AT94S10AL-25DGC - Atmel Corporation

Features

•Multichip Module Containing Field Programmable System Level Integrated Circuit

(FPSLIC®) and Secure Configuration EEPROM Memory

•512 Kbits to 1 Mbit of Configuration Memory with Security Protection and In-System

Programming (ISP)

•Field Programmable System Level Integrated Circuit (FPSLIC)

– AT40K SRAM-based FPGA with Embedded High-performance RISC AVR® Core and

Extensive Data and Instruction SRAM

•5,000 to 40,000 Gates of Patented SRAM-based AT40K FPGA with FreeRAM™

– 2 - 18.4 Kbits of Distributed Single/Dual Port FPGA User SRAM

– High-performance DSP Optimized FPGA Core Cell

– Dynamically Reconfigurable In-System – FPGA Configuration Access Available

On-chip from AVR Microcontroller Core to Support Cache Logic® Designs

– Very Low Static and Dynamic Power Consumption – Ideal for Portable and

Handheld Applications

•Patented AVR Enhanced RISC Architecture

– 120+ Powerful Instructions – Most Single Clock Cycle Execution

– High-performance Hardware Multiplier for DSP-based Systems

– Approaching 1 MIPS per MHz Performance

– C Code Optimized Architecture with 32 x 8 General-purpose Internal Registers

– Low-power Idle, Power-save, and Power-down Modes

– 100 µA Standby and Typical 2-3 mA per MHz Active

•Up to 36 Kbytes of Dynamically Allocated Instruction and Data SRAM

– Up to 16 Kbytes x 16 Internal 15 ns Instructions SRAM

– Up to 16 Kbytes x 8 Internal 15 ns Data SRAM

•JTAG (IEEE Std. 1149.1 Compliant) Interface

– Extensive On-chip Debug Support

– Limited Boundary-scan Capabilities According to the JTAG Standards (AVR Ports)

•AVR Fixed Peripherals

– Industry-standard 2-wire Serial Interface

– Two Programmable Serial UARTs

– Two 8-bit Timer/Counters with Separate Prescaler and PWM

– One 16-bit Timer/Counter with Separate Prescaler, Compare, Capture

Modes and Dual 8-, 9- or 10-bit PWM

•Support for FPGA Custom Peripherals

– AVR Peripheral Control – Up to 16 Decoded AVR Address Lines Directly

Accessible to FPGA

– FPGA Macro Library of Custom Peripherals

•Up to 16 FPGA Supplied Internal Interrupts to AVR

•Up to Four External Interrupts to AVR

•8 Global FPGA Clocks

– Two FPGA Clocks Driven from AVR Logic

– FPGA Global Clock Access Available from FPGA Core

•Multiple Oscillator Circuits

– Programmable Watchdog Timer with On-chip Oscillator

– Oscillator to AVR Internal Clock Circuit

– Software-selectable Clock Frequency

– Oscillator to Timer/Counter for Real-time Clock

Secure

5K - 40K Gates

of AT40K FPGA

with 8-bit

Microcontroller,

up to 36 Kbytes

of SRAM and

On-chip

Program

Storage

EEPROM

AT94S

Secure Series

Programmable

SLI

2314E–FPSLI–6/05

AT94S Secure Family

•VCC: 3.0V - 3.6V

•5V Tolerant I/O

•3.3V 33 MHz PCI Compliant FPGA I/O

– 20 mA Sink/Source High-performance I/O Structures

– All FPGA I/O Individually Programmable

•High-performance, Low-power 0.35µ CMOS Five-layer Metal Process

•State-of-the-art Integrated PC-based Software Suite including Co-verification

1. Description

The AT94S Series (Secure FPSLIC family) shown in Table 1-1 is a combination of the popular

Atmel AT40K Series SRAM FPGAs, the AT17 Series Configuration Memories and the high-per-

formance Atmel AVR 8-bit RISC microcontroller with standard peripherals. Extensive data and

instruction SRAM as well as device control and management logic are included in this multi-chip

module (MCM).

The embedded AT40K FPGA core is a fully 3.3V PCI-compliant, SRAM-based FPGA with dis-

tributed 10 ns programmable synchronous/asynchronous, dual-port/single-port SRAM, 8 global

clocks, Cache Logic ability (partially or fully reconfigurable without loss of data) and 5,000 to

40,000 usable gates.

Table 1-1. The AT94S Series Family

Device AT94S05AL AT94S10AL AT94S40AL

Configuration Memory Size 1 Mbit 1 Mbit 1 Mbit

FPGA Gates 5K 10K 40K

FPGA Core Cells 256 576 2304

FPGA SRAM Bits 2048 4096 18432

FPGA Registers (Total) 436 846 2862

Maximum FPGA User I/O 93 137 162

AVR Programmable I/O Lines 8 16 16

Program SRAM Bytes 4K - 16K 20K - 32K 20K - 32K

Data SRAM Bytes 4K - 16K 4K - 16K 4K - 16K

Hardware Multiplier (8-bit) Yes Yes Yes

2-wire Serial Interface Yes Yes Yes

UARTs 2 2 2

Watchdog Timer Yes Yes Yes

Timer/Counters 3 3 3

Real-time Clock Yes Yes Yes

JTAG ICE Yes Yes Yes

Typical AVR

Throughput

@ 25 MHz 19 MIPS 19 MIPS 19 MIPS

@ 40 MHz 30 MIPS 30 MIPS 30 MIPS

Operating Voltage 3.0 - 3.6V 3.0 - 3.6V 3.0 - 3.6V

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AT94S Secure Family

Figure 1-1. AT94S Architecture

The embedded AVR core achieves throughputs approaching 1 MIPS per MHz by executing

powerful instructions in a single-clock-cycle, and allows system designers to optimize power

consumption versus processing speed. The AVR core is based on an enhanced RISC architec-

ture that combines a rich instruction set with 32 general-purpose working registers. All 32

registers are directly connected to the Arithmetic Logic Unit (ALU), allowing two independent

registers to be accessed in one single instruction executed in one clock cycle. The resulting

architecture is more code-efficient while achieving throughputs up to ten times faster than con-

ventional CISC microcontrollers at the same clock frequency. The AVR executes out of on-chip

SRAM. Both the FPGA configuration SRAM and AVR instruction code SRAM are automatically

loaded at system power-up using Atmel’s in-system programmable AT17 Series EEPROM con-

figuration memories, which are part of the AT94S Multi-chip Module (MCM).

State-of-the-art FPSLIC design tools, System Designer, were developed in conjunction with the

FPSLIC architecture to help reduce overall time-to-market by integrating microcontroller devel-

opment and debugging, FPGA development, place and route, and complete system

co-verification in one easy-to-use software tool.

5 - 40K Gates FPGA

Up to

16K x 8

Data

SRAM

Up to 16K x 16

Program

SRAM Memory

PROGRAMMABLE I/O

with

Multiply Two 8-bit

Timer/Counters

16 Prog. I/O

Lines

I/O

2-wire Serial

Unit

Up to 16 Interrupt Lines

Up to 16

Decoded

Address Lines

4 Interrupt Lines

Configuration Logic

Configuration

EEPROM

I/O

For ISP

and Chip

Erase

Two Serial

UARTs

2314E–FPSLI–6/05

AT94S Secure Family

2. Internal Architecture

For details of the AT94S Secure FPSLIC architecture, please refer to the AT94K FPSLIC

datasheet and the AT17 Series Configuration Memory datasheet, available on the Atmel web

site at http://www.atmel.com. This document only describes the differences between the AT94S

Secure FPSLIC and the AT94K FPSLIC.

3. FPSLIC and Configurator Interface

• Fully In-System Programmable and Re-programmable

• When Security Bit Set:

– Data Verification Disabled

– Data Transfer to FPSLIC not Externally Visible

– Secured EEPROM Will Only Boot the FPSLIC Device or Respond to a Chip Erase

• When Security Bit Cleared:

– Entire Chip Erase Performed

– In-System Programming Enabled

– Data Verification Enabled

External Data pins allow for In-System Programming of the device and setting of the EEPROM-

based security bit. When the security bit is set (active) this programming connection will only

respond to a device erase command. Data cannot be read out of the external programming/data

pins when the security bit is set. The part can be re-programmed, but only after first being

erased.

4. Programming and Configuration Timing Characteristics

Atmel’s Configurator Programming Software (CPS), available from the Atmel web site

(http://www.atmel.com/dyn/products/tools_card.asp?tool_id=3191), creates the programming

algorithm for the embedded configurator; however, if you are planning to write your own soft-

ware or use other means to program the embedded configurator, the section below includes the

algorithm and other details.

4.1 The FPSLIC Configurator

The FPSLIC Configurator is a serial EEPROM memory which is used to load programmable

devices. This document describes the features needed to program the Configurator from within

its programming mode (i.e., when SER_EN is driven Low).

Reference schematics are supplied for ISP applications.

4.2 Serial Bus Overview

The serial bus is a two-wire bus; one wire (cSCK) functions as a clock and is provided by the

programmer, the second wire (cSDA) is a bi-directional signal and is used to provide data and

control information.

Information is transmitted on the serial bus in messages. Each MESSAGE is preceded by a

Start Condition and ends with a Stop Condition. The message consists of an integer number of

bytes, each byte consisting of 8 bits of data, followed by a ninth Acknowledge Bit. This Acknowl-

edge Bit is provided by the recipient of the transmitted byte. This is possible because devices

2314E–FPSLI–6/05

AT94S Secure Family

may only drive the cSDA line Low. The system must provide a small pull-up current (1 kΩ equiv-

alent) for the cSDA line.

The MESSAGE FORMAT for read and write instructions consists of the bytes shown in “Bit For-

mat” on page 5.

While writing, the programmer is responsible for issuing the instruction and data. While reading,

the programmer issues the instruction and acknowledges the data from the Configurator as

necessary.

Again, the Acknowledge Bit is asserted on the cSDA line by the receiving device on a byte-by-

byte basis.

The factory blanks devices to all zeros before shipping. The array cannot otherwise be “initial-

ized” except by explicitly writing a known value to each location using the serial protocol

described herein.

4.3 Bit Format

Data on the cSDA pin may change only during the cSCK Low time; whereas Start and Stop Con-

ditions are identified as transitions during the cSCK High time.

Write Instruction Message Format

Current Address Read (Extended to Sequential Read) Instruction Message Format

4.4 Start and Stop Conditions

The Start Condition is indicated by a high-to-low transition of the cSDA line when the cSCK line

is High. Similarly, the Stop Condition is generated by a low-to-high transition of the cSDA line

when the cSCK line is High, as shown in Figure 4-1.

The Start Condition will return the device to the state where it is waiting for a Device Address (its

normal quiescent mode).

The Stop Condition initiates an internally timed write signal whose maximum duration is tWR

(refer to AC Characteristics table for actual value). During this time, the Configurator must

remain in programming mode (i.e., SER_EN is driven Low). cSDA and cSCK lines are ignored

until the cycle is completed. Since the write cycle typically completes in less than tWR seconds,

we recommend the use of “polling” as described in later sections. Input levels to all other pins

should be held constant until the write cycle has been completed.

ACK BIT

(CONFIGURATOR)

DATA

BYTE n

STOP

CONDITION

START

CONDITION

DEVICE

ADDRESS

MS EEPROM

ADDRESS BYTE

(NEXT) EEPROM

ADDRESS BYTE

LS EEPROM

ADDRESS BYTE

DATA

BYTE 1

ACK BIT

(CONFIGURATOR)

DATA

BYTE n

STOP

CONDITION

START

CONDITION

DEVICE

ADDRESS

DATA

BYTE 1

ACK BIT

(PROGRAMMER)

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AT94S Secure Family

4.5 Acknowledge Bit

The Acknowledge (ACK) Bit shown in Figure 4-1 is provided by the Configurator receiving the

byte. The receiving Configurator can accept the byte by asserting a Low value on the cSDA line,

or it can refuse the byte by asserting (allowing the signal to be externally pulled up to) a High

value on the cSDA line. All bytes from accepted messages must be terminated by either an

Acknowledge Bit or a Stop Condition. Following an ACK Bit, when the cSDA line is released dur-

ing an exchange of control between the Configurator and the programmer, the cSDA line may

be pulled High temporarily due to the open-collector output nature of the line. Control of the line

must resume before the next rising edge of the clock.

4.6 Bit Ordering Protocol

The most significant bit is the first bit of a byte transmitted on the cSDA line for the Device

Address Byte and the EEPROM Address Bytes. It is followed by the lesser significant bits until

the eighth bit, the least significant bit, is transmitted. However, for Data Bytes (both writing and

reading), the first bit transmitted is the least significant bit. This protocol is shown in the diagrams

below.

4.7 Device Address Byte

The contents of the Device Address Byte are shown below, along with the order in which the bits

are clocked into the device.

The CE pin cannot be used for device selection in programming mode (i.e., when SER_EN is

drive Low).

Figure 4-1. Start and Stop Conditions

Where:R/W=1 Read

= 0 Write

8th Bit

STOP

Condition

Byte n

cSCK

cSDA

START

Condition

tWR

ACK BIT

Table 4-1. Device Address Byte

MSB LSB

1010011R/W

1st 2nd 3rd 4th 5th 6th 7th 8th

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AT94S Secure Family

4.7.1 EEPROM Address

The EEPROM Address consists of three bytes on the 1-Mbit part. Each Address Byte is followed

by an Acknowledge Bit (provided by the Configurator). These bytes define the normal address

space of the Configurator. The order in which each byte is clocked into the Configurator is also

indicated. Unused bits in an Address Byte must be set to “0”. Exceptions to this are when read-

ing Device and Manufacturer Codes.

MSB LSB MSB LSB MSB LSB

0000000A

E16 ACK AE15 AE14 AE13 AE12 AE11 AE10 AE9 AE8 ACK AE7 AE6 AE5 AE4 AE3 AE2 AE1 AE0 ACK

1st 2nd 3rd 4th 5th 6th 7th 8th 1st 2nd 3rd 4th 5th 6th 7th 8th 1st 2nd 3rd 4th 5th 6th 7th 8th

512-Kbit/1-Mbit Page Length

1-Mbit Address Space

Byte Order

512-Kbit Address Space

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AT94S Secure Family

4.8 Programming Summary:

Write to Whole Device

SER_EN ≤ Low

PAGE_COUNT ≤ 0

START

Send Start Condition

BYTE_COUNT ≤ 0

Send Device Address

($A6) ACK?

Send MSB of

EEPROM Address

(1)

ACK?

Send LSB of

EEPROM Address

(1)

Send Data Byte

(2)

BYTE_COUNT ≤

BYTE_COUNT+1

BYTE_COUNT =

T_BYTE?

Send Stop Condition

PAGE_COUNT ≤

PAGE_COUNT+1

PAGE_COUNT =

T_PAGE?

Yes

Send Start Condition

Send Device Address

($A7)

END

ACK?

Yes

ACK?

Yes

ACK?

Yes

SER_EN ≤ High

Low-power (Standby)

Power-Cycle EEPROM

(Latches 1st Byte for

FPGA Download

Operations)

1st Data Byte

Value Changed Due

to Write?

Verify Final Write

Cycle Completion

Yes

Middle Byte

EEPROM Address ACK?

Yes

Notes: 1. The 1-Mbit part requires three EEPROM address

bytes; all three bytes must be individually ACK’d by

the EEPROM.

2. Data byte received/sent LSB to MSB.

4.8.1 EEPROM Address is Defined as:

Note: where Xn ... X0 is (PAGE_COUNT)\b

4.8.2 T_BYTE

4.8.3 T_PAGE

AT17LV010 0000 000x9x8x7x6x5x4x3x2x1x0000 0000

AT17LV010 128

AT17LV010 1024

cSDA

cSCK

cSDA

cSCK

DATA BIT

STOP CONDITION

cSDA

cSCK

ACK BIT

cSDA

cSCK

ACK

START CONDITION

2314E–FPSLI–6/05

AT94S Secure Family

4.9 Programming Summary:

Read from Whole Device

SER_EN ≤ Low

START

Send Start Condition

Send Device Address

($A6) ACK?

Send MSB of

EEPROM Address(1) ACK?

Send LSB of

EEPROM Address(1)

Send Start condition

BYTE_COUNT ≤ 0

Send Device Address

($A7)

Yes

Read Data Byte(2)

BYTE_COUNT ≤

BYTE_COUNT+1

Send ACK

END

BYTE_COUNT=

TT_BYTE?

ACK?

Yes

Sent Stop Condition

SER_EN ≤ High

Low-power (Standby)

Sequential Read from Current Address

ACK? No

Yes

Random Access Setup

Middle Byte

EEPROM Address ACK? No

Yes

Notes: 1. The 1-Mbit part requires three EEPROM address

bytes; all three bytes must be individually ACK’d by

the EEPROM.

2. Data byte received/sent LSB to MSB

4.9.1 EEPROM Address is Defined as:

4.9.2 TT_BYTE

AT17LV010 00 00 00 \h

AT17LV010 131072 \d

cSDA

cSCK

cSDA

cSCK

SAMPLE DATA BIT

STOP CONDITION

START CONDITION

cSDA

cSCK

ACK BIT

cSDA

cSCK

ACK

2314E–FPSLI–6/05

AT94S Secure Family

The organization of the Data Byte is shown above. Note that in this case, the Data Byte is

clocked into the device LSB first and MSB last.

4.9.4 Writing

Writing to the normal address space takes place in pages. A page is 128-bytes long in the 1-Mbit

part. The page boundaries are, respectively, addresses where AE0 down to AEOS are all zero,

and AE6 down to AE0 are all zero. Writing can start at any address within a page and the number

of bytes written must be 128 for the 1-Mbit part. The first byte is written at the transmitted

address. The address is incremented in the Configurator following the receipt of each Data Byte.

Only the lower 7 bits of the address are incremented. Thus, after writing to the last byte address

within the given page, the address will roll over to the first byte address of the same page. A

Write Instruction consists of:

a Start Condition

a Device Address Byte with R/W = 0

An Acknowledge Bit from the Configurator

MS Byte of the EEPROM Address

An Acknowledge Bit from the Configurator

Next Byte of the EEPROM Address

An Acknowledge Bit from the Configurator

LS Byte of EEPROM Address

An Acknowledge Bit from the Configurator

One or more Data Bytes (sent to the

Configurator)

Each followed by an Acknowledge Bit from the

Configurator

a Stop Condition

4.9.4.1 Write Polling

On receipt of the Stop Condition, the Configurator enters an internally-timed write cycle. While

the Configurator is busy with this write cycle, it will not acknowledge any transfers. The program-

mer can start the next page write by sending the Start Condition followed by the Device Address,

in effect polling the Configurator. If this is not acknowledged, then the programmer should aban-

don the transfer without asserting a Stop Condition. The programmer can then repeatedly

initiate a write instruction as above, until an acknowledge is received. When the Acknowledge

Bit is received, the write instruction should continue by sending the first EEPROM Address Byte

to the Configurator.

An alternative to write polling would be to wait a period of tWR before sending the next page of

data or exiting the programming mode. All signals must be maintained during the entire write

cycle.

4.9.3 Data Byte

LSB MSB

D0 D1 D2 D3 D4 D5 D6 D7

1st 2nd 3rd 4th 5th 6th 7th 8th

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AT94S Secure Family

4.9.5 Reading

Read instructions are initiated similarly to write instructions. However, with the R/W bit in the

Device Address set to one. There are three variants of the read instruction: current address

read, random read and sequential read.

For all reads, it is important to understand that the internal Data Byte address counter maintains

the last address accessed during the previous read or write operation, incremented by one. This

address remains valid between operations as long as the chip power is maintained and the

device remains in 2-wire access mode (i.e., SER_EN is driven Low). If the last operation was a

read at address n, then the current address would be n + 1. If the final operation was a write at

address n, then the current address would again be n + 1 with one exception. If address n was

the last byte address in the page, the incremented address n + 1 would “roll over” to the first byte

address on the next page.

4.9.5.1 Current Address Read

Once the Device Address (with the R/W select bit set to High) is clocked in and acknowledged

by the Configurator, the Data Byte at the current address is serially clocked out by the Configu-

rator in response to the clock from the programmer. The programmer generates a Stop

Condition to accept the single byte of data and terminate the read instruction.

A Current Address Read instruction consists of

a Start Condition

a Device Address with R/W = 1

An Acknowledge Bit from the Configurator

a Data Byte from the Configurator

a Stop Condition from the programmer.

4.9.5.2 Random Read

A Random Read is a Current Address Read preceded by an aborted write instruction. The write

instruction is only initiated for the purpose of loading the EEPROM Address Bytes. Once the

Device Address Byte and the EEPROM Address Bytes are clocked in and acknowledged by the

Configurator, the programmer immediately initiates a Current Address Read.

A Random Address Read instruction consists of :

a Start Condition

a Device Address with R/W = 0

An Acknowledge Bit from the Configurator

MS Byte of the EEPROM Address

An Acknowledge Bit from the Configurator

Next Byte of the EEPROM Address

An Acknowledge Bit from the Configurator

LS Byte of EEPROM Address

An Acknowledge bit from the Configurator

a Start Condition

a Device Address with R/W = 1

An Acknowledge Bit from the Configurator

a Data Byte from the Configurator

a Stop Condition from the programmer.

2314E–FPSLI–6/05

AT94S Secure Family

4.9.5.3 Sequential Read

Sequential Reads follow either a Current Address Read or a Random Address Read. After the

programmer receives a Data Byte, it may respond with an Acknowledge Bit. As long as the Con-

figurator receives an Acknowledge Bit, it will continue to increment the Data Byte address and

serially clock out sequential Data Bytes until the memory address limit is reached.(1) The

Sequential Read instruction is terminated when the programmer does not respond with an

Acknowledge Bit but instead generates a Stop Condition following the receipt of a Data Byte.

Note: 1. If an ACK is sent by the programmer after the data in the last memory address is sent by the

configurator, the internal address counter will “rollover” to the first byte address of the memory

array and continue to send data as long as an ACK is sent by the programmer.

4.9.6 Programmer Functions

The following programmer functions are supported while the Configurator is in programming

mode (i.e., when SER_EN is driven Low):

1. Read the Manufacturer’s Code and the Device Code (optional for ISP).

2. Program the device.

3. Verify the device.

In the order given above, they are performed in the following manner.

4.9.7 Reading Manufacturer’s and Device Codes

On AT17LV010 Configurator, the sequential reading of these bytes are accomplished by per-

forming a Random Read at EEPROM Address 040000H.

The correct codes are:

Manufacturers Code -Byte 0 1E

Device Code - Byte 1 F7 AT17LV010

Note: The Manufacturer’s Code and Device Code are read using the byte ordering specified for Data

Bytes; i.e., LSB first, MSB last.

4.9.8 Programming the Device

All the bytes in a given page must be written. The page access order is not important but it is

suggested that the Configurator be written sequentially from address 0. Writing is accomplished

by using the cSDA and cSCK pins.

4.9.8.1 Important Note on AT94S Series Configurators Programming

The first byte of data will not be cached for read back during FPGA Configuration (i.e., when

SER_EN is driven High) until the Configurator is power-cycled.

4.9.9 Verifying the Device

All bytes in the Configurator should be read and compared to their intended values. Reading is

done using the cSDA and cSCK pins.

2314E–FPSLI–6/05

AT94S Secure Family

4.10 In-System Programming Applications

The AT94S Series Configurators are in-system (re)programmable (ISP). The example shown on

the following page supports the following programmer functions:

1. Read the Manufacturer’s Code and the Device Code.

2. Program the device.

3. Verify the device data.

While Atmel’s Secure FPSLIC Configurators can be programmed from various sources (e.g., on-

board microcontrollers or PLDs), the applications shown here are designed to facilitate users of

our ATDH2225 Configurator Programming Cable. The typical system setup is shown in Figure 4-

The pages within the configuration EEPROM can be selectively rewritten.

This document is limited to example implementations for Atmel’s AT94S application.

Figure 4-2. Typical System Setup

The diode connection between the AT94S’ RESET pin and the SER_EN signal allows the exter-

nal programmer to force the FPGA into a reset state during ISP. This eliminates the potential for

contention on the cSCK line. The pull-up resistors required on the lines to RESET, CON and

INIT are present on the inputs (internally) to the AT94S FPSLIC, see Figure 4-3.

Secure

FPSLIC

Target System

10-pin

Ribbon

Cable

Programming

Dongle

In-System

Programming

Connector

Header

ATDH2225 10

Secure

FPSLIC

2314E–FPSLI–6/05

AT94S Secure Family

Figure 4-3. ISP of the AT17LV512/010 in an AT94S FPSLIC Application

Note: 1. Configurator signal names are shown in parenthesis.

Figure 4-4. Serial Data Timing Diagram

cSDA 1

cSCK 3

SER_EN

VCC

GND

AT94S

(SER_EN)

DATA0 (cSDA)(1)

CLK (cSCK)(1)

INIT (RESET/OE)(1)

CON (CE)(1)

RESET

GND

RESET

tLOW tHIGH

tHD.STA

tSU.STA

tRtF

tSU.DAT

tHD.DAT

tDH

tAA

tSU.STO

tBUF

cSCK

cSDA

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AT94S Secure Family

Notes: 1. Specific to programming mode (i.e., when SER_EN is driven Low)

2. Commercial temperature range 0°C - 70°C

3. Industrial temperature range -40°C - 85°C

4. This parameter is characterized and is not 100% tested.

Notes: 1. Specific to programming mode (i.e., when SER_EN is driven Low)

2. Commercial temperature range 0°C - 70°C

3. Industrial temperature range -40°C - 85°C

4. This parameter is characterized and is not 100% tested.

4.11 DC Characteristics(1)

VCC = 3.3V ± 10%, TA = -40°C - 85°C(2)(3)(4)

Symbol Parameter Test Condition Min Typ Max Units

VCC Supply Voltage 3.0 3.3 3.6 V

ICC Supply Current VCC = 3.6 2 3 mA

ILL Input Leakage Current VIN = VCC or VSS 0.10 10 µA

ILO Output Leakage Current VOUT = VCC or VSS 0.05 10 µA

VIH High-level Input Voltage VCC x 0.7 VCC + 0.5 V

VIL Low-level Input Voltage -0.5 0.2 V

VOL Output Low-level Voltage IOL = 2.1 mA 0.4 V

4.12 AC Characteristics(1)

VCC = 3.3V ± 10%, TA = -40°C - 85°C(2)(3)(4)

Symbol Parameter Min Max Units

fCLOCK Clock Frequency, Clock 100 KHz

tLOW Clock Pulse Width Low 4 µs

tHIGH Clock Pulse Width High 4 µs

tAA Clock Low to Data Out Valid 0.1 1 µs

tBUF Time the Bus Must Be Free Before a New Transmission Can Start 4.5 µs

tHD;STA Start Hold Time 2 µs

tSU;STA Start Setup Time 2 µs

tHD DAT Data In Hold Time 0 µs

tSU DAT Data In Setup Time 0.2 µs

tRInputs Rise Time 0.3 µs

tFInputs Fall Time 0.3 µs

tSU STO Stop Setup Time 2 µs

tDH Data Out Hold Time 0.1 µs

tWR Write Cycle Time 20 ms

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AT94S Secure Family

4.14 Security Bit

Once the security bit is programmed, data will no longer output from the normal data pad. Once

the fuse is set, any attempt to erase the fuse will cause the configurator to erase all of it

contents.

4.14.1 AT17LV512/010 Security Bit Programming

4.14.1.1 Disabling the Security Bit

Write 4 bytes “00 00 00 00” to addresses 800000-800003 two consecutive times, using the pre-

viously defined 2-wire write algorithm. Thereafter, either cycle the power or toggle (HI-LO-HI) the

SER_EN pin in order to disable the security.

4.14.1.2 Enabling the Security Bit

Write 4 bytes “FF FF FF FF” to addresses 800000-800003 using the previously defined 2-wire

write algorithm.

4.14.1.3 Verifying the Security Bit

Read 4 bytes of data from addresses 800000-800003 using the previously defined 2-wire Ran-

dom Read algorithm. If the data is “FF FF FF FF”, the security bit has been enabled. If the data

is “00 00 00 00”, the security bit has been disabled.

4.13 Secure FPSLIC Configurator Pin Configurations

144-pin

LQFP

256-pin

CABGA Name I/O Description

105 D16 cSDA I/O Three-state DATA output for configuration. Open-

collector bi-directional pin for programming.

107 C16 cSCK O

CLOCK output. Used to increment the internal

address and bit counter for reading and

programming.

53 K9 RESET/OE I

RESET/OE input (when SER_EN is High). A Low

level on both the CE and RESET/OE inputs

enables the data output driver. A High level on

RESET/OE resets both the address and bit

counters. The logic polarity of this input is

programmable as either RESET/OE or RESET/OE.

This document describes the pin as RESET/OE.

72 N16 CE I

Chip Enable input. Used for device selection only

when SER_EN is High. A Low level on both CE and

OE enables the data output driver. A High level on

CE disables both the address and bit counters and

forces the device into a low-power mode. Note this

pin will not enable/disable the device in the 2-wire

Serial mode (i.e., when SER_EN is driven Low).

81 M5 SER_EN I

Serial enable is normally High during FPGA

loading operations. Bringing SER_EN Low enables

the programming mode.

2314E–FPSLI–6/05

AT94S Secure Family

4.15 Chip Erase Timing

The entire device can be erased at once by writing to a specific address. This operation will

erase the entire array. See Table 4-2 for specifics on the write algorithm.

Figure 4-5. Chip Erase Timing Diagram

5. Packaging and Pin List information

Table 4-2. Chip Erase Cycle Characteristics

Symbol Parameter

Tec Chip Erase Cycle Time (25 ms)

8th BIT

STOP

Condition

SCL

SDA

START

Condition

Tec

ACK

tsu.dat thigh tlow

tnd.dat

Table 5-1. Part and Package Combinations Available

Part # Package AT94S05 AT94S10 AT94S40

BG256 DG 93 137 162

LQ144 BQ – 84 84

Table 5-2. AT94K JTAG ICE Pin List

AT94S05

96 FPGA I/O

AT94S10

192 FPGA I/O

AT94S40

384 FPGA I/O

TDI IO34IO50IO98

TDO IO38 IO54 IO102

TMS IO43 IO63 IO123

TCK IO44 IO64 IO124

2314E–FPSLI–6/05

AT94S Secure Family

Table 5-3. AT94S Pin List

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

FPSLIC Array

I/O1, GCK1 (A16) I/O1, GCK1 (A16) I/O1, GCK1 (A16) A1 2

I/O2 (A17) I/O2 (A17) I/O2 (A17) D4 3

I/O3 I/O3 I/O3 D3 4

I/O4 I/O4 I/O4 B1 5

I/O5 (A18) I/O5 (A18) I/O5 (A18) C2 6

I/O6 (A19) I/O6 (A19) I/O6 (A19) C1 7

I/O7

I/O8

NC NC I/O9 D2

NC NC I/O10 D1

I/O11

I/O12

I/O13

I/O14

I/O7 I/O7 I/O15 E3

I/O8 I/O8 I/O16 E4

NC I/O9 I/O17 E2

NC I/O10 I/O18 E1

I/O19

I/O20

NC I/O11 I/O21 F4

NC I/O12 I/O22 F3

I/O23

I/O24

I/O9, FCK1 I/O13, FCK1 I/O25, FCK1 F1 9

I/O10 I/O14 I/O26 G7 10

I/O11 (A20) I/O15 (A20) I/O27 (A20) G6 11

I/O12 (A21) I/O16 (A21) I/O28 (A21) G4 12

NC I/O17 I/O29 G5

NC I/O18 I/O30 G2

I/O31

I/O32

2314E–FPSLI–6/05

AT94S Secure Family

I/O33

I/O34

NC NC I/O35 G1

NC NC I/O36 H7

I/O37

I/O38

NC NC I/O39 H6

NC NC I/O40 H5

NC I/O19 I/O41 H3

NC I/O20 I/O42 H4

I/O13 I/O21 I/O43 H2 13

I/O14 I/O22 I/O44 H1 14

I/O45

I/O46

I/O15 (A22) I/O23 (A22) I/O47 (A22) J7 15

I/O16 (A23) I/O24 (A23) I/O48 (A23) J1 16

I/O17 (A24) I/O25 (A24) I/O49 (A24) J4 19

I/O18 (A25) I/O26 (A25) I/O50 (A25) J5 20

I/O51

I/O52

I/O19 I/O27 I/O53 J6 21

I/O20 I/O28 I/O54 J8 22

NC I/O29 I/O55 K1

NC I/O30 I/O56 K2

I/O57

I/O58

I/O59

I/O60

NC NC I/O61 K4

NC NC I/O62 K5

I/O63

I/O64

NC NC I/O65 K6

NC NC I/O66 L1

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

NC I/O31 I/O67 L2

NC I/O32 I/O68 L5

I/O21 (A26) I/O33 (A26) I/O69 (A26) L4 23

I/O22 (A27) I/O34 (A27) I/O70 (A27) M1 24

I/O23 I/O35 I/O71 M2 25

I/O24, FCK2 I/O36, FCK2 I/O72, FCK2 N1 26

I/O73

I/O74

I/O37 I/O75

I/O38 I/O76

I/O77

I/O78

I/O79

I/O80

I/O25 I/O39 I/O81 M3

I/O26 I/O40 I/O82 N2

I/O41 I/O83

I/O42 I/O84

I/O85

I/O86

I/O87

I/O88

I/O27 (A28) I/O43 (A28) I/O89 (A28) P1 28

I/O28 I/O44 I/O90 P2 29

I/O91

I/O92

I/O29 I/O45 I/O93 R1 30

I/O30 I/O46 I/O94 N3 31

I/O31 (OTS) I/O47 (OTS) I/O95 (OTS)T132

I/O32, GCK2 (A29) I/O48, GCK2 (A29) I/O96, GCK2 (A29) P3 33

AVRRESET AVRRESET AVRRESET R2 34

M0 M0 M0 R3 36

FPSLIC Array

M2 M2 M2 T3 38

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

I/O33, GCK3 I/O49, GCK3 I/O97, GCK3 R4 39

I/O34 (HDC/TDI) I/O50 (HDC/TDI) I/O98 (HDC/TDI) T4 40

I/O35 I/O51 I/O99 N5 41

I/O36 I/O52 I/O100 P5 42

I/O53 I/O101 43

SER_EN SER_EN SER_EN M5 81

I/O38 (LDC/TDO) I/O54 (LDC/TDO) I/O102 (LDC/TDO) R5 44

I/O103

I/O104

I/O105

I/O106

NC NC I/O107 T5

NC NC I/O108 M6

I/O39 I/O55 I/O109 P6

I/O40 I/O56 I/O110 R6

NC I/O57 I/O111 L6

NC I/O58 I/O112 T6

I/O113

I/O114

I/O115

I/O116

I/O59 I/O117

I/O60 I/O118

I/O119

I/O120

I/O41 I/O61 I/O121 M7 46

I/O42 I/O62 I/O122 N7 47

I/O43 (TMS) I/O63 (TMS) I/O123 (TMS) P7 48

I/O44 (TCK) I/O64 (TCK) I/O124 (TCK) R7 49

NC I/O65 I/O125 K7

NC I/O66 I/O126 K8

I/O127

I/O128

I/O129

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

I/O130

I/O131

I/O132

I/O133

I/O134

NC I/O67 I/O135 M8

NC I/O68 I/O136 R8

I/O45 I/O69 I/O137 P8 50

I/O46 I/O70 I/O138 N8 51

I/O139

I/O140

I/O141

I/O142

I/O47 (TD7) I/O71 (TD7) I/O143 (TD7) L8 52

I/O48 (InitErr) RESET/OE I/O72 (InitErr) RESET/OE I/O144 (InitErr) RESET/OE K9 53

I/O49 (TD6) I/O73 (TD6) I/O145 (TD6) P9 56

I/O50 (TD5) I/O74 (TD5) I/O146 (TD5) N9 57

I/O147

I/O148

I/O149

I/O150

I/O51 I/O75 I/O151 M9 58

I/O52 I/O76 I/O152 L9 59

NC I/O77 I/O153 J9

NC I/O78 I/O154 T10

I/O155

I/O156

I/O157

I/O158

I/O159

I/O160

I/O161

I/O162

NC I/O79 I/O163 P10

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

NC I/O80 I/O164 N10

I/O53 (TD4) I/O81 (TD4) I/O165 (TD4) L10 60

I/O54 (TD3) I/O82 (TD3) I/O166 (TD3) T11 61

I/O55 I/O83 I/O167 R11 62

I/O56 I/O84 I/O168 M11 63

NC NC I/O169 N11

NC NC I/O170 T12

NC I/O85 I/O171 R12

NC I/O86 I/O172 T13

I/O173

I/O174

I/O175

I/O176

NC I/O87 I/O177 N12

NC I/O88 I/O178 P12

I/O57 I/O89 I/O179 R13

I/O58 I/O90 I/O180 T14

NC NC I/O181 N13

NC NC I/O182 P13

I/O59 (TD2) I/O91 (TD2) I/O183 (TD2) T16 65

I/O60 (TD1) I/O92 (TD1) I/O184 (TD1) P14 66

I/O185

I/O186

I/O187

I/O188

I/O61 I/O93 I/O189 R16 67

I/O62 I/O94 I/O190 P15 68

I/O63 (TD0) I/O95 (TD0) I/O191 (TD0) N14 69

I/O64, GCK4 I/O96, GCK4 I/O192, GCK4 P16 70

CON/CE CON/CE CON/CE N16 72

FPSLIC Array

RESET RESET RESET M14 74

PE0 PE0 PE0 M12 75

PE1 PE1 PE1 M15 76

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

PD0 PD0 PD0 M16 77

PD1 PD1 PD1 L12 78

PE2 PE2 PE2 L15 79

PD2 PD2 PD2 L11 80

NC NC NC E12

SER_EN SER_EN SER_EN M5 81

PD3 PD3 PD3 K11 82

PD4 PD4 PD4 K12 83

PE3 PE3 PE3 K14 84

CS0 CS0 CS0 K15 85

SDA SDA SDA J10

SCL SCL SCL J12

PD5 PD5 PD5 J14 86

PD6 PD6 PD6 J13 87

PE4 PE4 PE4 J16 88

PE5 PE5 PE5 J11 89

PE6 PE6 PE6 H15 92

PE7 (CHECK) PE7 (CHECK) PE7 (CHECK) H14 93

PD7 PD7 PD7 H13 94

INTP0 INTP0 INTP0 H12 95

XTAL1 XTAL1 XTAL1 G15 96

XTAL2 XTAL2 XTAL2 G14 97

RX0 RX0 RX0 G12 98

TX0 TX0 TX0 G11 99

INTP1 INTP1 INTP1 F15

INTP2 INTP2 INTP2 F14

TOSC1 TOSC1 TOSC1 E16 101

TOSC2 TOSC2 TOSC2 E15 102

RX1 RX1 RX1 E14 103

TX1 TX1 TX1 E13 104

DATA0/cSDA DATA0/cSDA DATA0/cSDA D16 105

INTP3 (CSOUT) INTP3 (CSOUT) INTP3 (CSOUT) D15 106

CCLK/cSCK CCLK/cSCK CCLK/cSCK C16 107

I/O65:96 Are Unbonded I/O97:144 Are Unbonded I/O193:288 Are Unbonded

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

FPSLIC Array

Testclock Testclock Testclock C15 109

I/O97 (A0) I/O145 (A0) I/O289 (A0) C14 111

I/O98, GCK7 (A1) I/O146, GCK7 (A1) I/O290, GCK7 (A1) B15 112

I/O99 I/O147 I/O291 A16 113

I/O100 I/O148 I/O292 D13 114

I/O293

I/O294

NC NC I/O295 C13

NC NC I/O296 B14

I/O101 (CS1, A2) I/O149 (CS1, A2) I/O297 (CS1, A2) A15 115

I/O102 (A3) I/O150 (A3) I/O298 (A3) A14 116

I/O299

I/O300

I/O104 I/O151 I/O301 Shared with Test

clock

NC I/O152 I/O302 D12

I/O103 I/O153 I/O303 C12 117

NC I/O154 I/O304 A13

NC NC I/O305 B12

I/O306

I/O307

I/O308

NC I/O155 I/O309 A12

NC I/O156 I/O310 E11

NC NC I/O311 C11

NC NC I/O312 D11

I/O105 I/O157 I/O313 A11 119

I/O106 I/O158 I/O314 F10 120

NC I/O159 I/O315 E10

NC I/O160 I/O316 D10

NC NC I/O317 C10

NC NC I/O318 B10

I/O319

I/O320

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

I/O321

I/O322

I/O323

I/O324

I/O107 (A4) I/O161 (A4) I/O325 (A4) A10 121

I/O108 (A5) I/O162 (A5) I/O326 (A5) G10 122

NC I/O163 I/O327 G9

NC I/O164 I/O328 F9

I/O109 I/O165 I/O329 E9 123

I/O110 I/O166 I/O330 C9 124

I/O331

I/O332

I/O333

I/O334

I/O111 (A6) I/O167 (A6) I/O335 (A6) B9 125

I/O112 (A7) I/O168 (A7) I/O336 (A7) A9 126

I/O113 (A8) I/O169 (A8) I/O337 (A8) A8 129

I/O114 (A9) I/O170 (A9) I/O338 (A9) B8 130

I/O339

I/O340

I/O341

I/O342

I/O115 I/O171 I/O343 C8 131

I/O116 I/O172 I/O344 D8 132

NC I/O173 I/O345 E8

NC I/O174 I/O346 F8

I/O117 (A10) I/O175 (A10) I/O347 (A10) H8 133

I/O118 (A11) I/O176 (A11) I/O348 (A11) A7 134

NC NC I/O349 C7

NC NC I/O350 D7

I/O351

I/O352

I/O353

I/O354

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

Note: 1. LQ144 is only offered in the AT94S10 and AT94S40.

I/O355

I/O356

NC I/O177 I/O357 F7

NC I/O178 I/O358 A6

I/O119 I/O179 I/O359 F6 135

I/O120 I/O180 I/O360 B6 136

I/O361

I/O362

NC I/O181 I/O363 D6

NC I/O182 I/O364 E6

I/O365

I/O366

I/O367

I/O368

I/O121 I/O183 I/O369 A5

I/O122 I/O184 I/O370 B5

I/O123 (A12) I/O185 (A12) I/O371 (A12) E5 138

I/O124 (A13) I/O186 (A13) I/O372 (A13) C5 139

I/O373

I/O374

I/O375

I/O376

I/O377

I/O378

NC I/O187 I/O379 A4

NC I/O188 I/O380 B4

I/O125 I/O189 I/O381 A3 140

I/O126 I/O190 I/O382 C4 141

I/O127 (A14) I/O191 (A14) I/O383 (A14) B3 142

I/O128, GCK8 (A15) I/O192, GCK8 (A15) I/O384, GCK8 (A15) A2 143

Table 5-3. AT94S Pin List (Continued)

AT94S05

96 FPGA I/O

AT94S10

144 FPGA I/O

AT94S40

288 FPGA I/O

Package

Chip Array 256

CABGA LQ144(1)

2314E–FPSLI–6/05

AT94S Secure Family

Note: 1. For power rail support for product migration to lower-power devices, refer to the “Designing in Split Power Supply Support for

AT94KAL/AX and AT94SAL/AX Devices” application note (doc2308.pdf), available on the Atmel web site, at

http://www.atmel.com/dyn/products/app_notes.asp?family_id=627.

6. Thermal Coefficient Table

Table 5-4. 256 CABGA and LQ144 VDD, VCC and GND Pins(1)

Package VDD (core) VCC (I/O) GND

256

CABGA

D14, E7, F12, G3, H9, K10,

L13, M13, P4, T9

B2, G8, G13, H10, K13, L3,

M10, R14, T3, T7

B11, B13, B16, B7, C3, C6, D5, D9, F11, F13, T15, F16,

F2, F5, G16, H11, H16, J15, J2, K16, K3, T2, L14, L16,

L7, M4, N15, N4, N6, P11, R9, R10, R15, T8

LQ144 18, 54, 90, 128 37, 73, 108, 144 1, 8, 17, 27, 35, 45, 55, 64, 71, 91, 100, 110, 118, 127,

137

Package Style Lead Count

Theta J-A [°C/W]

0 LFPM

Theta J-A [°C/W]

225 LFPM

Theta J-A [°C/W]

500 LPFM

CABGA 256 27 23 20

LQFP 144 35 — —

2314E–FPSLI–6/05

AT94S Secure Family

7. Ordering Information

Usable Gates Speed Grade Ordering Code Package Operation Range

5,000 25 MHz

AT94S05AL-25DGC

AT94S05AL-25BQC

256ZA

144L1

Commercial

(0°C - 70°C)

AT94S05AL-25DGI

AT94S05AL-25BQI

256ZA

144L1

Industrial

(-40°C - 85°C)

10,000 25 MHz

AT94S10AL-25DGC 256ZA Commercial

(0°C - 70°C)

AT94S10AL-25BQC 144L1

AT94S10AL-25DGI 256ZA Industrial

(-40°C - 85°C)

AT94S10AL-25BQI 144L1

40,000 16 MHz

AT94S40AL-25DGC 256ZA Commercial

(0°C - 70°C)

AT94S40AL-25DGI 256ZA Industrial

(-40°C - 85°C)

Package Type

256ZA 256-ball, Chip Array Ball Grid Array Package (CABGA)

144L1 144-lead, Low Profile Plastic Gull Wing Quad Flat Package (LQFP)

2314E–FPSLI–6/05

AT94S Secure Family

8. Packaging Information

8.1 256ZA – CABGA

2325 Orchard Parkway

San Jose, CA 95131

TITLE DRAWING NO.

REV.

256ZA, 256-ball (16 x 16 Array), 17 x 17 mm Body,

Chip Array Ball Grid Array (CABGA) Package A

256ZA

11/07/01

Top View

123

Ball Pad Corner

45678

910111214 131516

1.00 REF

Bottom View

(256 SOLDER BALLS)

Ball Pad Corner

Side View

COMMON DIMENSIONS

(Unit of Measure = mm)

SYMBOL MIN NOM MAX NOTE

D – 17 BSC –

E – 17 BSC –

A 1.30 1.40 1.50

A1 0.31 0.36 0.41

A2 0.29 0.34 0.39

A3 0.65 0.70 0.75

e 1.00 BSC

b 0.46 REF

Notes: 1. This drawing is for general information only. Refer to JEDEC Drawing MO-205 for proper dimensions, tolerances, datums, etc.

2. Array as seen from the bottom of the package.

2314E–FPSLI–6/05

AT94S Secure Family

8.2 144L1 – LQFP

2325 Orchard Parkway

San Jose, CA 95131

TITLE DRAWING NO.

REV.

144L1 A

11/30/01

144L1, 144-lead (20 x 20 x 1.4 mm Body), Low Profile

Plastic Quad Flat Pack (LQFP)

Bottom View

Side View

Top View

COMMON DIMENSIONS

(Unit of Measure = mm)

SYMBOL MIN NOM MAX NOTE

1. This drawing is for general information only; refer to JEDEC Drawing MS-026 for additional information.

2. The top package body size may be smaller than the bottom package size by as much as 0.15 mm.

3. Dimensions D1 and E1 do not include mold protrusions. Allowable protrusion is 0.25 mm per side. D1 and E1 are maximum plastic

body size dimensions including mold mismatch.

4. Dimension b does not include Dambar protrusion. Allowable Dambar protrusion shall not cause the lead width to exceed the maximum

b dimension by more than 0.08 mm. Dambar cannot be located on the lower radius or the foot. Minimum space between protrusion and

an adjacent lead is 0.07 mm for 0.4 and 0.5 mm pitch packages.

5. These dimensions apply to the flat section of the lead between 0.10 mm and 0.25 mm from the lead tip.

6. A1 is defined as the distance from the seating place to the lowest point on the package body.

A1 0.05 0.15 6

A2 1.35 1.40 1.45

D 22.00 BSC

D1 20.00 BSC 2, 3

E 22.00 BSC

E1 20.00 BSC 2, 3

e 0.50 BSC

b 0.17 0.22 0.27 4, 5

L1 1.00 REF

Notes:

Printed on recycled paper.

2314E–FPSLI–6/05

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