M36W432T M36W432B 32 Mbit (2Mb x16, Boot Block) Flash Memory and 4 Mbit (256K x16) SRAM, Multiple Memory Product PRODUCT PREVIEW FEATURES SUMMARY ■ SUPPLY VOLTAGE SRAM 4 Mbit (256K x 16 bit) – VDDF = 2.7V to 3.3V ■ – VDDS = VDDQF = 2.7V to 3.3V – VPPF = 12V for Fast Program (optional) ■ ACCESS TIME: 70ns ■ LOW VDDS DATA RETENTION: 1.5V ■ ACCESS TIME: 70,85ns ■ ■ LOW POWER CONSUMPTION POWER DOWN FEATURES USING TWO CHIP ENABLE INPUTS ■ ELECTRONIC SIGNATURE – Manufacturer Code: 20h Figure 1. Packages – Top Device Code, M36W432T: 88BAh – Bottom Device Code, M36W432B: 88BBh FLASH MEMORY 32 Mbit (2Mb x16) BOOT BLOCK ■ – 8 x 4 KWord Parameter Blocks (Top or Bottom Location) ■ PROGRAMMING TIME – 10µs typical – Double Word Programming Option ■ FBGA Stacked LFBGA66 (ZA) 8 x 8 ball array BLOCK LOCKING – All blocks locked at Power up – Any combination of blocks can be locked – WPF for Block Lock-Down ■ AUTOMATIC STAND-BY MODE ■ PROGRAM and ERASE SUSPEND ■ COMMON FLASH INTERFACE – 64 bit Security Code ■ SECURITY – 64 bit user programmable OTP cells – 64 bit unique device identifier – One parameter block permanently lockable February 2002 This is preliminary information on a new product now in development. Details are subject to change without notice. 1/57 M36W432T, M36W432B TABLE OF CONTENTS SUMMARY DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Figure 2. Logic Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Table 1. Signal Names . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Figure 3. LFBGA Connections (Top view through package) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 SIGNAL DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 FUNCTIONAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Figure 4. Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Table 2. Main Operation Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Flash Memory Component . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Figure 5. Flash Block Addresses. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Figure 6. Flash Security Block Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 SRAM Component . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 OPERATING MODES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Flash Bus Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Flash Command Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Table 3. Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table 4. Read Electronic Signature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 5. Read Block Signature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 6. Read Protection Register and Lock Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 7. Program, Erase Times and Program/Erase Endurance Cycles . . . . . . . . . . . . . . . . . . . . 17 Flash Block Locking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Table 8. Block Lock Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Table 9. Lock Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Flash Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Table 10. Status Register Bits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 SRAM Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 MAXIMUM RATING. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Table 11. Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 DC and AC PARAMETERS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Table 12. Operating and AC Measurement Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Figure 7. AC Measurement I/O Waveform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Figure 8. AC Measurement Load Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Table 13. Device Capacitance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Table 14. DC Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Figure 9. Flash Read AC Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Table 15. Flash Read AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 2/57 M36W432T, M36W432B Figure 10. Flash Write AC Waveforms, Write Enable Controlled . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 16. Flash Write AC Characteristics, Write Enable Controlled . . . . . . . . . . . . . . . . . . . . . . . . 27 Figure 11. Flash Write AC Waveforms, Chip Enable Controlled . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 Table 17. Flash Write AC Characteristics, Chip Enable Controlled. . . . . . . . . . . . . . . . . . . . . . . . . 29 Figure 12. Flash Power-Up and Reset AC Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 Table 18. Flash Power-Up and Reset AC Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 Figure 13. SRAM Read AC Waveforms, Address Controlled with UBS = LBS = VIL . . . . . . . . . . . 31 Figure 14. SRAM Read AC Waveforms, E1S, E2S or GS Controlled . . . . . . . . . . . . . . . . . . . . . . . 31 Figure 15. SRAM Standby AC Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Table 19. SRAM Read AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Figure 16. SRAM Write AC Waveforms, WS Controlled with GS Low . . . . . . . . . . . . . . . . . . . . . . 33 Figure 17. SRAM Write AC Waveforms, WS Controlled with GS High . . . . . . . . . . . . . . . . . . . . . . 33 Figure 18. SRAM Write AC Waveforms, UBS and LBS Controlled . . . . . . . . . . . . . . . . . . . . . . . . . 34 Figure 19. SRAM Write AC Waveforms, E1S Controlled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Table 20. SRAM Write AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Figure 20. SRAM Low VDDS Data Retention AC Waveforms, E1S Controlled . . . . . . . . . . . . . . . . 36 Figure 21. SRAM Low VDDS Data Retention AC Waveforms, E2S Controlled . . . . . . . . . . . . . . . . 36 Table 21. SRAM Low VDDS Data Retention Characteristic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 PACKAGE MECHANICAL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Figure 22. Stacked LFBGA66 - 8 x 8 ball array, 0.8 mm pitch, Bottom View Package Outline. . . . 37 Table 22. Stacked LFBGA66 - 8 x 8 ball array, 0.8 mm pitch, Package Mechanical Data . . . . . . . 37 Figure 23. Stacked LFBGA66 Daisy Chain - Package Connections (Top view through package) . 38 Figure 24. Stacked LFBGA66 Daisy Chain - PCB Connections proposal (Top view through package)39 PART NUMBERING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Table 23. Ordering Information Scheme . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Table 24. Daisy Chain Ordering Scheme . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 REVISION HISTORY. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 Table 25. Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 APPENDIX A. FLASH MEMORY BLOCK ADDRESS TABLES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 Table 26. Top Boot Block Addresses, M36W432T . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 Table 27. Bottom Boot Block Addresses, M36W432B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 APPENDIX B. COMMON FLASH INTERFACE (CFI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 Table 28. Query Structure Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 Table 29. CFI Query Identification String . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 Table 30. CFI Query System Interface Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 Table 31. Device Geometry Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 Table 32. Primary Algorithm-Specific Extended Query Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 Table 33. Security Code Area . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 APPENDIX C. FLASH MEMORY FLOWCHARTS and PSEUDO CODES . . . . . . . . . . . . . . . . . . . . . 49 3/57 M36W432T, M36W432B Figure 25. Program Flowchart and Pseudo Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 Figure 26. Double Word Program Flowchart and Pseudo Code . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 Figure 27. Program Suspend & Resume Flowchart and Pseudo Code . . . . . . . . . . . . . . . . . . . . . 51 Figure 28. Erase Flowchart and Pseudo Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 Figure 29. Erase Suspend & Resume Flowchart and Pseudo Code. . . . . . . . . . . . . . . . . . . . . . . . 53 Figure 30. Locking Operations Flowchart and Pseudo Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 APPENDIX D. FLASH MEMORY COMMAND INTERFACE and PROGRAM/ERASE CONTROLLER STATE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 Table 34. Write State Machine Current/Next, sheet 1 of 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 Table 35. Write State Machine Current/Next, sheet 2 of 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 4/57 M36W432T, M36W432B SUMMARY DESCRIPTION The M36W432 is a low voltage Multiple Memory Product which combines two memory devices; a 32 Mbit boot block Flash memory and a 4 Mbit SRAM. Recommended operating conditions do not allow both the Flash and the SRAM to be active at the same time. The memory is offered in a Stacked LFBGA66 (0.8 mm pitch) package and is supplied with all the bits erased (set to ‘1’). Table 1. Signal Names A0-A17 Address Inputs A18-A20 Address Inputs for Flash Chip only DQ0-DQ15 Data Input/Output VDDF Flash Power Supply VDDQF Flash Power Supply for I/O Buffers VPPF Flash Optional Supply Voltage for Fast Program & Erase VSSF Flash Ground VDDS SRAM Power Supply VSSS SRAM Ground NC Not Connected Internally Figure 2. Logic Diagram VDDQF VDDF VDDS VPPF 21 16 A0-A20 DQ0-DQ15 Flash control functions EF Chip Enable input GF GF Output Enable input WF WF Write Enable input RPF RPF Reset input WPF Write Protect input EF WPF M36W432T M36W432B E1S SRAM control functions E2S E1S, E2S Chip Enable inputs GS Output Enable input WS Write Enable input UBS Upper Byte Enable input LBS Lower Byte Enable input GS WS UBS LBS VSSF VSSS AI05200 5/57 M36W432T, M36W432B Figure 3. LFBGA Connections (Top view through package) #1 #2 1 2 3 4 5 6 7 8 #3 #4 NC NC A20 A11 A15 A14 A13 A12 VSSF VDDQF NC NC B A16 A8 A10 A9 DQ15 WS DQ14 DQ7 C WF NC DQ13 DQ6 DQ4 DQ5 D VSSS RPF DQ12 E2S VDDS VDDF E WPF VPPF A19 DQ10 DQ2 DQ3 F LBS UBS GS DQ9 DQ8 DQ0 DQ1 G A18 A17 A7 A6 A3 A2 A1 E1S NC A5 A4 A0 EF VSSF GF NC NC NC A H NC NC DQ11 AI05201 SIGNAL DESCRIPTIONS See Figure 2 Logic Diagram and Table 1,Signal Names, for a brief overview of the signals connected to this device. Address Inputs (A0-A17). Addresses A0-A17 are common inputs for the Flash and the SRAM components. The Address Inputs select the cells in the memory array to access during Bus Read operations. During Bus Write operations they control the commands sent to the Command Interface of the internal state machine. The Flash memory is accessed through the Chip Enable (EF) and Write Enable (WF) signals, while the SRAM is accessed through two Chip Enable signals (E1S and E2S) and the Write Enable signal (WS). Address Inputs (A18-A20). Addresses A18-A20 are inputs for the Flash component only. The Flash memory is accessed through the Chip Enable (EF) and Write Enable (WF) signals Data Input/Output (DQ0-DQ15). The Data I/O outputs the data stored at the selected address 6/57 during a Bus Read operation or inputs a command or the data to be programmed during a Write Bus operation. Flash Chip Enable (EF). The Chip Enable input activates the Flash memory control logic, input buffers, decoders and sense amplifiers. When Chip Enable is at VIL and Reset is at VIH the device is in active mode. When Chip Enable is at VIH the memory is deselected, the outputs are high impedance and the power consumption is reduced to the standby level. Flash Output Enable (GF). The Output Enable controls the data outputs during the Bus Read operation of the Flash memory. Flash Write Enable (WF). The Write Enable controls the Bus Write operation of the Flash memory’s Command Interface. The data and address inputs are latched on the rising edge of Chip Enable, EF, or Write Enable, WF, whichever occurs first. M36W432T, M36W432B Flash Write Protect (WPF). Write Protect is an input that gives an additional hardware protection for each block. When Write Protect is at VIL, the Lock-Down is enabled and the protection status of the block cannot be changed. When Write Protect is at VIH, the Lock-Down is disabled and the block can be locked or unlocked. (refer to Table 6, Read Protection Register and Protection Register Lock). Flash Reset (RPF). The Reset input provides a hardware reset of the Flash memory. When Reset is at VIL, the memory is in reset mode: the outputs are high impedance and the current consumption is minimized. After Reset all blocks are in the Locked state. When Reset is at VIH, the device is in normal operation. Exiting reset mode the device enters read array mode, but a negative transition of Chip Enable or a change of the address is required to ensure valid data outputs. SRAM Chip Enable (E1S, E2S). The Chip Enable inputs activate the SRAM memory control logic, input buffers and decoders. E1S at VIH or E2S at VIL deselects the memory and reduces the power consumption to the standby level. E1S and E2S can also be used to control writing to the SRAM memory array, while WS remains at VIL. It is not allowed to set EF at VIL, E1S at VIL and E2S at VIH at the same time. SRAM Write Enable (WS). The Write Enable input controls writing to the SRAM memory array. WS is active low. SRAM Output Enable (GS). The Output Enable gates the outputs through the data buffers during a read operation of the SRAM memory. GS is active low. SRAM Upper Byte Enable (UBS). The Upper Byte Enable enables the upper bytes for SRAM (DQ8-DQ15). UBS is active low. SRAM Lower Byte Enable (LBS). The Lower Byte Enable enables the lower bytes for SRAM (DQ0-DQ7). LBS is active low. VDDF Supply Voltage (2.7V to 3.3V). VDDF provides the power supply to the internal core of the Flash Memory device. It is the main power supply for all operations (Read, Program and Erase). VDDQF and VDDS Supply Voltage (2.7V to 3.3V). VDDQF provides the power supply for the Flash memory I/O pins and VDDS provides the power supply for the SRAM control pins. This allows all Outputs to be powered independently from the Flash core power supply, VDDF. VDDQF can be tied to VDDS VPPF Program Supply Voltage. VPPF is both a control input and a power supply pin for the Flash memory. The two functions are selected by the voltage range applied to the pin. The Supply Voltage VDDF and the Program Supply Voltage VPPF can be applied in any order. If VPPF is kept in a low voltage range (0V to 3.6V) VPPF is seen as a control input. In this case a voltage lower than VPPLK gives an absolute protection against program or erase, while VPPF > VPPLK enables these functions (see Table 14, DC Characteristics for the relevant values). VPPF is only sampled at the beginning of a program or erase; a change in its value after the operation has started does not have any effect and program or erase operations continue. If VPPF is in the range 11.4V to 12.6V it acts as a power supply pin. In this condition VPPF must be stable until the Program/Erase algorithm is completed (see Table 16 and 17). VSSF and VSSS Ground. VSSF and VSSS are the ground reference for all voltage measurements in the Flash and SRAM chips, respectively. Note: Each device in a system should have VDDF, VDDQF and VPPF decoupled with a 0.1µF capacitor close to the pin. See Figure 9, AC Measurement Load Circuit. The PCB trace widths should be sufficient to carry the required VPPF program and erase currents. 7/57 M36W432T, M36W432B FUNCTIONAL DESCRIPTION The Flash and SRAM components have separate power supplies and grounds and are distinguished by three chip enable inputs: EF for the Flash memory and, E1S and E2S for the SRAM. Recommended operating conditions do not allow both the Flash and the SRAM to be in active mode at the same time. The most common example is simultaneous read operations on the Flash and the SRAM which would result in a data bus contention. Therefore it is recommended to put the SRAM in the high impedance state when reading the Flash and vice versa (see Table 2 Main Operation Modes for details). Figure 4. Functional Block Diagram VDDF VDDF EF EF GF GF WF WF RPF RPF WPF WPF VDDQF VDDQF VPPF VPPF Flash Memory Flash Memory 32 Mbit (x16) 32 Mbit (x16) A18-A20 A18-A20 A0-A17 A0-A17 VSSF VSSF VDDS VDDS E1S E1S E2S E2S GS GS WS WS UBS UBS LBS LBS DQ0-DQ15 DQ0-DQ15 SRAM SRAM 4 Mbit (x16) 4 Mbit (x16) VSSS VSSS AI05202 AI05202 8/57 M36W432T, M36W432B SRAM Flash Memory Table 2. Main Operation Modes Operation Mode EF GF WF RPF WPF VPPF Read VIL VIL VIH VIH X Don't care SRAM must be disabled Data Output Write VIL VIH VIL VIH VIH VDDF or VPPFH SRAM must be disabled Data Input Block Locking VIL X X VIH VIL Don't care SRAM must be disabled X Standby VIH X X VIH X Don't care Any SRAM mode is allowed Hi-Z Reset X X X VIL X Don't care Any SRAM mode is allowed Hi-Z Output Disable VIL VIH VIH VIH X Don't care Any SRAM mode is allowed Hi-Z E1S E2S GS WS UBS, LBS (1) DQ15-DQ0 Read Flash must be disabled VIL VIH VIL VIH VIL Data out Word Read Write Flash must be disabled VIL VIH VIH VIL VIL Data in Word Write VIH X X X X Hi-Z X VIL X X X Hi-Z X X X X VIH Hi-Z VIH X X X X Hi-Z X VIL X X X Hi-Z X X X X VIH Hi-Z VIL VIH VIH VIH X Hi-Z Standby/ Power Down Data Retention Output Disable Any Flash mode is allowable Any Flash mode is allowable Any Flash mode is allowable Note: X = VIL or VIH, VPPFH = 12V ± 5%. 1. If UBS and LBS are tied together the bus is at 16 bit. For an 8 bit bus configuration use UBS and LBS separately. 9/57 M36W432T, M36W432B Flash Memory Component The Flash Memory is a 32 Mbit (2 Mbit x 16) device that can be erased electrically at the block level and programmed in-system on a Word-byWord basis. These operations can be performed using a single low voltage (2.7 to 3.3V) supply and the VDDQF for device I/0 operation feature the same voltage range. An optional 12V VPPF power supply is provided to speed up customer programming. The device features an asymmetrical blocked architecture with an array of 71 blocks: 8 Parameter Blocks of 4 KWord and 63 Main Blocks of 32 KWord. The M36W432T device has the Flash Memory Parameter Blocks at the top of the memory address space while the M36W432B device locates the Parameter Blocks starting from the bottom. The memory maps are shown in Figure 5, Block Addresses. The Flash Memory features an instant, individual block locking scheme that allows any block to be locked or unlocked with no latency, enabling instant code and data protection. All blocks have three levels of protection. They can be locked and locked-down individually preventing any accidental programming or erasure. There is an additional hardware protection against program and erase. When VPPF ≤ VPPLK all blocks are protected 10/57 against program or erase. All blocks are locked at Power Up. Each block can be erased separately. Erase can be suspended in order to perform either read or program in any other block and then resumed. Program can be suspended to read data in any other block and then resumed. Each block can be programmed and erased over 100,000 cycles. The device includes a 128 bit Protection Register and a Security Block to increase the protection of a system design. The Protection Register is divided into two 64 bit segments, the first one contains a unique device number written by ST, while the second one is one-time-programmable by the user. The user programmable segment can be permanently protected. The Security Block, parameter block 0, can be permanently protected by the user. Figure 6, shows the Flash Security Block Memory Map. Program and Erase commands are written to the Command Interface of the memory. An on-chip Program/Erase Controller takes care of the timings necessary for program and erase operations. The end of a program or erase operation can be detected and any error conditions identified. The command set required to control the memory is consistent with JEDEC standards. M36W432T, M36W432B Figure 5. Flash Block Addresses Bottom Boot Block Addresses Top Boot Block Addresses 1FFFFF 1FFFFF 32 KWords 4 KWords 1F8000 1F7FFF 1FF000 32 KWords Total of 8 4 KWord Blocks 1F0000 Total of 63 32 KWord Blocks 1F8FFF 4 KWords 1F8000 1F7FFF 32 KWords 00FFFF 1F0000 32 KWords 008000 007FFF 4 KWords Total of 63 32 KWord Blocks 007000 Total of 8 4 KWord Blocks 00FFFF 32 KWords 008000 007FFF 000FFF 32 KWords 4 KWords 000000 000000 AI05203 Note: Also see Appendix A, Tables 26 and 27 for a full listing of the Flash Block Addresses. Figure 6. Flash Security Block Memory Map 88h User Programmable OTP 85h 84h Parameter Block # 0 Unique device number 81h 80h Protection Register Lock 2 1 0 AI05204 SRAM Component The SRAM is an 4 Mbit asynchronous random access memory which features a super low voltage operation and low current consumption with an ac- cess time of 70 ns in all conditions. The memory operations can be performed using a single low voltage supply, 2.7V to 3.3V, which is the same as the Flash voltage supply. 11/57 M36W432T, M36W432B OPERATING MODES Flash Bus Operations There are six standard bus operations that control the device. These are Bus Read, Bus Write, Output Disable, Standby, Automatic Standby and Reset. See Table 2, Main Operation Modes, for a summary. Typically glitches of less than 5ns on Chip Enable or Write Enable are ignored by the memory and do not affect bus operations. Read. Read Bus operations are used to output the contents of the Memory Array, the Electronic Signature, the Status Register and the Common Flash Interface. Both Chip Enable and Output Enable must be at VIL in order to perform a read operation. The Chip Enable input should be used to enable the device. Output Enable should be used to gate data onto the output. The data read depends on the previous command written to the memory (see Command Interface section). See Figure 9, Read Mode AC Waveforms, and Table 15, Flash Read AC Characteristics, for details of when the output becomes valid. Read mode is the default state of the device when exiting Reset or after power-up. Write. Bus Write operations write Commands to the memory or latch Input Data to be programmed. A write operation is initiated when Chip Enable and Write Enable are at VIL with Output Enable at VIH. Commands, Input Data and Addresses are latched on the rising edge of Write Enable or Chip Enable, whichever occurs first. See Figures 10 and 11, Write AC Waveforms, and Tables 16 and 17, Flash Write AC Characteristics, for details of the timing requirements. Output Disable. The data outputs are high impedance when the Output Enable is at VIH. Standby. Standby disables most of the internal circuitry allowing a substantial reduction of the current consumption. The memory is in stand-by when Chip Enable is at VIH and the device is in read mode. The power consumption is reduced to the stand-by level and the outputs are set to high impedance, independently from the Output Enable or Write Enable inputs. If Chip Enable switches to VIH during a program or erase operation, the device enters Standby mode when finished. Automatic Standby. Automatic Standby provides a low power consumption state during Read mode. Following a read operation, the device enters Automatic Standby after 150ns of bus inactivity even if Chip Enable is Low, VIL, and the supply current is reduced to IDD1. The data Inputs/Out- 12/57 puts will still output data if a bus Read operation is in progress. Reset. During Reset mode when Output Enable is Low, VIL, the memory is deselected and the outputs are high impedance. The memory is in Reset mode when Reset is at VIL. The power consumption is reduced to the Standby level, independently from the Chip Enable, Output Enable or Write Enable inputs. If Reset is pulled to VSSF during a Program or Erase, this operation is aborted and the memory content is no longer valid. Flash Command Interface All Bus Write operations to the memory are interpreted by the Command Interface. Commands consist of one or more sequential Bus Write operations. An internal Program/Erase Controller handles all timings and verifies the correct execution of the Program and Erase commands. The Program/Erase Controller provides a Status Register whose output may be read at any time during, to monitor the progress of the operation, or the Program/Erase states. See Appendix 29, Table 34, Write State Machine Current/Next, for a summary of the Command Interface. The Command Interface is reset to Read mode when power is first applied, when exiting from Reset or whenever VDDF is lower than VLKO. Command sequences must be followed exactly. Any invalid combination of commands will reset the device to Read mode. Refer to Table 3, Commands, in conjunction with the text descriptions below. Read Memory Array Command. The Read command returns the memory to its Read mode. One Bus Write cycle is required to issue the Read Memory Array command and return the memory to Read mode. Subsequent read operations will read the addressed location and output the data. When a device Reset occurs, the memory defaults to Read mode. Read Status Register Command. The Status Register indicates when a program or erase operation is complete and the success or failure of the operation itself. Issue a Read Status Register command to read the Status Register’s contents. Subsequent Bus Read operations read the Status Register at any address, until another command is issued. See Table 10, Status Register Bits, for details on the definitions of the bits. The Read Status Register command may be issued at any time, even during a Program/Erase operation. Any Read attempt during a Program/ Erase operation will automatically output the content of the Status Register. M36W432T, M36W432B Read Electronic Signature Command. The Read Electronic Signature command reads the Manufacturer and Device Codes and the Block Locking Status, or the Protection Register. The Read Electronic Signature command consists of one write cycle, a subsequent read will output the Manufacturer Code, the Device Code, the Block Lock and Lock-Down Status, or the Protection and Lock Register. See Tables 4, 5 and 6 for the valid address. Read CFI Query Command. The Read Query Command is used to read data from the Common Flash Interface (CFI) Memory Area, allowing programming equipment or applications to automatically match their interface to the characteristics of the device. One Bus Write cycle is required to issue the Read Query Command. Once the command is issued subsequent Bus Read operations read from the Common Flash Interface Memory Area. See Appendix B, Common Flash Interface, Tables 28, 29, 30, 31, 32 and 33 for details on the information contained in the Common Flash Interface memory area. Block Erase Command. The Block Erase command can be used to erase a block. It sets all the bits within the selected block to ’1’. All previous data in the block is lost. If the block is protected then the Erase operation will abort, the data in the block will not be changed and the Status Register will output the error. Two Bus Write cycles are required to issue the command. ■ The first bus cycle sets up the Erase command. ■ The second latches the block address in the internal state machine and starts the Program/ Erase Controller. If the second bus cycle is not Write Erase Confirm (D0h), Status Register bits b4 and b5 are set and the command aborts. Erase aborts if Reset turns to VIL. As data integrity cannot be guaranteed when the Erase operation is aborted, the block must be erased again. During Erase operations the memory will accept the Read Status Register command and the Program/Erase Suspend command, all other commands will be ignored. Typical Erase times are given in Table 7, Program, Erase Times and Program/Erase Endurance Cycles. See Appendix C, Figure 28, Erase Flowchart and Pseudo Code, for a suggested flowchart for using the Erase command. Program Command. The memory array can be programmed word-by-word. Two bus write cycles are required to issue the Program Command. The first bus cycle sets up the Program command. ■ The second latches the Address and the Data to be written and starts the Program/Erase Controller. During Program operations the memory will accept the Read Status Register command and the Program/Erase Suspend command. Typical Program times are given in Table 7, Program, Erase Times and Program/Erase Endurance Cycles. Programming aborts if Reset goes to VIL. As data integrity cannot be guaranteed when the program operation is aborted, the block containing the memory location must be erased and reprogrammed. See Appendix C, Figure 25, Program Flowchart and Pseudo Code, for the flowchart for using the Program command. Double Word Program Command. This feature is offered to improve the programming throughput, writing a page of two adjacent words in parallel.The two words must differ only for the address A0. Programming should not be attempted when VPPF is not at VPPH. The command can be executed if VPPF is below VPPH but the result is not guaranteed. Three bus write cycles are necessary to issue the Double Word Program command. ■ The first bus cycle sets up the Double Word Program Command. ■ The second bus cycle latches the Address and the Data of the first word to be written. ■ The third bus cycle latches the Address and the Data of the second word to be written and starts the Program/Erase Controller. Read operations output the Status Register content after the programming has started. Programming aborts if Reset goes to VIL. As data integrity cannot be guaranteed when the program operation is aborted, the block containing the memory location must be erased and reprogrammed. See Appendix C, Figure 26, Double Word Program Flowchart and Pseudo Code, for the flowchart for using the Double Word Program command. Clear Status Register Command. The Clear Status Register command can be used to reset bits 1, 3, 4 and 5 in the Status Register to ‘0’. One bus write cycle is required to issue the Clear Status Register command. The bits in the Status Register do not automatically return to ‘0’ when a new Program or Erase command is issued. The error bits in the Status Register should be cleared before attempting a new Program or Erase command. ■ 13/57 M36W432T, M36W432B Program/Erase Suspend Command. The Program/Erase Suspend command is used to pause a Program or Erase operation. One bus write cycle is required to issue the Program/Erase command and pause the Program/Erase controller. During Program/Erase Suspend the Command Interface will accept the Program/Erase Resume, Read Array, Read Status Register, Read Electronic Signature and Read CFI Query commands. Additionally, if the suspend operation was Erase then the Program, Block Lock, Block Lock-Down or Protection Program commands will also be accepted. The block being erased may be protected by issuing the Block Protect, Block Lock or Protection Program commands. When the Program/ Erase Resume command is issued the operation will complete. Only the blocks not being erased may be read or programmed correctly. During a Program/Erase Suspend, the device can be placed in a pseudo-standby mode by taking Chip Enable to VIH. Program/Erase is aborted if Reset turns to VIL. See Appendix C, Figure 27, Program or Double Word Program Suspend & Resume Flowchart and Pseudo Code, and Figure 29, Erase Suspend & Resume Flowchart and Pseudo Code for flowcharts for using the Program/Erase Suspend command. Program/Erase Resume Command. The Program/Erase Resume command can be used to restart the Program/Erase Controller after a Program/Erase Suspend operation has paused it. One Bus Write cycle is required to issue the command. Once the command is issued subsequent Bus Read operations read the Status Register. See Appendix C, Figure 27, Program or Double Word Program Suspend & Resume Flowchart and Pseudo Code, and Figure 29, Erase Suspend & Resume Flowchart and Pseudo Code for flowcharts for using the Program/Erase Resume command. Protection Register Program Command. The Protection Register Program command is used to Program the 64 bit user One-Time-Programmable (OTP) segment of the Protection Register. The segment is programmed 16 bits at a time. When shipped all bits in the segment are set to ‘1’. The user can only program the bits to ‘0’. Two write cycles are required to issue the Protection Register Program command. ■ The first bus cycle sets up the Protection Register Program command. 14/57 The second latches the Address and the Data to be written to the Protection Register and starts the Program/Erase Controller. Read operations output the Status Register content after the programming has started. The segment can be protected by programming bit 1 of the Protection Lock Register. Bit 1 of the Protection Lock Register protects bit 2 of the Protection Lock Register. Programming bit 2 of the Protection Lock Register will result in a permanent protection of the Security Block (see Figure 6, Flash Security Block Memory Map). Attempting to program a previously protected Protection Register will result in a Status Register error. The protection of the Protection Register and/or the Security Block is not reversible. The Protection Register Program cannot be suspended. Block Lock Command. The Block Lock command is used to lock a block and prevent Program or Erase operations from changing the data in it. All blocks are locked at power-up or reset. Two Bus Write cycles are required to issue the Block Lock command. ■ The first bus cycle sets up the Block Lock command. ■ The second Bus Write cycle latches the block address. The Lock Status can be monitored for each block using the Read Block Signature command. Table. 9 shows the Lock Status after issuing a Block Lock command. The Block Lock bits are volatile, once set they remain set until reset or power-down/power-up. They are cleared by a Blocks Unlock command. Refer to the section, Block Locking, for a detailed explanation. Block Unlock Command. The Blocks Unlock command is used to unlock a block, allowing the block to be programmed or erased. Two Bus Write cycles are required to issue the Blocks Unlock command. ■ The first bus cycle sets up the Block Unlock command. ■ The second Bus Write cycle latches the block address. The Lock Status can be monitored for each block using the Read Block Signature command. Table. 9 shows the Lock Status after issuing a Block Unlock command. Refer to the section, Block Locking, for a detailed explanation. ■ M36W432T, M36W432B Block Lock-Down Command. A locked block cannot be Programmed or Erased, or have its Lock status changed when WP is low, VIL. When WP is high, VIH, the Lock-Down function is disabled and the locked blocks can be individually unlocked by the Block Unlock command. Two Bus Write cycles are required to issue the Block Lock command. ■ The first bus cycle sets up the Block Lock command. The second Bus Write cycle latches the block address. The Lock Status can be monitored for each block using the Read Block Signature command. Locked blocks revert to the protected (and not locked) state when the device is reset on powerdown. Table. 9 shows the Lock Status after issuing a Block Lock-Down command. Refer to the section, Block Locking, for a detailed explanation. ■ Table 3. Commands Bus Write Operations Commands No. of Cycles 1st Cycle 2nd Cycle 3nd Cycle Bus Op. Addr Data Bus Op. Addr Data Read Memory Array 1+ Write X FFh Read Read Addr Data Read Status Register 1+ Write X 70h Read X Status Register Read Electronic Signature 1+ Write X 90h Read Signature Addr (1) Signature Read CFI Query 1+ Write 55h 98h Read CFI Addr Query Erase 2 Write X 20h Write Block Addr D0h Program 2 Write X 40h or 10h Write Addr Data Input Double Word Program (2) 3 Write X 30h Write Addr 1 Data Input Clear Status Register 1 Write X 50h Program/Erase Suspend 1 Write X B0h Program/Erase Resume 1 Write X D0h Block Lock 2 Write X 60h Write Block Address 01h Block Unlock 2 Write X 60h Write Block Address D0h Block Lock-Down 2 Write X 60h Write Block Address 2Fh Protection Register Program 2 Write X C0h Write Address Data Input Bus Op. Addr Data Write Addr 2 Data Input Note: X = Don't Care. 1. The signature addresses are listed in Tables 4, 5 and 6. 2. Addr 1 and Addr 2 must be consecutive Addresses differing only for A0. 15/57 M36W432T, M36W432B Table 4. Read Electronic Signature Code Device EF GF WF A0 A1 A2-A7 A8-A11 A12-A20 DQ0-DQ7 DQ8-DQ15 VIL VIL VIH VIL VIL 0 Don't Care Don't Care 20h 00h M36W432T VIL VIL VIH VIH VIL 0 Don't Care Don't Care xxh 88h M36W432B VIL VIL VIH VIH VIL 0 Don't Care Don't Care xxh 88h Manufacture Code Device Code Note: RPF = VIH. Table 5. Read Block Signature EF GF WF A0 A1 A2-A7 Locked Block VIL VIL VIH VIL VIH 0 Unlocked Block VIL VIL VIH VIL VIH Locked-Down Block VIL VIL VIH VIL VIH Block Status A8-A20 A12-A20 DQ0 DQ1 DQ2-DQ15 Don't Care Block Address 1 0 00h 0 Don't Care Block Address 0 0 00h 0 Don't Care Block Address X (1) 1 00h Note: 1. A Locked Block can be protected "DQ0 = 1" or unprotected "DQ0 = 0"; see Block Locking section. Table 6. Read Protection Register and Lock Register EF GF WF A0-A7 A8-A20 DQ0 DQ1 DQ2 Lock VIL VIL VIH 80h Don't Care 0 OTP Prot. data Security prot. data 00h 00h Unique ID 0 VIL VIL VIH 81h Don't Care ID data ID data ID data ID data ID data Unique ID 1 VIL VIL VIH 82h Don't Care ID data ID data ID data ID data ID data Unique ID 2 VIL VIL VIH 83h Don't Care ID data ID data ID data ID data ID data Unique ID 3 VIL VIL VIH 84h Don't Care ID data ID data ID data ID data ID data OTP 0 VIL VIL VIH 85h Don't Care OTP data OTP data OTP data OTP data OTP data OTP 1 VIL VIL VIH 86h Don't Care OTP data OTP data OTP data OTP data OTP data OTP 2 VIL VIL VIH 87h Don't Care OTP data OTP data OTP data OTP data OTP data OTP 3 VIL VIL VIH 88h Don't Care OTP data OTP data OTP data OTP data OTP data Word 16/57 DQ3-DQ7 DQ8-DQ15 M36W432T, M36W432B Table 7. Program, Erase Times and Program/Erase Endurance Cycles Flash Memory Parameter Test Conditions Unit Min Word Program Double Word Program Typ Max VPPF = VDDF 10 200 µs VPPF = 12V ±5% 10 200 µs VPPF = 12V ±5% 0.16 5 s VPPF = VDDF 0.32 5 s VPPF = 12V ±5% 0.02 4 s VPPF = VDDF 0.04 4 s VPPF = 12V ±5% 1 10 s VPPF = VDDF 1 10 s VPPF = 12V ±5% 0.8 10 s VPPF = VDDF 0.8 10 s Main Block Program Parameter Block Program Main Block Erase Parameter Block Erase Program/Erase Cycles (per Block) Flash Block Locking The Flash Memory features an instant, individual block locking scheme that allows any block to be locked or unlocked with no latency. This locking scheme has three levels of protection. ■ Lock/Unlock - this first level allows softwareonly control of block locking. ■ Lock-Down - this second level requires hardware interaction before locking can be changed. ■ VPPF ≤ VPPLK - the third level offers a complete hardware protection against program and erase on all blocks. The locking status of each block can be set to Locked, Unlocked, and Lock-Down. The following sections explain the operation of the locking system. Table 7, defines all of the possible locking states (WP, DQ1, DQ0), and Appendix C, Figure 30, shows a flowchart for the locking operations. Locked State. The default status of all blocks on power-up or reset is Locked (states (0,0,1) or (1,0,1)). Locked blocks are fully protected from any program or erase. Any program or erase operations attempted on a locked block will return an error in the Status Register. The Status of a Locked block can be changed to Unlocked or Lock-Down using the appropriate software commands. An Unlocked block can be Locked by issuing the Lock command. 100,000 cycles Unlocked State. Unlocked blocks (states (0,0,0), (1,0,0) (1,1,0)), can be programmed or erased. All unlocked blocks return to the Locked state when the device is reset or powered-down. The status of an unlocked block can be changed to Locked or Locked-Down using the appropriate software commands. A locked block can be unlocked by issuing the Unlock command. Lock-Down State. Blocks that are Locked-Down (state (0,1,1))are protected from program and erase operations (as for Locked blocks) but their Lock status cannot be changed using software commands alone. A Locked or Unlocked block can be Locked-Down by issuing the Lock-Down command. Locked-Down blocks revert to the Locked state when the device is reset or powered-down. The Lock-Down function is dependent on the WPF input pin. When WPF=0 (VIL), the blocks in the Lock-Down state (0,1,1) are protected from program, erase and lock status changes. When WPF=1 (VIH) the Lock-Down function is disabled (1,1,1) and Locked-Down blocks can be individually unlocked to the (1,1,0) state by issuing the software command, where they can be erased and programmed. These blocks can then be re-locked (1,1,1) and unlocked (1,1,0) as desired while WPF remains high. When WPF is low, blocks that were previously Locked-Down return to the Lock-Down state (0,1,1) regardless of any changes made while WPF was high. Device reset or power-down resets all blocks, including those in Lock-Down, to the Locked state. 17/57 M36W432T, M36W432B Reading a Block’s Lock Status. The lock status of every block can be read in the Read Electronic Signature mode of the device. To enter this mode write 90h to the device. Subsequent reads at Block Address 00002h will output the lock status of that block. The lock status is represented by DQ0 and DQ1. DQ0 indicates the Block Lock/Unlock status and is set by the Lock command and cleared by the Unlock command. it is also automatically set when entering Lock-Down. DQ1 indicates the Lock-Down status and is set by the Lock-Down command. It cannot be cleared by software, only by a device reset or power-down. Locking Operations During Erase Suspend. Changes to block lock status can be performed during an erase suspend by using the standard locking command sequences to unlock, lock or lock-down a block. This is useful in the case when another block needs to be updated while an erase operation is in progress. To change block locking during an erase operation, first write the Erase Suspend command, then check the status register until it indicates that the erase operation has been suspended. Next write the desired Lock command sequence to a block and the lock status will be changed. After completing any desired lock, read, or program operations, resume the erase operation with the Erase Resume command. If a block is locked or locked-down during an erase suspend of the same block, the locking status bits will be changed immediately, but when the erase is resumed, the erase operation will complete. Locking operations cannot be performed during a program suspend. Refer to Appendix D, Command Interface and Program/Erase Controller State, for detailed information on which commands are valid during erase suspend. Table 8. Block Lock Status Item Block Lock Configuration Address Data xx002 LOCK Block is Unlocked DQ0=0 Block is Locked DQ0=1 Block is Locked-Down DQ1=1 Table 9. Lock Status Current Lock Status(1) (WPF, DQ1, DQ0) Next Lock Status(1) (WPF, DQ1, DQ0) Current State Program/Erase Allowed After Block Lock Command After Block Unlock Command After Block Lock-Down Command After WPF transition 1,0,0 yes 1,0,1 1,0,0 1,1,1 0,0,0 1,0,1(2) no 1,0,1 1,0,0 1,1,1 0,0,1 1,1,0 yes 1,1,1 1,1,0 1,1,1 0,1,1 1,1,1 no 1,1,1 1,1,0 1,1,1 0,1,1 0,0,0 yes 0,0,1 0,0,0 0,1,1 1,0,0 0,0,1(2) no 0,0,1 0,0,0 0,1,1 1,0,1 0,1,1 no 0,1,1 0,1,1 0,1,1 1,1,1 or 1,1,0 (3) Note: 1. The lock status is defined by the write protect pin and by DQ1 (‘1’ for a locked-down block) and DQ0 (‘1’ for a locked block) as read in the Read Electronic Signature command with A1 = VIH and A0 = VIL. 2. All blocks are locked at power-up, so the default configuration is 001 or 101 according to WPF status. 3. A WPF transition to VIH on a locked block will restore the previous DQ0 value, giving a 111 or 110. 18/57 M36W432T, M36W432B Flash Status Register The Status Register provides information on the current or previous Program or Erase operation. The various bits convey information and errors on the operation. To read the Status register the Read Status Register command can be issued, refer to Read Status Register Command section. To output the contents, the Status Register is latched on the falling edge of the Chip Enable or Output Enable signals, and can be read until Chip Enable or Output Enable returns to VIH. Either Chip Enable or Output Enable must be toggled to update the latched data. Bus Read operations from any address always read the Status Register during Program and Erase operations. The bits in the Status Register are summarized in Table 10, Status Register Bits. Refer to Table 10 in conjunction with the following text descriptions. Program/Erase Controller Status (Bit 7). The Program/Erase Controller Status bit indicates whether the Program/Erase Controller is active or inactive. When the Program/Erase Controller Status bit is Low (set to ‘0’), the Program/Erase Controller is active; when the bit is High (set to ‘1’), the Program/Erase Controller is inactive, and the device is ready to process a new command. The Program/Erase Controller Status is Low immediately after a Program/Erase Suspend command is issued until the Program/Erase Controller pauses. After the Program/Erase Controller pauses the bit is High. During Program, Erase, operations the Program/ Erase Controller Status bit can be polled to find the end of the operation. Other bits in the Status Register should not be tested until the Program/Erase Controller completes the operation and the bit is High. After the Program/Erase Controller completes its operation the Erase Status, Program Status, VPPF Status and Block Lock Status bits should be tested for errors. Erase Suspend Status (Bit 6). The Erase Suspend Status bit indicates that an Erase operation has been suspended or is going to be suspended. When the Erase Suspend Status bit is High (set to ‘1’), a Program/Erase Suspend command has been issued and the memory is waiting for a Program/Erase Resume command. The Erase Suspend Status should only be considered valid when the Program/Erase Controller Status bit is High (Program/Erase Controller inactive). Bit 7 is set within 30µs of the Program/Erase Sus- pend command being issued therefore the memory may still complete the operation rather than entering the Suspend mode. When a Program/Erase Resume command is issued the Erase Suspend Status bit returns Low. Erase Status (Bit 5). The Erase Status bit can be used to identify if the memory has failed to verify that the block has erased correctly. When the Erase Status bit is High (set to ‘1’), the Program/ Erase Controller has applied the maximum number of pulses to the block and still failed to verify that the block has erased correctly. The Erase Status bit should be read once the Program/Erase Controller Status bit is High (Program/Erase Controller inactive). Once set High, the Erase Status bit can only be reset Low by a Clear Status Register command or a hardware reset. If set High it should be reset before a new Program or Erase command is issued, otherwise the new command will appear to fail. Program Status (Bit 4). The Program Status bit is used to identify a Program failure. When the Program Status bit is High (set to ‘1’), the Program/Erase Controller has applied the maximum number of pulses to the byte and still failed to verify that it has programmed correctly. The Program Status bit should be read once the Program/Erase Controller Status bit is High (Program/Erase Controller inactive). Once set High, the Program Status bit can only be reset Low by a Clear Status Register command or a hardware reset. If set High it should be reset before a new command is issued, otherwise the new command will appear to fail. VPPF Status (Bit 3). The VPPF Status bit can be used to identify an invalid voltage on the VPPF pin during Program and Erase operations. The VPPF pin is only sampled at the beginning of a Program or Erase operation. Indeterminate results can occur if VPPF becomes invalid during an operation. When the VPPF Status bit is Low (set to ‘0’), the voltage on the VPPF pin was sampled at a valid voltage; when the VPPF Status bit is High (set to ‘1’), the VPPF pin has a voltage that is below the VPPF Lockout Voltage, VPPLK, the memory is protected and Program and Erase operations cannot be performed. Once set High, the VPPF Status bit can only be reset Low by a Clear Status Register command or a hardware reset. If set High it should be reset before a new Program or Erase command is issued, otherwise the new command will appear to fail. 19/57 M36W432T, M36W432B Program Suspend Status (Bit 2). The Program Suspend Status bit indicates that a Program operation has been suspended. When the Program Suspend Status bit is High (set to ‘1’), a Program/ Erase Suspend command has been issued and the memory is waiting for a Program/Erase Resume command. The Program Suspend Status should only be considered valid when the Program/Erase Controller Status bit is High (Program/ Erase Controller inactive). Bit 2 is set within 5µs of the Program/Erase Suspend command being issued therefore the memory may still complete the operation rather than entering the Suspend mode. When a Program/Erase Resume command is issued the Program Suspend Status bit returns Low. Block Protection Status (Bit 1). The Block Protection Status bit can be used to identify if a Program or Erase operation has tried to modify the contents of a locked block. When the Block Protection Status bit is High (set to ‘1’), a Program or Erase operation has been attempted on a locked block. Once set High, the Block Protection Status bit can only be reset Low by a Clear Status Register command or a hardware reset. If set High it should be reset before a new command is issued, otherwise the new command will appear to fail. Reserved (Bit 0). Bit 0 of the Status Register is reserved. Its value must be masked. Note: Refer to Appendix C, Flowcharts and Pseudo Codes, for using the Status Register. Table 10. Status Register Bits Bit 7 6 5 4 3 2 1 0 Name Logic Level Definition '1' Ready '0' Busy '1' Suspended '0' In progress or Completed '1' Erase Error '0' Erase Success '1' Program Error '0' Program Success '1' VPPF Invalid, Abort '0' VPPF OK '1' Suspended '0' In Progress or Completed '1' Program/Erase on protected block, Abort '0' No operation to protected blocks P/E.C. Status Erase Suspend Status Erase Status Program Status VPPF Status Program Suspend Status Block Protection Status Reserved Note: Logic level '1' is High, '0' is Low. SRAM Operations There are five standard operations that control the SRAM component. These are Bus Read, Bus Write, Standby/Power-down, Data Retention and Output Disable. A summary is shown in Table 2, Main Operation Modes Read. Read operations are used to output the contents of the SRAM Array. The SRAM is in Read mode whenever Write Enable, WS, is at VIH, Output Enable, GS, is at VIL, Chip Enable, E1S, is at 20/57 VIL, Chip Enable, E2S, is at VIH, and Byte Enables, UBS and LBS are at VIL. Valid data will be available on the output pins after a time of tAVQV after the last stable address. If the Chip Enable or Output Enable access times are not met, data access will be measured from the limiting parameter (tE1LQV, tE2HQV, or tGLQV) rather than the address. Data out may be indeterminate at tE1LQX, tE2HQX and tGLQX, but data lines will always be valid at tAVQV (see Table 19, Figures 13 and 14). M36W432T, M36W432B Write. Write operations are used to write data to the SRAM. The SRAM is in Write mode whenever WS and E1S are at VIL, and E2S is at VIH. Either the Chip Enable inputs, E1S and E2S, or the Write Enable input, WS, must be deasserted during address transitions for subsequent write cycles. A Write operation is initiated when E1S is at VIL, E2S is at VIH and WS is at VIL. The data is latched on the falling edge of E1S, the rising edge of E2S or the falling edge of WS, whichever occurs last. The Write cycle is terminated on the rising edge of E1S, the rising edge of WS or the falling edge of E2S, whichever occurs first. If the Output is enabled (E1S=VIL, E2S=VIH and GS=VIL), then WS will return the outputs to high impedance within tWLQZ of its falling edge. Care must be taken to avoid bus contention in this type of operation. The Data input must be valid for tDVWH before the rising edge of Write Enable, for tDVE1H before the rising edge of E1S or for tDVE2L before the falling edge of E2S, whichever occurs first, and remain valid for tWHDX, tE1HAX or tE2LAX (see Table 20, Figure 16, 17, 18 and 19). Standby/Power-Down. The SRAM component has a chip enabled power-down feature which invokes an automatic standby mode (see Table 19, Figure 15). The SRAM is in Standby mode whenever either Chip Enable is deasserted, E1S at VIH or E2S at VIL. Data Retention. The SRAM data retention performances as VDDS goes down to VDR are described in Table 21 and Figure 20, 21. In E1S controlled data retention mode, the minimum standby current mode is entered when E1S ≥ VDDS – 0.2V and E2S ≤ 0.2V or E2S ≥ VDDS – 0.2V. In E2S controlled data retention mode, minimum standby current mode is entered when E2S ≤ 0.2V. Output Disable. The data outputs are high impedance when the Output Enable, GS, is at VIH with Write Enable, WS, at VIH. MAXIMUM RATING Stressing the device above the rating listed in the Absolute Maximum Ratings table may cause permanent damage to the device. These are stress ratings only and operation of the device at these or any other conditions above those indicated in the Operating sections of this specification is not im- plied. Exposure to Absolute Maximum Rating conditions for extended periods may affect device reliability. Refer also to the STMicroelectronics SURE Program and other relevant quality documents. Table 11. Absolute Maximum Ratings Value Symbol Parameter Unit Min Max Ambient Operating Temperature (1) –40 85 °C TBIAS Temperature Under Bias –40 125 °C TSTG Storage Temperature –55 155 °C Input or Output Voltage –0.5 VDDQF +0.3 V Flash Supply Voltage –0.6 3.9 V VPPF Program Voltage –0.6 13 V VDDS SRAM Supply Voltage –0.5 3.9 V TA VIO VDDF, VDDQF Note: 1. Depends on range. 21/57 M36W432T, M36W432B DC AND AC PARAMETERS This section summarizes the operating and measurement conditions, and the DC and AC characteristics of the device. The parameters in the DC and AC characteristics Tables that follow, are derived from tests performed under the Measure- ment Conditions summarized in Table 12, Operating and AC Measurement Conditions. Designers should check that the operating conditions in their circuit match the measurement conditions when relying on the quoted parameters. Table 12. Operating and AC Measurement Conditions Parameter SRAM Flash Memory 70 70/85 Units Min Max Min Max – – 2.7 3.3 V VDDQ F = VDDS Supply Voltage 2.7 3.3 2.7 3.3 V Ambient Operating Temperature – 40 85 – 40 85 °C VDDF Supply Voltage Load Capacitance (CL) 50 50 Input Rise and Fall Times pF 5 Input Pulse Voltages Input and Output Timing Ref. Voltages 5 ns 0 to VDDQF 0 to VDDQF V VDDQF/2 VDDQF/2 V Figure 8. AC Measurement Load Circuit Figure 7. AC Measurement I/O Waveform VDDQF VDDQ VDDQ/2 VDDQF VDDF 0V 25kΩ AI05205 DEVICE UNDER TEST Note: VDDQ means VDDQF = VDDS CL 0.1µF 25kΩ 0.1µF CL includes JIG capacitance AI05206 Table 13. Device Capacitance Symbol CIN COUT Parameter Input Capacitance Output Capacitance Note: Sampled only, not 100% tested. 22/57 Test Condition Typ Max Unit VIN = 0V, f=1 MHz 12 14 pF VOUT = 0V, f=1 MHz 20 22 pF M36W432T, M36W432B Table 14. DC Characteristics Symbol Parameter Device Test Condition Min Typ Max Unit ILI Input Leakage Current Flash & SRAM 0V ≤ VIN ≤ VDDQF ±2 µA ILO Output Leakage Current Flash & SRAM 0V ≤ VOUT ≤ VDDQF, SRAM Outputs Hi-Z ±10 µA Flash EF = VDDQF ± 0.2V VDDQF = VDDF max 15 50 µA SRAM E1S = E2S ≥ VDDS – 0.2V or E2S ≤ 0.2V 20 50 µA Flash RPF = VSSF ± 0.2V 15 50 µA VIN ≤ VDDS – 0.2V or VIN ≤ 0.2V IIO = 0 mA, cycle time = 1µs 1 2 mA VIN ≤ VDDS – 0.2V or VIN ≤ 0.2V IIO = 0 mA, min cycle time 7 12 mA IDDS IDDD IDD VDD Standby Current Supply Current (Reset) Supply Current SRAM IDDR Supply Current (Read) Flash EF = VIL, GF = VIH, f = 5 MHz 10 20 mA IDDW Supply Current (Program) Flash Program in progress 10 20 mA IDDE Supply Current (Erase) Flash Erase in progress 5 20 mA IDDES Supply Current (Erase Suspend) Flash Erase Suspend in progress 50 µA IDDWS Supply Current (Program Suspend) Flash Program Suspend in progress 50 µA Program Current (Standby) Flash Program Current (Read) Flash IPPW Program Current (Program) IPPE VPPF ≤ VDDQF 0.2 5 µA VPPF > VDDF 100 400 µA VPPF ≤ VDDQF 0.2 5 µA VPPF = VDDF 100 400 µA Flash VPPF = 12V ± 0.6V Program in progress 5 10 mA Program Current (Erase) Flash VPPF = 12V ± 0.6V Program in progress 5 10 mA VIL Input Low Voltage Flash & SRAM VDDQF = VDDS ≥ 2.7V – 0.3 0.8 V VIH Input High Voltage Flash & SRAM VDDQF = VDDS ≥ 2.7V 2.2 VDDQF +0.3 V VOL Output Low Voltage Flash & SRAM VDDQF = VDDS = VDD min IOL = 100µA 0.1 V VOH Output High Voltage Flash & SRAM VDDQF = VDDS = VDD min IOH = –100µA VPPL Program Voltage (Program or Erase operations) IPPS IPPR Flash VDDQ –0.1 2.7 V 3.3 V 23/57 M36W432T, M36W432B Symbol Parameter Device VPPH Program Voltage (Program or Erase operations) Flash VPPLK Program Voltage (Program and Erase lock-out) VLKO VDDF Supply Voltage (Program and Erase lock-out) Test Condition Min Typ Max Unit 12.6 V Flash 1 V Flash 2 V 11.4 Figure 9. Flash Read AC Waveforms tAVAV VALID A0-A20 tAVQV tAXQX EF tELQV tELQX tEHQX tEHQZ GF tGLQV tGHQX tGLQX tGHQZ VALID DQ0-DQ15 OUTPUTS ENABLED ADDR. VALID CHIP ENABLE DATA VALID STANDBY AI05207 Table 15. Flash Read AC Characteristics Flash Symbol Alt Parameter Unit 70 85 tAVAV tRC Address Valid to Next Address Valid Min 70 85 ns tAVQV tACC Address Valid to Output Valid Max 70 85 ns tAXQX (1) tOH Address Transition to Output Transition Min 0 0 ns tEHQX (1) tOH Chip Enable High to Output Transition Min 0 0 ns tEHQZ (1) tHZ Chip Enable High to Output Hi-Z Max 20 20 ns tELQV (2) tCE Chip Enable Low to Output Valid Max 70 85 ns tELQX (1) tLZ Chip Enable Low to Output Transition Min 0 0 ns tGHQX (1) tOH Output Enable High to Output Transition Min 0 0 ns tGHQZ (1) tDF Output Enable High to Output Hi-Z Max 20 20 ns tGLQV (2) tOE Output Enable Low to Output Valid Max 20 20 ns 24/57 M36W432T, M36W432B Flash Symbol tGLQX (1) Alt tOLZ Parameter Output Enable Low to Output Transition Unit Min 70 85 0 0 ns Note: 1. Sampled only, not 100% tested. 2. GF may be delayed by up to tELQV - tGLQV after the falling edge of EF without increasing tELQV. 25/57 26/57 VPPF WPF DQ0-DQ15 WF GF EF A0-A20 tWLWH COMMAND SET-UP COMMAND tDVWH tELWL tWHDX tWHWL tWHEH CMD or DATA CONFIRM COMMAND OR DATA INPUT tVPHWH tWPHWH tAVWH VALID tAVAV tWHEL tWHGL tWHAX PROGRAM OR ERASE AI05208 tQVVPL tQVWPL STATUS REGISTER STATUS REGISTER READ 1st POLLING tELQV M36W432T, M36W432B Figure 10. Flash Write AC Waveforms, Write Enable Controlled M36W432T, M36W432B Table 16. Flash Write AC Characteristics, Write Enable Controlled Flash Symbol Alt Parameter Unit 70 85 tAVAV tWC Write Cycle Time Min 70 85 ns tAVWH tAS Address Valid to Write Enable High Min 45 45 ns tDVWH tDS Data Valid to Write Enable High Min 45 45 ns tELWL tCS Chip Enable Low to Write Enable Low Min 0 0 ns Chip Enable Low to Output Valid Min 70 85 ns Output Valid to VPPF Low Min 0 0 ns Output Valid to Write Protect Low Min 0 0 ns tELQV tQVVPL (1,2) tQVWPL tVPHWH (1) tVPS VPPF High to Write Enable High Min 200 200 ns tWHAX tAH Write Enable High to Address Transition Min 0 0 ns tWHDX tDH Write Enable High to Data Transition Min 0 0 ns tWHEH tCH Write Enable High to Chip Enable High Min 0 0 ns tWHEL Write Enable High to Output Enable Low Min 25 25 ns tWHGL Write Enable High to Output Enable Low Min 20 20 ns tWHWL tWPH Write Enable High to Write Enable Low Min 25 25 ns tWLWH tWP Write Enable Low to Write Enable High Min 45 45 ns Write Protect High to Write Enable High Min 45 45 ns tWPHWH Note: 1. Sampled only, not 100% tested. 2. Applicable if VPPF is seen as a logic input (VPPF < 3.6V). 27/57 28/57 VPPF WPF DQ0-DQ15 EF GF WF A0-A20 tELEH COMMAND POWER-UP AND SET-UP COMMAND tDVEH tWLEL tEHDX tEHEL tEHWH CMD or DATA CONFIRM COMMAND OR DATA INPUT tVPHEH tWPHEH tAVEH VALID tAVAV tEHGL tEHAX PROGRAM OR ERASE AI05209 tQVVPL tQVWPL STATUS REGISTER STATUS REGISTER READ 1st POLLING tELQV M36W432T, M36W432B Figure 11. Flash Write AC Waveforms, Chip Enable Controlled M36W432T, M36W432B Table 17. Flash Write AC Characteristics, Chip Enable Controlled Flash Symbol Alt Parameter Unit 70 85 tAVAV tWC Write Cycle Time Min 70 85 ns tAVEH tAS Address Valid to Chip Enable High Min 45 45 ns tDVEH tDS Data Valid to Chip Enable High Min 45 45 ns tEHAX tAH Chip Enable High to Address Transition Min 0 0 ns tEHDX tDH Chip Enable High to Data Transition Min 0 0 ns tEHEL tCPH Chip Enable High to Chip Enable Low Min 25 25 ns Chip Enable High to Output Enable Low Min 25 25 ns tEHGL tEHWH tWH Chip Enable High to Write Enable High Min 0 0 ns tELEH tCP Chip Enable Low to Chip Enable High Min 45 45 ns Chip Enable Low to Output Valid Min 70 85 ns Output Valid to VPPF Low Min 0 0 ns Data Valid to Write Protect Low Min 0 0 ns tELQV tQVVPL (1,2) tQVWPL tVPHEH (1) tVPS VPPF High to Chip Enable High Min 200 200 ns tWLEL tCS Write Enable Low to Chip Enable Low Min 0 0 ns Write Protect High to Chip Enable High Min 45 45 ns tWPHEH Note: 1. Sampled only, not 100% tested. 2. Applicable if VPPF is seen as a logic input (VPPF < 3.6V). 29/57 M36W432T, M36W432B Figure 12. Flash Power-Up and Reset AC Waveforms WF, EF,GF tPHWL tPHEL tPHGL tPHWL tPHEL tPHGL RPF tVDHPH tPLPH VDDF, VDDQF Power-Up Reset AI05210 Table 18. Flash Power-Up and Reset AC Characteristics Flash Symbol tPHWL tPHEL tPHGL Parameter Reset High to Write Enable Low, Chip Enable Low, Output Enable Low Test Condition Unit 70 85 During Program and Erase Min 50 50 µs others Min 30 30 ns tPLPH(1,2) Reset Low to Reset High Min 100 100 ns tVDHPH(3) Supply Voltages High to Reset High Min 50 50 µs Note: 1. The device Reset is possible but not guaranteed if tPLPH < 100ns. 2. Sampled only, not 100% tested. 3. It is important to assert RPF in order to allow proper CPU initialization during power up or reset. 30/57 M36W432T, M36W432B Figure 13. SRAM Read AC Waveforms, Address Controlled with UBS = LBS = VIL tAVAV A0-A17 VALID tAVQV tAXQX DQ0-DQ15 DATA VALID DATA VALID AI05211 Note: E1S = Low, E2S = High, GS = Low, WS = High. Figure 14. SRAM Read AC Waveforms, E1S, E2S or GS Controlled tAVAV VALID A0-A17 tAVQV tAXQX tE1LQV tE1HQZ E1S tE1LQX tE2HQV tE2LQZ E2S tE2HQX tBLQV tBHQZ UBS, LBS tBLQX tGLQV tGHQZ GS tGLQX DQ0-DQ15 DATA VALID AI05212 31/57 M36W432T, M36W432B Figure 15. SRAM Standby AC Waveforms E1S E2S tPU IDD tPD 50% AI05213 Table 19. SRAM Read AC Characteristics SRAM Symbol Alt Parameter Unit Min Max tAVAV tRC Read Cycle Time tAVQV tAA Address Valid to Output Valid tAXQX tOH Address Transition to Output Transition tBHQZ tBHZ UBS, LBS Disable to Hi-Z Output 25 ns tBLQV tBA UBS, LBS Access Time 70 ns tBLQX tBLZ UBS, LBS Enable to Low-Z Output tE1HQZ tHZ1 Chip Enable 1 High to Output Hi-Z 25 ns tE1LQV tCO1 Chip Enable 1 Low to Output Valid 70 ns tE1LQX tLZ1 Chip Enable 1 Low to Output Transition tE2HQV tCO2 Chip Enable 2 High to Output Valid tE2HQX tLZ2 Chip Enable 2 High to Output Transition tE2LQZ tHZ2 Chip Enable 2 Low to Output Hi-Z 25 ns tGHQZ tOHZ Output Enable High to Output Hi-Z 25 ns tGLQV tOE Output Enable Low to Output Valid 35 ns tGLQX tOLZ Output Enable Low to Output Transition tPD (1) Chip Enable 1 High or Chip Enable 2 Low to Power Down tPU (1) Chip Enable 1 Low or Chip Enable 2 High to Power Up Note: 1. Sampled only. Not 100% tested. 32/57 70 ns 70 10 ns 10 ns 10 ns 70 10 ns ns 5 ns 70 0 ns ns ns M36W432T, M36W432B Figure 16. SRAM Write AC Waveforms, WS Controlled with GS Low tAVAV VALID A0-A17 tAVWH tE1LWH tAVE1L tWHAX E1S tAVE2H E2S tE2HWH tBLWH UBS, LBS tAVWL tWLWH WS tWHQX tWLQZ tDVWH DQ0-DQ15 tWHDX INPUT VALID AI05214 Figure 17. SRAM Write AC Waveforms, WS Controlled with GS High tAVAV VALID A0-A17 tAVWH tE1LWH tAVE1L tWHAX E1S tAVE2H E2S tE2HWH tBLWH UBS, LBS tAVWL tWLWH WS GS tWHQX tGHQZ DQ0-DQ15 tDVWH tWHDX INPUT VALID AI05215 33/57 M36W432T, M36W432B Figure 18. SRAM Write AC Waveforms, UBS and LBS Controlled tAVAV VALID A0-A17 tE1LWH tE1HAX E1S tAVWH E2S tE2HWH tAVWL tBLWH UBS, LBS tWLWH WS tDVWH tWHDX DATA VALID DQ0-DQ15 AI05216 Figure 19. SRAM Write AC Waveforms, E1S Controlled tAVAV VALID A0-A17 tAVE1L tE1LWH tE1HAX E1S E2S tBLWH UBS, LBS tAVWL WS tDVE1H DQ0-DQ15 tWHDX INPUT VALID AI05217 34/57 M36W432T, M36W432B Table 20. SRAM Write AC Characteristics SRAM Symbol Alt Parameter Unit Min tAVAV tWC tAVE1L tAS (1) tAVE2H Write Cycle Time Max 70 ns Address Valid to Chip Enable 1 Low 0 ns tAS (1) Address Valid to Chip Enable 2 High 0 ns tAVWH tAW Address Valid to Write Enable High 60 ns tAVWL tAS (1) Address Valid to Write Enable Low 0 ns tBLWH tBW UBS, LBS Valid to End of Write 60 ns tDVE1H tDW Input Valid to Chip Enable 1 High 30 ns tDVE2L tDW Input Valid to Chip Enable 2 Low 30 ns tDVWH tDW Input Valid to Write Enable High 30 ns tE1HAX tWR (2) Chip Enable 1 High to Address Transition 0 ns tE1LWH, tE2HWH tCW (3) Chip Select to End of Write 60 ns tE2LAX tWR (2) Chip Enable 2 Low to Address Transition 0 ns tGHQZ tGHZ tWHAX tWR (2) tWHDX Output Enable High to Output Hi-Z 25 ns Write Enable High to Address Transition 0 ns tDH Write Enable High to Input Transition 0 ns tWHQX tOW Write Enable High to Output Transition 10 ns tWLQZ tWHZ Write Enable Low to Output Hi-Z tWLWH tWP (4) Note: 1. 2. 3. 4. Write Enable Pulse Width 25 50 ns ns tAS is measured from the address valid to the beginning of write. tWR is measured from the end or write to the address change. tWR applied in case a write ends as E1S or WS going high. tCW is measured from E1S going low end of write. A Write occurs during the overlap (tWP) of low E1S and low WS. A write begins when E1S goes low and WS goes low with asserting UBS or LBS for single byte operation or simultaneously asserting UBS and LBS for double byte operation. A write ends at the earliest transition when E1S goes high and WS goes high. The tWP is measured from the beginning of write to the end of write. 35/57 M36W432T, M36W432B Figure 20. SRAM Low VDDS Data Retention AC Waveforms, E1S Controlled tCDR tR DATA RETENTION MODE VDDS 2.8 V VDR ≥ 1.5V 1.5 V E1S ≥ VDDS – 0.2V E1S VSSS AI05218 Figure 21. SRAM Low VDDS Data Retention AC Waveforms, E2S Controlled DATA RETENTION MODE VDDS 2.8 V E2S tCDR 1.5 V VDR ≥ 1.5V tR E2S ≤ 0.2V 0.4 V VSSS AI05219 Table 21. SRAM Low VDDS Data Retention Characteristic Symbol Parameter Test Condition IDDDR Supply Current (Data Retention) VDDS = 3.3V, E1S ≥ VDDS – 0.2V, E2S ≥ VDDS – 0.2V or E2S ≤ 0.2V VDR Supply Voltage (Data Retention) E1S ≥ VDDS – 0.2V, E2S ≤ 0.2V 1.5 tCDR Chip Disable to Power Down E1S ≥ VDDS – 0.2V, E2S ≤ 0.2V 0 ns tRC ns tR Operation Recovery Time Note: 1. All other Inputs VIH ≤ VDD –0.2V or VIL ≤ 0.2V. 2. Sampled only. Not 100% tested. 36/57 Min Max Unit 15 µA 3.3 V M36W432T, M36W432B PACKAGE MECHANICAL Figure 22. Stacked LFBGA66 - 8 x 8 ball array, 0.8 mm pitch, Bottom View Package Outline D D2 D1 SE b BALL "A1" e E E1 FE FD SD ddd e A A2 A1 BGA-Z12 Note: Drawing is not to scale. Table 22. Stacked LFBGA66 - 8 x 8 ball array, 0.8 mm pitch, Package Mechanical Data Symbol millimeters Typ Min A inches Max Typ Min 1.400 A1 0.0551 0.250 A2 0.0098 1.100 b 0.400 0.350 Max 0.450 0.0433 0.0157 0.0138 0.0177 D 12.000 – – 0.4724 – – D1 5.600 – – 0.2205 – – D2 8.800 – – 0.3465 – – ddd 0.100 0.0039 E 8.000 – – 0.3150 – – E1 5.600 – – 0.2205 – – e 0.800 – – 0.0315 – – FD 1.600 – – 0.0630 – – FE 1.200 – – 0.0472 – – SD 0.400 – – 0.0157 – – SE 0.400 – – 0.0157 – – 37/57 M36W432T, M36W432B Figure 23. Stacked LFBGA66 Daisy Chain - Package Connections (Top view through package) #1 #2 1 2 3 4 5 6 7 8 #3 #4 A B C D E F G H AI05220 38/57 M36W432T, M36W432B Figure 24. Stacked LFBGA66 Daisy Chain - PCB Connections proposal (Top view through package) END POINT START POINT #1 #2 1 2 3 4 5 6 7 8 #3 #4 A B C D E F G H AI05221 39/57 M36W432T, M36W432B PART NUMBERING Table 23. Ordering Information Scheme Example: M36W432T 70 ZA 6 T Device Type M36 = MMP (Flash + SRAM) Operating Voltage W = VDDF = 2.7V to 3.3V, VDDS = VDDQF = 2.7V to 3.3V SRAM Chip Size & Organization 4 = 4 Mbit (256K x 16 bit) Device Function 32 = 32 Mbit (x16), Boot Block Array Matrix T = Top Boot B = Bottom Boot Speed 70 = 70ns 85 = 85ns Package ZA = LFBGA66: 0.8mm pitch Temperature Range 1 = 0 to 70°C 6 = –40 to 85°C Option T = Tape & Reel packing Devices are shipped from the factory with the memory content bits erased to ’1’. Table 24. Daisy Chain Ordering Scheme Example: M36W432 -ZA T Device Type M36W432 Daisy Chain -ZA = LFBGA66: 0.8mm pitch Option T = Tape & Reel Packing For a list of available options (Speed, Package, etc...) or for further information on any aspect of this device, please contact the STMicroelectronics Sales Office nearest to you. 40/57 M36W432T, M36W432B REVISION HISTORY Table 25. Document Revision History Date Version Revision Details 19-Jun-2001 -01 First Issue 16-Jul-2001 -02 Flash Commands Table corrections: Protect/Lock, Unprotect/Unlock, Lock/LockDown 11-Feb-2002 -03 Package mechanical data clarified (Table 22) 41/57 M36W432T, M36W432B APPENDIX A. FLASH MEMORY BLOCK ADDRESS TABLES Table 26. Top Boot Block Addresses, M36W432T # Size (KWord) Address Range 0 4 1FF000-1FFFFF 1 4 1FE000-1FEFFF 2 4 1FD000-1FDFFF 3 4 1FC000-1FCFFF 4 4 1FB000-1FBFFF 5 4 1FA000-1FAFFF 6 4 1F9000-1F9FFF 7 4 1F8000-1F8FFF 8 32 1F0000-1F7FFF 9 32 1E8000-1EFFFF 10 32 1E0000-1E7FFF 11 32 1D8000-1DFFFF 12 32 1D0000-1D7FFF 13 32 1C8000-1CFFFF 14 32 1C0000-1C7FFF 15 32 1B8000-1BFFFF 16 32 1B0000-1B7FFF 17 32 1A8000-1AFFFF 18 32 1A0000-1A7FFF 19 32 198000-19FFFF 20 32 190000-197FFF 21 32 188000-18FFFF 22 32 180000-187FFF 23 32 178000-17FFFF 24 32 170000-177FFF 25 32 168000-16FFFF 26 32 160000-167FFF 27 32 158000-15FFFF 28 32 150000-157FFF 29 32 148000-14FFFF 30 32 140000-147FFF 31 32 138000-13FFFF 32 32 130000-137FFF 33 32 128000-12FFFF 42/57 34 32 120000-127FFF 35 32 118000-11FFFF 36 32 110000-117FFF 37 32 108000-10FFFF 38 32 100000-107FFF 39 32 0F8000-0FFFFF 40 32 0F0000-0F7FFF 41 32 0E8000-0EFFFF 42 32 0E0000-0E7FFF 43 32 0D8000-0DFFFF 44 32 0D0000-0D7FFF 45 32 0C8000-0CFFFF 46 32 0C0000-0C7FFF 47 32 0B8000-0BFFFF 48 32 0B0000-0B7FFF 49 32 0A8000-0AFFFF 50 32 0A0000-0A7FFF 51 32 098000-09FFFF 52 32 090000-097FFF 53 32 088000-08FFFF 54 32 080000-087FFF 55 32 078000-07FFFF 56 32 070000-077FFF 57 32 068000-06FFFF 58 32 060000-067FFF 59 32 058000-05FFFF 60 32 050000-057FFF 61 32 048000-04FFFF 62 32 040000-047FFF 63 32 038000-03FFFF 64 32 030000-037FFF 65 32 028000-02FFFF 66 32 020000-027FFF 67 32 018000-01FFFF 68 32 010000-017FFF 69 32 008000-00FFFF 70 32 000000-007FFF M36W432T, M36W432B Table 27. Bottom Boot Block Addresses, M36W432B # Size (KWord) Address Range 70 32 1F8000-1FFFFF 69 32 1F0000-1F7FFF 68 32 1E8000-1EFFFF 67 32 1E0000-1E7FFF 66 32 1D8000-1DFFFF 65 32 1D0000-1D7FFF 64 32 1C8000-1CFFFF 63 32 1C0000-1C7FFF 62 32 1B8000-1BFFFF 61 32 1B0000-1B7FFF 60 32 1A8000-1AFFFF 59 32 1A0000-1A7FFF 58 32 198000-19FFFF 57 32 190000-197FFF 56 32 188000-18FFFF 55 32 180000-187FFF 54 32 178000-17FFFF 53 32 170000-177FFF 52 32 168000-16FFFF 51 32 160000-167FFF 50 32 158000-15FFFF 49 32 150000-157FFF 48 32 148000-14FFFF 47 32 140000-147FFF 46 32 138000-13FFFF 45 32 130000-137FFF 44 32 128000-12FFFF 43 32 120000-127FFF 42 32 118000-11FFFF 41 32 110000-117FFF 40 32 108000-10FFFF 39 32 100000-107FFF 38 32 0F8000-0FFFFF 37 32 0F0000-0F7FFF 36 32 0E8000-0EFFFF 35 32 0E0000-0E7FFF 34 32 0D8000-0DFFFF 33 32 0D0000-0D7FFF 32 32 0C8000-0CFFFF 31 32 0C0000-0C7FFF 30 32 0B8000-0BFFFF 29 32 0B0000-0B7FFF 28 32 0A8000-0AFFFF 27 32 0A0000-0A7FFF 26 32 098000-09FFFF 25 32 090000-097FFF 24 32 088000-08FFFF 23 32 080000-087FFF 22 32 078000-07FFFF 21 32 070000-077FFF 20 32 068000-06FFFF 19 32 060000-067FFF 18 32 058000-05FFFF 17 32 050000-057FFF 16 32 048000-04FFFF 15 32 040000-047FFF 14 32 038000-03FFFF 13 32 030000-037FFF 12 32 028000-02FFFF 11 32 020000-027FFF 10 32 018000-01FFFF 9 32 010000-017FFF 8 32 008000-00FFFF 7 4 007000-007FFF 6 4 006000-006FFF 5 4 005000-005FFF 4 4 004000-004FFF 3 4 003000-003FFF 2 4 002000-002FFF 1 4 001000-001FFF 0 4 000000-000FFF 43/57 M36W432T, M36W432B APPENDIX B. COMMON FLASH INTERFACE (CFI) The Common Flash Interface is a JEDEC approved, standardized data structure that can be read from the Flash memory device. It allows a system software to query the device to determine various electrical and timing parameters, density information and functions supported by the memory. The system can interface easily with the device, enabling the software to upgrade itself when necessary. When the CFI Query Command (RCFI) is issued the device enters CFI Query mode and the data structure is read from the memory. Tables 28, 29, 30, 31, 32 and 33 show the addresses used to retrieve the data. The CFI data structure also contains a security area where a 64 bit unique security number is written (see Table 33, Security Code area). This area can be accessed only in Read mode by the final user. It is impossible to change the security number after it has been written by ST. Issue a Read command to return to Read mode. Table 28. Query Structure Overview Offset Sub-section Name Description 00h Reserved Reserved for algorithm-specific information 10h CFI Query Identification String Command set ID and algorithm data offset 1Bh System Interface Information Device timing & voltage information 27h Device Geometry Definition Flash device layout P Primary Algorithm-specific Extended Query table Additional information specific to the Primary Algorithm (optional) A Alternate Algorithm-specific Extended Query table Additional information specific to the Alternate Algorithm (optional) Note: Query data are always presented on the lowest order data outputs. Table 29. CFI Query Identification String Offset Data Description 00h 0020h Manufacturer Code 01h 88BAh 88BBh Device Code 02h-0Fh reserved 10h 0051h 11h 0052h 12h 0059h 13h 0003h 14h 0000h 15h 0035h 16h 0000h 17h 0000h 18h 0000h 19h 0000h 1Ah 0000h ST Top Bottom Reserved "Q" Query Unique ASCII String "QRY" "R" "Y" Primary Algorithm Command Set and Control Interface ID code 16 bit ID code defining a specific algorithm Address for Primary Algorithm extended Query table (see Table 31) Intel compatible P = 35h Alternate Vendor Command Set and Control Interface ID Code second vendor specified algorithm supported (0000h means none exists) NA Address for Alternate Algorithm extended Query table (0000h means none exists) NA Note: Query data are always presented on the lowest order data outputs (DQ7-DQ0) only. DQ8-DQ15 are ‘0’. 44/57 Value M36W432T, M36W432B Table 30. CFI Query System Interface Information Offset Data Description Value 1Bh 0027h VDD Logic Supply Minimum Program/Erase or Write voltage bit 7 to 4 BCD value in volts bit 3 to 0 BCD value in 100 mV 2.7V 1Ch 0036h VDD Logic Supply Maximum Program/Erase or Write voltage bit 7 to 4 BCD value in volts bit 3 to 0 BCD value in 100 mV 3.6V 1Dh 00B4h VPP [Programming] Supply Minimum Program/Erase voltage bit 7 to 4 HEX value in volts bit 3 to 0 BCD value in 100 mV 11.4V 1Eh 00C6h VPP [Programming] Supply Maximum Program/Erase voltage bit 7 to 4 HEX value in volts bit 3 to 0 BCD value in 100 mV 12.6V 1Fh 0004h Typical timeout per single word program = 2n µs 16µs 20h 0004h Typical timeout for Double Word Program = 2n µs 16µs 21h 000Ah Typical timeout per individual block erase = 2n ms 1s 22h 0000h Typical timeout for full chip erase = 2n ms NA 23h 0005h Maximum timeout for word program = 2n times typical 512µs 24h 0005h Maximum timeout for Double Word Program = 2n times typical 512µs 25h 0003h Maximum timeout per individual block erase = 2n times typical 8s 26h 0000h Maximum timeout for chip erase = 2n times typical NA 45/57 M36W432T, M36W432B Table 31. Device Geometry Definition Data 27h 0016h Device Size = 2n in number of bytes 28h 29h 0001h 0000h Flash Device Interface Code description 2Ah 2Bh 0002h 0000h Maximum number of bytes in multi-byte program or page = 2n 4 2Ch 0002h Number of Erase Block Regions within the device. It specifies the number of regions within the device containing contiguous Erase Blocks of the same size. 2 2Dh 2Eh 003Eh 0000h Region 1 Information Number of identical-size erase block = 003Eh+1 63 2Fh 30h 0000h 0001h Region 1 Information Block size in Region 1 = 0100h * 256 byte 31h 32h 0007h 0000h Region 2 Information Number of identical-size erase block = 0007h+1 33h 34h 0020h 0000h Region 2 Information Block size in Region 2 = 0020h * 256 byte 2Dh 2Eh 0007h 0000h Region 1 Information Number of identical-size erase block = 0007h+1 2Fh 30h 0020h 0000h Region 1 Information Block size in Region 1 = 0020h * 256 byte 31h 32h 003Eh 0000h Region 2 Information Number of identical-size erase block = 003Eh=1 33h 34h 0000h 0001h Region 2 Information Block size in Region 2 = 0100h * 256 byte M36W432B M36W432T Offset Word Mode 46/57 Description Value 4 MByte x16 Async. 64 KByte 8 8 KByte 8 8 KByte 63 64 KByte M36W432T, M36W432B Table 32. Primary Algorithm-Specific Extended Query Table Offset P = 35h (1) Data (P+0)h = 35h 0050h (P+1)h = 36h 0052h (P+2)h = 37h 0049h (P+3)h = 38h 0031h Major version number, ASCII "1" (P+4)h = 39h 0030h Minor version number, ASCII "0" (P+5)h = 3Ah 0066h (P+6)h = 3Bh 0000h Extended Query table contents for Primary Algorithm. Address (P+5)h contains less significant byte. (P+7)h = 3Ch 0000h (P+8)h = 3Dh 0000h (P+9)h = 3Eh 0001h (P+A)h = 3Fh 0003h (P+B)h = 40h 0000h Description Value "P" Primary Algorithm extended Query table unique ASCII string “PRI” "R" "I" bit bit bit bit bit bit bit bit bit bit 0 1 2 3 4 5 6 7 8 31 to 9 Chip Erase supported Suspend Erase supported Suspend Program supported Legacy Lock/Unlock supported Queued Erase supported Instant individual block locking supported Protection bits supported Page mode read supported Synchronous read supported Reserved; undefined bits are ‘0’ (1 (1 (1 (1 (1 (1 (1 (1 (1 = Yes, = Yes, = Yes, = Yes, = Yes, = Yes, = Yes, = Yes, = Yes, 0 = No) 0 = No) 0 = No) 0 = No) 0 = No) 0 = No) 0 = No) 0 = No) 0 = No) No Yes Yes No No Yes Yes No No Supported Functions after Suspend Read Array, Read Status Register and CFI Query are always supported during Erase or Program operation bit 0 Program supported after Erase Suspend (1 = Yes, 0 = No) bit 7 to 1 Reserved; undefined bits are ‘0’ Yes Block Lock Status : Defines which bits in the Block Status Register section of the Query are implemented. Address (P+A)h contains less significant byte bit 0 Block Lock Status bit active (1 = Yes, 0 = No) bit 1 Block Lock-Down Status bit active (1 = Yes, 0 = No) bit 15 to 2 Reserved for future use; undefined bits are ‘0’ Yes Yes (P+C)h = 41h 0030h VDD Logic Supply Optimum Program/Erase voltage (highest performance) bit 7 to 4 HEX value in volts bit 3 to 0 BCD value in 100 mV 3V (P+D)h = 42h 00C0h VPP Supply Optimum Program/Erase voltage bit 7 to 4 HEX value in volts bit 3 to 0 BCD value in 100 mV 12V (P+E)h = 43h 0001h Number of Protection register fields in JEDEC ID space. "00h," indicates that 256 protection bytes are available 01 (P+F)h = 44h 0080h 80h (P+10)h = 45h 0000h (P+11)h = 46h 0003h (P+12)h = 47h 0003h Protection Field 1: Protection Description This field describes user-available. One Time Programmable (OTP) Protection register bytes. Some are pre-programmed with device unique serial numbers. Others are user programmable. Bits 0–15 point to the Protection register Lock byte, the section’s first byte. The following bytes are factory pre-programmed and user-programmable. bit 0 to 7 Lock/bytes JEDEC-plane physical low address bit 8 to 15 Lock/bytes JEDEC-plane physical high address bit 16 to 23 "n" such that 2n = factory pre-programmed bytes bit 24 to 31 "n" such that 2n = user programmable bytes (P+13)h = 48h 00h 8 Byte 8 Byte Reserved Note: 1. See Table 29, offset 15 for P pointer definition. 47/57 M36W432T, M36W432B Table 33. Security Code Area Offset Data 80h 00XX 81h XXXX 82h XXXX 83h XXXX 84h XXXX 85h XXXX 86h XXXX 87h XXXX 88h XXXX 48/57 Description Protection Register Lock 64 bits: unique device number 64 bits: User Programmable OTP M36W432T, M36W432B APPENDIX C. FLASH MEMORY FLOWCHARTS AND PSEUDO CODES Figure 25. Program Flowchart and Pseudo Code Start program_command (addressToProgram, dataToProgram) {: writeToFlash (any_address, 0x40) ; /*or writeToFlash (any_address, 0x10) ; */ Write 40h or 10h writeToFlash (addressToProgram, dataToProgram) ; /*Memory enters read status state after the Program Command*/ Write Address & Data do { status_register=readFlash (any_address) ; /* EF or GF must be toggled*/ Read Status Register b7 = 1 NO } while (status_register.b7== 0) ; YES b3 = 0 NO VPPF Invalid Error (1, 2) NO Program Error (1, 2) NO Program to Protected Block Error (1, 2) if (status_register.b3==1) /*VPPF invalid error */ error_handler ( ) ; YES b4 = 0 if (status_register.b4==1) /*program error */ error_handler ( ) ; YES b1 = 0 if (status_register.b1==1) /*program to protect block error */ error_handler ( ) ; YES End } AI05222 Note: 1. Status check of b1 (Protected Block), b3 (VPPF Invalid) and b4 (Program Error) can be made after each program operation or after a sequence. 2. If an error is found, the Status Register must be cleared before further Program/Erase Controller operations. 49/57 M36W432T, M36W432B Figure 26. Double Word Program Flowchart and Pseudo Code Start Write 30h double_word_program_command (addressToProgram1, dataToProgram1, addressToProgram2, dataToProgram2) { writeToFlash (any_address, 0x30) ; writeToFlash (addressToProgram1, dataToProgram1) ; /*see note (3) */ writeToFlash (addressToProgram2, dataToProgram2) ; /*see note (3) */ /*Memory enters read status state after the Program command*/ Write Address 1 & Data 1 (3) Write Address 2 & Data 2 (3) do { status_register=readFlash (any_address) ; /* EF or GF must be toggled*/ Read Status Register b7 = 1 NO } while (status_register.b7== 0) ; YES b3 = 0 NO VPPF Invalid Error (1, 2) NO Program Error (1, 2) NO Program to Protected Block Error (1, 2) if (status_register.b3==1) /*VPPF invalid error */ error_handler ( ) ; YES b4 = 0 if (status_register.b4==1) /*program error */ error_handler ( ) ; YES b1 = 0 if (status_register.b1==1) /*program to protect block error */ error_handler ( ) ; YES End } AI05223 Note: 1. Status check of b1 (Protected Block), b3 (VPPF Invalid) and b4 (Program Error) can be made after each program operation or after a sequence. 2. If an error is found, the Status Register must be cleared before further Program/Erase operations. 3. Address 1 and Address 2 must be consecutive addresses differing only for bit A0. 50/57 M36W432T, M36W432B Figure 27. Program Suspend & Resume Flowchart and Pseudo Code Start program_suspend_command ( ) { writeToFlash (any_address, 0xB0) ; Write B0h writeToFlash (any_address, 0x70) ; /* read status register to check if program has already completed */ Write 70h do { status_register=readFlash (any_address) ; /* EF or GF must be toggled*/ Read Status Register b7 = 1 NO } while (status_register.b7== 0) ; YES b2 = 1 NO Program Complete YES Write FFh } Read data from another address Write D0h if (status_register.b2==0) /*program completed */ { writeToFlash (any_address, 0xFF) ; read_data ( ) ; /*read data from another block*/ /*The device returns to Read Array (as if program/erase suspend was not issued).*/ else { writeToFlash (any_address, 0xFF) ; read_data ( ); /*read data from another address*/ writeToFlash (any_address, 0xD0) ; /*write 0xD0 to resume program*/ } Write FFh } Program Continues Read Data AI05224 51/57 M36W432T, M36W432B Figure 28. Erase Flowchart and Pseudo Code Start erase_command ( blockToErase ) { writeToFlash (any_address, 0x20) ; Write 20h writeToFlash (blockToErase, 0xD0) ; /* only A12-A20 are significannt */ /* Memory enters read status state after the Erase Command */ Write Block Address & D0h do { status_register=readFlash (any_address) ; /* EF or GF must be toggled*/ Read Status Register b7 = 1 NO } while (status_register.b7== 0) ; YES b3 = 0 NO VPPF Invalid Error (1) YES Command Sequence Error (1) if (status_register.b3==1) /*VPPF invalid error */ error_handler ( ) ; YES b4, b5 = 1 if ( (status_register.b4==1) && (status_register.b5==1) ) /* command sequence error */ error_handler ( ) ; NO b5 = 0 NO Erase Error (1) if ( (status_register.b5==1) ) /* erase error */ error_handler ( ) ; YES b1 = 0 NO Erase to Protected Block Error (1) if (status_register.b1==1) /*program to protect block error */ error_handler ( ) ; YES End } AI05225 Note: If an error is found, the Status Register must be cleared before further Program/Erase operations. 52/57 M36W432T, M36W432B Figure 29. Erase Suspend & Resume Flowchart and Pseudo Code Start Write B0h erase_suspend_command ( ) { writeToFlash (any_address, 0xB0) ; writeToFlash (any_address, 0x70) ; /* read status register to check if erase has already completed */ Write 70h { status_register=readFlash (any_address) ; /* EF or GF must be toggled*/ Read Status Register b7 = 1 NO } while (status_register.b7== 1) ; YES b6 = 1 NO Erase Complete YES if (status_register.b6==1) /*erase completed */ { writeToFlash (any_address, 0xFF) ; read_data ( ) ; /*read data from another block*/ /*The device returns to Read Array (as if program/erase suspend was not issued).*/ Write FFh Read data from another block or Program/Protection Program or Block Protect/Unprotect/Lock Write D0h } else { read_program_data ( ); /*read or program data from another address*/ writeToFlash (any_address, 0xD0) ; /*write 0xD0 to resume erase*/ } Write FFh } Erase Continues Read Data AI05226 53/57 M36W432T, M36W432B Figure 30. Locking Operations Flowchart and Pseudo Code Start locking_operation_command (address, lock_operation) { writeToFlash (any_address, 0x60) ; /*configuration setup*/ Write 60h if (lock_operation==PROTECT) /*to protect the block*/ writeToFlash (address, 0x01) ; else if (lock_operation==UNPROTECT) /*to unprotect the block*/ writeToFlash (address, 0xD0) ; else if (lock_operation==LOCK) /*to lock the block*/ writeToFlash (address, 0x2F) ; Write 01h, D0h or 2Fh writeToFlash (any_address, 0x90) ; Write 90h Read Status Register Locking change confirmed? if (readFlash (address) ! = locking_state_expected) error_handler () ; /*Check the locking state (see Read Block Signature table )*/ NO YES writeToFlash (any_address, 0xFF) ; /*Reset to Read Array mode*/ Write FFh } End AI05227 54/57 M36W432T, M36W432B APPENDIX D. FLASH MEMORY COMMAND INTERFACE AND PROGRAM/ERASE CONTROLLER STATE Table 34. Write State Machine Current/Next, sheet 1 of 2 Current State SR bit 7 Data When Read Read Array “1” Array Command Input (and Next State) Read Array (FFh) Program Setup (10/40h) Erase Confirm (D0h) Prog/Ers Resume (D0h) Read Status (70h) Clear Status (50h) Read Array Read Sts. Read Array Read Array Erase Setup Read Array Read Status Read Array Electronic Signature Read Array Program Setup Erase Setup Read Array Read Status Read Array “1” CFI Read Array Program Setup Erase Setup Read Array Read Status Read Array Lock Setup “1” Status Lock Cmd Error “1” Status Read Array Program Setup Erase Setup Read Array Read Status Read Array Lock (complete) “1” Status Read Array Program Setup Erase Setup Read Array Read Status Read Array Prot. Prog. Setup “1” Status Protection Register Program Prot. Prog. (continue) “0” Status Protection Register Program continue Prot. Prog. (complete) “1” Status Read Status Read Array Prog. Setup “1” Status Program (continue) “0” Status Prog. Sus Status “1” Status Prog. Sus Read Array Program Suspend to Read Array Program (continue) Prog. Sus Read Array Program (continue) Prog. Sus Read Sts Prog. Sus Read Array Prog. Sus Read Array “1” Array Prog. Sus Read Array Program Suspend to Read Array Program (continue) Prog. Sus Read Array Program (continue) Prog. Sus Read Sts Prog. Sus Read Array Prog. Sus Read Elect.Sg. “1” Electronic Signature Prog. Sus Read Array Program Suspend to Read Array Program (continue) Prog. Sus Read Array Program (continue) Prog. Sus Read Sts Prog. Sus Read Array Prog. Sus Read CFI “1” CFI Prog. Sus Read Array Program Suspend to Read Array Program (continue) Prog. Sus Read Array Program (continue) Prog. Sus Read Sts Prog. Sus Read Array Program (complete) “1” Status Read Array Read Status Read Array Erase Setup “1” Status Erase Cmd.Error “1” Status Erase (continue) “0” Status Erase Sus Read Sts “1” Status Erase Sus Read Array Program Setup Erase Sus Read Array Erase (continue) Erase Sus Read Array Erase (continue) Erase Sus Erase Sus Read Sts Read Array Erase Sus Read Array “1” Array Erase Sus Read Array Program Setup Erase Sus Read Array Erase (continue) Erase Sus Read Array Erase (continue) Erase Sus Erase Sus Read Sts Read Array Erase Sus Read Elect.Sg. “1” Electronic Signature Erase Sus Read Array Program Setup Erase Sus Read Array Erase (continue) Erase Sus Read Array Erase (continue) Erase Sus Erase Sus Read Sts Read Array Erase Sus Read CFI “1” CFI Erase Sus Read Array Program Setup Erase Sus Read Array Erase (continue) Erase Sus Read Array Erase (continue) Erase Sus Erase Sus Read Sts Read Array Erase (complete) “1” Status Read Array Program Setup Erase Setup “1” Status Read Elect.Sg. “1” Read CFI Query Ers. Setup Prog/Ers Suspend (B0h) Program Setup Read Status Read Array Prog.Setup Erase Setup (10/40h) Lock (complete) Lock Command Error Read Array Program Setup Erase Setup Lock Cmd Error Lock (complete) Read Array Lock Command Error Program Prog. Sus Read Sts Program (continue) Program Setup Erase Setup Erase Command Error Read Array Program Setup Program (continue) Read Array Erase (continue) Erase Setup Erase (continue) Erase CmdError Erase (continue) Erase Command Error Read Array Read Status Erase Sus Read Sts Erase (continue) Read Array Read Status Read Array Read Array Note: Cmd = Command, Elect.Sg. = Electronic Signature, Ers = Erase, Prog. = Program, Prot = Protection, Sus = Suspend. 55/57 M36W432T, M36W432B Table 35. Write State Machine Current/Next, sheet 2 of 2 Command Input (and Next State) Current State Read Elect.Sg. (90h) Read CFI Query (98h) Lock Setup (60h) Prot. Prog. Setup (C0h) Lock Confirm (01h) Lock Down Confirm (2Fh) Read Array Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Read Array Read Status Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Read Array Read Elect.Sg. Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Read Array Read CFI Query Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Read Array Lock Setup Lock Command Error Lock (complete) Lock Cmd Error Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Lock (complete) Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Prot. Prog. Setup Protection Register Program Prot. Prog. (continue) Protection Register Program (continue) Prot. Prog. (complete) Read Elect.Sg. Read CFI Query Unlock Confirm (D0h) Lock Setup Prot. Prog. Setup Prog. Setup Program Program (continue) Program (continue) Read Array Read Array Read Array Prog. Suspend Read Status Prog. Suspend Prog. Suspend Read Elect.Sg. Read CFI Query Program Suspend Read Array Program (continue) Prog. Suspend Read Array Prog. Suspend Prog. Suspend Read Elect.Sg. Read CFI Query Program Suspend Read Array Program (continue) Prog. Suspend Read Elect.Sg. Prog. Suspend Prog. Suspend Read Elect.Sg. Read CFI Query Program Suspend Read Array Program (continue) Prog. Suspend Read CFI Prog. Suspend Prog. Suspend Read Elect.Sg. Read CFI Query Program Suspend Read Array Program (continue) Program (complete) Read Elect.Sg. Read CFIQuery Erase Setup Erase Cmd.Error Lock Setup Prot. Prog. Setup Read Array Erase (continue) Erase Command Error Read Elect.Sg. Read CFI Query Lock Setup Erase (continue) Prot. Prog. Setup Read Array Erase (continue) Erase Suspend Read Ststus Erase Suspend Erase Suspend Read Elect.Sg. Read CFI Query Lock Setup Erase Suspend Read Array Erase (continue) Erase Suspend Read Array Erase Suspend Erase Suspend Read Elect.Sg. Read CFI Query Lock Setup Erase Suspend Read Array Erase (continue) Erase Suspend Read Elect.Sg. Erase Suspend Erase Suspend Read Elect.Sg. Read CFI Query Lock Setup Erase Suspend Read Array Erase (continue) Erase Suspend Erase Suspend Erase Suspend Read CFI Query Read Elect.Sg. Read CFI Query Lock Setup Erase Suspend Read Array Erase (continue) Erase (complete) Read Elect.Sg. Read CFI Query Lock Setup Prot. Prog. Setup Note: Cmd = Command, Elect.Sg. = Electronic Signature, Prog. = Program, Prot = Protection. 56/57 Read Array M36W432T, M36W432B Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is registered trademark of STMicroelectronics All other names are the property of their respective owners. 2002 STMicroelectronics - All Rights Reserved STMicroelectronics GROUP OF COMPANIES Australia - Brazil - China - Finland - France - Germany - Hong Kong - India - Italy - Japan - Malaysia - Malta - Morocco Singapore - Spain - Sweden - Switzerland - United Kingdom - U.S.A. www.st.com 57/57