Preliminary Specifications CMOS LSI LE28FV4001CTS-20 4M-Bit (512k × 8) Flash EEPROM Features CMOS Flash EEPROM Technology Single 3.3-Volt Read and Write Operations Sector Erase Capability: 256 Bytes per sector Fast Access Time: 200 ns Low Power Consumption Active Current(Read): 10 mA (Max.) Standby Current: 15 µA (Max.) High Read/Write Reliability Sector-write Endurance Cycles: 104 10 Years Data Retention Latched Address and Data Self-timed Erase and Programming Byte Programming: 40µ µs (Max.) End of Write Detection:Toggle Bit/ DATA Polling Hardware/Software Data Protection JEDEC Standard Byte-Wide EEPROM Pinouts Packages Available LE28FV4001CTS: 32-pin TSOP Normal(8×14mm) Product Description program or data memory. For all system applications, the LE28FV4001C significantly improves performance and reliability, while lowering power consumption when compared with floppy diskettes or EPROM approaches. EEPROM technology makes possible convenient and economical updating of codes and control programs on-line. The LE28FV4001C improves flexibility, while lowering the cost, of program and configuration storage applications. The LE28FV4001C is a 512K ×8 CMOS sector erase, byte program EEPROM. The LE28FV4001C is manufactured using SANYO's proprietary, high performance CMOS Flash EEPROM technology. Breakthroughs in EEPROM cell design and process architecture attain better reliability and manufacturability compared with conventional approaches. The LE28FV4001C erases and programs with a 3.3-volt only power supply. LE28FV4001C conforms to JEDEC standard pinouts for byte wide memories and is compatible with existing industry standard EPROM, flash EPROM and EEPROM pinouts. Featuring high performance programming, the LE28FV4001C typically byte programs in 30µs. The LE28FV4001C typically sector (256 bytes) erases in 2ms. Both program and erase times can be optimized using interface feature such as Toggle bit or DATA Polling to indicate the completion of the write cycle. To protect against an inadvertent write, the LE28FV4001C has on chip hardware and software date protection schemes. Designed, manufactured, and tested for a wide spectrum of applications, the LE28FV4001C is offered with a guaranteed sector write endurance of 104 cycles. Data retention is rated greater then 10 years. Figure 1 shows the pin assignments for the 32 lead Plastic TSOP packages. Figure 2 shows the functional block diagram of the LE28FV4001C. Pin description and operation modes can be found in Tables 1 through 3. Device Operation Commands are used to initiate the memory operation functions of the device. Commands are written to the device using standard microprocessor write sequences. A command is written by asserting WE low while keeping CE low. The address bus is latched on the falling edge of WE , CE , whichever occurs last. The data bus is latched on the rising edge of WE , CE , whichever occurs first. However, during the software write protection sequence the address are latched on the rising edge of OE or CE , whichever occurs first. The LE28FV4001C is best suited for applications that require reprogrammable nonvolatile mass storage of *This product incorporate technology licensed from Silicon Storage Technology, Inc. This preliminary specification is subject to change without notice. SANYO Electric Co., Ltd. Semiconductor Company 1-1, 1 Chome, Sakata, Oizumi-machi, Ora-gun, GUNMA, 370-0596 JAPAN Revision 2.20-February 23,2001-AY/ay-1/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications A11 A9 A8 A13 A14 A17 WE Vcc A18 A16 A15 A12 A7 A6 A5 A4 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 32 pin TSOP 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 Normal (Top View) OE A10 CE DQ7 DQ6 DQ5 DQ4 DQ3 Vss DQ2 DQ1 DQ0 A0 A1 A2 A3 Figure 1: Pin Assignments for 32-pin Plastic TSOP XDECODER A18-A0 4,194,304 Bit SuperFlash EEPROM Cell Array ADDRESS BUFFERS & LATCHES Y-DECODER CE OE WE CONTROL LOGIC I/O BUFFERS & DATA LATCHES DQ7-DQ0 Figure 2: Functional Block Diagram of LE28FV4001C SANYO Electric Co., Ltd. 2/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Table 1: Pin Description Symbol Pin Name A18-A0 Functions Address Inputs To provide memory address. Address are internally latched during write cycle. DQ7-DQ0 Data Input/Output To output data during read cycle and receive input data during write cycles. Data is internally latched during a write cycle. The outputs are in tri-state when OE or CE is high. CE Chip Enable To activate the device when CE is low. Deselects and puts the device to standby when CE is high. OE Output Enable To activate the data output buffers. OE is active low. WE Write Enable To activate the write operation. WE is active low. VDD Power Supply To provide 3.3V±0.3V supply. VSS Ground Table 2: Operation Modes Selection Mode Read Write Standby Write Inhibit Product ID CE OE WE DQ Address VIL VIL VIH X X VIL VIL VIH X VIL X VIL VIH VIL X X VIH VIH DOUT DIN High-Z High-Z / DOUT High-Z / DOUT Manufacturer Code (BF) Device Code (04) AIN AIN X X X A18-A1=VIL, A9=12V, A0=VIL A18-A1=VIL, A9=12V, A0=VIH Table 3: Command Summary Command Sector_Erase Byte_Program Reset Read_ID Software_Data_Unprotect (6) Software_Data_Protect (6) Required Setup Command Cycle Cycle Operation Address Data 2 Write X 20H 2 Write X 10H 1 Write X FFH 3 Write X 90H 7 7 Execute Command Cycle Operation Address Data Write SA D0H Write PA PD Read (7) (7) SDP N N Y Y Definitions for Table 3: 1. 2. 3. 4. 5. 6. Type definitions : X=high or low Address definitions : SA=Sector Address=A18-A8 ; sector size=256byte ; A7-A0=X for this command Address definitions : PA=Program Address=A18-A0 Data definition : PD=Program Data, H=number in hex. SDP=Software Data Protect mode using 7-Read-Cycle-Sequence. Y=the operation can be executed with software data protect enabled. N=the operation cannot be executed with software data protect enabled. Refer to Figure 11 and 12 for the 7-Read-Cycle-Sequence Software Data Protection. 7. Address 0000H retrieves the manufacturer code of BF(Hex), address 0001H retrieves the device code of 04(Hex). SANYO Electric Co., Ltd. 3/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Command Definition Table 3 contains a command list and a brief summary of the commands. The following is a detailed description of the options initiated by each command. The LE28FV4001C has to have the Software Data Unprotect Sequence executed prior a Byte Program or Erase in order to perform those functions. Sector_Erase Operation The Sector_Erase operation is initiated by a setup command and an execute command. The setup command stages the device for electrical erasing of all bytes within a sector. A sector contains 256 bytes. This sector erasability enhances the flexibility and usefulness of the LE28FV4001C, since most applications only need to change a small number of bytes or sectors, not the entire chip. The setup command is performed by writing (20H) to the device. To execute the sector-erase operation, the execute command (D0H) must be written to the device. The erase operation begins with the rising edge of the WE pulse and terminated automatically by using an internal timer. See Figure 8 for timing waveforms. The two-step sequence of a setup command followed by an execute command ensures that only memory contents within the addressed sector are erased and other sectors are not inadvertently erased. Sector_Erase Flowchart Description Fast and Reliable erasing of the memory contents within a sector is accomplished by following the sector erase flowchart as shown in Figure 3. The entire procedure consists of the execution of two commands. The Sector_Erase operation will terminate after a maximum of 4ms. A Reset command can be executed to terminate the erase operation; however, if the erase operation is terminated prior to the 4ms time-out, the sector may not be completely erased. An erase command can be reissued as many times an necessary to complete the erase operation. The LE28FV4001C cannot be “overerased”. Byte_Program Operation operation begins with either the rising edge of WE , CE , whichever occurs first. The programming operation is terminated automatically by an internal timer. See the programming characteristics and waveforms for details, Figures 4, 6 and 7. The two-step sequence of a setup command followed by an execute command ensures that only the addressed byte is programmed and other bytes are not inadvertently programmed. The Byte_Program Flow Chart Description Programming data into the device is accomplished by following the Byte_Program flowchart as shown in Figure 3. The Byte_Program command sets up the byte for programming. The address bus is latched on the falling edge of WE , CE , whichever occurs last. The data bus is latched on the rising edge of WE , CE , whichever occurs first, and begins the program operation. The end of write can be detected using either the DATA polling or Toggle bit. Reset Operation A Reset Command is provided as a means to safely abort the erase or program command sequences. Following either setup command (erase or program) with a write of (FFH) will safely abort the operation. Memory contents will not be altered. After the Reset command, the device returns to the read mode. The reset command dose not enable write protect. See figure 10 for timing waveforms. Read Operation The read operation is initiated by setting CE , OE and WE into the read mode. See Figure 5 for read memory timing waveforms and Table 2 for the read mode. Read cycles from the host retrieve data from the array. The device remains enabled for read until another operating mode is accessed. During initial power-up, the device is in the read mode and is write protected. The device must be unprotected in order to execute a write operation The read operation is controlled by OE and CE at logic low. When CE is high, the chip is deselected and only standby power will be consumed. OE is the output control and is used to gate to the output pins. The data bus is in a high impedance state when either CE or OE is high. The Byte_Program operation is initiated by writing the setup command (10H). Once the program setup is performed, programming is executed by the next WE pulse. See Figure 6 and 7 for timing waveforms. The address bus is latched on the falling edge of WE , CE , or the rising edge of OE , whichever occurs first. The programming SANYO Electric Co., Ltd. 4/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Read_ID Operation DATA Polling (DQ7) The Read_ID operation is initiated by writing a single command (90H). A read of address 0000H will outputs the manufacturer’s code (BFH). A read of address 0001H will outputs the device code (04H).Any other valid command will terminate this operation. The LE28FV4001C features DATA Polling to indicate the and of a write cycle. During a write cycle, any attempt to read the last byte loaded will result in the complement of the loaded data on DQ7. Once the write cycle is completed, DQ7 will show true data. See Figure 13 for timing waveforms. In order for DATA Polling to function correctly, the byte being polled must be erased prior to programming. Data Protection from Inadvertent Writes In order to protect the integrity of nonvolatile data storage, the LE28FV4001C provides hardware and software features to prevent writes to the device, for example, during system power-up or power-down. Such provisions are described below. Hardware Write Protection The LE28FV4001C is designed with hardware features to prevent inadvertent writes. This is done in the following ways: 1. Write Inhibit Mode: OE low, CE high or WE high inhibit the write operation. 2. Noise and Glitch Protection: Write operations are initiated when the WE pulse width is less than 15 ns. 3. After power-up the device is in the read mode and the device is in the write protect state. Toggle Bit (DQ6) An alternate means for determining the end of a write cycle is by monitoring the Toggle Bit DQ6. During a write operation, successive attempts to read data from the device will result in DQ6 toggling between logic "1" (high) and "0" (low). Once the write cycle has completed, DQ6 will stop toggling and valid data will be read. The Toggle Bit may be monitored any time during the write cycle. See Figure 14 for timing waveforms. Successive Reads An alternate means for determining the end of a write cycle is by reading the same address for two consecutive data matches. Product Identification Software Data Protection Provisions have been made to further prevent inadvertent writes through software. In order to perform the write functions of erase or program, a two-step command sequence consisting of a setup command followed by an execute command avoids inadvertent erasing or programming of the device. The LE28FV4001C will default to write protect after power-up. A sequence of seven consecutive reads at specified device addresses will unprotect the device. The address sequence is 1823H, 1820H, 1822H, 0418H, 041BH, 0419H, 041AH. The address has to be latched in the rising edge of OE or CE , whichever occurs first. A similar seven read sequence of 1823H, 1820H, 1822H, 0418H, 041BH, 0419H, 040AH will protect the device. Also, refer to Figure 11, 12 for the 7-read-sequence Software Write Protection. The DQ pins can be in any state (i.e., high, low, or High-Z). The Product Identification mode identifies the device and manufacturer as SANYO. This mode may be accessed by hardware or software operations. The hardware operation is typically used by an external programming to identify the correct algorithm for the SANYO LE28FV4001C. Users may wish to use the software operation to identify the device (i.e., using the device code). For details, see Table 2 for the hardware operation. The manufacturer and device codes are the same for both operations. Notes for Operation During power up, the device’s state should be the write inhibition mode. (During power up, the device’s state should be CE =VIH or OE =VIL or WE =VIH) If CE = WE =VIL and OE =VIH during power up, RESET command should be asserted before operation. End of Write Detection Detection of where a write cycle ended is necessary to optimize system performance. The end of a write cycle (erase or program) can be detected by three means: 1) monitoring the DATA polling bit; 2) monitoring the Toggle bit; 3) by two successive reads of the same data. These three detection mechanisms are described below. SANYO Electric Co., Ltd. 5/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Start Initial Sector Address Execute Two Step Sector Erase Command Read FF from Device N Verify FF Y Increment Address N Last Address? Y Sector Erase Completed Erase Error Figure 3: Sector_Erase Flowchart SANYO Electric Co., Ltd. 6/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Start Initialize Addresses Setup Byte Program Command Load Address and Data & Start Programming Read End of Write Detection Programming Completed? N Y Data Verifies? N Programming Failure Next Address Y N Last Address Y Programming Completed Figure 4: Byte_Program Flowchart SANYO Electric Co., Ltd. 7/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Absolute Maximum Stress Ratings Temperature Under Bias..........................................................-55 °C ~ 125 °C Storage Temperature................................................................-65 °C ~ 150 °C D.C. Voltage on Any Pin to Grand Potential ...........................-0.5V ~ VCC+0.5V Transient Voltage (<20ns) on any Pin to Grand Potential .......-1.0V ~ VCC+1.0V Voltage on A9 to Grand Potential............................................-0.5V ~ 14.0V Operating Range Ambient Temperature..............................................................0 °C ~ 70 °C Supply Voltage (VDD) .............................................................3.0V ~ 3.6V DC Operating Characteristics Symbol Parameter Limit Min. Typ. Units Test Condition Max. ICCR Power Supply Current (Read) 10 mA CE = OE =VIL, WE =VIH, all DQs open Address inputs=VIH / VIL, at f=1/tRC, VDD=VDD max. ICCW Power Supply Current (Write) 25 mA CE = WE =VIL, OE =VIH, VDD=VDD max. ISB2 Standby VDD Current (CMOS input) 15 µA CE =VDD-0.3V, VDD=VDD max. ILI Input Leakage Current 10 µA VIN=VSS~VDD, VDD=VDD max. ILO Output Leakage Current 10 µA VOUT=Vss~VDD, VDD=VDD max. VIL Input Low Voltage -0.3 0.6 V VDD=VDD max. VIH Input High Voltage 2.0 Vcc+0.3 V VDD=VDD max. VOL Output Low Voltage 0.4 V IOL=100µA, VDD=VDD min. VOH Output High Voltage V IOH= -100µA, VDD=VDD min. 2.4 Power-up Timing Symbol Parameter Minimum Units tPU_READ Power-up to Read Operation 10 ms tPU_WRITE Power-up to Write Operation 10 ms Capacitance (Ta=25°C, f=1MHz) Maximum Units CDQ Symbol DQ Pin Capacitance Descriptions 12 pF VDQ = 0V Test Condition CIN Input Capacitance 6 pF VIN = 0V SANYO Electric Co., Ltd. 8/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications AC Characteristics Read Cycle Timing Parameters Symbol tRC tCE tAA tOE tCLZ tOLZ tCHZ tOHZ tOH Parameter -20 Min. 200 Read Cycle Time Chip Enable Access Time Address Access Time Output Enable Access Time CE Low to Active Output OE Low to Active Output CE High to High-Z Output OE High to High-Z Output Output Hold Time Units Max. 200 200 100 0 0 60 60 0 ns ns ns ns ns ns ns ns ns Erase/Program Cycle Timing Parameters Symbol Parameter -20 Min. tSE tBP tAS tAH tCS tCH tOES tOEH tCP tWP tCPH tWPH tDS tDH tRST tPCP tPCH tPAS tPAH Sector Erase Cycle Time Byte Program Cycle Time Address Setup Time Address Hold Time Chip Enable Setup Time Chip Enable Hold Time Output Enable Setup Time from WE Output Enable Hold Time from WE Write Pulse Width ( CE ) Write Pulse Width CE High Pulse Width WE High Pulse Width Data Setup Time Data Hold Time Reset Command Recovery Time Protect Chip Enable Pulse Width Protect Chip Enable High Time Protect Address Setup Time Protect Address Hold Time Units Max. 4 40 10 50 0 0 10 10 100 100 50 50 50 10 4 100 150 40 100 ms µs ns ns ns ns ns ns ns ns ns ns ns ns µs ns ns ns ns Note: This parameter is measured only for initial qualification and after a design or process change that could affect this parameter. AC Test Conditions Input Load Levels ....................................................................1TTL Gate and CL=30pF Input Rise/Fall Time ................................................................10ns SANYO Electric Co., Ltd. 9/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Figure 5: Read Cycle Diagram tRC A18-0 tCE CE tOE tAA OE tOHZ tOLZ WE tOH tCHZ tCLZ DQ7-0 DATA VALID DATA VALID Figure 6: WE Controlled Write Cycle Timing Diagram tAS tAH A18-0 tCS tCH CE tOEH OE tOES tWPH tWP WE tDS DQ7-0 tDH DATA VALID SANYO Electric Co., Ltd. 10/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Figure 7: CE Controlled Write Cycle Timing Diagram tAS tAH A18-0 tCP CE tCPH OE tOES tOEH WE tDS DQ7-0 tDH DATA VALID Figure 8: Sector Erase Timing Diagram Self-timed Page Erase Cycle Execute command Setup command A18-0 AIN tAS tAH WE(CE) OE tSE CE(WE) tDS DQ7-0 tDH tDS (20H) tDH (D0H) SANYO Electric Co., Ltd. 11/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Figure 9: Byte Program Timing Diagram Self-timed Program Cycle Execute command Setup command A18-0 AIN tAS tAH WE(CE) OE tBP CE(WE) tDS DQ7-0 tDH tDS (10H) tDH DIN Figure 10: Reset Command Timing Diagram Reset command A18-0 WE(CE) OE CE(WE) tDS DQ7-0 tDH (FFH) tRST SANYO Electric Co., Ltd. 12/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Figure 11: Software Data Unprotect Sequence OE tPCH tPCP CE Address 1823 1820 1822 0418 041B 0419 041A 041B 0419 040A tPAH tPAS Notes on Figure 11 1. 2. The address is latched on the rising edge of CE or WE , whichever is earlier. Pins A16 to A18 should be at either VIL or VIH Figure 12: Software Data Protect Sequence OE tPCH tPCP CE Address 1823 tPAS 1820 1822 0418 tPAH Notes on Figure 12 1. 2. The address is latched on the rising edge of CE or WE , whichever is earlier. Pins A16 to A18 should be at either VIL or VIH SANYO Electric Co., Ltd. 13/14 LE28FV4001CTS-20 4M-Bit Flash EEPROM Preliminary Specifications Figure 13: DATA Polling Timing Diagram (DQ7) A18-0 AN AN AN AN tBP WE tCE tOES CE tOEH tOE OE DQ7 DIN=X DOUT=X DOUT=X DOUT=X Figure 14: Toggle Bit Timing Diagram (DQ6) A18-0 Note WE tCE CE tOEH OE tOES tOE DQ6 Note: This time interval signal can be tSE or tBP, depending upon the selected operation mode. SANYO Electric Co., Ltd. 14/14