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| LH28F040SUTD-Z4 FEATURES 40-PIN TSOP 4M (512K x 8) Flash Memory TOP VIEW * 512K x 8 Bit Configuration * 5 V Write/Erase Operation (5 V VPP, 3.3 VCC) - VCC for Write/Erase at as low as 2.9 V NC1 NC1 A11 A9 A8 A13 A14 A17 WE VCC VPP A16 A15 A12 A7 A6 A5 A4 NC2 NC2 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 NC OE NC A10 BE1 BE0 DQ7 DQ6 DQ5 DQ4 DQ3 GND DQ2 DQ1 DQ0 A0 A1 A2 A3 NC 28F040SUZ4-1 * Min. 2.7 V Read Capability - 190 ns Maximum Access Time (VCC = 2.7 V) * 2 Banks Enable the Simultaneous Read/Write/Erase Operation * 32 Independently Lockable Blocks (16K) * 100,000 Erase Cycles per Block * Automated Byte Write/Block Erase - Command User Interface - Status Register * System Performance Enhancement - Erase Suspend for Read - Two-Byte Write - Bank Erase * Data Protection - Hardware Erase/Write Lockout during Power Transitions - Software Erase/Write Lockout Figure 1. TSOP Configuration * Independently Lockable for Write/Erase on Each Block (Lock Block and Protect Set/Reset) * 20 A (Maximum) ICC in CMOS Standby * State-of-the-Art 0.55 m ETOXTM Flash Technology * 40-Pin, 1.2 mm x 10 mm x 20 mm TSOP (Type I) Package 1 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory Bank1 Bank0 DQ0 - DQ7 OUTPUT BUFFER INPUT BUFFER ID REGISTER DATA QUEUE REGISTER I/O LOGIC CSR OUTPUT MULTIPLEXER REGISTER BE1 BE0 CUI OE WE DATA COMPARATOR A0 - A17 INPUT BUFFER Y-DECODER 16KB BLOCK 0 Y GATING/SENSING 16KB BLOCK 14 16KB BLOCK 15 16KB BLOCK 1 WSM ADDRESS QUEUE LATCH ... X-DECODER ... ADDRESS COUNTER ... PROGRAM/ ERASE VOLTAGE SWITCH VPP VCC GND 28F040SUZ4-2 Figure 2. LH28F040SUTD-Z4 Block Diagram 2 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 PIN DESCRIPTION SYMBOL TYPE NAME AND FUNCTION BYTE-SELECT ADDRESSES: Select a byte within one 16K block. These addresses are latched during Data Writes. BLOCK-SELECT ADDRESSES: Select 1 of 16K Erase blocks. These addresses are latched during Data Writes, Erase and Lock-Block operations. DATA INPUT/OUTPUT: Inputs data and commands during CUI write cycles. Outputs array, buffer, identifier or status data in the appropriate Read mode. Floated when the chip is de-selected or the outputs are disabled. BANK ENABLE INPUTS: Activate the device's control logic, input buffers, decoders and sense amplifiers. CE must be low to select the device. When BE 0 is low, bank0 is active. When BE 1 is low, bank1 is active. Both BE 0 and BE 1 must not be low at the same time. OUTPUT ENABLE: Gates device data through the output buffers when low. The outputs float to tri-state off when OE is high. WRITE ENABLE: Controls access to the CUI, Page Buffers, Data Queue Registers and Address Queue Latches. WE is active low, and latches both address and data (command or array) on its rising edge. ERASE/WRITE POWER SUPPLY (5.0 V 0.5 V): For erasing memory array blocks or writing bytes into the flash array. DEVICE POWER SUPPLY (3.3 V 0.3 V): Do not leave any power pins floating. GROUND FOR ALL INTERNAL CIRCUITRY: Do not leave any ground pins floating. NO CONNECTION OPEN PIN: But NC1 (between pin1 and pin2) and also NC2 (pin19 and pin20) are connected inside package. A0 - A13 A14 - A17 INPUT INPUT DQ0 - DQ7 INPUT/OUTPUT BE 0, BE 1 INPUT OE INPUT WE INPUT VPP VCC GND NC NC1, NC2 SUPPLY SUPPLY SUPPLY INTRODUCTION Sharp's LH28F040SUTD-Z4 4M Flash Memory is a revolutionary architecture which enables the design of truly mobile, high performance, personal computing and communication products. With innovative capabilities, 3.3 V low power operation and very high read/write performance, the LH28040SU-Z4 is also the ideal choice for designing embedded mass storage flash memory systems. The LH28F040SUTD-Z4 is a very high density, highest performance non-volatile read/write solution for solidstate storage applications. Its independently lockable 32 symmetrical blocked architecture (16K each) extended cycling, low power operation, very fast write and read performance and selective block locking provide a highly flexible memory component suitable for high density memory cards, Resident Flash Arrays and PCMCIA-ATA Flash Drives. The LH28F040SUTD-Z4's 5.0 V/3.3 V power supply operation enables the design of memory cards which can be read in 3.3 V system and written in 5.0 V/3.3 V systems. Its x8 architecture allows the optimization of memory to processor interface. The flexible block locking option enables bundling of executable application software in a Resident Flash Array or memory card. Manufactured on Sharp's 0.55 m ETOXTM process technology, the LH28F040SUTDZ4 is the most cost-effective, high-density 3.3 V flash memory. LH28F040SUTD-Z4 divides 4M into two areas. Each area can read/write/erase independently. For example, while you write and erase on one area, you can simultaneously read the data from the other area. This enables users to reduce the number of components in their system. 3 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory DESCRIPTION The LH28F040SUTD-Z4 is a high performance 4M (4,194,304 bit) block erasable non-volatile random access memory organized as 256K x 8 x 2 banks. The LH28F040SUTD-Z4 includes thirty-two 16K (16,384) blocks. A chip memory map is shown in Figure 3. The two banks, the one selected by BE0 (bank0) and the other selected by BE1 (bank1) can be controlled independently. For example, while erase the data in bank0, the data in bank1 can be read out. The implementation of a new architecture, with many enhanced features, will improve the device operating characteristics and results in greater product reliability and ease of use. Among the significant enhancements of the LH28F040SUTD-Z4: LH28F040SUTD-Z4 allows to erase all unlocked blocks for each bank selected by BE0 or BE1. It is desirable in case of which you have to implement Erase operation maximum 32 times. LH28F040SUTD-Z4 enables Two-Byte serial Write which is operated by three times command input. This feature can improve system write performance by up to typically 17 s per byte. All operations are started by a sequence of Write commands to the device. Status Register (described in detail later) provide information on the progress of the requested operation. Same as the LH28F008SA, LH28F040SUTD-Z4 requires an operation to complete before the next operation can be requested, also it allows to suspend block erase to read data from any other block, and allow to resume erase operation. The LH28F040SUTD-Z4 provides user-selectable block locking to protect code or data such as Device Drivers, PCMCIA card information, ROM-Executable OS or Application Code. Each block has an associated nonvolatile lock-bit which determines the lock status of the block. In addition, the LH28F040SUTD-Z4 has a software controlled master Write Protect circuit which prevents any modifications to memory blocks whose lockbits are set. When the device power-up, Write Protect Set/ Confirm command must be written both in bank0 and bank1. Otherwise, all lock bits in the device remain being locked, can't perform the Write to each block and single Block Erase. Write Protect Set/Confirm command must be written to reflect the actual lock status. However, when the device power-on, Erase All Unlocked Blocks can be used. If used, Erase is performed with reflecting actual lock status, and after that Write and Block Erase can be used. The LH28F040SUTD-Z4 contains Status Register to accomplish various functions: * 3 V Read, 5 V Write/Erase Operation (5 V VPP, 3 V VCC) * Low Power Capability (2.7 V VCC Read) * Improved Write/Erase Performance (Two-Byte Serial Write, Bank Erase) * Dedicated Block Write/Erase Protection * Command-Controlled Memory Protection Set/Reset Capability The LH28F040SUTD-Z4 will be available in a 40-pin, 1.2 mm thick x 10 mm x 20 mm TSOP (Type I) package. This form factor and pinout allow for very high board layout densities. A Command User Interface (CUI) serves as the system interface between the microprocessor or microcontroller and the internal memory operation. Internal Algorithm Automation allows Byte Writes and Block Erase operations to be executed using a TwoWrite command sequence to the CUI in the same way as the LH28F008SA 8M Flash memory. A Superset of commands have been added to the basic LH28F008SA command-set to achieve higher write performance and provide additional capabilities. These new commands and features include: * A Compatible Status Register (CSR) which is 100% compatible with the LH28F008SA Flash memory's Status Register. This register, when used alone, provides a straightforward upgrade capability to the LH28F040SUTD-Z4 from a LH28F008SA based design. The LH28F040SUTD-Z4 is specified for a maximum access time of 150 ns (tACC) at 3.3 V operation (3.0 to 3.6 V) over the commercial temperature range (-20 to +70C). A corresponding maximum access time of 190 ns (tACC) at 2.7 V (-20 to +70C) is achieved for reduced power consumption applications. * * * * Software Locking of Memory Blocks Memory Protection Set/Reset Capability Two-Byte Serial Writes in 8-bit Systems Bank Erase All Unlocked Blocks Writing of memory data is performed typically within 20 s. A Block Erase operation erases one of the 32 blocks in typically 1.5 seconds, independent of the other blocks. 4 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 The LH28F040SUTD-Z4 incorporates an Automatic Power Saving (APS) feature which substantially reduces the active current when the device is in static mode of operation (addresses not switching). In APS mode, the typical ICC current is 2 mA at 3.3 V. A bank reset mode of operation is enabled when whole BE0 (or BE1), WE and OE hold low more than 5 s. In this mode, all operations are aborted, the internal control circuit is reset and CSR register is cleared. When the device power up, this bank reset operation must be executed for each bank to initialize the control circuit. If BEX (either BE0 or BE1 which is in low state) and or WE and or OE and or goes high, chip reset mode will be finished. It needs more than 750 ns from one of the BEX, WE or OE goes high until output data are valid. It is impossible to reset the whole chip at once, the bank reset must be executed separately for bank0 and bank1. A CMOS Standby mode of operation is enabled when BEX transitions high with all input control pins at CMOS levels. In this mode, the device draws an ICC standby current of 20 A. Please do not execute reprogramming 0 for the bit which has already been programmed 0. Overwrite operation may generate unerasable bit. In case of reprogramming 0 to the data which has been programmed 1. * Program 0 for the bit in which you want to change data from 1 to 0. * Program 1 for the bit which has already been programmed 0. For example, changing data from 10111101 to 10111100 requires 11111110 programming. MEMORY MAP Bank0 (BE0 = Low) 3FFFFH 3C000H 3BFFFH 38000H 37FFFH 34000H 33FFFH 30000H 2FFFFH 2C000H 2BFFFH 28000H 27FFFH 24000H 23FFFH 20000H 1FFFFH 1C000H 1BFFFH 18000H 17FFFH 14000H 13FFFH 10000H 0FFFFH 0C000H 0BFFFH 08000H 07FFFH 04000H 03FFFH 00000H Bank1 (BE1 = Low) 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 3FFFFH 3C000H 3BFFFH 38000H 37FFFH 34000H 33FFFH 30000H 2FFFFH 2C000H 2BFFFH 28000H 27FFFH 24000H 23FFFH 20000H 1FFFFH 1C000H 1BFFFH 18000H 17FFFH 14000H 13FFFH 10000H 0FFFFH 0C000H 0BFFFH 08000H 07FFFH 04000H 03FFFH 00000H 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 16KB BLOCK 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 28F040SUZ4-3 Figure 3. Memory Map 5 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory BUS OPERATIONS, COMMANDS AND STATUS REGISTER DEFINITIONS Bus Operations MODE BE 0 Bank 0 VIL VIH X VIH Bank 0 VIL VIH VIL VIH VIL VIH BE 1 VIH VIL X VIH VIH VIL VIH VIL VIH VIL OE WE A0 DQ0 - DQ7 NOTE Read Bank 1 Output Disable Standby Manufacturer ID Bank 1 Bank 0 Device ID Bank 1 Bank 0 Write Bank1 VIL VIH X VIL VIH VIH X VIH X X X VIL DOUT High-Z High-Z B0H 1 1 1 2 VIL VIH VIH 31H 2 VIH VIL X DIN 1, 3 NOTES: 1. X can be VIH or VIL for address or control pins, which is either VOL or VOH. 2. A0 at VIL provide manufacturer ID codes. A0 at VIH provide device ID codes. All other addresses are set to zero. 3. Commands for different Erase operations, Data Write operations, and Lock-Block operations can only be successfully completed when VPP = VPPH. 4. Both BE0 and BE1 must not be low at the same time. 6 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 LH28F008SA-Compatible Mode Command Bus Definitions Following is the commands to be applied to each bank. FIRST BUS CYCLE COMMAND OPER. ADDRESS DATA OPER. ADDRESS DATA SECOND BUS CYCLE NOTE Read Array Intelligent Identifier Read Compatible Status Register Clear Status Register Byte Write Alternate Byte Write Block Erase/Confirm Erase Suspend/Resume ADDRESS AA = Array Address BA = Block Address IA = Identifier Address WA = Write Address X = Don't Care Write Write Write Write Write Write Write Write DATA AD = Array Data CSRD = CSR Data ID = Identifier Data WD = Write Data X X X X X X X X FFH 90H 70H 50H 40H 10H 20H B0H Read Read Read AA IA X AD ID CSRD 1 2 3 Write Write Write Write WA WA BA X WD WD D0H D0H 4 4 NOTES: 1. Following the intelligent identifier command, two Read operations access the manufacturer and device signature codes. 2. The CSR is automatically available after device enters Data Write, Erase or Suspend operations. 3. Clears CSR.3, CSR.4, and CSR.5. See Status register definitions. 4. While device performs Block Erase, if you issue Erase Suspend command (B0H), be sure to confirm ESS (Erase-Suspend-Status) is set to 1 on compatible status register. In the case, ESS bit was not set to 1, also completed the Erase (ESS = 0, WSMS = 1), be sure to issue Resume command (D0H) after completed next Erase command. Beside, when the Erase Suspend command is issued, while the device is not in Erase, be sure to issue Resume command (D0H) after the next erase complete. 7 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 Performance Enhancement Command Bus Definitions Following is the commands to be applied to each bank. COMMAND FIRST BUS CYCLE SECOND BUS CYCLE DATA THIRD BUS CYCLE OPER. ADD. DATA NOTE OPER. ADD. DATA OPER. ADD. Protect Set/Confirm Protect Reset/Confirm Lock Block/Confirm Two-Byte Write ADDRESS BA = Block Address WA = Write Address X = Don't Care Write Write Write Write X X X X X 57H 47H 77H A7H FBH Write Write Write Write Write 0FFH 0FFH BA X A10 D0H D0H D0H D0H WD (L, H) Write WA 1, 2, 6 3, 6 1, 2, 4 1, 2 WD (H, L) 1, 2, 5 Bank Erase All Unlocked Blocks Write DATA AD = Array Data WD (L, H) = Write Data (Low, High) WD (H, L) = Write Data (High, Low) NOTES: 1. After initial device power-up, or reset is completed, the block lock status bit default to the locked state independent of the data in the corresponding lock bits. In order to upload the lock bit status, it requires to write Protect Set/Confirm command. 2. To reflect the actual lock-bit status, the Protect Set/Confirm command must be written after Lock Block/Confirm command. 3. When Protect Reset/Confirm command is written, all blocks can be written and erased regardless of the state of the lock-bits. 4. The Lock Block/Confirm command must be written after Protect Reset/Confirm command was written. 5. A0 is automatically complemented to load second byte of data A0 value determines which WD is supplied first: A0 = 0 looks at the WDL, A0 = 1 looks at the WDH. 6. Second bus cycle address of Protect Set/Confirm and Protect Reset/Confirm command is 0FFH. Specifically A9 - A8 = 0, A7 - A0 = 1, others are don't care. Compatible Status Register Following is the commands to be applied to each bank. WSMS 7 ESS 6 ES 5 DWS 4 VPPS 3 R 2 R 1 R 0 CSR.7 = WRITE STATE MACHINE STATUS (WSMS) 1 = Ready 2 = Busy CSR.6 = ERASE-SUSPEND STATUS (ESS) 1 = Erase Suspended 0 = Erase in Progress/Completed CSR.5 = ERASE STATUS (ES) 1 = Error in Block Erasure 0 = Successful Block Erase CSR.4 = DATA-WRITE STATUS (DWS) 1 = Error in Data Write 0 = Data Write Successful CSR.3 = VPP STATUS (VPPS) 1 = VPP Low Detect, Operation Abort 0 = VPP OK NOTES: 1. RY/BY output or WSMS bit must be checked to determine completion of an operation (Erase Suspend, Erase or Data Write) before the appropriate Status bit (ESS, ES or DWS) is checked for success. 2. If DWS and ES are set to `1' during an erase attempt, an improper command sequence was entered. Clear the CSR and attempt the operation again. 3. The VPPS bit, unlike an A/D converter, does not provide continuous indication of VPP level. The WSM interrogates VPP's level only after the Data-Write or Erase command sequences have been entered, and informs the system if VPP has not been switched on. VPPS is not guaranteed to report accurate feedback between VPPL and VPPH. 4. CSR.2 - CSR.0 = Reserved for further enhancements. These bits are reserved for future use and should be masked out when polling the CSR. 8 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 4M DUAL WORK FLASH MEMORY SOFTWARE ALGORITHMS Overview With the advanced Command User Interface, its Performance Enhancement commands and Status Registers, the software code required to perform a given operation may become more intensive but it will result in much higher write/erase performance compared with current flash memory architectures. The software flowcharts describing how a given operation proceeds are shown here. Figures 4 through 6 depict flowcharts using the 2nd generation flash device in the LH28F008SA-compatible mode. Figures 7 through 12 depict flowcharts using the 2nd generation flash device's performance enhancement commands mode. When the device power-up or reset is completed, Set Write Protect command must be written to both the bank selected by BE0 and BE1 in order to reflect actual block lock status. When the device power-up or reset is completed, all blocks come up locked. Therefore, Byte Write, Two Byte Serial Write and Block Erase can not be performed in each block. However, at that time, Erase All Unlocked Block is performed normally, if used, and reflect actual lock status, also the unlocked block data is erased. When the device power-up or reset is completed, Set Write Protect command must be written to reflect actual block lock status. Reset Write Protect command must be written before Write Block Lock command. To reflect actual block lock status, Set Write Protect command is succeeded. The Compatible Status Register (CSR) used to determine which blocks are locked. In order to see Lock Status of certain block, a Byte Write command (WA = Block Address, WD = FHH) is written to the CUI, after issuing Set Write Protect command. If CSR.7, CSR.5 and CSR.4 (WSMS, ES and DWS) are set to `1's, the block is locked. If CSR.7 is set to `1', the block is not locked. Reset Write Protect command enables Write/Erase operation to each block. In the case of Block Erase is performed, the block lock information is also erased. Block Lock command and Set Write Protect command must be written to prohibit Write/Erase operation to each block. There are unassigned commands. It is not recommended that the customer use any command other than the valid commands specified in "Command Bus Definitions". Sharp reserved the right to redefine these codes for future functions. 9 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory START BUS OPERATION COMMAND COMMENTS WRITE 40H or 10H Write Write Byte Write D = 40H or 10H A=X D = WD A = WA Q = CSRD Toggle BE0, BE1 or OE to update CSRD. A=X Check CSR.7 1 = WSM Ready 0 = WSM Busy WRITE DATA/ADDRESS Read READ COMPATIBLE STATUS REGISTER Standby 0 CSR.7 = 1 CSR FULL STATUS CHECK IF DESIRED Repeat for subsequent Byte Writes. CSR Full Status Check can be done after each Byte Write, or after a sequence of Byte Writes. Write FFH after the last operation to reset device to read array mode. See Command Bus Cycle notes for description of codes. OPERATION COMPLETE CSR FULL STATUS CHECK PROCEDURE READ CSRD (see above) BUS OPERATION COMMAND COMMENTS Standby 0 DATA WRITE SUCCESSFUL Check CSR.4, 5 1 = Data Write Unsuccessful 0 = Data Write Successful Check CSR.3 1 = VPP Low Detect 0 = VPP OK CSR.4, 5 = Standby 1 CSR.3 = 1 VPP LOW DETECT CSR.3, 4, 5 should be cleared, if set, before further attempts are initiated. 0 CLEAR CSRD RETRY/ERROR RECOVERY 28F040SUZ4-4 Figure 4. Byte Writes with Compatible Status Register 10 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 START BUS OPERATION COMMAND COMMENTS WRITE 20H Write Write Block Erase Confirm D = 20H A=X D = D0H A = BA Q = CSRD Toggle BE0, BE1 or OE to update CSRD. A=X Check CSR.7 1 = WSM Ready 0 = WSM Busy WRITE D0H AND BLOCK ADDRESS Read READ COMPATIBLE STATUS REGISTER SUSPEND NO ERASE LOOP SUSPEND YES ERASE Standby CSR.7 = 0 1 CSR FULL STATUS CHECK IF DESIRED Repeat for subsequent Block Erasures. CSR Full Status Check can be done after each Block Erase, or after a sequence of Block Erasures. Write FFH after the last operation to reset device to read array mode. See Command Bus Cycle notes for description of codes. OPERATION COMPLETE CSR FULL STATUS CHECK PROCEDURE READ CSRD (see above) BUS OPERATION COMMAND COMMENTS Standby 0 ERASE SUCCESSFUL CSR.4, 5 = Check CSR.4, 5 1 = Erase Error 0 = Erase Successful Both 1 = Command Sequence Error Check CSR.3 1 = VPP Low Detect 0 = VPP OK 1 Standby CSR.3 = 1 VPP LOW DETECT 0 CLEAR CSRD RETRY/ERROR RECOVERY (NOTE) CSR.3, 4, 5 should be cleared, if set, before further attempts are initiated. NOTE: If CSR.3 (VPPS) is set to '1', after clearing CSR.3/4/5, 1. Issue Reset WP command. 2. Retry Single Block Erase command. 3. Set WP command is issued, if necessary. If CSR.3 (VPPS) is set to '0', after clearing CSR.3/4/5, 1. Retry Single Block Erase command. Where power off or chip reset during erase operation, 1. Clear CSR.3/4/5 and issue Reset WP command, 2. Retry Single Block Erase command. 3. Set WP command is issued, if necessary. 28F040SUZ4-5 Figure 5. Block Erase with Compatible Status Register 11 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory START BUS OPERATION COMMAND COMMENTS WRITE B0H Write Read Erase Suspend D = B0H A=X Q = CSRD Toggle BE0, BE1 or OE to update CSRD. A=X Check CSR.7 1 = WSM Ready 0 = WSM Busy Check CSR.6 1 = Erase Suspended 0 = Erase Completed READ COMPATIBLE STATUS REGISTER Standby CSR.7 = 0 1 Standby CSR.6 = 0 Write ERASE COMPLETED Read Array D = FFH A=X Q = AD Read must be from block other than the one suspended. 1 WRITE FFH Read Write READ ARRAY DATA Erase Resume D = D0H A=X See Command Bus Cycle notes for description of codes. DONE READING NO YES WRITE D0H WRITE FFH ERASE RESUMED READ ARRAY DATA 28F040SUZ4-6 Figure 6. Erase Suspend to Read Array with Compatible Status Register 12 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 START BUS COMMAND OPERATION COMMENTS READ COMPATIBLE STATUS REGISTER Read Q = CSRD to update CSRD. 1 = WSM Ready 0 = WSM Busy Toggle BE0, BE1 or OE CSR.7 = 0 Write Read Reset Write Protect After Write D = 47H A = X, Write D = D0H A = 0FFH Q = CSRD to update CSRD. 1 = WSM Ready 0 = WSM Busy 1 RESET WP Toggle BE0, BE1 or OE READ COMPATIBLE STATUS REGISTER Write Write Lock Block Confirm D = 77H A=X D = D0H A = BA Q = CSRD Toggle BE0, BE1, or OE to update CSRD. 1 = WSM Ready 0 = WSM Busy CSR.7 = 0 Read 1 WRITE 77H Write WRITE D0H AND BLOCK ADDRESS Set Write Protect After Write D = 57H A = X, Write D = D0H A = 0FFH READ COMPATIBLE STATUS REGISTER NOTE: See CSR Full Status Check for Data-Write operation. If CSR.4, 5 is set, as it is command sequence error, should be cleared before further attempts are initiated. Write FFH after the last operation to reset device to read array mode. See Command Bus Definitions for description of codes. CSR.7 = 0 1 CSR.4, 5 = 1 (NOTE) 0 LOCK YES ANOTHER BLOCK NO SET WP OPERATION COMPLETE 28F040SUZ4-7 Figure 7. Block Locking Scheme 13 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory START START RESET WP (NOTE 1) RESET WP (NOTE 1) ERASE BLOCK (NOTE 2) WRITE MORE DATA TO BLOCK (NOTE 4) SET WP (NOTE 3) SET WP (NOTE 3) WRITE NEW DATA TO BLOCK (NOTE 4) OPERATION COMPLETE FLOW TO ADD DATA RELOCK BLOCK (NOTE 5) OPERATION COMPLETE FLOW TO REWRITE DATA NOTES: 1. Use Reset-Write-Protect flowchart. Enable Write/Erase operation to all blocks. 2. Use Block-Erase flowchart. Erasing a block clears any previously established lockout for that block. 3. Use Set-Write-Protect flowchart. This step re-implements protection to locked blocks. 4. Use Byte-Write or 2-Byte-Write flowchart sequences to write data. 5. Use Block-Lock flowchart to write lock bit if desired. 28F040SUZ4-8 Figure 8. Updating Data in a Locked Block 14 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 START BUS COMMAND OPERATION COMMENTS READ COMPATIBLE STATUS REGISTER Read Q = CSRD Toggle BE0, BE1 or OE to update CSRD. 1 = WSM Ready 0 = WSM Busy Write Write 2-Byte Write D = FBH A=X D = WD A0 = 0 loads low byte of Data Register. A0 = 1 loads high byte of Data Register. Other Addresses = X D = WD A = WA Internally, A0 is automatically complemented to load the alternate byte location of the Data Register. Q = CSRD to update CSRD. 1 = WSM Ready 0 = WSM Busy CSR.7 = 0 1 WRITE FBH WRITE DATA/A0 Write WRITE DATA/ADDRESS READ COMPATIBLE STATUS REGISTER Read Toggle BE0, BE1 or OE CSR.7 = 0 1 CSR.4, 5 = 1 (NOTE) NOTE: If CSR.4, 5 is set, as it is command sequence error, should be cleared before further attempts are initiated. CSR Full Status Check can be done after each 2-Byte Write, or after a sequence of 2-Byte Writes. Write FFH after the last operation to reset device to read array mode. See Command Bus Cycle notes for description of codes. 0 ANOTHER 2-BYTE WRITE NO YES OPERATION COMPLETE 28F040SUZ4-9 Figure 9. Two-Byte Serial Writes with Compatible Status Registers 15 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory START (NOTE) BUS OPERATION COMMAND COMMENTS Write WRITE A7H Erase All Unlocked Blocks Confirm D = A7H A=X D = D0H A=X Q = CSRD Toggle BE0, BE1 or OE to update CSRD. A=X Check CSR.7 1 = WSM Ready 0 = WSM Busy WRITE D0H Write Read READ COMPATIBLE STATUS REGISTER SUSPEND NO ERASE LOOP 0 YES Standby CSR.7 = SUSPEND ERASE 1 CSR FULL STATUS CHECK IF DESIRED CSR Full Status Check can be done after Erase All Unlocked Block, or after a sequence of Erasures. Write FFH after the last operation to reset device to read array mode. See Command Bus Cycle notes for description of codes. NOTE: Where power off or reset during erase operation, 1. Clear CSR.3/4/5 and issue Reset WP command, 2. Retry Erase All Unlocked Block Erase command to erase all blocks, or issue Single Block Erase to erase all of the unlocked blocks in sequence. 3. Set WP command is issued, if necessary. OPERATION COMPLETE CSR FULL STATUS CHECK PROCEDURE READ CSRD (see above) BUS OPERATION COMMAND COMMENTS Standby CSR.4, 5 = 0 ERASE SUCCESSFUL Check CSR.4, 5 1 = Erase Error 0 = Erase Successful Both 1 = Command Sequence Error Check CSR.3 1 = VPP Low Detect 0 = VPP OK Standby 1 CSR.3 = 1 VPP LOW DETECT CSR.3, 4, 5 should be cleared, if set, before further attempts are initiated. NOTE: If CSR.3 (VPPS) is set to '1', after clearing CSR.3/4/5, 1. Issue Reset WP command, 2. Retry Erase All Unlocked Block Erase command to erase all blocks, or issue Single Block Erase to erase all of the unlocked blocks in sequence. 3. Set WP command is issued, if necessary. If CSR.3 (VPPS) is set to '0', after clearing CSR.3/4/5, 1. Retry Erase All Unlocked Block Erase command. 0 CLEAR CSRD RETRY/ERROR RECOVERY (NOTE) 28F040SUZ4-10 Figure 10. Bank Erase All Unlocked Blocks with Compatible Status Registers 16 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 START BUS COMMAND OPERATION COMMENTS Read READ COMPATIBLE STATUS REGISTER Check CSR.7 1 = WSM Ready 0 = WSM Busy Set Write Protect Set Confirm D = 57H A=X D = D0H A = 0FFH (A9 - A8 = 0, A7 - A0 = 1, Others = X) Check CSR.7 1 = WSM Ready 0 = WSM Busy Check CSR.4, 5 1 = Unsuccesful 0 = Successful Write Write CSR.7 = 0 1 Read WRITE 57H Read WRITE CONFIRM DATA/ADDRESS READ COMPATIBLE STATUS REGISTER CSR.7 = 0 NOTE: If CSR.4, 5 is set, as it is command sequence error, should be cleared before further attempts are initiated. Upon device power-up or reset is complete, Set Write Protect command must be written to reflect the actual lock-bit status. Write FFH after the last operation to reset device to Read Array Mode. See Command Bus Cycle notes for description of codes. 1 CSR.4, 5 = 1 (NOTE) 0 OPERATION COMPLETE 28F040SUZ4-11 Figure 11. Set Write Protect 17 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory START BUS COMMAND OPERATION COMMENTS Read READ COMPATIBLE STATUS REGISTER Check CSR.7 1 = WSM Ready 0 = WSM Busy Reset Write Protect Reset Confirm D = 47H A=X D = D0H A = 0FFH (A9 - A8 = 0, A7 - A0 = 1, Others = X) Check CSR.7 1 = WSM Ready 0 = WSM Busy Check CSR.4, 5 1 = Unsuccesful 0 = Successful Write Write CSR.7 = 0 1 Read WRITE 47H Read WRITE CONFIRM DATA/ADDRESS READ COMPATIBLE STATUS REGISTER CSR.7 = 0 NOTE: If CSR.4, 5 is set, as it is command sequence error, should be cleared before further attempts are initiated. Reset Write Protect command enables Write/Erase operation to all blocks. Write FFH after the last operation to reset device to Read Array Mode. See Command Bus Cycle notes for description of codes. 1 CSR.4, 5 = 1 (NOTE) 0 OPERATION COMPLETE 28F040SUZ4-12 Figure 12. Reset Write Protect 18 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 ELECTRICAL SPECIFICATIONS Absolute Maximum Ratings* Temperature under bias ...................... -20C to +80C Storage temperature ......................... -65C to +125C SYMBOL PARAMETER MIN. *WARNING: Stressing the device beyond the "Absolute Maximum Ratings" may cause permanent damage. These are stress ratings only. Operation beyond the "Operating Conditions" is not recommended and extended exposure beyond the "Operating Conditions" may affect device reliability. MAX. UNITS TEST CONDITIONS NOTE TA VCC VPP V I IOUT Operating Temperature, Commercial VCC with Respect to GND VPP Supply Voltage with Respect to GND Voltage on any Pin (Except VCC, VPP) with Respect to GND Current into any Non-Supply Pin Output Short Circuit Current 0 -0.2 -0.2 -0.5 70.0 7.0 7.0 VCC + 0.5 30 100.0 C V V V mA mA Ambient Temperature 1 2 2 2 3 NOTES: 1. Operating temperature is for commercial product defined by this specification. 2. Minimum DC voltage is -0.5 V on input/output pins. During transitions, this level may undershoot to -2.0 V for periods < 20 ns. Maximum DC voltage on input/output pins is VCC + 0.5 V which, during transitions, may overshoot to VCC + 2.0 V for periods < 20 ns. 3. Output shorted for no more than one second. No more than one output shorted at a time. Capacitance SYMBOL PARAMETER TYP. MAX. UNITS TEST CONDITIONS NOTE CIN COUT CLOAD Capacitance Looking into an Address/Control Pin Capacitance Looking into an Output Pin Load Capacitance Driven by Outputs for Timing Specifications Equivalent Testing Load Circuit VCC 10% 14 18 20 24 50 2.5 pF pF pF ns TA = 25C, f = 1.0 MHz TA = 25C, f = 1.0 MHz For VCC = 3.3 V 0.3 V 50 transmission line delay 1, 2 1 1 NOTE: 1. Sampled, not 100% tested. 2. BE0 and BE1 have half the value of this. 19 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory Timing Nomenclature For 3.3 V systems use 1.5 V cross point definitions. Each timing parameter consists of 5 characters. Some common examples are defined below: tCE tOE tAS tDH tELQV tGLQV time (t) from BE (E) going low (L) to the outputs (Q) becoming valid (V) time (t) from OE (G) going low (L) to the outputs (Q) becoming valid (V) time (t) from address (A) valid (V) to the outputs (Q) becoming valid (V) tACC tAVQV tAVWH time (t) from address (A) valid (V) to WE (W) going high (H) tWHDX time (t) from WE (W) going high (H) to when the data (D) can become undefined (X) PIN CHARACTERS PIN STATES A D Q E G W V 3V Address Inputs Data Inputs Data Outputs BE (Byte Enable)1 OE (Output Enable) WE (Write Enable) Any Voltage Level VCC at 3.0 V Min. H L V X Z High Low Valid Driven, but not necessarily valid High Impedance NOTE: 1. BEX means either BE0 or BE1. 3.0 INPUT 1.5 0.0 TEST POINTS 1.5 OUTPUT FROM OUTPUT UNDER TEST 2.5 ns OF 50 TRANSMISSION LINE TEST POINT NOTE: AC test inputs are driven at 3.0 V for a Logic '1' and 0.0 V for a Logic '0'. Input timing begins and output timing ends at 1.5 V. Input rise and fall times (10% to 90%) < 10 ns. 28F040SUZ4-13 TOTAL CAPACITANCE = 50 pF 28F040SUZ4-14 Figure 13. Transient Input/Output Reference Waveform (VCC = 3.3 V) Figure 14. Transient Equivalent Testing Load Circuit (VCC = 3.3 V) 20 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 DC Characteristics VCC = 3.3 V 0.3 V, TA = -20C to +70C Following is the current consumption of one bank. For the current consumption of one device total, please refer to Note 5. SYMBOL PARAMETER TYP. MIN. MAX. UNITS TEST CONDITIONS NOTE IIL ILO Input Load Current Output Leakage Current 5 2 20 10 4 A A A mA VCC = VCC MAX., VIN = VCC or GND VCC = VCC MAX., VIN = VCC or GND VCC = VCC MAX., BE 0, BE 1 = VCC 0.2 V VCC = VCC MAX., BE 0, BE 1 = VIH VCC = VCC MAX., CMOS: BE 0, BE 1 = GND 0.2 V Inputs = GND 0.2 V or VCC 0.2 V, TTL: BE 0, BE 1 = VIL, Inputs = VIL or VIH, f = 10 MHz, IOUT = 0 mA VCC = VCC MAX., CMOS: BE 0, BE 1 = GND 0.2 V Inputs = GND 0.2 V or VCC 0.2 V, TTL: BE 0, BE 1 = VIL, Inputs = VIL or VIH, f = 5 MHz, IOUT = 0 mA Byte/Two-Byte Serial Write in Progress Block Erase in Progress BE 0, BE 1 = VIH Block Erase Suspended VPP VCC 1 1 ICCS VCC Standby Current 0.3 1, 4, 5 ICCR1 VCC Read Current (10 MHz Operation) 35 mA 1, 3, 4, 5 ICCR2 VCC Read Current (5 MHz Operation) 10 20 mA 1, 3, 4, 5 ICCW ICCE ICCES IPPS VCC Write Current VCC Block Erase Current VCC Erase Suspend Current VPP Standby Current 8 6 3 1 12 12 6 10 mA mA mA A 1, 5 1, 5 1, 2, 5 1, 5 21 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory DC Characteristics (Continued) VCC = 3.3 V 0.3 V, TA = -20C to +70C SYMBOL PARAMETER TYPE MIN. MAX. UNITS TEST CONDITIONS NOTE IPPR IPPW IPPE IPPES VIL VIH VOL VOH1 VPP Read Current VPP Write Current VPP Erase Current VPP Erase Suspend Current Input Low Voltage Input High Voltage Output Low Voltage 65 15 20 65 -0.3 2.0 200 35 40 200 0.8 VCC + 0.3 0.4 2.4 A mA mA A V V V V V VPP > VCC VPP = VPPH, Byte/Two-Byte Serial Write in Progress VPP = VPPH, Block Erase in Progress VPP = VPPH, Block Erase Suspended 1, 5 1, 5 1, 5 1, 5 VCC = VCC MIN. and IOL = 4 mA IOH = -2 mA VCC = VCC MIN. IOH = 100 A VCC = VCC MIN. Output High Voltage VOH 2 VCC - 0.2 VPP during Normal Operations VPP during Write/Erase Operations VCC Erase/Write Lock Voltage 5.0 0.0 4.5 1.4 5.5 5.5 VPPL VPPH VLKO V V V NOTES: 1. All currents are in RMS unless otherwise noted. Typical values at VCC = 3.3 V, VPP = 5.0 V, T = 25C. 2. ICCES is specified with the device de-selected. If the device is read while in erase suspend mode, current draw is the sum of ICCES and ICCR. 3. Automatic Power Saving (APS) reduces ICCR to less than 2 mA in Static operation. 4. CMOS inputs are either VCC 0.2 V or GND 0.2 V. TTL Inputs are either VIL or VIH. 5. These are the values of the current which is consumed within one bank area. The value for the bank0 and bank1 should be added in order to calculate the value for the whole chip. If the bank0 is in write state and bank1 is in read state, the I CC = ICCW + ICCR. If both banks are in standby mode, the value for the device is 2 times the value in the above table. 22 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 AC Characteristics - Read Only Operations1 VCC = 3.3 V 0.3 V, TA = -20C to +70C SYMBOL PARAMETER MIN. MAX. UNITS NOTE tAVAV tAVGL tAVQV tELQV tGLQV tELQX tEHQZ tGLQX tGHQZ tOH Read Cycle Time Address Setup to OE Going Low Address to Output Delay BE 0, BE 1 to Output Delay OE to Output Delay BE 0, BE 1 to Output in Low Z BE 0, BE 1 to Output in High Z OE to Output in Low Z OE to Output in High Z Output Hold from Address, BE 0, BE 1 or OE change, whichever occurs first 150 0 150 150 50 0 55 0 40 0 ns ns ns ns ns ns ns ns ns ns 2 2 3 3 3 3 3 3 AC Characteristics - Read Only Operations1 (Continuted) VCC = 2.85 V 0.15 V, TA = -20C to +70C SYMBOL PARAMETER MIN. MAX. UNITS NOTE tAVAV tAVGL tAVQV tELQV tGLQV tELQX tEHQZ tGLQX tGHQZ tOH Read Cycle Time Address Setup to OE Going Low Address to Output Delay BE 0, BE 1 to Output Delay OE to Output Delay BE 0, BE 1 to Output in Low Z BE 0, BE 1 to Output in High Z OE to Output in Low Z OE to Output in High Z Output Hold from Address, BE 0, BE 1 or OE change, whichever occurs first 190 0 190 190 65 0 70 0 55 0 ns ns ns ns ns ns ns ns ns ns 2 2 3 3 3 3 3 3 NOTES: 1. See AC Input/Output Reference Waveforms for timing measurements, Figure 4. 2. OE may be delayed up to tELQV - tGLQV after the falling edge of BE0, BE1 without impact on tELQV. 3. Sampled, not 100% tested. 23 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory VCC POWER-UP STANDBY DEVICE AND ADDRESS SELECTION OUTPUTS ENABLED DATA VALID ADDRESSES (A) VIH VIL ADDRESSES STABLE tAVAV ... ... VCC STANDBY POWER-DOWN BEX (E) (NOTE) VIH VIL ... tEHQZ OE (G) VIH VIL tAVGL VIH VIL tGLQV tELQV tGLQX tELQX VOH VOL tAVQV 3.3 V HIGH-Z tOH ... tGHQZ ... WE (W) ... VALID OUTPUT DATA (D/Q) HIGH-Z ... VCC GND NOTE: BEX means either BE0 or BE1 28F040SUZ4-15 Figure 15. Read Timing Waveforms 24 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 POWER-UP AND RESET TIMINGS VCC POWER UP tELRS tEHRS BEX (E) (NOTE) OE (G) tGLRS tGHRS WE (W) 3.3 V 3.0 V VCC (3.5 V) 0V tWLPL 3.3 V ADDRESS (A) VALID tAVQV DATA (Q) tPHQV NOTE: BEX means either BE0 or BE1 VALID 3.3 V OUTPUTS 28F040SUZ4-16 Figure 16. VCC Power-Up and RP Reset Waveforms SYMBOL PARAMETER MIN. MAX. UNITS NOTE tWLPL tAVQV tPHQV tELRS tGLRS tEHRS tGHRS WE Low to VCC at 3.0 V MIN. Address Valid to Data Valid for VCC = 3.3 V 0.3 V WE High to Data Valid for VCC = 3.3 V 0.3 V BE 0 and BE 1 Setup to WE Going Low OE Setup to WE Going Low BE 0 and BE 1 Hold from WE Going High OE Hold from WE Going High 5 150 500 100 100 100 100 s ns ns ns ns ns ns 1 2 2 NOTES: BE0, BE1 and OE must be set high once after power-up. BE0 and BE1 must not be set low at the same time. 1. Chip reset is enabled when the low state of all BE0 (or BE1), OE and WE exceeds 5 s. Especially when you will power on the chip, execute an above chip reset sequence for a protection from noise. All BE0 (or BE1), OE and WE must not be low, except for the purpose of chip reset. 2. These values are shown for 3.3 V VCC operation. Refer to the AC Characteristics Read Only Operations also. 25 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory AC Characteristics for WE - Controlled Command Write Operations1 VCC = 3.25 V 0.35 V, TA = -20C to +70C SYMBOL PARAMETER TYP. MIN. MAX. UNITS NOTE tAVAV tVPWH tELWL tAVWH tDVWH tWLWH tWHDX tWHAX tWHEH tWHWL tGHWL tWHGL tQVVL tWHQV1 tWHQV2 Write Cycle Time VPP Set up to WE Going High BE 0 and BE 1 Setup to WE Going Low Address Setup to WE Going High Data Setup to WE Going High WE Pulse Width Data Hold from WE High Address Hold from WE High BE 0 and BE 1 Hold from WE High WE Pulse Width High Read Recovery before Write Write Recovery before Read VPP Hold from Valid Status Register Data Duration of Byte Write Operation Duration of Block Erase Operation 20 150 100 0 110 110 110 10 10 10 75 0 120 0 8 0.3 250 ns ns ns ns ns ns ns ns ns ns ns ns s s s 4, 5, 7 4 2 2 2, 6 2, 6 3 NOTES: 1. Read timing during write and erase are the same as for normal read. 2. Refer to command definition tables for valid address and data values. 3. Sampled, but not 100% tested. 4. Write/Erase durations are measured to valid Status Register (CSR) Data. 5. Byte write operations are typically performed with 1 Programming Pulse. 6. Address and Data are latched on the rising edge of WE for all Command Write operations. 7. The maximum value of byte write time is the maximum write time inside the chip. It is not the time until the whole writing procedure is completed properly. It is necessary to check CSR to see if the writing procedure is properly completed. 26 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 WRITE DATA-WRITE OR ERASE SETUP COMMAND WRITE VALID ADDRESS AND DATA (DATA-WRITE) OR ERASE CONFIRM COMMAND AUTOMATED DATA-WRITE OR ERASE DELAY READ COMPATIBLE STATUS REGISTER DATA ADDRESSES (A) VIH (NOTE 1) VIL tAVAV BEX (E) VIH (NOTE 3) VIL tWHEH tELWL VIH VIL tWHWL VIH VIL tWLWH tWHDX tDVWH DATA (D/Q) VIH VIL HIGH-Z DIN AIN tAVWH tWHAX (NOTE 2) tWHGL OE (G) tWHQV 1, 2 tGHWL WE (W) DIN tVPWH DIN DOUT DIN tQVVL VPPH VPP (V) V PPL NOTES: 1. This address string depicts Data-Write/Erase cycles with corresponding verification via CSRD. 2. This cycle is invalid when using CSRD for verification during Data-Write/Erase operations. 3. BEX means either BE0 or BE1 28F040SUZ4-17 Figure 17. Waveforms for Command Write Operations 27 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory AC Characteristics for BE - Controlled Command Write Operations2 VCC = 3.25 V 0.35 V, TA = -20C to +70C SYMBOL PARAMETER TYP. MIN. MAX. UNITS NOTE tAVAV tVPEH tWLEL tAVEH tDVEH tELEH tEHDX tEHAX tEHWH tEHEL tGHEL tEHGL tQVVL tEHQV1 tEHQV2 Write Cycle Time VPP Set up to BE 0 or BE 1 Going High WE Setup to BE 0 or BE 1 Going Low Address Setup to BE 0 or BE 1 Going High Data Setup to BE 0 or BE 1 Going High BE 0 or BE 1 Pulse Width Data Hold from BE 0 or BE 1 High Address Hold from BE 0 or BE 1 High WE Hold from BE 0 or BE 1 High BE 0 or BE 1 Pulse Width High Read Recovery before Write Write Recovery before Read VPP Hold from Valid Status Register Data Duration of Byte Write Operation Duration of Block Erase Operation 20 150 100 0 110 110 110 10 10 10 75 0 120 0 8 0.3 250 ns ns ns ns ns ns ns ns ns ns ns ns s s s 4, 5, 7 4 2 2 2, 6 2, 6 3 NOTES: 1. Read timing during write and erase are the same as for normal read. 2. Refer to command definition tables for valid address and data values. 3. Sampled, but not 100% tested. 4. Write/Erase durations are measured to valid Status Register (CSR) Data. 5. Byte Write operations are typically performed with 1 Programming Pulse. 6. Address and Data are latched on the rising edge of BE0 or BE1 for all Command Write operations. 7. The MAX. value of byte write time is the maximum wrtie time inside the chip. It is not the time until the whole writing procedure is completed properly. It is necessary to check CSR to see if the writing procedure is properly completed. 28 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 WRITE DATA-WRITE OR ERASE SETUP COMMAND WRITE VALID ADDRESS AND DATA (DATA-WRITE) OR ERASE CONFIRM COMMAND AUTOMATED DATA-WRITE OR ERASE DELAY READ COMPATIBLE STATUS REGISTER DATA ADDRESSES (A) VIH (NOTE 1) VIL tAVAV VIH VIL tEHWH tWLEL VIH VIL tEHEL BEX (E) VIH (NOTE 3) VIL tELEH tEHDX tDVEH DATA (D/Q) VIH VIL HIGH-Z DIN AIN tAVEH tEHAX (NOTE 2) WE (W) tEHGL OE (E) tEHQV 1, 2 tGHEL DIN tVPEH DIN DOUT DIN tQVVL VPPH VPP (V) VPPL NOTES: 1. This address string depicts Data-Write/Erase cycles with corresponding verification via CSRD. 2. This cycle is invalid when using CSRD for verification during Data-Write/Erase operations. 3. BEX means either BE0 or BE1 28F040SUZ4-18 Figure 18. Alternate AC Waveforms for Command Write Operations 29 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory Erase and Byte Write Performance VCC = 3.25 V 0.35 V, TA = -20C to +70C SYMBOL PARAMETER TYP.(1) MIN. MAX. UNITS TEST CONDITIONS NOTE tWHRH1 tWHRH2 tWHRH3 tWHRH4 Byte Write Time Two-Byte Serial Write Time 16KB Block Write Time 16KB Block Write Time Block Erase Time (16KB) 2M Bit Bank Erase Time 20 34 0.33 0.28 0.8 9 - 15 250 s s 2, 3 2 Byte Write Mode Two-Byte Serial Write Mode 2 2 2 2, 4 1.0 1.0 10 s s s s NOTES: 1. 25C, VPP = 5.0 V 2. Excludes System-Level Overhead. It actually indicates the time from input write/erase command until bit7 of status register becomes ready (WSMS = 0). 3. The MAX. value of byte write time is the maximum write time inside the chip. It is not the time until the whole writing procedure is completed properly. It is necessary to check CSR to see if the writing procedure is properly completed. 4. Depends on the number of protected blocks. 30 4M (512K x 8) Flash Memory LH28F040SUTD-Z4 40TSOP (TSOP040-P-1020) 1 40 0.50 [0.020] TYP. 0.25 [0.010] 0.15 [0.006] 10.20 [0.402] 9.80 [0.386] 20 21 1.10 [0.043] 0.90 [0.035] SEE DETAIL 1.19 [0.047] MAX. 0.49 [0.019] 0.39 [0.015] DETAIL 0.125 [0.005] 18.60 [0.732] 18.20 [0.717] 19.30 [0.760] 18.70 [0.736] 20.30 [0.799] 19.70 [0.776] MAXIMUM LIMIT MINIMUM LIMIT 0.49 [0.019] 0.39 [0.015] 0.22 [0.009] 0.02 [0.001] 0 - 10 0.18 [0.007] 0.08 [0.003] 40TSOP DIMENSIONS IN MM [INCHES] ORDERING INFORMATION LH28F040SU T Device Type Package D -Z4 Speed 190 Access Time (ns) Dual Works 40-pin, 1.2 mm x 10 mm x 20 mm TSOP (Type I) (TSOP040-P-1020) 4M (512K x 8) Flash Memory Example: LH28F040SUT-Z4 (4M (512K x 8) Flash Memory, 190 ns, 40-pin TSOP) 28F040SUZ4-19 31 LH28F040SUTD-Z4 4M (512K x 8) Flash Memory LIFE SUPPORT POLICY SHARP components should not be used in medical devices with life support functions or in safety equipment (or similiar applications where component failure would result in loss of life or physical harm) without the written approval of an officer of the SHARP Corporation. WARRANTY SHARP warrants to Customer that the Products will be free from defects in material and workmanship under normal use and service for a period of one year from the date of invoice. Customer's exclusive remedy for breach of this warranty is that SHARP will either (i) repair or replace, at its option, any Product which fails during the warranty period because of such defect (if Customer promptly reported the failure to SHARP in writing) or, (ii) if SHARP is unable to repair or replace, SHARP will refund the purchase price of the Product upon its return to SHARP. This warranty does not apply to any Product which has been subjected to misuse, abnormal service or handling, or which has been altered or modified in design or construction, or which has been serviced or repaired by anyone other than SHARP. The warranties set forth herein are in lieu of, and exclusive of, all other warranties, express or implied. ALL EXPRESS AND IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR USE AND FITNESS FOR A PARTICULAR PURPOSE ARE SPECIFICALLY EXCLUDED. SHARP reserves the right to make changes in specifications at any time and without notice. SHARP does not assume any responsibility for the use of any circuitry described; no circuit patent licenses are implied. (R) NORTH AMERICA EUROPE ASIA SHARP Electronics Corporation Microelectronics Group 5700 NW Pacific Rim Blvd., M/S 20 Camas, WA 98607, U.S.A. Phone: (360) 834-2500 Telex: 49608472 (SHARPCAM) Facsimile: (360) 834-8903 http://www.sharpmeg.com SHARP Electronics (Europe) GmbH Microelectronics Division Sonninstrae 3 20097 Hamburg, Germany Phone: (49) 40 2376-2286 Telex: 2161867 (HEEG D) Facsimile: (49) 40 2376-2232 SHARP Corporation Integrated Circuits Group 2613-1 Ichinomoto-Cho Tenri-City, Nara, 632, Japan Phone: (07436) 5-1321 Telex: LABOMETA-B J63428 Facsimile: (07436) 5-1532 (c)1997 by SHARP Corporation Issued July 1996 Reference Code SMT96117 |
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