Intel Corporation GT28F800F3T95, GT28F800F3T120, GT28F160F3T120, GT28F160F3B95, GT28F160F3B120 Datasheet

...

PRODUCT PREVIEW

May 1998 Order Number: 290644-001

High Performance



54 MHz Effective Zero Wait-State Performance



Synchronous Burst-Mode Reads



Asynchronous Page-Mode Reads

SmartVoltage Technology



2.7 V−3.6 V Read and Write Operations for Low Power Designs



12 V VPP Fast Factory Programming

Flexible I/O Voltage



1.65 V I/O Reduces Overall System Power Consumption



5 V-Safe I/O Enables Interfacing to 5 V Devices

Enhanced Data Protection



Absolute Write Protection with

= GND



Block Locking



Block Erase/Program Lockout during Power Transitions

Density Upgrade Path



8- and 16-Mbit

Manufactured on ETOX™ V Flash Technology

Supports Code Plus Data Storage



Optimized for Flash Data Integrator (FDI) Software



Fast Program Suspend Capability



Fast Erase Suspend Capability

Flexible Blocking Architecture



Eight 4-Kword Blocks for Data



32-Kword Main Blocks for Code



Top or Bottom Configurations Available

Extended Cycling Capability



Minimum 10,000 Block Erase Cycles Guaranteed

Low Power Consumption



Automatic Power Savings Mode

Decreases Power Consumption

Automated Program and Block Erase Algorithms



Command User Interface for Automation



Status Register for System Feedback

Industry-Standard Packaging



56-Lead SSOP



µBGA* CSP

Intel’s Fast Boot Bloc k memory famil y renders high perf ormance as ynchronous page-m ode and sync hronous burst reads making it an ideal memory solution for burs t CPUs. Combining high read performance wit h the intrinsic non-volatility of flas h memory, this flash memory f amily eliminates the traditional redundant memory paradigm of shadowing code from a slow nonvolatile storage source to a faster execution memory for improved system performance. Therefore, it reduces the total memory requirement which helps increase reliability and reduce overall system power consumption and cost.

This family of product s is manufac tured on Intel’ s 0.4 µm ETOX ™ V process technology . They are available in industry-standard packages: the µBGA* CSP, ideal for board-constrained applications, and the rugged 56-lead SSOP.

FAST BOOT BLOCK

FLASH MEMORY FAMILY

8 AND 16 MBIT

28F800F3, 28F160F3

Includes Extended and Automotive Temperature Specifications

Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provi ded in Intel ’s Terms and Condi tions of Sale for such products, Intel assumes no liability whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not intended for use in medical, life saving, or life sustaining applications.

Intel may make changes to specifications and product descriptions at any time, without notice. The 28F800F3, 28F160F3 may contain design defects or errors known as errata which may cause the product to devi ate from

published specifications. Current characterized errata are available on request. Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order. Copies of documents which have an ordering number and are referenced in this document, or other Intel literature, may be

obtained from:

Intel Corporation P.O. Box 5937 Denver, CO 80217-9808

or call 1-800-548-4725

or visit Intel’s Website at http://www.intel.com

*Third-party brands and names are the property of their respective owners

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

CONTENTS

PAGE PAGE

1.0 INTRODUCTION .............................................5

1.2 Product Overview.........................................5

2.0 PRODUCT DESCRIPTION..............................6

2.1 Pinouts.........................................................6

2.2 Pin Description.............................................6

2.3 Memory Blocking Organization.....................9

2.3.1 Parameter Blocks..................................9

2.3.2 Main Blocks...........................................9

3.0 PRINCIPLES OF OPERATION .....................12

3.1 Bus Operations ..........................................12

3.1.1 Read....................................................12

3.1.2 Output Disable.....................................12

3.1.3 Standby...............................................12

3.1.4 Write....................................................12

3.1.5 Reset...................................................13

4.0 COMMAND DEFINITIONS............................13

4.1 Read Array Command................................15

4.2 Read Identifier Codes Command...............15

4.3 Read Status Register Command................15

4.4 Clear Status Register Command................15

4.5 Block Erase Command ..............................15

4.6 Program Command....................................17

4.7 Block Erase Suspend/Resume Command .17

4.8 Program Suspend/Resume Command.......17

4.9 Set Read Configuration Command.............19

4.9.1 Read Configuration..............................19

4.9.2 Frequency Configuration .....................20

4.9.3 Data Output Configuration...................20

4.9.4 WAIT# Configuration...........................20

4.9.5 Burst Sequence...................................20

4.9.6 Clock Configuration.............................20

4.9.7 Burst Length........................................20

5.0 DATA PROTECTION.....................................26

5.1 V

= VIL for Complete Protection..............26

5.2 WP# = V

for Block Locking ......................26

5.3 WP# = V

for Block Unlocking...................26

6.0 V

VOLTAGES............................................26

7.0 POWER CONSUMPTION..............................26

7.1 Active Power..............................................26

7.2 Automatic Power Savings ..........................26

7.3 Standby Power...........................................27

7.4 Power-Up/Down Operation.........................27

7.4.1 RST# Connection................................27

7.4.2 V

, VPP and RST# Transitions...........27

7.5 Power Supply Decoupling ..........................27

7.5.1 V

Trace on Printed Circuit Boards....27

8.0 ELECTRICAL SPECIFICATIONS .................28

8.1 Absolute Maximum Ratings........................28

8.2 Extended Temperature Operating

Conditions.................................................28

8.3 Capacitance...............................................29

8.4 DC Characteristics—Extended

Temperature..............................................30

8.5 AC Characteristics—Read-Only

Operations—Extended Temperature.........32

8.6 AC Characteristics—Write Operations—

Extended Temperature..............................38

8.7 AC Characteristics—Reset Operation—

Extended Temperature..............................40

8.8 Extended Temperature Block Erase and

Program Performance...............................41

8.9 Automotive Temperature Operating

Conditions.................................................41

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

8.10 Capacitance.............................................42

8.11 DC Characteristics—Automotive

Temperature..............................................43

8.12 AC Characteristics—Read-Only

Operations—Automotive Temperature......44

8.13 Automotive Temperature Frequency

Configuration Settings...............................45

8.14 Automotive Temperature Block Erase and

Program Performance...............................45

9.0 ORDERING INFORMATION..........................46

10.0 ADDITIONAL INFORMATION.....................47

REVISION HISTORY

Date of

Revision

Version Description

05/12/98 -001 Original version

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

1.0 INTRODUCTION

This datasheet contains 8- and 16-Mbit Fast Boot Block memory informati on. Section 1.0 provides a flash memory overview. Sections 2.0 through 8.0 describe the memory functionality and electrical specifications for extended and automotive temperature product offerings.

1.2 Product Overview

The Fast Boot Block flas h memory family provides density upgrades with pinout compatibility for 8- and 16-Mbit densities. This family of products are high performance, low voltage memories with a 16-bit data bus and individually erasable blocks. These blocks are optimally sized for code and data storage. Eight 4-Kword parameter blocks are positioned at either the top (denot ed by -T s uffix ) or bottom (denoted by -B suffix) of the addres s map. The rest of the device is grouped into 32-Kword main blocks. The upper two (or lower two) parameter and all main blocks can be locked for complete code protection.

The device’s optimized architecture and interface dramatically increases read performance beyond previously attainable levels. It supports asynchronous page-mode and synchronous burst reads from main blocks (parameter blocks support single asynchronous and synchronous reads). Upon initial power-up or return from reset, the device defaults to a page-mode read conf iguration. Page-mode read configuration is ideal for non-c lock memory systems and is compatible with pagemode ROM. Synchronous burst reads are enabl ed by writing to the read configuration register. In synchronous burst mode, t he CLK input increm ents an internal burst address generator, synchronizes the flash memory with t he host CPU, and outputs data on every rising (or falling) CLK edge up to 54 MHz (25 MHz for automotive temperature). An output signal, WAIT#, is als o provided to eas e CPU to flash memory communication and synchronization during continuous burst operations.

In addition to the enhanced architecture and interface, this family of products incorporates SmartVoltage technology whi ch enables fast f actory programming and low power designs. Specifically designed for low voltage systems, Fast Boot Block flash memory components support read operations at 2.7 V (3.3 V for automoti ve temperature) V

and

block erase and program operations at 2.7 V (3.3 V for automotive temperature) and 12 V V

The 12 V V

option renders the fastest program performance to increase factory programming throughput. With the 2.7 V (3.3 V for automotive temperature) V

option, VCC and VPP can be tied together for a simple, low power design. In addition to the voltage flexibility, the dedicat ed V

pin gives

complete data protection when V

≤ V

PPLK

The flexible input/output (I/O) voltage capability helps reduce system power consumption and simplify interfacing to sub 2.7 V and 5 V CPUs. Powered by V

CCQ

pins, the I/O buffers c an operate at a lower voltage than the flash memory core. Wi th V

CCQ

voltage at 1.65 V, the I/Os swing between GND and 1.65 V, reducing I/O power cons umption by 65% over standard 3 V flash memory components. The low voltage and 5 V-safe feature also helps ease CPU interfacing by adapting t o the CPU’s bus voltage.

The device’s Command User Interface (CUI ) serv es as the interface between t he system processor and internal flash memory operation. A v alid command sequence written to the CUI initiates device automation. This automation is controlled by an internal Write State Machine (WSM) which automatically executes the algorithms and timings necessary for block eras e and program operations. The status register provides WSM feedback by signifying block erase or program completion and status.

Block erase and program automati on allows erase and program operations to be executed using an industry-standard two-write comm and sequence. A block erase operation erases one bloc k at a time, and data is programmed in word inc rements. Erase suspend allows system software to suspend an ongoing block erase operation in order to read from or program data to any other block. Program suspend allows system software to suspend an ongoing program operation in order to read from any other location.

Fast Boot Block flas h memory devi ces off er two low power savings features: A utomatic Power Savings (APS) and standby mode. The device automatically enters APS mode following the completion of a read cycle. Standby mode is initiated when the system deselects the device by driving CE# inactive or RST# active. RST# also res ets the device to read array, provides write protection, and clears the status register. Combined, these two features significantly reduce power consumption.

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

2.0 PRODUCT DESCRIPTION

This section describes the pinout and block architecture of the device family.

2.1 Pinouts

Intel’s Fast Boot Block flash memory family provides upgrade paths in each pack age pinout up

to the 16-Mbit density. The family is available in µBGA CSP and 56-lead SSOP pac kages. Pinouts for the 8- and 16-Mbit components are illus trated in Figures 1 and 2.

2.2 Pin Description

The pin description table describes pin usage.

123456789

A15A

GND

WE#

CLK V

A17A

A13A

18A7

WP#RST#

ADV#

CCQ

DQ10DQ9DQ0CE#DQ

A16DQ15DQ

DQ2DQ1OE#

WAIT# GND DQ14GND

CCQ

DQ8GND

16M

32M

64M

NOTES:

1. Shaded connections indicate upgrade address connections. Lower density devices will not have upper address solder balls. Routing is not recommended in this area.

2. A20 and A21 are the upgrade address for potential 32-Mbit and 64-Mbit devices (currently not on road map).

3. Reference the

Micro Ball Grid Array Package Mechanical Specification and Media Information

on Intel’s World Wide Web

home page for detailed package specifications.

Figure 1. 56-Ball µBGA* Package Pinout (Top View, Ball Down)

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

16-Mbit

WE# WE# RST# RST# V

WP# WP# NC A

OE# OE# GND GND CE# CE# A

NC NC V

CCQ

CLKCLK

ADV#ADV#

GNDGND

NCNC A

NCNC

GNDGND

GNDGND V

CCQ

WAIT#WAIT#

56-Lead SSOP

16 mm x 23.7 mm

TOP VIEW

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28

56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29

8-Mbit 8-Mbit 16-Mbit

Figure 2. SSOP Pinout

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

Table 1. Pin Descriptions

Sym Type Name and Function

A0–A

INPUT ADDRESS INPUTS: Inputs for addresses during read and write operations.

Addresses are internally latched during read and write cycles. 8-Mbit: A

0–18

, 16-Mbit: A

0–19

DQ0–

INPUT/

OUTPUT

DATA INPUT/OUTPUTS: Inputs data and commands during write cycles, outputs data during memory array, status register (DQ

–DQ7), and identifier code read cycles. Data pins float to high-impedance when the chip is deselected or outputs are disabled. Data is internally latched during a write cycle.

CLK INPUT CLOCK: Synchronizes the flash memory to the system operating frequency during

synchronous burst-mode read operations. When configured for synchronous burstmode reads, address is latched on the first rising (or falling, depending upon the read configuration register setting) CLK edge when ADV# is active or upon a rising ADV# edge, whichever occurs first. CLK is ignored during asynchronous pagemode read and write operations.

ADV# INPUT ADDRESS VALID: Indicates that a valid address is present on the address inputs.

Addresses are latched on the rising edge of ADV# during read and write operations. ADV# may be tied active during asynchronous read and write operations.

CE# INPUT CHIP ENABLE: Activates the device’s control logic, input buffers, decoders, and

sense amplifiers. CE#-high deselects the device and reduces power consumption to standby levels.

RST# INPUT RESET: When driven low, RST# inhibits write operations which provides data

protection during power transitions, and it resets internal automation. RST#-high enables normal operation. Exit from reset sets the device to asynchronous read array mode.

OE# INPUT OUTPUT ENABLE: Gates data outputs during a read cycle. WE# INPUT WRITE ENABLE: Controls writes to the CUI and array. Addresses and data are

latched on the rising edge of the WE# pulse.

WP# INPUT WRITE PROTECTION: Provides a method for locking and unlocking all main

blocks and two parameter blocks. When WP# is at logic low, lockable blocks are locked. If a program or erase

operation is attempted on a locked block, SR.1 and either SR.4 [program] or SR.5 [block erase] will be set to indicate the operation failed.

When WP# is at logic high, the lockable blocks are unlocked and can be programmed or erased.

WAIT# OUTPUT WAIT: Provides data valid feedback when configured for synchronous burst-mode

and the burst length is set to continuous. This signal is gated by OE# and CE# and is internally pull-up to V

CCQ

via a resistor. WAIT# from several components can be

tied together to form one system WAIT# signal.

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

Table 1. Pin Descriptions

Sym Type Name and Function

SUPPLY BLOCK ERASE AND PROGRAM POWER SUPPLY (2.7 V–3.6 V,

11.4 V–12.6 V): For erasing array blocks or programming data, a valid voltage must be applied to this pin. With V

≤ V

PPL

, memory contents cannot be altered.

Block erase and program with an invalid V

voltage should not be attempted.

Applying 11.4 V–12.6 V to V

can only be done for a maximum of 1000 cycles on

main blocks and 2500 cycles on the parameter blocks.

VPP

may be connected to

12 V for a total of 80 hours maximum (see Section 6.0 for details).

SUPPLY DEVICE POWER SUPPLY (2.7 V–3.6 V): With VCC ≤ V

LKO

, all write attempts to

the flash memory are inhibited. Device operations at invalid V

voltages should

not be attempted.

CCQ

SUPPLY OUTPUT POWER SUPPLY (1.65 V–2.5 V, 2.7 V–3.6 V): Enables all outputs to be

driven to 1.65 V to 2.5 V or 2.7 V to 3.6 V. When V

CCQ

equals 1.65 V–2.5 V, V

voltage must not exceed 3.3 V and should be regulated to 2.7 V–2.85 V to achieve lowest power operation (see

DC Characteristics

for detailed information).

This input may be tied directly to V

. GND SUPPLY GROUND: Do not float any ground pins. NC NO CONNECT: Lead is not internally connected; it may be driven or floated.

2.3 Memory Blocking Organization

The Fast Boot Block flash memory family is an asymmetrically-blocked architecture that enables system integration of code and data within a single flash device. For the address locations of each block, see the memory m aps in Figure 3 (top boot blocking) and Figure 4 (bottom boot blocking).

2.3.1 PARAMETER BLOCKS

The Fast Boot Block flash memory architecture includes parameter blocks to facilitate storage of frequently updated small parameters that would

normally be stored in an EEPROM. By using software techniques, the word-rewrite functionality of EEPROMs can be emulated. Each 8- and 16-Mbit device contains eight 4-Kwords (4,096-words) parameter blocks.

2.3.2 MAIN BLOCKS

After the parameter blocks, the remainder of the array is divided into equal si ze m ain blocks for code and/or data storage. The 8-Mbit device contains fifteen 32-Kword (32,768-word) main blocks, and the 16-Mbit device contains thirty-one 32-Kword (32,768-word) main blocks.

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

32-KWord

Address Range

78000h - 78FFFh 70000h - 77FFFh

68000h - 6FFFFh

60000h - 67FFFh

58000h - 5FFFFh

50000h - 57FFFh

48000h - 4FFFFh

40000h - 47FFFh

38000h - 3FFFFh

30000h - 37FFFh

28000h - 2FFFFh

20000h - 27FFFh

18000h - 1FFFFh

10000h - 17FFFh

08000h - 0FFFFh

00000h - 07FFFh

8-Mbit

32-KWord

Block 22 Block 21

Block 20 Block 19 Block 18 Block 17 Block 16 Block 15

Block 14 Block 13 Block 12 Block 11 Block 10

Block 9 Block 8 Block 7 Block 6 Block 5 Block 4 Block 3 Block 2 Block 1 Block 0

79000h - 79FFFh

7A000h - 7AFFFh

7B000h - 7BFFFh

7C000h - 7CFFFh

7D000h - 7DFFFh

7E000h - 7EFFFh

7F000h - 7FFFFh

4-KWord

32-KWord

Address Range

F8000h - F8FFFh F0000h - F7FFFh

E8000h - EFFFFh

E0000h - E7FFFh D8000h - DFFFFh D0000h - D7FFFh C8000h - CFFFFh C0000h - C7FFFh B8000h - BFFFFh B0000h - B7FFFh A8000h - AFFFFh A0000h - A7FFFh

98000h - 9FFFFh

90000h - 97FFFh

88000h - 8FFFFh

80000h - 87FFFh

16-Mbit

32-KWord

Block 38 Block 37 Block 36 Block 35 Block 34 Block 33 Block 32 Block 31

Block 30 Block 29 Block 28 Block 27

Block 26

Block 25 Block 24 Block 23 Block 22 Block 21 Block 20 Block 19 Block 18 Block 17 Block 16

F9000h - F9FFFh

FA000h - FAFFFh

FB000h - FBFFFh

FC000h - FCFFFh

FD000h - FDFFFh

FE000h - FEFFFh

FF000h - FFFFFh

32-KWord

32-KWord 78000h - 7FFFFh

70000h - 77FFFh

68000h - 6FFFFh

60000h - 67FFFh

58000h - 5FFFFh

50000h - 57FFFh

48000h - 4FFFFh

40000h - 47FFFh

38000h - 3FFFFh

30000h - 37FFFh

28000h - 2FFFFh

20000h - 27FFFh

18000h - 1FFFFh

10000h - 17FFFh

32-KWord

Block 15 Block 14 Block 13 Block 12 Block 11 Block 10

Block 9 Block 8 Block 7 Block 6 Block 5 Block 4 Block 3 Block 2

08000h - 0FFFFh

00000h - 07FFFh

32-KWord

32-KWordBlock 1

Block 0

4-KWord

Figure 3. 8- and 16-Mbit Top Boot Memory Map

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

Address Range

16-Mbit

32-KWord

32-KWord F8000h - FFFFFh

F0000h - F7FFFh E8000h - EFFFFh E0000h - E7FFFh D8000h - DFFFFh D0000h - D7FFFh C8000h - CFFFFh C0000h - C7FFFh B8000h - BFFFFh B0000h - B7FFFh A8000h - AFFFFh A0000h - A7FFFh 98000h - 9FFFFh

90000h - 97FFFh 88000h - 8FFFFh

32-KWord

Block 38 Block 37 Block 36 Block 35 Block 34 Block 33 Block 32 Block 31 Block 30 Block 29 Block 28 Block 27 Block 26 Block 25 Block 24

32-KWord

32-KWord 80000h - 87FFFh

78000h - 7FFFFh

70000h - 77FFFh 68000h - 6FFFFh

60000h - 67FFFh 58000h - 5FFFFh

50000h - 57FFFh 48000h - 4FFFFh

40000h - 47FFFh 38000h - 3FFFFh

30000h - 37FFFh 28000h - 2FFFFh

20000h - 27FFFh 18000h - 1FFFFh

32-KWord

Block 23 Block 22 Block 21 Block 20 Block 19 Block 18 Block 17 Block 16 Block 15 Block 14 Block 13 Block 12 Block 11 Block 10

10000h - 17FFFh

32-KWordBlock 9

00000h - 00FFFh

Block 7 Block 6 Block 5 Block 4 Block 3 Block 2 Block 1 Block 0

01000h - 01FFFh

02000h - 02FFFh

03000h - 03FFFh

04000h - 04FFFh

05000h - 05FFFh

06000h - 06FFFh

07000h - 07FFFh

4-KWord

32-KWordBlock 8 08000h - 0FFFFh

32-KWord

Address Range

78000h - 7FFFFh 70000h - 77FFFh 68000h - 6FFFFh 60000h - 67FFFh 58000h - 5FFFFh 50000h - 57FFFh 48000h - 4FFFFh 40000h - 47FFFh 38000h - 3FFFFh 30000h - 37FFFh 28000h - 2FFFFh 20000h - 27FFFh 18000h - 1FFFFh 10000h - 17FFFh 08000h - 0FFFFh

8-Mbit

32-KWord

Block 22 Block 21 Block 20 Block 19 Block 18 Block 17 Block 16 Block 15 Block 14 Block 13 Block 12 Block 11 Block 10

Block 9 Block 8

Block 7 Block 6 Block 5 Block 4 Block 3 Block 2 Block 1 Block 0 00000h - 00FFFh

01000h - 01FFFh

02000h - 02FFFh

03000h - 03FFFh

04000h - 04FFFh

05000h - 05FFFh

06000h - 06FFFh

4-KWord

07000h - 07FFFh

Figure 4. 8- and 16-Mbit Bottom Boot Memory Map

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

3.0 PRINCIPLES OF OPERATION

The Fast Boot Block flash memory components include an on-chip WSM to manage block erase and program. It allows for CMOS-level control inputs, fixed power suppli es, and minim al proces sor overhead with RAM-like interface timings.

3.1 Bus Operations

All bus cycles to and from flash memory conform to standard microprocessor bus cycles.

3.1.1 READ

The flash memory has three read modes av ailable: read array, identifier codes, and status register. These modes are accessible independent of the V

voltage. The appropriate read command (Read Array, Read Identifier Codes, or Read Status Register) must be written to the CUI to enter the requested read mode. Upon initial power-up or exit from reset, the device defaults to read array mode.

When reading information from main blocks in read array mode, the device supports two highperformance read configurations: asynchronous page-mode and synchronous burst-mode. Asynchronous page-mode is t he default state and provides high data transfer rate for non-clocked memory subsystems. In this state, data is internally read and stored in a high-speed page buffer. A

1:0

addresses data in the page buffer. The page size i s four words. The other read configuration, synchronous burst-mode, is enabled by writing to read configuration register. This register sets the read configuration, burst order, frequency configuration, and burst length. In synchronous burst-mode, the device latches the initial address then outputs a sequence of data wi th res pect to t he input CLK and read configuration setting.

Read operations from the parameter blocks, identifier codes and status register transpire as single asynchronous or synchronous read cycles. The read configuration register setting determines whether or not read operations are asynchronous or synchronous.

For all read operations, CE# mus t be driven act ive to enable the devices, ADV# must be driven low to open the internal address latch, and OE# must be driven low to activate t he outputs. In async hronous mode, the address is latc hed when ADV# is driven high. In synchronous mode, the address is latched by ADV# going high or ADV# low in conjunction with a rising (falling) clock edge, whichever occurs first. WE# must be at V

. Figures 14 through 19

illustrate different read cycles.

3.1.2 OUTPUT DISABLE

With OE# at a logic-high level (V

), the device

outputs are disabled. Output pins DQ

–DQ15 are

placed in a high-impedance state.

3.1.3 STANDBY

Deselecting the device by bringi ng CE# to a logichigh level (V

) places the device in standby mode, which substantially reduces device power consumption. In standby, outputs are placed in a high-impedance state independent of OE#. If deselected during program or erase operat ion, the device continues to c onsume active power unt il the program or erase operation is complete.

3.1.4 WRITE

Commands are written to the CUI using standard microprocessor write timings when ADV#, WE#, and CE# are active and OE# inactive. The CUI does not occupy an addressable m emory location. The address is latched on the ris ing edge of ADV#, WE#, or CE# (whichever occurs first) and data needed to execute a command is latched on the rising edge of WE# or CE# (whichever goes high first). Write operations are asynchronous. Therefore, CLK is ignored during write operations. Figure 20 illustrates a write operation.

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

3.1.5 RESET

The device enters a reset mode when RST# is driven low. In reset mode, i nternal c irc uitry is t urned off and outputs are placed in a high-impedance state.

After return from reset, a time t

PHQV

is required until

outputs are valid, and a delay (t

PHWL

or t

PHEL

) is required before a write sequence can be init iated. After this wake-up interval, normal operation is restored. The device defaults to read array mode, the status register is set to 80H, and the read configuration register defaults to asynchronous page-mode reads.

If RP# is taken low during a block erase or program operation, the operation will be aborted and the memory contents at the aborted location are no longer valid. See Figure 21 for detail ed information regarding reset timings.

4.0 COMMAND DEFINITIONS

Device operations are selected by writing specific commands into the CUI. Table 3 defines these commands.

Table 2. Bus Operations

Mode Notes RST# CE# ADV# OE# WE# Address V

0–15

Reset V

XXXXXXHigh Z

Standby V

XXXXXHigh Z

Output Disable V

XVIHV

X X High Z

Read 1,2 V

XXD

OUT

Read Identifier Codes

See

Table 4

X See

Table 4

Write 3,4 V

XX D

NOTES:

1. Refer to

DC Characteristics

. When VPP ≤ V

PPLK

, memory contents can be read, but not altered.

2. X can be V

or VIH for control and address input pins and V

PPLK

or V

PPH1/2

for VPP. See

DC Characteristics

for V

PPLK

and

PPH1/2

voltages.

3. Command writes involving block erase or program are reliably executed when V

= V

PPH1/2

and VCC = V

CC1/2

(see Section 8 for operating conditions at different temperatures).

4. Refer to Table 3 for valid D

during a write operation.

FAST BOOT BLOCK DATASHEET E

PRODUCT PREVIEW

Table 3. Command Definitions

(1)

Bus Cycles First Bus Cycle Second Bus Cycle

Command Req’d. Notes Oper

(2)

Addr

(3)

Data

(4)

Oper

(2)

Addr

(3)

Data

(4)

Read Array/Reset 1 Write X FFH Read Identifier Codes ≥ 2 5 Write X 90H Read IA ID Read Status Register 2 Write X 70H Read X SRD Clear Status Register 1 Write X 50H Block Erase 2 6,7 Write X 20H Write BA D0H Program 2 6,7,8 Write X 40H

10H

Write WA WD

Block Erase and Program Suspend

1 6 Write X B0H

Block Erase and Program Resume

1 6 Write X D0H

Set Read Configuration 2 Write X 60H Write RCD 03H

NOTES:

1. Commands other than those shown above are reserved by Intel for future device implementations and should not be used.

2. Bus operations are defined in Table 2.

3. X = Any valid address within the device.

IA = Identifier Code Address. BA = Address within the block being erased. WA = Address of memory location to be written. RCD = Data to be written to the read configuration register. This data is presented to the device on A

15-0

; set all other

address inputs to “0.”

4. SRD = Data read from status register. See Table 5 for a description of the status register bits.

WD = Data to be written at location WA. Data is latched on the rising edge of WE# or CE# (whichever goes high first). ID = Data read from identifier codes. See Table 4 for manufacturer and device codes. RCD = Data to be written to read configuration register. See Table 6 for a description of the read configuration register bits.

5. Following the Read Identifier Codes command, read operations access manufacturer, device codes, and read

configuration register.

6. Following a block erase, program, and suspend operation, read operations access the status register.

7. To issue a block erase, program, or suspend operation to a lockable block, hold WP# at V

8. Either 40H or 10H are recognized by the WSM as the program setup.

E FAST BOOT BLOCK DATASHEET

PRODUCT PREVIEW

4.1 Read Array Command

Upon initial device power-up or exit from reset, the device defaults to read array mode. The read configuration register defaults to asynchronous page-mode. The Read Array command als o c auses the device to enter read array mode. The device remains enabled for reads until another c ommand is written. Once the internal WSM has started a block erase or program, the device will not recognize the Read Array command until the WSM completes its operation or unless the WSM is suspended via an Erase or Program Suspend command. The Read Array command functions independently of the V

voltage.

4.2 Read Identifier Codes

Command

The identifier code operation is initiat ed by writing the Read Identifier Codes command. After writing the command, read cycles retrieve the manufacturer and device codes (see Table 4 for identifier code values). Page-mode and burst reads are not supported in this read mode. To t erminate the operation, write another valid c omm and, li ke the Read Array command. The Read Identifier Codes command functions independently of the V

voltage.

Table 4. Identifier Codes

Code

Address

(Hex)

Data

(Hex)

Manufacturer Code 00000 0089 Device Code 8 Mbit -T 00001 88F1

-B 00001 88F2

16 Mbit -T 00001 88F3

-B 00001 88F4

4.3 Read Status Register

Command

The status register can be read at any time by writing the Read Status Register command to the CUI. After writing this command, all subsequent read operations output status register data until

another valid command is writ ten. Page-mode and burst reads are not supported in this read mode. The status register content i s updated and latched on the rising edge of ADV# or rising (falling) CLK edge when ADV# is low during synchronous burstmode or the falling edge of OE# or CE #, whichever occurs first. The Read Status Register command functions independently of the V

voltage.

4.4 Clear Status Register Command

Status register bits SR. 5, S R.4, S R.3, and SR. 1 are set to “1”s by the WSM and can only be cleared by

issuing the Clear Status Regis ter command. These bits indicate various error conditions. By allowing system software to reset these bits, several operations may be performed (such as cumul ati vely erasing or writing several byt es in sequence). The status register may be polled to determine if a problem occurred during the sequence. The Clear Status Register command functions independently of the applied V

voltage. After executing this

command, the device returns to read array mode.

4.5 Block Erase Command

Erase is executed one block at a time and init iated by a two-cycle command. A block erase setup is written first, followed by a block erase c onfirm. This command sequence requires appropriate sequencing and address within the block to be erased (erase changes all block data to FFH). Block preconditioning, eras e, and verify are handled internally by the WSM. After the two-cycle block erase sequence is written, the devic e automatically outputs status register data when read (see Figure 7,

Automated Block Erase Flowchart

). The CPU can detect block erase completion by analyzing status register bit SR.7.

When the block erase completes, check status register bit SR.5 for an error fl ag (“1”). If an error i s detected, check status register bits SR.4, SR.3, and SR.1 to understand what caused t he failure. After examining the status register, it should be c leared if an error was detected before issuing a new command. The device will remain in status regis ter read mode until another command is written to the CUI.

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Intel Corporation GT28F800F3T95, GT28F800F3T120, GT28F160F3T120, GT28F160F3B95, GT28F160F3B120 Datasheet

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