E ADVANCE INFORMATION WORD-WIDE FlashFileTM MEMORY FAMILY 28F160S3, 28F320S3 Includes Extended Temperature Specifications n n n n n n Two 32-Byte Write Buffers 2.7 s per Byte Effective Programming Time Low Voltage Operation 2.7V or 3.3V VCC 2.7V, 3.3V or 5V V PP 100 ns Read Access Time (16 Mbit) 110 ns Read Access Time (32 Mbit) High-Density Symmetrically-Blocked Architecture 32 64-Kbyte Erase Blocks (16 Mbit) 64 64-Kbyte Erase Blocks (32 Mbit) System Performance Enhancements STS Status Output Industry-Standard Packaging BGA* package, SSOP, and TSOP (16 Mbit) BGA* package and SSOP (32 Mbit) n n n n n n Cross-Compatible Command Support Intel Standard Command Set Common Flash Interface (CFI) Scaleable Command Set (SCS) 100,000 Block Erase Cycles Enhanced Data Protection Features Absolute Protection with V PP = GND Flexible Block Locking Block Erase/Program Lockout during Power Transitions Configurable x8 or x16 I/O Automation Suspend Options Program Suspend to Read Block Erase Suspend to Program Block Erase Suspend to Read ETOXTM V Nonvolatile Flash Technology Intel's Word-Wide FlashFileTM memory family provides high-density, low-cost, non-volatile, read/write storage solutions for a wide range of applications. The Word-Wide FlashFile memories are available at various densities in the same package type. Their symmetrically-blocked architecture, flexible voltage, and extended cycling provide highly flexible components suitable for resident flash arrays, SIMMs, and memory cards. Enhanced suspend capabilities provide an ideal solution for code or data storage applications. For secure code storage applications, such as networking, where code is either directly executed out of flash or downloaded to DRAM, the Word-Wide FlashFile memories offer three levels of protection: absolute protection with VPP at GND, selective block locking, and program/erase lockout during power transitions. These alternatives give designers ultimate control of their code security needs. This family of products is manufactured on Intel's 0.4 m ETOXTM V process technology. It comes in the industry-standard 56-lead SSOP and BGA packages. In addition, the 16-Mb device is available in the industry-standard 56-lead TSOP package. June 1997 Order Number: 290608-001 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 provided in Intel's Terms and Conditions 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 28F160S3 and 28F320S3 may contain design defects or errors known as errata. 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 7641 Mt. Prospect, IL 60056-7641 or call 1-800-879-4683 or visit Intel's website at http:\\www.intel.com COPYRIGHT (c) INTEL CORPORATION, 1997 *Third-party brands and names are the property of their respective owners. CG-041493 E 28F160S3, 28F320S3 CONTENTS PAGE 1.0 INTRODUCTION .............................................5 1.1 New Features...............................................5 1.2 Product Overview.........................................5 1.3 Pinout and Pin Description ...........................6 2.0 PRINCIPLES OF OPERATION .....................10 2.1 Data Protection ..........................................11 3.0 BUS OPERATION .........................................12 3.1 Read ..........................................................12 3.2 Output Disable ...........................................12 3.3 Standby......................................................12 3.4 Deep Power-Down .....................................12 3.5 Read Query Operation ...............................12 3.6 Read Identifier Codes Operation ................13 3.7 Write ..........................................................13 4.0 COMMAND DEFINITIONS ............................13 4.1 Read Array Command................................16 4.2 Read Query Mode Command.....................17 4.2.1 Query Structure Output .......................17 4.2.2 Query Structure Overview ...................19 4.2.3 Block Status Register ..........................20 4.2.4 CFI Query Identification String.............21 4.2.5 System Interface Information...............22 4.2.6 Device Geometry Definition .................23 4.2.7 Intel-Specific Extended Query Table ...24 4.3 Read Identifier Codes Command ...............25 4.4 Read Status Register Command................25 4.5 Clear Status Register Command................26 4.6 Block Erase Command ..............................26 4.7 Full Chip Erase Command .........................26 4.8 Write to Buffer Command...........................27 ADVANCE INFORMATION PAGE 4.9 Byte/Word Write Command ........................27 4.10 STS Configuration Command...................28 4.11 Block Erase Suspend Command ..............28 4.12 Program Suspend Command ...................28 4.13 Set Block Lock-Bit Commands .................29 4.14 Clear Block Lock-Bits Command ..............29 5.0 DESIGN CONSIDERATIONS ........................39 5.1 Three-Line Output Control..........................39 5.2 STS and WSM Polling ................................39 5.3 Power Supply Decoupling ..........................39 5.4 VPP Trace on Printed Circuit Boards...........39 5.5 VCC, VPP, RP# Transitions..........................39 5.6 Power-Up/Down Protection ........................39 6.0 ELECTRICAL SPECIFICATIONS..................40 6.1 Absolute Maximum Ratings ........................40 6.2 Operating Conditions..................................40 6.2.1 Capacitance.........................................41 6.2.2 AC Input/Output Test Conditions .........41 6.2.3 DC Characteristics...............................42 6.2.4 AC Characteristics - Read-Only Operations..........................................44 6.2.5 AC Characteristics - Write Operations .46 6.2.6 Reset Operations.................................48 6.2.7 Erase, Program, And Lock-Bit Configuration Performance.................49 APPENDIX A: Device Nomenclature and Ordering Information ..................................51 APPENDIX B: Additional Information ...............52 3 E 28F160S3, 28F320S3 REVISION HISTORY Number -001 4 Description Original version ADVANCE INFORMATION E 1.0 INTRODUCTION This datasheet contains 16- and 32-Mbit WordWide FlashFileTM memory (28F160S3 and 28F320S3) specifications. Section 1 provides a flash memory overview. Sections 2, 3, 4, and 5 describe the memory organization and functionality. Section 6 covers electrical specifications for extended temperature product offerings. 1.1 New Features 28F160S3, 28F320S3 This family of products are optimized for fast factory programming and low power designs. Specifically designed for 3V systems, the 28F160S3 and 28F320S3 support read operations at 2.7V-3.6V Vcc with block erase and program operations at 2.7V-3.6V and 5V VPP. High programming performance is achieved through highly-optimized write buffers. A 5V VPP option is available for even faster factory programming. For a simple low power design, VCC and VPP can be tied to 2.7V. Additionally, the dedicated VPP pin gives complete data protection when VPP VPPLK. The Word-Wide FlashFile memory family maintains basic compatibility with Intel's 28F016SA and 28F016SV. Key enhancements include: Internal VPP detection configures the device operations. * Common Flash Interface (CFI) Support * Scaleable Command Set (SCS) Support * Low Voltage Technology * Enhanced Suspend Capabilities A Common Flash Interface (CFI) permits OEMspecified software algorithms to be used for entire families of devices. This allows device-independent, JEDEC ID-independent, and forward- and backward-compatible software support for the specified flash device families. Flash vendors can standardize their existing interfaces for long-term compatibility. They share a compatible Status Register, basic software commands, and pinout. These similarities enable a clean migration from the 28F016SA or 28F016SV. When upgrading, it is important to note the following differences: * Because of new feature and density options, the devices have different manufacturer and device identifier codes. This allows for software optimization. * New software commands. * To take advantage of low voltage on the 28F160S3 and 28F320S3, allow VPP connection to VCC. The 28F160S3 and 28F320S3 do not support a 12V VPP option. 1.2 Product Overview The Word-Wide FlashFile memory family provides density upgrades with pinout compatibility for the 16- and 32-Mbit densities. They are highperformance memories arranged as 1 Mword and 2 Mwords of 16 bits or 2 Mbyte and 4 Mbyte of 8 bits. This data is grouped in thirty-two and sixtyfour 64-Kbyte blocks that can be erased, locked and unlocked in-system. Figure 1 shows the block diagram, and Figure 5 illustrates the memory organization. ADVANCE INFORMATION circuitry automatically for optimized write Scaleable Command Set (SCS) allows a single, simple software driver in all host systems to work with all SCS-compliant flash memory devices, independent of system-level packaging (e.g., memory card, SIMM, or direct-to-board placement). Additionally, SCS provides the highest system/device data transfer rates and minimizes device and system-level implementation costs. A Command User Interface (CUI) serves as the interface between the system processor and internal device operation. A valid command sequence written to the CUI initiates device automation. An internal Write State Machine (WSM) automatically executes the algorithms and timings necessary for block erase, program, and lock-bit configuration operations. A block erase operation erases one of the device's 64-Kbyte blocks typically within tWHQV2/EHQV2 independent of other blocks. Each block can be independently erased 100,000 times. Block erase suspend mode allows system software to suspend block erase to read or write data from any other block. Data is programmed in byte, word or page increments. Program suspend mode enables the system to read data or execute code from any other flash memory array location. 5 E 28F160S3, 28F320S3 The device incorporates two Write Buffers of 32 bytes (16 words) to allow optimum-performance data programming. This feature can improve system program performance by up to four times over non-buffer programming. Individual block locking uses a combination of block lock-bits to lock and unlock blocks. Block lock-bits gate block erase, full chip erase, program and write to buffer operations. Lock-bit configuration operations (Set Block Lock-Bit and Clear Block Lock-Bits commands) set and clear lock-bits. The Status Register and the STS pin in RY/BY# mode indicate whether or not the device is busy executing an operation or ready for a new command. Polling the Status Register, system software retrieves WSM feedback. STS in RY/BY# mode gives an additional indicator of WSM activity by providing a hardware status signal. Like the Status Register, RY/BY#-low indicates that the WSM is performing a block erase, program, or lockbit operation. RY/BY#-high indicates that the WSM is ready for a new command, block erase is suspended (and program is inactive), program is suspended, or the device is in deep power-down mode. The Automatic Power Savings (APS) feature substantially reduces active current when the device is in static mode (addresses not switching). The BYTE# pin allows either x8 or x16 read/writes to the device. BYTE# at logic low selects 8-bit mode with address A0 selecting between the low byte and high byte. BYTE# at logic high enables 16-bit operation with address A1 becoming the lowest order address. Address A0 is not used in 16bit mode. When one of the CEX# pins (CE0#, CE1#) and RP# pins are at VCC, the component enters a CMOS standby mode. Driving RP# to GND enables a deep power-down mode which significantly reduces power consumption, provides write protection, resets the device, and clears the Status Register. A reset time (tPHQV) is required from RP# switching high until outputs are valid. Likewise, the device has a wake time (tPHEL) from RP#-high until writes to the CUI are recognized. 1.3 Pinout and Pin Description The 16-Mbit device is available in the 56-lead TSOP, 56-lead SSOP and BGA packages. The 32- Mb device is available in the 56-lead SSOP and BGA packages. The pinouts are shown in Figures 2, 3 and 4. DQ0 - DQ15 Output Buffer Input Buffer Identifier Register Status Register Write Buffer I/O Logic Data Register Output Multiplexer Query VCC BYTE# CE# WE# OE# RP# WP# Command User Interface Multiplexer Data Comparator 16-Mbit: A0- A20 32-Mbit: A0 - A21 Y-Decoder Y-Gating STS Input Buffer Address Latch Write State Machine X-Decoder 16-Mbit: Thirty-two 32-Mbit: Sixty-four 64-Kbyte Blocks Program/Erase Voltage Switch VPP VCC GND Address Counter Figure 1. Block Diagram 6 ADVANCE INFORMATION E 28F160S3, 28F320S3 Table 1. Pin Descriptions Sym A0-A21 Type Name and Function INPUT ADDRESS INPUTS: Address inputs for read and write operations are internally latched during a write cycle. A 0 selects high or low byte when operating in x8 mode. In x16 mode, A0 is not used; input buffer is off. 16-Mbit A0-A20 DQ0- DQ15 32-Mbit A0-A21 INPUT/ DATA INPUTS/OUTPUTS: Inputs data and commands during CUI write cycles; OUTPUT outputs data during memory array, Status Register, query 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. CE0#, CE1# INPUT CHIP ENABLE: Activates the device's control logic, input buffers, decoders, and sense amplifiers. With CE 0# or CE1# high, the device is deselected and power consumption reduces to standby levels. Both CE 0# and CE1# must be low to select the device. Device selection occurs with the latter falling edge of CE 0# or CE1#. The first rising edge of CE0# or CE1# disables the device. RP# INPUT RESET/DEEP POWER-DOWN: When driven low, RP# inhibits write operations which provides data protection during system power transitions, puts the device in deep power-down mode, and resets internal automation. RP#-high enables normal operation. Exit from deep power-down sets the device to read array mode. OE# INPUT OUTPUT ENABLE: Gates the device's outputs during a read cycle. WE# INPUT WRITE ENABLE: Controls writes to the CUI and array blocks. Addresses and data are latched on the rising edge of the WE# pulse. STS WP# BYTE# STATUS: Indicates the status of the internal state machine. When configured in OPEN DRAIN level mode (default), it acts as a RY/BY# pin. For this and alternate configurations OUTPUT of the STATUS pin, see the Configuration command. Tie STS to VCC with a pull-up resistor. INPUT WRITE PROTECT: Master control for block locking. When V IL, locked blocks cannot be erased or programmed, and block lock-bits cannot be set or cleared. INPUT BYTE ENABLE: Configures x8 mode (low) or x16 mode (high). VPP SUPPLY BLOCK ERASE, PROGRAM, LOCK-BIT CONFIGURATION POWER SUPPLY: Necessary voltage to perform block erase, program, and lock-bit configuration operations. Do not float any power pins. VCC SUPPLY DEVICE POWER SUPPLY: Do not float any power pins. Do not attempt block erase, program, or block-lock configuration with invalid VCC values. GND SUPPLY GROUND: Do not float any ground pins. NC NO CONNECT: Lead is not internally connected; it may be driven or floated. ADVANCE INFORMATION 7 E 28F160S3, 28F320S3 28F016SA 28F160S3 28F160S3 28F016SA 28F016SV 28F160S5 28F160S5 28F016SV 3/5# CE1# NC A20 A19 A18 A17 A16 VCC A15 A14 A13 A12 CE0# VPP RP# A11 A10 A9 A8 GND A7 A6 A5 A4 A3 A2 A1 NC CE1# NC A20 A19 A18 A17 A16 VCC A15 A14 A13 A12 CE0# VPP RP# A11 A10 A9 A8 GND A7 A6 A5 A4 A3 A2 A1 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 56-LEAD TSOP STANDARD PINOUT 14 mm x 20 mm TOP VIEW WP# WP# WE# WE# OE# OE# RY/BY# STS RY/BY# DQ15 DQ15 DQ7 DQ7 DQ14 DQ14 DQ6 DQ6 GND GND DQ13 DQ13 DQ5 DQ5 DQ12 DQ12 DQ4 DQ4 VCC VCC GND GND DQ11 DQ11 DQ3 DQ3 DQ10 DQ10 DQ2 DQ2 VCC VCC DQ9 DQ9 DQ1 DQ1 DQ8 DQ8 DQ0 DQ0 A0 A0 BYTE# BYTE# NC NC NC NC Highlights pinout changes. Figure 2. TSOP 56-Lead Pinout 8 ADVANCE INFORMATION E 28F160S3, 28F320S3 Figure 3. SSOP 56-Lead Pinout ADVANCE INFORMATION 9 E 28F160S3, 28F320S3 GND A10 VPP CE0 A14 VCC VCC A14 CE0 VPP A10 GND A4 A7 A9 A11 A12 A15 A17 A19 A19 A17 A15 A12 A11 A9 A7 A4 A5 A6 A8 RP# A13 A16 A21 A20 A20 A21 A16 A13 RP# A8 A6 A5 A2 A1 A3 A18 CE1 NC NC A3 A1 A2 NC NC BYTE# DQ7 WP# WE# WE# WP# DQ7 BYTE# NC NC A0 DQ8 DQ1 DQ3 DQ12 DQ6 DQ15 OE# OE# DQ15 DQ6 DQ12 DQ3 DQ1 DQ8 A0 CE1 A18 DQ0 DQ9 DQ2 DQ11 DQ4 DQ13 DQ14 STS STS DQ14 DQ13 DQ4 DQ11 DQ2 DQ9 DQ0 VCC DQ10 GND VCC DQ5 GND GND DQ5 VCC GND DQ10 VCC This is the view of the package as surface mounted on the board. Note that the signals are mirror imaged. Bottom View NOTES: 1. Figures are not drawn to scale. 2. Address A21 is not included in the 28F160S3. 3. More information on BGA* packages is available by contacting your Intel/Distribution sales office. Figure 4. BGA* Package Pinout 2.0 PRINCIPLES OF OPERATION The word-wide memories include an on-chip Write State Machine (WSM) to manage block erase, program, and lock-bit configuration functions. It allows for: 100% TTL-level control inputs, fixed power supplies during block erasure, programming, lock-bit configuration, and minimal processor overhead with RAM-like interface timings. After initial device power-up or return from deep power-down mode (see Bus Operations), the 10 device defaults to read array mode. Manipulation of external memory control pins allow array read, standby, and output disable operations. Read Array, Status Register, query, and identifier codes can be accessed through the CUI independent of the VPP voltage. Proper programming voltage on VPP enables successful block erasure, program, and lock-bit configuration. All functions associated with altering memory contents--block erase, program, lock-bit configuration--are accessed via the CUI and verified through the Status Register. ADVANCE INFORMATION E 28F160S3, 28F320S3 Commands are written using standard microprocessor write timings. The CUI contents serve as input to the WSM that controls the block erase, programming, and lock-bit configuration. The internal algorithms are regulated by the WSM, including pulse repetition, internal verification, and margining of data. Addresses and data are internally latched during write cycles. Writing the appropriate command outputs array data, identifier codes, or Status Register data. Interface software that initiates and polls progress of block erase, programming, and lockbit configuration can be stored in any block. This code is copied to and executed from system RAM during flash memory updates. After successful completion, reads are again possible via the Read Array command. Block erase suspend allows system software to suspend a block erase to read or write data from any other block. Program suspend allows system software to suspend a program to read data from any other flash memory array location. 2.1 Data Protection Depending on the application, the system designer may choose to make the VPP power supply switchable or hardwired to VPPH1/2. The device supports either design practice, and encourages optimization of the processormemory interface. When VPP VPPLK, memory contents cannot be altered. When high voltage is applied to VPP, the two-step block erase, program, or lock-bit configuration command sequences provide protection from unwanted operations. All write functions are disabled when VCC voltage is below the write lockout voltage VLKO or when RP# is at VIL. The device's block locking capability provides additional protection from inadvertent code or data alteration. Figure 5. Memory Map ADVANCE INFORMATION 11 28F160S3, 28F320S3 3.0 BUS OPERATION The local CPU reads and writes flash memory insystem. All bus cycles to or from the flash memory conform to standard microprocessor bus cycles. 3.1 Read Block information, query information, identifier codes and Status Registers can be read independent of the VPP voltage. The first task is to place the device into the desired read mode by writing the appropriate read-mode command (Read Array, Query, Read Identifier Codes, or Read Status Register) to the CUI. Upon initial device power-up or after exit from deep power-down mode, the device automatically resets to read array mode. Control pins dictate the data flow in and out of the component. CE0#, CE1# and OE# must be driven active to obtain data at the outputs. CE0# and CE1# are the device selection controls, and, when both are active, enable the selected memory device. OE# is the data output (DQ0- DQ15) control: When active it drives the selected memory data onto the I/O bus. WE# must be at VIH and RP# must be at VIH. Figure 17 illustrates a read cycle. 3.2 Output Disable With OE# at a logic-high level (VIH), the device outputs are disabled. Output pins DQ0-DQ15 are placed in a high-impedance state. 3.3 Deep Power-Down RP# at VIL initiates the deep power-down mode. In read mode, RP#-low deselects the memory, places output drivers in a high-impedance state, and turns off all internal circuits. RP# must be held low for time tPLPH. Time tPHQV is required after return from power-down until initial memory access outputs are valid. After this wake-up interval, normal operation is restored. The CUI resets to read array mode, and the Status Register is set to 80H. During block erase, programming, or lock-bit configuration modes, RP#-low will abort the operation. STS in RY/BY# mode remains low until the reset operation is complete. Memory contents being altered are no longer valid; the data may be partially corrupted after programming or partially altered after an erase or lock-bit configuration. Time tPHWL is required after RP# goes to logic-high (VIH) before another command can be written. It is important in any automated system to assert RP# during system reset. When the system comes out of reset, it expects to read from the flash memory. Automated flash memories provide status information when accessed during block erase, programming, or lock-bit configuration modes. If a CPU reset occurs with no flash memory reset, proper CPU initialization may not occur because the flash memory may be providing status information instead of array data. Intel's Flash memories allow proper CPU initialization following a system reset through the use of the RP# input. In this application, RP# is controlled by the same RESET# signal that resets the system CPU. Standby CE0# or CE1# at a logic-high level (VIH) places the device in standby mode, substantially reducing device power consumption. DQ0-DQ15 (or DQ0- DQ7 in x8 mode) outputs are placed in a high-impedance state independent of OE#. If deselected during block erase, programming, or lock-bit configuration, the device continues functioning and consuming active power until the operation completes. 12 3.4 E 3.5 Read Query Operation The read query operation outputs block status, Common Flash Interface (CFI) ID string, system interface, device geometry, and Intel-specific extended query information. ADVANCE INFORMATION E 3.6 Read Identifier Codes Operation The read-identifier codes operation outputs the manufacturer code, device code, and block lock configuration codes for each block configuration (see Figure 6). Using the manufacturer and device codes, the system software can automatically match the device with its proper algorithms. The block-lock configuration codes identify each block's lock-bit setting. 28F160S3, 28F320S3 3.7 Write Writing commands to the CUI enables reading of device data, query, identifier codes, inspection and clearing of the Status Register. Additionally, when VPP = VPPH1/2, block erasure, programming, and lock-bit configuration can also be performed. The Block Erase command requires appropriate command data and an address within the block to be erased. The Byte/Word Write command requires the command and address of the location to be written. Set Block Lock-Bit commands require the command and address within the block to be locked. The Clear Block Lock-Bits command requires the command and an address within the device. The CUI does not occupy an addressable memory location. It is written when WE#, CE0#, and CE1# are active and OE# = VIH. The address and data needed to execute a command are latched on the rising edge of WE# or CEX# (CE0#, CE1#), whichever goes high first. Standard microprocessor write timings are used. Figure 18 illustrates a write operation. 4.0 COMMAND DEFINITIONS VPP voltage VPPLK enables read operations from the Status Register, identifier codes, or memory blocks. Placing VPPH1/2 on VPP enables successful block erase, programming, and lockbit configuration operations. Device operations are selected by writing specific commands into the CUI. and Table 3 define these commands. Figure 6. Device Identifier Code Memory Map ADVANCE INFORMATION 13 E 28F160S3, 28F320S3 Table 2. Bus Operations Mode CE1# OE#(11) WE#(11) Address VPP DQ(8) STS(3) VIH X X DOUT X VIH VIH X X High Z X X X X X High Z X High Z High Z(9) Notes RP# CE0# 1,2 VIH VIL VIL VIL Output Disable VIH VIL VIL Standby VIH VIL VIH Read VIH VIL VIH VIH Reset/PowerDown Mode 10 VIL X X X X X X Read Identifier Codes 4 VIH VIL VIL VIL VIH See Figure 6 X DOUT High Z(9) Read Query 5 VIH VIL VIL VIL VIH See Table 6 X DOUT High Z(9) 3,6,7 VIH VIL VIL VIH VIL X VPPH1/2 DIN X Write NOTES: 1. Refer to Table 19. When VPP VPPLK, memory contents can be read, but not altered. 2. X can be VIL or VIH for control and address input pins and VPPLK or VPPH1/2 for VPP. See Table 19, for VPPLK and VPPH1/2 voltages. 3. STS in level RY/BY# mode (default) is VOL when the WSM is executing internal block erase, programming, or lock-bit configuration algorithms. It is VOH when the WSM is not busy, in block erase suspend mode (with programming inactive), program suspend mode, or deep power-down mode. 4. See Section 4.3 for read identifier code data. 5. See Section 4.2 for read query data. 6. Command writes involving block erase, write, or lock-bit configuration are reliably executed when VPP = VPPH1/2 and VCC = VCC1/2 (see Section 6.2). 7. Refer to Table 3 for valid DIN during a write operation. 8. DQ refers to DQ0-7 if BYTE# is low and DQ0-15 if BYTE# is high. 9. High Z will be VOH with an external pull-up resistor. 10. RP# at GND 0.2V ensures the lowest deep power-down current. 11. OE# = VIL and WE# = VIL concurrently is an undefined state and should not be attempted. 14 ADVANCE INFORMATION E 28F160S3, 28F320S3 Table 3. Word-Wide FlashFileTM Memory Command Set Definitions(13) Command Scaleable Bus Notes or Basic Cycles Command Req'd Set(14) First Bus Cycle Second Bus Cycle Oper(1) Addr(2) Data(3,4) Oper(1) Addr(2) Data(3,4) Read Array SCS/BCS 1 Read Identifier Codes SCS/BCS 2 5 Write X FFH Write X 90H Read IA ID SCS 2 Write X 98H Read QA QD Read Status Register SCS/BCS 2 Write X 70H Read X SRD Clear Status Register SCS/BCS 1 Write X 50H SCS >2 8, 9, 10 Write BA E8H Write BA N Word/Byte Program SCS/BCS 2 6,7 Write X 40H or 10H Write PA PD Block Erase SCS/BCS 2 6,10 Write X 20H Write BA D0H Block Erase, Word/Byte SCS/BCS Program Suspend 1 6 Write X B0H Block Erase, Word/Byte SCS/BCS Program Resume 1 6 Write X D0H STS pin Configuration SCS 2 Write X B8H Write X CC Set Block Lock-Bit SCS 2 11 Write X 60H Write BA 01H Clear Block Lock-Bits SCS 2 12 Write X 60H Write X D0H Full Chip Erase SCS 2 10 Write X 30H Write X D0H Read Query Write to Buffer ADVANCE INFORMATION 15 28F160S3, 28F320S3 NOTES: 1. Bus operations are defined in Table 2. 2. X = Any valid address within the device. BA = Address within the block being erased or locked. IA = Identifier Code Address: see Table 12. QA = Query database Address. PA = Address of memory location to be programmed. 3. ID = Data read from Query database. SRD = Data read from Status Register. See Table 15 for a description of the Status Register bits. PD = Data to be programmed at location PA. Data is latched on the rising edge of WE#. CC = Configuration Code. (See Table 14.) 4. The upper byte of the data bus (DQ8-15) during command writes is a "Don't Care" in x16 operation. E 5. Following the Read Identifier Codes command, read operations access manufacturer, device, and block-lock codes. See Section 4.3 for read identifier code data. 6. If a block is locked (i.e., the block's lock-bit is set to 0), WP# must be at VIH in order to perform block erase, program and suspend operations. Attempts to issue a block erase, program and suspend operation to a locked block while WP# is VIL will fail. 7. Either 40H or 10H are recognized by the WSM as the byte/word program setup. 8. After the Write to Buffer command is issued, check the XSR to make sure a Write Buffer is available. 9. N = byte/word count argument such that the number of bytes/words to be written to the input buffer = N + 1. N = 0 is 1 byte/word length, and so on. Write to Buffer is a multi-cycle operation, where a byte/word count of N + 1 is written to the correct memory address (WA) with the proper data (WD). The Confirm command (D0h) is expected after exactly N + 1 write cycles; any other command at that point in the sequence aborts the buffered write. Writing a byte/word count outside the buffer boundary causes unexpected results and should be avoided. 10. The write to buffer, block erase, or full chip erase operation does not begin until a Confirm command (D0h) is issued. Confirm also reactivates suspended operations. 11. A block lock-bit can be set only while WP# is VIH. 12. WP# must be at VIH to clear block lock-bits. The clear block lock-bits operation simultaneously clears all block lock-bits. 13. Commands other than those shown above are reserved for future use and should not be used. 14. The Basic Command Set (BCS) is the same as the 28F008SA Command Set or Intel Standard Command Set. The Scaleable Command Set (SCS) is also referred to as the Intel Extended Command Set. 16 ADVANCE INFORMATION E 4.1 Read Array Command Upon initial device power-up and after exit from deep power-down mode, the device defaults to read array mode. This operation is also initiated by writing the Read Array command. The device remains enabled for reads until another command is written. Once the internal WSM has started block erase, program, or lock-bit configuration, the device will not recognize the Read Array command until the WSM completes its operation--unless the WSM is suspended via an Erase-Suspend or ProgramSuspend command. The Read Array command functions independently of the VPP voltage. 4.2 Read Query Mode Command This section defines the data structure or "database" returned by the Common Flash Interface (CFI) Query command. System software should parse this structure to gain critical information such as block size, density, x8/x16, and electrical specifications. Once this information has been obtained, the software will know which command sets to use to enable flash writes, block erases, and otherwise control the flash component. The Query is part of an overall specification for multiple command set and control interface descriptions called Common Flash Interface, or CFI. 4.2.1 QUERY STRUCTURE OUTPUT 28F160S3, 28F320S3 Query data are always presented on the lowestorder data outputs (DQ0-7) only. The numerical offset value is the address relative to the maximum bus width supported by the device. On this device, the Query table device starting address is a 10h word address, since the maximum bus width is x16. For this word-wide (x16) device, the first two bytes of the Query structure, "Q" and "R" in ASCII, appear on the low byte at word addresses 10h and 11h. This CFI-compliant device outputs 00H data on upper bytes. Thus, the device outputs ASCII "Q" in the low byte (DQ0-7) and 00h in the high byte (DQ8-15). Since the device is x8/x16 capable, the x8 data is still presented in word-relative (16-bit) addresses. However, the "fill data" (00h) is not the same as driven by the upper bytes in the x16 mode. As in x16 mode, the byte address (A0) is ignored for Query output so that the "odd byte address" (A0 high) repeats the "even byte address" data (A0 low). Therefore, in x8 mode using byte addressing, the device will output the sequence "Q", "Q", "R", "R", "Y", "Y", and so on, beginning at byte-relative address 20h (which is equivalent to word offset 10h in x16 mode). At Query addresses containing two or more bytes of information, the least significant data byte is presented at the lower address, and the most significant data byte is presented at the higher address. The Query "database" allows system software to gain critical information for controlling the flash component. This section describes the device's CFI-compliant interface that allows the host system to access Query data. ADVANCE INFORMATION 17 E 28F160S3, 28F320S3 Table 4. Summary of Query Structure Output as a Function of Device and Mode Device Type/Mode Word Addressing Location Byte Addressing Query Data Hex, ASCII Location Query Data Hex, ASCII x16 device/ x16 mode 10h 11h 12h 0051h "Q" 0052h "R" 0059h "Y" 20h 21h 22h 51h 00h 52h "Q" null "R" x16 device/ x8 mode N/A(1) N/A 20h 21h 22h 51h 51h 52h "Q" "Q" "R" NOTE: 1. The system must drive the lowest order addresses to access all the device's array data when the device is configured in x8 mode. Therefore, word addressing where lower addresses are not toggled by the system is"Not Applicable" for x8configured devices. Table 5. Example of Query Structure Output of a x16- and x8-Capable Device Device Address Word Addressing: Query Data Byte Address Byte Addressing: Query Data A16-A1 D15-D0 A7-A0 D7-D0 0010h 0011h 0012h 0013h 0014h 0015h 0016h 0017h 0018h ... 18 0051h 0052h 0059h P_IDLO P_IDHI PLO PHI A_IDLO A_IDHI ... "Q" "R" "Y" PrVendor ID # PrVendor TblAdr AltVendor ID # 20h 21h 22h 23h 24h 25h 26h 27h 28h ... 51h 51h 52h 52h 59h 59h P_IDLO P_IDLO P_IDHI ... "Q" "Q" "R" "R" "Y" "Y" PrVendor ID # " ADVANCE INFORMATION E 4.2.2 28F160S3, 28F320S3 QUERY STRUCTURE OVERVIEW The Query command causes the flash component to display the Common Flash Interface (CFI) Query structure or "database." The structure sub-sections and address locations are summarized in Table 8. The following sections describe the Query structure sub-sections in detail. Table 6. Query Structure(1) Offset Sub-Section Name Description 00h Manufacturer Code 01h Device Code (BA+2)h(2) Block Status Register Block-specific information 04-0Fh Reserved Reserved for vendor-specific information 10h CFI Query Identification String Command set ID and vendor data offset 1Bh System Interface Information Device timing & voltage information 27h Device Geometry Definition Flash device layout P(3) Primary Intel-Specific Extended Query Table Vendor-defined additional information specific to the Primary Vendor Algorithm NOTES: 1. Refer to Section 4.2.1 and Table 4 for the detailed definition of offset address as a function of device word width and mode. 2. BA = The beginning location of a Block Address (i.e., 08000h is the beginning location of block 1 when the block size is 32 Kword). 3. Offset 15 defines "P" which points to the Primary Intel-specific Extended Query Table. ADVANCE INFORMATION 19 E 28F160S3, 28F320S3 4.2.3 BLOCK STATUS REGISTER The Block Status Register indicates whether an erase operation completed successfully or whether a given block is locked or can be accessed for flash program/erase operations. Block Erase Status (BSR.1) allows system software to determine the success of the last block erase operation. BSR.1 can be used just after power-up to verify that the VCC supply was not accidentally removed during an erase operation. This bit is only reset by issuing another erase operation to the block. The Block Status Register is accessed from word address 02h within each block. Table 7. Block Status Register Offset (BA+2)h(1) Length (bytes) 01h Description 28F320S3/ 28F160S3 x16 Device/Mode Block Status Register BA+2: 0000h or 0001h BSR.0 = Block Lock Status 1 = Locked 0 = Unlocked BA+2 (bit 0): 0 or 1 BSR.1 = Block Erase Status 1 = Last erase operation did not complete successfully 0 = Last erase operation completed successfully BA+2 (bit 1): 0 or 1 BSR 2-7 Reserved for future use BA+2 (bits 2-7): 0 NOTE: 1. BA = The beginning location of a Block Address (i.e., 008000h is the beginning location of block 1 in word mode.) 20 ADVANCE INFORMATION E 4.2.4 28F160S3, 28F320S3 CFI QUERY IDENTIFICATION STRING The Identification String provides verification that the component supports the Common Flash Interface specification. Additionally, it indicates which version of the specification and which vendor-specified command set(s) is (are) supported. Table 8. CFI Identification Offset Length (Bytes) Description 28F320S3/ 28F160S3 10h 03h Query-Unique ASCII string "QRY" 10: 11: 12: 0051h 0052h 0059h 13h 02h Primary Vendor Command Set and Control Interface ID Code 16-bit ID Code for Vendor-Specified Algorithms 13: 14: 0001h 0000h 15h 02h Address for Primary Algorithm Extended Query Table Offset value = P = 31h 15: 16: 0031h 0000h 17h 02h Alternate Vendor Command Set and Control Interface ID Code Second Vendor-Specified Algorithm Supported Note: 0000h means none exists 17: 18: 0000h 0000h 19h 02h Address for Secondary Algorithm Extended Query Table Note: 0000h means none exists 19: 1A: 0000h 0000h ADVANCE INFORMATION 21 E 28F160S3, 28F320S3 4.2.5 SYSTEM INTERFACE INFORMATION The following device information can be useful in optimizing system interface software. Table 9. System Interface Information Offset Length (bytes) Description 28F320S3/ 28F160S3 1Bh 01h VCC Logic Supply Minimum Program/Erase Voltage bits 7-4 BCD volts bits 3-0 BCD 100 mv 1B: 0030h 1Ch 01h VCC Logic Supply Maximum Program/Erase Voltage bits 7-4 BCD volts bits 3-0 BCD 100 mv 1C: 0055h 1Dh 01h VPP [Programming] Supply Minimum Program/Erase Voltage bits 7-4 HEX volts bits 3-0 BCD 100 mv 1D: 0030h 1Eh 01h VPP [Programming] Supply Maximum Program/Erase Voltage bits 7-4 HEX volts bits 3-0 BCD 100 mv 1E: 0055h 1Fh 01h Typical Time-Out per Single Byte/Word Program, 2N -sec 1F: 0003h 20: 0006h 21: 000Ah 22: 000Fh 20h 21h 01h 01h Typical Time-Out for Max. Buffer Write, 2N -sec Typical Time-Out per Individual Block Erase, 2N 2N m-sec 22h 01h Typical Time-Out for Full Chip Erase, 23h 01h Maximum Time-Out for Byte/Word Program, 2N Times Typical 23: TBD 24h 01h Maximum Time-Out for Buffer Write, 2 N Times Typical 24: TBD 25h 01h Maximum Time-Out per Individual Block Erase, 2N Times Typical 25: TBD 26h 01h Maximum Time-Out for Chip Erase, 2N Times Typical 26: TBD 22 m-sec ADVANCE INFORMATION E 4.2.6 28F160S3, 28F320S3 DEVICE GEOMETRY DEFINITION This field provides critical details of the flash device geometry. Table 10. Device Geometry Definition Offset 27h 28h Length (bytes) 01h 02h Description Device Size = 2N in Number of Bytes Flash Device Interface Description value meaning 0002h x8/x16 asynchronous 28F320S3/ 28F160S3 27: 0015h (16Mb) 27: 0016h (32Mb) 28: 29: 0002h 0000h 2Ah 02h Maximum Number of Bytes in Write Buffer = 2 N 2A: 2B: 0005h 0000h 2Ch 01h Number of Erase Block Regions within Device: 2C: 0001h Erase Block Region Information y: bits 15-0 = y, Where y+1 = Number of Erase Blocks of Identical Size within Region 2D: 2E: 32 Blk (16Mb) 001Fh 0000h bits 31-16 = z, Where the Erase Block(s) within This Region are (z) x 256 Bytes y: bits 7-0 = x = # of Erase Block Regions 2Dh 04h ADVANCE INFORMATION 2D: 2E: 64 Blk (32Mb) 003Fh 0000h z: 2F: 30: 64-KB 0000h 0001h 23 E 28F160S3, 28F320S3 4.2.7 INTEL-SPECIFIC EXTENDED QUERY TABLE Certain flash features and commands are optional. The Intel-Specific Extended Query table specifies this and other similar types of information. Table 11. Primary-Vendor Specific Extended Query Offset(1) Length (bytes) (P)h 03h Primary Extended Query Table Unique ASCII String "PRI" 31: 32: 33: 0050h 0052h 0049h (P+3)h 01h Major Version Number, ASCII 34: 0031h (P+4)h 01h Minor Version Number, ASCII 35: 0030h (P+5)h 04h Optional Feature & Command Support 36: 37: 38: 39: 000Fh 0000h 0000h 0000h 3A: 0001h 3B: 3C: 0003h 0000h Description bit 0 bit 1 bit 2 bit 3 bit 4 Chip Erase Supported Suspend Erase Supported Suspend Program Supported Lock/Unlock Supported Queued Erase Supported Data (1=yes, 0=no) (1=yes, 0=no) (1=yes, 0=no) (1=yes, 0=no) (1=yes, 0=no) bits 5-31 Reserved for future use; undefined bits are "0" (P+9)h 01h Supported Functions after Suspend Read Array, Status, and Query are always supported during suspended Erase or Program operation. This field defines other operations supported. bit 0 Program Supported after Erase Suspend (1=yes, 0=no) bits 1-7 Reserved for future use; undefined bits are "0" (P+A)h 02h Block Status Register Mask Defines which bits in the Block Status Register section of Query are implemented. bit 0 Block Status Register Lock-Bit [BSR.0] active (1=yes, 0=no) bit 1 Block Erase Status Bit [BSR.1] active (1=yes, 0=no) bits 2-15 Reserved for future use; undefined bits are "0" NOTES: 1. The variable P is a pointer which is defined at offset 15h in Table 8. 24 ADVANCE INFORMATION E Offset (P+C)h 28F160S3, 28F320S3 Table 11. Primary-Vendor Specific Extended Query (Continued) Length (bytes) 01h Description VCC Logic Supply Optimum Program/Erase voltage (highest performance) bits 7-4 bits 3-0 (P+D)h 01h reserved 3D: 0050h 3E: 0050h BCD value in volts BCD value in 100 mv VPP [Programming] Supply Optimum Program/Erase voltage bits 7-4 bits 3-0 (P+E)h Data HEX value in volts BCD value in 100 mv Reserved for future use 4.3 Table 12. Identifier Codes Code Address(2) Data Manufacturer Code Device Code 16 Mbit 32 Mbit Block Lock Configuration * Block is Unlocked * Block is Locked * Reserved for Future Use Block Erase Status * Last erase completed successfully * Last erase did not complete successfully * Reserved for Future Use 000000 000001 000001 X0002(1) B0 D0 D4 DQ0 = 0 DQ0 = 1 DQ2-7 x0002(1) DQ1 = 0 Read Identifier Codes Command The identifier code operation is initiated by writing the Read Identifier Codes command. Following the command write, read cycles from addresses shown in Figure 6 retrieve the manufacturer, device, block lock configuration, and block erase status codes (see Table 12 for identifier code values). To terminate the operation, write another valid command. Like the Read Array command, the Read Identifier Codes command functions independently of the VPP voltage. Following the Read Identifier Codes command, the information in Table 12 can be read. DQ1 = 1 4.4 DQ2-7 NOTES: 1. X selects the specific block lock configuration code. See Figure 6 for the device identifier code memory map. 2. A0 should be ignored in this address. The lowest order address line is A1 in both word and byte mode. ADVANCE INFORMATION Read Status Register Command The Status Register may be read to determine when programming, block erasure, or lock-bit configuration is complete and whether the operation completed successfully. It may be read at any time by writing the Read Status Register command. After writing this command, all subsequent read operations output data from the Status Register until another valid command is written. The Status Register contents are latched on the falling edge of OE#, CE0#, or CE1# whichever occurs last. OE# or CEX# must toggle to VIH to update the Status Register latch. The Read Status Register command functions independently of the VPP voltage. 25 E 28F160S3, 28F320S3 Following a program, block erase, set block lock-bit, or clear block lock-bits command sequence, only SR.7 is valid until the Write State Machine completes or suspends the operation. Device I/O pins DQ0-6 and DQ8-15 are invalid. When the operation completes or suspends (SR.7 = 1), all contents of the Status Register are valid when read. The eXtended Status Register (XSR) may be read to determine Write Buffer availability (see Table 16). The XSR may be read at any time by writing the Write to Buffer command. After writing this command, all subsequent read operations output data from the XSR, until another valid command is written. The contents of the XSR are latched on the falling edge of OE# or CEX# whichever occurs last in the read cycle. Write to buffer command must be re-issued to update the XSR latch. 4.5 Clear Status Register Command Status Register bits SR.5, SR.4, SR.3, and SR.1 are set to "1"s by the WSM and can only be reset by the Clear Status Register command. These bits indicate various failure conditions (see Table 15). By allowing system software to reset these bits, several operations (such as cumulatively erasing or locking multiple blocks or programming several bytes/words in sequence) may be performed. The Status Register may be polled to determine if an error occurred during the sequence. To clear the Status Register, the Clear Status Register command is written. It functions independently of the applied VPP voltage. This command is not functional during block erase or program suspend modes. 4.6 Block Erase Command Block Erase is executed one block at a time and initiated by a two-cycle command. A Block Erase Setup command is written first, followed by a Confirm command. This command sequence requires appropriate sequencing and an address within the block to be erased (erase changes all block data to FFH). Block preconditioning, erase, and verify are handled internally by the WSM (invisible to the system). After the two-cycle block erase sequence is written, the device automatically outputs Status Register data when read (see Figure 10). The CPU can detect block erase completion by 26 analyzing STS in level RY/BY# mode or Status Register bit SR.7. Toggle OE#, CE0#, or CE1# to update the Status Register. When the block erase is complete, Status Register bit SR.5 should be checked. If a block erase error is detected, the Status Register should be cleared before system software attempts corrective actions. The CUI remains in read Status Register mode until a new command is issued. This two-step command sequence of set-up followed by execution ensures that block contents are not accidentally erased. An invalid Block Erase command sequence will result in both Status Register bits SR.4 and SR.5 being set to "1." Also, reliable block erasure can only occur when VCC = VCC1/2 and VPP = VPPH1/2. In the absence of these voltages, block contents are protected against erasure. If block erase is attempted while VPP VPPLK, SR.3 and SR.5 will be set to "1." Successful block erase requires that the corresponding block lock-bit be cleared, or WP# = VIH. If block erase is attempted when the corresponding block lock-bit is set and WP# = VIL, the block erase will fail and SR.1 and SR.5 will be set to "1." 4.7 Full Chip Erase Command The Full Chip Erase command followed by a Confirm command erases all unlocked blocks. After the Confirm command is written, the device erases all unlocked blocks from block 0 to block 31 (or 63) sequentially. Block preconditioning, erase, and verify are handled internally by the WSM. After the Full Chip Erase command sequence is written to the CUI, the device automatically outputs the Status Register data when read. The CPU can detect full chip erase completion by polling the STS pin in level RY/BY# mode or Status Register bit SR.7. When the full chip erase is complete, Status Register bit SR.5 should be checked to see if the operation completed successfully. If an erase error occurred, the Status Register should be cleared before issuing the next command. The CUI remains in read Status Register mode until a new command is issued. If an error is detected while erasing a block during a full chip erase operation, the WSM skips the remaining cells in that block and proceeds to erase the next block. Reading the block valid status code by issuing the Read Identifier Codes command or Query command informs the user of which block(s) failed to erase. ADVANCE INFORMATION E 28F160S3, 28F320S3 This two-step command sequence of setup followed by execution ensures that block contents are not accidentally erased. An invalid Full Chip Erase command sequence will result in both Status Register bits SR.4 and SR.5 being set to 1. Also, reliable full chip erasure can only occur when VCC = VCC1/2 and VPP = VPPH1/2. In the absence of these voltages, block contents are protected against erasure. If full chip erase is attempted while VPP VPPLK, SR.3 and SR.5 will be set to 1. When WP# = VIL, only unlocked blocks are erased. Full chip erase cannot be suspended. If an error occurs while writing, the device will stop programming, and Status Register bit SR.4 will be set to a "1" to indicate a program failure. Any time a media failure occurs during a program or an erase (SR.4 or SR.5 is set), the device will not accept any more Write to Buffer commands. Additionally, if the user attempts to write past an erase block boundary with a Write to Buffer command, the device will abort programming. This will generate an "Invalid Command/Sequence" error and Status Register bits SR.5 and SR.4 will be set to "1." To clear SR.4 and/or SR.5, issue a Clear Status Register command. 4.8 Reliable buffered programming can only occur when VCC = VCC1/2 and VPP = VPPH1/2. If programming is attempted while VPP VPPLK, Status Register bits SR.4 and SR.5 will be set to "1." Programming attempts with invalid VCC and VPP voltages produce spurious results and should not be attempted. Finally, successful programming requires that the corresponding Block Lock-Bit be cleared, or WP# = VIH. If a buffered write is attempted when the corresponding Block Lock-Bit is set and WP# = VIL, SR.1 and SR.4 will be set to "1." Write to Buffer Command To program the flash device via the write buffers, a Write to Buffer command sequence is initiated. A variable number of bytes or words, up to the buffer size, can be written into the buffer and programmed to the flash device. First, the Write to Buffer setup command is issued along with the Block Address. At this point, the eXtended Status Register information is loaded and XSR.7 reverts to the "buffer available" status. If XSR.7 = 0, no write buffer is available. To retry, continue monitoring XSR.7 by issuing the Write to Buffer setup command with the Block Address until XSR.7 = 1. When XSR.7 transitions to a "1," the buffer is ready for loading. Now a Word/Byte count is issued at an address within the block. On the next write, a device start address is given along with the write buffer data. For maximum programming performance and lower power, align the start address at the beginning of a Write Buffer boundary. Subsequent writes must supply additional device addresses and data, depending on the count. All subsequent addresses must lie within the start address plus the count. After the final buffer data is given, a Write Confirm command is issued. This initiates the WSM to begin copying the buffer data to the flash memory. If a command other than Write Confirm is written to the device, an "Invalid Command/Sequence" error will be generated and Status Register bits SR.5 and SR.4 will be set to "1." For additional buffer writes, issue another Write to Buffer setup command and check XSR.7. The write buffers can be loaded while the WSM is busy as long as XSR.7 indicates that a buffer is available. Refer to Figure 7 for the Write to Buffer flowchart. ADVANCE INFORMATION 4.9 Byte/Word Program Commands Byte/Word programming is executed by a two-cycle command sequence. Byte/Word Program setup (standard 40H or alternate 10H) is written, followed by a second write that specifies the address and data (latched on the rising edge of WE#). The WSM then takes over, controlling the program and verify algorithms internally. After the write sequence is written, the device automatically outputs Status Register data when read. The CPU can detect the completion of the program event by analyzing STS in level RY/BY# mode or Status Register bit SR.7. When programming is complete, Status Register bit SR.4 should be checked. If a programming error is detected, the Status Register should be cleared. The internal WSM verify only detects errors for "1"s that do not successfully program to "0"s. The CUI remains in read Status Register mode until it receives another command. Refer to Figure 8 for the Word/Byte Program flowchart. Also, Reliable byte/word programming can only occur when VCC = VCC1/2 and VPP = VPPH1/2. In the absence of this high voltage, contents are protected against programming. If a byte/word program is 27 E 28F160S3, 28F320S3 attempted while VPP VPPLK, Status Register bits SR.4 and SR.3 will be set to "1." Successful byte/word programming requires that the corresponding block lock-bit be cleared. If a byte/word program is attempted when the corresponding block lock-bit is set and WP# = VIL, SR.1 and SR.4 will be set to "1." 4.10 STS Configuration Command The Status (STS) pin can be configured to different states using the STS pin Configuration command. Once the STS pin has been configured, it remains in that configuration until another configuration command is issued or RP# is low. Initially, the STS pin defaults to level RY/BY# operation where STS low indicates that the state machine is busy. STS high indicates that the state machine is ready for a new operation or suspended. To reconfigure the Status (STS) pin to other modes, the STS pin Configuration command is issued followed by the desired configuration code. The three alternate configurations are all pulse mode for use as a system interrupt as described in Table 14. For these configurations, bit 0 controls Erase Complete interrupt pulse, and bit 1 controls Write Complete interrupt pulse. When the device is configured in one of the pulse modes, the STS pin pulses low with a typical pulse width of 250 ns. Supplying the 00h configuration code with the Configuration command resets the STS pin to the default RY/BY# level mode. Refer to Table 14 for configuration coding definitions. The Configuration command may only be given when the device is not busy or suspended. Check SR.7 for device status. An invalid configuration code will result in both Status Register bits SR.4 and SR.5 being set to "1." 4.11 Block Erase Suspend Command The Block Erase Suspend command allows block-erase interruption to read or program data in another block of memory. Once the block erase process starts, writing the Block Erase Suspend command requests that the WSM suspend the block erase sequence at a predetermined point in the algorithm. The device outputs Status Register data when read after the Block Erase Suspend command is written. Polling Status Register bit 28 SR.7 can determine when the block erase operation has been suspended. When SR.7 = 1, SR.6 should also be set to "1," indicating that the device is in the erase suspend mode. STS in level RY/BY# mode will also transition to VOH. Specification tWHRH2 defines the block erase suspend latency. At this point, a Read Array command can be written to read data from blocks other than that which is suspended. A Program command sequence can also be issued during erase suspend to program data in other blocks. Using the Program Suspend command (see Section 4.12), a program operation can also be suspended. During a program operation with block erase suspended, Status Register bit SR.7 will return to "0" and STS in RY/BY# mode will transition to VOL. However, SR.6 will remain "1" to indicate block erase suspend status. The only other valid commands while block erase is suspended are Read Status Register and Block Erase Resume. After a Block Erase Resume command is written to the flash memory, the WSM will continue the block erase process. Status register bits SR.6 and SR.7 will automatically clear and STS in RY/BY# mode will return to VOL. After the Erase Resume command is written, the device automatically outputs Status Register data when read (see Figure 11). VPP must remain at VPPH1/2 and VCC must remain at VCC1/2 (the same VPP and VCC levels used for block erase) while block erase is suspended. RP# must also remain at VIH (the same RP# level used for block erase). Block erase cannot resume until program operations initiated during block erase suspend have completed. 4.12 Program Suspend Command The Program Suspend command allows program interruption to read data in other flash memory locations. Once the programming process starts, writing the Program Suspend command requests that the WSM suspend the program sequence at a predetermined point in the algorithm. The device continues to output Status Register data when read after the Program Suspend command is written. Polling Status Register bits SR.7 can determine when the programming operation has been suspended. When SR.7 = 1, SR.2 should also be set to "1", indicating that the device is in the program suspend mode. STS in level RY/BY# mode will also transition to VOH. Specification tWHRH1 defines the program suspend latency. ADVANCE INFORMATION E At this point, a Read Array command can be written to read data from locations other than that which is suspended. The only other valid commands while programming is suspended are Read Status Register and Program Resume. After a Program Resume command is written, the WSM will continue the programming process. Status Register bits SR.2 and SR.7 will automatically clear and STS in RY/BY# mode will return to VOL. After the Program Resume command is written, the device automatically outputs Status Register data when read. VPP must remain at VPPH1/2 and VCC must remain at VCC1/2 (the same VPP and VCC levels used for programming) while in program suspend mode. RP# must also remain at VIH (the same RP# level used for programming). Refer to Figure 9 for the Program Suspend/Resume flowchart. 4.13 Set Block Lock-Bit Command A flexible block locking and unlocking scheme is enabled via a combination of block lock-bits. The block lock-bits gate program and erase operations. With WP# = VIH, individual block lock-bits can be set using the Set Block Lock-Bit command. Set block lock-bit is initiated using a two-cycle command sequence. The Set Block Lock-Bit setup along with appropriate block or device address is written followed by the Set Block Lock-Bit Confirm and an address within the block to be locked. The WSM then controls the set lock-bit algorithm. After the sequence is written, the device automatically outputs Status Register data when read. The CPU can detect the completion of the set lock-bit event by analyzing STS in level RY/BY# mode or Status Register bit SR.7. When the set lock-bit operation is complete, Status Register bit SR.4 should be checked. If an error is detected, the Status Register should be cleared. The CUI will remain in read Status Register mode until a new command is issued. This two-step sequence of setup followed by execution ensures that lock-bits are not accidentally set. An invalid Set Block Lock-Bit command will result in Status Register bits SR.4 and SR.5 being set to "1." Also, reliable operations occur only when VCC = VCC1/2 and VPP = VPPH1/2. In the absence of these voltages, lock-bit contents are protected against alteration. ADVANCE INFORMATION 28F160S3, 28F320S3 A successful set block lock-bit operation requires that WP# = VIH. If it is attempted with WP# = VIL, the operation will fail and SR.1 and SR.4 will be set to "1." See Table 13 for write protection alternatives. Refer to Figure 12 for the Set Block Lock-Bit flowchart. 4.14 Clear Block Lock-Bits Command All set block lock-bits are cleared in parallel via the Clear Block Lock-Bits command. This command is valid only when WP# = VIH. The clear block lock-bits operation is initiated using a two-cycle command sequence. A Clear Block Lock-Bits setup command is written followed by a Confirm command. Then, the device automatically outputs Status Register data when read (see Figure 13). The CPU can detect completion of the clear block lock-bits event by analyzing STS in level RY/BY# mode or Status Register bit SR.7. This two-step sequence of set-up followed by execution ensures that block lock-bits are not accidentally cleared. An invalid Clear Block Lock-Bits command sequence will result in Status Register bits SR.4 and SR.5 being set to "1." Also, a reliable clear block lock-bits operation can only occur when VCC = VCC1/2 and VPP = VPPH1/2. If a clear block lock-bits operation is attempted while VPP VPPLK, SR.3 and SR.5 will be set to "1." In the absence of these voltages, the block lock-bits contents are protected against alteration. A successful clear block lock-bits operation requires that WP# = VIH. If a clear block lock-bits operation is aborted due to VPP or VCC transitioning out of valid range or RP# or WP# active transition, block lock-bit values are left in an undetermined state. A repeat of clear block lock-bits is required to initialize block lock-bit contents to known values. When the operation is complete, Status Register bit SR.5 should be checked. If a clear block lock-bit error is detected, the Status Register should be cleared. The CUI will remain in read Status Register mode until another command is issued. 29 E 28F160S3, 28F320S3 Table 13. Write Protection Alternatives Block LockBit WP# Program and 0 VIL or VIH Block Erase 1 VIL Block is locked. Block erase and programming disabled Operation Full Chip Erase Set or Clear Effect Block erase and programming enabled VIH Block Lock-Bit override. Block erase and programming enabled 0,1 VIL All unlocked blocks are erased X VIH Block Lock-Bit override. All blocks are erased X VIL Set or clear block lock-bit disabled VIH Set or clear block lock-bit enabled Block Lock-Bit Table 14. Configuration Coding Definitions Reserved Pulse on Write Complete Pulse on Erase Complete bits 7-2 bit 1 bit 0 DQ7-DQ2 = Reserved DQ7-DQ2 are reserved for future use. DQ1/DQ0 = STS Pin Configuration Codes default (DQ1/DQ0 = 00) RY/BY#, level mode -----used to control HOLD to a memory controller to prevent accessing a flash memory subsystem while any flash device's WSM is busy. 00 = default, level mode RY/BY# (device ready) indication 01 = pulse on Erase complete 10 = pulse on Flash Program complete 11 = pulse on Erase or Program Complete Configuration Codes 01b, 10b, and 11b are all pulse mode such that the STS pin pulses low then high when the operation indicated by the given configuration is completed. Configuration Command Sequences for STS pin configuration (masking bits D7-D2 to 00h) are as follows: Default RY/BY# level mode ER INT (Erase Interrupt): Pulse-on-Erase Complete PR INT (Program Interrupt): Pulse-on-Flash-Program Complete ER/PR INT (Erase or Program Interrupt): Pulse-on-Erase or Program Complete B8h, 00h B8h, 01h B8h, 02h B8h, 03h configuration 01 ER INT, pulse mode(1) -----used to generate a system interrupt pulse when any flash device in an array has completed a block erase or sequence of queued block erases. Helpful for reformatting blocks after file system free space reclamation or `cleanup' configuration 10 PR INT, pulse mode(1) -----used to generate a system interrupt pulse when any flash device in an array has complete a program operation. Provides highest performance for servicing continuous buffer write operations. configuration ER/PR INT, pulse mode(1) -----used to generate system interrupts to trigger servicing of flash arrays when either erase or flash program operations are completed when a common interrupt service routine is desired. NOTE: 1. When the device is configured in one of the pulse modes, the STS pin pulses low with a typical pulse width of 250 ns. 30 ADVANCE INFORMATION E 28F160S3, 28F320S3 Table 15. Status Register Definition WSMS ESS ECLBS BWSLBS VPPS BWSS DPS R 7 6 5 4 3 2 1 0 NOTES: Check STS in RY/BY# mode or SR.7 to determine block erase, programming, or lock-bit configuration completion. SR.6-0 are invalid while SR.7 = "0." SR.7 = WRITE STATE MACHINE STATUS 1 = Ready 0 = Busy SR.6 = ERASE SUSPEND STATUS 1 = Block erase suspended 0 = Block erase in progress/completed SR.5 = ERASE AND CLEAR LOCK-BITS STATUS 1 = Error in block erasure or clear lock-bits 0 = Successful block erase or clear lock-bits If both SR.5 and SR.4 are "1"s after a block erase or lock-bit configuration attempt, an improper command sequence was entered. SR.4 = PROGRAM AND SET LOCK-BIT STATUS 1 = Error in program or block lock-bit 0 = Successful program or set block lock-bit SR.3 does not provide a continuous indication of VPP level. The WSM interrogates and indicates the VPP level only after a block erase, program, or lockbit configuration operation. SR.3 reports accurate feedback only when VPP = VPPH1/2. SR.3 = VPP STATUS 1 = VPP low detect, operation abort 0 = VPP OK SR.2 = PROGRAM SUSPEND STATUS 1 = Program suspended 0 = Program in progress/completed SR.1 = DEVICE PROTECT STATUS 1 = Block Lock-Bit and/or RP# lock detected, operation abort 0 = Unlock SR.1 does not provide a continuous indication of block lock-bit values. The WSM interrogates the block lock-bit, and WP# only after a block erase, program, or lock-bit configuration operation. It informs the system, depending on the attempted operation, if the block lock-bit is set. SR.0 = RESERVED FOR FUTURE ENHANCEMENTS SR.0 is reserved for future use and should be masked when polling the Status Register. Table 16. Extended Status Register Definition WBS R R R R R R R 7 6 5 4 3 2 1 0 NOTES: XSR.7 = WRITE BUFFER STATUS 1 = Write to buffer available 0 = Write to buffer not available After a Write to buffer command, XSR.7 indicates that another Write to buffer command is possible. XSR.6 = RESERVED FOR FUTURE ENHANCEMENTS SR.6-0 are reserved for future use and should be masked when polling the status register ADVANCE INFORMATION 31 E 28F160S3, 28F320S3 Command Bus Operation Write Write to Buffer Read Start Set Time-Out Issue Write Command E8H, Block Address No Read Extended Status Register Write Buffer Time-Out? 0 XSR.7 = 1 Write Word or Byte Count, Block Address Write Buffer Data, Start Address X=0 Yes X=N No Yes Abort Buffer Write Command? Yes Write to Another Block Address Buffer Write to Flash Aborted Yes No Write Next Buffer Data, Device Address Comments Data = E8h Addr = Block Address XSR.7=valid Addr = X Standby Check XSR.7 1 = Write buffer available 0 = Write buffer not available Write Data = N = word/byte count (Note 1, 2) N = 0 corresponds to count = 1 Addr = Block Address Write Data = write buffer data (Note 3, 4) Addr = device start address Write Data = write buffer data (Note 5, 6) Addr = device address Write Buffer Data = D0h write to flash Addr = X confirm Read Status Register data CE# & OE# low updates SR Addr = X Standby Check SR.7 1 = WSM ready 0 = WSM busy 1. Byte- or word-count values on DQ0-7 are loaded into the Count register. 2. The device now outputs the Status Register when read (XSR is no longer available). 3. Write Buffer contents will be programmed at the device start address or destination flash address. 4. Align the start address on a Write Buffer boundary for maximum programming performance. 5. The device aborts the Write to Buffer command if the current address is outside of the original block address. 6. The Status Register indicates an "improper command sequence" if the Write to Buffer command is aborted. Follow this with a Clear Status Register command. Full status check can be done after all Erase and Write sequences complete. Write FFh after the last operation to reset the device to Read Array mode. X=X+1 Buffer Write to Flash Confirm D0H Another Buffer Write? Issue Read Status Command No Read Status Register SR.7 = No 0 Suspend Write? Suspend Write Loop Yes 1 Full Status Check if Desired Buffer Write to Flash Complete Figure 7. Write to Buffer Flowchart 32 ADVANCE INFORMATION E 28F160S3, 28F320S3 Figure 8. Single Byte/Word Program Flowchart ADVANCE INFORMATION 33 E 28F160S3, 28F320S3 Figure 9. Program Suspend/Resume Flowchart 34 ADVANCE INFORMATION E 28F160S3, 28F320S3 Bus Command Comments Operation Write Erase Block Data = 28h or 20h Addr = Block Address Start Device Supports Queuing Read Yes Set Time-Out Issue Block Queue Erase Command 28H, Block Address No Read Extended Status Register Queued Erase Section (Include this section for compatibility with future SCS-compliant devices) Erase Block Time-Out? 0=No Is Queue Available? XSR.7= No 1=Yes Another Block Erase? Yes Yes XSR.7=valid Addr = X Standby Check XSR.7 1 = Erase queue available 0 = No Erase queue available Write Erase Block Data = 28H Addr = Block Address Read SR.7=valid; SR.6-0=X With the device enabled, OE# low updates SR Addr = X Standby Check XSR.7 1 = Erase queue available 0 = No Erase queue available Write Erase Data = D0H (Note 1) Confirm Addr = X Read Status Register data With the device enabled, OE# low updates SR Addr = X Standby Check SR.7 1 = WSM ready 0 = WSM busy 1. The Erase Confirm byte must follow Erase Setup when the Erase Queue status (XSR.7)=0. Yes Full status check can be done after all Erase and Write sequences complete. Write FFh after the last operation to reset the device to Read Array mode. Issue Erase Command 28H Block Address 1=No No Read Extended Status Register Is Queue Full? XSR.7= Issue Single Block Erase Command 20H, Block Address 0=Yes Write Confirm D0H Block Address Issue Read Status Command Write Confirm D0H Block Address Another Block Erase? No Read Status Register No Suspend Erase Loop 0 SR.7 = Suspend Erase Yes 1 Full Status Check if Desired Erase Flash Block(s) Complete Figure 10. Block Erase Flowchart ADVANCE INFORMATION 35 E 28F160S3, 28F320S3 Start Bus Operation Write Write B0H Command Erase Suspend Status Register Data Addr = X Standby Check SR.7 1 = WSM Ready 0 = WSM Busy 0 Check SR.6 1 = Block Erase Suspended 0 = Block Erase Completed Standby 1 SR.6 = Write 0 Block Erase Completed Data = B0H Addr = X Read Read Status Register SR.7 = Comments Erase Resume Data = D0H Addr = X 1 Read Read Array Data Write Read or Write? No Write Loop Done? Yes Write D0H Write FFH Block Erase Resumed Read Array Data Figure 11. Block Erase Suspend/Resume Flowchart 36 ADVANCE INFORMATION E 28F160S3, 28F320S3 Start Bus Operation Command Comments Write Set Block/Master Lock-Bit Setup Data = 60H Addr = Block Address (Block), Device Address (Master) Write 01H/F1H, Block/Device Address Write Set Block or Master Lock-Bit Confirm Data = 01H (Block), F1H (Master) Addr = Block Address (Block), Device Address (Master) Read Status Register Read Write 60H, Block/Device Address Status Register Data Check SR.7 1 = WSM Ready 0 = WSM Busy Standby 0 SR.7 = Repeat for subsequent lock-bit set operations. Full status check can be done after each lock-bit set operation or after a sequence of lock-bit set operations. Write FFH after the last lock-bit set operation to place device in read array mode. 1 Full Status Check if Desired Set Lock-Bit Complete FULL STATUS CHECK PROCEDURE Bus Operation Read Status Register Data (See Above) SR.3 = 1 Command Standby Check SR.3 1 = Programming Voltage Error Detect Standby Check SR.1 1 = Device Protect Detect RST# = VIH (Set Master Lock-Bit Operation) RST# = VIH , Master Lock-Bit Is Set (Set Block Lock-Bit Operation) Standby Check SR.4,5 Both 1 = Command Sequence Error Standby Check SR.4 1 = Set Lock-Bit Error Voltage Range Error 0 SR.1 = 1 Device Protect Error 0 1 SR.4,5 = Command Sequence Error 0 1 SR.4 = Set Lock-Bit Error 0 Comments SR.5, SR.4, SR.3 and SR.1 are only cleared by the Clear Status Register command in cases where multiple lock-bits are set before full status is checked. If error is detected, clear the Status Register before attempting retry or other error recovery. Set Lock-Bit Successful Figure 12. Set Block Lock-Bit Flowchart ADVANCE INFORMATION 37 E 28F160S3, 28F320S3 Start Write 60H Bus Operation Command Write Clear Block Lock-Bits Setup Data = 60H Addr = X Write Clear Block Lock-Bits Confirm Data = D0H Addr = X Comments Write D0H Read Status Register Data Read Status Register Check SR.7 1 = WSM Ready 0 = WSM Busy Standby 0 SR.7 = Write FFH after the Clear Block Lock-Bits operation to place device to read array mode. 1 Full Status Check if Desired Clear Block Lock-Bits Complete FULL STATUS CHECK PROCEDURE Bus Operation Read Status Register Data (See Above) Command Check SR.3 1 = Programming Voltage Error Detect Standby SR.3 = 1 Voltage Range Error 0 SR.1= 1 Device Protect Error Comments Standby Check SR.1 1 = Device Protect Detect RST# = VIH , Master Lock-Bit Is Set Standby Check SR.4,5 Both 1 = Command Sequence Error Standby Check SR.5 1 = Clear Block Lock-Bits Error 0 1 SR.4,5 = Command Sequence Error 0 1 SR.5 = Clear Block Lock-Bits Error SR.5, SR.4, SR.3 and SR.1 are only cleared by the Clear Status Register command. If error is detected, clear the Status Register before attempting retry or other error recovery. 0 Clear Block Lock-Bits Successful Figure 13. Clear Block Lock-Bits Flowchart 38 ADVANCE INFORMATION E 5.0 DESIGN CONSIDERATIONS 5.1 Three-Line Output Control Intel provides three control inputs to accommodate multiple memory connections: CEX# (CE0#, CE1#), OE#, and RP#. Three-line control provides for: 28F160S3, 28F320S3 Additionally, for every eight devices, a 4.7 F electrolytic capacitor should be placed at the array's power supply connection between VCC and GND. The bulk capacitor will overcome voltage slumps caused by PC board trace inductance. 5.4 a. Lowest possible memory power dissipation; b. Data bus contention avoidance. To use these control inputs efficiently, an address decoder should enable CEx# while OE# should be connected to all memory devices and the system's READ# control line. This assures that only selected memory devices have active outputs, while deselected memory devices are in standby mode. RP# should be connected to the system POWERGOOD signal to prevent unintended writes during system power transitions. POWERGOOD should also toggle during system reset. 5.2 STS and WSM Polling STS is an open drain output that should be connected to VCC by a pull-up resistor to provide a hardware form of detecting block erase, program, and lock-bit configuration completion. In default mode, it transitions low during execution of these commands and returns to VOH when the WSM has finished executing the internal algorithm. For alternate STS pin configurations, see Section 4.10. STS can be connected to an interrupt input of the system CPU or controller. It is active at all times. STS, in default mode, is also VOH when the device is in block erase suspend (with programming inactive) or in reset/power-down mode. 5.3 Power Supply Decoupling Flash memory power switching characteristics require careful device decoupling. Standby current levels, active current levels and transient peaks produced by falling and rising edges of CEX# and OE# are areas of interest. Two-line control and proper decoupling capacitor selection will suppress transient voltage peaks. Each device should have a 0.1 F ceramic capacitor connected between its VCC and GND and VPP and GND. These highfrequency, low-inductance capacitors should be placed as close as possible to package leads. ADVANCE INFORMATION VPP Trace on Printed Circuit Boards Updating target-system resident flash memories requires that the printed circuit board designer pay attention to VPP power supply traces. The VPP pin supplies the memory cell current for programming and block erasing. Use similar trace widths and layout considerations given to the VCC power bus. Adequate VPP supply traces and decoupling will decrease VPP voltage spikes and overshoots. 5.5 VCC, VPP, RP# Transitions Block erase, program, and lock-bit configuration are not guaranteed if RP# VIH, or if VPP or VCC fall outside of a valid voltage range (VCC1/2 and VPPH1/2). If VPP error is detected, Status Register bit SR.3 and SR.4 or SR.5 are set to "1." If RP# transitions to VIL during block erase, program, or lock-bit configuration, STS in level RY/BY# mode will remain low until the reset operation is complete. Then, the operation will abort and the device will enter deep power-down. Because the aborted operation may leave data partially altered, the command sequence must be repeated after normal operation is restored. 5.6 Power-Up/Down Protection The device offers protection against accidental block erase, programming, or lock-bit configuration during power transitions. A system designer must guard against spurious writes for VCC voltages above VLKO when VPP is active. Since both WE# and CEX# must be low for a command write, driving either input signal to VIH will inhibit writes. The CUI's two-step command sequence architecture provides an added level of protection against data alteration. In-system block lock and unlock renders additional protection during power-up by prohibiting block erase and program operations. RP# = VIL disables the device regardless of its control inputs states. 39 E 28F160S3, 28F320S3 6.0 6.1 ELECTRICAL SPECIFICATIONS NOTICE: This datasheet contains information on products in the design phase of development. Do not finalize a design with this information. Revised information will be published when the product is available. Verify with your local Intel Sales office that you have the latest datasheet before finalizing a design Absolute Maximum Ratings Temperature under Bias ................ -40C to +85C Storage Temperature................... -65C to +125C Voltage On Any Pin (except VCC and VPP ) .................................... -0.5V to + VCC +0.5V(1) VCC Supply Voltage ............ -0.2V to + VCC+0.5V(1) VPP Update Voltage during Block Erase, Flash Write, and Lock-Bit Configuration ........... -0.2V to +7.0V(2) Output Short Circuit Current.....................100 mA(3) *WARNING: Stressing the device beyond the "Absolute Maximum Ratings" may cause permanent damage. These are stress ratings only. Operation beyond the "Operating Conditions" is not recommended and extended exposure beyond the "Operating Conditions" may affect device reliability. NOTES: 1. All specified voltages are with respect to GND. Minimum DC voltage is -0.5V on input/output pins and -0.2V on VCC and VPP pins. During transitions, this level may undershoot to -2.0V for periods <20 ns. Maximum DC voltage on input/output pins and VCC is VCC +0.5V which, during transitions, may overshoot to VCC +2.0V for periods <20 ns. 2. Maximum DC voltage on VPP may overshoot to +7.0V for periods <20 ns. 3. Output shorted for no more than one second. No more than one output shorted at a time. 4. Operating temperature is for extended product defined by this specification. 6.2 Operating Conditions Table 17. Temperature and VCC Operating Conditions(1) Symbol Parameter Notes Min Max Unit Test Condition Ambient Temperature TA Operating Temperature -40 +85 C VCC1 VCC Supply Voltage (2.7V to 3.6V) 2.7 3.6 V VCC2 VCC Supply Voltage (3.3V 0.3V) 3.0 3.6 V NOTES: 1. Device operations in the VCC voltage ranges not covered in the table produce spurious results and should not be attempted. 40 ADVANCE INFORMATION E 6.2.1 28F160S3, 28F320S3 CAPACITANCE Table 18. Capacitance(1), TA = +25C, f = 1 MHz Symbol Parameter Typ Max Unit Condition CIN Input Capacitance 6 8 pF VIN = 0.0V COUT Output Capacitance 8 12 pF VOUT = 0.0V NOTE: 1. Sampled, not 100% tested. 6.2.2 AC INPUT/OUTPUT TEST CONDITIONS 2.7 INPUT 1.35 TEST POINTS 1.35 OUTPUT 0.0 AC test inputs are driven at 2.7V for a Logic "1" and 0.0V for a Logic "0." Input timing begins, and output timing ends, at 1.35V. Input rise and fall times (10% to 90%) <10 ns. Figure 14. Transient Input/Output Reference Waveform for VCC = 2.7V-3.6V 3.0 INPUT 1.5 TEST POINTS 1.5 OUTPUT 0.0 AC test inputs are driven at 3.0V for a Logic "1" and 0.0V for a Logic "0." Input timing begins, and output timing ends, at 1.5V. Input rise and fall times (10% to 90%) <10 ns. Figure 15. Transient Input/Output Reference Waveform for VCC = 3.3V 0.3V (High Speed Testing Configuration) Test Configuration Capacitance Loading Value Test Configuration CL (pF) 1.3V 1N914 VCC = 3.3V 0.3V, 2.7V to 3.6V 50 R L = 3.3 k DEVICE UNDER TEST OUT CL C L Includes Jig Capacitance Figure 16. Transient Equivalent Testing Load Circuit ADVANCE INFORMATION 41 E 28F160S3, 28F320S3 6.2.3 DC CHARACTERISTICS Table 19. DC Characteristics, TA = -40oC to +85oC Sym Parameter Notes Typ Max Unit Conditions ILI Input Load Current 1 0.5 A VCC = VCC1/2 Max VIN = VCC1/2 or GND ILO Output Leakage Current 1 0.5 A VCC = VCC1/2 Max Vout = VCC1/2 or GND ICCS VCC Standby Current 20 100 A CMOS Inputs VCC = VCC1/2 Max CEX# = RP# = VCC 0.2V 0.2 2 mA TTL Inputs VCC = VCC1/2 Max CEX# = RP# = VIH 1 20 A RP# = GND 0.2V IOUT (RY/BY#) = 0 mA 1,5,6 25 mA CMOS Inputs VCC = VCC1/2 Max ICCD VCC Deep Power-Down Current ICCR VCC Read Current 1,3,6 CEX# = GND f = 5 MHz, I OUT = 0 mA 30 mA TTL Inputs VCC = VCC1/2 Max CEX# = VIL f = 5 MHz, I OUT = 0 mA ICCW VCC Programming and Set Lock-Bit Current 1,7 17 mA VPP = VPPH1/2 ICCE VCC Block Erase or Clear Block Lock-Bits Current 1,7 17 mA VPP = VPPH1/2 ICCWS V Program Suspend or CC ICCES Block Erase Suspend Current 1,2 1 6 mA CEX# = VIH 1 2 15 A VPP VCC 10 200 A VPP VCC 0.1 5 A RP# = GND 0.2V IPPS VPP Standby or VPP Read IPPR Current IPPD VPP Deep Power-Down Current IPPW VPP Program or Set Lock-Bit Current 1,7 80 mA VPP = VPPH1/2 IPPE VPP Block Erase or Clear Block Lock-Bits Current 1,7 40 mA VPP = VPPH1/2 IPPWS IPPES VPP Program Suspend or Block Erase Suspend Current 1 200 A VPP = VPPH1/2 42 1 10 ADVANCE INFORMATION E Sym 28F160S3, 28F320S3 Parameter Table 19. DC Characteristics (Continued) Notes Min Max Unit Conditions VIL Input Low Voltage 7 -0.5 0.8 V VIH Input High Voltage 7 2.0 VCC +0.5 V VOL Output Low Voltage 3,7 0.4 V VCC = VCC1/2 Min IOL = 5.8 mA VOH1 Output High Voltage (TTL) 3,7 2.4 V VCC = VCC1/2 Min IOH = -2.5 mA VOH2 Output High Voltage (CMOS) 3,7 0.85 x VCC V VCC = VCC1/2 Min IOH = -2.5 mA VCC - 0.4 V VCC = VCC1/2 Min IOH = -100 A VPPLK VPP Lockout Voltage 4,7 1.5 V VPPH1 VPP Voltage 4 2.7 3.6 V VPPH2 VPP Voltage 4 4.5 5.5 V VLKO 8 2.0 VCC Lockout Voltage V NOTES: 1. All currents are in RMS unless otherwise noted. Typical values at nominal VCC voltage and TA = +25C. These currents are valid for all product versions (packages and speeds). 2. ICCWS and ICCES are specified with the device de-selected. If read or programmed while in erase suspend mode, the device's current is the sum of ICCWS or ICCES and ICCR or ICCW. 3. Includes STS in level RY/BY# mode. 4. Block erase, program, and lock-bit configurations are inhibited when VPP VPPLK, and not guaranteed in the ranges between VPPLK (max) and VPPH1 (min), between VPPH1 (max) and VPPH2 (min), and above VPPH2 (max). 5. Automatic Power Savings (APS) reduces typical ICCR to 3 mA at 2.7V and 3.3V VCC static operation. 6. CMOS inputs are either VCC 0.2V or GND 0.2V. TTL inputs are either VIL or VIH. 7. Sampled, not 100% tested. 8. With VCC VLKO flash memory writes are inhibited. ADVANCE INFORMATION 43 E 28F160S3, 28F320S3 6.2.4 AC CHARACTERISTICS - READ-ONLY OPERATIONS Table 20. AC Read Characteristics (1,5), TA = -40oC to +85oC Versions(4) 3.3V 0.3V VCC (All units in ns unless otherwise noted) 2.7V - 3.6V VCC # Sym Parameter R1 tAVAV Read/Write Cycle Time R2 tAVQV Address to Output Delay R3 tELQV CEX# to Output Delay -100/-110 -130/-140 -120/-130 -150/-160 Notes Min Max Min Max Min Max Min Max 16 Mbit 1 100 120 130 150 32 Mbit 1 110 130 140 160 16 Mbit 1 100 120 130 150 32 Mbit 1 110 130 140 160 16 Mbit 2 100 120 130 150 32 Mbit 2 110 130 140 160 2 45 50 50 55 600 600 600 600 R4 tGLQV OE# to Output Delay R5 tPHQV RP# High to Output Delay R6 tELQX CEX# to Output in Low Z 3 0 0 0 0 R7 tGLQX OE# to Output in Low Z 3 0 0 0 0 R8 tEHQZ CEX# High to Output in High Z 3 50 50 55 55 R9 tGHQZ OE# High to Output in High Z 3 20 20 25 25 R10 tOH 3 Output Hold from Address, CEX#, or OE# Change, Whichever Occurs First 0 0 0 0 R11 tELFL CEX# Low to BYTE# High or Low tELFH 3 5 5 5 5 R12 tFLQV BYTE# to Output Delay tFHQV 16 Mbit 3 100 120 130 150 32 Mbit 3 110 130 140 160 3 30 30 40 40 R13 tFLQZ BYTE# to Output in High Z NOTES: 1. See AC Input/Output Reference Waveform for maximum allowable input slew rate. 2. OE# may be delayed up to tELQV-tGLQV after the falling edge of CEX# without impact on tELQV. 3. Sampled, not 100% tested. 4. See Ordering Information for device speeds (valid operational combinations). 5. See Figures 14 through 16 for testing characteristics. 44 ADVANCE INFORMATION E 28F160S3, 28F320S3 Note: CEX# is the latter of CE0# and CE1# low or the first of CE0# or CE1# high. Figure 17. AC Waveform for Read Operations ADVANCE INFORMATION 45 E 28F160S3, 28F320S3 6.2.5 AC CHARACTERISTICS - WRITE OPERATIONS Table 21. Write Operations(1,5,6), TA = -40C to +85C Versions(5) # 3.3V 0.3V, 2.7V-3.6V VCC Valid for All Speeds Sym Parameter Notes Min W1 tPHWL (tPHEL) RP# High Recovery to WE# (CEX#) Going Low 2 1 s W2 tELWL CEX# Setup to WE# Going Low 10 ns (tWLEL) (WE# Setup to CEX# Going Low) 0 ns tWLWH WE# Pulse Width 50 ns (tELEH) (CEX# Pulse Width) 70 ns W3 Max Unit W4 tDVWH (tDVEH) Data Setup to WE# (CEX# ) Going High 3 50 ns W5 tAVWH (tAVEH) Address Setup to WE# (CEX# ) Going High 3 50 ns W6 tWHEH CEX# Hold from WE# High 10 ns (tEHWH) (WE# Hold from CEX# High) 0 ns W7 tWHDX (tEHDX) Data Hold from WE# (CEX# ) High 5 ns W8 tWHAX (tEHAX) Address Hold from WE# (CEX# ) High 5 ns W9 tWHWL WE# Pulse Width High 30 ns (tEHEL) (CEX# Pulse Width High) 25 ns 100 ns 100 ns 0 ns W10 tSHWH (tSHEH) WP# VIH Setup to WE# (CEX# ) Going High W11 tVPWH (tVPEH) W12 tWHGL (tEHGL) Write Recovery before Read W13 tWHRL (tEHRL) WE# High to STS in RY/BY# Low W14 tQVSL WP# VIH Hold from Valid SRD 2,4 0 ns W15 tQVVL VPP Hold from Valid SRD, STS in RY/BY# High 2,4 0 ns VPP Setup to WE# (CEX# ) Going High 2 100 ns NOTES: 1. Read timing characteristics during block erase, program, and lock-bit configuration operations are the same as during read-only operations. Refer to AC Characteristics for read-only operations. 2. Sampled, not 100% tested. 3. Refer to Table 3 for valid AIN and DIN for block erase, program, or lock-bit configuration. 4. VPP should be at VPPH1/2 until determination of block erase, program, or lock-bit configuration success (SR.1/3/4/5 = 0). 5. See Ordering Information for device speeds (valid operational combinations). 6. See Figures 14 through 16 for testing characteristics. 46 ADVANCE INFORMATION E 28F160S3, 28F320S3 NOTES: A. VCC power-up and standby. B. Write block erase or program setup. C. Write block erase confirm or valid address and data.. D. Automated erase or program delay. E. Read Status Register data. F. Write Read Array command. CEX# is the latter of CE0# and CE1# low or the first of CE0# or CE1# high. Figure 18. AC Waveform for Write Operations ADVANCE INFORMATION 47 E 28F160S3, 28F320S3 6.2.6 RESET OPERATIONS Figure 19. AC Waveform for Reset Operation Table 22. Reset AC Specifications(1) # Sym Parameter P1 tPLPH RP# Pulse Low Time (If RP# is tied to V CC, this specification is not applicable) P2 tPLRH RP# Low to Reset during Block Erase, Program, or Lock-Bit Configuration P3 t3VPH VCC at 2.7V to RP# High VCC at 3.0V to RP# High Notes VCC = 2.7V VCC = 3.3V Min Min Max 100 2,3 Max 100 Unit ns 20 20 s 50 50 s NOTES: 1. These specifications are valid for all product versions (packages and speeds). 2. If RP# is asserted while a block erase, program, or lock-bit configuration operation is not executing, the reset will complete within tPLPH. 3. A reset time, tPHQV, is required from the latter of STS in RY/BY# mode or RP# going high until outputs are valid. 48 ADVANCE INFORMATION E 6.2.7 28F160S3, 28F320S3 ERASE, PROGRAM, AND LOCK-BIT CONFIGURATION PERFORMANCE Table 23. Erase/Write/Lock Performance(3,4) 2.7V-3.6V VCC Version # W16 Sym 2.7V VPP Parameter Byte/word program time (using write buffer) Notes Typ(1) 5 3.3V VPP 5V VPP Max Typ(1) Max Typ(1) Max Units 5.76 TBD 5.76 TBD 2.76 TBD s W16 tWHQV1 Per byte program time tEHQV1 (without write buffer) 2 19.89 TBD 19.89 TBD 13.2 TBD s W16 tWHQV1 Per word program time tEHQV1 (without write buffer) 2 22.17 TBD 22.17 TBD 13.2 TBD s W16 Block program time (byte mode) 2 1.63 TBD 1.63 TBD 0.87 TBD sec W16 Block program time (word mode) 2 0.91 TBD 0.91 TBD 0.44 TBD sec W16 Block program time (using write buffer) 2 0.37 TBD 0.37 TBD 0.16 TBD sec 2 0.56 TBD 0.56 TBD 0.42 TBD sec W16 W16 tWHQV2 Block erase time tEHQV2 Full chip erase time 16 Mbit 17.9 17.9 13.3 sec 32 Mbit 35.8 35.8 26.6 sec tWHQV3 Set Lock-Bit time W16 tEHQV3 2 22.17 TBD 22.17 TBD 13.3 TBD s tWHQV4 Clear block lock-bits time W16 tEHQV4 2 0.56 TBD 0.56 TBD 0.42 TBD sec tWHRH1 Program suspend latency W16 tEHRH1 time to read 7.24 10.2 7.24 10.2 6.73 9.48 s tWHRH2 Erase suspend latency time W16 tEHRH2 to read 15.5 21.5 15.5 21.5 12.54 17.54 s NOTES: 1. Typical values measured at TA = +25C and nominal voltages. Assumes corresponding lock-bits are not set. Subject to change based on device characterization. 2. Excludes system-level overhead. 3. These performance numbers are valid for all speed versions. 4. Sampled but not 100% tested. 5. Uses whole buffer. ADVANCE INFORMATION 49 E 28F160S3, 28F320S3 Table 24. Erase/Write/Lock Performance(3,4) 3.3V 0.3V VCC Version # Sym 3.3V VPP Parameter Notes Typ(1) 5V VPP Max Typ(1) Max Units W16 Byte/word program time (using write buffer) 5 5.66 TBD 2.7 TBD s tWHQV1 W16 tEHQV1 Per byte program time (without write buffer) 2 19.51 TBD 12.95 TBD s tWHQV1 W16 tEHQV1 Per word program time (without write buffer) 2 21.75 TBD 12.95 TBD s W16 Block program time (byte mode) 2 1.6 TBD 0.85 TBD sec W16 Block program time (word mode) 2 0.89 TBD 0.43 TBD sec W16 Block program time (using write buffer) 2 0.36 TBD 0.18 TBD sec Block erase time 2 0.55 TBD 0.41 TBD sec 16 Mbit 17.6 TBD 13.1 TBD sec 32 Mbit 35.2 TBD 26.2 TBD sec tWHQV2 W16 tEHQV2 W16 Full chip erase time tWHQV3 W16 tEHQV3 Set Lock-Bit time 2 22.75 TBD 12.95 TBD s tWHQV4 W16 tEHQV4 Clear block lock-bits time 2 0.55 TBD 0.41 TBD sec tWHRH1 W16 tEHRH1 Program suspend latency time to read 7.1 10 6.6 9.3 s tWHRH2 W16 tEHRH2 Erase suspend latency time to read 15.2 21.1 12.3 17.2 s NOTES: 1. Typical values measured at TA = +25C and nominal voltages. Assumes corresponding lock-bits are not set. Subject to change based on device characterization. 2. Excludes system-level overhead. 3. These performance numbers are valid for all speed versions. 4. Sampled but not 100% tested. 5. Uses whole buffer. 50 ADVANCE INFORMATION E 28F160S3, 28F320S3 APPENDIX A DEVICE NOMENCLATURE AND ORDERING INFORMATION Product line designator for all Intel Flash products T E 2 8 F 1 6 0 S3 - 1 0 0 Package DT = Extended Temp. 56-Lead SSOP TE = Extended Temp. 56-Lead TSOP GT = Extended Temp. 56-Bump BGA* package Device Density 160 = 16-Mbit 320 = 32-Mbit Order Code by Density 16 Mb 32 Mb Access Speed (ns) 100 ns (3.3V), 120 ns (2.7V-3.6V) Device Type 3 = 2.7V / 3.3V VCC 2.7V/3.3V / 5V VPP Product Family S = FlashFileTM Memory Valid Operational Combinations 2.7V-3.6V VCC 50 pF load (16 Mb / 32 Mb) 3.3V 0.3V VCC 50 pF load (16 Mb / 32 Mb) 56-lead TSOP S3-100 56-lead TSOP S3-110 -120 / -130 -100 / -110 56-lead TSOP S3-130 56-lead TSOP S3-140 -150 / -160 -130 / -140 56-lead SSOP S3-100 56-lead SSOP S3-110 -120 / -130 -100 / -110 56-lead SSOP S3-130 56-lead SSOP S3-140 -150 / -160 -130 / -140 56-bump BGA S3-100 56-bump BGA S3-110 -120 / -130 -100 / -110 56-bump BGA S3-130 56-bump BGA S3-140 -150 / -160 -130 / -140 ADVANCE INFORMATION 51 28F160S3, 28F320S3 APPENDIX B ADDITIONAL INFORMATION(1,2) E Order Number Document/Tool 290609 Word-Wide FlashFile MemoryTM Family 28F160S5, 28F320S5 Datasheet 292203 AP-645 28F160S3/S5 Compatibility with 28F016SA/SV 292204 AP-646 Common Flash Interface (CFI) and Command Sets www.mcif.com Common Flash Interface Specification 290528 28F016SV 16-Mb (1Mbit x 16, 2 Mbit x 8) FlashFileTM Memory Datasheet 290489 28F016SA 16-Mb (1Mbit x 16, 2 Mbit x 8) FlashFileTM Memory Datasheet 297372 16-Mbit Flash Product Family User's Manual 292123 AP-374 Flash Memory Write Protection Techniques 292144 AP-393 28F016SV Compatibility with 28F016SA 292159 AP-607 Multi-Site Layout Planning with Intel's FlashFileTM Components, Including ROM Capability 292163 AP-610 Flash Memory In-System Code and Data Update Techniques Contact Intel/Distribution Sales Office Mechanical Specification BGA* Package Preliminary Guide Contact Intel/Distribution Sales Office Surface Mount and PCB Guidelines for BGA* Packaging Contact Intel/Distribution Sales Office Multi-Site Layouts: 56-lead TSOP to 56-bump BGA* package 56-lead SSOP to 56-bump BGA package Contact Intel/Distribution Sales Office CFI - Common Flash Interface Reference Code NOTES: 1. Please call the Intel Literature Center at (800) 548-4725 to request Intel documentation. International customers should contact their local Intel or distribution sales office. 2. Visit Intel's World Wide Web home page at http://www.intel.com for technical documentation and tools. 52 ADVANCE INFORMATION