 T3-
W1 PL34B 6 C3- PL38B 6 C3-
R3 PL35A 6 - VREF2_6 PL39A 6 - VREF2_6
R4 PL36B 6 - - PL40B 6 - -
R6 PL37A 6 T3DQS PL41A 6 T3DQS
R5 PL37B 6 C3- PL41B 6 C3-
- GNDIO6 6 - - GNDIO6 6 - -
Y2 PL38A 6 T LLM0_PLLT_FB_A PL42A 6 T LLM0_PLLT_FB_A
Y1 PL38B 6 C LLM0_PLLC_FB_A PL42B 6 C LLM0_PLLC_FB_A
T3 PL39A 6 T3- PL43A 6 T3-
T4 PL39B 6 C3- PL43B 6 C3-
W3 PL40A 6 T3- PL44A 6 T3-
V3 PL40B 6 C3- PL44B 6 C3-
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-45
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
T6 PL41A 6 T - PL45A 6 T -
T5 PL41B 6 C - PL45B 6 C -
- GNDIO6 6 - - GNDIO6 6 - -
U3 PL42A 6 T3- PL46A 6 T3-
U4 PL42B 6 C3- PL46B 6 C3-
V4 PL43A 6 - - PL47A 6 - -
W4 SLEEPN1/
TOE2-- - SLEEPN1/
TOE2-- -
W5 INITN 5 - - INITN 5 - -
Y3 - - - - PB3B 5 - -
- GNDIO5 5 - - GNDIO5 5 - -
U5 - - - - PB4A 5 T -
V5 - - - - PB4B 5 C -
Y4 - - - - PB5A 5 T -
Y5 - - - - PB5B 5 C -
V6 - - - - PB6A 5 T -
- GNDIO5 5 - - GNDIO5 5 - -
U6 - - - - PB6B 5 C -
W6 PB3A 5 T - PB7A 5 T -
Y6 PB3B 5 C - PB7B 5 C -
AA2 PB4A 5 T - PB8A 5 T -
AA3 PB4B 5 C - PB8B 5 C -
V7 PB5A 5 - - PB9A 5 - -
U7PB6B5--PB10B5--
Y7 PB7A 5 T DQS PB11A 5 T DQS
W7PB7B5C-PB11B5C-
AA4 PB8A 5 T - PB12A 5 T -
- GNDIO5 5 - - GNDIO5 5 - -
AA5 PB8B 5 C - PB12B 5 C -
AB3 PB9A 5 T - PB13A 5 T -
AB4 PB9B 5 C - PB13B 5 C -
AA6 PB10A 5 T - PB14A 5 T -
AA7 PB10B 5 C - PB14B 5 C -
U8 PB11A 5 T - PB15A 5 T -
V8 PB11B 5 C - PB15B 5 C -
Y8 PB12A 5 T VREF1_5 PB16A 5 T VREF1_5
- GNDIO5 5 - - GNDIO5 5 - -
W8 PB12B 5 C - PB16B 5 C -
V9 PB13A 5 - - PB17A 5 - -
U9 PB14B 5 - - PB18B 5 - -
Y9 PB15A 5 T DQS PB19A 5 T DQS
W9 PB15B 5 C - PB19B 5 C -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-46
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
AB5 PB16A 5 T - PB20A 5 T -
AB6 PB16B 5 C - PB20B 5 C -
AA8 PB17A 5 T - PB21A 5 T -
AA9 PB17B 5 C VREF2_5 PB21B 5 C VREF2_5
W10 PB18A 5 T - PB22A 5 T -
- GNDIO5 5 - - GNDIO5 5 - -
V10 PB18B 5 C - PB22B 5 C -
AB7 PB19A 5 T - PB23A 5 T -
AB8 PB19B 5 C - PB23B 5 C -
AB9 PB20A 5 T - PB24A 5 T -
AB10 PB20B 5 C - PB24B 5 C -
Y10 PB21A 5 - - PB25A 5 - -
AA10 PB22B 5 - - PB26B 5 - -
W11 PB23A 5 T DQS PB27A 5 T DQS
V11 PB23B 5 C - PB27B 5 C -
- GNDIO5 5 - - GNDIO5 5 - -
Y11 PB24A 5 T - PB28A 5 T -
AA11 PB24B 5 C - PB28B 5 C -
AB11 PB25A 5 T - PB29A 5 T -
AB12 PB25B 5 C - PB29B 5 C -
Y12 PB26A 4 T - PB30A 4 T -
AA12 PB26B 4 C - PB30B 4 C -
W12 PB27A 4 T PCLKT4_0 PB31A 4 T PCLKT4_0
V12 PB27B 4 C PCLKC4_0 PB31B 4 C PCLKC4_0
- GNDIO4 4 - - GNDIO4 4 - -
AB13 PB28A 4 T - PB32A 4 T -
AB14 PB28B 4 C - PB32B 4 C -
AA13 PB29A 4 - - PB33A 4 - -
Y13 PB30B 4 - - PB34B 4 - -
AB15 PB31A 4 T DQS PB35A 4 T DQS
AB16 PB31B 4 C VREF1_4 PB35B 4 C VREF1_4
V13 PB32A 4 T - PB36A 4 T -
W13 PB32B 4 C - PB36B 4 C -
AA14 PB33A 4 T - PB37A 4 T -
- GNDIO4 4 - - GNDIO4 4 - -
AA15 PB33B 4 C - PB37B 4 C -
AB17 PB34A 4 T - PB38A 4 T -
AB18 PB34B 4 C - PB38B 4 C -
W14 PB35A 4 T - PB39A 4 T -
Y14 PB35B 4 C - PB39B 4 C -
U14 PB36A 4 T VREF2_4 PB40A 4 T VREF2_4
V14 PB36B 4 C - PB40B 4 C -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-47
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
AB19 PB37A 4 - - PB41A 4 - -
AB20 PB38B 4 - - PB42B 4 - -
- GNDIO4 4 - - GNDIO4 4 - -
V15 PB39A 4 T DQS PB43A 4 T DQS
U15 PB39B 4 C - PB43B 4 C -
Y15 PB40A 4 T - PB44A 4 T -
W15 PB40B 4 C - PB44B 4 C -
AA16 PB41A 4 T - PB45A 4 T -
AA17 PB41B 4 C - PB45B 4 C -
AA18 PB42A 4 T - PB46A 4 T -
AA19 PB42B 4 C - PB46B 4 C -
Y16 PB43A 4 T - PB47A 4 T -
W16 PB43B 4 C - PB47B 4 C -
- GNDIO4 4 - - GNDIO4 4 - -
AA20 PB44A 4 T - PB48A 4 T -
AA21 PB44B 4 C - PB48B 4 C -
Y17 PB45A 4 - - PB49A 4 - -
Y18 PB46B 4 - - PB50B 4 - -
Y19 PB47A 4 T DQS PB51A 4 T DQS
Y20 PB47B 4 C - PB51B 4 C -
V16 PB48A 4 T - PB52A 4 T -
U16 PB48B 4 C - PB52B 4 C -
- GNDIO4 4 - - GNDIO4 4 - -
U18 - - - - PB53A 4 T -
V18 - - - - PB53B 4 C -
W19 - - - - PB54A 4 T -
W18 - - - - PB54B 4 C -
U17 - - - - PB55A 4 T -
V17 - - - - PB55B 4 C -
- GNDIO4 4 - - GNDIO4 4 - -
W17 - - - - PB56A 4 - -
- GNDIO3 3 - - GNDIO3 3 - -
V19 PR43A 3 - - PR47A 3 - -
U20 PR42B 3 C3-PR46B3C
3-
U19 PR42A 3 T3-PR46A3T
3-
V20 PR41B 3 C - PR45B 3 C -
W20 PR41A 3 T - PR45A 3 T -
T17 PR40B 3 C3-PR44B3C
3-
T18 PR40A 3 T3-PR44A3T
3-
T19 PR39B 3 C3-PR43B3C
3-
T20 PR39A 3 T3-PR43A3T
3-
- GNDIO3 3 - - GNDIO3 3 - -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-48
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
R18 PR38B 3 C RLM0_PLLC_FB_A PR42B 3 C RLM0_PLLC_FB_A
R17 PR38A 3 T RLM0_PLLT_FB_A PR42A 3 T RLM0_PLLT_FB_A
Y22 PR37B 3 C3-PR41B3C
3-
Y21 PR37A 3 T3DQS PR41A 3 T3DQS
W22 PR36B 3 - - PR40B 3 - -
W21 PR35A 3 - VREF1_3 PR39A 3 - VREF1_3
P17 PR34B 3 C3-PR38B3C
3-
P18 PR34A 3 T3-PR38A3T
3-
- GNDIO3 3 - - GNDIO3 3 - -
R19 PR33B 3 C - PR37B 3 C -
R20 PR33A 3 T - PR37A 3 T -
V22 PR32B 3 C3-PR36B3C
3-
V21 PR32A 3 T3-PR36A3T
3-
U22 PR30B 3 C3-PR34B3C
3-
U21 PR30A 3 T3-PR34A3T
3-
P19 PR29B 3 C RLM0_PLLC_IN_A PR33B 3 C RLM0_PLLC_IN_A
P20 PR29A 3 T RLM0_PLLT_IN_A PR33A 3 T RLM0_PLLT_IN_A
- GNDIO3 3 - - GNDIO3 3 - -
T22 PR28B 3 C3-PR32B3C
3-
T21 PR28A 3 T3DQS PR32A 3 T3DQS
R22 PR27B 3 - - PR31B 3 - -
R21 PR26A 3 - VREF2_3 PR30A 3 - VREF2_3
N19 PR25B 3 C3-PR29B3C
3-
N20 PR25A 3 T3-PR29A3T
3-
N18 PR24B 3 C - PR28B 3 C -
M18 PR24A 3 T - PR28A 3 T -
- GNDIO3 3 - - GNDIO3 3 - -
P22 PR23B 3 C3-PR27B3C
3-
P21 PR23A 3 T3-PR27A3T
3-
N22 - - - - PR26B 3 C3-
N21 - - - - PR26A 3 T3-
M19 - - - - PR25B 3 - -
M20 GNDP1 - - - GNDP1 - - -
L18 VCCP1 - - - VCCP1 - - -
M21 - - - - PR24A 2 - -
M22 PR22B 2 C3-PR23B2C
3-
L22 PR22A 2 T3-PR23A2T
3-
- GNDIO2 2 - - GNDIO2 2 - -
L19 - - - - PR22B 2 C3-
L20 - - - - PR22A 2 T3-
L21 PR21B 2 C PCLKC2_0 PR21B 2 C PCLKC2_0
K22 PR21A 2 T PCLKT2_0 PR21A 2 T PCLKT2_0
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-49
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
J21 PR20B 2 C3-PR20B2C
3-
J22 PR20A 2 T3DQS PR20A 2 T3DQS
K18 PR19B 2 - - PR19B 2 - -
K19 PR18A 2 - VREF1_2 PR18A 2 - VREF1_2
- GNDIO2 2 - - GNDIO2 2 - -
K21 PR17B 2 C3-PR17B2C
3-
K20 PR17A 2 T3-PR17A2T
3-
H21 PR16B 2 C RUM0_PLLC_IN_A PR16B 2 C RUM0_PLLC_IN_A
H22 PR16A 2 T RUM0_PLLT_IN_A PR16A 2 T RUM0_PLLT_IN_A
J20 PR15B 2 C3-PR15B2C
3-
J19 PR15A 2 T3-PR15A2T
3-
- GNDIO2 2 - - GNDIO2 2 - -
J17 PR13B 2 C3-PR13B2C
3-
J18 PR13A 2 T3-PR13A2T
3-
G21 PR12B 2 C - PR12B 2 C -
G22 PR12A 2 T - PR12A 2 T -
F21 PR11B 2 C3-PR11B2C
3-
F22 PR11A 2 T3DQS PR11A 2 T3DQS
- GNDIO2 2 - - GNDIO2 2 - -
H20 PR10B 2 - - PR10B 2 - -
H19 PR9A 2 - VREF2_2 PR9A 2 - VREF2_2
H17 PR8B 2 C3-PR8B2C
3-
H18 PR8A 2 T3-PR8A2T
3-
E21 PR7B 2 C RUM0_PLLC_FB_A PR7B 2 C RUM0_PLLC_FB_A
E22 PR7A 2 T RUM0_PLLT_FB_A PR7A 2 T RUM0_PLLT_FB_A
D21 PR6B 2 C3-PR6B2C
3-
D22 PR6A 2 T3-PR6A2T
3-
G20 PR5B 2 C3-PR5B2C
3-
G19 PR5A 2 T3-PR5A2T
3-
G17 PR4B 2 C - PR4B 2 C -
G18 PR4A 2 T - PR4A 2 T -
- GNDIO2 2 - - GNDIO2 2 - -
F18 PR3B 2 C3-PR3B2C
3-
F19 PR3A 2 T3-PR3A2T
3-
C22 PR2B 2 - - PR2B 2 - -
F20 TDO - - - TDO - - -
E20 VCCJ - - - VCCJ - - -
D19 TDI - - - TDI - - -
E19 TMS - - - TMS - - -
D20 TCK - - - TCK - - -
C20 - - - - PT56A 1 - -
- GNDIO1 1 - - GNDIO1 1 - -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-50
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
D18 - - - - PT55B 1 C -
E18 - - - - PT55A 1 T -
C19 - - - - PT54B 1 C -
C18 - - - - PT54A 1 T -
C21 - - - - PT53B 1 C -
- GNDIO1 1 - - GNDIO1 1 - -
B21 - - - - PT53A 1 T -
E17 PT48B 1 C - PT52B 1 C -
E16 PT48A 1 T - PT52A 1 T -
C17 PT47B 1 C - PT51B 1 C -
D17 PT47A 1 T DQS PT51A 1 T DQS
F17 PT46B 1 - - PT50B 1 - -
F16 PT45A 1 - - PT49A 1 - -
C16 PT44B 1 C - PT48B 1 C -
D16 PT44A 1 T - PT48A 1 T -
A20 PT43B 1 C - PT47B 1 C -
- GNDIO1 1 - - GNDIO1 1 - -
B20 PT43A 1 T - PT47A 1 T -
A19 PT42B 1 C - PT46B 1 C -
B19 PT42A 1 T - PT46A 1 T -
C15 PT41B 1 C - PT45B 1 C -
D15 PT41A 1 T - PT45A 1 T -
A18 PT40B 1 C - PT44B 1 C -
B18 PT40A 1 T - PT44A 1 T -
F15 PT39B 1 C VREF1_1 PT43B 1 C VREF1_1
- GNDIO1 1 - - GNDIO1 1 - -
E15 PT39A 1 T DQS PT43A 1 T DQS
A17 PT38B 1 - - PT42B 1 - -
B17 PT37A 1 - - PT41A 1 - -
E14 PT36B 1 C - PT40B 1 C -
F14 PT36A 1 T - PT40A 1 T -
D14 PT35B 1 C - PT39B 1 C -
C14 PT35A 1 T D0 PT39A 1 T D0
A16 PT34B 1 C D1 PT38B 1 C D1
B16 PT34A 1 T VREF2_1 PT38A 1 T VREF2_1
A15 PT33B 1 C - PT37B 1 C -
B15 PT33A 1 T D2 PT37A 1 T D2
- GNDIO1 1 - - GNDIO1 1 - -
E13 PT32B 1 C D3 PT36B 1 C D3
D13 PT32A 1 T - PT36A 1 T -
C13 PT31B 1 C - PT35B 1 C -
B13 PT31A 1 T DQS PT35A 1 T DQS
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-51
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
A14 PT30B 1 - - PT34B 1 - -
B14 PT29A 1 - D4 PT33A 1 - D4
C12 PT28B 1 C - PT32B 1 C -
B12 PT28A 1 T D5 PT32A 1 T D5
- GNDIO1 1 - - GNDIO1 1 - -
D12 PT27B 1 C D6 PT31B 1 C D6
E12 PT27A 1 T - PT31A 1 T -
A13 PT26B 1 C D7 PT30B 1 C D7
A12 PT26A 1 T - PT30A 1 T -
A11 PT25B 0 C BUSY PT29B 0 C BUSY
- GNDIO0 0 - - GNDIO0 0 - -
A10 PT25A 0 T CS1N PT29A 0 T CS1N
D11 PT24B 0 C PCLKC0_0 PT28B 0 C PCLKC0_0
E11 PT24A 0 T PCLKT0_0 PT28A 0 T PCLKT0_0
B11 PT23B 0 C - PT27B 0 C -
C11 PT23A 0 T DQS PT27A 0 T DQS
B9 PT22B 0 - - PT26B 0 - -
A9 PT21A 0 - DOUT PT25A 0 - DOUT
B8 PT20B 0 C - PT24B 0 C -
- GNDIO0 0 - - GNDIO0 0 - -
A8 PT20A 0 T WRITEN PT24A 0 T WRITEN
E10 PT19B 0 C - PT23B 0 C -
D10 PT19A 0 T VREF1_0 PT23A 0 T VREF1_0
C10 PT18B 0 C - PT22B 0 C -
B10 PT18A 0 T DI PT22A 0 T DI
B7 PT17B 0 C - PT21B 0 C -
A7 PT17A 0 T CSN PT21A 0 T CSN
C9 PT16B 0 C - PT20B 0 C -
D9 PT16A 0 T - PT20A 0 T -
B6 PT15B 0 C VREF2_0 PT19B 0 C VREF2_0
A6 PT15A 0 T DQS PT19A 0 T DQS
F9 PT14B 0 - - PT18B 0 - -
E9 PT13A 0 - - PT17A 0 - -
- GNDIO0 0 - - GNDIO0 0 - -
B5 PT12B 0 C - PT16B 0 C -
A5 PT12A 0 T - PT16A 0 T -
C8 PT11B 0 C - PT15B 0 C -
D8 PT11A 0 T - PT15A 0 T -
B4 PT10B 0 C - PT14B 0 C -
A4 PT10A 0 T - PT14A 0 T -
F8PT9B0C - PT13B0C -
E8 PT9A 0 T - PT13A 0 T -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-52
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
B3 PT8B 0 C - PT12B 0 C -
A3 PT8A 0 T - PT12A 0 T -
- GNDIO0 0 - - GNDIO0 0 - -
D7PT7B0C - PT11B0C -
C7 PT7A 0 T DQS PT11A 0 T DQS
B2 PT6B 0 - - PT10B 0 - -
C2 PT5A 0 - - PT9A 0 - -
C3 PT4B 0 C - PT8B 0 C -
D3 PT4A 0 T - PT8A 0 T -
F7 PT3B 0 C - PT7B 0 C -
E7 PT3A 0 T - PT7A 0 T -
- GNDIO0 0 - - GNDIO0 0 - -
C6 - - - - PT6B 0 C -
D6 - - - - PT6A 0 T -
C5 - - - - PT5B 0 C -
C4 - - - - PT5A 0 T -
F6 - - - - PT4B 0 C -
E6 - - - - PT4A 0 T -
- GNDIO0 0 - - GNDIO0 0 - -
E4 - - - - PT3B 0 - -
E5 CFG0 0 - - CFG0 0 - -
D4 CFG1 0 - - CFG1 0 - -
D5 DONE 0 - - DONE 0 - -
A1 GND - - - GND - - -
A2 GND - - - GND - - -
A21 GND - - - GND - - -
A22 GND - - - GND - - -
AA1 GND - - - GND - - -
AA22 GND - - - GND - - -
AB1 GND - - - GND - - -
AB2 GND - - - GND - - -
AB21 GND - - - GND - - -
AB22 GND - - - GND - - -
B1 GND - - - GND - - -
B22 GND - - - GND - - -
H14 GND - - - GND - - -
H9 GND - - - GND - - -
J10 GND - - - GND - - -
J11 GND - - - GND - - -
J12 GND - - - GND - - -
J13 GND - - - GND - - -
J14 GND - - - GND - - -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-53
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
J15 GND - - - GND - - -
J8 GND - - - GND - - -
J9 GND - - - GND - - -
K10 GND - - - GND - - -
K11 GND - - - GND - - -
K12 GND - - - GND - - -
K13 GND - - - GND - - -
K14 GND - - - GND - - -
K9 GND - - - GND - - -
L10 GND - - - GND - - -
L11 GND - - - GND - - -
L12 GND - - - GND - - -
L13 GND - - - GND - - -
L14 GND - - - GND - - -
L9 GND - - - GND - - -
M10 GND - - - GND - - -
M11 GND - - - GND - - -
M12 GND - - - GND - - -
M13 GND - - - GND - - -
M14 GND - - - GND - - -
M9 GND - - - GND - - -
N10 GND - - - GND - - -
N11 GND - - - GND - - -
N12 GND - - - GND - - -
N13 GND - - - GND - - -
N14 GND - - - GND - - -
N9 GND - - - GND - - -
P10 GND - - - GND - - -
P11 GND - - - GND - - -
P12 GND - - - GND - - -
P13 GND - - - GND - - -
P14 GND - - - GND - - -
P15 GND - - - GND - - -
P8 GND - - - GND - - -
P9 GND - - - GND - - -
R14 GND - - - GND - - -
R9 GND - - - GND - - -
F10VCC-- - VCC-- -
F13VCC-- - VCC-- -
G10VCC-- - VCC-- -
G13VCC-- - VCC-- -
G14VCC-- - VCC-- -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-54
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
G9VCC---VCC---
H15 VCC - - - VCC - - -
H8VCC---VCC---
J16VCC-- - VCC-- -
J7VCC---VCC---
K16VCC-- - VCC-- -
K17VCC-- - VCC-- -
K6 VCC - - - VCC - - -
K7 VCC - - - VCC - - -
N16 VCC - - - VCC - - -
N17 VCC - - - VCC - - -
N6VCC---VCC---
N7VCC---VCC---
P16VCC-- - VCC-- -
P7 VCC - - - VCC - - -
R15 VCC - - - VCC - - -
R8VCC---VCC---
T10VCC-- - VCC-- -
T13VCC-- - VCC-- -
T14VCC-- - VCC-- -
T9VCC---VCC---
U10 VCC - - - VCC - - -
U13 VCC - - - VCC - - -
G15 VCCAUX - - - VCCAUX - - -
G16 VCCAUX - - - VCCAUX - - -
G7 VCCAUX - - - VCCAUX - - -
G8 VCCAUX - - - VCCAUX - - -
H16 VCCAUX - - - VCCAUX - - -
H7 VCCAUX - - - VCCAUX - - -
R16 VCCAUX - - - VCCAUX - - -
R7 VCCAUX - - - VCCAUX - - -
T15 VCCAUX - - - VCCAUX - - -
T16 VCCAUX - - - VCCAUX - - -
T7 VCCAUX - - - VCCAUX - - -
T8 VCCAUX - - - VCCAUX - - -
F11 VCCIO0 0 - - VCCIO0 0 - -
G11 VCCIO0 0 - - VCCIO0 0 - -
H10 VCCIO0 0 - - VCCIO0 0 - -
H11 VCCIO0 0 - - VCCIO0 0 - -
F12 VCCIO1 1 - - VCCIO1 1 - -
G12 VCCIO1 1 - - VCCIO1 1 - -
H12 VCCIO1 1 - - VCCIO1 1 - -
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-55
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
H13 VCCIO1 1 - - VCCIO1 1 - -
K15 VCCIO2 2 - - VCCIO2 2 - -
L15 VCCIO2 2 - - VCCIO2 2 - -
L16 VCCIO2 2 - - VCCIO2 2 - -
L17 VCCIO2 2 - - VCCIO2 2 - -
M15 VCCIO3 3 - - VCCIO3 3 - -
M16 VCCIO3 3 - - VCCIO3 3 - -
M17 VCCIO3 3 - - VCCIO3 3 - -
N15 VCCIO3 3 - - VCCIO3 3 - -
R12 VCCIO4 4 - - VCCIO4 4 - -
R13 VCCIO4 4 - - VCCIO4 4 - -
T12 VCCIO4 4 - - VCCIO4 4 - -
U12 VCCIO4 4 - - VCCIO4 4 - -
R10 VCCIO5 5 - - VCCIO5 5 - -
R11 VCCIO5 5 - - VCCIO5 5 - -
T11 VCCIO5 5 - - VCCIO5 5 - -
U11 VCCIO5 5 - - VCCIO5 5 - -
M6 VCCIO6 6 - - VCCIO6 6 - -
M7 VCCIO6 6 - - VCCIO6 6 - -
M8 VCCIO6 6 - - VCCIO6 6 - -
N8 VCCIO6 6 - - VCCIO6 6 - -
K8 VCCIO7 7 - - VCCIO7 7 - -
L6 VCCIO7 7 - - VCCIO7 7 - -
L7 VCCIO7 7 - - VCCIO7 7 - -
L8 VCCIO7 7 - - VCCIO7 7 - -
1. Applies to LFXP “C” only.
2. Applies to LFXP “E” only.
3. Supports dedicated LVDS outputs.
LFXP15 & LFXP20 Logic Signal Connections: 484 fpBGA (Cont.)
Ball
Number
LFXP15 LFXP20
Ball
Function Bank Differential
Dual
Function
Ball
Function Bank Differential
Dual
Function
4-56
Pinout Information
Lattice Semiconductor LatticeXP Family Data Sheet
Thermal Management
Thermal management is recommended as part of any sound FPGA design methodology. To assess the thermal
characteristics of a system, Lattice specifies a maximum allowable junction temperature in all device data sheets.
Designers must complete a thermal analysis of their specific design to ensure that the device and package do not
exceed the junction temperature limits. Refer to the Thermal Management document to find the device/package
specific thermal values.
For Further Information
For further information regarding Thermal Management, refer to the following located on the Lattice website at
www.latticesemi.com.
Thermal Management document
Technical Note TN1052 - Power Estimation and Management for LatticeECP/EC and LatticeXP Devices
Power Calculator tool included with Lattice’s ispLEVER design tool, or as a standalone download from
www.latticesemi.com/software
December 2005 Data Sheet DS1001
© 2005 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 5-1 DS1001 Ordering Information_03.0
Part Number Description
LFXP XX X – X XXXXXX X
Grade
C = Commercial
I = Industrial
Logic Capacity
3K LUTs = 3
6K LUTs = 6
10K LUTs = 10
15K LUTs = 15
20K LUTs = 20
Note: Parts dual marked per table below.
Supply Voltage
C = 1.8V/2.5V/3.3V
E = 1.2V
Speed
3 = Slowest
4
5 = Fastest
Package
T100 = 100-pin TQFP
T144 = 144-pin TQFP
Q208 = 208-pin PQFP
F256 = 256-ball fpBGA
F388 = 388-ball fpBGA
F484 = 484-ball fpBGA
TN100 = 100-pin Lead-free TQFP
TN144 = 144-pin Lead-free TQFP
QN208 = 208-pin Lead-free PQFP
FN256 = 256-ball Lead-free fpBGA
FN388 = 388-ball Lead-free fpBGA
FN484 = 484-ball Lead-free fpBGA
Device Family
LatticeXP FPGA
Ordering Information (Contact Factory for Specific Device Availability)
Note:þLatticeXP devices are dual marked. For example, the commercial speed grade LFXP10E-4F256C is also
marked with industrial grade -3I (LFXP10E-3F256I). The commercial grade is one speed grade faster than the
associated dual mark industrial grade. The slowest commercial speed grade does not have industrial markings.
The markings appear as follows:
LFXP10E-
4F256C-3I
Datecode
LatticeXP Family Data Sheet
Ordering Information
5-2
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Conventional Packaging
Commercial
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3C-3Q208C 136 1.8/2.5/3.3V -3 PQFP 208 COM 3.1K
LFXP3C-4Q208C 136 1.8/2.5/3.3V -4 PQFP 208 COM 3.1K
LFXP3C-5Q208C 136 1.8/2.5/3.3V -5 PQFP 208 COM 3.1K
LFXP3C-3T144C 100 1.8/2.5/3.3V -3 TQFP 144 COM 3.1K
LFXP3C-4T144C 100 1.8/2.5/3.3V -4 TQFP 144 COM 3.1K
LFXP3C-5T144C 100 1.8/2.5/3.3V -5 TQFP 144 COM 3.1K
LFXP3C-3T100C 62 1.8/2.5/3.3V -3 TQFP 100 COM 3.1K
LFXP3C-4T100C 62 1.8/2.5/3.3V -4 TQFP 100 COM 3.1K
LFXP3C-5T100C 62 1.8/2.5/3.3V -5 TQFP 100 COM 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6C-3F256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 5.8K
LFXP6C-4F256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 5.8K
LFXP6C-5F256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 5.8K
LFXP6C-3Q208C 142 1.8/2.5/3.3V -3 PQFP 208 COM 5.8K
LFXP6C-4Q208C 142 1.8/2.5/3.3V -4 PQFP 208 COM 5.8K
LFXP6C-5Q208C 142 1.8/2.5/3.3V -5 PQFP 208 COM 5.8K
LFXP6C-3T144C 100 1.8/2.5/3.3V -3 TQFP 144 COM 5.8K
LFXP6C-4T144C 100 1.8/2.5/3.3V -4 TQFP 144 COM 5.8K
LFXP6C-5T144C 100 1.8/2.5/3.3V -5 TQFP 144 COM 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10C-3F388C 244 1.8/2.5/3.3V -3 fpBGA 388 COM 9.7K
LFXP10C-4F388C 244 1.8/2.5/3.3V -4 fpBGA 388 COM 9.7K
LFXP10C-5F388C 244 1.8/2.5/3.3V -5 fpBGA 388 COM 9.7K
LFXP10C-3F256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 9.7K
LFXP10C-4F256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 9.7K
LFXP10C-5F256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 9.7K
5-3
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Commercial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15C-3F484C 300 1.8/2.5/3.3V -3 fpBGA 484 COM 15.5K
LFXP15C-4F484C 300 1.8/2.5/3.3V -4 fpBGA 484 COM 15.5K
LFXP15C-5F484C 300 1.8/2.5/3.3V -5 fpBGA 484 COM 15.5K
LFXP15C-3F388C 268 1.8/2.5/3.3V -3 fpBGA 388 COM 15.5K
LFXP15C-4F388C 268 1.8/2.5/3.3V -4 fpBGA 388 COM 15.5K
LFXP15C-5F388C 268 1.8/2.5/3.3V -5 fpBGA 388 COM 15.5K
LFXP15C-3F256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 15.5K
LFXP15C-4F256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 15.5K
LFXP15C-5F256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20C-3F484C 340 1.8/2.5/3.3V -3 fpBGA 484 COM 19.7K
LFXP20C-4F484C 340 1.8/2.5/3.3V -4 fpBGA 484 COM 19.7K
LFXP20C-5F484C 340 1.8/2.5/3.3V -5 fpBGA 484 COM 19.7K
LFXP20C-3F388C 268 1.8/2.5/3.3V -3 fpBGA 388 COM 19.7K
LFXP20C-4F388C 268 1.8/2.5/3.3V -4 fpBGA 388 COM 19.7K
LFXP20C-5F388C 268 1.8/2.5/3.3V -5 fpBGA 388 COM 19.7K
LFXP20C-3F256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 19.7K
LFXP20C-4F256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 19.7K
LFXP20C-5F256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3E-3Q208C 136 1.2V -3 PQFP 208 COM 3.1K
LFXP3E-4Q208C 136 1.2V -4 PQFP 208 COM 3.1K
LFXP3E-5Q208C 136 1.2V -5 PQFP 208 COM 3.1K
LFXP3E-3T144C 100 1.2V -3 TQFP 144 COM 3.1K
LFXP3E-4T144C 100 1.2V -4 TQFP 144 COM 3.1K
LFXP3E-5T144C 100 1.2V -5 TQFP 144 COM 3.1K
LFXP3E-3T100C 62 1.2V -3 TQFP 100 COM 3.1K
LFXP3E-4T100C 62 1.2V -4 TQFP 100 COM 3.1K
LFXP3E-5T100C 62 1.2V -5 TQFP 100 COM 3.1K
5-4
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Commercial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6E-3F256C 188 1.2V -3 fpBGA 256 COM 5.8K
LFXP6E-4F256C 188 1.2V -4 fpBGA 256 COM 5.8K
LFXP6E-5F256C 188 1.2V -5 fpBGA 256 COM 5.8K
LFXP6E-3Q208C 142 1.2V -3 PQFP 208 COM 5.8K
LFXP6E-4Q208C 142 1.2V -4 PQFP 208 COM 5.8K
LFXP6E-5Q208C 142 1.2V -5 PQFP 208 COM 5.8K
LFXP6E-3T144C 100 1.2V -3 TQFP 144 COM 5.8K
LFXP6E-4T144C 100 1.2V -4 TQFP 144 COM 5.8K
LFXP6E-5T144C 100 1.2V -5 TQFP 144 COM 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10E-3F388C 244 1.2V -3 fpBGA 388 COM 9.7K
LFXP10E-4F388C 244 1.2V -4 fpBGA 388 COM 9.7K
LFXP10E-5F388C 244 1.2V -5 fpBGA 388 COM 9.7K
LFXP10E-3F256C 188 1.2V -3 fpBGA 256 COM 9.7K
LFXP10E-4F256C 188 1.2V -4 fpBGA 256 COM 9.7K
LFXP10E-5F256C 188 1.2V -5 fpBGA 256 COM 9.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15E-3F484C 300 1.2V -3 fpBGA 484 COM 15.5K
LFXP15E-4F484C 300 1.2V -4 fpBGA 484 COM 15.5K
LFXP15E-5F484C 300 1.2V -5 fpBGA 484 COM 15.5K
LFXP15E-3F388C 268 1.2V -3 fpBGA 388 COM 15.5K
LFXP15E-4F388C 268 1.2V -4 fpBGA 388 COM 15.5K
LFXP15E-5F388C 268 1.2V -5 fpBGA 388 COM 15.5K
LFXP15E-3F256C 188 1.2V -3 fpBGA 256 COM 15.5K
LFXP15E-4F256C 188 1.2V -4 fpBGA 256 COM 15.5K
LFXP15E-5F256C 188 1.2V -5 fpBGA 256 COM 15.5K
5-5
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Commercial (Cont.)
Industrial
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20E-3F484C 340 1.2V -3 fpBGA 484 COM 19.7K
LFXP20E-4F484C 340 1.2V -4 fpBGA 484 COM 19.7K
LFXP20E-5F484C 340 1.2V -5 fpBGA 484 COM 19.7K
LFXP20E-3F388C 268 1.2V -3 fpBGA 388 COM 19.7K
LFXP20E-4F388C 268 1.2V -4 fpBGA 388 COM 19.7K
LFXP20E-5F388C 268 1.2V -5 fpBGA 388 COM 19.7K
LFXP20E-3F256C 188 1.2V -3 fpBGA 256 COM 19.7K
LFXP20E-4F256C 188 1.2V -4 fpBGA 256 COM 19.7K
LFXP20E-5F256C 188 1.2V -5 fpBGA 256 COM 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3C-3Q208I 136 1.8/2.5/3.3V -3 PQFP 208 IND 3.1K
LFXP3C-4Q208I 136 1.8/2.5/3.3V -4 PQFP 208 IND 3.1K
LFXP3C-3T144I 100 1.8/2.5/3.3V -3 TQFP 144 IND 3.1K
LFXP3C-4T144I 100 1.8/2.5/3.3V -4 TQFP 144 IND 3.1K
LFXP3C-3T100I 62 1.8/2.5/3.3V -3 TQFP 100 IND 3.1K
LFXP3C-4T100I 62 1.8/2.5/3.3V -4 TQFP 100 IND 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6C-3F256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 5.8K
LFXP6C-4F256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 5.8K
LFXP6C-3Q208I 142 1.8/2.5/3.3V -3 PQFP 208 IND 5.8K
LFXP6C-4Q208I 142 1.8/2.5/3.3V -4 PQFP 208 IND 5.8K
LFXP6C-3T144I 100 1.8/2.5/3.3V -3 TQFP 144 IND 5.8K
LFXP6C-4T144I 100 1.8/2.5/3.3V -4 TQFP 144 IND 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10C-3F388I 244 1.8/2.5/3.3V -3 fpBGA 388 IND 9.7K
LFXP10C-4F388I 244 1.8/2.5/3.3V -4 fpBGA 388 IND 9.7K
LFXP10C-3F256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 9.7K
LFXP10C-4F256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 9.7K
5-6
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Industrial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15C-3F484I 300 1.8/2.5/3.3V -3 fpBGA 484 IND 15.5K
LFXP15C-4F484I 300 1.8/2.5/3.3V -4 fpBGA 484 IND 15.5K
LFXP15C-3F388I 268 1.8/2.5/3.3V -3 fpBGA 388 IND 15.5K
LFXP15C-4F388I 268 1.8/2.5/3.3V -4 fpBGA 388 IND 15.5K
LFXP15C-3F256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 15.5K
LFXP15C-4F256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20C-3F484I 340 1.8/2.5/3.3V -3 fpBGA 484 IND 19.7K
LFXP20C-4F484I 340 1.8/2.5/3.3V -4 fpBGA 484 IND 19.7K
LFXP20C-3F388I 268 1.8/2.5/3.3V -3 fpBGA 388 IND 19.7K
LFXP20C-4F388I 268 1.8/2.5/3.3V -4 fpBGA 388 IND 19.7K
LFXP20C-3F256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 19.7K
LFXP20C-4F256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3E-3Q208I 136 1.2V -3 PQFP 208 IND 3.1K
LFXP3E-4Q208I 136 1.2V -4 PQFP 208 IND 3.1K
LFXP3E-3T144I 100 1.2V -3 TQFP 144 IND 3.1K
LFXP3E-4T144I 100 1.2V -4 TQFP 144 IND 3.1K
LFXP3E-3T100I 62 1.2V -3 TQFP 100 IND 3.1K
LFXP3E-4T100I 62 1.2V -4 TQFP 100 IND 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6E-3F256I 188 1.2V -3 fpBGA 256 IND 5.8K
LFXP6E-4F256I 188 1.2V -4 fpBGA 256 IND 5.8K
LFXP6E-3Q208I 142 1.2V -3 PQFP 208 IND 5.8K
LFXP6E-4Q208I 142 1.2V -4 PQFP 208 IND 5.8K
LFXP6E-3T144I 100 1.2V -3 TQFP 144 IND 5.8K
LFXP6E-4T144I 100 1.2V -4 TQFP 144 IND 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10E-3F388I 244 1.2V -3 fpBGA 388 IND 9.7K
LFXP10E-4F388I 244 1.2V -4 fpBGA 388 IND 9.7K
LFXP10E-3F256I 188 1.2V -3 fpBGA 256 IND 9.7K
LFXP10E-4F256I 188 1.2V -4 fpBGA 256 IND 9.7K
5-7
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Industrial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15E-3F484I 300 1.2V -3 fpBGA 484 IND 15.5K
LFXP15E-4F484I 300 1.2V -4 fpBGA 484 IND 15.5K
LFXP15E-3F388I 268 1.2V -3 fpBGA 388 IND 15.5K
LFXP15E-4F388I 268 1.2V -4 fpBGA 388 IND 15.5K
LFXP15E-3F256I 188 1.2V -3 fpBGA 256 IND 15.5K
LFXP15E-4F256I 188 1.2V -4 fpBGA 256 IND 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20E-3F484I 340 1.2V -3 fpBGA 484 IND 19.7K
LFXP20E-4F484I 340 1.2V -4 fpBGA 484 IND 19.7K
LFXP20E-3F388I 268 1.2V -3 fpBGA 388 IND 19.7K
LFXP20E-4F388I 268 1.2V -4 fpBGA 388 IND 19.7K
LFXP20E-3F256I 188 1.2V -3 fpBGA 256 IND 19.7K
LFXP20E-4F256I 188 1.2V -4 fpBGA 256 IND 19.7K
5-8
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Lead-free Packaging
Commercial
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3C-3QN208C 136 1.8/2.5/3.3V -3 PQFP 208 COM 3.1K
LFXP3C-4QN208C 136 1.8/2.5/3.3V -4 PQFP 208 COM 3.1K
LFXP3C-5QN208C 136 1.8/2.5/3.3V -5 PQFP 208 COM 3.1K
LFXP3C-3TN144C 100 1.8/2.5/3.3V -3 TQFP 144 COM 3.1K
LFXP3C-4TN144C 100 1.8/2.5/3.3V -4 TQFP 144 COM 3.1K
LFXP3C-5TN144C 100 1.8/2.5/3.3V -5 TQFP 144 COM 3.1K
LFXP3C-3TN100C 62 1.8/2.5/3.3V -3 TQFP 100 COM 3.1K
LFXP3C-4TN100C 62 1.8/2.5/3.3V -4 TQFP 100 COM 3.1K
LFXP3C-5TN100C 62 1.8/2.5/3.3V -5 TQFP 100 COM 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6C-3FN256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 5.8K
LFXP6C-4FN256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 5.8K
LFXP6C-5FN256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 5.8K
LFXP6C-3QN208C 142 1.8/2.5/3.3V -3 PQFP 208 COM 5.8K
LFXP6C-4QN208C 142 1.8/2.5/3.3V -4 PQFP 208 COM 5.8K
LFXP6C-5QN208C 142 1.8/2.5/3.3V -5 PQFP 208 COM 5.8K
LFXP6C-3TN144C 100 1.8/2.5/3.3V -3 TQFP 144 COM 5.8K
LFXP6C-4TN144C 100 1.8/2.5/3.3V -4 TQFP 144 COM 5.8K
LFXP6C-5TN144C 100 1.8/2.5/3.3V -5 TQFP 144 COM 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10C-3FN388C 244 1.8/2.5/3.3V -3 fpBGA 388 COM 9.7K
LFXP10C-4FN388C 244 1.8/2.5/3.3V -4 fpBGA 388 COM 9.7K
LFXP10C-5FN388C 244 1.8/2.5/3.3V -5 fpBGA 388 COM 9.7K
LFXP10C-3FN256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 9.7K
LFXP10C-4FN256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 9.7K
LFXP10C-5FN256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 9.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15C-3FN484C 300 1.8/2.5/3.3V -3 fpBGA 484 COM 15.5K
LFXP15C-4FN484C 300 1.8/2.5/3.3V -4 fpBGA 484 COM 15.5K
LFXP15C-5FN484C 300 1.8/2.5/3.3V -5 fpBGA 484 COM 15.5K
LFXP15C-3FN388C 268 1.8/2.5/3.3V -3 fpBGA 388 COM 15.5K
LFXP15C-4FN388C 268 1.8/2.5/3.3V -4 fpBGA 388 COM 15.5K
LFXP15C-5FN388C 268 1.8/2.5/3.3V -5 fpBGA 388 COM 15.5K
LFXP15C-3FN256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 15.5K
LFXP15C-4FN256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 15.5K
LFXP15C-5FN256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 15.5K
5-9
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Commercial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20C-3FN484C 340 1.8/2.5/3.3V -3 fpBGA 484 COM 19.7K
LFXP20C-4FN484C 340 1.8/2.5/3.3V -4 fpBGA 484 COM 19.7K
LFXP20C-5FN484C 340 1.8/2.5/3.3V -5 fpBGA 484 COM 19.7K
LFXP20C-3FN388C 268 1.8/2.5/3.3V -3 fpBGA 388 COM 19.7K
LFXP20C-4FN388C 268 1.8/2.5/3.3V -4 fpBGA 388 COM 19.7K
LFXP20C-5FN388C 268 1.8/2.5/3.3V -5 fpBGA 388 COM 19.7K
LFXP20C-3FN256C 188 1.8/2.5/3.3V -3 fpBGA 256 COM 19.7K
LFXP20C-4FN256C 188 1.8/2.5/3.3V -4 fpBGA 256 COM 19.7K
LFXP20C-5FN256C 188 1.8/2.5/3.3V -5 fpBGA 256 COM 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3E-3QN208C 136 1.2V -3 PQFP 208 COM 3.1K
LFXP3E-4QN208C 136 1.2V -4 PQFP 208 COM 3.1K
LFXP3E-5QN208C 136 1.2V -5 PQFP 208 COM 3.1K
LFXP3E-3TN144C 100 1.2V -3 TQFP 144 COM 3.1K
LFXP3E-4TN144C 100 1.2V -4 TQFP 144 COM 3.1K
LFXP3E-5TN144C 100 1.2V -5 TQFP 144 COM 3.1K
LFXP3E-3TN100C 62 1.2V -3 TQFP 100 COM 3.1K
LFXP3E-4TN100C 62 1.2V -4 TQFP 100 COM 3.1K
LFXP3E-5TN100C 62 1.2V -5 TQFP 100 COM 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6E-3FN256C 188 1.2V -3 fpBGA 256 COM 5.8K
LFXP6E-4FN256C 188 1.2V -4 fpBGA 256 COM 5.8K
LFXP6E-5FN256C 188 1.2V -5 fpBGA 256 COM 5.8K
LFXP6E-3QN208C 142 1.2V -3 PQFP 208 COM 5.8K
LFXP6E-4QN208C 142 1.2V -4 PQFP 208 COM 5.8K
LFXP6E-5QN208C 142 1.2V -5 PQFP 208 COM 5.8K
LFXP6E-3TN144C 100 1.2V -3 TQFP 144 COM 5.8K
LFXP6E-4TN144C 100 1.2V -4 TQFP 144 COM 5.8K
LFXP6E-5TN144C 100 1.2V -5 TQFP 144 COM 5.8K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10E-3FN388C 244 1.2V -3 fpBGA 388 COM 9.7K
LFXP10E-4FN388C 244 1.2V -4 fpBGA 388 COM 9.7K
LFXP10E-5FN388C 244 1.2V -5 fpBGA 388 COM 9.7K
LFXP10E-3FN256C 188 1.2V -3 fpBGA 256 COM 9.7K
LFXP10E-4FN256C 188 1.2V -4 fpBGA 256 COM 9.7K
LFXP10E-5FN256C 188 1.2V -5 fpBGA 256 COM 9.7K
5-10
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Commercial (Cont.)
Industrial
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15E-3FN484C 300 1.2V -3 fpBGA 484 COM 15.5K
LFXP15E-4FN484C 300 1.2V -4 fpBGA 484 COM 15.5K
LFXP15E-5FN484C 300 1.2V -5 fpBGA 484 COM 15.5K
LFXP15E-3FN388C 268 1.2V -3 fpBGA 388 COM 15.5K
LFXP15E-4FN388C 268 1.2V -4 fpBGA 388 COM 15.5K
LFXP15E-5FN388C 268 1.2V -5 fpBGA 388 COM 15.5K
LFXP15E-3FN256C 188 1.2V -3 fpBGA 256 COM 15.5K
LFXP15E-4FN256C 188 1.2V -4 fpBGA 256 COM 15.5K
LFXP15E-5FN256C 188 1.2V -5 fpBGA 256 COM 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20E-3FN484C 340 1.2V -3 fpBGA 484 COM 19.7K
LFXP20E-4FN484C 340 1.2V -4 fpBGA 484 COM 19.7K
LFXP20E-5FN484C 340 1.2V -5 fpBGA 484 COM 19.7K
LFXP20E-3FN388C 268 1.2V -3 fpBGA 388 COM 19.7K
LFXP20E-4FN388C 268 1.2V -4 fpBGA 388 COM 19.7K
LFXP20E-5FN388C 268 1.2V -5 fpBGA 388 COM 19.7K
LFXP20E-3FN256C 188 1.2V -3 fpBGA 256 COM 19.7K
LFXP20E-4FN256C 188 1.2V -4 fpBGA 256 COM 19.7K
LFXP20E-5FN256C 188 1.2V -5 fpBGA 256 COM 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3C-3QN208I 136 1.8/2.5/3.3V -3 PQFP 208 IND 3.1K
LFXP3C-4QN208I 136 1.8/2.5/3.3V -4 PQFP 208 IND 3.1K
LFXP3C-3TN144I 100 1.8/2.5/3.3V -3 TQFP 144 IND 3.1K
LFXP3C-4TN144I 100 1.8/2.5/3.3V -4 TQFP 144 IND 3.1K
LFXP3C-3TN100I 62 1.8/2.5/3.3V -3 TQFP 100 IND 3.1K
LFXP3C-4TN100I 62 1.8/2.5/3.3V -4 TQFP 100 IND 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6C-3FN256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 5.8K
LFXP6C-4FN256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 5.8K
LFXP6C-3QN208I 142 1.8/2.5/3.3V -3 PQFP 208 IND 5.8K
LFXP6C-4QN208I 142 1.8/2.5/3.3V -4 PQFP 208 IND 5.8K
LFXP6C-3TN144I 100 1.8/2.5/3.3V -3 TQFP 144 IND 5.8K
LFXP6C-4TN144I 100 1.8/2.5/3.3V -4 TQFP 144 IND 5.8K
5-11
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Industrial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10C-3FN388I 244 1.8/2.5/3.3V -3 fpBGA 388 IND 9.7K
LFXP10C-4FN388I 244 1.8/2.5/3.3V -4 fpBGA 388 IND 9.7K
LFXP10C-3FN256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 9.7K
LFXP10C-4FN256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 9.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15C-3FN484I 300 1.8/2.5/3.3V -3 fpBGA 484 IND 15.5K
LFXP15C-4FN484I 300 1.8/2.5/3.3V -4 fpBGA 484 IND 15.5K
LFXP15C-3FN388I 268 1.8/2.5/3.3V -3 fpBGA 388 IND 15.5K
LFXP15C-4FN388I 268 1.8/2.5/3.3V -4 fpBGA 388 IND 15.5K
LFXP15C-3FN256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 15.5K
LFXP15C-4FN256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20C-3FN484I 340 1.8/2.5/3.3V -3 fpBGA 484 IND 19.7K
LFXP20C-4FN484I 340 1.8/2.5/3.3V -4 fpBGA 484 IND 19.7K
LFXP20C-3FN388I 268 1.8/2.5/3.3V -3 fpBGA 388 IND 19.7K
LFXP20C-4FN388I 268 1.8/2.5/3.3V -4 fpBGA 388 IND 19.7K
LFXP20C-3FN256I 188 1.8/2.5/3.3V -3 fpBGA 256 IND 19.7K
LFXP20C-4FN256I 188 1.8/2.5/3.3V -4 fpBGA 256 IND 19.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP3E-3QN208I 136 1.2V -3 PQFP 208 IND 3.1K
LFXP3E-4QN208I 136 1.2V -4 PQFP 208 IND 3.1K
LFXP3E-3TN144I 100 1.2V -3 TQFP 144 IND 3.1K
LFXP3E-4TN144I 100 1.2V -4 TQFP 144 IND 3.1K
LFXP3E-3TN100I 62 1.2V -3 TQFP 100 IND 3.1K
LFXP3E-4TN100I 62 1.2V -4 TQFP 100 IND 3.1K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP6E-3FN256I 188 1.2V -3 fpBGA 256 IND 5.8K
LFXP6E-4FN256I 188 1.2V -4 fpBGA 256 IND 5.8K
LFXP6E-3QN208I 142 1.2V -3 PQFP 208 IND 5.8K
LFXP6E-4QN208I 142 1.2V -4 PQFP 208 IND 5.8K
LFXP6E-3TN144I 100 1.2V -3 TQFP 144 IND 5.8K
LFXP6E-4TN144I 100 1.2V -4 TQFP 144 IND 5.8K
5-12
Ordering Information
Lattice Semiconductor LatticeXP Family Data Sheet
Industrial (Cont.)
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP10E-3FN388I 244 1.2V -3 fpBGA 388 IND 9.7K
LFXP10E-4FN388I 244 1.2V -4 fpBGA 388 IND 9.7K
LFXP10E-3FN256I 188 1.2V -3 fpBGA 256 IND 9.7K
LFXP10E-4FN256I 188 1.2V -4 fpBGA 256 IND 9.7K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP15E-3FN484I 300 1.2V -3 fpBGA 484 IND 15.5K
LFXP15E-4FN484I 300 1.2V -4 fpBGA 484 IND 15.5K
LFXP15E-3FN388I 268 1.2V -3 fpBGA 388 IND 15.5K
LFXP15E-4FN388I 268 1.2V -4 fpBGA 388 IND 15.5K
LFXP15E-3FN256I 188 1.2V -3 fpBGA 256 IND 15.5K
LFXP15E-4FN256I 188 1.2V -4 fpBGA 256 IND 15.5K
Part Number I/Os Voltage Grade Package Pins Temp. LUTs
LFXP20E-3FN484I 340 1.2V -3 fpBGA 484 IND 19.7K
LFXP20E-4FN484I 340 1.2V -4 fpBGA 484 IND 19.7K
LFXP20E-3FN388I 268 1.2V -3 fpBGA 388 IND 19.7K
LFXP20E-4FN388I 268 1.2V -4 fpBGA 388 IND 19.7K
LFXP20E-3FN256I 188 1.2V -3 fpBGA 256 IND 19.7K
LFXP20E-4FN256I 188 1.2V -4 fpBGA 256 IND 19.7K
November 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 6-1 DS1001 Further Information_01.3
For Further Information
A variety of technical notes for the LatticeXP family are available on the Lattice website at www.latticesemi.com.
LatticeECP/EC and LatticeXP sysIO Usage Guide (TN1056)
Lattice ispTRACY Usage Guide (TN1054)
LatticeECP/EC and LatticeXP sysCLOCK PLL Design and Usage Guide (TN1049)
Memory Usage Guide for LatticeECP/EC and LatticeXP Devices (TN1051)
LatticeECP/EC and XP DDR Usage Guide (TN1050)
Power Estimation and Management for LatticeECP/EC and LatticeXP Devices (TN1052)
LatticeXP sysCONFIG Usage Guide (TN1082)
For further information on interface standards refer to the following web sites:
JEDEC Standards (LVTTL, LVCMOS, SSTL, HSTL): www.jedec.org
PCI: www.pcisig.com
LatticeXP Family Data Sheet
Supplemental Information
November 2007 Data Sheet DS1001
© 2007 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand
or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice.
www.latticesemi.com 7-1
Revision History
Date Version Section Change Summary
February 2005 01.0 Initial release.
April 2005 01.1 Architecture EBR memory support section updated with clarification.
May 2005 01.2 Introduction Added TransFR Reconfiguration to Features section.
Architecture Added TransFR section.
June 2005 01.3 Pinout Information Added pinout information for LFXP3, LFXP6, LFXP15 and LFXP20.
July 2005 02.0 Introduction Updated XP6, XP15 and XP20 EBR SRAM Bits and Block numbers.
Architecture Updated Per Quadrant Primary Clock Selection figure.
Added Typical I/O Behavior During Power-up section.
Updated Device Configuration section under Configuration and Testing.
DC and Switching
Characteristics Clarified Hot Socketing Specification
Updated Supply Current (Standby) Table
Updated Initialization Supply Current Table
Added Programming and Erase Flash Supply Current table
Added LVDS Emulation section. Updated LVDS25E Output Termination
Example figure and LVDS25E DC Conditions table.
Updated Differential LVPECL diagram and LVPECL DC Conditions
table.
Deleted 5V Tolerant Input Buffer section. Updated RSDS figure and
RSDS DC Conditions table.
Updated sysCONFIG Port Timing Specifications
Updated JTAG Port Timing Specifications. Added Flash Download
Time table.
Pinout Information Updated Signal Descriptions table.
Updated Logic Signal Connections Dual Function column.
Ordering Information Added lead-free ordering part numbers.
July 2005 02.1 DC and Switching
Characteristics Clarification of Flash Programming Junction Temperature
August 2005 02.2 Introduction Added Sleep Mode feature.
Architecture Added Sleep Mode section.
DC and Switching
Characteristics Added Sleep Mode Supply Current Table
Added Sleep Mode Timing section
Pinout Information Added SLEEPN and TOE signal names, descriptions and footnotes.
Added SLEEPN and TOE to pinout information and footnotes.
Added footnote 3 to Logic Signal Connections tables for clarification on
emulated LVDS output.
September 2005 03.0 Architecture Added clarification of PCI clamp.
Added clarification to SLEEPN Pin Characteristics section.
DC and Switching
Characteristics DC Characteristics, added footnote 4 for clarification. Updated Supply
Current (Sleep Mode), Supply Current (Standby), Initialization Supply
Current, and Programming and Erase Flash Supply Current typical
numbers.
LatticeXP Family Data Sheet
Revision History
7-2
Revision History
Lattice Semiconductor LatticeXP Family Data Sheet
September 2005
(cont.) 03.0
(cont.) DC and Switching
Characteristics (cont.) Updated Typical Building Block Function Performance timing numbers.
Updated External Switching Characteristics timing numbers.
Updated Internal Timing Parameters.
Updated LatticeXP Family timing adders.
Updated LatticeXP "C" Sleep Mode timing numbers.
Updated JTAG Port Timing numbers.
Pinout Information Added clarification to SLEEPN and TOE description.
Clarification of dedicated LVDS outputs.
Supplemental
Information Updated list of technical notes.
September 2005 03.1 Pinout Information Power Supply and NC Connections table corrected VCCP1 pin number
for 208 PQFP.
December 2005 04.0 Introduction Moved data sheet from Advance to Final.
Architecture Added clarification to Typical I/O Behavior During Power-up section.
DC and Switching
Characteristics Added clarification to Recommended Operating Conditions.
Updated timing numbers.
Pinout Information Updated Signal Descriptions table.
Added clarification to Differential I/O Per Bank.
Updated Differential dedicated LVDS output support.
Ordering Information Added 208 PQFP lead-free package and ordering part numbers.
February 2006 04.1 Pinout Information Corrected description of Signal Names VREF1(x) and VREF2(x).
March 2006 04.2 DC and Switching
Characteristics Corrected condition for IIL and IIH.
March 2006 04.3 DC and Switching
Characteristics Added clarification to Recommended Operating Conditions for
VCCAUX.
April 2006 04.4 Pinout Information Removed Bank designator "5" from SLEEPN/TOE ball function.
May 2006 04.5 DC and Switching
Characteristics Added footnote 2 regarding threshold level for PROGRAMN to sysCON-
FIG Port Timing Specifications table.
June 2006 04.6 DC and Switching
Characteristics Corrected LVDS25E Output Termination Example.
August 2006 04.7 Architecture Added clarification to Typical I/O Behavior During Power-Up section.
Added clarification to Left and Right sysIO Buffer Pair section.
DC and Switching
Characteristics Changes to LVDS25E Output Termination Example diagram.
December 2006 04.8 Architecture EBR Asynchronous Reset section added.
February 2007 04.9 Architecture Updated EBR Asynchronous Reset section.
July 2007 05.0 Introduction Updated LatticeXP Family Selection Guide table.
Architecture Updated Typical I/O Behavior During Power-up text section.
DC and Switching
Characteristics Updated sysIO Single-Ended DC Electrical Characteristics table. Split
out LVCMOS 1.2 by supply voltage.
November 2007 05.1 DC and Switching
Characteristics Added JTAG Port Timing Waveforms diagram.
Pinout Information Added Thermal Management text section.
Supplemental
Information Updated title list.
Date Version Section Change Summary