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muxonenand1g(kfm1g16q2m-deb5) flash memory 1 muxonenand2g(kfn2g16q2m-deb5) muxonenand tm specification density part no. v cc (core & io) temperature pkg 1gb kfm1g16q2m-deb5 1.8v(1.7v~1.95v) extended 63fbga(lf) 2gb kfn2g16q2m-deb5 1.8v(1.7v~1.95v) extended 63fbga(lf) version: ver. 1.0 date: may 17th, 2005
muxonenand1g(kfm1g16q2m-deb5) flash memory 2 muxonenand2g(kfn2g16q2m-deb5) 1.0 introduction this specification c ontains information about the sams ung electronics company muxonenand ? ? flash memory product family. section 1.0 includes a general overview, revisi on history, and product ordering information. section 2.0 describes the muxonenand device. section 3.0 provides information about device operation. electr ical specifications and timing waveforms are in sections 4.0 though 6.0. section 7. 0 provides additional application and technical notes pertaining to use of the muxonenand. package dimensions are found in section 8.0 information in this document is provid ed in relation to samsung products, and is subject to change without notice. nothing in this document shall be construed as granting any license, express or implied, by estoppel or otherwise, to any intellectual property rights in samsung products or technology. all information in this document is provided on as "as is" basis without guarantee or warranty of any kind. 1. for updates or additional information about samsung products, contact your nearest samsung office. 2. samsung products are not intended for use in life support, critical care, medical, safety equipment, or similar applications where product failure could result in loss of life or personal or phys ical harm, or any military or defense application, or any governmental pr ocurement to which special terms or provisions may apply. muxonenand ? ? is a trademark of samsung electronics company, ltd. ot her names and brands may be claimed as the property of their rightful owners. copyright ? 2005, samsung electronics company, ltd
muxonenand1g(kfm1g16q2m-deb5) flash memory 3 muxonenand2g(kfn2g16q2m-deb5) document title muxonenand revision history revision no. 0.0 0.1 0.2 0.3 remark draft advance preliminary preliminary draft date dec. 3, 2003 may 19, 2004 nov. 4, 2004 jan. 10, 2005 history initial issue. 1. corrected the errata 2. added data protection scheme during power-down 3. ecc description is revised. 4. added read while load and write while program diagram. 5. revised and added otp description. 6. added write protection description 7. added multi block erase operation notes 8. added nand array memory map 9. rdy conf bit in system configuration register is added. 10. controller status register is revised. 11. added dc/ac parameters 12. revised otp area assignment 13. added the addressing for program operation 14. added int guidance 15. added reset descriptions. 16. revised status flag 1. updated all description with a new format 1. corrected the errata 2. revised typical value of isb from 50ua to 10ua 3. revised maximum value of isb from 100ua to 50ua 4. revised erase current as tbd 5. revised maximum value of tce, taa and tacc from 70ns to 76ns 6. revised vcc-io description 7. revised spare area description 8. added version id register information 9. added extra information on controller status register 10. added commands related to interrupt status register bits 11. revised write protection status on chapter 3.4.3 12. revised copy-back progr am operation description 13. added copy-back program operation with random data input 14. added extra information on multi-block erase operation 15. disabled fba restriction in otp operation 16. revised cache read flow chart 17. added dq6 toggle bit information on chapter 3.13 18. added isb information on ddp 19. revised reset parameter descriptions 20. added asynchronous write timing diagram 21. added rdy information on warm reset timing diagram 22. added information on data protection timing during power down 23. added toggle bit timing in asynchronous read timing diagram 24. revised interrupt pin rise and falling slope graph 25. added restriction on address register setting on dual operations 26. added restriction on address register setting on cache read operation 27. added technical note 1.1 revision history
muxonenand1g(kfm1g16q2m-deb5) flash memory 4 muxonenand2g(kfn2g16q2m-deb5) revision history revision no. 0.4 1.0 remark preliminary final draft date feb. 28, 2005 may. 17, 2005 history 1. corrected the errata 2. updated dc parameters to rms values 3. revised warm reset timing diagram 4. added int capacitance information 5. added speed information ordering information 6. added booting sequence in technical note 7. revised otp program and lock flow chart 8. revised toez description on chapter 5.5 9. revised taso value to 10ns 10. added rdy and int pin behavior before iobe=1 11. added erase suspend and resume information for multi block erase 12. added i li and i lo values for ddp on chater 4.3 1. corrected the errata 2. added data protection flow chart. 3. removed cache read operation. 4. added additional information on command register. 5. revised interrupt status register information. 6. added int pin schematic. 7. changed tpgm1 to 205 from 320us, tpgm2 to 220 from 350us. 8. revised ac/dc parameters 9. revised ecc bypass description 10. revised reset parameters and timing diagrams.
muxonenand1g(kfm1g16q2m-deb5) flash memory 5 muxonenand2g(kfn2g16q2m-deb5) samsung offers a variety of flash soluti ons including nand flash, muxonenand ? and nor flash. samsung offers flash products both component and a variety of card formats including rs-mmc, mmc, compactflash, and smartmedia. to determine which samsung flash product solution is best for your application, refer the product selector chart. application requires samsung flash products nand muxonenand ? nor fast random read ? fast sequential read ?? fast write/program ?? multi block erase ? (max 64 blocks) ? erase suspend/resume ?? copyback ? (edc) ? (ecc) lock/unlock/lock-tight ?? ecc external (hardware/software) internal x scalability ?? 1.3 ordering information k f m 1g 1 6 q 2 m - d e b 5 samsung muxonenand mem- device type m : single chip n : dual chip density 1g : 1gb 2g : 2gb operating temperature range e = extended temp. (-30 c to 85 c) page architecture 2 : 2kb page version 1st generation product line desinator b : include bad block d : daisy sample operating voltage range q : 1.8v(1.7 v to 1.95v) package d : fbga(lead free) organization x16 organization speed 5 : 54mhz 6 : 66mhz 1.2 flash product type selector
muxonenand1g(kfm1g16q2m-deb5) flash memory 6 muxonenand2g(kfn2g16q2m-deb5) the attached datasheets are prepared and approved by samsung elec tronics. samsung electronics co., ltd. reserve the right to change the specifications. sams ung electronics will evaluate and reply to y our requests and questions about device. if you h ave any questions, please c ontact the samsung branch office near you. muxonenand is a highly integrated non-volatile memory solution based around a nand flash memory array. the chip integrates system features including: ? a bootram and bootloader ? two independent bi-directional 2kb dataram buffers ? a high-speed x16 host interface ? on-chip error correction ? on-chip nor interface controller this on-chip integration enables system des igners to reduce external system logic and use high-density nand flash in applicatio ns that would otherwise have to use more nor components. muxonenand takes advantage of the higher performance nand program time, low power, and high density and combines it with the synchronous read performance of nor. the nor flash host interface makes muxo nenand an ideal solution for applications like g3 smart phones, camera phones, and mobile applications that have large, advanced mult imedia applications and operating systems, but lack a nand controller. when integrated into a samsung multi-chip-package with sa msung mobile ddr sdram, designers can complete a high-perfor- mance, small footprint solution. 1.4 architectural benefits
muxonenand1g(kfm1g16q2m-deb5) flash memory 7 muxonenand2g(kfn2g16q2m-deb5) device architecture ? design technology: ? supply voltage: ? host interface: ? 5kb internal bufferram: ? slc nand array: device performance ? host interface type: - up to 54mhz clock frequenc y - linear burst 4-, 8-, 16, 3 2-words with wrap around - continuous 1k word sequent ial burst ? programmable burst read latency ? multiple sector read: ? multiple reset modes: ? multi block erase ? low power dissipation: - standby current : 10ua - synchronous burst read cur rent(54mhz) : 12ma - load current : 30ma - program current : 25ma - erase current : 20ma - multi block erase current : 20ma ? reliable cmos floating-gate technology - endurance : 100k program/erase cycles - data retention : 10 years system hardware ? voltage detector generating internal reset signal from vcc ? hardware reset input (/rp) ? data protection modes ? user-controlled one time programmable(otp) area ? internal 2bit edc / 1bit ecc ? internal bootloader supports booting solution in system ? handshaking feature ? detailed chip information packaging ? 1g products ? 2g ddp products 90nm 1.8v (1.7v ~ 1.95v) 16 bit 1kb bootram, 4kb dataram (2k+64)b page size, (128k+4k)b block size synchronous burst read asynchronous random read - 76ns access time asynchronous random write latency 3(up to 40mhz), 4, 5, 6, and 7 up to 4 sectors using sector count register cold/warm/hot/nand flash resets up to 64 blocks typical power, - write protection for bootram - write protection for nand flash array - write protection during power-up - write protection during power-down - int pin indicates ready / busy - polling the interrupt register status bit - by id register 63ball, 10mm x 13mm x max 1.0mmt , 0.8mm ball pitch fbga 63ball, 11mm x 13mm x max 1.2mmt , 0.8mm ball pitch fbga (tbd) 1.5 product features
muxonenand1g(kfm1g16q2m-deb5) flash memory 8 muxonenand2g(kfn2g16q2m-deb5) muxonenand ? ? is a monolithic integrated circuit with a nand flash ar ray using a nor flash interfac e. this device includes con- trol logic, a nand flash array, and 5kb of internal bufferram. the bufferram reserves 1kb for boot code buffering (bootram) and 4kb for data buffering (dataram), split between 2 independent buffers . it has a x16 host interface and a random access time spe ed of ~76ns. the device operates up to a maximum host-dr iven clock frequency of 54mhz for synchronous reads at vcc(or vccq. refer to chapter 4.2) with minimum 4-clock latency. below 40mhz it is accessible with minimum 3-clock lat ency. appropriate wait cycles are deter- mined by programmable read latency. muxonenand provides for multiple sector read operations by assigning the number of se ctors to be read in the sector counter register. the device includes one block-sized otp (one time programmable) area that can be used to increase system security or to provide identific ation capabilities. 1.6 general overview
muxonenand1g(kfm1g16q2m-deb5) flash memory 9 muxonenand2g(kfn2g16q2m-deb5) 2.1 detailed product description the muxonenand is an advanced generation, hi gh-performance nand-based flash memory. it integrates on-chip a single-level-cell (slc) nand flash arra y memory with two independent data buffers, boot ram buffer, a p age buffer for the flash array, and a one-time-programmable block. the combination of these memory areas enabl e high-speed pipelining of reads from host , bufferram , page buffer , and nand flash array. clock speeds up to 54mhz with a x16 wi de i/o yields a 68mbyte/second bandwidth. the muxonenand also includes a boot ram and boot loader. this enables the device to efficiently load boot code at device startu p from the nand array without the need for off-chip boot device. one block of the nand array is set aside as an otp memory area. this area, available to the us er, can be configured and locked with secured user information. on-chip controller interfaces ena ble the device to operate in systems without nand host controllers. 2.0 device description
muxonenand1g(kfm1g16q2m-deb5) flash memory 10 muxonenand2g(kfn2g16q2m-deb5) b (capital letter) byte, 8bits w (capital letter) word, 16bits b (lower-case letter) bit ecc error correction code calculated ecc ecc that has been calculated during a load or program access written ecc ecc that has been stored as data in the nand flash array or in the bufferram bufferram on-chip internal buffer consisting of bootram and dataram bootram a 1kb portion of the bufferram reserved for boot code buffering dataram a 4kb portion of the bufferram reserved for data buffering sector part of a page of which 512b is the main data area and 16b is the spare data area. it is also the minimum load/pr ogram/copy-back program unit during a 1~4 sector operation is available. data unit possible data unit to be read from memory to bufferram or to be programmed to memory. - 528b of which 512b is in main area and 16b in spare area - 1056b of which 1024b is in main area and 32b in spare area - 1584b of which 1536b is in main area and 48b in spare area - 2112b of which 2048b is in main area and 64b in spare area 2.2 definitions
muxonenand1g(kfm1g16q2m-deb5) flash memory 11 muxonenand2g(kfn2g16q2m-deb5) nc nc nc nc int nc nc nc nc nc nc nc nc we rp adq1 v ss v ss adq2 adq3 adq7 adq14 oe adq6 v cc adq8 adq11 adq4 adq5 adq12 v cc adq0 nc adq15 adq10 adq9 ce adq13 nc nc nc avd nc nc nc nc nc nc nc nc nc nc nc nc nc nc nc nc core io clk nc nc nc rdy (top view, balls facing down) 63ball fbga muxonenand chip single chip : 63ball, 10mm x 13mm x max 1.0mmt , 0.8mm ball pitch fbga 2.3.1 1gb product / 2gb prod uct (kfm1g16q2m/kfn2g16q2m) ddp : 63ball, 11mm x 13mm x max 1.2mmt , 0.8mm ball pitch fbga 2.3 pin configuration
muxonenand1g(kfm1g16q2m-deb5) flash memory 12 muxonenand2g(kfn2g16q2m-deb5) note: do not leave power supply(vcc-core/vcc-io, v ss ) disconnected. pin name type name and description host interface adq15~adq0 i/o multiplexed address/data bus - inputs for addresses during read operation, which are for addressing bufferram & register. - inputs data during program and commands for all operations, outputs data during memory array/ register read cycles. data pins float to high-impedance when t he chip is deselected or outputs are disabled. int o interrupt notifies the host when a command is completed. it is open drain output with internal resistor(~50kohms). after power-up, it is at hi-z condition. once iobe is set to 1, it does not float to hi-z condition even when t he chip is deselected or when outputs are disabled. rdy o ready indicates data valid in synchronous read modes and is activated while ce is low clk i clock clk synchronizes the device to the syst em bus frequency in synchronous read mode. the first rising edge of clk in conjunction with avd low latches address input. we i write enable we controls writes to the bufferram and registers. datas are latched on the we pulse?s rising edge avd i address valid detect indicates valid address presence on address inputs. during asynchronous read operation, all addresses are latched on avd ?s rising edge, and during synchronous read operation, all addresses are latched on clk?s rising edge while avd is held low for one clock cycle. > low : for asynchronous mode, indicates valid address ;for burst mode, causes starting address to be latched on rising edge on clk > high : device ignores address inputs rp i reset pin when low, rp resets internal operation of muxonenand. rp status is don?t care during power-up and bootloading. ce i chip enable ce -low activates internal control logic, and ce -high deselects the device, places it in standby state, and places a/dq in hi-z oe i output enable oe -low enables the device?s output data buffers during a read cycle. power supply v cc -core / vcc power for muxonenand core this is the power supply for muxonenand core. v cc -io / vccq power for muxonenand i/o this is the power supply for muxonenand i/o vcc-io / vccq is internally se parated from vcc-core / vcc. v ss ground for muxonenand etc. dnu do not use leave it disconnected. these pins are used for testing. nc no connection lead is not internally connected. 2.4 pin description
muxonenand1g(kfm1g16q2m-deb5) flash memory 13 muxonenand2g(kfn2g16q2m-deb5) bootram host interface clk ce oe we rp avd statemachine bootloader internal registers (address/command/configuration /status registers) error correction logic int dataram0 bufferram nand flash array otp (one block) rdy adq15~adq0 2.6 memory array organization the muxonenand architecture integrates several memory areas on a single chip. 2.6.1 internal (nand arra y) memory organization the on-chip internal memory is a single-level-cell (slc) nand array used for data storage and code. the internal memory is divi ded into a main area and a spare area. main area the main area is the primary memory array. this main area is divided into blocks of 64 pages. within a block, each page is 2k b and is comprised of 4 sectors. within a page, each sector is 512b and is comprised of 256 words. spare area the spare area is used for invalid block information and ecc st orage. spare area internal memory is associated with correspondi ng main area memory. within a block, each page has four 16b sectors of spare area. each spare area sector is 8 words. dataram1 2.5 block diagram
muxonenand1g(kfm1g16q2m-deb5) flash memory 14 muxonenand2g(kfn2g16q2m-deb5) internal memory array information internal memory array organization area block page sector main 128kb 2kb 512b spare 4kb 64b 16b 2kb page0 512b 16b 64b page0 2kb page63 64b page63 sector main area spare area block page main area spare area 2kb 64b main area spare area 128kb 4kb page 0 page 63 512b sector0 512b sector1 512b sector2 512b sector3 16b sector0 16b sector1 16b sector2 16b sector3
muxonenand1g(kfm1g16q2m-deb5) flash memory 15 muxonenand2g(kfn2g16q2m-deb5) the on-chip external memory is comprised of 3 buffers used for boot code storage and data buffering. the bootram is a 1kb buffer that receives boot code from the inte rnal memory and makes it available to the host at start up. there are two independent 2kb bi-directional data buffers, dataram0 and dataram1. these dual buffers enable the host to execute simultaneous read-while load, and write-while-program operations af ter boot up. during boot up, the bootram is used by the host to initialize the main memory, and deliver boot code from nand flash core to host. the external memory is divided into a main area and a sp are area. each buffer is the equivalent size of a sector. the main area data is 512b. the spare area data is 16b. external memory array information area bootram dataram0 dataram1 total size 1kb+32b 2kb+64b 2kb+64b number of sectors 2 4 4 sector main 512b 512b 512b spare 16b 16b 16b host otp block nand array boot code (1kb) bootram (1kb) dataram0 (2kb) dataram1 (2kb) external (bufferram) memory internal (nand array) memory 2.6.2 external (buffer ram) memory organization
muxonenand1g(kfm1g16q2m-deb5) flash memory 16 muxonenand2g(kfn2g16q2m-deb5) external memory array organization bootram 0 bootram 1 bootram dataram 1_0 dataram 1_1 dataram 1_2 dataram 1_3 dataram1 { main area data spare area data dataram 0_0 dataram 0_1 dataram 0_2 dataram 0_3 dataram0 sector: (512 + 16) byte { (512b) (16b)
muxonenand1g(kfm1g16q2m-deb5) flash memory 17 muxonenand2g(kfn2g16q2m-deb5) the following tables are the memory maps for the muxonenand. 2.7.1 internal (nand arr ay) memory organization the following tables show the internal memory address map in word order. block block address page and sector address size block block address page and sector address size block0 0000h 0000h~00ffh 128kb block32 0020h 0000h~00ffh 128kb block1 0001h 0000h~00ffh 128kb block33 0021h 0000h~00ffh 128kb block2 0002h 0000h~00ffh 128kb block34 0022h 0000h~00ffh 128kb block3 0003h 0000h~00ffh 128kb block35 0023h 0000h~00ffh 128kb block4 0004h 0000h~00ffh 128kb block36 0024h 0000h~00ffh 128kb block5 0005h 0000h~00ffh 128kb block37 0025h 0000h~00ffh 128kb block6 0006h 0000h~00ffh 128kb block38 0026h 0000h~00ffh 128kb block7 0007h 0000h~00ffh 128kb block39 0027h 0000h~00ffh 128kb block8 0008h 0000h~00ffh 128kb block40 0028h 0000h~00ffh 128kb block9 0009h 0000h~00ffh 128kb block41 0029h 0000h~00ffh 128kb block10 000ah 0000h~00ffh 128kb block42 002ah 0000h~00ffh 128kb block11 000bh 0000h~00ffh 128kb block43 002bh 0000h~00ffh 128kb block12 000ch 0000h~00ffh 128kb block44 002ch 0000h~00ffh 128kb block13 000dh 0000h~00ffh 128kb block45 002dh 0000h~00ffh 128kb block14 000eh 0000h~00ffh 128kb block46 002eh 0000h~00ffh 128kb block15 000fh 0000h~00ffh 128kb block47 002fh 0000h~00ffh 128kb block16 0010h 0000h~00ffh 128kb block48 0030h 0000h~00ffh 128kb block17 0011h 0000h~00ffh 128kb block49 0031h 0000h~00ffh 128kb block18 0012h 0000h~00ffh 128kb block50 0032h 0000h~00ffh 128kb block19 0013h 0000h~00ffh 128kb block51 0033h 0000h~00ffh 128kb block20 0014h 0000h~00ffh 128kb block52 0034h 0000h~00ffh 128kb block21 0015h 0000h~00ffh 128kb block53 0035h 0000h~00ffh 128kb block22 0016h 0000h~00ffh 128kb block54 0036h 0000h~00ffh 128kb block23 0017h 0000h~00ffh 128kb block55 0037h 0000h~00ffh 128kb block24 0018h 0000h~00ffh 128kb block56 0038h 0000h~00ffh 128kb block25 0019h 0000h~00ffh 128kb block57 0039h 0000h~00ffh 128kb block26 001ah 0000h~00ffh 128kb block58 003ah 0000h~00ffh 128kb block27 001bh 0000h~00ffh 128kb block59 003bh 0000h~00ffh 128kb block28 001ch 0000h~00ffh 128kb block60 003ch 0000h~00ffh 128kb block29 001dh 0000h~00ffh 128kb block61 003dh 0000h~00ffh 128kb block30 001eh 0000h~00ffh 128kb block62 003eh 0000h~00ffh 128kb block31 001fh 0000h~00ffh 128kb block63 003fh 0000h~00ffh 128kb 2.7 memory map
muxonenand1g(kfm1g16q2m-deb5) flash memory 18 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block64 0040h 0000h~00ffh 128kb block96 0060h 0000h~00ffh 128kb block65 0041h 0000h~00ffh 128kb block97 0061h 0000h~00ffh 128kb block66 0042h 0000h~00ffh 128kb block98 0062h 0000h~00ffh 128kb block67 0043h 0000h~00ffh 128kb block99 0063h 0000h~00ffh 128kb block68 0044h 0000h~00ffh 128kb block100 0064h 0000h~00ffh 128kb block69 0045h 0000h~00ffh 128kb block101 0065h 0000h~00ffh 128kb block70 0046h 0000h~00ffh 128kb block102 0066h 0000h~00ffh 128kb block71 0047h 0000h~00ffh 128kb block103 0067h 0000h~00ffh 128kb block72 0048h 0000h~00ffh 128kb block104 0068h 0000h~00ffh 128kb block73 0049h 0000h~00ffh 128kb block105 0069h 0000h~00ffh 128kb block74 004ah 0000h~00ffh 128kb block106 006ah 0000h~00ffh 128kb block75 004bh 0000h~00ffh 128kb block107 006bh 0000h~00ffh 128kb block76 004ch 0000h~00ffh 128kb block108 006ch 0000h~00ffh 128kb block77 004dh 0000h~00ffh 128kb block109 006dh 0000h~00ffh 128kb block78 004eh 0000h~00ffh 128kb block110 006eh 0000h~00ffh 128kb block79 004fh 0000h~00ffh 128kb block111 006fh 0000h~00ffh 128kb block80 0050h 0000h~00ffh 128kb block112 0070h 0000h~00ffh 128kb block81 0051h 0000h~00ffh 128kb block113 0071h 0000h~00ffh 128kb block82 0052h 0000h~00ffh 128kb block114 0072h 0000h~00ffh 128kb block83 0053h 0000h~00ffh 128kb block115 0073h 0000h~00ffh 128kb block84 0054h 0000h~00ffh 128kb block116 0074h 0000h~00ffh 128kb block85 0055h 0000h~00ffh 128kb block117 0075h 0000h~00ffh 128kb block86 0056h 0000h~00ffh 128kb block118 0076h 0000h~00ffh 128kb block87 0057h 0000h~00ffh 128kb block119 0077h 0000h~00ffh 128kb block88 0058h 0000h~00ffh 128kb block120 0078h 0000h~00ffh 128kb block89 0059h 0000h~00ffh 128kb block121 0079h 0000h~00ffh 128kb block90 005ah 0000h~00ffh 128kb block122 007ah 0000h~00ffh 128kb block91 005bh 0000h~00ffh 128kb block123 007bh 0000h~00ffh 128kb block92 005ch 0000h~00ffh 128kb block124 007ch 0000h~00ffh 128kb block93 005dh 0000h~00ffh 128kb block125 007dh 0000h~00ffh 128kb block94 005eh 0000h~00ffh 128kb block126 007eh 0000h~00ffh 128kb block95 005fh 0000h~00ffh 128kb block127 007fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 19 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block128 0080h 0000h~00ffh 128kb block160 00a0h 0000h~00ffh 128kb block129 0081h 0000h~00ffh 128kb block161 00a1h 0000h~00ffh 128kb block130 0082h 0000h~00ffh 128kb block162 00a2h 0000h~00ffh 128kb block131 0083h 0000h~00ffh 128kb block163 00a3h 0000h~00ffh 128kb block132 0084h 0000h~00ffh 128kb block164 00a4h 0000h~00ffh 128kb block133 0085h 0000h~00ffh 128kb block165 00a5h 0000h~00ffh 128kb block134 0086h 0000h~00ffh 128kb block166 00a6h 0000h~00ffh 128kb block135 0087h 0000h~00ffh 128kb block167 00a7h 0000h~00ffh 128kb block136 0088h 0000h~00ffh 128kb block168 00a8h 0000h~00ffh 128kb block137 0089h 0000h~00ffh 128kb block169 00a9h 0000h~00ffh 128kb block138 008ah 0000h~00ffh 128kb block170 00aah 0000h~00ffh 128kb block139 008bh 0000h~00ffh 128kb block171 00abh 0000h~00ffh 128kb block140 008ch 0000h~00ffh 128kb block172 00ach 0000h~00ffh 128kb block141 008dh 0000h~00ffh 128kb block173 00adh 0000h~00ffh 128kb block142 008eh 0000h~00ffh 128kb block174 00aeh 0000h~00ffh 128kb block143 008fh 0000h~00ffh 128kb block175 00afh 0000h~00ffh 128kb block144 0090h 0000h~00ffh 128kb block176 00b0h 0000h~00ffh 128kb block145 0091h 0000h~00ffh 128kb block177 00b1h 0000h~00ffh 128kb block146 0092h 0000h~00ffh 128kb block178 00b2h 0000h~00ffh 128kb block147 0093h 0000h~00ffh 128kb block179 00b3h 0000h~00ffh 128kb block148 0094h 0000h~00ffh 128kb block180 00b4h 0000h~00ffh 128kb block149 0095h 0000h~00ffh 128kb block181 00b5h 0000h~00ffh 128kb block150 0096h 0000h~00ffh 128kb block182 00b6h 0000h~00ffh 128kb block151 0097h 0000h~00ffh 128kb block183 00b7h 0000h~00ffh 128kb block152 0098h 0000h~00ffh 128kb block184 00b8h 0000h~00ffh 128kb block153 0099h 0000h~00ffh 128kb block185 00b9h 0000h~00ffh 128kb block154 009ah 0000h~00ffh 128kb block186 00bah 0000h~00ffh 128kb block155 009bh 0000h~00ffh 128kb block187 00bbh 0000h~00ffh 128kb block156 009ch 0000h~00ffh 128kb block188 00bch 0000h~00ffh 128kb block157 009dh 0000h~00ffh 128kb block189 00bdh 0000h~00ffh 128kb block158 009eh 0000h~00ffh 128kb block190 00beh 0000h~00ffh 128kb block159 009fh 0000h~00ffh 128kb block191 00bfh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 20 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block192 00c0h 0000h~00ffh 128kb block224 00e0h 0000h~00ffh 128kb block193 00c1h 0000h~00ffh 128kb block225 00e1h 0000h~00ffh 128kb block194 00c2h 0000h~00ffh 128kb block226 00e2h 0000h~00ffh 128kb block195 00c3h 0000h~00ffh 128kb block227 00e3h 0000h~00ffh 128kb block196 00c4h 0000h~00ffh 128kb block228 00e4h 0000h~00ffh 128kb block197 00c5h 0000h~00ffh 128kb block229 00e5h 0000h~00ffh 128kb block198 00c6h 0000h~00ffh 128kb block230 00e6h 0000h~00ffh 128kb block199 00c7h 0000h~00ffh 128kb block231 00e7h 0000h~00ffh 128kb block200 00c8h 0000h~00ffh 128kb block232 00e8h 0000h~00ffh 128kb block201 00c9h 0000h~00ffh 128kb block233 00e9h 0000h~00ffh 128kb block202 00cah 0000h~00ffh 128kb block234 00eah 0000h~00ffh 128kb block203 00cbh 0000h~00ffh 128kb block235 00ebh 0000h~00ffh 128kb block204 00cch 0000h~00ffh 128kb block236 00ech 0000h~00ffh 128kb block205 00cdh 0000h~00ffh 128kb block237 00edh 0000h~00ffh 128kb block206 00ceh 0000h~00ffh 128kb block238 00eeh 0000h~00ffh 128kb block207 00cfh 0000h~00ffh 128kb block239 00efh 0000h~00ffh 128kb block208 00d0h 0000h~00ffh 128kb block240 00f0h 0000h~00ffh 128kb block209 00d1h 0000h~00ffh 128kb block241 00f1h 0000h~00ffh 128kb block210 00d2h 0000h~00ffh 128kb block242 00f2h 0000h~00ffh 128kb block211 00d3h 0000h~00ffh 128kb block243 00f3h 0000h~00ffh 128kb block212 00d4h 0000h~00ffh 128kb block244 00f4h 0000h~00ffh 128kb block213 00d5h 0000h~00ffh 128kb block245 00f5h 0000h~00ffh 128kb block214 00d6h 0000h~00ffh 128kb block246 00f6h 0000h~00ffh 128kb block215 00d7h 0000h~00ffh 128kb block247 00f7h 0000h~00ffh 128kb block216 00d8h 0000h~00ffh 128kb block248 00f8h 0000h~00ffh 128kb block217 00d9h 0000h~00ffh 128kb block249 00f9h 0000h~00ffh 128kb block218 00dah 0000h~00ffh 128kb block250 00fah 0000h~00ffh 128kb block219 00dbh 0000h~00ffh 128kb block251 00fbh 0000h~00ffh 128kb block220 00dch 0000h~00ffh 128kb block252 00fch 0000h~00ffh 128kb block221 00ddh 0000h~00ffh 128kb block253 00fdh 0000h~00ffh 128kb block222 00deh 0000h~00ffh 128kb block254 00feh 0000h~00ffh 128kb block223 00dfh 0000h~00ffh 128kb block255 00ffh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 21 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block256 0100h 0000h~00ffh 128kb block288 0120h 0000h~00ffh 128kb block257 0101h 0000h~00ffh 128kb block289 0121h 0000h~00ffh 128kb block258 0102h 0000h~00ffh 128kb block290 0122h 0000h~00ffh 128kb block259 0103h 0000h~00ffh 128kb block291 0123h 0000h~00ffh 128kb block260 0104h 0000h~00ffh 128kb block292 0124h 0000h~00ffh 128kb block261 0105h 0000h~00ffh 128kb block293 0125h 0000h~00ffh 128kb block262 0106h 0000h~00ffh 128kb block294 0126h 0000h~00ffh 128kb block263 0107h 0000h~00ffh 128kb block295 0127h 0000h~00ffh 128kb block264 0108h 0000h~00ffh 128kb block296 0128h 0000h~00ffh 128kb block265 0109h 0000h~00ffh 128kb block297 0129h 0000h~00ffh 128kb block266 010ah 0000h~00ffh 128kb block298 012ah 0000h~00ffh 128kb block267 010bh 0000h~00ffh 128kb block299 012bh 0000h~00ffh 128kb block268 010ch 0000h~00ffh 128kb block300 012ch 0000h~00ffh 128kb block269 010dh 0000h~00ffh 128kb block301 012dh 0000h~00ffh 128kb block270 010eh 0000h~00ffh 128kb block302 012eh 0000h~00ffh 128kb block271 010fh 0000h~00ffh 128kb block303 012fh 0000h~00ffh 128kb block272 0110h 0000h~00ffh 128kb block304 0130h 0000h~00ffh 128kb block273 0111h 0000h~00ffh 128kb block305 0131h 0000h~00ffh 128kb block274 0112h 0000h~00ffh 128kb block306 0132h 0000h~00ffh 128kb block275 0113h 0000h~00ffh 128kb block307 0133h 0000h~00ffh 128kb block276 0114h 0000h~00ffh 128kb block308 0134h 0000h~00ffh 128kb block277 0115h 0000h~00ffh 128kb block309 0135h 0000h~00ffh 128kb block278 0116h 0000h~00ffh 128kb block310 0136h 0000h~00ffh 128kb block279 0117h 0000h~00ffh 128kb block311 0137h 0000h~00ffh 128kb block280 0118h 0000h~00ffh 128kb block312 0138h 0000h~00ffh 128kb block281 0119h 0000h~00ffh 128kb block313 0139h 0000h~00ffh 128kb block282 011ah 0000h~00ffh 128kb block314 013ah 0000h~00ffh 128kb block283 011bh 0000h~00ffh 128kb block315 013bh 0000h~00ffh 128kb block284 011ch 0000h~00ffh 128kb block316 013ch 0000h~00ffh 128kb block285 011dh 0000h~00ffh 128kb block317 013dh 0000h~00ffh 128kb block286 011eh 0000h~00ffh 128kb block318 013eh 0000h~00ffh 128kb block287 011fh 0000h~00ffh 128kb block319 013fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 22 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block320 0140h 0000h~00ffh 128kb block352 0160h 0000h~00ffh 128kb block321 0141h 0000h~00ffh 128kb block353 0161h 0000h~00ffh 128kb block322 0142h 0000h~00ffh 128kb block354 0162h 0000h~00ffh 128kb block323 0143h 0000h~00ffh 128kb block355 0163h 0000h~00ffh 128kb block324 0144h 0000h~00ffh 128kb block356 0164h 0000h~00ffh 128kb block325 0145h 0000h~00ffh 128kb block357 0165h 0000h~00ffh 128kb block326 0146h 0000h~00ffh 128kb block358 0166h 0000h~00ffh 128kb block327 0147h 0000h~00ffh 128kb block359 0167h 0000h~00ffh 128kb block328 0148h 0000h~00ffh 128kb block360 0168h 0000h~00ffh 128kb block329 0149h 0000h~00ffh 128kb block361 0169h 0000h~00ffh 128kb block330 014ah 0000h~00ffh 128kb block362 016ah 0000h~00ffh 128kb block331 014bh 0000h~00ffh 128kb block363 016bh 0000h~00ffh 128kb block332 014ch 0000h~00ffh 128kb block364 016ch 0000h~00ffh 128kb block333 014dh 0000h~00ffh 128kb block365 016dh 0000h~00ffh 128kb block334 014eh 0000h~00ffh 128kb block366 016eh 0000h~00ffh 128kb block335 014fh 0000h~00ffh 128kb block367 016fh 0000h~00ffh 128kb block336 0150h 0000h~00ffh 128kb block368 0170h 0000h~00ffh 128kb block337 0151h 0000h~00ffh 128kb block369 0171h 0000h~00ffh 128kb block338 0152h 0000h~00ffh 128kb block370 0172h 0000h~00ffh 128kb block339 0153h 0000h~00ffh 128kb block371 0173h 0000h~00ffh 128kb block340 0154h 0000h~00ffh 128kb block372 0174h 0000h~00ffh 128kb block341 0155h 0000h~00ffh 128kb block373 0175h 0000h~00ffh 128kb block342 0156h 0000h~00ffh 128kb block374 0176h 0000h~00ffh 128kb block343 0157h 0000h~00ffh 128kb block375 0177h 0000h~00ffh 128kb block344 0158h 0000h~00ffh 128kb block376 0178h 0000h~00ffh 128kb block345 0159h 0000h~00ffh 128kb block377 0179h 0000h~00ffh 128kb block346 015ah 0000h~00ffh 128kb block378 017ah 0000h~00ffh 128kb block347 015bh 0000h~00ffh 128kb block379 017bh 0000h~00ffh 128kb block348 015ch 0000h~00ffh 128kb block380 017ch 0000h~00ffh 128kb block349 015dh 0000h~00ffh 128kb block381 017dh 0000h~00ffh 128kb block350 015eh 0000h~00ffh 128kb block382 017eh 0000h~00ffh 128kb block351 015fh 0000h~00ffh 128kb block383 017fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 23 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block384 0180h 0000h~00ffh 128kb block416 01a0h 0000h~00ffh 128kb block385 0181h 0000h~00ffh 128kb block417 01a1h 0000h~00ffh 128kb block386 0182h 0000h~00ffh 128kb block418 01a2h 0000h~00ffh 128kb block387 0183h 0000h~00ffh 128kb block419 01a3h 0000h~00ffh 128kb block388 0184h 0000h~00ffh 128kb block420 01a4h 0000h~00ffh 128kb block389 0185h 0000h~00ffh 128kb block421 01a5h 0000h~00ffh 128kb block390 0186h 0000h~00ffh 128kb block422 01a6h 0000h~00ffh 128kb block391 0187h 0000h~00ffh 128kb block423 01a7h 0000h~00ffh 128kb block392 0188h 0000h~00ffh 128kb block424 01a8h 0000h~00ffh 128kb block393 0189h 0000h~00ffh 128kb block425 01a9h 0000h~00ffh 128kb block394 018ah 0000h~00ffh 128kb block426 01aah 0000h~00ffh 128kb block395 018bh 0000h~00ffh 128kb block427 01abh 0000h~00ffh 128kb block396 018ch 0000h~00ffh 128kb block428 01ach 0000h~00ffh 128kb block397 018dh 0000h~00ffh 128kb block429 01adh 0000h~00ffh 128kb block398 018eh 0000h~00ffh 128kb block430 01aeh 0000h~00ffh 128kb block399 018fh 0000h~00ffh 128kb block431 01afh 0000h~00ffh 128kb block400 0190h 0000h~00ffh 128kb block432 01b0h 0000h~00ffh 128kb block401 0191h 0000h~00ffh 128kb block433 01b1h 0000h~00ffh 128kb block402 0192h 0000h~00ffh 128kb block434 01b2h 0000h~00ffh 128kb block403 0193h 0000h~00ffh 128kb block435 01b3h 0000h~00ffh 128kb block404 0194h 0000h~00ffh 128kb block436 01b4h 0000h~00ffh 128kb block405 0195h 0000h~00ffh 128kb block437 01b5h 0000h~00ffh 128kb block406 0196h 0000h~00ffh 128kb block438 01b6h 0000h~00ffh 128kb block407 0197h 0000h~00ffh 128kb block439 01b7h 0000h~00ffh 128kb block408 0198h 0000h~00ffh 128kb block440 01b8h 0000h~00ffh 128kb block409 0199h 0000h~00ffh 128kb block441 01b9h 0000h~00ffh 128kb block410 019ah 0000h~00ffh 128kb block442 01bah 0000h~00ffh 128kb block411 019bh 0000h~00ffh 128kb block443 01bbh 0000h~00ffh 128kb block412 019ch 0000h~00ffh 128kb block444 01bch 0000h~00ffh 128kb block413 019dh 0000h~00ffh 128kb block445 01bdh 0000h~00ffh 128kb block414 019eh 0000h~00ffh 128kb block446 01beh 0000h~00ffh 128kb block415 019fh 0000h~00ffh 128kb block447 01bfh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 24 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block448 01c0h 0000h~00ffh 128kb block480 01e0h 0000h~00ffh 128kb block449 01c1h 0000h~00ffh 128kb block481 01e1h 0000h~00ffh 128kb block450 01c2h 0000h~00ffh 128kb block482 01e2h 0000h~00ffh 128kb block451 01c3h 0000h~00ffh 128kb block483 01e3h 0000h~00ffh 128kb block452 01c4h 0000h~00ffh 128kb block484 01e4h 0000h~00ffh 128kb block453 01c5h 0000h~00ffh 128kb block485 01e5h 0000h~00ffh 128kb block454 01c6h 0000h~00ffh 128kb block486 01e6h 0000h~00ffh 128kb block455 01c7h 0000h~00ffh 128kb block487 01e7h 0000h~00ffh 128kb block456 01c8h 0000h~00ffh 128kb block488 01e8h 0000h~00ffh 128kb block457 01c9h 0000h~00ffh 128kb block489 01e9h 0000h~00ffh 128kb block458 01cah 0000h~00ffh 128kb block490 01eah 0000h~00ffh 128kb block459 01cbh 0000h~00ffh 128kb block491 01ebh 0000h~00ffh 128kb block460 01cch 0000h~00ffh 128kb block492 01ech 0000h~00ffh 128kb block461 01cdh 0000h~00ffh 128kb block493 01edh 0000h~00ffh 128kb block462 01ceh 0000h~00ffh 128kb block494 01eeh 0000h~00ffh 128kb block463 01cfh 0000h~00ffh 128kb block495 01efh 0000h~00ffh 128kb block464 01d0h 0000h~00ffh 128kb block496 01f0h 0000h~00ffh 128kb block465 01d1h 0000h~00ffh 128kb block497 01f1h 0000h~00ffh 128kb block466 01d2h 0000h~00ffh 128kb block498 01f2h 0000h~00ffh 128kb block467 01d3h 0000h~00ffh 128kb block499 01f3h 0000h~00ffh 128kb block468 01d4h 0000h~00ffh 128kb block500 01f4h 0000h~00ffh 128kb block469 01d5h 0000h~00ffh 128kb block501 01f5h 0000h~00ffh 128kb block470 01d6h 0000h~00ffh 128kb block502 01f6h 0000h~00ffh 128kb block471 01d7h 0000h~00ffh 128kb block503 01f7h 0000h~00ffh 128kb block472 01d8h 0000h~00ffh 128kb block504 01f8h 0000h~00ffh 128kb block473 01d9h 0000h~00ffh 128kb block505 01f9h 0000h~00ffh 128kb block474 01dah 0000h~00ffh 128kb block506 01fah 0000h~00ffh 128kb block475 01dbh 0000h~00ffh 128kb block507 01fbh 0000h~00ffh 128kb block476 01dch 0000h~00ffh 128kb block508 01fch 0000h~00ffh 128kb block477 01ddh 0000h~00ffh 128kb block509 01fdh 0000h~00ffh 128kb block478 01deh 0000h~00ffh 128kb block510 01feh 0000h~00ffh 128kb block479 01dfh 0000h~00ffh 128kb block511 01ffh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 25 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block512 0200h 0000h~00ffh 128kb block544 0220h 0000h~00ffh 128kb block513 0201h 0000h~00ffh 128kb block545 0221h 0000h~00ffh 128kb block514 0202h 0000h~00ffh 128kb block546 0222h 0000h~00ffh 128kb block515 0203h 0000h~00ffh 128kb block547 0223h 0000h~00ffh 128kb block516 0204h 0000h~00ffh 128kb block548 0224h 0000h~00ffh 128kb block517 0205h 0000h~00ffh 128kb block549 0225h 0000h~00ffh 128kb block518 0206h 0000h~00ffh 128kb block550 0226h 0000h~00ffh 128kb block519 0207h 0000h~00ffh 128kb block551 0227h 0000h~00ffh 128kb block520 0208h 0000h~00ffh 128kb block552 0228h 0000h~00ffh 128kb block521 0209h 0000h~00ffh 128kb block553 0229h 0000h~00ffh 128kb block522 020ah 0000h~00ffh 128kb block554 022ah 0000h~00ffh 128kb block523 020bh 0000h~00ffh 128kb block555 022bh 0000h~00ffh 128kb block524 020ch 0000h~00ffh 128kb block556 022ch 0000h~00ffh 128kb block525 020dh 0000h~00ffh 128kb block557 022dh 0000h~00ffh 128kb block526 020eh 0000h~00ffh 128kb block558 022eh 0000h~00ffh 128kb block527 020fh 0000h~00ffh 128kb block559 022fh 0000h~00ffh 128kb block528 0210h 0000h~00ffh 128kb block560 0230h 0000h~00ffh 128kb block529 0211h 0000h~00ffh 128kb block561 0231h 0000h~00ffh 128kb block530 0212h 0000h~00ffh 128kb block562 0232h 0000h~00ffh 128kb block531 0213h 0000h~00ffh 128kb block563 0233h 0000h~00ffh 128kb block532 0214h 0000h~00ffh 128kb block564 0234h 0000h~00ffh 128kb block533 0215h 0000h~00ffh 128kb block565 0235h 0000h~00ffh 128kb block534 0216h 0000h~00ffh 128kb block566 0236h 0000h~00ffh 128kb block535 0217h 0000h~00ffh 128kb block567 0237h 0000h~00ffh 128kb block536 0218h 0000h~00ffh 128kb block568 0238h 0000h~00ffh 128kb block537 0219h 0000h~00ffh 128kb block569 0239h 0000h~00ffh 128kb block538 021ah 0000h~00ffh 128kb block570 023ah 0000h~00ffh 128kb block539 021bh 0000h~00ffh 128kb block571 023bh 0000h~00ffh 128kb block540 021ch 0000h~00ffh 128kb block572 023ch 0000h~00ffh 128kb block541 021dh 0000h~00ffh 128kb block573 023dh 0000h~00ffh 128kb block542 021eh 0000h~00ffh 128kb block574 023eh 0000h~00ffh 128kb block543 021fh 0000h~00ffh 128kb block575 023fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 26 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block576 0240h 0000h~00ffh 128kb block608 0260h 0000h~00ffh 128kb block577 0241h 0000h~00ffh 128kb block609 0261h 0000h~00ffh 128kb block578 0242h 0000h~00ffh 128kb block610 0262h 0000h~00ffh 128kb block579 0243h 0000h~00ffh 128kb block611 0263h 0000h~00ffh 128kb block580 0244h 0000h~00ffh 128kb block612 0264h 0000h~00ffh 128kb block581 0245h 0000h~00ffh 128kb block613 0265h 0000h~00ffh 128kb block582 0246h 0000h~00ffh 128kb block614 0266h 0000h~00ffh 128kb block583 0247h 0000h~00ffh 128kb block615 0267h 0000h~00ffh 128kb block584 0248h 0000h~00ffh 128kb block616 0268h 0000h~00ffh 128kb block585 0249h 0000h~00ffh 128kb block617 0269h 0000h~00ffh 128kb block586 024ah 0000h~00ffh 128kb block618 026ah 0000h~00ffh 128kb block587 024bh 0000h~00ffh 128kb block619 026bh 0000h~00ffh 128kb block588 024ch 0000h~00ffh 128kb block620 026ch 0000h~00ffh 128kb block589 024dh 0000h~00ffh 128kb block621 026dh 0000h~00ffh 128kb block590 024eh 0000h~00ffh 128kb block622 026eh 0000h~00ffh 128kb block591 024fh 0000h~00ffh 128kb block623 026fh 0000h~00ffh 128kb block592 0250h 0000h~00ffh 128kb block624 0270h 0000h~00ffh 128kb block593 0251h 0000h~00ffh 128kb block625 0271h 0000h~00ffh 128kb block594 0252h 0000h~00ffh 128kb block626 0272h 0000h~00ffh 128kb block595 0253h 0000h~00ffh 128kb block627 0273h 0000h~00ffh 128kb block596 0254h 0000h~00ffh 128kb block628 0274h 0000h~00ffh 128kb block597 0255h 0000h~00ffh 128kb block629 0275h 0000h~00ffh 128kb block598 0256h 0000h~00ffh 128kb block630 0276h 0000h~00ffh 128kb block599 0257h 0000h~00ffh 128kb block631 0277h 0000h~00ffh 128kb block600 0258h 0000h~00ffh 128kb block632 0278h 0000h~00ffh 128kb block601 0259h 0000h~00ffh 128kb block633 0279h 0000h~00ffh 128kb block602 025ah 0000h~00ffh 128kb block634 027ah 0000h~00ffh 128kb block603 025bh 0000h~00ffh 128kb block635 027bh 0000h~00ffh 128kb block604 025ch 0000h~00ffh 128kb block636 027ch 0000h~00ffh 128kb block605 025dh 0000h~00ffh 128kb block637 027dh 0000h~00ffh 128kb block606 025eh 0000h~00ffh 128kb block638 027eh 0000h~00ffh 128kb block607 025fh 0000h~00ffh 128kb block639 027fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 27 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block640 0280h 0000h~00ffh 128kb block672 02a0h 0000h~00ffh 128kb block641 0281h 0000h~00ffh 128kb block673 02a1h 0000h~00ffh 128kb block642 0282h 0000h~00ffh 128kb block674 02a2h 0000h~00ffh 128kb block643 0283h 0000h~00ffh 128kb block675 02a3h 0000h~00ffh 128kb block644 0284h 0000h~00ffh 128kb block676 02a4h 0000h~00ffh 128kb block645 0285h 0000h~00ffh 128kb block677 02a5h 0000h~00ffh 128kb block646 0286h 0000h~00ffh 128kb block678 02a6h 0000h~00ffh 128kb block647 0287h 0000h~00ffh 128kb block679 02a7h 0000h~00ffh 128kb block648 0288h 0000h~00ffh 128kb block680 02a8h 0000h~00ffh 128kb block649 0289h 0000h~00ffh 128kb block681 02a9h 0000h~00ffh 128kb block650 028ah 0000h~00ffh 128kb block682 02aah 0000h~00ffh 128kb block651 028bh 0000h~00ffh 128kb block683 02abh 0000h~00ffh 128kb block652 028ch 0000h~00ffh 128kb block684 02ach 0000h~00ffh 128kb block653 028dh 0000h~00ffh 128kb block685 02adh 0000h~00ffh 128kb block654 028eh 0000h~00ffh 128kb block686 02aeh 0000h~00ffh 128kb block655 028fh 0000h~00ffh 128kb block687 02afh 0000h~00ffh 128kb block656 0290h 0000h~00ffh 128kb block688 02b0h 0000h~00ffh 128kb block657 0291h 0000h~00ffh 128kb block689 02b1h 0000h~00ffh 128kb block658 0292h 0000h~00ffh 128kb block690 02b2h 0000h~00ffh 128kb block659 0293h 0000h~00ffh 128kb block691 02b3h 0000h~00ffh 128kb block660 0294h 0000h~00ffh 128kb block692 02b4h 0000h~00ffh 128kb block661 0295h 0000h~00ffh 128kb block693 02b5h 0000h~00ffh 128kb block662 0296h 0000h~00ffh 128kb block694 02b6h 0000h~00ffh 128kb block663 0297h 0000h~00ffh 128kb block695 02b7h 0000h~00ffh 128kb block664 0298h 0000h~00ffh 128kb block696 02b8h 0000h~00ffh 128kb block665 0299h 0000h~00ffh 128kb block697 02b9h 0000h~00ffh 128kb block666 029ah 0000h~00ffh 128kb block698 02bah 0000h~00ffh 128kb block667 029bh 0000h~00ffh 128kb block699 02bbh 0000h~00ffh 128kb block668 029ch 0000h~00ffh 128kb block700 02bch 0000h~00ffh 128kb block669 029dh 0000h~00ffh 128kb block701 02bdh 0000h~00ffh 128kb block670 029eh 0000h~00ffh 128kb block702 02beh 0000h~00ffh 128kb block671 029fh 0000h~00ffh 128kb block703 02bfh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 28 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block704 02c0h 0000h~00ffh 128kb block736 02e0h 0000h~00ffh 128kb block705 02c1h 0000h~00ffh 128kb block737 02e1h 0000h~00ffh 128kb block706 02c2h 0000h~00ffh 128kb block738 02e2h 0000h~00ffh 128kb block707 02c3h 0000h~00ffh 128kb block739 02e3h 0000h~00ffh 128kb block708 02c4h 0000h~00ffh 128kb block740 02e4h 0000h~00ffh 128kb block709 02c5h 0000h~00ffh 128kb block741 02e5h 0000h~00ffh 128kb block710 02c6h 0000h~00ffh 128kb block742 02e6h 0000h~00ffh 128kb block711 02c7h 0000h~00ffh 128kb block743 02e7h 0000h~00ffh 128kb block712 02c8h 0000h~00ffh 128kb block744 02e8h 0000h~00ffh 128kb block713 02c9h 0000h~00ffh 128kb block745 02e9h 0000h~00ffh 128kb block714 02cah 0000h~00ffh 128kb block746 02eah 0000h~00ffh 128kb block715 02cbh 0000h~00ffh 128kb block747 02ebh 0000h~00ffh 128kb block716 02cch 0000h~00ffh 128kb block748 02ech 0000h~00ffh 128kb block717 02cdh 0000h~00ffh 128kb block749 02edh 0000h~00ffh 128kb block718 02ceh 0000h~00ffh 128kb block750 02eeh 0000h~00ffh 128kb block719 02cfh 0000h~00ffh 128kb block751 02efh 0000h~00ffh 128kb block720 02d0h 0000h~00ffh 128kb block752 02f0h 0000h~00ffh 128kb block721 02d1h 0000h~00ffh 128kb block753 02f1h 0000h~00ffh 128kb block722 02d2h 0000h~00ffh 128kb block754 02f2h 0000h~00ffh 128kb block723 02d3h 0000h~00ffh 128kb block755 02f3h 0000h~00ffh 128kb block724 02d4h 0000h~00ffh 128kb block756 02f4h 0000h~00ffh 128kb block725 02d5h 0000h~00ffh 128kb block757 02f5h 0000h~00ffh 128kb block726 02d6h 0000h~00ffh 128kb block758 02f6h 0000h~00ffh 128kb block727 02d7h 0000h~00ffh 128kb block759 02f7h 0000h~00ffh 128kb block728 02d8h 0000h~00ffh 128kb block760 02f8h 0000h~00ffh 128kb block729 02d9h 0000h~00ffh 128kb block761 02f9h 0000h~00ffh 128kb block730 02dah 0000h~00ffh 128kb block762 02fah 0000h~00ffh 128kb block731 02dbh 0000h~00ffh 128kb block763 02fbh 0000h~00ffh 128kb block732 02dch 0000h~00ffh 128kb block764 02fch 0000h~00ffh 128kb block733 02ddh 0000h~00ffh 128kb block765 02fdh 0000h~00ffh 128kb block734 02deh 0000h~00ffh 128kb block766 02feh 0000h~00ffh 128kb block735 02dfh 0000h~00ffh 128kb block767 02ffh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 29 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block768 0300h 0000h~00ffh 128kb block800 0320h 0000h~00ffh 128kb block769 0301h 0000h~00ffh 128kb block801 0321h 0000h~00ffh 128kb block770 0302h 0000h~00ffh 128kb block802 0322h 0000h~00ffh 128kb block771 0303h 0000h~00ffh 128kb block803 0323h 0000h~00ffh 128kb block772 0304h 0000h~00ffh 128kb block804 0324h 0000h~00ffh 128kb block773 0305h 0000h~00ffh 128kb block805 0325h 0000h~00ffh 128kb block774 0306h 0000h~00ffh 128kb block806 0326h 0000h~00ffh 128kb block775 0307h 0000h~00ffh 128kb block807 0327h 0000h~00ffh 128kb block776 0308h 0000h~00ffh 128kb block808 0328h 0000h~00ffh 128kb block777 0309h 0000h~00ffh 128kb block809 0329h 0000h~00ffh 128kb block778 030ah 0000h~00ffh 128kb block810 032ah 0000h~00ffh 128kb block779 030bh 0000h~00ffh 128kb block811 032bh 0000h~00ffh 128kb block780 030ch 0000h~00ffh 128kb block812 032ch 0000h~00ffh 128kb block781 030dh 0000h~00ffh 128kb block813 032dh 0000h~00ffh 128kb block782 030eh 0000h~00ffh 128kb block814 032eh 0000h~00ffh 128kb block783 030fh 0000h~00ffh 128kb block815 032fh 0000h~00ffh 128kb block784 0310h 0000h~00ffh 128kb block816 0330h 0000h~00ffh 128kb block785 0311h 0000h~00ffh 128kb block817 0331h 0000h~00ffh 128kb block786 0312h 0000h~00ffh 128kb block818 0332h 0000h~00ffh 128kb block787 0313h 0000h~00ffh 128kb block819 0333h 0000h~00ffh 128kb block788 0314h 0000h~00ffh 128kb block820 0334h 0000h~00ffh 128kb block789 0315h 0000h~00ffh 128kb block821 0335h 0000h~00ffh 128kb block790 0316h 0000h~00ffh 128kb block822 0336h 0000h~00ffh 128kb block791 0317h 0000h~00ffh 128kb block823 0337h 0000h~00ffh 128kb block792 0318h 0000h~00ffh 128kb block824 0338h 0000h~00ffh 128kb block793 0319h 0000h~00ffh 128kb block825 0339h 0000h~00ffh 128kb block794 031ah 0000h~00ffh 128kb block826 033ah 0000h~00ffh 128kb block795 031bh 0000h~00ffh 128kb block827 033bh 0000h~00ffh 128kb block796 031ch 0000h~00ffh 128kb block828 033ch 0000h~00ffh 128kb block797 031dh 0000h~00ffh 128kb block829 033dh 0000h~00ffh 128kb block798 031eh 0000h~00ffh 128kb block830 033eh 0000h~00ffh 128kb block799 031fh 0000h~00ffh 128kb block831 033fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 30 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block832 0340h 0000h~00ffh 128kb block864 0360h 0000h~00ffh 128kb block833 0341h 0000h~00ffh 128kb block865 0361h 0000h~00ffh 128kb block834 0342h 0000h~00ffh 128kb block866 0362h 0000h~00ffh 128kb block835 0343h 0000h~00ffh 128kb block867 0363h 0000h~00ffh 128kb block836 0344h 0000h~00ffh 128kb block868 0364h 0000h~00ffh 128kb block837 0345h 0000h~00ffh 128kb block869 0365h 0000h~00ffh 128kb block838 0346h 0000h~00ffh 128kb block870 0366h 0000h~00ffh 128kb block839 0347h 0000h~00ffh 128kb block871 0367h 0000h~00ffh 128kb block840 0348h 0000h~00ffh 128kb block872 0368h 0000h~00ffh 128kb block841 0349h 0000h~00ffh 128kb block873 0369h 0000h~00ffh 128kb block842 034ah 0000h~00ffh 128kb block874 036ah 0000h~00ffh 128kb block843 034bh 0000h~00ffh 128kb block875 036bh 0000h~00ffh 128kb block844 034ch 0000h~00ffh 128kb block876 036ch 0000h~00ffh 128kb block845 034dh 0000h~00ffh 128kb block877 036dh 0000h~00ffh 128kb block846 034eh 0000h~00ffh 128kb block878 036eh 0000h~00ffh 128kb block847 034fh 0000h~00ffh 128kb block879 036fh 0000h~00ffh 128kb block848 0350h 0000h~00ffh 128kb block880 0370h 0000h~00ffh 128kb block849 0351h 0000h~00ffh 128kb block881 0371h 0000h~00ffh 128kb block850 0352h 0000h~00ffh 128kb block882 0372h 0000h~00ffh 128kb block851 0353h 0000h~00ffh 128kb block883 0373h 0000h~00ffh 128kb block852 0354h 0000h~00ffh 128kb block884 0374h 0000h~00ffh 128kb block853 0355h 0000h~00ffh 128kb block885 0375h 0000h~00ffh 128kb block854 0356h 0000h~00ffh 128kb block886 0376h 0000h~00ffh 128kb block855 0357h 0000h~00ffh 128kb block887 0377h 0000h~00ffh 128kb block856 0358h 0000h~00ffh 128kb block888 0378h 0000h~00ffh 128kb block857 0359h 0000h~00ffh 128kb block889 0379h 0000h~00ffh 128kb block858 035ah 0000h~00ffh 128kb block890 037ah 0000h~00ffh 128kb block859 035bh 0000h~00ffh 128kb block891 037bh 0000h~00ffh 128kb block860 035ch 0000h~00ffh 128kb block892 037ch 0000h~00ffh 128kb block861 035dh 0000h~00ffh 128kb block893 037dh 0000h~00ffh 128kb block862 035eh 0000h~00ffh 128kb block894 037eh 0000h~00ffh 128kb block863 035fh 0000h~00ffh 128kb block895 037fh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 31 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block896 0380h 0000h~00ffh 128kb block928 03a0h 0000h~00ffh 128kb block897 0381h 0000h~00ffh 128kb block929 03a1h 0000h~00ffh 128kb block898 0382h 0000h~00ffh 128kb block930 03a2h 0000h~00ffh 128kb block899 0383h 0000h~00ffh 128kb block931 03a3h 0000h~00ffh 128kb block900 0384h 0000h~00ffh 128kb block932 03a4h 0000h~00ffh 128kb block901 0385h 0000h~00ffh 128kb block933 03a5h 0000h~00ffh 128kb block902 0386h 0000h~00ffh 128kb block934 03a6h 0000h~00ffh 128kb block903 0387h 0000h~00ffh 128kb block935 03a7h 0000h~00ffh 128kb block904 0388h 0000h~00ffh 128kb block936 03a8h 0000h~00ffh 128kb block905 0389h 0000h~00ffh 128kb block937 03a9h 0000h~00ffh 128kb block906 038ah 0000h~00ffh 128kb block938 03aah 0000h~00ffh 128kb block907 038bh 0000h~00ffh 128kb block939 03abh 0000h~00ffh 128kb block908 038ch 0000h~00ffh 128kb block940 03ach 0000h~00ffh 128kb block909 038dh 0000h~00ffh 128kb block941 03adh 0000h~00ffh 128kb block910 038eh 0000h~00ffh 128kb block942 03aeh 0000h~00ffh 128kb block911 038fh 0000h~00ffh 128kb block943 03afh 0000h~00ffh 128kb block912 0390h 0000h~00ffh 128kb block944 03b0h 0000h~00ffh 128kb block913 0391h 0000h~00ffh 128kb block945 03b1h 0000h~00ffh 128kb block914 0392h 0000h~00ffh 128kb block946 03b2h 0000h~00ffh 128kb block915 0393h 0000h~00ffh 128kb block947 03b3h 0000h~00ffh 128kb block916 0394h 0000h~00ffh 128kb block948 03b4h 0000h~00ffh 128kb block917 0395h 0000h~00ffh 128kb block949 03b5h 0000h~00ffh 128kb block918 0396h 0000h~00ffh 128kb block950 03b6h 0000h~00ffh 128kb block919 0397h 0000h~00ffh 128kb block951 03b7h 0000h~00ffh 128kb block920 0398h 0000h~00ffh 128kb block952 03b8h 0000h~00ffh 128kb block921 0399h 0000h~00ffh 128kb block953 03b9h 0000h~00ffh 128kb block922 039ah 0000h~00ffh 128kb block954 03bah 0000h~00ffh 128kb block923 039bh 0000h~00ffh 128kb block955 03bbh 0000h~00ffh 128kb block924 039ch 0000h~00ffh 128kb block956 03bch 0000h~00ffh 128kb block925 039dh 0000h~00ffh 128kb block957 03bdh 0000h~00ffh 128kb block926 039eh 0000h~00ffh 128kb block958 03beh 0000h~00ffh 128kb block927 039fh 0000h~00ffh 128kb block959 03bfh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 32 muxonenand2g(kfn2g16q2m-deb5) block block address page and sector address size block block address page and sector address size block960 03c0h 0000h~00ffh 128kb block992 03e0h 0000h~00ffh 128kb block961 03c1h 0000h~00ffh 128kb block993 03e1h 0000h~00ffh 128kb block962 03c2h 0000h~00ffh 128kb block994 03e2h 0000h~00ffh 128kb block963 03c3h 0000h~00ffh 128kb block995 03e3h 0000h~00ffh 128kb block964 03c4h 0000h~00ffh 128kb block996 03e4h 0000h~00ffh 128kb block965 03c5h 0000h~00ffh 128kb block997 03e5h 0000h~00ffh 128kb block966 03c6h 0000h~00ffh 128kb block998 03e6h 0000h~00ffh 128kb block967 03c7h 0000h~00ffh 128kb block999 03e7h 0000h~00ffh 128kb block968 03c8h 0000h~00ffh 128kb block1000 03e8h 0000h~00ffh 128kb block969 03c9h 0000h~00ffh 128kb block1001 03e9h 0000h~00ffh 128kb block970 03cah 0000h~00ffh 128kb block1002 03eah 0000h~00ffh 128kb block971 03cbh 0000h~00ffh 128kb block1003 03ebh 0000h~00ffh 128kb block972 03cch 0000h~00ffh 128kb block1004 03ech 0000h~00ffh 128kb block973 03cdh 0000h~00ffh 128kb block1005 03edh 0000h~00ffh 128kb block974 03ceh 0000h~00ffh 128kb block1006 03eeh 0000h~00ffh 128kb block975 03cfh 0000h~00ffh 128kb block1007 03efh 0000h~00ffh 128kb block976 03d0h 0000h~00ffh 128kb block1008 03f0h 0000h~00ffh 128kb block977 03d1h 0000h~00ffh 128kb block1009 03f1h 0000h~00ffh 128kb block978 03d2h 0000h~00ffh 128kb block1010 03f2h 0000h~00ffh 128kb block979 03d3h 0000h~00ffh 128kb block1011 03f3h 0000h~00ffh 128kb block980 03d4h 0000h~00ffh 128kb block1012 03f4h 0000h~00ffh 128kb block981 03d5h 0000h~00ffh 128kb block1013 03f5h 0000h~00ffh 128kb block982 03d6h 0000h~00ffh 128kb block1014 03f6h 0000h~00ffh 128kb block983 03d7h 0000h~00ffh 128kb block1015 03f7h 0000h~00ffh 128kb block984 03d8h 0000h~00ffh 128kb block1016 03f8h 0000h~00ffh 128kb block985 03d9h 0000h~00ffh 128kb block1017 03f9h 0000h~00ffh 128kb block986 03dah 0000h~00ffh 128kb block1018 03fah 0000h~00ffh 128kb block987 03dbh 0000h~00ffh 128kb block1019 03fbh 0000h~00ffh 128kb block988 03dch 0000h~00ffh 128kb block1020 03fch 0000h~00ffh 128kb block989 03ddh 0000h~00ffh 128kb block1021 03fdh 0000h~00ffh 128kb block990 03deh 0000h~00ffh 128kb block1022 03feh 0000h~00ffh 128kb block991 03dfh 0000h~00ffh 128kb block1023 03ffh 0000h~00ffh 128kb
muxonenand1g(kfm1g16q2m-deb5) flash memory 33 muxonenand2g(kfn2g16q2m-deb5) the figure below shows the assignment of the spare area in the internal memory nand array. spare area assignment in the internal memory nand array information word byte note description 1 lsb 1 invalid block information in 1st and 2nd page of an invalid block msb 2 lsb 2 managed by internal ecc logic for logical sector number data msb 3 lsb msb 3 reserved for future use 4 lsb msb 5 lsb dedicated to internal ecc logic. read only. eccm 1st for main area data msb dedicated to internal ecc logic. read only. eccm 2nd for main area data 6 lsb dedicated to internal ecc logic. read only. eccm 3rd for main area data msb dedicated to internal ecc logic. read only. eccs 1st for 2nd word of spare area data 7 lsb dedicated to internal ecc logic. read only. eccs 2nd for 3rd word of spare area data msb 3 reserved for future use 8 lsb 4 available to the user msb main area 256w main area 256w main area 256w main area 256w spare area 8w spare area 8w spare area 8w spare area 8w { 1 st w eccm 1st eccm 2nd eccm 3rd eccs 1st eccs 2nd lsb msb lsb msb { 2 nd w lsb msb { 3 rd w lsb msb { 4 th w lsb msb { 5 th w lsb msb { 6 th w lsb msb { 7 th w lsb msb { 8 th w lsb msb note1 note1 note2 note2 note2 note3 note3 note3 note4 note4 note3 2.7.2 internal memory spare area assignment
muxonenand1g(kfm1g16q2m-deb5) flash memory 34 muxonenand2g(kfn2g16q2m-deb5) division address (word order) address (byte order) size (total 128kb) usage description main area (64kb) 0000h~00ffh 00000h~001feh 512b 1kb r bootm 0 bootram main sector0 0100h~01ffh 00200h~003feh 512b bootm 1 bootram main sector1 0200h~02ffh 00400h~005feh 512b 4kb r/w datam 0_0 dataram main page0/sector0 0300h~03ffh 00600h~007feh 512b datam 0_1 dataram main page0/sector1 0400h~04ffh 00800h~009feh 512b datam 0_2 dataram main page0/sector2 0500h~05ffh 00a00h~00bfeh 512b datam 0_3 dataram main page0/sector3 0600h~06ffh 00c00h~00dfeh 512b datam 1_0 dataram main page1/sector0 0700h~07ffh 00e00h~00ffeh 512b datam 1_1 dataram main page1/sector1 0800h~08ffh 01000h~011feh 512b datam 1_2 dataram main page1/sector2 0900h~09ffh 01200h~013feh 512b datam 1_3 dataram main page1/sector3 0a00h~7fffh 01400h~0fffeh 59k 59k - reserved reserved spare area (8kb) 8000h~8007h 10000h~1000eh 16b 32b r boots 0 bootram spare sector0 8008h~800fh 10010h~1001eh 16b boots 1 bootram spare sector1 8010h~8017h 10020h~1002eh 16b 128b r/w datas 0_0 dataram spare page0/sector0 8018h~801fh 10030h~1003eh 16b datas 0_1 dataram spare page0/sector1 8020h~8027h 10040h~1004eh 16b datas 0_2 dataram spare page0/sector2 8028h~802fh 10050h~1005eh 16b datas 0_3 dataram spare page0/sector3 8030h~8037h 10060h~1006eh 16b datas 1_0 dataram spare page1/sector0 8038h~803fh 10070h~1007eh 16b datas 1_1 dataram spare page1/sector1 8040h~8047h 10080h~1008eh 16b datas 1_2 dataram spare page1/sector2 8048h~804fh 10090h~1009eh 16b datas 1_3 dataram spare page1/sector3 8050h~8fffh 100a0h~11ffeh 8032b 8032b - reserved reserved reserved (24kb) 9000h~bfffh 12000h~17ffeh 24kb 24kb - reserved reserved reserved (8kb) c000h~cfffh 18000h~19ffeh 8kb 8kb - reserved reserved reserved (16kb) d000h~efffh 1a000h~1dffeh 16kb 16kb - reserved reserved registers (8kb) f000h~ffffh 1e000h~1fffeh 8kb 8kb r or r/w registers registers the following table shows the external me mory address map in word and byte order. note that the data output is unknown while hos t reads a register bit of reserved area. 2.7.3 external memory (bufferram) address map
muxonenand1g(kfm1g16q2m-deb5) flash memory 35 muxonenand2g(kfn2g16q2m-deb5) the tables below show word order address map inform ation for the bootram and dataram main and spare areas. -0000h~01ffh: 2(sector) x 512byte(nand main area) = 1kb 0000h~00ffh(512b) bootm 0 (sector 0 of page 0) 0100h~01ffh(512b) bootm 1 (sector 1 of page 0) ? bootram(main area) -0200h~09ffh: 8(sector) x 512byte(nand main area) = 4kb 0200h~02ffh(512b) datam 0_0 (sector 0 of page 0) 0300h~03ffh(512b) datam 0_1 (sector 1 of page 0) 0400h~04ffh(512b) datam 0_2 (sector 2 of page 0) 0500h~05ffh(512b) datam 0_3 (sector 3 of page 0) 0600h~06ffh(512b) datam 1_0 (sector 0 of page 1) 0700h~07ffh(512b) datam 1_1 (sector 1 of page 1) 0800h~08ffh(512b) datam 1_2 (sector 2 of page 1) 0900h~09ffh(512b) datam 1_3 (sector 3 of page 1) ? dataram(main area) -8000h~800fh: 2(sector) x 16byte(nand spare area) = 32b 8000h~8007h(16b) boots 0 (sector 0 of page 0) 8008h~800fh(16b) boots 1 (sector 1 of page 0) ? bootram(spare area) -8010h~804fh: 8(sector) x 16byte(nand spare area) = 128b *nand flash array consists of 2k b page size and 128kb block size. 8010h~8017h(16b) datas 0_0 (sector 0 of page 0) 8018h~801fh(16b) datas 0_1 (sector 1 of page 0) 8020h~8027h(16b) datas 0_2 (sector 2 of page 0) 8028h~802fh(16b) datas 0_3 (sector 3 of page 0) 8030h~8037h(16b) datas 1_0 (sector 0 of page 1) 8038h~803fh(16b) datas 1_1 (sector 1 of page 1) 8040h~8047h(16b) datas 1_2 (sector 2 of page 1) 8048h~804fh(16b) datas 1_3 (sector 3 of page 1) ? dataram(spare area) 2.7.4 external memory map detail information
muxonenand1g(kfm1g16q2m-deb5) flash memory 36 muxonenand2g(kfn2g16q2m-deb5) buf. word address byte address f e d c b a 9 8 7 6 5 4 3 2 1 0 boots 0 8000h 10000h bi 8001h 10002h managed by internal ecc logic 8002h 10004h reserved for the future use managed by internal ecc logic 8003h 10006h reserved for the current and future use 8004h 10008h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 8005h 1000ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 8006h 1000ch ffh(reserved for the future use) ecc code for spare area data (2 nd ) 8007h 1000eh free usage boots 1 8008h 10010h bi 8009h 10012h managed by internal ecc logic 800ah 10014h reserved for the future use managed by internal ecc logic 800bh 10016h reserved for the current and future use 800ch 10018h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 800dh 1001ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 800eh 1001ch ffh(reserved for the future use) ecc code for spare area data (2 nd ) 800fh 1001eh free usage datas 0_0 8010h 10020h bi 8011h 10022h managed by internal ecc logic 8012h 10024h reserved for the future use managed by internal ecc logic 8013h 10026h reserved for the current and future use 8014h 10028h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 8015h 1002ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 8016h 1002ch ffh(reserved for the future use) ecc code for spare area data (2 nd ) 8017h 1002eh free usage datas 0_1 8018h 10030h bi 8019h 10032h managed by internal ecc logic 801ah 10034h reserved for the future use managed by internal ecc logic 801bh 10036h reserved for the current and future use 801ch 10038h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 801dh 1003ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 801eh 1003ch ffh(reserved for the future use) ecc code for spare area data (2 nd ) 801fh 1003eh free usage equivalent to 1word of nand flash 2.7.5 external memory spare area assignment
muxonenand1g(kfm1g16q2m-deb5) flash memory 37 muxonenand2g(kfn2g16q2m-deb5) buf. word address byte address f e d c b a 9 8 7 6 5 4 3 2 1 0 datas 0_2 8020h 10040h bi 8021h 10042h managed by internal ecc logic 8022h 10044h reserved for the future use managed by internal ecc logic 8023h 10046h reserved for the current and future use 8024h 10048h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 8025h 1004ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 8026h 1004ch reserved for the future use ecc code for spare area data (2 nd ) 8027h 1004eh free usage datas 0_3 8028h 10050h bi 8029h 10052h managed by internal ecc logic 802ah 10054h reserved for the future use managed by internal ecc logic 802bh 10056h reserved for the current and future use 802ch 10058h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 802dh 1005ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 802eh 1005ch reserved for the future use ecc code for spare area data (2 nd ) 802fh 1005eh free usage datas 1_0 8030h 10060h bi 8031h 10062h managed by internal ecc logic 8032h 10064h reserved for the future use managed by internal ecc logic 8033h 10066h reserved for the current and future use 8034h 10068h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 8035h 1006ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 8036h 1006ch reserved for the future use ecc code for spare area data (2 nd ) 8037h 1006eh free usage datas 1_1 8038h 10070h bi 8039h 10072h managed by internal ecc logic 803ah 10074h reserved for the future use managed by internal ecc logic 803bh 10076h reserved for the current and future use 803ch 10078h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 803dh 1007ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 803eh 1007ch reserved for the future use ecc code for spare area data (2 nd ) 803fh 1007eh free usage datas 1_2 8040h 10080h bi 8041h 10082h managed by internal ecc logic 8042h 10084h reserved for the future use managed by internal ecc logic 8043h 10086h reserved for the current and future use 8044h 10088h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 8045h 1008ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 8046h 1008ch reserved for the future use ecc code for spare area data (2 nd ) 8047h 1008eh free usage
muxonenand1g(kfm1g16q2m-deb5) flash memory 38 muxonenand2g(kfn2g16q2m-deb5) equivalent to 1word of nand flash note: - bi: bad block information >host can use complete spare area exce pt bi and ecc code area. for example, host can write data to spare area buffer except for the area controlled by ecc logic at program operation. >in case of ?with ecc? mode, muxonenand automatically generates ecc code for both main and spare data of memory during program operation, but does not update ecc code to spare bufferram during load operation. >when loading/programming spare area, spare area bufferram address( bsa) and bufferram sector count(bsc) is chosen via start bu ffer register as it is. buf. word address byte address f e d c b a 9 8 7 6 5 4 3 2 1 0 datas 1_3 8048h 10090h bi 8049h 10092h managed by internal ecc logic 804ah 10094h reserved for the future use managed by internal ecc logic 804bh 10096h reserved for the current and future use 804ch 10098h ecc code for main area data (2 nd ) ecc code for main area data (1 st ) 804dh 1009ah ecc code for spare area data (1 st ) ecc code for main area data (3 rd ) 804eh 1009ch reserved for the future use ecc code for spare area data (2 nd ) 804fh 1009eh free usage equivalent to 1word of nand flash
muxonenand1g(kfm1g16q2m-deb5) flash memory 39 muxonenand2g(kfn2g16q2m-deb5) section 2.8 of this specification provides information about the muxonenand1g registers. 2.8.1 regis ter address map this map describes the register addresses, register name, register description, and host accessibility. address (word order) address (byte order) name host access description f000h 1e000h manufacturer id r manufacturer identification f001h 1e002h device id r device identification f002h 1e004h version id r n/a f003h 1e006h data buffer size r data buffer size f004h 1e008h boot buffer size r boot buffer size f005h 1e00ah amount of buffers r amount of data/boot buffers f006h 1e00ch technology r info about technology f007h~f0ffh 1e00eh~1e1feh reserved - reserved for user f100h 1e200h start address 1 r/w chip address for selection of nand core in ddp & block address f101h 1e202h start address 2 r/w chip address for selection of bufferram in ddp f102h 1e204h start address 3 r/w destination block address for copy back program f103h 1e206h start address 4 r/w destination page & sector address for copy back program f104h 1e208h start address 5 - n/a f105h 1e20ah start address 6 - n/a f106h 1e20ch start address 7 - n/a f107h 1e20eh start address 8 r/w nand flash page & sector address f108h~f1ffh 1e210h~1e3feh reserved - reserved for user f200h 1e400h start buffer r/w buffer number for the page data transfer to/from the memory and the start buffer address the meaning is with which buffer to start and how many buffers to use for the data transfer f201h~f207h 1e402h~1e40eh reserved - reserved for user f208h~f21fh 1e410h~1e43eh reserved - rese rved for vendor specific purposes f220h 1e440h command r/w host control and memory operation commands f221h 1e442h system configuration 1 r, r/w memory and host interface configuration f222h 1e444h system configuration 2 -n/a f223h~f22fh 1e446h~1e45eh reserved - reserved for user f230h~f23fh 1e460h~1e47eh reserved - rese rved for vendor specific purposes f240h 1e480h controller status r controller status and result of memory operation f241h 1e482h interrupt r/w memory command completion interrupt status f242h~f24bh 1e484h~1e496h reserved - reserved for user f24ch 1e498h start block address r/w start memory block address in write protection mode 2.8 registers
muxonenand1g(kfm1g16q2m-deb5) flash memory 40 muxonenand2g(kfn2g16q2m-deb5) address (word order) address (byte order) name host access description f24dh 1e49ah reserved r/w reserved for user f24eh 1e49ch write protection status r current memory write protection status (unlocked/locked/tight-locked) f24fh~feffh 1e49eh~1fdfeh reserved - reserved for user ff00h 1fe00h ecc status register r ecc status of sector ff01h 1fe02h ecc result of main area data r ecc error position of main area data error for first selected sector ff02h 1fe04h ecc result of spare area data r ecc error position of spare area data error for first selected sector ff03h 1fe06h ecc result of main area data r ecc error position of main area data error for second selected sector ff04h 1fe08h ecc result of spare area data r ecc error position of spare area data error for second selected sector ff05h 1fe0ah ecc result of main area data r ecc error position of main area data error for third selected sector ff06h 1fe0ch ecc result of spare area data r ecc error position of spare area data error for third selected sector ff07h 1fe0eh ecc result of main area data r ecc error position of main area data error for fourth selected sector ff08h 1fe10h ecc result of spare area data r ecc error position of spare area data error for fourth selected sector ff09h~ffffh 1fe12h~1fffeh reserved - reser ved for vendor specific purposes this read register describes the manufacturer's identification. samsung electronics company m anufacturer's id is 00ech. f000h, default = 00ech 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 manufid 2.8.2 manufacturer id register f000h (r)
muxonenand1g(kfm1g16q2m-deb5) flash memory 41 muxonenand2g(kfn2g16q2m-deb5) this read register describes the device. f001h, see table for default. 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 deviceid device identification device id default device identification description deviceid [1:0] vcc 00 = 1.8v, 01 = 2.65v/3.3v, 10/11 = reserved deviceid [2] muxed/demuxed 0 = muxed, 1 = demuxed deviceid [3] single/dpp 0 = single, 1 = ddp deviceid [6:4] density 000 = 128mb, 001 = 256mb, 010 = 512mb, 011 = 1gb, 100 = 2gb device deviceid[15:0] kfm1g16q2m 0030h kfn2g16q2m 0048h 2.8.3 device id register f001h (r)
muxonenand1g(kfm1g16q2m-deb5) flash memory 42 muxonenand2g(kfn2g16q2m-deb5) 2.8.5 data buffer size register f003h (r) this read register describes t he size of the data buffer. f003h, default = 0800h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 databufsize data buffer size information version identification description databufsize total data buffer size in words equal to 2 buffers of 1024 words each (2 x 1024 = 2 11 ) in the memory interface 2.8.4 version id register f002h this register is reserved for future use.
muxonenand1g(kfm1g16q2m-deb5) flash memory 43 muxonenand2g(kfn2g16q2m-deb5) 2.8.7 number of bu ffers register f005h (r) this read register describes the number of each buffer. f005h, default = 0201h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 databufamount bootbufamount number of buffers information register information description databufamount the number of data buffers = 2 (2 n , n=1) bootbufamount the number of boot buffers = 1 (2 n , n=0) 2.8.8 technology register f006h (r) this read register describes the internal nand array technology. f006h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 te c h technology information technology register setting nand slc 0000h nand mlc 0001h reserved 0002h ~ ffffh this read register describes t he size of the boot buffer. f004h, default = 0200h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 bootbufsize register information description bootbufsize total boot buffer size in words equal to 1 buffer of 512 words (1 x 512 = 2 9 ) in the memory interface 2.8.6 boot buffer size register f004h (r)
muxonenand1g(kfm1g16q2m-deb5) flash memory 44 muxonenand2g(kfn2g16q2m-deb5) this read/write register describes the nand flash bloc k address which will be loaded, programmed, or erased. f100h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 dfs reserved(00000) fba device number of block fba 2gb ddp 2048 dfs[15] & fba[9:0] 1gb 1024 fba[9:0] start address1 information register information description fba nand flash block address dfs flash core of ddp (device flash core select) 2.8.10 start address2 register f101h (r/w) this read/write register describes the bu fferram of ddp (device bufferram select) f101h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 dbs reserved(000000000000000) start address2 information register information description dbs bufferram of ddp (device bufferram select) comp comp dbs dfs ddp_opt gnd ce control logic sram buffer flash core comp comp dbs dfs ddp_opt v dd ce control logic sram buffer flash core ce int chip 1 chip 2 int int 2.8.9 start address 1 register f100h (r/w)
muxonenand1g(kfm1g16q2m-deb5) flash memory 45 muxonenand2g(kfn2g16q2m-deb5) this read/write register describes t he nand flash destination block addres s which will be copy back programmed. f102h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(000000) fcba device number of block fba 1gb 1024 fcba[9:0] start address3 information register information description fcba nand flash copy back block address 2.8.12 start address4 register f103h (r/w) this read/write register describes the nand flash destination page address in a bl ock and the nand flash destination sector address in a page for copy back programming. f103h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(00000000) fcpa fcsa start address4 information item description default value range fcpa nand flash copy back page address 000000 000000 ~ 111111, 6 bits for 64 pages fcsa nand flash copy back sector address 00 00 ~ 11, 2 bits for 4 sectors 2.8.11 start address3 register f102h (r/w)
muxonenand1g(kfm1g16q2m-deb5) flash memory 46 muxonenand2g(kfn2g16q2m-deb5) this register is reserved for future use. 2.8.14 start address6 register f105h this register is reserved for future use. 2.8.15 start addr ess7 register f106h this register is reserved for future use. 2.8.16 start address8 register f107h (r/w) this read/write register describes the nand flash start page address in a block for a page load, copy back program, or program operation and the nand flash start sector address in a pa ge for a load, copy back program, or program operation. f107h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved (00000000) fpa fsa start address8 information item description default value range fpa nand flash page address 000000 000000 ~ 111111, 6 bits for 64 pages fsa nand flash sector address 00 00 ~ 11, 2 bits for 4 sectors 2.8.13 start address5 register f104h
muxonenand1g(kfm1g16q2m-deb5) flash memory 47 muxonenand2g(kfn2g16q2m-deb5) this read/write register describes the bufferram sector count (bsc) and bufferram sector address (bsa). the bufferram sector count (bsc) field specifies the number of sectors to be loaded, programmed, or copy back programmed. at 00 value (the default value), the number of sector is "4". if th e internal ram buffer reaches its maximum value of 11, it will count up to 0 value to meet the bsc value. for example, if bsa = 1101, bsc = 00, then the selected bufferram will count up from '1101 1110 1111 1100'. the bufferram sector address (bsa) is the sector 0~3 addres s in the internal bootram and dataram where data is placed. f200h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000) bsa reserved(000000) bsc start address8 information item description bsa[3] selection bit between bootram and dataram bsa[2] selection bit between dataram0 and dataram1 bsa[1:0] selection bit between sector0 and sector1 in the internal bootram selection bit between sector0 to sector3 in the internal dataram bootram 0 bootram 1 bootram sector: (512 + 16) byte dataram 1_0 dataram 1_1 dataram 1_2 dataram 1_3 dataram1 0000 0001 1100 1101 1110 1111 bsc number of sectors 01 1 sector 10 2 sector 11 3 sector 00 4 sector { main area data { spare area data bsa dataram 0_0 dataram 0_1 dataram 0_2 dataram 0_3 dataram0 1000 1001 1010 1011 512b 16b 2.8.17 start buffer register f200h (r/w)
muxonenand1g(kfm1g16q2m-deb5) flash memory 48 muxonenand2g(kfn2g16q2m-deb5) this read/write register describes the operation of the muxonenand interface. note that all commands should be issued right after int is turned from ready state to busy state. (i.e. right after 0 is writte n to int reg- ister.) after any command is issued and the corresponding operation is completed, int goes back to ready state. (00f0h and 00f3 h may be accepted during busy state of some operations. refer to the rightmost column of the command register table below.) f220h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 command note : 1) 0080h programs both main and spare area, while 001ah programs only spare area. refer to chapter 5.8 for nop limits in issuin g these commands. when using 0080h and 001ah command, read-only part in spar e area must be masked by ff. (refer to chapter 2.7.2) 2)?reset muxonenand?(=hot reset) command makes the registers and nand flash core into default state as the warm reset(=reset by rp pin). cmd operation acceptable command during busy 0000h load single/multiple sector data unit into buffer 00f0h, 00f3h 0013h load single/multiple spare sector into buffer 00f0h, 00f3h 0080h program single/multiple sector data unit from buffer 1) 00f0h, 00f3h 001ah program single/multiple spare data unit from buffer 00f0h, 00f3h 001bh copy back program operation 00f0h, 00f3h 0023h unlock nand array a block - 002ah lock nand array a block - 002ch lock-tight nand array a block 0071h erase verify read 00f0h, 00f3h 0094h block erase 00f0h, 00f3h 0095h multi-block erase 00f0h, 00f3h 00b0h erase suspend - 0030h erase resume 00f0h, 00f3h 00f0h reset nand flash core - 00f3h reset muxonenand 2) - 0065h otp access 00f0h, 00f3h 2.8.18 command register f220h (r/w)
muxonenand1g(kfm1g16q2m-deb5) flash memory 49 muxonenand2g(kfn2g16q2m-deb5) this read/write register descri bes the system configuration. f221h, default = 40c0h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 r/w r/w r/w r/w r/w r/w r/w r/w r r rm brl bl ecc rdy pol int pol iobe rdy conf reserved(000) bwps read mode (rm) rm read mode 0 asynchronous read(default) 1 synchronous read read mode information[15] item definition description rm read mode selects between asynchronous read mode and synchronous read mode burst read latency (brl) brl latency cycles 000 8(n/a) 001 9(n/a) 010 10(n/a) 011 3(up to 40mhz) 100 4(default, min.) 101 5 110 6 111 7 burst read latency (brl) information[14:12] item definition description brl burst read latency specifies the access latency in the burst read transfer for the initial access 2.8.19 system configurati on 1 register f221h (r, r/w)
muxonenand1g(kfm1g16q2m-deb5) flash memory 50 muxonenand2g(kfn2g16q2m-deb5) burst length (bl) bl burst length(main) burst length(spare) 000 continuous(default) 001 4 words 010 8 words 011 16 words 100 32 words n/a 101~111 reserved burst length (bl) information[11:9] item definition description bl burst length specifies the size of the burst length during a synchronous read, wrap around and linear burst read error correction code (ecc) information[8] item definition description ecc error correction code operation 0 = with correction (default) 1 = without correction (bypassed) rdy polarity (rdypol) information[7] item definition description rdypol rdy signal polarity 1 = high for ready (default) 0 = low for ready int polarity (intpol) information[6] intpol int bit of interrupt status register int pin output 0 0 (busy) high 1 (ready) low 1 (default) 0 (busy) low 1 (ready) high
muxonenand1g(kfm1g16q2m-deb5) flash memory 51 muxonenand2g(kfn2g16q2m-deb5) i/o buffer enable (iobe) iobe is the i/o buffer enable for the in t and rdy signals. at startup, int and rdy outputs are high-z. bits 6 and 7 become vali d after iobe is set to "1". iobe can be reset by a cold reset or by writing "0" to bit 5 of system configuration1 register. i/o buffer enable information[5] item definition description iobe i/o buffer enable for int and rdy signals 0 = disable (default) 1 = enable rdy configuration (rdy conf) rdy configuration information[4] item definition description rdy conf rdy configuration 0=active with valid data(default) 1=active one clock before valid data boot buffer write protect status(bwps) boot buffer write protect status information[0] item definition description bwps boot buffer write protect status 0=locked(fixed)
muxonenand1g(kfm1g16q2m-deb5) flash memory 52 muxonenand2g(kfn2g16q2m-deb5) this register is reserved for future use. 2.8.21 controller status register f240h (r) this read register shows the overall internal status of the muxonenand and the controller. f240h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 ongo lock load prog erase error sus reserv ed(0) rstb otp l reserved(000000) to (0) ongo this bit shows the overall internal status of the muxonenand device. ongo information[15] item definition description ongo internal device status 0 = ready 1 = busy lock this bit shows whether the host is loading data from the nand flash array into t he locked bootram or whether the host is perfor m- ing a program/erase of a locked block of the nand flash array. lock information[14] lock locked/unlocked check result 0unlocked 1locked load this bit shows the load operation status. load information[13] item definition description load load operation status 0 = ready (default) 1 = busy or error (see controller status output modes) 2.8.20 system config uration 2 register f222h
muxonenand1g(kfm1g16q2m-deb5) flash memory 53 muxonenand2g(kfn2g16q2m-deb5) program this bit shows the program operation status. program information[12] item definition description prog program operation status 0 = ready (default) 1 = busy or error (see controller status output modes) erase this bit shows the erase operation status. erase information[11] item definition description erase erase operation status 0 = ready (default) 1 = busy or error (see controller status output modes) error this bit shows the overall erro r status, including load reset, program reset, and erase reset status. error information[10] error current sector/page load/program/copyback. program/ erase result and invalid command input 0pass 1fail erase suspend (sus) this bit shows the erase suspend status. sus information[9] sus erase suspend status 0 erase resume(default) 1 erase suspend, program ongoing(susp.), load ongoing(susp.), program fail(susp.), load fail(susp.), invalid command(susp.)
muxonenand1g(kfm1g16q2m-deb5) flash memory 54 muxonenand2g(kfn2g16q2m-deb5) reset / busy (rstb) this bit shows the reset operation status. rstb information[7] item definition description rstb reset operation status 0 = ready (default) 1 = busy (see controller status output modes) otp lock status (otp l ) this bit shows whether the otp block is lo cked or unlocked. locking the otp has the effect of a 'write-protect' to guard agains t accidental re-programming of data stored in the otp block. the otp l status bit is automatically updated at power-on. otp lock information[6] otp l otp locked/unlocked status 0 otp block unlock status(default) 1 otp block lock status(disable otp program/erase) time out (to) this bit determines if there is a time out for load, program, copy back program, and erase operati ons. it is fixed at 'no time out'. to information[0] item definition description to time out 0 = no time out
muxonenand1g(kfm1g16q2m-deb5) flash memory 55 muxonenand2g(kfn2g16q2m-deb5) controller status register output modes note : 1. erm and/or ers bits in ecc status register at load fail case is 10. (2bits error - uncorrectable) 2. erm and ers bits in ecc status register at load reset case are 00. (no error) 3. multi block erase status should be checked by erase verify read operation. mode controller status register [15:0] ongo lock load prog erase error sus reserved(0) rstb otp l reserved(0) to load ongoing 1 0 1 0 0 0 0 0 0 0/1 00000 0 program ongoing 1 0 0 1 0 0 0 0 0 0/1 00000 0 erase ongoing 1 0 0 0 1 0 0 0 0 0/1 00000 0 reset ongoing 1 0 0 0 0 0 0 0 1 0/1 00000 0 multi-block erase ongoing 1 0 0 0 1 0 0 0 0 0/1 00000 0 erase verify read ongoing 1 0 0 0 0 0 0 0 0 0/1 00000 0 load ok 0 0 0 0 0 0 0 0 0 0/1 00000 0 program ok 0 0 0 0 0 0 0 0 0 0/1 00000 0 erase ok 0 0 0 0 0 0 0 0 0 0/1 00000 0 erase verify read ok 3) 0 0 0 0 0 0 0 0 0 0/1 00000 0 load fail 1) 0 0 1 0 0 1 0 0 0 0/1 00000 0 program fail 0 0 0 1 0 1 0 0 0 0/1 00000 0 erase fail 0 0 0 0 1 1 0 0 0 0/1 00000 0 erase verify read fail 3) 0 0 0 0 1 1 0 0 0 0/1 00000 0 load reset 2) 0 0 1 0 0 1 0 0 1 0/1 00000 0 program reset 0 0 0 1 0 1 0 0 1 0/1 00000 0 erase reset 0 0 0 0 1 1 0 0 1 0/1 00000 0 erase suspend 0 0 0 0 1 0 1 0 0 0/1 00000 0 program lock 0 1 0 1 0 1 0 0 0 0/1 00000 0 erase lock 0 1 0 0 1 1 0 0 0 0/1 00000 0 load lock(buffer lock) 0 1 1 0 0 1 0 0 0 0/1 00000 0 otp program fail(lock) 0 1 0 1 0 1 0 0 0 1 00000 0 otp program fail 0 0 0 1 0 1 0 0 0 0 00000 0 otp erase fail 0 1 0 0 1 1 0 0 0 0/1 00000 0 program ongo- ing(susp.) 1 0 0 1 1 0 1 0 0 0/1 00000 0 load ongoing(susp.) 1 0 1 0 1 0 1 0 0 0/1 00000 0 program fail(susp.) 0 0 0 1 1 1 1 0 0 0/1 00000 0 load fail(susp.) 0 0 1 0 1 1 1 0 0 0/1 00000 0 invalid command 0 0 0 0 0 1 0 0 0 0/1 00000 0 invalid com- mand(susp.) 0 0 0 0 1 1 1 0 0 0/1 00000 0
muxonenand1g(kfm1g16q2m-deb5) flash memory 56 muxonenand2g(kfn2g16q2m-deb5) this read/write register shows st atus of the muxonenand interrupts. f241h, defaults = 8080h after cold reset; 8010h after warm/hot reset 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 int reserved(0000000) ri wi ei rsti reserved(0000) 2.8.22 interrupt status register f241h (r/w) interrupt (int) this is the master interrupt bit. the int bi t is wired directly to the int pin on the chip. upon writing '0' to the int bit, th e int pin goes low if intpol is high and goes high if intpol is low. int interrupt [15] status conditions default state valid state interrupt function cold warm/hot 11 0 off sets itself to ?1? one or more of ri, wi, rsti and ei is set to ?1?, or 0065h, 0023h, 0071h, 002a and 002c com- mands are completed 0 1 pending clears to ?0? ?0? is written to this bit, or cold/warm/hot reset is being performed 1 0 off read interrupt (ri) this is the read interrupt bit. ri interrupt [7] status conditions default state valid state interrupt function cold warm/hot 10 0 off sets itself to ?1? at the completion of an load operation (0000h, 0013h, load data into buffer, or boot is done) 0 1 pending clears to ?0? ?0? is written to this bit, or cold/warm/hot reset is being performed 1 0 off write interrupt (wi) this is the write interrupt bit. wi interrupt [6] status conditions default state valid state interrupt function cold warm/hot 00 0 off sets itself to ?1? at the completion of an program operation (0080h, 001ah, 001bh) 0 1 pending clears to ?0? ?0? is written to this bit, or cold/warm/hot reset is being performed 1 0 off
muxonenand1g(kfm1g16q2m-deb5) flash memory 57 muxonenand2g(kfn2g16q2m-deb5) this read/write register shows the nand flash block address in the write protection mode. setting this register precedes a 'loc k block' command, 'unlock block' command, or ?lock-tight' command. f24ch, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000) sba device number of block sba 1gb 1024 [9:0] sba information[9:0] item definition description sba start block address precedes lock blo ck, unlock block, or lock-tight commands 2.8.23 start block addr ess register f24ch (r/w) erase interrupt (ei) this is the erase interrupt bit. ei interrupt [5] status conditions default state valid state interrupt function cold warm/hot 00 0 off sets itself to ?1? at the completion of an erase operation (0094h, 0095h, 0030h) 0 1 pending clears to ?0? ?0? is written to this bit, or cold/warm/hot reset is being performed 1 0 off reset interrupt (rsti) this is the reset interrupt bit. rsti interrupt [4] status conditions default state valid state interrupt function cold warm/hot 01 0 off sets itself to ?1? at the completion of an reset operation (00b0h, 00f0h, 00f3h or warm reset is released) 0 1 pending clears to ?0? ?0? is written to this bit 1 0 off
muxonenand1g(kfm1g16q2m-deb5) flash memory 58 muxonenand2g(kfn2g16q2m-deb5) 2.8.25 nand flash write protec tion status register f24eh (r) this read register shows the write protection status of the nand flash memory array. to read the write protection status, f ba has to be set before reading the register . f24eh, default = 0002h write protection status information[2:0] 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000000000) us ls lts item bit definition description us 2 unlocked status 1 = current nand flash block is unlocked ls 1 locked status 1 = current nand flash block is locked lts 0 locked-tight status 1 = current nand flash block is locked-tight this register is reserved for future use. 2.8.26 ecc status register ff00h (r) this read register shows the error correcti on status. the muxonenand can detect 1- or 2-bit errors and correct 1-bit errors. 3- bit or more error detection and correction is not supported. ecc can be performed on the nand flash main and spare memory area s. the ecc status register can also show the number of errors in a sector as a result of an ecc check in during a load operation. ecc status bits are also updated during a boot loadi ng oper- ation. ff00h, default = 0000h error status 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 erm3 ers3 erm2 ers2 erm1 ers1 erm0 ers0 erm, ers ecc status 00 no error 01 1-bit error(correctable) 10 2 bits error (uncorrectable) 11 reserved 2.8.24 end block addr ess register f24dh
muxonenand1g(kfm1g16q2m-deb5) flash memory 59 muxonenand2g(kfn2g16q2m-deb5) ecc information[15:0] item definition description erm0 1st selected sector of the main bufferram status of errors in the 1st selected sector of the main bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. erm1 2nd selected sector of the main bufferram status of errors in the 2nd selected sector of the main bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. erm2 3rd selected sector of the main bufferram status of errors in the 3rd selected sector of the main bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. erm3 4th selected sector of the main bufferram status of errors in the 4th selected sector of the main bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. ers0 1st selected sector of the spare bufferram status of errors in the 1st selected sector of the spare bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. ers1 2nd selected sector of the spare bufferram status of errors in the 2nd selected sector of the spare bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. ers2 3rd selected sector of the spare bufferram status of errors in the 3rd selected sector of the spare bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. ers3 4th selected sector of the spare bufferram status of errors in the 4th selected sector of the spare bufferram as a result of an ecc check during a load operation. also updated during a bootload operation. 2.8.28 ecc result of 1 st selected sector, spare area data register ff02h (r) this read register shows the error correction result for the 1st selected sector of the spare area data. ecclogsector0 is the e rror position address for 1.5 words of 2nd and 3rd words in the spare ar ea. eccposio0 is the error position address which selects 1 of 16 dqs. ecclogsector0 and eccposio0 are also updated at boot loading. ff02h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000000) ecclogsector0 eccposio0 this read register shows the error correction result for the 1st selected sector of the main area data. eccposword0 is the erro r position address in the main area data of 256 words. eccposio 0 is the error position address which selects 1 of 16 dqs. eccposword0 and eccposio0 are also updated at boot loading. ff01h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000) eccposword0 eccposio0 2.8.27 ecc result of 1 st selected sector, main area data register ff01h (r)
muxonenand1g(kfm1g16q2m-deb5) flash memory 60 muxonenand2g(kfn2g16q2m-deb5) this read register shows the error correction result for the 2nd selected sector of the main area data. eccposword1 is the erro r position address in the main area data of 256 words. eccpos io1 is the error position address which selects 1 of 16 dqs. eccposword1 and eccposio1 are also updated at boot loading. ff03h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000) eccposword1 eccposio1 2.8.30 ecc result of 2 nd selected sector, spare area data register ff04h (r) this read register shows the error correction result for the 2nd selected sector of the spare area data. ecclogsector1 is the e rror position address for 1.5 words of 2nd and 3rd words in the spare ar ea. eccposio1 is the error position address which selects 1 of 16 dqs. ecclogsector1 and eccposio1 are also updated at boot loading. ff04h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000000) ecclogsector1 eccposio1 2.8.32 ecc result of 3 rd selected sector, spare area data register ff06h (r) this read register shows the error correction result for the 3r d selected sector of the spare area data. ecclogsector2 is the e rror position address for 1.5 words of 2nd and 3rd words in the spare ar ea. eccposio2 is the error position address which selects 1 of 16 dqs. ecclogsector2 and eccposio2 are also updated at boot loading. ff06h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000000) ecclogsector2 eccposio2 2.8.31 ecc result of 3 rd selected sector, main area data register ff05h (r) this read register shows the error correction result for the 3rd selected sector of the main area data. eccposword2 is the erro r position address in the main area data of 256 words. eccposio 2 is the error position address which selects 1 of 16 dqs. eccposword2 and eccposio2 are also updated at boot loading. ff05h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000) eccposword2 eccposio2 2.8.29 ecc result of 2 nd selected sector, main area data register ff03h (r)
muxonenand1g(kfm1g16q2m-deb5) flash memory 61 muxonenand2g(kfn2g16q2m-deb5) this read register shows the error correction result for the 4th selected sector of the main area data. eccposword3 is the erro r position address in the main area data of 256 words. eccpos io3 is the error position address which selects 1 of 16 dqs. eccposword3 and eccposio3 are also updated at boot loading. ff07h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000) eccposword3 eccposio3 2.8.34 ecc result of 4 th selected sector , spare area data register ff08h (r) this read register shows the error correction result for the 4th selected sector of the spare area data. ecclogsector3 is the e rror position address for 1.5 words of 2nd and 3rd words in the spare ar ea. eccposio3 is the error position address which selects 1 of 16 dqs. ecclogsector3 and eccposio3 are also updated at boot loading. ff08h, default = 0000h 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 reserved(0000000000) ecclogsector3 eccposio3 2.8.33 ecc result of 4 th selected sector, main area data register ff07h (r) ecc log sector ecclogsector0~ecclogsector3 indicates t he error position in the 2nd word and lsb of 3rd word in the spare area. refer to note 2 in chapter 2.7.2 ecclogsector information [5:4] ecclogsector error position 00 2nd word 01 3rd word 10, 11 reserved
muxonenand1g(kfm1g16q2m-deb5) flash memory 62 muxonenand2g(kfn2g16q2m-deb5) this section of the datasheet discusses the operation of the muxonenand device. it is followed by ac/dc characteristics and timing diagrams which ma y be consulted for further information. the muxonenand supports a limited command-based interface in addi tion to a register-based interface for performing operations on the device. 3.1 command based operation the command-based interface is active in the boot partition. co mmands can only be written with a boot area address. boot area d ata is only returned if no command has been issued prior to the read. the entire address range, except for the boot area, can be used for the data buffer. all commands are written to the boot parti tion. writes outside the boot partition are treated as normal writes to the buffers or registers. the command consists of one or more cycles depending on the comm and. after completion of the command the device starts its exe- cution. writing incorrect information including address and data to the boot partition or writing an improper command will term inate the previous command sequence and make the device enter the ready status. the defined valid command sequences are stated in command sequences table. command sequences note: 1) dp(data partition) : dataram area 2) bp(boot partition) : bootram area [0000h ~ 01ffh, 8000h ~ 800fh]. 3) load data into buffer operation is available within a block(128kb) 4) load 2kb unit into dataram0. current start address(fpa) is automatically incremented by 2kb unit after the load. 5) 0000h -> data is manufacturer id 0001h -> data is device id 0002h -> current block write protection status 6) we toggling can terminate ?read identification data? operation. command definition cycles 1st cycle 2nd cycle read data from buffer add 1 dp 1) data data write data to buffer add 1 dp data data reset muxonenand add 1 bp 2) data 00f0h load data into buffer 3) add 2 bp bp data 00e0h 0000h 4) read identification data 6) add 2 bp xxxxh 5) data 0090h data 3.0 device operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 63 muxonenand2g(kfn2g16q2m-deb5) the buffer memory can be read by addressing a read to the desired buffer area. 3.1.2 writing data to buffer the buffer memory can be written to by addressing a write to a desired buffer area. 3.1.3 reset muxonenand command the reset command is given by writing 00f0h to the boot partiti on address. reset will return all default values into the device . 3.1.4 load data into buffer command load data into buffer command is a two-cycle command. two sequent ial designated command activates this operation. sequentially writing 00e0h and 0000h to the boot partition [0000h~01ffh, 8000h~800f h] will load one page to dataram0. this operation refers to fba and fpa. fsa, bsa, and bsc are not considered. at the end of this operation, fpa will be automatically increased by 1. so conti nuous issue of this command will sequentially l oad data in next page to dataram0. this page address increment is restricted within a block. the default value of fba and fpa is 0. therefore, initial issue of this command after power on will load the first page of memo ry, which is usually boot code. 3.1.5 read identi fication data command the read identification data command consists of two cycles. it gives out the devices identificat ion data according to the give n address. the first cycle is 0090h to the boot partition address and second cycle is r ead from the addresses specified in identi fication data description table. identification data description note 1) to read the write protection status, fba has to be set before issuing this command. address data out 0000h manufacturer id (00ech) 0001h device id (0020h) 0002h current block write protection status 1) 3.1.1 reading data from buffer
muxonenand1g(kfm1g16q2m-deb5) flash memory 64 muxonenand2g(kfn2g16q2m-deb5) the device bus operations are shown in the table below. note : l=v il (low), h=v ih (high), x=don?t care. operation ce oe we adq0~15 rp clk avd standby h x x high-z h x x warm reset xxxhigh-zlxx asynchronous write l h l add. in / data in hl asynchronous read l l h add. in / data out hl load initial burst address l h h add. in h burst read l l h burst data out h terminate burst read cycle h x h high-z h x x terminate burst read cycle via rp xxxhigh-zlxx terminate current burst read cycle and start new burst read cycle h h add in h h 3.2 device bus operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 65 muxonenand2g(kfn2g16q2m-deb5) the one nand has 4 reset modes: cold/warm/hot reset, and nand flash array reset. section 3.3 discusses the operation of these reset modes. the register reset table shows the which registers ar e affected by the various types or reset operations. internal register reset table note: 1) rdypol, intpol, iobe are reset by cold reset. the other bits except otp l are reset by cold/warm/hot reset. otp l is updated by cold reset, referring to the specified otp area. 2) ecc status register & ecc result registers are reset when any command is issued. 3) refer to device id register f001h. internal registers default cold reset warm reset (rp ) hot reset (00f3h) hot reset (bp-f0) nand flash reset(00f0h) f000h manufacturer id register (r) 00ech n/a n/a n/a n/a f001h device id register (r): muxonenand (note 3) n/a n/a n/a n/a f002h version id register (r) n/a n/a n/a n/a n/a f003h data buffer size register (r) 0800h n/a n/a n/a n/a f004h boot buffer size register (r) 0200h n/a n/a n/a n/a f005h amount of buffers register (r) 0201h n/a n/a n/a n/a f006h technology register (r) 0000h n/a n/a n/a n/a f100h start address1 register (r/w): fba 0000h 0000h 0000h 0000h n/a f101h start address2 register (r/w): reserved 0000h 0000h 0000h 0000h n/a f102h start address3 register (r/w): fcba 0000h 0000h 0000h 0000h n/a f103h start address4 register (r/w): fcpa, fcsa 0000h 0000h 0000h 0000h n/a f107h start address8 register (r/w): fpa, fsa 0000h 0000h 0000h 0000h n/a f200h start buffer register (r/w): bsa, bsc 0000h 0000h 0000h 0000h n/a f220h command register (r/w) 0000h 0000h 0000h 0000h n/a f221h system configuration 1 register (r/w) 40c0h 40c0h (note1) (note1) n/a f240h controller status register (r) 0000h 0000h 0000h 0000h n/a f241h interrupt status register (r/w) - 8080h 8010h 8010h n/a f24ch start block address (r/w) 0000h 0000h 0000h n/a n/a f24dh end block address: n/a n/a n/a n/a n/a n/a f24eh nand flash write protection status (r) 0002h 0002h 0002h n/a n/a ff00h ecc status register (r) (note2) 0000h 0000h 0000h 0000h n/a ff01h ecc result of sector 0 main area data register(r) 0000h 0000h 0000h 0000h n/a ff02h ecc result of sector 0 spare area data register (r) 0000h 0000h 0000h 0000h n/a ff03h ecc result of sector 1 main area data register(r) 0000h 0000h 0000h 0000h n/a ff04h ecc result of sector 1 spare area data register (r) 0000h 0000h 0000h 0000h n/a ff05h ecc result of sector 2 main area data register(r) 0000h 0000h 0000h 0000h n/a ff06h ecc result of sector 2 spare area data register (r) 0000h 0000h 0000h 0000h n/a ff07h ecc result of sector 3 main area data register(r) 0000h 0000h 0000h 0000h n/a ff08h ecc result of sector 3 spare area data register (r) 0000h 0000h 0000h 0000h n/a 3.3 reset mode operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 66 muxonenand2g(kfn2g16q2m-deb5) 3.3.2 warm r eset mode operation see timing diagrams 6.10 a warm reset means that the host resets the device by using t he /rp pin. when the a /rp low is issued, the device logic stops a ll current operations and executes internal reset operation and re sets current nand flash core operation synchronized with the falling edge of /rp. during an internal reset operation, the device initializes internal registers and makes output signals go to default status. the bufferram data is kept unchanged after warm/hot reset operations. the device guarantees the logic reset operation in case /rp pulse is longer than trp min(200ns). the device may reset if trp < trp min(200ns), but this is not guaranteed. warm reset will abort the current nand flash core operation. duri ng a warm reset, the content of memory cells being altered is no longer valid as the data will be partially programmed or erased. warm reset has no effect on contents of bootram and dataram. 3.3.3 hot re set mode operation see timing diagram 6.11 a hot reset means that the host resets the device by reset command. the reset command can be either command based or register based. upon receiving the reset command, the device logic stops all current operation and executes an internal reset operation and resets the current nand flash core operation. during an internal reset operation, the device initializes inte rnal registers and makes output signals go to default status. th e bufferram data is kept unchanged after warm/hot reset operations. hot reset has no effect on contents of bootram and dataram. 3.3.4 nand flash core reset mode operation see timing diagram 6.12 the host can reset the nand flash core operation by issuing a nand flash core reset command. nand flash core reset will abort the current nand flash core operation. during a nand flash core reset, the content of memory cells being altered is no lo nger valid as the data will be partially programmed or erased. nand flash core reset has an effect on neither cont ents of bootram and dataram nor register values. at system power-up, the voltage detector in the device detects the rising edge of vcc and releases an internal power-up reset s ignal. this triggers bootcode loading. bootcode loading means that the boot loader in the device copies designated sized data (1kb) fr om the beginning of memory into the bootram. this sequence is the cold reset of muxonenand. the por(power on reset) triggering le vel is typically 1.5v. boot code copy operation activates 400us after por. therefore, the system power should reach 1.7v within 400us from the por triggering level for bootcode data to be valid. it takes approximately 70us to copy 1kb of bootcode. upon completi on of loading into the bootram, it is available to be read by the host. the int pin is not available until afte r iobe = 1 and iobe bit can be changed by host. 3.3.1 cold reset mode operation see timing diagram 6.9
muxonenand1g(kfm1g16q2m-deb5) flash memory 67 muxonenand2g(kfn2g16q2m-deb5) the muxonenand can be write-protected to pr event re-programming or erasure of data. the areas of write-protection are the bootram, and the nand flash array. 3.4.1 bootram write protection operation at system power-up, voltage detector in the device detects the ri sing edge of vcc and releases the internal power-up reset sign al which triggers bootcode loading. and the des ignated size data(1kb) is copied from the first page of the first block in the nand flash array to the bootram. after the bootcode loading is completed, t he bootram is always locked to protect the boot code from the accidental write. 3.4.2 nand flash array wr ite protection operation the device has both hardware and software writ e protection of the nand flash array. hardware write protection operation the hardware write protection operation is implemented by executing a cold or warm reset. on power up, the nand flash array is in its default, locked state. the entire nand flash array goes to a locked state after a cold or warm reset. software write protection operation the software write protection operation is implemented by writing a lock command ( 002ah) or a lock-tight command (002ch) to command register (f220h). lock (002ah) and lock-tight (002ch) commands write protects t he block defined in the start block address register f24ch. 3.4.3 nand array write protection states there are three lock states in the nand array: unlocked, locked, and locked-tight. muxonenand1g supports lock/unlock/lock-tight by one block , so each block should be locked/un locked/locked-tight individually. write protection status the current block write protection status c an be read in nand flash write protection status register(f24eh). there are three bi ts - us, ls, lts -, which are not cleared by hot reset. these writ e protection status registers are updated when fba is set, and whe n write protection command is entered. the followings summarize locking status. example) in default, [2:0] values are 010. -> if host executes unlock bl ock operation, then [2:0] values turn to 100. -> if host executes lock-tight block operation, then [2:0] values turn to 001. 3.4 write protection operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 68 muxonenand2g(kfn2g16q2m-deb5) an unlocked block can be programmed or erased. the status of an unlocked block can be changed to locked or locked-tight using the appropriate software command. (locked-tight state can be achieved via lock-tight command which follows lock command) only one block can be released from lock state to unlock st ate with unlock command and addresses. the unlocked block can be changed with new lock command. therefore, each bl ock has its own lock/unlock/lock-tight state. unlock command sequence: start block address+unlock block command (0023h) unlocked 3.4.3.2 locked nand array writ e protection state a locked block cannot be programmed or erased. all blocks default to a locked state following a cold or warm reset. unlocked blocks can be changed to locked using the lock block command. the status of a lo cked block can be changed to unlocked or locked-tight using the appropriate software command. lock command sequence: start block address+lock block command (002ah) locked 3.4.3.1 unlocked nand array write protection state
muxonenand1g(kfm1g16q2m-deb5) flash memory 69 muxonenand2g(kfn2g16q2m-deb5) a block that is in a locked-tight state can only be changed to locked state after a cold or warm reset. unlock and lock command sequences will not affect its state. this is an added level of write protection security. a block must first be set to a locked state before it can be changed to locked-tight using the lock-tight command. locked-tight blocks will revert to a locked state following a cold or warm reset. lock-tight command sequence: start block address+lock-tight block command (002ch) locked-tight 3.4.4 nand flash arra y write protection state diagram power on start block address +unlock block command rp pin: high & lock block command rp pin: high & +lock-tight block command rp pin: high & cold reset or unlock lock lock-tight lock lock warm reset start block address lock lock start block address cold reset or warm reset or 3.4.3.3 locked-tight nand array write protection state
muxonenand1g(kfm1g16q2m-deb5) flash memory 70 muxonenand2g(kfn2g16q2m-deb5) data protection operation flow diagram start write ?dfs*, sba? of flash add: f24ch dq=dfs*, sba lock/unlock/lock-tight write ?lock/unlock/lock-tight? add: f220h dq=002ah/0023h/002ch wait for int register low to high transition add: f241h dq[15]=int write 0 to interrupt register add: f241h dq=0000h command completed * dfs is for ddp note) samsung strongly recommends to follow the above flow chart
muxonenand1g(kfm1g16q2m-deb5) flash memory 71 muxonenand2g(kfn2g16q2m-deb5) the device is designed to offer protection from any involuntary program/erase during power-transitions. an internal voltage detector disables all functions whenever vc c is below por level, about 1.3v. it is recommended that the /rp pin, which provides hardware protection, s hould be kept at vil before power-down. 3.6 load operation see timing diagrams 6.6 the load operation is initiated by setting up the start address from which the data is to be loaded. the load command is issued in order to initiate the load. during a load operation, the device: -transfers t he data from nand flash array into the bufferram -ecc is checked and any detect ed and corrected error is reported in the status response as well as any unrecoverable error. once the bufferram has been filled, an interrupt is issued to the host so that the contents of the bufferram can be read. the r ead from the bufferram can be an asynchronous read mode or synchron ous read mode. the status information related to load operation can be checked by the host if required. the device has a dual data buffer memory architecture (dataram 0, dataram1), each 2kb in size. each dataram buffer has 4 sectors. the device is capable of independent and simultaneous dat a-read operation from one data buffer and data-load operation to the other data buffer. refer to the information for more details in section 3.12.1, "read-while-load operation". load operation flow chart diagram start write ?dfs*, fba? of flash add: f100h dq=fba write ?fpa, fsa? of flash add: f107h dq=fpa, fsa write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc select dataram for ddp add: f101h dq=dbs write ?load? command add: f220h dq=0000h or 0013h wait for int register low to high transition add: f241h dq[15]=int read controller add: f240h dq[10]=error dq[10]=0? no yes * dbs, dfs is for ddp status register host reads data from dataram read completed map out write 0 to interrupt register add: f241h dq=0000h 3.5 data protection during power down operation see timing diagram 6.13
muxonenand1g(kfm1g16q2m-deb5) flash memory 72 muxonenand2g(kfn2g16q2m-deb5) the device has two read modes; asynch ronous read and synchronous burst read. the initial state machine automatically sets the device into the asynchronous read mode (rm=0) to prevent the spurious altering of memory content upon device power up or after a hardware reset. no commands are required to retrieve data in asynchronous read mode. the synchronous read mode is enabled by setting rm bit of system configuration1 register (f221h) to synchronous read mode (rm=1). see section 2.8.19 for mo re information about system configuration1 register. in an asynchronous read mode, data is output with respect to a logic input, /avd. output data will appear on dq15-dq0 when a va lid address is asserted on a15-a0 while driv ing /avd and /ce to vil. / we is held at vih. the function of the /avd si gnal is to latch the valid address. address access time from /avd low (taa) is equal to the delay from valid addresses to valid output data. the chip enable access time (tce) is equal to the delay from the falling edge of /ce to valid data at the outputs. the output enable access time (toe) is the delay from the falling edge of oe to valid data at the output. 3.7.2 synchronous re ad mode operation (rm=1) see timing diagrams 6.1 and 6.2 in a synchronous read mode, data is out put with respect to a clock input. the device is capable of a continuous linear burst operation and a fixed-length linear bur st operation of a preset length. bur st address sequences for continuous and fixed-length bur st operations are shown in the table below. burst address sequences in the burst mode, the initial word will be output asynchronously, regardless of brl. while the following words will be determi ned by brl value. the latency is determined by the host based on the brl bit setting in the system configuration 1 register. the default brl is 4 latency cycles. at clock frequencie s of 40mhz or lower, latency cycles can be r educed to 3. brl can be set up to 7 latency cycl es. the brl registers can be read during a burst read mode by using the /avd signal with an address. start addr. burst address sequence(decimal) continuous burst 4-word burst 8-word burst 16-word burst 32-word burst wrap around 0 0-1-2-3-4-5-6... 0-1-2-3-0... 0-1-2-3-4-5-6-7-0... 0-1-2-3-4-....-13-14-15-0... 0-1-2-3-4-....-29-30-31-0... 1 1-2-3-4-5-6-7... 1-2-3-0-1... 1-2-3-4-5-6-7-0-1... 1-2-3-4-5-....-14-15-0-1... 1-2-3-4-5-....-30-31-0-1... 2 2-3-4-5-6-7-8... 2-3-0-1-2... 2-3-4-5-6-7-0-1-2... 2-3-4-5-6-....-15-0-1-2... 2-3-4-5-6-....-31-0-1-2... . . . . . . . . . . . . 3.7.1 asynchronous read mode operation (rm=0) see timing diagrams 6.3 and 6.4 3.7 read operation see timing diagrams 6.1, 6.2, 6.3 and 6.4
muxonenand1g(kfm1g16q2m-deb5) flash memory 73 muxonenand2g(kfn2g16q2m-deb5) first clock cycle the initial word is output at tiaa after the rising edge of the first clk cycle. the rdy output indicates the initial word is r eady to the system by pulsing high. if the devic e is accessed synchronously while it is set to asynchronous read mode, the first data can s till be read out. subsequent clock cycles subsequent words are output (burst access time from valid clock to output) tba after the rising edge of each successive clock cycle, which automatically increment s the internal address counter. terminating burst read the device will continue to output sequentia l burst data until the system asserts /c e high, or /rp low, wrapping around until i t reaches the designated address (see section 2.7.3 for address map information). alternately, a cold/warm/hot reset, or a /we low pulse will terminate the burst read operation. synchronous read boundary division add.map(word order) bootram main(0.5kw) 0000h~01ffh brfferram0 main(1kw) 0200h~05ffh bufferram1 main(1kw) 0600h~09ffh reserved main 0a00h~7fffh bootram spare(16w) 8000h~800fh bufferram0 spare(32w) 8010h~802fh bufferram1 spare(32w) 8030h~804fh reserved spare 8050h~8fffh reserved register 9000h~efffh register(4kw) f000h~ffffh not support not support * reserved area is not available on synchronous read 3.7.2.2 4-, 8-, 16- , 32-word linear burst read operation see timing diagram 6.1 an alternate burst read mode enables a fixed number of words to be read from consecutive address. the device supports a burst read from cons ecutive addresses of 4-, 8-, 16-, and 32-words with a linear-wrap around. when the la st word in the burst has been reached, assert /ce and /oe high to terminate the operation. in this mode, the start address for the burst read can be any address of the address map with one exception. the device does no t support a 32-word linear burst read on the spare area of the bufferram. not support not support not support 3.7.2.1 continuou s linear burst read operation see timing diagram 6.2
muxonenand1g(kfm1g16q2m-deb5) flash memory 74 muxonenand2g(kfn2g16q2m-deb5) upon power up, the number of initial clock cycles from vali d address (/avd) to initial data defaults to four clocks. the number of clock cycles (n) which are inserted after the cloc k which is latching t he address. the host can read the first da ta with the (n+1)th rising edge. the number of total initial access cycles is programmable from three to seven cycles . after the number of programmed burst cloc k cycles is reached, the rising edge of the nex t clock cycle triggers the next burst data. four clock burst read latency (default condition) 3.7.3 handshaking operation the handshaking feature allows the host system to simply monitor the rdy signal from the device to determine when the initial word of burst data is ready to be read. to set the number of initial cycles for optimal burst mode, t he host should use the programmable burst read latency configurati on (see section 2.8.19, "system configuration1 register"). the rising edge of rdy which is derived at the same cycle of data fetch clock indica tes the initial word of valid burst data. 3.7.2.3 programmable burs t read latency operation see timing diagrams 6.1 and 6.2 t iaa hi-z ce clk avd oe rdy t rdya a/dq0: a/dq15 d6 d7 d0 d1 d2 d3 d7 d0 hi-z valid address -1 0 1 2 3 t ba rising edge of the clock cycle following last read latency triggers next burst data t rdys 4
muxonenand1g(kfm1g16q2m-deb5) flash memory 75 muxonenand2g(kfn2g16q2m-deb5) when the /ce or /oe input is at v ih , output from the device is disabled. the outputs are placed in the high impedance state. the program operation is used to program data from the on-chip bufferrams into the nand flash memory array. the device has two 2kb data buffers, each 1 page (2kb + 64b) in size. each page has 4 sectors of 512b each main area and 16b spare area. the device can be programmed in units of 1~4 sectors. the architecture of the datarams permits a simultaneous data-write operation from the host to one of data buffers and a program operation from the other data buffer to the nand flash array me mory. refer to section 3.12.2, "write while program operation", for more information. 3.8 program operation see timing diagram 6.7 within a block, the pages must be programme d consecutively from the lsb (least significant bit) page of the block to msb (most sig- nificant bit) pages of the block. r andom page address programming is prohibited. from the lsb page to msb page data in: data (1) data (64) (1) (2) (3) (32) (64) data register page 0 page 1 page 2 page 31 page 63 ex.) random page program (prohibition) data in: data (1) data (64) (2) (32) (3) (1) (64) data register page 0 page 1 page 2 page 31 page 63 addressing for program operation : : : : 3.7.4 output disable mode operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 76 muxonenand2g(kfn2g16q2m-deb5) program operation flow diagram during the execution of the internal program routine, the host is not required to provide any furt her controls or timings. furt hermore, all commands, except a reset command, will be ignored. a reset duri ng a program operation will cause data corruption at the cor re- sponding location. if a program error is detected at the completion of the internal program routine, map out the block, including the page in err or, and copy the target data to another block. an error is signal ed if dq10 = "1" of controller status register(f240h) . data input from the host to the dataram can be done at any time during the internal program routine after "start" but before th e "write program command" is written. start data input write ?dfs*, fba? of flash add: f100h dq=dfs*?, fba write ?fpa, fsa? of flash add: f107h dq=fpa, fsa select dataram for ddp 1) add: f101h dq=dbs* write data into dataram 2) add: dp dq=data-in program completed write ?program? command add: f220h dq=0080h or 001ah completed? wait for int register low to high transition add: f241h dq[15]=int read controller status register add: f240h dq[10]=error dq[10]=0? program error yes no no yes * dbs, dfs is for ddp : if program operation results in an error, map out the block including the page in error and copy the target data to another block. * note 1) this must happen before data input 2) data input could be done anywhere between "start" and "write program command". write 0 to interrupt register add: f241h dq=0000h write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc
muxonenand1g(kfm1g16q2m-deb5) flash memory 77 muxonenand2g(kfn2g16q2m-deb5) the copy-back program is configured to qu ickly rewrite data stored in one page without utilizing memory other than muxonenand. since the time-consuming cycles of serial access and re-loading c ycles are removed, the system performance is improved. the ben - efit is especially obvious when a portion of block is updated and the rest of the blo ck also need to be copied to the newly ass igned free block. data from the source page is saved in one of the on-chip dataram buffers and then programmed directly into the destination page . the dataram overwrites the previous data using the buffer sector a ddress (bsa) and buffer sector count (bsc). the copy-back program operation does this by performing s equential page-reads without a serial access and executing a copy-program using the address of the destination page. copy-back program operation flow chart start write ?dfs*, fba? of flash add: f100h dq=dfs*, fba write ?fpa, fsa? of flash add: f107h dq=fpa, fsa write ?fcba? of flash add: f102h dq=fcba write ?fcpa, fcsa? of flash add: f103h dq=fcpa, fcsa copy back completed write ?copy-back program? command add: f220h dq=001bh wait for int register low to high transition add: f241h dq[15]=int read controller status register add: f240h dq[10]=error dq[10]=0? copy back error yes no * dbs, dfs is for ddp note 1) selected dataram by bsa & bsc is used for copy back operation, so previous data is overwritten. : if program operation results in an error, map out the block including the page in error and copy the target data to another block. * 2) fba, fpa and fsa should be input prior to fcba, fcpa and fcsa. select dataram for ddp add: f101h dq=dbs* write 0 to interrupt register add: f241h dq=0000h write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc 1) 3.9 copy-back program operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 78 muxonenand2g(kfn2g16q2m-deb5) the copy-back steps shown in the flow chart are: ? data is read from the nand array using flash bl ock address (fba), flash page address (fpa) and flash sector address (fsa). fba, fpa, and fsa identify the source address to read data from nand flash array. ? the bufferram sector count (bsc) and bufferram se ctor address (bsa) identifies how many sectors and the location of the sectors in dataram that are used. ? the destination address in the nand array is writt en using the flash copy-ba ck block address (fcba), flash copy-back page addre ss (fcpa), and flash copy-bac k sector address (fcsa). ? the copy-back program command is issued to start programming. ? upon completion of copy-back programming to the destination page address, the host checks the status to see if the operation was successful ly completed. if there was an error, map out the block including the page in error and copy the target data to another block.
muxonenand1g(kfm1g16q2m-deb5) flash memory 79 muxonenand2g(kfn2g16q2m-deb5) the copy-back program operation with random data input in muxonenand consists of 2 phase, load data into dataram, modify data and program into designated page. data from the source page is saved in one of the on-chip dataram buffers and modified by the host, then programmed into the destination page. as shown in the flow chart, data modificati on is possible upon completion of load operat ion. ecc is also available at the end o f load operation. therefore, using hardware ecc of muxo nenand, accumulation of 1 bit error can be avoided. copy-back program operation with random data input will be effe ctively utilized at modifying ce rtain bit, byte, word, or sector of source page to destination p age while it is being copied. copy-back program operation with random data input flow chart start write ?dfs*, fba? of flash add: f100h dq=dfs, fba write ?fpa, fsa? of flash add: f107h dq=fpa, fsa write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc select dataram for ddp add: f101h dq=dbs write ?load? command add: f220h dq=0000h or 0013h wait for int register low to high transition add: f241h dq[15]=int read controller add: f240h dq[10]=error dq[10]=0? no yes * dbs, dfs is for ddp status register map out write 0 to interrupt register add: f241h dq=0000h copy back completed wait for int register low to high transition add: f241h dq[15]=int read controller status register add: f240h dq[10]=error dq[10]=0? copy back error yes no random data input write ?fba? of flash add: f100h dq=fba write ?fpa, fsa? of flash add: f107h dq=fpa, fsa write ?program? command add: f220h dq=0080h or 001ah write 0 to interrupt register add: f241h dq=0000h add: random address in selected dataram dq=data 3.9.1 copy-back program op eration with random data input
muxonenand1g(kfm1g16q2m-deb5) flash memory 80 muxonenand2g(kfn2g16q2m-deb5) there are multiple methods for erasing data in th e device including block erase and multi-block erase. 3.10.1 block erase operation see timing diagram 6.8 the device can be erased one block at a time. to erase a block is to write all 1's into the desired memory block by executing t he inter- nal erase routine. all previous data is lost. block erase operation flow chart start write ?dfs*, fba? of flash add: f100h dq=dfs*, fba write ?erase? command add: f220h dq=0094h wait for int register add: f241h dq=[15]=int add: f240h dq[10]=error erase completed dq[10]=0? yes erase error no low to high transition read controller status register : if erase operation results in an error, map out the failing block and replace it with another block. * write 0 to interrupt register add: f241h dq=0000h * dfs is for ddp 3.10 erase operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 81 muxonenand2g(kfn2g16q2m-deb5) in order to perform the internal erase rout ine, the following comm and sequence is necessary. ? the host selects flash core of ddp chip. ? the host sets the block address of the memory location. ? the erase command initiates the internal erase routin e. during the execution of the routine, the host is not required to provide further controls or timings. during the internal erase routine, all commands, except the reset command and eras e suspend command, written to the device will be ignored. a reset during an erase operation will cause data corruption at the corresponding location. using multi-block erase, the device can eras e up to 64 multiple blocks simultaneously. multiple blocks can be erased by issuing a multi-block erase command and writing the block address of the memory location to be erased. the final flash block address (fba) and block erase command initiate the internal multi block erase routine. during a multi-block erase, the ongo bit of the cont roller status register is set to '1'(busy) from the time first block address to be l atched is written until the actual erase has finished. during block address latch sequence, issui ng of other commands except block erase, multi block erase, and erase suspend at int=high will abort the current operation. so to speak, it will c ancel the previously latched addresses of multi block erase op eration. on the other hand, other command issue at int=low will be ignored. a reset during an erase operation will cause data corrupti on at the address location being operated on during the reset. despite a failed block during multi-block erase operation, the de vice will continue the erase oper ation until all other specifi ed blocks are erased. erase suspend command issue during multi bloc k erase address latch sequence is prohibited. locked blocks if there are locked blocks in the specified range, t he multi-block erase operation works as the follows. case 1: all specified blocks except ba(2) will be erased. [ba(1)+0095h] + [ ba((2), locked)) +0095h] + ... + [ba(n-1)+0095h] + [ba(n)+0094h] case 2: multi-block erase operation is su spended and fails to start if the last block erase command is put together with the lo cked block address until right command and address input are issued. [ba(1)+0095h] + [ba(2)+0095h] + ... + [ba(n-1)+0095h] + [ ba((n), locked)) +0094h] case 3: all specified blocks except ba(n) are erased. [ba(1)+0095h] + [ba(2)+0095h] + ... + [ba(n-1)+0095h] + [ ba((n, locked)) +0094h] + [ba(n+1)+0094h] 3.10.2 multi-blo ck erase operation see timing diagram 6.8
muxonenand1g(kfm1g16q2m-deb5) flash memory 82 muxonenand2g(kfn2g16q2m-deb5) after a multi-block erase operation, verify erase operation result of each block with multi-block erase verify command combined with address of each block. if a failed address is identified, it must be managed in firmware. multi block erase/ multi block erase verify read flow chart start write ?dfs 1) , fba? of flash add: f100h dq=dfs, fba write ?multi block erase? add: f220h dq=0095h wait for int register add: f241h dq=[15]=int final multi block yes no low to high transition write 0 to interrupt register add: f241h dq=0000h command erase? write ?fba? of flash add: f100h dq=fba write ?block erase add: f220h dq=0094h wait for int register add: f241h dq=[15]=int low to high transition write 0 to interrupt register add: f241h dq=0000h command? multi block erase verify read write ?fba? of flash add: f100h dq=fba write ?multi block erase add: f220h dq=0071h wait for int register add: f241h dq=[15]=int low to high transition write 0 to interrupt register add: f241h dq=0000h verify read command? read controller add: f240h dq[10]=error status register dq[10]=0? multi block erase completed final multi block yes no erase address? erase completed yes erase error no *dfs is for ddp note 1) dfs should be a fixed value, for multi block erase is performed within a single chip. 3.10.3 multi-block er ase verify read operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 83 muxonenand2g(kfn2g16q2m-deb5) the erase suspend/erase resume commands interrupt and restart a bl ock erase or multi-block eras e operation so that user may perform another urgent operation on the block that is not being designated by erase/mu lti-block erase operation. erase suspend during a block erase operation when erase suspend command is written during a block erase or multi-block erase operat ion, the device requires a maximum of 500us to suspend erase operation. erase suspend command issue during block address latch sequence is prohibited. after the erase operation has been suspended, the device is ready for the next operation including a load, program, copy-back program, lock, unlock, lock-tight, hot reset, nand flash core reset, command based reset, multi-block erase read verity, or otp access. the subsequent operation can be to any block that was not being erased. a special case arises pertaining erase suspend to the otp. a reset command is used to exit from the otp access mode. if the reset-triggered exit from the otp access mode happens during an er ase suspend operation, the eras e routine could fail. therefor e to exit from the otp access mode without suspending the er ase operation stop, a 'nand flash core reset' command should be issued. for the duration of the erase suspend peri od the following commands are not accepted: ? block erase/multi-blo ck erase/erase suspend erase suspend and erase resume operation flow chart start write ?erase suspend add: f220h dq=00b0h wait for int register add: f241h dq=[15]=int low to high transition for 500us command? 1) write 0 to interrupt register add: f241h dq=0000h write ?erase resume add: f220h dq=0030h wait for int register add: f241h dq=[15]=int low to high transition write 0 to interrupt register add: f241h dq=0000h command? another operation * * another operation ; load, program copy-back program, otp access 2) , hot reset, flash reset, cmd reset, multi block erase verify, lock, lock-tight, unlock check controller status register do multi block erase verify read in case of block erase in case of multi block erase 2) if otp access mode exit happens with reset operation during erase suspend mode, reset operation could hurt the erase operation. so if a user wants to exit from otp access mode without the erase operation stop, reset nand flash core command should be used. note 1) erase suspend command input is prohibited during multi block erase address latch period. 3.10.4 erase suspend / erase resume operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 84 muxonenand2g(kfn2g16q2m-deb5) erase resume when the erase resume command is executed, the block erase will restart. the erase resume operation does not actually resume the erase, but starts it again from the beginning. when an erase suspend or erase resume command is executed, the addresses are in don't care state. for multi block erase, erase suspend/resume can be operated after final erase command (0094h) is issued. therefore, erase resume operation does not actually resume from the erased block. but resumes the multi block erase from the begging. on block of the nand flash array memory is rese rved as a one-time programmable block memory area. the otp block can be read, programmed and locked using the same operations as any other nand flash array memory block. otp block cannot be erased. otp block is fully-guaran teed to be a valid block. entering the otp block the otp block is separately accessible from the rest of the nand flash array by using the otp access command instead of the flash block address (fba). exiting the otp block to exit the otp access mode, a cold-, warm-, hot- , or nand flash core reset operation is performed. exiting the otp block during an erase operation if the reset-triggered exit from the otp access mode happens during an erase suspend operation, the erase routine could fail. therefore to exit from the otp ac cess mode without suspending the erase operation stop, a 'nand flash core reset' command should be issued. the otp block page assignments otp area is one block size (128kb+4kb, 64 pages) and is divided into two areas. the 10- page user area is available as an otp storage area. the 54-page manufacturer area is programmed by t he manufacturer prior to shipping the device to the user. otp block page allocation information area page use user 0 ~ 9 (10 pages) designated as user area manufacturer 10 ~ 63 (54 pages) us ed by the device manufacturer 3.11 otp operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 85 muxonenand2g(kfn2g16q2m-deb5) otp area structure page:2kb+64b sector(main area):512b sector(spare area):16b one block: 128kb+4kb 64pages manufacturer area : page 10 to page 63 54pages user area : page 0 to page 9 10pages
muxonenand1g(kfm1g16q2m-deb5) flash memory 86 muxonenand2g(kfn2g16q2m-deb5) an otp load operation accesses the otp ar ea and transfers identified content from the otp to the dataram on-chip buffer, thus making the otp contents available to the host. the otp area is a separate part of the nand flash array memo ry. it is accessed by issuing otp access command(65h) instead of a flash block address (fba) command. after being accessed with the ot p access command, the contents of otp memory area are loaded using the same operations as a normal load operation to the nand flash array memory (see section 3.6 for more information). to exit the otp access mode following an otp load operation, a cold -, warm-, hot-, or nand flash core reset operation is per- formed. otp read operation flow chart start wait for int register add: f241h dq[15]=int write 0 to interrupt register add: f241h dq=0000h write ?fpa, fsa? of flash add: f107h dq=fpa, fsa otp reading completed write ?load? command add: f220h dq=0000h or 0013h wait for int register low to high transition add: f241h dq[15]=int write ?otp access? command add: f220h dq=0065h write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc low to high transition otp exit host reads data from dataram note 1) fba(nand flash block address) could be any address. do cold/warm/hot /nand flash core reset * dfs is for ddp write ?dfs*, fba? of flash 1) add: f100h dq=dfs*?, fba write 0 to interrupt register add: f241h dq=0000h select dataram for ddp add: f101h dq=dbs* 3.11.1 otp load operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 87 muxonenand2g(kfn2g16q2m-deb5) an otp program operation accesses the otp area and programs c ontent from the dataram on-chip buffer to the designated page(s) of the otp. a memory location in the otp area can be programmed only one time (no erase operation permitted). the otp area is programmed using the same sequence as norma l program operation after being accessed by the command (see section 3.8 for more information). programming the otp area ? issue the otp access command ? write data into the dataram (data can be input at anyti me between the "start" and "write program" commands ? issue a flash block address (fba) which is unlo cked area address of nand flash array address map. ? issue a write program command to program the data from the dataram into the otp ? when the otp programming is complete, do a cold-, warm-, ho t-, nand flash core reset to exit the otp access mode. 3.11.2 otp program operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 88 muxonenand2g(kfn2g16q2m-deb5) otp program operation flow chart select dataram for ddp add: f101h dq=dbs* write ?dfs*, fba? of flash 1) add: f100h dq=dfs*?, fba start data input write ?otp access? command add: f220h dq=0065h write ?fpa, fsa? of flash add: f107h dq=fpa, fsa write ?bsa, bsc? of dataram add: f200h dq=bsa, bsc write data into dataram 2) add: dp dq=data-in otp programmin g completed write program command dq=0080h or 001ah completed? wait for int register low to high transition add: f241h dq[15]=int no add: f220h wait for int register add: f241h dq[15]=int write 0 to interrupt register add: f241h dq=0000h low to high transition do cold/warm/hot otp exit automatically checked update controller add: f240h status register wait for int register low to high transition add: f241h dq[15]=int otp exit automatically otp l =0? yes no updated read controller status register add: f240h dq[10]=1(error) dq[14]=1(lock), dq[10]=1(error) add: f200h dq=bsa, bsc write ?fba? of flash add: f100h dq=fba 1) read controller status register add: f240h dq[10]=0(pass) /nand flash core reset do cold/warm/hot /nand flash core reset write 0 to interrupt register add: f241h dq=0000h 2) data input could be done anywhere between "start" and "write program command". note 1) fba(nand flash block address) could be omitted or any address. 3) fba should point the unlocked area address among nand flash array address map.
muxonenand1g(kfm1g16q2m-deb5) flash memory 89 muxonenand2g(kfn2g16q2m-deb5) even though the otp area can only be programmed once without eras e capability, it can be locked when the device starts up to pr e- vent any changes from being made. unlike the main area of the nand flash array memory, once the otp block is locked, it cannot be unlocked. locking the otp programming to the otp area can be prevented by locki ng the otp area. locking the otp area is accomplished by programming xxxch to 8th word of sector0 of page0 of the spare0 memory area. at device power-up, this word location is checked and if xxxch is found, the otpl bit of the controller status register is set to "1", indicating the otp is locked. when the program operation finds that the status of t he otp is locked, the device updates the err or bit of the controller status register as "1" (fail). otp lock operation steps ? issue the otp access command ? fill data to be programmed into dataram (data can be input at anytime between the "start" and "write program" commands) ? write 'xxxch' data into the 8th word of sector0 of page0 of the spare0 memory area of the dataram. ? issue a flash block address (fba) which is unlo cked area address of nand flash array address map. ? issue a program command to program the data from the dataram into the otp ? when the otp lock is complete, do a cold reset to exit the otp access mode and update otp lock bit[6]. ? otp lock bit[6] of the controller status regist er will be set to "1" and the otp will be locked. 3.11.3 otp lock operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 90 muxonenand2g(kfn2g16q2m-deb5) otp lock operation flow chart start write ?fpa, fsa? of flash add: f107h dq=0000h write ?bsa, bsc? of dataram add: f200h dq=0001h write data into dataram 2) add: 8th word write program command dq=0080h or 001ah wait for int register low to high transition add: f241h dq[15]=int add: f220h write 0 to interrupt register add: f241h dq=0000h automatically updated dq=xxxch in spare0/sector0/page0 update controller add: f240h status register otp lock completed dq[6]=1(otp l ) write ?fba? of flash add: f100h dq=fba 3) write ?otp access? command add: f220h dq=0065h wait for int register add: f241h dq[15]=int low to high transition write 0 to interrupt register add: f241h dq=0000h do cold reset write ?dfs?, ?fba? of flash 1) add: f100h dq=dfs, fba select dataram for ddp add: f101h dq=dbs* * dbs, dfs is for ddp 2) data input could be done anywhere between "start" and "write program command". note 1) fba(nand flash block address) could be omitted or any address. 3) fba should point the unlocked area address among nand flash array address map.
muxonenand1g(kfm1g16q2m-deb5) flash memory 91 muxonenand2g(kfn2g16q2m-deb5) the device has independent dual data buffers on-chip (except duri ng the boot load period) that enables higher performance read and program operation. 3.12.1 read-whi le-load operation this operation accelerates the read performance of the device by enabling data to be read out by the host from one dataram buff er while the other dataram buffer is being loaded wi th data from the nand flash array memory. page a page b 1) data load 2) data load data buffer1 data buffer0 2) data read 3) data read 3) data load the dual data buffer architecture provides the capability of executing a data-read operation from one of dataram buffers during a simultaneous data-load operation from flash to the other buffe r. simultaneous load and read operation to same data buffer is prohibited. see sections 3.6 and 3.7 for mo re information on load and read operations. if host sets fba, fsa, or fpa while loading into designated page, it will fail the internal load operation. address registers should not be updated until internal operation is completed. 3.12.2 write-while-program operation this operation accelerates the programming performance of the dev ice by enabling data to be wri tten by the host into one datara m buffer while the nadn flash array memory is being programmed with data from the other dataram buffer. page a page b 2) program 3) program data buffer1 data buffer0 1) data write 2) data write 3) data write the dual data buffer architecture provides the capability of executing a data-write operation to one of dataram buffers during simul- taneous data-program operation to flash from the other buffer. simultaneous program and write operation to same data buffer is prohibited. see sections 3.8 for more information on program operation. if host sets fba, fsa, or fpa while programming into designated page, it will fail the internal program operation. address reg isters should not be updated until internal operation is completed. 3.12 dual operations
muxonenand1g(kfm1g16q2m-deb5) flash memory 92 muxonenand2g(kfn2g16q2m-deb5) read while load diagram page b adq we oe int 0~15 2) 2) page a int_reg : interrupt register address add_reg : address register address flash_add : flash address to be loaded dbn_add : dataram address to be loaded cmd_reg : command register address ld_cmd : load command data load_dbn : load data from nand flash array to dataramn cs_reg : controller status register address data read_dbn : read data from dbn 1) avd add_ reg flash _add add_ reg db1 _add cmd_ reg cs_ reg data load _db0 data load _db1 data read _db0 * ld_ cmd read status add_ reg flash _add add_ reg db0 _add cmd_ reg ld_ cmd int_ reg 0000h int_ reg 0000h
muxonenand1g(kfm1g16q2m-deb5) flash memory 93 muxonenand2g(kfn2g16q2m-deb5) write while program diagram page b adq we oe int 0~15 3) 2) page a add_reg : address register address dbn_add : dataram address to be programmed data write_dbn : write data to dataramn flash_add : flash address to be programmed int_reg : interrupt register address cmd_reg : command register address pd_cmd : program command data pgm_pagea : program data from dataram to pagea cs_reg : controller status register address 1) avd data write _db0 * data pgm _pagea add_ reg flash _add add_ reg db0 _add int_ reg 0000h cmd_ reg pd_ cmd data write _db1 * add_ reg flash _add cs_ reg read status add_ reg db1 _add int_ reg 0000h cmd_ reg pd_ cmd data pgm _pageb 2) data write _db0 *
muxonenand1g(kfm1g16q2m-deb5) flash memory 94 muxonenand2g(kfn2g16q2m-deb5) the muxonenand device has dq6 toggle bit. to ggle bit is another option to detect whet her an internal load operation is in progr ess or completed. once the bufferram(bootram, dataram0, dataram1 ) is at a busy state during internal load operation, dq6 will tog- gle. toggling dq6 will stop after the device completes its intern al load operation. the muxonenand device?s dq6 toggle will be valid only when host reads bufferram designated by bsa which will be loaded by internal load operation. dq6 toggle can be used 350ns after load command(0000h, 0013h, and 00e0h of command based operat ion) issue, until data s ensing from the nand flash array memory into page buffer and transferring from the page buffer to the dataram are finished. by reading the same address more than twice utilizing either asynchronous or synchronous r ead (figure 6.14, 6.15 and 6.16), the host will read toggled valu e of dq6 and the rest of dq?s are not guaranteed to be fixed value. dq 6 toggle is only for reading status of bufferram which is bein g loaded by internal operation, that is, bufferram designated by bsa. host may read previous data from bufferram not pointed by bsa during internal load operation. dq6 toggle bit can be useful at cold reset to determine the ready /busy state of muxonenand. since int pin is initially at high- z state, when host needs to check the completion of bootcode copy operation, the host cannot judge the ready/busy status of mux- onenand by int pin. therefore, by chec king dq6 toggle of bootram, the host s hould detect the completion of bootcode copy. status dq15~dq7 dq6 dq5~dq0 in progress data loading x (don?t care) toggle x (don?t care) 3.13 dq6 toggle bit
muxonenand1g(kfm1g16q2m-deb5) flash memory 95 muxonenand2g(kfn2g16q2m-deb5) the muxonenand device has on-chip ecc with t he capability of detecting 2 bit errors and correcting 1-bit errors in the nand fla sh array memory main and spare areas. as the device transfers data from a bufferram to the nand flash array memory page buffer for pr ogram operation, the device ini- tiates a background operation which generates an error correction c ode (ecc) of 24bits for each sector main area data and 10bit s for 2nd and 3rd word data of each sector spare area. during a load operation from the nand flash array memory page, the on-chip ecc engine generates a new ecc. the 'load ecc result' is compared to the originally 'program ecc' thus detec ting the number and position of errors. single-bit error is corre cted. ecc is updated by the device automatically. after a load operatio n, the host can determine whether there was error by reading t he 'ecc status register' (refer to section 2.8.26). error types are divided into 'no erro r', '1bit correctable error', and '2bit error uncorrectable error'. muxonenand supports 2bit edc even though 2bit e rror seldom or never occurs. hence, it is not recommeded for host to read 'ecc status register' for checking ecc error because the built-in error correction logic of muxonenand automatically corrects ecc error. when the device reads the nand flash array memory main and sp are area data with an ecc operation, the device doesn't place the newly generated ecc for main and spare area into the buffer. instead it places the ecc which was generated and written duri ng the program operation into the buffer. an ecc operation is also done during the boot loading operation. 3.14.1 ecc bypass operation in an ecc bypass operation, the device does not generate ecc as a background operation. the result does not indicate error posi - tion (refer to the ecc result table). in a program operation the ecc code to nand flash array memory spare area is not updated. during a load operation, the on-chip ecc engine does not generate a ne w ecc internally. also the ecc status & result to regis- ters are invalid. the error is not corrected and detected by itself, so that ecc bypass operation is not recommended for host. ecc bypass operation is set by the 9bit of system configuration 1 register (see section 2.8.19) ecc code and ecc result by ecc operation note: 1. pre-written ecc code : ecc code which is previously written to nand flash spare area in program operation. operation program operation load operation ecc code update to nand flash array spare area ecc code at bufferram spare area ecc status & result update to registers 1bit error ecc operation update pre-written ecc code (1) loaded update correct ecc bypass not update pre-written code loaded invalid not correct 3.14 ecc operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 96 muxonenand2g(kfn2g16q2m-deb5) invalid blocks are defined as blocks in the device's nand flash array memory that cont ain one or more invalid bits whose reliab ility is not guaranteed by samsung. the information regarding the invalid block(s) is called the invalid block information. devices with invalid block(s) have the same quality level as devices with all valid blocks and have the same ac and dc characteristics. an invalid block(s) does not affect the per formance of valid block(s) because it is isolated from the bit line and the common s ource line by a select transistor. the system design must be able to mask ou t the invalid block(s) via address mapping. the 1st block, which is placed on 00h bloc k address, is always fully guaranteed to be a valid block. due to invalid marking, during load operation for indentifying invalid block, a load error may occur. 3.15.1 invalid block id entification table operation a system must be able to recognize invali d block(s) based on the original invalid bl ock information and create an invalid block table. invalid blocks are identified by erasing al l address locations in the nand flash array memory except locations where the invali d block(s) information is written prior to shipping. an invalid block(s) status is defined by the 1st word in the sp are area. samsung makes sure that either the 1st or 2nd page of every invalid block has non-ffffh data at the 1st word of sector0. since the invalid block informati on is also erasable in most cases, it is impos sible to recover the information once it has bee n erased. any intentional erase of the original in valid block information is prohibited. the following suggested flow chart can be used to create an invalid block table. 3.15 invalid block operation
muxonenand1g(kfm1g16q2m-deb5) flash memory 97 muxonenand2g(kfn2g16q2m-deb5) invalid block table creation flow chart within its life time, additional invalid bl ocks may develop with nand flash array me mory. refer to the device's qualification r eport for the actual data. the following possible failure m odes should be considered to im plement a highly reliable system. in the case of a status read failure after erase or program, a block replacement should be done. because program status failure during a page program does not affect the data of the other pages in the same block, a block repl acement can be executed with a page-sized buffer by finding an erased empty block and reprogramming the current target data and copying the rest of the replac ed block. block failure modes and countermeasures failure mode detection and countermeasure sequence erase failure status read after erase --> block replacement program failure status read after program --> block replacement single bit failure in load operation error correction by ecc mode of the device 3.15.2 invalid block replacement operation * check "ffffh" at the 1st word of sector 0 start set block address = 0 check increment block address last block ? end no yes yes create (or update) no invalid block(s) table in 1st and 2nd page of every block "ffffh" ?
muxonenand1g(kfm1g16q2m-deb5) flash memory 98 muxonenand2g(kfn2g16q2m-deb5) referring to the diagram for further illustration, when an error happens in the nth page of block 'a' during program operation, copy the data in the 1st ~ (n-1)th page to the same location of block 'b' via data buffer0. then copy the nth page data of block 'a' in the data buffer1 to the nth page of block 'b' or any free block. do not further era se or program block 'a' but instead complete the operation by creat ing an 'invalid block table' or other appropriate scheme. block replacement operation sequence data buffer1 of the device 1st block a block b (n-1)th nth (page) { 1st (n-1)th nth (page) { an error occurs. 1 2 data buffer0 of the device 1 (assuming the nth page data is maintained)
muxonenand1g(kfm1g16q2m-deb5) flash memory 99 muxonenand2g(kfn2g16q2m-deb5) 4.1 absolute maximum ratings notes : 1. minimum dc voltage is -0.5v on input/ output pins. during tr ansitions, this level should not fall to por level(typ. 1.5v) . maximum dc voltage is vcc+0.6v on input / output pins which, during transitions, may overshoot to vcc+2.0v for periods <20n s. 2. permanent device damage may occur if absolute maximum ratings are exceeded. functional operation should be restricted to the conditions detailed in the operational sections of this data sheet. exposure to absolute maximum rating conditions for extended perio ds may affect reliability. parameter symbol rating unit voltage on any pin relative to v ss vcc vcc -0.5 to + 2.45 v all pins v in -0.5 to + 2.45 temperature under bias extended t bias -30 to +125 c industrial -40 to +125 storage temperature t stg -65 to +150 c short circuit output current i os 5ma recommended operating temperature t a (extended temp.) -30 to +85 c t a (industrial temp.) -40 to +85 4.2 operating conditions voltage reference to gnd notes : 1. the system power should reach 1.7v after por triggering level(typ. 1.5v) within 400us. 2. vcc-core (or vcc) should reach the operating voltage leve l prior to or at the same time as vcc-io (or vccq). parameter symbol kfm1g16q2m unit min typ. max supply voltage v cc- core / vcc 1.7 1.8 1.95 v v cc- io / vccq v ss 000v 4.0 dc characteristics
muxonenand1g(kfm1g16q2m-deb5) flash memory 100 muxonenand2g(kfn2g16q2m-deb5) note 1. ce should be vih for rdy. iobe should be ?0? for int. note 2. icc active for host access note 3. icc active for internal operation. (without host access) note 4. vccq is equivalent to vcc-io parameter symbol test conditions kfm1g16q2m unit min typ max input leakage current i li v in =v ss to v cc , v cc =v ccmax single - 1.0 - + 1.0 a ddp - 2.0 - + 2.0 output leakage current i lo v out =v ss to v cc , v cc =v ccmax , ce or oe =v ih (note 1) single - 1.0 - + 1.0 a ddp - 2.0 + 2.0 active asynchronous read current (note 2) i cc1 ce =v il , oe =v ih -815ma active burst read current (note 2) i cc2 ce =v il , oe =v ih 54mhz - 12 20 ma 1mhz - 3 4 ma 54mhz (ddp) -1722ma 1mhz (ddp) -34ma active write current (note 2) i cc3 ce =v il , oe =v ih single -815ma ddp -1320ma active load current (note 3) i cc4 ce =v il , oe =v ih , we =v ih -3040ma active program current (note 3) i cc5 ce =v il , oe =v ih , we =v ih -2530ma active erase current (note 3) i cc6 ce =v il , oe =v ih , we =v ih -2025ma multi block erase current (note 3) i cc7 ce =v il , oe =v ih , we =v ih , 64blocks - 20 25 ma standby current i sb ce = rp =v cc 0.2v single -1050 a ddp - 20 100 input low voltage v il --0.5-0.4v input high voltage (note 4) v ih -v ccq -0.4 - v ccq +0.4 v output low voltage v ol i ol = 100 a ,v cc =v ccmin , v ccq =v ccqmin --0.2v output high voltage v oh i oh = -100 a , v cc =v ccmin , v ccq =v ccqmin v ccq -0.1 - - v 4.3 dc characteristics
muxonenand1g(kfm1g16q2m-deb5) flash memory 101 muxonenand2g(kfn2g16q2m-deb5) 5.1 ac test conditions parameter value input pulse levels 0v to v cc input rise and fall times clk 3ns other inputs 5ns input and output timing levels v cc /2 output load c l = 30pf 0v v cc v cc /2 v cc /2 input pulse and test point input & output test point output load device under te s t * c l = 30pf including scope and jig capacitance 5.2 device capacitance notes: 1. the device may include invalid blocks when first shipped. additional inva lid blocks may develop while being used. the number of valid blo cks is pre- sented with both cases of invalid blocks considered. invalid bl ocks are defined as blocks that contain one or more bad bits . do not erase or program factory-marked bad blocks. 2. the 1st block, which is placed on 00h bloc k address, is fully guaranteed to be a valid block. parameter symbol min typ. max unit valid block number single n vb 1004 - 1024 blocks ddp 2008 - 2048 blocks capacitance (t a = 25 c, v cc = 1.8v, f = 1.0mhz) note : capacitance is periodically sampled and not 100% tested. item symbol test condition single ddp unit min max min max input capacitance c in1 v in =0v - 10 - 20 pf control pin capacitance c in2 v in =0v - 10 - 20 pf output capacitance c out v out =0v - 10 - 20 pf int capacitance c int v out =0v - 15 - 30 pf 5.3 valid block characteristics 5.0 ac characteristics
muxonenand1g(kfm1g16q2m-deb5) flash memory 102 muxonenand2g(kfn2g16q2m-deb5) note 1. if oe is disabled at the same time or before ce is disabled, the output will go to high-z by t oez . if ce is disabled at the same time or before oe is disabled, the output will go to high-z by t cez . if ce and oe are disabled at the same time, th e output will go to high-z by t oez . 2. it is the following clock of address fetch clock. parameter symbol kfm1g16q2m unit min max clock clk 1 54 mhz clock cycle t clk 18.5 - ns initial access time t iaa -76ns burst access time valid clock to output delay t ba - 14.5 ns avd setup time to clk t avds 7-ns avd hold time from clk t avdh 7-ns avd high to oe low t avdo 0-ns address setup time to clk t acs 7-ns address hold time from clk t ach 9-ns data hold time from next clock cycle t bdh 4-ns output enable to data t oe -20ns ce disable to output high z t cez 1) -20ns oe disable to output high z t oez 1) -17ns ce setup time to clk t ces 7-ns clk high or low time t clkh/l t clk /3 - ns clk 2) to rdy valid t rdyo - 14.5 ns clk to rdy setup time t rdya - 14.5 ns rdy setup time to clk t rdys 4-ns ce low to rdy valid t cer -15ns 5.4 ac characteristic s for synchronous burst read see timing diagrams 6.1, 6.2 and 6.16
muxonenand1g(kfm1g16q2m-deb5) flash memory 103 muxonenand2g(kfn2g16q2m-deb5) note: 1. if oe is disabled at the same time or before ce is disabled, the output will go to high-z by t oez . if ce is disabled at the same time or before oe is disabled, the output will go to high-z by t cez . if ce and oe are disabled at the same time, the output will go to high-z by t oez . these parameters are not 100% tested. 2. this parameter is valid at toggle bit timing in asynchronous read only. (timing diagram 6.14 and 6.15) parameter symbol kfm1g16q2m unit min max access time from ce low t ce -76ns asynchronous access time from avd low t aa -76ns asynchronous access time from address valid t acc -76ns read cycle time t rc 76 - ns avd low time t avdp 12 - ns address setup to rising edge of avd t aavds 5-ns address hold from rising edge of avd t aavdh 7-ns output enable to output valid t oe -20ns ce setup to avd falling edge t ca 0-ns ce disable to output & rdy high z 1) t cez -20ns oe disable to output high z 1) t oez -17ns avd high to oe low t avdo 0-ns ce low to rdy valid t cer -15ns we disable to avd enable t wea 15 - ns address to oe low t aso 2) 10 - ns 5.6 ac characteristics for warm reset (rp ), hot reset and nand flash core reset see timing diagrams 6.10, 6.11 and 6.12 5.5 ac characteris tics for asynchronous read see timing diagrams 6.3, 6.4, 6.14 and 6.15 note: 1. these parameters are tested based on int bit of interrupt r egister. because the time on int pin is related to the pull-up an d pull-down resistor value. 2. the device may reset if trp < trp mi n(200ns), but this is not guaranteed. parameter symbol min max unit rp & reset command latch to bootram access tready1 (bufferram) -5 s rp & reset command latch(during load routines) to int high (note1) tready2 (nand flash array) -10 s rp & reset command latch(during program routines) to int high (note1) tready2 (nand flash array) -20 s rp & reset command latch(during erase routines) to int high (note1) tready2 (nand flash array) - 500 s rp & reset command latch(not during internal routines) to int high (note1) tready2 (nand flash array) -10 s rp pulse width (note2) trp 200 - ns
muxonenand1g(kfm1g16q2m-deb5) flash memory 104 muxonenand2g(kfn2g16q2m-deb5) parameter symbol min max unit we cycle time t wc 70 - ns avd low pulse width t avdp 12 - ns address setup time t aavds 5 - ns address hold time t aavdh 7 - ns data setup time t ds 30 - ns data hold time t dh 0 - ns ce setup time t cs 0 - ns ce hold time t ch 0 - ns we pulse width t wpl 40 - ns we pulse width high t wph 30 - ns we disable to avd enable t wea 15 - ns ce low to rdy valid t cer - 15 ns these parameters are tested based on int bit of interrupt register . because the time on int pin is related to the pull-up and p ull-down resistor value. parameter symbol min typ max unit sector load time(note 1) t rd1 -2335 s page load time(note 1) t rd2 -3045 s sector program time(note 1) t pgm1 - 205 720 s page program time(note 1) t pgm2 - 220 750 s otp access time(note 1) t otp - 500 700 ns lock/unlock/lock-tight time(note 1) t lock - 500 700 ns erase suspend time(note 1) t esp - 400 500 s erase resume time(note 1) 1 block t ers1 -23ms 2~64 blocks t ers2 46ms number of partial program cycles in the sector (including main and spare area) nop - - 2 cycles block erase time (note 1) 1 block t bers1 -23ms 2~64 blocks t bers2 -46ms multi block erase verify read time(note 1) t rd3 - 70 100 s 5.8 ac characteristics fo r load/program/erase performance see timing diagrams 6.6, 6.7, and 6.8 5.7 ac characteristics for asynchronous write/load/ program/erase operation see timing diagrams 6.5, 6.6, 6.7, and 6.8
muxonenand1g(kfm1g16q2m-deb5) flash memory 105 muxonenand2g(kfn2g16q2m-deb5) 6.1 8-word linear burst mode with wrap around see ac characteristics table 5.4 6.2 continuous linear burst mode with wrap around see ac characteristics table 5.4 6 cycles for second access shown. t ces t avds t avdh t acs t ach t iaa t rdyo t ba t bdh t clk hi-z ce clk avd oe rdy t rdys t rdya t oe brl = 4 a/dq0: a/dq15 t cer t avdo t cez t oez d6 d7 d0 d1 d2 d3 d7 d0 t clkh t clkl hi-z t cer 6 cycles for sec ond access shown. t ces t avds t avdh t acs t ach t iaa t ba t bdh t clk hi-z ce clk avd oe rdy t rdys t rdya t oe brl = 4 a/dq0: a/dq15 t cez t oez da+1 da+2 da+3 da+4 da+5 da+n da+n+1 t avdo hi-z t rdyo t cer d6 6.0 timing diagrams
muxonenand1g(kfm1g16q2m-deb5) flash memory 106 muxonenand2g(kfn2g16q2m-deb5) 6.4 asynchronous read (va transition after avd low) see ac characteristics table 5.5 6.3 asynchronous read (va transition before avd low) see ac characteristics table 5.5 t oe va valid rd t ce t oeh t oez t aavdh t avdp t aavds ce oe we a/dq0: avd a/dq15 hi-z hi-z rdy t aa t rc t wea t ca t cez t cer t avdo hi-z note: va=valid read address, rd=read data. see timing diagram 6.14, 6.15 for taso t oe va valid rd t oeh t oez t acc t aavdh t avdp t aavds ce oe we a/dq0: avd a/dq15 t wea t cez t ca t cer t avdo hi-z hi-z rdy t rc t ce hi-z note: va=valid read address, rd=read data. see timing diagram 6.14, 6.15 for taso
muxonenand1g(kfm1g16q2m-deb5) flash memory 107 muxonenand2g(kfn2g16q2m-deb5) note: va=valid read address, wd=write data. ce we oe rp t cs t ds rdy t wpl t wph t wc t cer hi-z hi-z clk v il t ch adq15-adq0 valid wd va valid wd avd t aavds t avdp t aavdh t wea t dh t cez va 6.5 asynchronous write see ac characteristics table 5.7
muxonenand1g(kfm1g16q2m-deb5) flash memory 108 muxonenand2g(kfn2g16q2m-deb5) notes: 1. aa = address of address register ca = address of command register lcd = load command lma = address of memory to be loaded ba = address of bufferram to load the data sa = address of status register 2. ?in progress? and ?complete? refer to status register 3. status reads in this figure is asynchronous read, but status read in synchronous mode is also supported. 6.6 load operation timing see ac characteristics tables 5.7 and 5.8 t cer load command sequence (last two cycles) we ce clk t avdp t ds t dh t ch t wpl t wph t wc sa ba completed da+n lcd ca lma aa adq0~15 oe read data v il t wea t aavds t aavdh t rd int t cs avd rdy hi-z t cer t cez bit t cez
muxonenand1g(kfm1g16q2m-deb5) flash memory 109 muxonenand2g(kfn2g16q2m-deb5) notes: 1. aa = address of address register ca = address of command register pcd = program command pma = address of memory to be programmed ba = address of bufferram to write the data bd = program data sa = address of status register 2. ?in progress? and ?complete? refer to status register 3. status reads in this figure is asynchronous read , but status read in synchronous mode is also supported. 6.7 program operation timing see ac characteristics tables 5.7 and 5.8 program command sequence (last two cycles) we ce clk t ds t dh t ch t wpl t cs t wph t wc sa sa in progress completed aa oe read status data v il avd ba ca pcd pma bd t aavdh t aavds t pgm int t avdp t wea t cer a/dq0: a/dq15 rdy hi-z t cer t cez bit t cez
muxonenand1g(kfm1g16q2m-deb5) flash memory 110 muxonenand2g(kfn2g16q2m-deb5) notes: 1. aa = address of address register ca = address of command register ecd = erase command ema = address of memory to be erased sa = address of status register 2. ?in progress? and ?complete? refer to status register 3. status reads in this figure is asynchronous read , but status read in synchronous mode is also supported. 6.8 block erase operation timing see ac characteristics tables 5.7 and 5.8 program command sequence (last two cycles) we ce clk t ds t dh t ch t wpl t cs t wph t wc sa sa in progress completed aa oe read status data v il avd ba ca pcd pma bd t aavdh t aavds t pgm int t avdp t wea t cer a/dq0: a/dq15 rdy hi-z t cer t cez bit t cez
muxonenand1g(kfm1g16q2m-deb5) flash memory 111 muxonenand2g(kfn2g16q2m-deb5) note: 1) bootcode copy operation starts 400us later than por activation. the system power should reach vcc after por triggering level(typ. 1.5v) within 400us for valid boot code data. 2) 1k bytes bootcode copy takes 70us(estimated) from sector0 and sector1/page0/block0 of nand flash array to bootram. host can read bootcode in bootram(1k bytes) after bootcode copy completion. 3) int register goes ?low? to ?high? on the condition of ?bootcode-copy done? and rp rising edge. if rp goes ?low? to ?high? before ?bootcode-copy done?, int register goes to ?low? to ?high? as soon as ?bootcode-copy done? system power sleep bootcode copy idle bootcode - copy done por triggering level 3) 2) rp int muxonenand operation 0 (default) 1 iobe bit 1 (default) intpol bit high-z 1) int bit 0 (default) 1 6.9 cold reset timing
muxonenand1g(kfm1g16q2m-deb5) flash memory 112 muxonenand2g(kfn2g16q2m-deb5) 6.10 warm reset timing ce , oe rp t rp t ready1 rdy int high-z high-z t ready2 idle 1) operation status reset ongoing 2) bootram access 3) idle 1) int bit polling 4) notes: 1. the status which can accept any register based operation(load, program, erase command, etc). 2. the status where reset is ongoing. 3. the status allows only bootram(bl1) read operation for boot sequence.(refer to 7.2.2 boot sequence) 4. to read bl2 of boot sequence, host should wait int until becomes ready. and then, host can issue load command. (refer to 7.2.2 boot sequence, 7.1 methods of determing interrupt status) bit
muxonenand1g(kfm1g16q2m-deb5) flash memory 113 muxonenand2g(kfn2g16q2m-deb5) 6.11 hot reset timing note: 1. internal reset operation means that the device initializes in ternal registers and makes output signals go to default status and bufferram data are kept unchanged after warm/hot reset operations. 2. reset command : command based reset or register based reset 3. bp(boot partition): bootram area [0000h~01ffh, 8000h~800fh] 4. 00f0h for bp, and 00f3h for f220h avd bp(note 3) adqi 00f0h ce or f220h or 00f3h int we oe t ready 2 bit rdy operation or idle onenand reset idle onenand operation high-z
muxonenand1g(kfm1g16q2m-deb5) flash memory 114 muxonenand2g(kfn2g16q2m-deb5) 6.13 data protection timing during power do wn v cc rp nand write protected idle muxonenand reset int muxonenand operation typ. 1.3v 0v the device is designed to offer protection fr om any involuntary program/erase during pow er-transitions. an internal voltage det ector disables all functions whenever vcc is below about 1.3v. rp pin provides hardware protection and is recommended to be kept at v il before power-down. 6.12 nand flash core reset timing avd adqi 00f0h ce f220h rdy operation or idle nand flash core reset idle muxonenand operation high-z int we oe t ready 2 bit bit
muxonenand1g(kfm1g16q2m-deb5) flash memory 115 muxonenand2g(kfn2g16q2m-deb5) 6.15 toggle bit timing in asynchronous read (va transition after avd low) see ac characteristics table 5.5 t oe status rd 1) t ce t oez t avdp ce oe we a/dq0: avd a/dq15 hi-z rdy 2) t aa t rc t ca t cez t cer t avdo hi-z t oe status rd 1) t oez t acc t aavdh t avdp t aavds ce oe we a/dq0: avd a/dq15 t cez t ca t cer t avdo hi-z hi-z rdy 2) t rc t ce hi-z note: va status rd hi-z t aso va status rd t ca t aso t aavdh t aavds va 1) va 1) 1. va=valid read address, rd=read data. 2. before iobe is set to 1, rdy and int pin are high-z state. note: 1. va=valid read address, rd=read data. 2. before iobe is set to 1, rdy and int pin are high-z state. 6.14 toggle bit timing in asynchronous read (va transition before avd low) see ac characteristics table 5.5 3. refer to chapter 5.5 for taso description and value. 3. refer to chapter 5.5 for taso description and value.
muxonenand1g(kfm1g16q2m-deb5) flash memory 116 muxonenand2g(kfn2g16q2m-deb5) note : 1. va = valid address. when the internal routine operation is complete, the toggle bits will stop toggling. 2. before iobe is set to 1, rdy and int pin are high-z state. t ces t aavds t aavdh t iaa hi-z ce clk avd oe a/dq0: a/dq15 rdy 2) va 1) t rdys status data va status data t ach t acs t avdo 6.16 toggle bit timing in synchronous read mode
muxonenand1g(kfm1g16q2m-deb5) flash memory 117 muxonenand2g(kfn2g16q2m-deb5) from time-to-time supplemental technical information and application notes pertaining to the design and operation of the device in a system are included in this section. contact your samsung repr esentative to determine if add itional notes are available. 7.1 methods of determining interrupt status there are two methods of determining interrupt status on the muxo nenand. using the int pin or monitoring the interrupt status register bit. the muxonenand int pin is an output pin function used to notif y the host when a command has been completed. this provides a hardware method of signaling the completion of a program, erase, or load operation. in its normal state, the int pin is high if the int polarity bi t is default. before a command is written to the command registe r, the int bit must be written to '0' so the int pin transitions to a lo w state indicating start of the operation. upon completion of the command operation by the muxonenand?s internal controller, int returns to a high state. int is an open drain output allowing multiple int outputs to be or -tied together. int does not float to a hi-z condition when t he chip is deselected or when outputs are disabled. refer to section 2.8 for additional information about int. int can be implemented by tying int to a host gpio or by continuous polling of the interrupt status register. 7.1.1 the int pin to a host general purpose i/o int can be tied to a host gpio to detect the rising edge of int, signaling the end of a command operation. this can be configured to operate either synchronously or asynchronously as s hown in the diagrams below. int command 7.0 technical and application notes
muxonenand1g(kfm1g16q2m-deb5) flash memory 118 muxonenand2g(kfn2g16q2m-deb5) synchronous mode using the int pin when operating synchronously, int is tied directly to a host gpio. an alternate method of determining the end of an operation is to continuously monitor the interrupt status register bit instead of using the int pin. host muxonenand asynchronous mode using the int pin when configured to operate in an asynchronous mode, /ce and /avd of the muxonenand are tied to /ce of the host. clk is tied to the host vss (ground). /rdy is tied to a no-connect. /oe of th e muxonenand and host are tied together and int is tied to a gpio . rdy oe clk ce rdy oe clk ce avd avd gpio int host muxonenand n.c oe vss ce rdy oe clk ce avd gpio int this can be configured in either a sync hronous mode or an asynchronous mode. int command 7.1.2 polling the interrupt register st atus bit
muxonenand1g(kfm1g16q2m-deb5) flash memory 119 muxonenand2g(kfn2g16q2m-deb5) synchronous mode using interrupt status register bit polling when operating synchronously, /ce, /avd, clk, /rdy, /oe, and dq pins on the host and muxonenand are tied together. host muxonenand rdy oe clk ce rdy oe clk ce avd avd dq dq asynchronous mode using interrupt status register bit polling when configured to operate in an asynchronous mode, /ce and /avd of the muxonenand are tied to /ce of the host. clk is tied to the host vss (ground). /rdy is tied to a no-connect. /oe and dq of the muxonenand and host are tied together. host muxonenand n.c oe ce rdy oe clk ce avd dq dq vss
muxonenand1g(kfm1g16q2m-deb5) flash memory 120 muxonenand2g(kfn2g16q2m-deb5) because the pull-up resistor value is related to tr(int) an appr opriate value can obtained with the following reference charts. 7.1.3 determining rp value tr,tf ibusy [ma] rp(ohm) ibusy tr[us] kfg1g16q2m @ vcc = 1.8v, ta = 25 c , c l = 30pf 1k 10k 20k 30k 0.089 tf[ns] 0.7727 1.345 1.788 3.77 3.77 3.77 3.77 1.75 0.18 0.09 40k 50k 2.142 2.431 3.77 3.77 0.045 0.06 0.036 open(100k) 5.420 0.000 busy state ready vcc voh tf tr vol vss ~50k ohm int internal vcc rp int pol = ?high? tr,tf ibusy [ma] rp(ohm) ibusy tr[us] kfn2g16q2m @ vcc = 1.8v, ta = 25 c , c l = 30pf 1k 10k 20k 30k 0.161 tf[ns] 1.238 1.97 2.458 8.73 8.73 8.73 8.73 1.75 0.18 0.09 40k 50k 2.807 3.07 8.73 8.73 0.045 0.06 0.036 open(100k) 3.785 0.000
muxonenand1g(kfm1g16q2m-deb5) flash memory 121 muxonenand2g(kfn2g16q2m-deb5) ~50k ohm int internal vcc rp int pol = ?low? tr,tf ibusy [ma] rp(ohm) ibusy tf[us] @ vcc = 1.8v, ta = 25 c , c l = 30pf 1k 10k 20k 30k 0.067 tr[ns] 0.586 1.02 1.356 6.49 6.49 6.49 6.49 1.75 0.18 0.09 40k 50k 1.623 1.84 6.49 6.49 0.045 0.06 0.036 open(100k) 4.05 0.000 busy state ready voh tf tr vol vss vcc tr,tf ibusy [ma] rp(ohm) ibusy tf[us] kfn2g16q2m @ vcc = 1.8v, ta = 25 c , c l = 30pf 1k 10k 20k 30k 0.122 tr[ns] 0.944 1.507 1.883 10.73 10.73 10.73 10.73 1.75 0.18 0.09 40k 50k 2.153 2.356 10.73 10.73 0.045 0.06 0.036 open(100k) 2.912 0.000
muxonenand1g(kfm1g16q2m-deb5) flash memory 122 muxonenand2g(kfn2g16q2m-deb5) one of the best features muxonenand has is that it can be a booting device itself since it c ontains an internally built-in boot loader despite the fact that its core architecture is based on nand flash. thus, muxonenand does not make any additional booting devic e necessary for a system, which imposes extra cost or area overhead on the overall system. as the system power is turned on, the boot code originally stored in nand flash arrary is moved to bootram automatically and th en fetched by cpu through the same interface as sram?s or nor flash? s if the size of the boot code is less than 1kb. if its size i s larger than 1kb and less than or equal to 3kb, only 1kb of it can be mo ved to bootram automatically and fetched by cpu, and the rest o f it can be loaded into one of the datarams w hose size is 2kb by load command and cpu can take it from the dataram after finish- ing the code-fetching job for bootram. if it s size is larger than 3kb, the 1kb portion of it can be moved to bootram automatica lly and fetched by cpu, and its remaining part can be moved to dram through two datarams using dual buffering and taken by cpu to reduce cpu fetch time. a typical boot scheme usually used to boot the system with muxonenand is explai ned at patition of nand flash array and mux- onenand boot sequence. in this boot scheme, boot code is comp rised of bl1, where bl stands for boot loader, bl2, and bl3. moreover, the size of the boot code is larger than 3kb (the 3rd case above). bl1 is called primary boot loader in other words. here is the table of detailed explanations about the function of each boot loader in this specific boot scheme. boot loaders in muxonenand nand flash array of muxonenand is divided into the partitions as described at partiti on of nand flash array to show where each component of code is located and how much portion of the over all nand flash array each one occupies. in addition, the boot sequence is listed below and depicted at boot sequence. boot loader description bl1 moves bl2 from nand flash array to dra m through two datarams using dual buffering bl2 moves os image (or bl3 opt ionally) from nand flash array to dram through two datarams using dual buffering bl3 (optional) moves or writes the image through usb interface 7.2.1 boot loaders in muxonenand boot sequence : 1. power is on bl1 is loaded into bootram 2. bl1 is executed in bootram bl2 is loaded into dram through two datarams using dual buffering by bl1 3. bl2 is executed in dram os image is loaded into dram through two datarams using dual buffering by bl2 4. os is running 7.2.2 boot sequence 7.2 boot sequence
muxonenand1g(kfm1g16q2m-deb5) flash memory 123 muxonenand2g(kfn2g16q2m-deb5) reservoir file system os image nbl3 nbl2 nbl1 partition 6 block 162 block 2 block 1 block 0 partition 5 sector 0 sector 1 sector 2 sector 3 page 63 page 62 page 2 page 1 page 0 bl2 partition 4 partition 3 partition of nand flash array reservoir file system os image bl3 bl2 bl1 partition 6 block 162 block 2 block 1 block 0 partition 5 sector 0 sector 1 sector 2 sector 3 page 63 page 62 page 2 page 1 page 0 partition 4 partition 3 : : reservoir file system os image bl2 bl1 os image bl 2 nand flash array muxonenand dram muxonenand boot sequence bl1 internal bufferram data ram 1 data ram 0 boot ram(bl 1) note : step 2 and step 3 can be copied into dram through two datarams using dual buffering block 512 step 1 step 2 step 3
muxonenand1g(kfm1g16q2m-deb5) flash memory 124 muxonenand2g(kfn2g16q2m-deb5) 0.10 max 0.45 0.05 0.32 0.05 0.9 0.10 bottom view top view a c e b d f 0.80x9=7.20 a 0.80x11=8.80 63- ? 0.45 0.05 g 4.40 0 . 8 0 b 0.20 m a b ? (datum a) (datum b) 2 543 1 6 3.60 #a1 index h 10.00 0.10 13.00 0.10 #a1 13.00 0.10 0 . 8 0 10.00 0.10 13.00 0.10 1g product (kfg1g16q2m) 2g product (kfn2g16q2m) 0.10 max 0.45 0.05 0.32 0.05 1.1 0.10 bottom view top view a c e b d f 0.80x9=7.20 a 0.80x11=8.80 63- ? 0.45 0.05 g 4.40 0 . 8 0 b 0.20 m a b ? (datum a) (datum b) 2 543 1 6 3.60 #a1 index h 11.00 0.10 13.00 0.10 #a1 13.00 0.10 0 . 8 0 11.00 0.10 13.00 0.10 8.0 package dimensions

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