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this data sheet states saifun's current technical specifications regarding the products described herein. this data sheet may be revised by subsequent versions or modifications due to changes in technical specifications. publication# 1985 rev: 1 amendment: 0 issue date: 24 july 2003 sa25f010 advanced information features ? = saifun nrom? flash cell ? = serial peripheral interface (spi) compatible, supports spi modes 0 (0,0) and 3 (1,1) ? = page program operation: ? 512 pages (256 bytes/page) ? single page rewrite cycle (erase and program) in 10ms typical ? = page program mode (up to 256 bytes) in 9ms typical ? = page erase (256 bytes) in 3 ms ? = sector erase (256 kb) in 0.3 s ? = bulk erase (1 mb) ? = single supply voltage: 2.7 v to 3.6 v ? = 25mhz clock rate ? = block write protection: protect quarter, half or entire array ? = write protect pin and write disable instructions of both hardware and software data protection ? = 100,000 erase cycles (minimum) ? = more than 20-year data retention ? = low-power standby current (less than 1 a) ? = 8-soic narrow package ? = mlf leadless package ? = temperature range: ? industrial: -40c to +85c ? commercial: 0c to +70c 1mb serial flash with 25mhz spi bus interface http://www.saifun.com saifun nrom tm is a trademark of saifun semiconductors ltd.
sa25f010 advanced information saifun 2 general description the sa25f010 is a 1mb (256k x 4) cmos non-volatile serial flash memory. this device fully conforms to the spi 4-wire protocol, is enabled through the chip select (csb) pin, and uses clock (sck), data-in (si) and data-out (so) pins to synchronously control data transfer between the spi microcontroller and the serial flash memory. the memory can be programmed from 1 up to 256 bytes at a time via the page program (pp) instruction. the memory is organized into four sectors. each sector contains 128 pages, with each page being 256 bytes wide. the entire memory can therefore be viewed as consisting of 512 pages, or 131,072 bytes. the memory can be erased in one of the following ways: ? = 256 bytes at a time, using the page erase (pe) instruction ? = 256 kb at a time, using the sector erase (se) instruction ? = 1 mb at a time, using the bulk erase (be) instruction each device requires only a 3.0v power supply (2.7 v to 3.6 v) for both read and write functions. internally generated and regulated voltages are provided for the program and erase operations. the sa25f010 does not require a v pp supply. the holdb pin may be used to suspend any serial communication without resetting the serial sequence. in addition, the serial interface allows a minimal-pin-count packaging designed to simplify pc board layout requirements and offers the designer a variety of low-voltage and low-power options. the sa25f010 is available in a space-saving, 8-lead narrow soic package the sa25f010 is part of the spi flash and eeprom family. it is designed to work with any spi-compatible, high-speed microcontroller, and offers both hardware (wpb pin) and software (?block protect?) data protection. for example, programming a 2-bit code into the status register prevents program with top ?, top ? or entire array write protection and enables block write protection. separate program enable and program disable instructions are provided for additional data protection. hardware data protection is provided via the wpb pin to protect against inadvertent write attempts to the status register. saifun?s spi serial flash products are designed and tested for applications requiring high endurance and low power consumption for a continuously reliable non-volatile solution for all markets.
sa25f010 advanced information saifun 3 table of contents features ......................................................................... 1 general description ...................................................... 2 memory organization.................................................... 5 connection diagrams ................................................... 6 ordering information .................................................... 7 product specifications ................................................. 8 absolute maximum ratings..................................... 8 esd/latch up specification (jedec 8 spec) ......... 8 operating conditions............................................... 8 dc characteristics ........................................................ 9 ac test conditions ..................................................... 10 timing diagrams ......................................................... 11 signal description....................................................... 13 chip select (csb).................................................. 13 serial clock (sck) ................................................ 13 serial input (si) ..................................................... 13 serial output (so)................................................. 13 hold (holdb)........................................................ 13 write protect (wpb) .............................................. 13 serial interface description ........................................ 14 spi modes ............................................................ 14 master ........................................................... 14 slave ............................................................. 14 transmitter/receiver ..................................... 14 serial opcode................................................ 14 invalid opcode .............................................. 14 chip select (csb).......................................... 14 hold condition............................................... 15 write protect ................................................. 16 functional description ............................................... 17 instructions............................................................ 17 read status register (rdsr) ............................... 18 write enable (wren) ........................................... 20 write disable (wrdi)............................................ 20 write status register (wrsr) .............................. 21 read data bytes (read) ...................................... 23 fast read (fast_read) ..................................... 24 page programming (pp) ....................................... 25 page erase (pe)................................................... 27 sector erase (se) ................................................. 28 bulk erase (be)..................................................... 29 software protection (sp)/ deep powerdown (dp) . 30 release from software protect (res) ................... 31 release from software protection and read electronic signature (res).................................... 32 powerup and powerdown ...................................... 33 physical dimensions................................................... 34 contact information .................................................... 37 life support policy...................................................... 37
sa25f010 advanced information saifun 4 list of figures figure 1. sa25f010 block diagram ................................ 5 figure 2. soic 8 (150 mil)/pdip/mlf package (top view) ............................................................. 6 figure 3. sa25f010 ordering information....................... 7 figure 4. spi mode 0 (0,0) input timing........................ 11 figure 5. spi mode 0 (0,0) output timing..................... 11 figure 6. ac measurements i/o waveform................... 12 figure 7. supported spi modes .................................... 14 figure 8. hold condition................................................ 15 figure 9. spi serial interface ........................................ 17 figure 10. read status register (rdsr) instruction sequence ............................................................ 19 figure 11. write enable (wren) instruction sequence 20 figure 12. write disable (wrdi) instruction sequence. 20 figure 13. write status register (wrsr) instruction sequence ............................................................ 22 figure 14. read (read) instruction sequence ............. 23 figure 15. fast read (fast_read) instruction sequence ............................................................ 24 figure 16. page programming (pp) instruction sequence ............................................................ 26 figure 17. page erase (pe) instruction sequence ........ 27 figure 18. sector erase (se) instruction sequence ...... 28 figure 19. bulk erase (be) instruction sequence.......... 29 figure 20. software protection instruction sequence .... 30 figure 21. release from software protect (res) instruction sequence ............................................................ 31 figure 22. release from software protection and read electronic signature (res) instruction sequence 32 figure 23. 8-pin soic package..................................... 34 figure 24. 8-pin mlf leadless package ....................... 35 figure 25. molded dual-in-line package (n) package number n08e...................................................... 36 list of tables table 1. memory organization ........................................ 5 table 2. pin names......................................................... 6 table 3. dc characteristics............................................. 9 table 4. ac test conditions.......................................... 10 table 5. ac measurements........................................... 12 table 6. instruction set ................................................. 17 table 7. status register format.................................... 18 table 8. read status register definition....................... 18 table 9. block write protect bits................................... 21 table 10. wpben operation ........................................ 21 table 11. powerup ........................................................ 33
sa25f010 advanced information saifun 5 memory organization the memory is organized in the following manner: ? = 131,072 bytes (8 bits each) ? = 4 sectors (256 kb, 32,768 bytes each), as shown in table 1 ? = 512 pages (256 bytes each) each page can be individually programmed, with the bits programmed from 1 to 0. the sa25f010's memory can be erased via the page, sector or bulk erase commands, with the bits erased from 0 to 1. table 1. memory organization sector address range 3 18000h 1ffffh 2 10000h 17fffh 1 8000h 0ffffh 0 00000h 07fffh holdb wpb vcc gnd so si sck csb ps sram io array - r x d e c logic array - l data path rd figure 1. sa25f010 block diagram
sa25f010 advanced information saifun 6 connection diagrams sa25f010 1 2 3 4 8 7 6 5 csb so wpb gnd vcc holdb sck si figure 2. soic 8 (150 mil)/pdip/mlf package (top view) table 2. pin names pin name signal name csb chip select sck serial data clock si serial data input so serial data output gnd ground v cc power supply wpb write protect holdb suspend serial input
sa25f010 advanced information saifun 7 ordering information l xx f 25 sa letter l 010 f 25 sa interface density voltage operating range description 2.7 v to 3.6 v 1 mb with write protect flash spi-2 wires saifun non-volatile memory x blank x tube tape and reel pp package n m8 mlf 8-pin dip 8-pin soic (150 mil) 8-lead mlf f blank f non-lead free lead free e blank e temp. range 0 to 70 c -40 to +85 c o o figure 3. sa25f010 ordering information
sa25f010 advanced information saifun 8 product specifications absolute maximum ratings storage temperature -65 c to +150 c all input or output voltages with respect to ground 4.5 v to -0.3 v lead temperature (soldering, 10 seconds) +235 c esd rating 2000 v min. esd/latch up specification (jedec 8 spec) human body model minimum 4 kv machine model minimum 500 v charge device model minimum 1 kv latch up 100 ma on all pins +125 c operating conditions operating temperature: sa25f010 sa25f010e 0 c to +70 c -40 c to +85 c positive power supply: sa25f010 2.7 v to 3.6 v
sa25f010 advanced information saifun 9 dc characteristics applicable over recommended operating range from t ai = -40 oc to 85 oc, v cc = 2.7-3.6 v. table 3. dc characteristics limits symbol parameter test conditions min typ* max unit v cc supply voltage 2.7 3 3.6 v i cc1 active power supply current (read) sck = 0.1v cc /0.9 v cc @ 25 mhz 9 12 ma i cc2 active power supply current (page program) csb = v cc 15 ma i cc3 active power supply current (wrsr) csb = v cc 15 ma i cc4 active power supply current (se) csb = v cc 15 ma i cc5 active power supply current (be) csb = v cc 15 ma i sb standby current v cc = 3.0 v, csb = v cc 1 a i il input leakage current v in = gnd to v cc 1 a i ol output leakage current v in = gnd to v cc 1 a v il input low voltage -0.3 0.3 v cc v v ih input high voltage 0.7 v cc v cc + 0.5 v v oh output high voltage i oh = -0.1 ma v cc - 0.2 v v ol output low voltage i ol = 1.6 ma; v cc = 2.7 v 0.4 v *typical values are at t ai = 25 oc and 3 v.
sa25f010 advanced information saifun 10 ac test conditions table 4. ac test conditions 25 mhz symbol parameter min typ max unit f sck sck clock frequency d.c. 25 mhz t crt clock rise time (slew rate) 0.1 v/ns t cft clock fall time (slew rate) 0.1 v/ns t wh sck high time 18 ns t wl sck low time 18 ns t cs csb high time 100 ns t css ** csb setup time 10 ns t csh ** csb hold time 10 ns t hd ** holdb setup time 10 ns t cd ** holdb hold time 10 ns t v output valid 0 15 ns t ho output hold time 0 ns t hd:dat data in hold time 5 ns t su:dat data in setup time 5 ns t lz ** holdb to output low z 15 ns t hz ** holdb to output high z 20 ns t dis ** output disable time 15 ns t wps ** write protect setup time 20 ns t wph ** write protect hold time 100 ns t pp * 256-byte page programming 8 10 ms t ep * page erase and programming 10 15 ms t pe page erase time 3 6 ms t se sector erase time 0.3 0.4 sec t be bulk erase time 1 1.5 sec t res release sp mode 1000 ns endurance 100k erase cycles * 256 bytes in the checkerboard programming formation. ** value guaranteed by characterization, not 100% tested in production
sa25f010 advanced information saifun 11 timing diagrams all timing diagrams are based on spi protocol modes 0 and 1. sck si cs t csh t csh t css t css msb in t su:dat t hd:dat t crt t cft lsb in t cs so high impedance figure 4. spi mode 0 (0,0) input timing sck cs t wl t v t wh lsb out so t ho t v t ho t dis figure 5. spi mode 0 (0,0) output timing
sa25f010 advanced information saifun 12 0.7vcc 0.2vcc 0.8vcc 0.3vcc input levels input and output timing reference levels figure 6. ac measurements i/o waveform table 5. ac measurements symbol parameter min max unit c l load capacitance 30 pf input rise and fall times 5 ns input pulse voltage 0.2 v cc to 0.8 v cc v input and output timing reference voltages 0.3 v cc to 0.7 v cc v
sa25f010 advanced information saifun 13 signal description chip select (csb) this is an active-low input pin to the device that is generated by the master controlling the device. a low level on this pin selects the device, while a high level deselects the device. all serial communications with the device are enabled only when this pin is held low. serial clock (sck) this is an input pin to the device that is generated by the master controlling the device. it is a clock signal that synchronizes the communication between a master and the device. all input information (si) to the device is latched on the rising edge of this clock input, while output data (so) from the device is driven after the falling edge of this clock input. serial input (si) this is an input pin to the device that is generated by the master controlling the device. the master transfers input information (instruction, addresses and the data to be programmed) into the device serially via this pin. this input information is latched on the rising edge of the sck. serial output (so) this is an output pin from the device that is used to transfer output data to the controlling master. output data is serially shifted out on this pin after the falling edge of the sck. hold (holdb) this is an active low input pin to the device that is generated by the master controlling the device. when driven low, this pin suspends any current communication with the device. the suspended communication can be resumed by driving this pin high. this feature eliminates the need to re-transmit the entire sequence by enabling the master to resume the communication from where it was left off. this pin should be tied high if this feature is not used. refer to hold condition , page 15, for additional details. write protect (wpb) this is an active low input pin to the device. this pin allows enabling and disabling of writes to the device's memory array and status register. when this pin is held low, writes to the memory array and status register are disabled; when it is held high, they are enabled. refer to write protect , page 16, for additional details.
sa25f010 advanced information saifun 14 serial interface description spi modes these devices can be driven by a microcontroller with its spi peripheral running in either of the two following modes: ? = cpol=0, cpha=0 ? = cpol=1, cpha=1 in both of these modes, input data is latched on the rising edge of sck, and output data is available from the falling edge of sck. the difference between the two modes, as shown in figure 7, is the clock polarity when the bus master is in standby mode and is not transferring data, as follows: ? = sck remains at 0 for cpol = 0, cpha = 0 ? = sck remains at 1 for cpol = 1, cpha = 1 msb msb cs cs so si 0 1 0 1 cpol cpha figure 7. supported spi modes master the device that generates the sck. slave as the sck pin is always an input, the sa25f010 always operates as a slave. transmitter/receiver the sa25f010 has separate pins designated for data transmission and reception. serial opcode the first byte is received after the device is selected. this byte contains the opcode that defines the operation to be performed (for more details, refer to table 6, page 17). invalid opcode if an invalid opcode is received, no data is shifted into the sa25f010, and the serial output pin remains in a high impedance state until a csb falling edge is detected again, which reinitializes the serial communication.
sa25f010 advanced information saifun 15 chip select (csb) the sa25f010 is selected when the csb pin is low. when the device is not selected, data is not accepted via the si pin, and the so pin remains in a high impedance state. hold condition the holdb pin is used in conjunction with the csb pin to select the sa25f010. when the device is selected and a serial sequence is underway, holdb can be used to pause the serial communication with the master device without resetting the serial sequence. to enter the hold condition the device must be selected, with csb low. as shown in figure 8, the hold condition starts on the falling edge of the holdb signal, provided that sck is low. the hold condition ends on the rising edge of the holdb signal, provided that sck is low. if the falling edge does not coincide with sck being low, the hold condition starts only after sck next goes low. similarly, if the rising edge does not coincide with sck being low, the hold condition ends only after sck next goes low. during the hold condition, so is high impedance, and si and sck are don?t care. in most cases, the device is kept selected, with csb driven low, for the entire duration of the hold condition, which ensures that the internal logic state remains unchanged from the moment it enters the hold condition. note: driving csb high while holdb is still low is not a legal operation. hold condition (standard use) hold condition (non-standard use) sck hold figure 8. hold condition
sa25f010 advanced information saifun 16 write protect the wpb pin enables write operations to the status register when held high. when the wpb pin is brought low and the wpben bit is 1, all write operations to the status register are inhibited (for more details, refer to table 11, page 21). if wpb goes low while csb is still low, the write to the status register is interrupted. if the internal write cycle has already been initiated, wpb going low has no effect on any write operations to the status register. the wpb pin function is blocked when the wpben bit in the status register is 0, which enables the user to install the sa25f010 in a system with the wpb pin tied to ground but still able to write to the status register. all wpb pin functions are enabled when the wpben bit is set to 1.
sa25f010 advanced information saifun 17 functional description instructions figure 9 presents a schematic diagram of the sa25f010's spi serial interface. si so csb sck si so csb sck si so csb sck data out data in serial clock sso ss1 ss2 ss3 master: microcontroller slave sa25f010 si so csb sck figure 9. spi serial interface the sa25f010's spi consists of an 8-bit instruction register that decodes a specific instruction to be executed. thirteen different instructions (called opcodes ) are incorporated in the device for various operations. table 6 lists the instruction set and the format for proper operation. all opcodes, array addresses and data are transferred in an msb-first-lsb-last fashion. detailed information about each of these opcodes is provided for the individual instruction descriptions in the sections that follow. table 6. instruction set instruction name instruction format operation wren 0000 0110 set write enable latch wrdi 0000 0100 reset write enable latch rdsr 0000 0101 read status register wrsr 0000 0001 write status register read 0000 0011 read data from memory array fast_read 0000 1011 read data from memory array page program 0000 0010 write data to memory array pe 1000 0001 page erase se 1101 1000 sector erase be 1100 0111 bulk erase sp 1011 1001 software protect 1010 1011 release from software protect mode res 1010 1011 +3 dummy bytes release from software protect + read id read_id 1010 1011 +3 dummy bytes read id
sa25f010 advanced information saifun 18 in addition to the instruction register, the device also contains an 8-bit status register that can be accessed by rdsr and wrsr instructions. the byte defines the block write protection (bp1 and bp0) levels, write enable (wen) status, busy/rdy (/rdy) status and hardware write protect (wpben) status of the device. table 7 illustrates the format of the status register. table 7. status register format bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit1 bit 0 wpben x x x bp1 bp0 wen /rdy read status register (rdsr) the rdsr instruction provides read access to the status register. the busy/rdy and wren statuses of the device can also be determined by this instruction. in addition, the block write protection bits indicate the extent of protection employed. in order to determine the status of the device, the value of the /rdy bit can be continuously polled before sending any write instruction. table 8. read status register definition bit definition bit 0 (/rdy) bit 0 = 0 (/rdy) indicates that the device is ready. bit 0 = 1 indicates that a write cycle is in progress. bit 1 (wen) bit 1 = 0 indicates that the device is not write enabled. bit 1 = 1 indicates that the device is write enabled. bit 2 (bp0) block write protect bit 0 bit 3 (bp1) block write protect bit 1 bit 7 (wpben) write protect mode enable bit bit 7 (wpben) is hardware write protect mode. if this bit is a 1, this mode is enabled and the status register is write protected. bits 6 through 4 are always 0. bit 3 (bp1) and bit 2 (bp0) together indicate a block write protection previously sent to the device. bits 0 and 1 are 1 during an internal write cycle. bit 1 (wen) indicates the write enable status of the device. this bit is read by executing an rdsr instruction. if this bit is 1, the device is write enabled; if it is 0, it is write disabled. bit 0 (/rdy) indicates the busy/ready status of the device. this bit is a read-only bit and is read by executing an rdsr instruction. if this bit is 1, the device is busy doing a program or erase cycle; if it is 0, the device is ready.
sa25f010 advanced information saifun 19 the rdsr command requires the following sequence: 1. the csb pin is pulled low to select the device and the rdsr opcode is transmitted on the si pin. 2. the data on the si pin becomes don't care. 3. the data from the status register is shifted out on the so pins, with the d7 bit first and the d0 bit last, as shown in figure 10. 1 3 210 9 8 7 6 5 4 0 14 13 12 11 instruction 1 32 0 7654 sck so high impedance msb status register out si 15 18 17 16 22 21 20 19 1 32 0 7654 msb status register out 23 7 msb cs figure 10. read status register (rdsr) instruction sequence
sa25f010 advanced information saifun 20 write enable (wren) the device powers up in the write disable state when v cc is applied. all programming instructions must be preceded by a wren instruction. the instruction sequence is shown in figure 11, with so in high impedance. write disable (wrdi) to protect the device against inadvertent writes, the wrdi instruction disables all programming modes. the wrdi instruction is independent of the wp pin's status. the wren instruction should be executed after the wrdi instruction to re-enable all programming modes. the instruction sequence is shown in figure 12, with so in high impedance. 3 27 6 5 4 0 instruction sck si 1 cs figure 11. write enable (wren) instruction sequence 3 27 6 5 4 0 instruction sck si 1 cs figure 12. write disable (wrdi) instruction sequence
sa25f010 advanced information saifun 21 write status register (wrsr) the wrsr instruction enables the user to select one of four levels of protection. the sa25f010 is divided into four array segments. the top quarter, top half or all of the memory segments can be protected (for more details, refer to table 9). the data within a selected segment is therefore read-only. table 9. block write protect bits status register bits level bp1 bp0 array addresses protected 0 0 0 none 1/4 0 1 18000 - 1ffff 1/2 1 0 10000 - 1ffff all 1 1 00000 - 1ffff the wrsr instruction (as shown in table 11) also allows the user to enable or disable the wpb pin via the wpben bit. hardware write protection is enabled when the wpb pin is low and the wpben bit is 1, and disabled when either the wp pin is high or the wpben bit is 0. when the device is hardware write protected, writes to the status register are disabled. note: when the wpben bit is hardware write protected, it cannot be changed back to 0 while the wpb pin is held low. table 11. wpben operation wpb wpben wen protected blocks un- protected blocks status register x 0 0 protected protected protected x 0 1 protected writeable writeable low 1 0 protected protected protected low 1 1 protected writeable protected high x 0 protected protected protected high x 1 protected writeable writeable the wrsr instruction is enabled: 1. when the wpb pin is held high and the device has been previously write enabled via the wren instruction. 2. when the wpb pin is held low, the wpben bit is 0 and the device has been previously write enabled via the wren instruction.
sa25f010 advanced information saifun 22 the wrsr command requires the following sequence: 1. the csb pin is pulled low to select the device. 2. the wrsr opcode is then transmitted on the si pin, followed by the data to be programmed. the instruction sequence is shown in figure 13. instruction status register in 1 3 210 9 8 7 6 5 4 0 14 13 12 11 15 1 32 0 7654 sck si so msb high impedance cs figure 13. write status register (wrsr) instruction sequence
sa25f010 advanced information saifun 23 read data bytes (read) reading the memory via the serial spi link requires the following sequence: 1. after the csb line is pulled low to select the device, the read opcode is transmitted via the si line, followed by the 3-byte address to be read (address bits a23 to a18 are don?t care). 2. upon completion, any data on the si line is ignored. 3. the data (d7-d0) at the specified address is then shifted out onto the so line. each bit is shifted out at a maximum sck frequency of f sck . if only one byte is to be read, the csb line should be driven high after the data comes out. the read sequence can be continued, as the byte address is automatically incremented and data continues to shift out. when the highest address is reached, the address counter rolls over to the lowest address, enabling the entire memory to be read in one continuous read cycle. the instruction sequence is shown in figure 14. driving csb high terminates the read instruction, which can be done at any time during data output. any read instruction executed while an erase, program or wrsr cycle is in progress is rejected without having any effect on the cycle in progress. 1 3 210 9 8 7 6 5 4 0 31 30 29 28 instruction 24-bit address 23 21 22 1 32 0 1 32 0 7654 36 35 34 33 32 39 38 37 sck si so high impedance msb data out 1 data out 2 7 msb cs figure 14. read (read) instruction sequence
sa25f010 advanced information saifun 24 fast read (fast_read) the fast read instruction is included in the device in order for it to be compatible with other spi flash devices. both the read and fast_read instructions read the memory at the specified sck frequency (f sck ), with a maximum speed of 25 mhz. reading the memory via the serial spi link requires the following sequence: 1. after the csb line is pulled low to select the device, the read opcode is transmitted via the si line, followed by the 3-byte address and a dummy byte (address bits a23 to a18 are don?t care). 2. upon completion, any data on the si line is ignored. 3. the data (d7-d0) at the specified address is then shifted out onto the so line. each bit is shifted out at a maximum frequency of f sck . if only one byte is to be read, the csb line should be driven high after the data comes out. the read sequence can be continued, as the byte address is automatically incremented and data continues to shift out. when the highest address is reached, the address counter rolls over to the lowest address, enabling the entire memory to be read in one continuous read cycle. the instruction sequence is shown in figure 15. driving csb high terminates the fast_read instruction, which can be done at any time during data output. any fast_read instruction executed while an erase or program cycle is in progress is rejected without having any effect on the cycle in progress. 1 3 210 9 8 7 6 5 4 031 30 29 28 instruction 24-bit address 23 21 22 1 32 0 1 32 0 7654 36 35 34 33 32 39 38 37 1 32 0 7654 dummy byte 44 43 42 41 40 47 46 45 data out 1 data out 2 sck si so msb high impedance 7 msb cs figure 15. fast read (fast_read) instruction sequence
sa25f010 advanced information saifun 25 page programming (pp) the pp instruction allows bytes to be programmed in the memory (changing bits from 1 to 0). in order to program to the sa25f010, two separate instructions must be executed. the device must first be write enabled via the wren instruction, and then a pp sequence (which consists of four bytes plus data) may be executed. the address of the memory locations to be written must be outside the protected address field location selected by the block write protection level. during an internal program cycle, all commands are ignored except the rdsr instruction. a pp instruction requires the following sequence: ? = after the csb line is pulled low to select the device, the pp opcode is transmitted via the si line, followed by the byte address and the data (d7-d0) to be written. programming starts after the csb pin is brought high. the csb pin's low-to-high transition must occur during the sck low time, immediately after the clock in the d0 (lsb) data bit. the instruction sequence is shown in figure 16, page 26. as soon as csb is driven high, the self-timed pp cycle (whose duration is defined as t pp ) is initiated. while the page program cycle is in progress, the status register may be read to check the value of the write in progress (/rdy) bit. the /rdy bit is 1 during the self-timed page program cycle, and 0 when it is completed. the write enable latch (wen) bit is reset at some unspecified time before the cycle is completed. the sa25f010's pp operation is capable of up to a 256-byte programming, from 1 to 256 bytes at a time (changing bits from 1 to 0), provided that they lie in consecutive addresses on the same page of memory. after each byte is received, the eight low-order address bits are internally incremented by one. if more than 256 bytes of data are transmitted, the address counter rolls over and the previously written data is overwritten. the sa25f010 is automatically returned to the write disable state at the completion of a write cycle. notes: 1. if the device is not write enabled, the device ignores the pp instruction and returns to the standby state when csb is brought high. a new csb falling edge is required to re-initiate the serial communication. 2. a pp instruction applied to a page that is protected by the block protect (bp1, bp0) bits (as described in table 8, page 18, and table 9, page 21) is not executed.
sa25f010 advanced information saifun 26 1 3 210 9 8 7 6 5 4 031 30 29 28 instruction 24-bit address 23 21 22 1 32 0 36 35 34 33 32 39 38 37 1 32 0 7654 data byte 1 2072 1 32 0 7654 data byte 2 44 43 42 41 40 47 46 45 52 51 59 49 48 55 54 53 1 32 0 7654 data byte 3 2079 2078 2077 2076 2075 2074 2073 data byte 256 sck si sck si msb msb msb msb msb cs cs 1 32 0 7654 figure 16. page programming (pp) instruction sequence
sa25f010 advanced information saifun 27 page erase (pe) the pe instruction sets all 256 bytes in the selected page to 1. before it can be executed, two separate instructions must be carried out. the device must first be write enabled via the wren instruction, and then a pe sequence, which consists of one opcode byte and three data bytes may be executed. the address of the memory locations to be written must be inside the page to be erased and outside the protected address field location selected by the block write protection level. during an internal pe cycle, all commands are ignored except the rdsr instruction. a pe instruction requires the following sequence: 1. after the csb line is pulled low to select the device, the pe opcode is transmitted via the si line, followed by the 3-byte address. 2. erasing begins after the csb pin is brought high. the csb pin's low-to-high transition must occur during the sck low time, immediately after the clock in the last address bit. as soon as csb is driven high, the self-timed pe cycle (whose duration is defined as t pe ) is initiated. while the pe cycle is in progress, the status register may be read to check the value of the /rdy bit. the /rdy bit is 1 during the self-timed pe cycle, and 0 when it is completed. the wen bit is reset at some unspecified time before the cycle is completed. the instruction sequence is shown in figure 18. the sa25f010 is automatically returned to the write disable state at the completion of a pe cycle. notes: 1. if the device is not write enabled, the device ignores the pe instruction and returns to the standby state when csb is brought high. a new csb falling edge is required to re-initiate the serial communication. 2. a pe instruction applied to a page that is protected by the block protect (bp1, bp0) bits (as described in table 8, page 18, and table 9, page 21) is not executed. 1 3 210 9 8 7 6 5 4 0 31 30 29 28 instruction 24 bit address 1 32 0 sck si msb cs 23 21 22 figure 18. page erase (pe) instruction sequence
sa25f010 advanced information saifun 28 sector erase (se) the se instruction sets all 256 kb in the selected sector to 1. before it can be executed, two separate instructions must be carried out. the device must first be write enabled via the wren instruction, and then a se sequence, which consists of four bytes, may be executed. the address of the memory locations to be written must be inside the sector to be erased and outside the protected address field location selected by the block write protection level. during an internal se cycle, all commands are ignored except the rdsr instruction. a se instruction requires the following sequence: 1. after the csb line is pulled low to select the device, the se opcode is transmitted via the si line, followed by the 3-byte address. 2. erasing begins after the csb pin is brought high. the csb pin's low-to-high transition must occur during the sck low time, immediately after the clock in the last address bit. as soon as csb is driven high, the self-timed se cycle (whose duration is defined as t se ) is initiated. while the se cycle is in progress, the status register may be read to check the value of the /rdy bit. the /rdy bit is 1 during the self-timed se cycle, and 0 when it is completed. the wen bit is reset at some unspecified time before the cycle is completed. the instruction sequence is shown in figure 20. the sa25f010 is automatically returned to the write disable state at the completion of an se cycle. notes: 1. if the device is not write enabled, the device ignores the se instruction and returns to the standby state when csb is brought high. a new csb falling edge is required to re-initiate the serial communication. 2. a se instruction applied to a sector that is protected by the block protect (bp1, bp0) bits (as described in table 8, page 18, and table 9, page 21) is not executed. 1 3 210 9 8 7 6 5 4 0 31 30 29 28 instruction 24 bit address 23 21 22 1 32 0 sck si msb cs figure 20. sector erase (se) instruction sequence
sa25f010 advanced information saifun 29 bulk erase (be) the be instruction sets all bits in the memory array to 1. before it can be executed, two separate instructions must be carried out. the device must first be write enabled via the wren instruction, and then a be sequence, which consists of four bytes plus data, may be executed. the address of the memory locations to be written must be outside the protected address field location selected by the block write protection level. during an internal be cycle, all commands are ignored except the rdsr instruction. a be instruction requires the following sequence: 1. after the csb line is pulled low to select the device, the be opcode is transmitted via the si line. 2. erasing begins after the csb pin is brought high. the csb pin's low-to-high transition must occur during the sck low time, immediately after the clock in the last opcode bit. as soon as csb is driven high, the self-timed be cycle (whose duration is defined as t be ) is initiated. while the be cycle is in progress, the status register may be read to check the value of the /rdy bit. the /rdy bit is 1 during the self-timed be cycle, and 0 when it is completed. the wen bit is reset at some unspecified time before the cycle is completed. the instruction sequence is shown in figure 22. the sa25f010 is automatically returned to the write disable state at the completion of a be cycle. notes: 1. if the device is not write enabled, the device ignores the be instruction and returns to the standby state when csb is brought high. a new csb falling edge is required to re-initiate the serial communication. 2. a be instruction can be applied only if both block protect (bp1, bp0) bits (as described in table 8, page 18, and table 9, page 21) are 0. 3 27 6 5 4 0 instruction sck si 1 cs figure 22. bulk erase (be) instruction sequence
sa25f010 advanced information saifun 30 software protection (sp)/ deep powerdown (dp) the dp instruction is included in the device in order to be compatible with other spi flash devices, and is identical to the sp instruction. the sa25f010's low standby current of 1 a is the same in both dp and standby modes. it is recommended that the standard standby mode be used for the lowest power current draw, as well as an extra sp mechanism while the device is not in active use. this is due to the fact that while in this mode, the device ignores all write, program and erase instructions. the sp instruction is entered by driving csb low, followed by the instruction code on the si pin. csb must be driven low for the entire duration of the sequence. the instruction sequence is shown in figure 24. csb must be driven high after the eighth bit of the instruction code has been latched in; otherwise, the sp instruction is not executed. as soon as csb is driven high, it requires a delay of t dp before sp mode is entered. once the device has entered sp mode, all instructions are ignored except the release from software protect and read electronic signature (res) instructions, which release the device from this mode. res instructions also enable the electronic signature to be read on the so pin. sp mode automatically stops at powerdown, and the device always powers up in the standby mode. any sp instruction executed while an erase, program or wrsr cycle is in progress is rejected without having any effect on the cycle in progress. 1 3 27 6 5 4 0 instruction sck si t dp software protect mode standby mode cs figure 24. software protection instruction sequence
sa25f010 advanced information saifun 31 release from software protect (res) once the device has entered sp mode, all instructions are ignored except the res mode. any res instruction executed while an erase, program or write status register cycle is in progress is not decoded, and has no effect on the cycle that is in progress. the device is first selected by driving csb low, followed by an 8 - bit instruction byte, with each bit being latched in on si during the rising edge of sck. driving csb high after the 8 - bit instruction byte has been received by the device, but before the whole of the 8-bit electronic signature has been transmitted for the first time (as shown in figure 25), will still ensure that the device is put into standby mode. the transition to standby mode is delayed by t res , and csb must remain high for at least t res (max), as specified in table 4 on page 10. once in standby mode, the device waits to be selected, so that it can receive, decode and execute instructions. 1 3 27 6 5 4 0 instruction sck si t res software protect mode standby mode cs figure 25. release from software protect (res) instruction sequence
sa25f010 advanced information saifun 32 release from software protection and read electronic signature (res) once the device has entered sp mode, all instructions are ignored except the res mode. the instruction can also be used to read the 8-bit electronic signature of the device on the so pin. the res instruction always provides access to the electronic signature of the device (except while an erase, program or write status register cycle is in progress), and can be applied even if sp mode has not been entered. any res instruction executed while an erase, program or write status register cycle is in progress is not decoded, and has no effect on the cycle in progress. this instruction serves a second purpose as well. the device features an 8-bit electronic signature, whose value for the sa25f010 is 10h. this can be read using the res instruction. the device is first selected by driving csb low. the instruction code is followed by three dummy bytes, each bit being latched in on si during the rising edge of sck. the 8-bit electronic signature, which stored in the memory, is then shifted out on so, with each bit being shifted out during the falling edge of sck. the instruction sequence is shown in figure 27. driving csb high after the electronic signature has been read at least once terminates the res instruction. sending additional clock cycles on sck, while csb is driven low causes the electronic signature to be output repeatedly. when csb is driven high, the device is put into standby mode. the transition to standby mode is delayed by t res , and csb must remain high for at least t res (max), as specified in table 4 on page 10. once in standby mode, the device waits to be selected, so that it can receive, decode and execute instructions. 1 3 210 9 8 7 6 5 4 0 31 30 29 28 instruction 3 dummy bytes 23 21 22 1 32 0 36 35 34 33 32 39 38 37 sck si so high impedance msb electonic id msb t res software protect mode standby mode 1 32 0 7654 cs figure 27. release from software protection and read electronic signature (res) instruction sequence
sa25f010 advanced information saifun 33 powerup and powerdown the device must not be selected at powerup or powerdown (that is, csb must follow the voltage applied on v cc ) until v cc reaches the correct value, as follows: ? = v cc (min) at powerup, and then for a further delay of t pu (as described in table 11) ? = v ss at powerdown a simple pull-up resistor on csb can usually be used to insure safe and proper powerup and powerdown. to avoid data corruption and inadvertent write operations during powerup, a power on reset (por) circuit is included. the logic inside the device is held at reset while v cc is less than the por threshold value (v por ), all operations are disabled and the device does not respond to any instructions. the device ignores all instructions until a time delay of t pu has elapsed after the moment that v cc rises above the vwi threshold. however, correct operation of the device is not guaranteed if by this time v cc is still below v cc (min). no write status register, program or erase instructions should be sent until t pu reaches the minimum v cc threshold after v cc . at powerup, the device is in standby mode (not sp mode) and the wen bit is reset. normal precautions must be taken for supply rail decoupling to stabilize the v cc feed. each device in a system should have the v cc rail decoupled by a suitable capacitor close to the package pins (this capacitor is generally of the order of 0.1 f). all operations are disabled and the device does not respond to any instructions when v cc drops at powerdown from the operating voltage to below the v por threshold. (the designer must be aware that if a powerdown occurs while a write, program or erase cycle is in progress, data corruption can result.) table 11. powerup symbol parameter min. max . unit v por por threshold value 2.2 2.4 v t pu v cc (min) to cs low 2 ms
sa25f010 advanced information saifun 34 physical dimensions all measurements are in inches (millimeters), unless otherwise specified. figure 29. 8-pin soic package
sa25f010 advanced information saifun 35 figure 30. 8-pin mlf leadless package
sa25f010 advanced information saifun 36 figure 31. molded dual-in-line package (n) package number n08e
sa25f010 advanced information saifun 37 contact information international headquarters united states saifun semiconductors ltd. elrod building 45 hamelach st. sappir industrial park netanya 42504 israel tel.: +972-9-892-8444 fax: +972-9-892-8445 saifun semiconductors inc. 2350 mission college blvd. suite 1070 santa clara, ca 95054 u.s.a. tel: +1-408-982-5888 fax: +1-408-982-5890 email: tech_support@saifun.com http://www.saifun.com revision history rev date description of change 0.0 26-may-03 initial release 1.0 24-jul-03 modified ordering information ? saifun semiconductors ltd. 2003 saifun reserves the right, without notice, to change any of the products described in this guide, in order to improve functionality, reliability or design. saifun assumes no liability arising from the application or use of any product described in this guide; and under its patent rights, gives no authorization for the use of this product or associated products. the buyer will not hold saifun responsible for direct or indirect damages and expenses, as well as any claim of injury or death, associated with the unauthorized use, including claims of manufacture or design negligence. saifun and saifun nrom are trademarks or registered trademarks of saifun semiconductors ltd. other company and brand products and service names are trademarks or registered trademarks of their respective holders. life support policy saifun's products are not authorized for use as critical components in life support devices or systems without the express writ ten approval of the president of saifun semiconductors ltd. as used herein: 1. life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. 2. a critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.

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