F59L8G81XSB-25TG2X [ESMT]
8 Gbit (1Gb x 8) 3.3V NAND Flash Memory;型号: | F59L8G81XSB-25TG2X |
厂家: | ELITE SEMICONDUCTOR MEMORY TECHNOLOGY INC. |
描述: | 8 Gbit (1Gb x 8) 3.3V NAND Flash Memory |
文件: | 总82页 (文件大小:1960K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
ESMT
(Preliminary)
F59L8G81XSB (2X)
Flash
8 Gbit (1Gb x 8)
3.3V NAND Flash Memory
FEATURES
ò
ò
Density
ò
Operation status byte provides software method for
detecting
–
8 Gb (4 Gb x 2)
Operating voltage range
Operation completion
Pass/Fail condition
Write-protect status
VCC: 2.7–3.6V
ò
ò
ò
Open NAND Flash Interface (ONFI) 1.0-compliant1
Single-level cell (SLC) technology
Organization (For each 4Gb device)
ò
Ready/Busy# (R/B#) signal provides a hardware method
of detecting operation completion
Page size: 4352 bytes (4096 + 256 bytes)
Block size: 64 pages
Plane size: 2048 blocks
ò
ò
WP# signal: Write protect entire device
ECC: 8-bit internal ECC is disabled at default2. It can be
toggled using the SET FEATURE command
Blocks 0 is valid when shipped from factory with ECC. For
minimum required ECC, see Error Management.
RESET (FFh) required as first command after power- on.
Internal data move operations supported within the plane
from which data is read
ò
ò
Asynchronous I/O performance
tRC/tWC: 25ns
Array performance
ò
ò
ò
Read page: 115µs (MAX) with on-die ECC enabled
Read page: 25µs (MAX) with on-die ECC disabled
Program page: 200µs (TYP) with on-die ECC
disabled
ò
Quality and reliability
Endurance: 100,000 PROGRAM/ERASE cycles
Data retention: JESD47G-compliant; see qualification
report
Program page: 240µs (TYP) with on-die ECC enabled
Erase block: 2ms (TYP)
Additional: Uncycled data retention: 10 years 24/7 @
70°C
ò
ò
Command set: ONFI NAND Flash protocol
Advanced command set
Program page cache mode
Read page cache mode
Permanent block locking (blocks 47:0)
One-time programmable (OTP) mode
Block lock
Read unique ID
Internal data move
Programmable drive strength
ORDERING INFORMATION
Product ID
Speed
25 ns
25 ns
Package
Comments
Pb-free
F59L8G81XSB -25TG2X
F59L8G81XSB -25BG2X
48 pin TSOPI
63 ball BGA
Pb-free
GENERAL DESCRIPTION
The device is an 8Gb SLC NAND Flash memory, which is stacked by two 4Gb chips for some special operations and applications.
NAND Flash devices include an asynchronous data interface for high-performance I/O operations. These devices use a highly
multiplexed 8-bit bus (I/Ox) to transfer commands, address, and data. There are five control signals used to implement the
asynchronous data interface: CE#, CLE, ALE, WE#, and RE#. Additional signals control hardware write protection and monitor device
status (R/B#).
This hardware interface creates a low pin-count device with a standard pinout that remains the same from one density to another,
enabling future upgrades to higher densities with no board redesign.
A target is the unit of memory accessed by a chip enable signal. A target contains one or more NAND Flash die. An NAND Flash die is
the minimum unit that can independently execute commands and report status. An NAND Flash die, in the ONFI specification, is
referred to as a logical unit (LUN). There is at least one NAND Flash die per chip enable signal. For further details, see Device and
Array Organization.
Elite Semiconductor Memory Technology Inc.
Publication Date: May 2019
Revision: 0.2 1/82
ESMT
(Preliminary)
F59L8G81XSB (2X)
PIN CONFIGURATION (TOP VIEW)
(TSOPI 48L, 12mm X 20mm Body, 0.5mm Pin Pitch)
Elite Semiconductor Memory Technology Inc.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
BALL CONFIGURATION (x8) (TOP VIEW)
(BGA 63 BALL, 9mm X 11mm Body, 0.8 Ball Pitch)
Elite Semiconductor Memory Technology Inc.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
PIN / BALL DESCRIPTIONS
Pin Name
ALE
Type
Input
Input
Input
Function
Address latch enable: Loads an address from I/O[7:0] into the address register.
Chip enable: Enables or disables one or more die (LUNs) in a target.
CE#
Command latch enable: Loads a command from I/O[7:0] into the command register.
CLE
When LOCK is HIGH during power-up, the BLOCK LOCK function is enabled. To disable the
BLOCK LOCK, connect LOCK to VSS during power-up, or leave it disconnected (internal
pull-down).
LOCK
Input
Read enable: Transfers serial data from the NAND Flash to the host system.
RE#
Input
Input
Write enable: Transfers commands, addresses, and serial data from the host system to the
NAND Flash.
WE#
Write protect: Enables or disables array PROGRAM and ERASE operations.
WP#
Input
I/O
Data inputs/outputs: The bidirectional I/Os transfer address, data, and command information.
I/O[7:0]
Ready/busy: An open-drain, active-low output that requires an external pull-up resistor.
This signal indicates target array activity.
R/B#
Output
VCC: Core power supply
VCC
VSS
Supply
VSS: Core ground connection
Supply
No connect: NCs are not internally connected. They can be driven or left unconnected.
Do not use: DNUs must be left unconnected.
NC
–
–
DNU
Elite Semiconductor Memory Technology Inc.
Publication Date: May 2019
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Architecture
4Gb SLC NAND device use NAND Flash electrical and command interfaces. Data, commands, and addresses are multiplexed onto
the same pins and received by I/O control circuits.
The commands received at the I/O control circuits are latched by a command register and are transferred to control logic circuits for
generating internal signals to control device operations. The addresses are latched by an address register and sent to a row decoder to
select a row address, or to a column decoder to select a column address.
Data is transferred to or from the NAND Flash memory array, byte by byte, through a data register and a cache register.
The NAND Flash memory array is programmed and read using page-based operations and is erased using block-based operations.
During normal page operations, the data and cache registers act as a single register. During cache operations, the data and cache
registers operate independently to increase data throughput. The status register reports the status of die operations.
Block Diagram
Elite Semiconductor Memory Technology Inc.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Device and Array Organization
Array Organization
Array Addressing
Cycle
First
I/07
CA7
I/06
CA6
I/05
CA5
I/04
CA4
CA122
I/03
CA3
I/02
CA2
I/01
CA1
CA9
PA1
BA9
BA17
I/00
CA0
CA8
PA0
BA8
BA16
Second
Third
LOW
BA7
LOW
BA6
LOW
PA5
CA11
PA3
CA10
PA2
PA4
Fourth
Fifth
BA15
LOW
BA14
LOW
BA13
LOW
BA12
LOW
BA11
LOW
BA10
LOW
Notes:
1. Block address concatenated with page address = actual page address. CAx = column address; PAx = page address; BAx = block
address.
2. If CA12 is 1, then CA[11:8] must be 0.
3. Die address boundary: 0 = 0-4Gb; 1 = 4Gb-8Gb.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Interface Bus Operation
The bus on the device is multiplexed. Data I/O, addresses, and commands all share the same pins. Addresses and commands are
always supplied on I/O[7:0].
The command sequence typically consists of a COMMAND LATCH cycle, ADDRESS INPUT cycles, and one or more DATA cycles,
either READ or WRITE.
Asynchronous Interface Mode Selection
Mode1
Standby2
CE#
H
L
CLE
X
ALE
X
WE#
RE#
X
I/Ox
X
WP#
X
0V/VCC
Command input
Address input
Data input
H
L
H
X
H
H
H
X
L
L
L
H
H
X
L
L
L
H
X
Data output
Write protect
L
L
L
H
X
X
X
X
X
X
X
Notes:
1. Mode selection settings for this table: H = Logic level HIGH; L = Logic level LOW; X = VIH or VIL.
2. WP# should be biased to CMOS LOW or HIGH for standby.
Asynchronous Enable/Standby
When the device is not performing an operation, the CE# pin is typically driven HIGH and the device enters standby mode. The
memory will enter standby if CE# goes HIGH while data is being transferred and the device is not busy. This helps to reduce power
consumption.
The CE# “Don’t Care” operation enables the NAND Flash to reside on the same asynchronous memory bus as other Flash or SRAM
devices. Other devices on the memory bus can then be accessed while the NAND Flash is busy with internal operations. This
capability is important for designs that require multiple NAND Flash devices on the
same bus.
A HIGH CLE signal indicates that a command cycle is taking place. A HIGH ALE signal signifies that an ADDRESS INPUT cycle is
occurring.
Asynchronous Commands
An asynchronous command is written from I/O[7:0] to the command register on the rising edge of WE# when CE# is LOW, ALE is LOW,
CLE is HIGH, and RE# is HIGH.
Commands are typically ignored by die (LUNs) that are busy (RDY = 0); however, some commands, including READ STATUS (70h)
and READ STATUS ENHANCED (78h), are accepted by die (LUNs) even when they are busy.
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Publication Date: May 2019
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Command Latch Cycle
Asynchronous Addresses
An asynchronous address is written from I/O[7:0] to the address register on the rising edge of WE# when CE# is LOW, ALE is HIGH,
CLE is LOW, and RE# is HIGH.
Bits that are not part of the address space must be LOW (see Device and Array Organization).
The number of cycles required for each command varies. Refer to the command descriptions to determine addressing requirements.
Addresses are typically ignored by die (LUNs) that are busy (RDY = 0); however, some addresses are accepted by die (LUNs) even
when they are busy; for example, like address cycles that follow the READ STATUS ENHANCED (78h) command.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Address Latch Cycle
Asynchronous Data Input
Data is written from I/O[7:0] to the cache register of the selected die (LUN) on the rising edge of WE# when CE# is LOW, ALE is LOW,
CLE is LOW, and RE# is HIGH.
Data input is ignored by die (LUNs) that are not selected or are busy (RDY = 0). Data is written to the data register on the rising edge of
WE# when CE#, CLE, and ALE are LOW, and the device is not busy.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Data Input Cycles
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Data Output
Data can be output from a die (LUN) if it is in a ready state. Data output is supported following a READ operation from the NAND Flash
array. Data is output from the cache register of the selected die (LUN) to IO bus on the falling edge of RE# when CE# is LOW, ALE is
LOW, CLE is LOW, and WE# is HIGH.
If the host controller is using a tRC of 25ns or greater, the host can latch the data on the rising edge of RE# (see the figure below for
proper timing). If the host controller is using a tRC of less than 25ns, the host can latch the data on the next falling edge of RE#.
Using the READ STATUS ENHANCED (78h) command prevents data contention following an interleaved die (multi-LUN) operation.
After issuing the READ STATUS ENHANCED (78h) command, to enable data output, issue the READ MODE (00h) command.
Data output requests are typically ignored by a die (LUN) that is busy (RDY = 0); however, it is possible to output data from the status
register even when a die (LUN) is busy by first issuing the READ STATUS or READ STATUS ENHANCED (78h) command.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Asynchronous Data Output Cycles
Asynchronous Data Output Cycles (EDO Mode)
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Write Protect#
The write protect# (WP#) signal enables or disables PROGRAM and ERASE operations to a target. When WP# is LOW, PROGRAM
and ERASE operations are disabled. When WP# is HIGH, PROGRAM and ERASE operations are enabled.
It is recommended that the host drive WP# LOW during power-on until VCC is stable to prevent inadvertent PROGRAM and ERASE
operations (see Device Initialization for additional details).
WP# must be transitioned only when the target is not busy and prior to beginning a command sequence. After a command sequence is
complete and the target is ready,
WP# can be transitioned. After WP# is transitioned, the host must wait tWW before issuing a new command.
The WP# signal is always an active input, even when CE# is HIGH. This signal should not be multiplexed with other signals.
Ready/Busy#
The ready/busy# (R/B#) signal provides a hardware method of indicating whether a target is ready or busy. A target is busy when one
or more of its die (LUNs) are busy (RDY = 0). A target is ready when all of its die (LUNs) are ready (RDY = 1). Because each
die (LUN) contains a status register, it is possible to determine the independent status of each die (LUN) by polling its status register
instead of using the R/B# signal (see Status Operations for details regarding die (LUN) status).
This signal requires a pull-up resistor, Rp, for proper operation. R/B# is HIGH when the target is ready, and transitions LOW when the
target is busy. The signal's open-drain driver enables multiple R/B# outputs to be OR-tied. Typically, R/B# is connected to an
interrupt pin on the system controller.
The combination of Rp and capacitive loading of the R/B# circuit determines the rise time of the R/B# signal. The actual value used for
Rp depends on the system timing requirements. Large values of Rp cause R/B# to be delayed significantly. Between the 10% and 90%
points on the R/B# waveform, the rise time is approximately two time constants (TC).
Where R = Rp (resistance of pull-up resistor), and C = total capacitive load.
The fall time of the R/B# signal is determined mainly by the output impedance of the R/B# signal and the total load capacitance.
Approximate Rp values using a circuit load of 100pF are provided in Figure of TC vs. Rp.
The minimum value for Rp is determined by the output drive capability of the R/B# signal, the output voltage swing, and VCC
.
Where ΣIL is the sum of the input currents of all devices tied to the R/B# pin.
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ESMT
(Preliminary)
F59L8G81XSB (2X)
READ/BUSY# Open Drain
tFall and tRise
Notes:
1. tFall and tRise calculated at 10% and 90% points.
2. tRise dependent on external capacitance and resistive loading and output transistor impedance.
3. tRise primarily dependent on external pull-up resistor and external capacitive loading.
4. tFall = 10ns at 3.3V.
5. See TC values in Figure for approximate Rp value and TC.
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(Preliminary)
F59L8G81XSB (2X)
IOL vs. Rp
TC vs. Rp
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(Preliminary)
F59L8G81XSB (2X)
Device Initialization
NAND Flash devices are designed to prevent data corruption during power transitions. VCC is internally monitored. (The WP# signal
supports additional hardware protection during power transitions.) When ramping VCC, use the following procedure to initialize the
device:
1. Ramp VCC
2. The host must wait for R/B# to be valid and HIGH before issuing RESET (FFh) to any target. The R/B# signal becomes valid when
50µs has elapsed since the beginning the VCC ramp, and 10µs has elapsed since VCC reaches VCC,min
.
.
3. If not monitoring R/B#, the host must wait at least 100µs after VCC reaches VCC,min
.
If monitoring R/B#, the host must wait until R/B# is HIGH.
4. The asynchronous interface is active by default for each target. Each LUN draws less than an average of 10mA (IST) measured
over intervals of 1ms until the RESET (FFh) command is issued.
5. The RESET (FFh) command must be the first command issued to all targets (CE#s) after the NAND Flash device is powered on.
Each target will be busy for 1ms after a RESET command is issued. The RESET busy time can be monitored by polling R/B# or
issuing the READ STATUS (70h) command to poll the status register.
6. The device is now initialized and ready for normal operation.
R/B# Power-On Behavior
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F59L8G81XSB (2X)
Power Cycle Requirements
Upon power-down the NAND device requires a maximum voltage and minimum time that the host must hold VCC and VCCQ below the
voltage prior to power-on.
Power Cycle Requirements
Device can not operate correctly when VCC is lower than 2.5V@3.3V
Parameter
Value
100
Unit
mV
ns
Maximum VCC/VCCQ
Minimum time below maximum voltage
100
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Command Definitions
Command Set
Valid While
Selected
LUN is
Valid While
Other
Command
1st Cycle
Command
2nd Cycle
Number of Valid Data Input
Command
Notes
Address Cycles
Cycles
LUNs are
Busy1
Busy 1
Reset Operations
RESET
FFh
0
-
-
Yes
Yes
Identification Operation
READ ID
90h
1
1
-
-
-
-
No
No
No
No
READ UNIQUE ID
Feature Operations
GET FEATURES
EDh
EEh
EFh
1
1
-
-
-
No
No
No
No
SET FEATURES
4
Status Operations
READ STATUS
70h
78h
0
3
-
-
-
-
Yes
Yes
N/A
Yes
READ STATUS ENHANCED
Column Address Operations
RANDOM DATA READ
RANDOM DATA INPUT
2
3
05h
85h
2
2
-
E0h
-
No
No
Yes
Yes
Optional
PROGRAM FOR INTERNAL
DATA MOVE
85h
5
Optional
-
No
Yes
Read Operations
READ MODE
READ PAGE
00h
00h
0
5
-
-
-
No
No
Yes
Yes
30h
READ PAGE CACHE
SEQUENTIAL
31h
0
-
-
No
Yes
4
READ PAGE CACHE RANDOM
READ PAGE CACHE LAST
Program Operations
00h
3Fh
5
0
-
-
31h
-
No
No
Yes
Yes
4
4
PROGRAM PAGE
80h
80h
5
5
Yes
Yes
10h
15h
No
No
Yes
Yes
2
PROGRAM PAGE CACHE
Erase Operations
2,5
ERASE BLOCK
60h
3
-
D0h
No
Yes
Internal Data Move Operations
READ FOR INTERNAL DATA
MOVE
00h
85h
5
5
-
35h
10h
No
No
Yes
Yes
3
PROGRAM FOR INTERNAL
DATA MOVE
Optional
Block Lock Operations
BLOCK UNLOCK LOW
BLOCK UNLOCK HIGH
BLOCK LOCK
23h
24h
2Ah
2Ch
7Ah
3
3
-
-
-
-
-
-
-
-
-
-
-
No
No
No
No
No
Yes
Yes
Yes
Yes
Yes
BLOCK LOCK-TIGHT
BLOCK LOCK READ STATUS
-
3
PERMANENT BOOT BLOCK
PROTECT
PERMANENT BOOT BLOCK
PROTECT
PERMANENT BOOT BLOCK
PROTECT Disable
-
-
-
-
-
No
No
No
Yes
Yes
No
83h
80h
5
5
10h
10h
Yes
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ESMT
(Preliminary)
F59L8G81XSB (2X)
Valid While
Selected
LUN is
Valid While
Other
Command
1st Cycle
Command
2nd Cycle
Number of Valid Data Input
Command
Notes
Address Cycles
Cycles
LUNs are
Busy1
Busy 1
One-Time Programmable (OTP) Operations
OTP DATA LOCK BY BLOCK
(ONFI)
80h
5
No
10h
No
No
6
OTP DATA PROGRAM (ONFI)
OTP DATA READ (ONFI)
80h
00h
5
5
Yes
No
10h
30h
No
No
No
No
6
6
Notes:
1. Busy means RDY = 0.
2. These commands can be used for interleaved die (multi-LUN) operations (applicable to Multi-LUN Operations).
3. Do not cross plane address boundaries when using READ for INTERNAL DATA MOVE and PROGRAM for INTERNAL DATA
MOVE.
4. Issuing a READ PAGE CACHE series (31h, 00h-31h, 00h-32h, 3Fh) command when the array is busy (RDY = 1, ARDY = 0) is
supported if the previous command was a READ PAGE (00h-30h) or READ PAGE CACHE series command; otherwise, it is
prohibited.
5. Issuing a PROGRAM PAGE CACHE (80h-15h) command when the array is busy (RDY = 1, ARDY = 0) is supported if the
previous command was a PROGRAM PAGE CACHE (80h-15h) command; otherwise, it is prohibited.
6. OTP commands can be entered only after issuing the SET FEATURES command with the feature address.
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(Preliminary)
F59L8G81XSB (2X)
Reset Operations
RESET (FFh)
The RESET command is used to put the memory device into a known condition and to abort the command sequence in progress.
READ, PROGRAM, and ERASE commands can be aborted while the device is in the busy state. The contents of the memory location
being programmed or the block being erased are no longer valid. The data may be partially erased or programmed, and is invalid. The
command register is cleared and is ready for the next command. The data register and cache register contents are marked invalid.
The status register contains the value E0h when WP# is HIGH; otherwise it is written with a 60h value. R/B# goes LOW for tRST after
the RESET command is written to the command register.
The RESET command must be issued to all CE#s as the first command after power-on.
The device will be busy for a maximum of 1ms.
RESET (FFh) Operation
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F59L8G81XSB (2X)
Identification Operations
READ ID (90h)
The READ ID (90h) command is used to read identifier codes programmed into the target. This command is accepted by the target
only when all die (LUNs) on the target are idle.
Writing 90h to the command register puts the target in read ID mode. The target stays in this mode until another valid command is
issued.
When the 90h command is followed by an 00h address cycle, the target returns a 5-byte identifier code that includes the manufacturer
ID, device configuration, and part-specific information.
When the 90h command is followed by a 20h address cycle, the target returns the 4-byte ONFI identifier code.
READ ID (90h) with 00h Address Operation
READ ID (90h) with 20h Address Operation
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F59L8G81XSB (2X)
READ ID Parameter Tables
READ ID Parameters for Address 00h
Byte
Options
I/O7
0
I/O6
0
I/O5
1
I/O4
0
I/O3
1
I/O2
1
I/O1
0
I/O0 Value
Byte 0 - Manufacturer ID
Manufacturer
Byte 1 - Device ID
Device
0
1
0
2Ch
D3h
8Gb, x8, 3.3V
1
1
0
1
0
0
1
Byte 2
Number of die per CE#
Cell type
1
0
00b
00b
SLC
0
0
0
Number of simultaneously
programmed pages
2
0
0
1
1
01b
1b
Interleaved operations
between multiple die
Supported (8Gb)
1
1
Cache programming
Byte value
Supported
8Gb
1
1
1b
0
1
0
1
0
0
D0b
Byte 3
Page size
4KB
256B
256KB
x8
10b
1b
Spare area size ( bytes)
Block size ( without spare)
Organization
1
1
0
0
10b
0b
0
0
Serial access (MIN)
Byte value
25ns
1
1
0
0
10b
A6h
×8, 3.3V
1
1
1
0
0
Byte 4
8-bit ECC/512B(main)+
16B(spare)+16B(parity)
bytes
Internal ECC level
10b
Planes per CE#
Plane size
1
0
0
0
1
00b
110b
0b
4Gb
1
1
1
1
0
0
ECC Disabled
ECC Enabled
8Gb
0
1
x
Internal ECC
1b
Byte value
1
0
66h
Note:
1.
b = binary; h = hexadecimal.
READ ID Parameters for Address 20h
Byte
Options
“O”
I/O7 I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0
Value
4Fh
0
0
0
0
X
1
1
1
1
X
0
0
0
0
X
0
0
0
0
X
1
1
0
1
X
1
1
1
0
X
1
1
1
0
X
1
0
0
1
X
0
1
2
3
4
4Eh
46h
“N”
“F”
49h
“I”
XXh
Undefined
Note:
1. h = hexadecimal; X = VIH or VIL.
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(Preliminary)
F59L8G81XSB (2X)
READ UNIQUE ID (EDh)
The READ UNIQUE ID (EDh) command is used to read a unique identifier programmed into the target. This command is accepted by
the target only when all die (LUNs) on the target are idle.
Writing EDh to the command register puts the target in read unique ID mode. The target stays in this mode until another valid
command is issued.
t
When the EDh command is followed by an 00h address cycle, the target goes busy for R. If the READ STATUS (70h) command is
used to monitor for command completion, the READ MODE (00h) command must be used to re-enable data output mode.
After tR completes, the host enables data output mode to read the unique ID. When the asynchronous interface is active, one data byte
is output per RE# toggle.
Sixteen copies of the unique ID data are stored in the device. Each copy is 32 bytes. The first 16 bytes of a 32-byte copy are unique
data, and the second 16 bytes are the complement of the first 16 bytes. The host should XOR the first 16 bytes with the second 16
bytes. If the result is 16 bytes of FFh, then that copy of the unique ID data is correct. In the event that a non-FFh result is returned, the
host can repeat the XOR operation on a subsequent copy of the unique ID data. If desired, the RANDOM DATA READ (05h-E0h)
command can be used to change the data output location.
READ UNIQUE ID (EDh) Operation
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F59L8G81XSB (2X)
Feature Operations
The SET FEATURES (EFh) and GET FEATURES (EEh) commands are used to modify the target's default power-on behavior. These
commands use a one-byte feature address to determine which sub-feature parameters will be read or modified. Each feature address
(in the 00h to FFh range) is defined in below. The SET FEATURES (EFh) command writes sub-feature parameters (P1–P4) to the
specified feature address. The GET FEATURES command reads the sub-feature parameters (P1–P4) at the specified feature address.
Feature Address Definitions
Feature Address
Definition
00h
01h
Reserved
Timing mode
02h–7Fh
80h
Reserved
Programmable output drive strength
Programmable RB# pull-down strength
Reserved
81h
82h–FFh
90h
Array operation mode
Feature Addresses 90h: Timing Mode
Subfeature Parameter Options
P1
I/O7 I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0
Value
Notes
Normal
Reserved(0)
Reserved(0)
0
1
1
0
0
00h
01h
03h
00h
08h
1
OTP operation
OTP protection
Disable ECC
Enable ECC
Reserved(0)
Reserved(0)
Reserved(0)
1
0
0
Timing mode
0
1
0
0
3
1,2
Permanent block
lock disable
Reserved(0)
1
0
0
0
0
10h
P2
P3
Reserved(0)
Reserved(0)
Reserved(0)
00h
00h
00h
P4
Notes:
1. These bits are reset to 00h after power cycle.
2. Bit3 is used to enable/disable ECC. For ECC always on or ECC always off configuration, bit3 is reserved (0) and should be set to
0.
3. For MPNs with "-ITE" ECC enabled by default, this bit is Reserved.
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F59L8G81XSB (2X)
SET FEATURES (EFh)
The SET FEATURES (EFh) command writes the subfeature parameters (P1–P4) to the specified feature address to enable or disable
target-specific features.
Writing EFh to the command register puts the target in the set features mode. The target stays in this mode until another command is
issued.
The EFh command is followed by a valid feature address. The host waits for tADL before the subfeature parameters are input. When
the asynchronous interface is active, one subfeature parameter is latched per rising edge of WE#.
t
After all four subfeature parameters are input, the target goes busy for FEAT. The READ STATUS (70h) command can be used to
monitor for command completion.
Feature address 01h (timing mode) operation is unique. If SET FEATURES is used to modify the interface type, the target will be busy
for tITC.
SET FEATURES (EFh) Operation
GET FEATURES (EEh)
The GET FEATURES (EEh) command reads the subfeature parameters (P1–P4) from the specified feature address. This command is
accepted by the target only when all die (LUNs) on the target are idle.
Writing EEh to the command register puts the target in get features mode. The target stays in this mode until another valid command is
issued.
When the EEh command is followed by a feature address, the target goes busy for tFEAT.
If the READ STATUS (70h) command is used to monitor for command completion, the READ MODE (00h) command must be used to
re-enable data output mode. During and prior to data output, use of the READ STATUS ENHANCED (78h) command is prohibited.
After tFEAT completes, the host enables data output mode to read the subfeature parameters.
GET FEATURES (EEh) Operation
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F59L8G81XSB (2X)
Feature Addresses 01h: Timing Mode
Subfeature Parameter
P1
Options
I/O7
I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0
Value
Notes
Mode 0
(default)
Reserved(0)
0
0
0
00h
1
Mode 1
Mode 2
Mode 3
Mode 4
Mode 5
Reserved(0)
Reserved(0)
Reserved(0)
Reserved(0)
Reserved(0)
0
0
0
1
1
0
1
1
0
0
1
0
1
0
1
01h
02h
03h
04h
05h
Timing mode
P2
P3
Reserved(0)
Reserved(0)
Reserved(0)
00h
00h
00h
P4
Note:
1. The timing mode feature address is used to change the default timing mode. The timing mode should be selected to indicate the
maximum speed at which the device will receive commands, addresses, and data cycles. The five supported settings for the
timing mode are shown. The default timing mode is mode 0. The device returns to mode 0 when the device is power cycled.
Supported timing modes are reported in the parameter page.
Feature Addresses 80h: Programmable I/O Drive Strength
Subfeature Parameter
P1
Options
I/O7 I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0
Value
Notes
Full (default)
Three-quarters
One-half
Reserved(0)
Reserved(0)
Reserved(0)
Reserved(0)
0
0
1
1
0
1
0
1
00h
01h
02h
03h
1
I/O drive strength
One-quarter
P2
P3
Reserved(0)
00h
00h
00h
Reserved(0)
Reserved(0)
P4
Note:
1. The programmable drive strength feature address is used to change the default I/O drive strength. Drive strength should be
selected based on expected loading of the memory bus. This table shows the four supported output drive strength settings. The
default drive strength is full strength. The device returns to the default drive strength mode when the device is power cycled. AC
timing parameters may need to be relaxed if I/O drive strength is not set to full.
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(Preliminary)
F59L8G81XSB (2X)
Feature Addresses 81h: Programmable R/B# Pull-Down Strength
Subfeature Parameter
P1
Options
I/O7 I/O6 I/O5 I/O4 I/O3 I/O2 I/O1 I/O0
Value
Notes
Full (default)
Three-quarters
One-half
0
0
1
1
0
1
0
1
00h
01h
02h
03h
1
R/B# pull-down strength
One-quarter
P2
P3
Reserved(0)
Reserved(0)
Reserved(0)
00h
00h
00h
P4
Note:
1. This feature address is used to change the default R/B# pull-down strength. Its strength should be selected based on the expected
loading of R/B#. Full strength is the default, power-on value.
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F59L8G81XSB (2X)
Status Operations
Each die (LUN) provides its status independently of other die (LUNs) on the same target through its 8-bit status register.
When a READ STATUS (70h) or READ STATUS ENHANCED (78h) command is issued, status register output is enabled. Status
register contents are returned on I/O[7:0] for each data output request.
When the asynchronous interface is active and status register output is enabled, changes in the status register are seen on I/O[7:0]
when CE# and RE# are LOW; it is not necessary to toggle RE# to see the status register update.
While monitoring the status register for completion of a data transfer from the Flash array to the data register (tR), the host must issue
the READ MODE (00h) command to disable the status register and enable data output (see Read Operations).
The READ STATUS (70h) command returns the status of the most recently selected die (LUN). To prevent data contention during or
following an interleaved die (multi-LUN) operation, the host must enable only one die (LUN) for status output by using the READ
STATUS ENHANCED (78h) command (see Interleaved Die (Multi-LUN) Operations).
Status Register Definition
Program Page
Cache Mode
Page Read
Cache Mode
SR Bit
Program Page
Page Read
Block Erase
Description
0 = Protected
7
Write protect
Write protect
Write protect
Write protect
RDY cache
Write protect
1 = Not protected
0 = Busy (PROGRAM operation
in progress)
1 = Ready (Cache can accept
data; R/B# follows)
6
5
4
RDY
ARDY
0
RDY cache
RDY
ARDY
RDY
ARDY
0
0 = Busy (PROGRAM operation
in progress)
1 = Ready (Internal operations
completed, if cache
mode is used)
00 = Normal or uncorrectable
01 = 4~6
ARDY
0
ARDY
ECC Status
(N–1)1
ECC status1
10 = 1~3
11 = 7~8(Rewrite recommended)
00 = Normal or uncorrectable
01 = 4~6
10 = 1~3
ECC Status
(N–1)1
ECC status1
-
3
2
0
-
0
-
0
-
11 = 7~8(Rewrite recommended)
Don’t Care
-
0 = Pass
1 = Fail
This bit is valid only when RDY
(SR bit 6) is 1. This bit retains the
status of the previous valid
program operation when the most
recent program operation is
complete.
1
0
FAILC ( N-1)
FAILC ( N-1)
Reserved
-
-
0 = Pass
1 = Fail
This bit is set if the most recent
finished operation on the selected
die (LUN) failed. This bit is valid
only when ARDY (SR bit 5) is 1.
FAIL
FAIL (N)
FAIL2
FAIL (N-1)
FAIL
Note:
1. Bit = 11 when a rewrite is recommended because the page includes READ errors per sector (512-Byte [main] + 16-Byte [spare] +
16-Byte [parity]). When ECC is enabled, up to 7~8-bit error is corrected automatically.
2. A status register bit defined as FAIL signifies that an uncorrectable READ error has occurred.
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F59L8G81XSB (2X)
READ STATUS (70h)
The READ STATUS (70h) command returns the status of the last-selected die (LUN) on a target. This command is accepted by the
last-selected die (LUN) even when it is busy (RDY = 0).
If there is only one die (LUN) per target, the READ STATUS (70h) command can be used to return status following any NAND
command.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ
STATUS ENHANCED (78h) command must be used to select the die (LUN) that should report status. In this situation, using the READ
STATUS (70h) command will result in bus contention, as two or more die
(LUNs) could respond until the next operation is issued. The READ STATUS (70h) command can be used following all single die (LUN)
operations.
READ STATUS (70h) Operation
READ STATUS ENHANCED (78h)
The READ STATUS ENHANCED (78h) command returns the status of the addressed die (LUN) on a target even when it
is busy (RDY = 0). This command is accepted by all die (LUNs), even when they are BUSY (RDY = 0).
Writing 78h to the command register, followed by three row address cycles containing the page, block, and LUN
addresses, puts the selected die (LUN) into read status mode.
The selected die (LUN) stays in this mode until another valid command is issued. Die (LUNs) that are not addressed are
deselected to avoid bus contention.
The selected LUN's status is returned when the host requests data output. The RDY and ARDY bits of the status register
are shared for all planes on the selected die (LUN). The FAILC and FAIL bits are specific to the plane specified in the row
address.
The READ STATUS ENHANCED (78h) command also enables the selected die (LUN) for data output. To begin data
output following a READ-series operation after the selected die (LUN) is ready (RDY = 1), issue the READ MODE (00h)
command, then begin data output.
Use of the READ STATUS ENHANCED (78h) command is prohibited during the poweron RESET (FFh) command and
when OTP mode is enabled. It is also prohibited following some of the other reset, identification, and configuration
operations. See individual operations for specific details.
READ STATUS ENHANCED (78h) Operation
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F59L8G81XSB (2X)
Column Address Operations
The column address operations affect how data is input to and output from the cache registers within the selected die (LUNs). These
features provide host flexibility for managing data, especially when the host internal buffer is smaller than the number of data bytes or
words in the cache register.
When the asynchronous interface is active, column address operations can address any byte in the selected cache register.
RANDOM DATA READ (05h-E0h)
The RANDOM DATA READ (05h-E0h) command changes the column address of the selected cache register and enables data output
from the last selected die (LUN). This command is accepted by the selected die (LUN) when it is ready (RDY = 1; ARDY = 1). It is also
accepted by the selected die (LUN) during CACHE READ operations (RDY = 1; ARDY = 0).
Writing 05h to the command register, followed by two column address cycles containing the column address, followed by the E0h
command, puts the selected die (LUN) into data output mode. After the E0h command cycle is issued, the host must wait at least tWHR
before requesting data output. The selected die (LUN) stays in data output mode until another valid command is issued.
In devices with more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS
ENHANCED (78h) command must be issued prior to issuing the RANDOM DATA READ (05h-E0h). In this situation, using the
RANDOM DATA READ (05h-E0h) command without the READ STATUS ENHANCED (78h) command will result in bus contention
because two or more die (LUNs) could output data.
RANDOM DATA READ (05h-E0h) Operation
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RANDOM DATA INPUT (85h)
The RANDOM DATA INPUT (85h) command changes the column address of the selected cache register and enables data input on
the last-selected die (LUN). This command is accepted by the selected die (LUN) when it is ready (RDY = 1; ARDY = 1). It is also
accepted by the selected die (LUN) during cache program operations (RDY = 1; ARDY = 0).
Writing 85h to the command register, followed by two column address cycles containing the column address, puts the selected die
t
(LUN) into data input mode. After the second address cycle is issued, the host must wait at least ADL before inputting data. The
selected die (LUN) stays in data input mode until another valid command is issued. Though data input mode is enabled, data input from
the host is optional. Data input begins at the column address specified.
The RANDOM DATA INPUT (85h) command is allowed after the required address cycles are specified, but prior to the final command
cycle (10h, 11h, 15h) of the following commands while data input is permitted: PROGRAM PAGE (80h-10h), PROGRAM PAGE
CACHE (80h-15h) and PROGRAM FOR INTERNAL DATA MOVE (85h-10h).
In devices that have more than one die (LUN) per target, the RANDOM DATA INPUT (85h) command can be used with other
commands that support interleaved die (multi- LUN) operations.
RANDOM DATA INPUT (85h) Operation
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PROGRAM FOR INTERNAL DATA INPUT (85h)
The PROGRAM FOR INTERNAL DATA INPUT (85h) command changes the row address (block and page) where the cache register
contents will be programmed in the NAND Flash array. It also changes the column address of the selected cache register and enables
data input on the specified die (LUN). This command is accepted by the selected die (LUN) when it is ready (RDY = 1; ARDY = 1). It is
also accepted by the selected die (LUN) during cache programming operations (RDY = 1; ARDY = 0).
Write 85h to the command register. Then write two column address cycles and three row address cycles. This updates the page and
block destination of the selected device for the addressed LUN and puts the cache register into data input mode. After the fifth address
t
cycle is issued the host must wait at least ADL before inputting data. The selected LUN stays in data input mode until another valid
command is issued. Though data input mode is enabled, data input from the host is optional. Data input begins at the column address
specified.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command is allowed after the required address cycles are specified, but prior to
the final command cycle (10h, 11h, 15h) of the following commands while data input is permitted: PROGRAM PAGE (80h-10h),
PROGRAM PAGE CACHE (80h-15h) and PROGRAM FOR INTERNAL DATA MOVE (85h-10h). When used with these commands,
the LUN address and plane select bits are required to be identical to the LUN address and plane select bits originally specified.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command enables the host to modify the original page and block address for the
data in the cache register to a new page and block address.
In devices that have more than one die (LUN) per target, the PROGRAM FOR INTERNAL DATA INPUT (85h) command can be used
with other commands that support interleaved die (multi-LUN) operations.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command can be used with the RANDOM DATA READ (05h-E0h) commands to
read and modify cache register contents in small sections prior to programming cache register contents to the NAND Flash array. This
capability can reduce the amount of buffer memory used in the host controller.
The RANDOM DATA INPUT (85h) command can be used during the PROGRAM FOR INTERNAL DATA MOVE command sequence
to modify one or more bytes of the original data. First, data is copied into the cache register using the 00h-35h command sequence,
then the RANDOM DATA INPUT (85h) command is written along with the address of the data to be modified next. New data is input on
the external data pins. This copies the new data into the cache register.
PROGRAM FOR INTERNAL DATA INPUT (85h) Operation
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F59L8G81XSB (2X)
Read Operations
The READ PAGE (00h-30h) command, when issued by itself, reads one page from the NAND Flash array to its cache register and
enables data output for that cache register.
During data output the following commands can be used to read and modify the data in the cache registers: RANDOM DATA READ
(05h-E0h) and RANDOM DATA INPUT (85h).
Read Cache Operations
To increase data throughput, the READ PAGE CACHE series (31h, 00h-31h) commands can be used to output data from the cache
register while concurrently copying a page from the NAND Flash array to the data register.
To begin a read page cache sequence, begin by reading a page from the NAND Flash array to its corresponding cache register using
the READ PAGE (00h-30h) command.
R/B# goes LOW during tR and the selected die (LUN) is busy (RDY = 0, ARDY = 0). After tR (R/B# is HIGH and RDY = 1, ARDY = 1),
issue either of these commands:
ò
ò
READ PAGE CACHE SEQUENTIAL (31h) – copies the next sequential page from the NAND Flash array to the data register
READ PAGE CACHE RANDOM (00h-31h) – copies the page specified in this command from the NAND Flash array to its
corresponding data register
After the READ PAGE CACHE series (31h, 00h-31h) command has been issued, R/B# goes LOW on the target, and RDY = 0 and
t
t
ARDY = 0 on the die (LUN) for RCBSY while the next page begins copying data from the array to the data register. After RCBSY,
R/B# goes HIGH and the die’s (LUN’s) status register bits indicate the device is busy with a cache operation (RDY = 1, ARDY = 0). The
cache register becomes available and the page requested in the READ PAGE CACHE operation is transferred to the data register. At
this point, data can be output from the cache register, beginning at column address 0. The RANDOM DATA READ (05h-E0h)
command can be used to change the column address of the data output by the die (LUN).
After outputting the desired number of bytes from the cache register, either an additional READ PAGE CACHE series (31h, 00h-31h)
operation can be started or the READ PAGE CACHE LAST (3Fh) command can be issued.
If the READ PAGE CACHE LAST (3Fh) command is issued, R/B# goes LOW on the target, and RDY = 0 and ARDY = 0 on the die
(LUN) for tRCBSY while the data register is copied into the cache register. After tRCBSY, R/B# goes HIGH and RDY = 1 and ARDY = 1,
indicating that the cache register is available and that the die (LUN) is ready. Data can then be output from the cache register,
beginning at column address 0. The RANDOM DATA READ (05h-E0h) command can be used to change the column address of the
data being output.
For READ PAGE CACHE series (31h, 00h-31h, 3Fh), during the die (LUN) busy time, tRCBSY, when RDY = 0 and ARDY = 0, the only
valid commands are status operations (70h, 78h) and RESET (FFh). When RDY = 1 and ARDY = 0, the only valid commands during
READ PAGE CACHE series (31h, 00h-31h) operations are status operations (70h, 78h), READ MODE (00h), READ PAGE CACHE
series (31h, 00h-31h), RANDOM DATA READ (05h-E0h), and RESET (FFh).
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READ MODE (00h)
The READ MODE (00h) command disables status output and enables data output for the last-selected die (LUN) and cache register
after a READ operation (00h-30h, 00h-3Ah, 00h-35h) has been monitored with a status operation (70h, 78h). This command is
accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN) during READ PAGE CACHE
(31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ
STATUS ENHANCED (78h) command must be used to select only one die (LUN) prior to issuing the READ MODE (00h) command.
This prevents bus contention.
READ PAGE (00h-30h)
The READ PAGE (00h–30h) command copies a page from the NAND Flash array to its respective cache register and enables data
output. This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1).
To read a page from the NAND Flash array, write the 00h command to the command register, then write n address cycles to the
t
address registers, and conclude with the 30h command. The selected die (LUN) will go busy (RDY = 0, ARDY = 0) for R as data is
transferred.
To determine the progress of the data transfer, the host can monitor the target's R/B# signal or, alternatively, the status operations (70h,
78h) can be used. If the status operations are used to monitor the LUN's status, when the die (LUN) is ready (RDY = 1, ARDY = 1), the
host disables status output and enables data output by issuing the READ MODE (00h) command. When the host requests data output,
output begins at the column address specified.
During data output the RANDOM DATA READ (05h-E0h) command can be issued.
When internal ECC is enabled, the READ STATUS (70h) command is required after the completion of the data transfer (tR_ECC) to
determine whether an uncorrectable read error occured. (tR_ECC is the data transferred with internal ECC enabled.)
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations the READ
STATUS ENHANCED (78h) command must be used to select only one die (LUN) prior to the issue of the READ MODE (00h)
command. This prevents bus contention.
READ PAGE (00h-30h) Operation
READ PAGE (00h-30h) Operation with Internal ECC Enabled
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READ PAGE CACHE SEQUENTIAL (31h)
The READ PAGE CACHE SEQUENTIAL (31h) command reads the next sequential page within a block into the data register while the
previous page is output from the cache register. This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It
is also accepted by the die (LUN) during READ PAGE CACHE (31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
To issue this command, write 31h to the command register. After this command is issued, R/B# goes LOW and the die (LUN) is busy
(RDY = 0, ARDY = 0) for tRCBSY. After tRCBSY, R/B# goes HIGH and the die (LUN) is busy with a cache operation (RDY = 1, ARDY =
0), indicating that the cache register is available and that the specified page is copying from the NAND Flash array to the data register.
At this point, data can be output from the cache register beginning at column address 0. The RANDOM DATA READ (05h-E0h)
command can be used to change the column address of the data being output from the cache register.
The READ PAGE CACHE SEQUENTIAL (31h) command can be used to cross block boundaries. If the READ PAGE CACHE
SEQUENTIAL (31h) command is issued after the last page of a block is read into the data register, the next page read will be the next
logical block in which the 31h command was issued. Do not issue the READ PAGE CACHE SEQUENTIAL (31h) to cross die (LUN)
boundaries. Instead, issue the READ PAGE CACHE LAST (3Fh) command.
READ PAGE CACHE SEQUENTIAL (31h) Operation
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READ PAGE CACHE RANDOM (00h-31h)
The READ PAGE CACHE RANDOM (00h-31h) command reads the specified block and page into the data register while the previous
page is output from the cache register.
This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN) during READ
PAGE CACHE (31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
To issue this command, write 00h to the command register, then write n address cycles to the address register, and conclude by writing
31h to the command register. The column address in the address specified is ignored. The die (LUN) address must match the same
die (LUN) address as the previous READ PAGE (00h-30h) command or, if applicable, the previous READ PAGE CACHE RANDOM
(00h-31h) command.
After this command is issued, R/B# goes LOW and the die (LUN) is busy (RDY = 0, ARDY = 0) for tRCBSY. After tRCBSY, R/B# goes
HIGH and the die (LUN) is busy with a cache operation (RDY = 1, ARDY = 0), indicating that the cache register is available and that the
specified page is copying from the NAND Flash array to the data register.
At this point, data can be output from the cache register beginning at column address 0. The RANDOM DATA READ (05h-E0h)
command can be used to change the column address of the data being output from the cache register.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations the READ
STATUS ENHANCED (78h) command followed by the READ MODE (00h) command must be used to select only one die (LUN) and
prevent bus contention.
READ PAGE CACHE RANDOM (00h-31h) Operation
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READ PAGE CACHE LAST (3Fh)
The READ PAGE CACHE LAST (3Fh) command ends the read page cache sequence and copies a page from the data register to the
cache register. This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN)
during READ PAGE CACHE (31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
To issue the READ PAGE CACHE LAST (3Fh) command, write 3Fh to the command register. After this command is issued, R/B# goes
LOW and the die (LUN) is busy (RDY = 0, ARDY = 0) for tRCBSY. After tRCBSY, R/B# goes HIGH and the die (LUN) is ready (RDY =
1, ARDY = 1). At this point, data can be output from the cache register, beginning
at column address 0. The RANDOM DATA READ (05h-E0h) command can be used to change the column address of the data being
output from the cache register.
In devices that have more than one LUN per target, during and following interleaved die (multi-LUN) operations the READ STATUS
ENHANCED (78h) command followed by the READ MODE (00h) command must be used to select only one die (LUN) and prevent
bus contention.
READ PAGE CACHE LAST (3Fh) Operation
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Program Operations
Program operations are used to move data from the cache or data registers to the NAND array. During a program operation the
contents of the cache and/or data registers are modified by the internal control logic.
Within a block, pages must be programmed sequentially from the least significant page address to the most significant page address (0,
1, 2, ….., 63). During a program operation, the contents of the cache and/or data registers are modified by the internal control logic.
Program Operations
The PROGRAM PAGE (80h-10h) command programs one page from the cache register to the NAND Flash array. When the die (LUN)
is ready (RDY = 1, ARDY = 1), the host should check the FAIL bit to verify that the operation has completed successfully.
Program Cache Operations
The PROGRAM PAGE CACHE (80h-15h) command can be used to improve program operation system performance. When this
command is issued, the die (LUN) goes busy (RDY = 0, ARDY = 0) while the cache register contents are copied to the data register,
and the die (LUN) is busy with a PROGRAM CACHE operation (RDY = 1, ARDY = 0.
While the contents of the data register are moved to the NAND Flash array, the cache register is available for an additional PROGRAM
PAGE CACHE (80h-15h) or PROGRAM PAGE (80h-10h) command.
For PROGRAM PAGE CACHE series (80h-15h) operations, during the die (LUN) busy times, tCBSY and tLPROG, when RDY = 0 and
ARDY = 0, the only valid commands are status operations (70h, 78h) and reset (FFh). When RDY = 1 and ARDY = 0, the only valid
commands during PROGRAM PAGE CACHE series (80h-15h) operations are status operations (70h, 78h), PROGRAM PAGE
CACHE (80h-15h), PROGRAM PAGE (80h-10h), RANDOM DATA INPUT (85h), PROGRAM FOR INTERNAL DATA INPUT (85h),
and RESET (FFh).
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F59L8G81XSB (2X)
PROGRAM PAGE (80h-10h)
The PROGRAM PAGE (80h-10h) command enables the host to input data to a cache register, and moves the data from the cache
register to the specified block and page address in the array of the selected die (LUN). This command is accepted by the die (LUN)
when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN) when it is busy with a PROGRAM PAGE CACHE (80h-15h)
operation (RDY = 1, ARDY = 0).
To input a page to the cache register and move it to the NAND array at the block and page address specified, write 80h to the
command register. Issuing the 80h to the command register clears all of the cache registers' contents on the selected target. Then
write n address cycles containing the column address and row address. Data input cycles follow. Serial data is input beginning at the
column address specified. At any time during the data input cycle the RANDOM DATA INPUT (85h) and PROGRAM FOR INTERNAL
DATA INPUT (85h) commands may be issued. When data input is complete, write 10h to the command register. The selected LUN will
go busy (RDY = 0, ARDY = 0) for tPROG as data is transferred.
To determine the progress of the data transfer, the host can monitor the target's R/B# signal or, alternatively, the status operations (70h,
78h) may be used. When the die (LUN) is ready (RDY = 1, ARDY = 1), the host should check the status of the FAIL bit.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ
STATUS ENHANCED (78h) command must be used to select only one die (LUN) for status output. Use of the READ STATUS (70h)
command could cause more than one die (LUN) to respond, resulting in bus contention.
t
t
When internal ECC is enabled, the duration of array programming time is PROG_ECC. During PROG_ECC, the internal ECC
generates parity bits when error detection is complete.
PROGRAM PAGE (80h-10h) Operation
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PROGRAM PAGE CACHE (80h-15h)
The PROGRAM PAGE CACHE (80h-15h) command enables the host to input data to a cache register; copies the data from the cache
register to the data register; then moves the data register contents to the specified block and page address in the array of the selected
die (LUN). After the data is copied to the data register, the cache register is available for additional PROGRAM PAGE CACHE
(80h-15h) or PROGRAM PAGE (80h-10h) commands. The PROGRAM PAGE CACHE (80h-15h) command is accepted by the die
(LUN) when it is ready (RDY =1, ARDY = 1). It is also accepted by the die (LUN) when busy with a PROGRAM PAGE CACHE
(80h-15h) operation (RDY = 1, ARDY = 0).
To input a page to the cache register to move it to the NAND array at the block and page address specified, write 80h to the command
register. Issuing the 80h to the command register clears all of the cache registers' contents on the selected target. Then write n
address cycles containing the column address and row address. Data input cycles follow.
Serial data is input beginning at the column address specified. At any time during the data input cycle the RANDOM DATA INPUT (85h)
and PROGRAM FOR INTERNAL DATA INPUT (85h) commands may be issued. When data input is complete, write 15h to the
command register. The selected LUN will go busy (RDY = 0, ARDY = 0) for tCBSY to allow the data register to become available from a
previous program cache operation, to copy data from the cache register to the data register, and then to begin moving the data register
contents to the specified page and block address.
t
To determine the progress of CBSY, the host can monitor the target's R/B# signal or, alternatively, the status operations (70h, 78h)
can be used. When the LUN’s status shows that it is busy with a PROGRAM CACHE operation (RDY = 1, ARDY = 0), the host should
check the status of the FAILC bit to see if a previous cache operation was successful.
t
If, after CBSY, the host wants to wait for the PROGRAM CACHE operation to complete, without issuing the PROGRAM PAGE
(80h-10h) command, the host should monitor ARDY until it is 1. The host should then check the status of the FAIL and FAILC bits.
In devices with more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS
ENHANCED (78h) command must be used to select only one die (LUN) for status output. Use of the READ STATUS (70h) command
could cause more than one die (LUN) to respond, resulting in bus contention.
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PROGRAM PAGE CACHE (80h–15h) Operation (Start)
PROGRAM PAGE CACHE (80h–15h) Operation (End)
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Erase Operations
Erase operations are used to clear the contents of a block in the NAND Flash array to prepare its pages for program operations.
Erase Operations
The ERASE BLOCK (60h-D0h) command, erases one block in the NAND Flash array.
When the die (LUN) is ready (RDY = 1, ARDY = 1), the host should check the FAIL bit to verify that this operation completed
successfully.
ERASE BLOCK (60h-D0h)
The ERASE BLOCK (60h-D0h) command erases the specified block in the NAND Flash array. This command is accepted by the die
(LUN) when it is ready (RDY = 1, ARDY = 1).
To erase a block, write 60h to the command register. Then write three address cycles containing the row address; the page address is
ignored. Conclude by writing D0h to the command register. The selected die (LUN) will go busy (RDY = 0, ARDY = 0) for tBERS while
the block is erased.
To determine the progress of an ERASE operation, the host can monitor the target's R/B# signal, or alternatively, the status operations
(70h, 78h) can be used. When the die (LUN) is ready (RDY = 1, ARDY = 1) the host should check the status of the FAIL bit.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ
STATUS ENHANCED (78h) command must be used to select only one die (LUN) for status output. Use of the READ STATUS (70h)
command could cause more than one die (LUN) to respond, resulting in bus contention.
ERASE BLOCK (60h-D0h) Operation
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Internal Data Move Operations
Internal data move operations make it possible to transfer data within a device from one page to another, on the same plane, using the
cache register. This is particularly useful for block management and wear leveling.
It is not possible to use the READ FOR INTERNAL DATA MOVE operation to move data from one die (LUN) to another. Instead, use a
READ PAGE (00h-30h) or READ FOR INTERNAL DATA MOVE (00h-35h) command to read the data out of the NAND, and then use a
PROGRAM PAGE (80h-10h) command with data input to program the data to a new die (LUN).
Between the READ FOR INTERNAL DATA MOVE (00h-35h) and PROGRAM FOR INTERNAL DATA MOVE (85h-10h) commands,
the following commands are supported: status operations (70h, 78h) and column address operations (05h-E0h, 06h-E0h, 85h). The
RESET operation (FFh) can be issued after READ FOR INTERNAL DATA MOVE (00h-35h), but the contents of the cache registers on
the target are not valid.
In devices that have more than one die (LUN) per target, once the READ FOR INTERNAL DATA MOVE (00h-35h) is issued,
interleaved die (multi-LUN) operations are prohibited until after the PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command is
issued.
READ FOR INTERNAL DATA MOVE (00h-35h)
The READ FOR INTERNAL DATA MOVE (00h-35h) command is functionally identical to the READ PAGE (00h-30h) command,
except that 35h is written to the command register instead of 30h.
Though it is not required, it is recommended that the host read the data out of the device to verify the data prior to issuing the
PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command to prevent the propagation of data errors.
If internal ECC is enabled, the data does not need to be toggled out by the host to be corrected and moving data can then be written to
a new page without data reloading, which improves system performance.
READ FOR INTERNAL DATA MOVE (00h-35h) Operation
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READ FOR INTERNAL DATA MOVE (00h–35h) with RANDOM DATA READ (05h–E0h)
INTERNAL DATA MOVE (85h-10h) with Internal ECC Enabled
INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT with Internal ECC Enabled
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PROGRAM FOR INTERNAL DATA MOVE (85h–10h)
The PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command is functionally identical to the PROGRAM PAGE (80h-10h)
command, except that when 85h is written to the command register, cache register contents are not cleared.
PROGRAM FOR INTERNAL DATA MOVE (85h–10h) Operation
PROGRAM FOR INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT (85h)
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Block Lock Feature
The block lock feature protects either the entire device or ranges of blocks from being programmed and erased. Using the block lock
feature is preferable to using WP# to prevent PROGRAM and ERASE operations.
Block lock is enabled and disabled at power-on through the LOCK pin. At power-on, if LOCK is LOW, all BLOCK LOCK commands are
disabled. However if LOCK is HIGH at power-on, the BLOCK LOCK commands are enabled and, by default, all the blocks on the
device are protected, or locked, from PROGRAM and ERASE operations, even if WP# is HIGH.
Before the contents of the device can be modified, the device must first be unlocked. Either a range of blocks or the entire device may
be unlocked. PROGRAM and ERASE operations complete successfully only in the block ranges that have been unlocked. Blocks,
once unlocked, can be locked again to protect them from further PROGRAM and ERASE operations.
Blocks that are locked can be protected further, or locked tight. When locked tight, the device’s blocks can no longer be locked or
unlocked.
WP# and Block Lock
The following is true when the block lock feature is enabled:
ò
ò
Holding WP# LOW locks all blocks, provided the blocks are not locked tight.
If WP# is held LOW to lock blocks, then returned to HIGH, a new UNLOCK command must be issued to unlock blocks.
UNLOCK (23h-24h)
By default at power-on, if LOCK is HIGH, all the blocks are locked and protected from PROGRAM and ERASE operations. The
UNLOCK (23h) command is used to unlock a range of blocks. Unlocked blocks have no protection and can be programmed or erased.
The UNLOCK command uses two registers, a lower boundary block address register and an upper boundary block address register,
and the invert area bit to determine what range of blocks are unlocked. When the invert area bit = 0, the range of blocks within the
lower and upper boundary address registers are unlocked. When the invert area bit = 1, the range of blocks outside the boundaries of
the lower and upper boundary address registers are unlocked. The lower boundary block address must be less than the upper
boundary block address. The figures below show examples of how the lower and upper boundary address registers work with the
invert area bit.
To unlock a range of blocks, issue the UNLOCK (23h) command followed by the appropriate address cycles that indicate the lower
boundary block address. Then issue the 24h command followed by the appropriate address cycles that indicate the upper boundary
block address. The least significant page address bit, PA0, should be set to 1 if setting the invert area bit; otherwise, it should be 0. The
other page address bits should be 0.
Only one range of blocks can be specified in the lower and upper boundary block address registers. If after unlocking a range of blocks
the UNLOCK command is again issued, the new block address range determines which blocks are unlocked. The previous unlocked
block address range is not retained.
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Flash Array Protected: Invert Area Bit = 0
Flash Array Protected: Invert Area Bit = 1
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Block Lock Address Cycle Assignments
ALE Cycle
First
I/O7
BA7
I/O6
BA6
I/O5
I/O4
LOW
BA12
LOW
I/O3
LOW
BA11
LOW
I/O2
LOW
BA10
LOW
I/O1
LOW
BA9
I/O0
Invert area bit1
BA8
LOW
BA13
LOW
Second
Third
BA15
LOW
BA14
LOW
BA17
BA16
Notes:
1. Invert area bit is applicable for 24h command; it may be LOW or HIGH for 23h command.
UNLOCK Operation
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LOCK (2Ah)
By default at power-on, if LOCK is HIGH, all the blocks are locked and protected from PROGRAM and ERASE operations. If portions of
the device are unlocked using the UNLOCK (23h) command, they can be locked again using the LOCK (2Ah) command. The LOCK
command locks all of the blocks in the device. Locked blocks are write-protected from PROGRAM and ERASE operations.
To lock all of the blocks in the device, issue the LOCK (2Ah) command.
When a PROGRAM or ERASE operation is issued to a locked block, R/B# goes LOW for tLBSY. The PROGRAM or ERASE operation
does not complete. Any READ STATUS command reports bit 7 as 0, indicating that the block is protected.
The LOCK (2Ah) command is disabled if LOCK is LOW at power-on or if the device is locked tight.
LOCK Operation
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LOCK TIGHT (2Ch)
The LOCK TIGHT (2Ch) command prevents locked blocks from being unlocked and also prevents unlocked blocks from being locked.
When this command is issued, the UNLOCK (23h) and LOCK (2Ah) commands are disabled. This provides an additional level of
protection against inadvertent PROGRAM and ERASE operations to locked blocks.
To implement LOCK TIGHT in all of the locked blocks in the device, verify that WP# is HIGH and then issue the LOCK TIGHT (2Ch)
command.
When a PROGRAM or ERASE operation is issued to a locked block that has also been locked tight, R/B# goes LOW for tLBSY. The
PROGRAM or ERASE operation does not complete. The READ STATUS (70h) command reports bit 7 as 0, indicating that the block is
protected. PROGRAM and ERASE operations complete successfully to blocks that were not locked at the time the LOCK TIGHT
command was issued.
After the LOCK TIGHT command is issued, the command cannot be disabled via a software command. Lock tight status can be
disabled only by power cycling the device or toggling WP#. When the lock tight status is disabled, all of the blocks become locked, the
same as if the LOCK (2Ah) command had been issued.
The LOCK TIGHT (2Ch) command is disabled if LOCK is LOW at power-on.
LOCK TIGHT Operation
PROGRAM/ERASE Issued to Locked Block
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BLOCK LOCK READ STATUS (7Ah)
The BLOCK LOCK READ STATUS (7Ah) command is used to determine the protection status of individual blocks. The address cycles
have the same format, as shown below, and the invert area bit should be set LOW. On the falling edge of RE# the I/O pins output the
block lock status register, which contains the information on the protection status of the block.
Block Lock Status Register Bit Definitions
I/O3
(Protect#)
I/O2
(Lock#)
I/O1
(LT#)
I/O0
(LT)
Block Lock Status Register Definitions
I/O[7:4]
Block is locked tight
X
X
X
X
X
1
1
1
1
0
0
0
1
1
X
0
1
0
1
X
1
0
1
0
X
Block is locked
Block is unlocked, and device is locked tight
Block is unlocked, and device is not locked tight
Block is permanently protected
BLOCK LOCK READ STATUS
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BLOCK LOCK Flowchart
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PROTECT Command
Blocks 00h–07h are guaranteed valid with ECC when shipped from the factory. The PROTECT command provides nonvolatile,
irreversible protection of up to twelve groups (48 blocks total). Implementation of the protection is group-based, which means that a
minimum of one group (4 blocks) is protected when the PROTECT command is issued.
Because block protection is nonvolatile, a power-on or power-off sequence does not affect the block status after the PROTECT
command is issued. The device ships from the factory with no blocks protected so that users can program or erase the blocks before
issuing the PROTECT command. Block protection is also irreversible in that when protection is enabled by the issuing PROTECT
command, the protected blocks can no longer be programmed or erased.
The PROTECT command includes the steps detailed below.
Address and Command Cycles
Note:
1. In the 4th address cycle, 0YH is the last 4 bits and represents the group of blocks to be protected. There are always 12 Groups, so
Y = 0000b-1011b: Y = 0000 protects Group0 = blks 0, 1, 2, 3; Y = 0001 protects Group1 = blks 4, 5, 6, 7; Y = 1011 protects
Group11 = blks 44, 45, 46, 47.
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Protection Command Details
To enable protection, four bus WRITE cycles set up the 4Ch, 03h, 1Dh, and 41h commands. Next, one bus WRITE cycle sets up the
PAGE PROGRAM command (80h).
Then, five bus WRITE cycles are required to input the targeted block group information: 00h, 00h, 00h, 0Yh, 00h. In this 4th address
cycle, 0YH is the last 4 bits and represents the group of blocks to be protected. There are always 12 Groups, so Y = 0000b-1011b:
ò
ò
ò
Y = 0000 protects Group0 = blks 0, 1, 2, 3.
Y = 0001 protects Group1 = blks 4, 5, 6, 7.
Y = 1011 protects Group11 = blks 44, 45, 46, 47.
One bus cycle is required to issue the PAGE PROGRAM CONFIRM command. After tPROG, the targeted block groups are protected.
The EXIT protection command (FFh) is issued to ensure the device exits protection mode.
(4Ch-03h-1Dh-41h)-80h-addr(00h-00h-00h-0Yh-00h)-10h-tPROG-FFh
The enable protection step is four bytes wide to prevent implementing involuntary protection.
In addition, any spurious command/address/data cycles between each byte invalidates the entire process and the next PROGRAM
command does not affect the block protection status. Likewise, any spurious command/address/data cycle between enable protection
and setting up the PAGE PROGRAM command invalidates the entire protection command process.
If enable protection is followed by an operation other than the PROGRAM operation, such as a PAGE READ or BLOCK ERASE
operation, this other operation is executed without affecting block protection status. Therefore, the PROTECT operation must still be
executed to protect the block. The PROTECT operation is inhibited if WP# is LOW.
Upon PROTECT operation failure, the status register reports a value of E1h. Upon PROTECT operation success, the status register
reports value of E0h.
The following is an example of boot block protection:
Protect group 5 (blks20-23): (4Ch-03h-1Dh-41h)-80h-addr(00h-00h-00h-05h-00h)-10htPROG- FFh
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Permanent Block Lock Disable Mode
The PROTECT command provides nonvolatile, irreversible protection of up to twelve groups (48 blocks total), these blocks are
permanent locked once the PROTECT command is issued to them. The permanent block lock disable mode provides the command
sequence to freeze the block lock status, it is highly recommended for customers to follow this operation to prevent unintentional or
malicious changes but not limited to these scenarios:
ò
ò
Only certain number of groups of blocks need to be permanently locked, the rest of the block groups do not need to be
permanently locked
Customer do not need permanent block lock feature, and all 48 blocks are normal blocks
In permanent block lock disable mode, the following program sequence is used to disable protection command to add more permanent
locked block groups:
ò
SET FEATURE command (EFh) with feature address 90h and data value 10h-00h-00h-00h to enter permanent block lock disable
mode
ò
ò
PROGRAM command (80h-10h) with block/page address all "0", and data input 0x00
READ STATUS command 70h to check the operation status and success
READ command also could be used in permanent block lock disable mode to check whether PROTECT command is disabled by
reading out all "0"; all "1" indicates Protection command is not disabled.
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One-Time Programmable (OTP) Operations
This NAND Flash device offers a protected, one-time programmable NAND Flash memory area. 48 full pages of OTP data are
available on the device, and the entire range is guaranteed to be good. The OTP area is accessible only through the OTP commands.
Customers can use the OTP area any way they choose; typical uses include programming serial numbers or other data for permanent
storage.
The OTP area leaves the factory in an unwritten state (all bits are 1s). Programming or partial-page programming enables the user to
program only 0 bits in the OTP area. The OTP area cannot be erased, whether it is protected or not. Protecting the OTP area prevents
further programming of that area.
Provides a unique way to program and verify data before permanently protecting it and preventing future changes. The OTP area is
only accessible while in OTP operation mode. To set the device to OTP operation mode, issue the SET FEATURE (EFh) command to
feature address 90h and write 01h to P1, followed by three cycles of 00h to P2-P4. For parameters to enter OTP mode, see Features
Operations.
When the device is in OTP operation mode, all subsequent PAGE READ (00h-30h) and PROGRAM PAGE (80h-10h) commands are
applied to the OTP area. The OTP area is assigned to page addresses 02h-31h. To program an OTP page, issue the PROGRAM
PAGE (80h-10h) command. The pages must be programmed in the ascending order. Similarly, to read an OTP page, issue the PAGE
READ (00h-30h) command.
Protecting the OTP is done by entering OTP protect mode. To set the device to OTP protect mode, issue the SET FEATURE (EFh)
command to feature address 90h and write 03h to P1, followed by three cycles of 00h to P2-P4.
To determine whether the device is busy during an OTP operation, either monitor R/B# or use the READ STATUS (70h) command.
To exit OTP operation or protect mode, write 00h to P1 at feature address 90h.
Legacy OTP Commands
For legacy OTP commands, OTP DATA PROGRAM (A0h-10h), OTP DATA PROTECT (A5h-10h), and OTP DATA READ (AFh-30h).
OTP DATA PROGRAM (80h-10h)
The OTP DATA PROGRAM (80h-10h) command is used to write data to the pages within the OTP area. An OTP page allows only four
partial-page programs. There is no ERASE operation for OTP pages.
PROGRAM PAGE enables programming into an offset of an OTP page using two bytes of the column address (CA[12:0]). The
command is compatible with the RANDOM DATA INPUT (85h) command. The PROGRAM PAGE command will not execute if the
OTP area has been protected.
To use the PROGRAM PAGE command, issue the 80h command. Issue n address cycles.
The first two address cycles are the column address. For the remaining cycles, select a page in the range of 02h-00h through 31h-00h.
Next, write n bytes of data. After data input is complete, issue the 10h command. The internal control logic automatically executes the
proper programming algorithm and controls the necessary timing for programming and verification.
R/B# goes LOW for the duration of the array programming time (tPROG). The READ STATUS (70h) command is the only valid
command for reading status in OTP operation mode. Bit 5 of the status register reflects the state of R/B#. When the device is ready,
read bit 0 of the status register to determine whether the operation passed or failed (see Status Operations). Each OTP page can be
programmed to 4 partial-page programming.
RANDOM DATA INPUT (85h)
After the initial OTP data set is input, additional data can be written to a new column address with the RANDOM DATA INPUT (85h)
command. The RANDOM DATA INPUT command can be used any number of times in the same page prior to the OTP PAGE WRITE
(10h) command being issued.
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(Preliminary)
F59L8G81XSB (2X)
OTP DATA PROGRAM (After Entering OTP Operation Mode)
OTP DATA PROGRAM Operation with RANDOM DATA INPUT (After Entering OTP Operation Mode)
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(Preliminary)
F59L8G81XSB (2X)
OTP DATA PROTECT (80h-10)
The OTP area is protected on a block basis. To protect a block, set the device to OTP protect mode, then issue the PROGRAM PAGE
(80h-10h) command and write OTP address 00h, 00h, 00h, 00h. To set the device to OTP protect mode, issue the SET FEATURE
(EFh) command to 90h (feature address) and write 03h to P1, followed by three cycles of 00h to P2-P4.
After the data is protected, it cannot be programmed further. When the OTP area is protected, the pages within the area are no longer
programmable and cannot be unprotected.
To use the PROGRAM PAGE command to protect the OTP area, issue the 80h command, followed by n address cycles, write 00h
data, data cycle of 00h, followed by the 10h command. (An example of the address sequence is shown in the following figure.) If an
OTP DATA PROGRAM command is issued after the OTP area has been protected, R/B# will go LOW for tOBSY.
The READ STATUS (70h) command is the only valid command for reading status in OTP operation mode. Bit 5 of the status register
reflects the state of R/B#.
When the device is ready, read bit 0 of the status register to determine whether the operation passed or failed (see Status Operations).
OTP DATA PROTECT Operation (After Entering OTP Protect Mode)
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(Preliminary)
F59L8G81XSB (2X)
OTP DATA READ (00h-30h)
To read data from the OTP area, set the device to OTP operation mode, then issue the PAGE READ (00h-30h) command. Data can be
read from OTP pages within the OTP area whether the area is protected or not.
To use the PAGE READ command for reading data from the OTP area, issue the 00h command, and then issue five address cycles:
for the first two cycles, the column address; and for the remaining address cycles, select a page in the range of 02h-00h-00h through
31h-00h-00h. Lastly, issue the 30h command. The PAGE READ CACHE MODE command is not supported on OTP pages.
R/B# goes LOW (tR) while the data is moved from the OTP page to the data register. The READ STATUS (70h) command is the only
valid command for reading status in OTP operation mode. Bit 5 of the status register reflects the state of R/B# (see Status Operations).
Normal READ operation timings apply to OTP read accesses. Additional pages within the OTP area can be selected by repeating the
OTP DATA READ command.
The PAGE READ command is compatible with the RANDOM DATA OUTPUT (05h-E0h) command.
Only data on the current page can be read. Pulsing RE# outputs data sequentially.
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(Preliminary)
F59L8G81XSB (2X)
OTP DATA READ
OTP DATA READ with RANDOM DATA READ Operation
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(Preliminary)
F59L8G81XSB (2X)
ECC Protection
Internal ECC enables 9-bit detection and 8-bit correction in 512 bytes of main area. During the busy time for PROGRAM operations,
internal ECC generates parity bits when error detection is complete. During READ operations the device executes the internal ECC
engine (9-bit detection and 8-bit error correction). When the READ operation is complete, read status bit 0 must be checked to
determine whether errors larger than eight bits have occurred.
Following the READ STATUS command, the device must be returned to read mode by issuing the 00h command.
Limitations of internal ECC include the spare area, defined in the Spare Area Mapping tables, and ECC parity areas that cannot be
written to. Each ECC user area (referred to main and spare) must be written within one partial-page program so that the NAND device
can calculate the proper ECC parity. The number of partial-page programs within a page cannot exceed four.
During a PROGRAM operation, the device calculates an ECC code on the 4K page in the cache register, before the page is written to
the NAND Flash array. The ECC code is stored in the spare area of the page.
During a READ operation, the page data is read from the array to the cache register, where the ECC code is calculated and compared
with the ECC code value read from the array. If a 1- to 8-bit error is detected, the error is corrected in the cache register. Only corrected
data is output on the I/O bus. The ECC status bit indicates whether the error correction was successful. The Spare Area Mapping
tables that follow show the ECC protection scheme used throughout a page.
With internal ECC, the user must accommodate the following:
ò
ò
Spare area definitions provided in the Spare Area Mapping table below.
WRITEs to ECC are supported for main and spare areas 0 and 1. WRITEs to the ECC area are prohibited (see the Spare Area
Mapping table below).
ò
When using partial-page programming, the following conditions must both be met: First, in the main user area and in user meta
data area, single partial-page programming operations must be used (see the Spare Area Mapping table below). Second, within
a page, the user can perform a maximum of four partial-page programming operations.
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F59L8G81XSB (2X)
Spare Area Mapping
Max Byte Address
Min Byte Address
ECC Protected
Area
Description
User Data
1FFh
000h
200h
400h
600h
800h
A00h
C00h
E00h
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Main 0
Main 1
Main 2
Main 3
Main 4
Main 5
Main 6
Main 7
User data 0
User data 1
User data 2
User data 3
User data 4
User data 5
User data 6
User data 7
3FFh
5FFh
7FFh
9FFh
BFFh
DFFh
FFFh
User Meta Data
100Fh
101Fh
102Fh
103Fh
104Fh
105Fh
106Fh
107Fh
ECC
1000h
1010h
1020h
1030h
1040h
1050h
1060h
1070h
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Spare 0
Spare 1
Spare 2
Spare 3
Spare 4
Spare 5
Spare 6
Spare 7
User meta data
User meta data
User meta data
User meta data
User meta data
User meta data
User meta data
User meta data
108Fh
109Fh
10AFh
10BFh
10CFh
10DFh
10EFh
10FFh
1080h
1090h
10A0h
10B0h
10C0h
10D0h
10E0h
10F0h
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Spare 0
Spare 1
Spare 2
Spare 3
Spare 4
Spare 5
Spare 6
Spare 7
ECC for main/spare 0
ECC for main/spare 1
ECC for main/spare 2
ECC for main/spare 3
ECC for main/spare 4
ECC for main/spare 5
ECC for main/spare 6
ECC for main/spare 7
ECC Status
Bit 4
Bit 3
Bit 0
Description
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
No bit errors were detected.
More than 8 bits error were detected and not corrected.
4 to 6 bit errors were detected and corrected. Refresh is recommended.
Reserved
1 to 3 bit errors/page were detected and corrected.
Reserved
7 to 8 bit errors were detected and corrected. Refresh is required to guarantee data retention.
Reserved
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F59L8G81XSB (2X)
Error Management
Each NAND Flash die (LUN) is specified to have a minimum number of valid blocks (NVB) of the total available blocks. This means the
die (LUNs) could have blocks that are invalid when shipped from the factory. An invalid block is one that contains at least one page that
has more bad bits than can be corrected by the minimum required ECC. Additional blocks can develop with use. However, the total
number of available blocks per die (LUN) will not fall below NVB during the endurance life of the product.
Although NAND Flash memory devices could contain bad blocks, they can be used quite reliably in systems that provide bad block
management and error-correction algorithms. This type of software environment ensures data integrity.
Internal circuitry isolates each block from other blocks, so the presence of a bad block does not affect the operation of the rest of the
NAND Flash array.
NAND Flash devices are shipped from the factory erased. The factory identifies invalid blocks before shipping by attempting to
program the bad block mark into every location in the first page of each invalid block. It may not be possible to program every location
with the bad block mark. However, the first spare area location in each bad block is guaranteed to contain the bad block mark. This
method is compliant with ONFI Factory Defect Mapping requirements.
System software should check the first spare area location on the first and second page of each block prior to performing any
PROGRAM or ERASE operations on the NAND Flash device.
A bad block table can then be created, enabling system software to map around these areas. Factory testing is performed under
worst-case conditions. Because invalid blocks could be marginal, it may not be possible to recover this information if the block is
erased.
Over time, some memory locations may fail to program or erase properly. In order to ensure that data is stored properly over the life of
the NAND Flash device, the following precautions are required:
ò
ò
ò
Always check status after a PROGRAM or ERASE operation
Under typical conditions, use the minimum required ECC (see table below)
Use bad block management and wear-leveling algorithms
Error Management Details
Description
Requirement
Minimum number of valid blocks (NVB) per LUN
Total available blocks per LUN
First spare area location
4016
4096
byte 4096
Bad block mark
00h
Minimum required ECC
8-bit ECC per 544 bytes of data
Minimum ECC with internal ECC enabled
8-bit ECC per 528 bytes (user data) + 16 bytes (parity data)
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F59L8G81XSB (2X)
Electrical Specifications
Stresses greater than those listed can cause permanent damage to the device. This is stress rating only, and functional operation of
the device at these or any other conditions above those indicated in the operational sections of this specification is not guaranteed.
Exposure to absolute maximum rating conditions for extended periods can affect reliability.
Absolute Maximum Ratings
Parameter
Symbol
VIN
Min
-0.6
Max
+4.6
+4.6
+150
2000
Unit
Voltage input
V
V
VCC supply voltage
VCC
-0.6
℃
Storage Temperature
Electrostatic discharge voltage
TSTG
VESD
-65
-2000
V
NOTE:
1.
All specified voltages are with respect to VSS
.
Recommended Operating Condition
(Voltage reference to GND, TA = 0 to 70 ℃)
Parameter
Supply Voltage
Supply Voltage
NOTE:
Symbol
VCC
Min.
Typ.
3.3
0
Max.
Unit
V
2.7
0
3.6
0
VSS
V
1.
All specified voltages are with respect to VSS.
Capacitance
(TC=25℃, Vin=0V, f=1.0MHz)
Item
Input / Output Capacitance
Input Capacitance
Symbol
CI/O
Test Condition
VIL = 0V
Min.
Max.
Unit
pF
-
-
8
6
CIN
VIN = 0V
pF
NOTE:
1.
These parameters will be verified in device characterization.
AC Test Condition
(TA= 0 to 70 ℃, VCC=1.7V~1.95V)
Parameter
Input Pulse Levels
Input Rise and Fall Times
Input and Output Timing Levels
Output Load
Condition
0V to VCC
5 ns
VCC /2
1 TTL Gate and CL=50pF
NOTE:
1. These parameters will be verify in device characterization.
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F59L8G81XSB (2X)
DC and Operation Characteristics
Parameter
Symbol
Test Conditions
Min.
Typ.
Max.
Unit Notes
Sequential READ
current
ECC off
tRC= tRC (MIN) ; CE#
=VIL; IOUT=0mA
ICC1
-
15
20
Sequential READ
current
ECC on
tRC= tRC (MIN) ; CE#
=VIL; IOUT=0mA
ICC1
-
-
25
15
35
20
Operating
Current
mA
1
PROGRAM
current ECC off
PROGRAM
current ECC on
ICC2
-
ICC2
ICC3
ISB1
-
-
-
-
-
20
15
-
25
20
1
ERASE
CE# =VIH;
Stand-by Current (TTL)
mA
uA
LOCK=WP# =0V/VCC
CE# = VCC-0.2V;
WP# =0V/VCC
Stand-by Current (CMOS)
Staggered power-up current
ISB2
IST
-
-
20
-
100
Rise time=1ms,
Line capacitance=0.1uF
10 per die
mA
2
Input Leakage Current
Output Leakage Current
ILI
VIN=0 to VCC
-
-
-
-
±10
±10
uA
uA
ILO
VOUT=0 to VCC
I/O[7:0], CE#, CLE, ALE,
WE#, RE#, WP#, R/B#
Input High Voltage
VIH
0.8 x VCC
-
VCC+0.3
V
Input Low Voltage, All inputs
Output High Voltage Level
Output Low Voltage Level
Output Low Current
VIL
VOH
VOL
-
-0.3
-
-
0.2 x VCC
V
V
IOH= -400uA
IOL= 2.1mA
0.67 × VCC
-
0.4
-
3
3
4
-
-
V
IOL (R /B#) VOL= 0.4V
8
10
mA
Notes:
1. Typical and maximum values are for single-plane operation only.
2. Measurement is taken with 1ms averaging intervals and begins after VCC reaches VCC,min
3. VOH and VOL may need to be relaxed if I/O drive strength is not set to full.
4. IOL (R/B#) may need to be relaxed if R/B pull-down strength is not set to full.
.
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F59L8G81XSB (2X)
AC Characteristics for Command / Address / Data Input
Parameter
ALE to data start
Symbol
tADL
tALH
tALS
tCH
tCLH
tCLS
tCS
Min.
70
5
Max.
Unit
Notes
-
-
-
-
-
-
-
-
ns
ns
ns
ns
ns
ns
ns
ns
1
ALE hold time
ALE setup time
CE# hold time
CLE hold time
CLE setup time
CE# setup time
Data hold time
10
5
5
10
15
5
tDH
tDS
tWC
tWH
tWP
-
-
-
-
ns
ns
ns
ns
7
25
7
Data setup time
WRITE cycle time
WE# pulse width HIGH
WE# pulse width
NOTE:
1
1
1
10
1. Timing for tADL begins in the address cycle on the final rising edge of WE#, and ends with the first rising edge of WE# for data
input.
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F59L8G81XSB (2X)
AC Characteristics for Normal Operation
Parameter
ALE to RE# Delay
Symbol
tAR
Min.
10
-
Max.
Unit
Notes
-
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
CE# Access Time
tCEA
tCHZ
tCLR
tCOH
tIR
25
CE# High to Output High-Z
CLE to RE# delay
-
10
15
0
30
2
-
CE# HIGH to output hold
Output High-Z to RE# LOW
Read Cycle Time
-
-
tRC
25
-
-
RE# Access Time
tREA
tREH
tRHOH
tRHW
tRHZ
tRLOH
tRP
tRR
tRST
tWB
16
RE# High hold time
7
-
RE# High to output hold
RE# High to WE# LOW
RE# High to output High-Z
RE# LOW to output hold
RE# pulse width
15
100
-
-
-
2
100
5
-
10
20
-
ns
ns
us
ns
ns
Ready to RE# LOW
-
5/10/500
100
Reset time (READ/ PROGRAM/ ERASE)
WE# High to busy
-
-
3
4
WE# High to RE# Low
NOTE:
tWHR
60
-
1. AC characteristics may need to be relaxed if I/O drive strength is not set to “full."
2. Transition is measured ±200mV from steady-state voltage with load. This parameter is sampled and not 100% tested.
3. The first time the RESET (FFh) command is issued while the device is idle, the device will go busy for a maximum of 1ms.
Thereafter, the device goes busy for a maximum of 5µs.
4. Do not issue a new command during tWB, even if R/B# is ready.
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(Preliminary)
F59L8G81XSB (2X)
Program / Erase Characteristics
Parameter
Number of partial-page programs
BLOCK ERASE operation time
Busy time for PROGRAM CACHE operation
Cache read busy time
Symbol
NOP
tBERS
Min.
Typ.
Max.
4
Unit
Cycles
ms
Notes
-
-
-
-
-
-
2
1
10
tCBSY
tRCBSY
tRCBSY_ECC
3
600
25
us
2
3
5
us
Cache read busy time enabled
TBD
115
us
Busy time for SET FEATURES and GET FEATURES
operations
tFEAT
tLPROG
tOBSY
-
-
-
-
-
-
1
-
us
-
LAST PAGE PROGRAM operation time
Busy time for OTP DATA PROGRAM operation if OTP
is protected (ECC disabled)
30
us
Busy time for OTP DATA PROGRAM operation if OTP
is protected (ECC enabled)
tOBSY_ECC
-
-
75
us
Busy time for PROGRAM/ERASE on locked blocks
PROGRAM PAGE operation time
PROGRAM PAGE ECC on operation time
Power-on reset time
tLBSY
tPROG
tPROG_ECC
tPOR
tR
tR_ECC
-
-
-
-
-
-
-
200
240
-
3
us
us
us
ms
us
us
600
600
1
READ PAGE operation time
-
25
READ PAGE operation time ECC enabled
TBD
115
NOTE:
1. Four total partial-page programs to the same page.
2. tCBSY (MAX) time depends on timing between internal program completion and datain.
3. tLPROG = tPROG (last page) + tPROG (last - 1 page) - command load time (last page) - address load time (last page) - data load
time (last page).
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F59L8G81XSB (2X)
RESET Operation
READ STATUS Cycle
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F59L8G81XSB (2X)
READ STATUS ENHANCED Cycle
READ PARAMETER PAGE
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F59L8G81XSB (2X)
READ PAGE
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F59L8G81XSB (2X)
READ PAGE Operation with CE# “Don’t Care”
RANDOM DATA READ
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F59L8G81XSB (2X)
READ PAGE CACHE SEQUENTIAL
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F59L8G81XSB (2X)
READ PAGE CACHE RANDOM
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F59L8G81XSB (2X)
READ ID Operation
PROGRAM PAGE Operation
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F59L8G81XSB (2X)
PROGRAM PAGE Operation with CE# “Don’t Care”
PROGRAM PAGE Operation with RANDOM DATA INPUT
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F59L8G81XSB (2X)
PROGRAM PAGE CACHE
PROGRAM PAGE CACHE Ending on 15h
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F59L8G81XSB (2X)
INTERNAL DATA MOVE
ERASE BLOCK Operation
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F59L8G81XSB (2X)
PACKING DIMENSION
48-LEAD TSOP(I) ( 12x20 mm )
Dimension in mm
Min Norm Max
------- ------- 1.20 ------- ------- 0.047
0.05 ------- 0.15 0.006 ------- 0.002
Dimension in inch
Min Norm Max
Dimension in mm
Dimension in inch
Min Norm Max
0.787 BSC
Symbol
Symbol
Min Norm Max
20.00 BSC
18.40 BSC
12.00 BSC
0.50 BSC
A
A 1
A 2
b
b1
c
D
D 1
E
e
L
0.724 BSC
0.472 BSC
0.020 BSC
0.95 1.00
0.17 0.22
0.17 0.20
1.05 0.037 0.039 0.041
0.27 0.007 0.009 0.011
0.23 0.007 0.008 0.009
0.50 0.60
0O
-------
0.70 0.020 0.024 0.028
8O 0O 8O
-------
0.10 ------- 0.21 0.004 ------- 0.008
0.10 ------- 0.16 0.004 ------- 0.006
θ
c1
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(Preliminary)
F59L8G81XSB (2X)
PACKING DIMENSIONS
63-BALL
NAND Flash ( 9x11 mm )
E
Pin #1
D
A2
A
A1
Seating plane
C
ccc C
Detail A
Detail A
e
e
Solder ball
e
e
b
D1
Detail B
Pin #1
Index
E1
Detail B
Dimension in mm
Dimension in inch
Symbol
Min
—
Norm
—
Max
1.00
0.35
Min
—
Norm
—
Max
0.039
0.014
A
A1
A2
Φb
D
—
0.60 BSC
—
—
0.024 BSC
—
0.25
0.010
0.40
10.90
8.90
0.50
11.10
9.10
0.016
0.429
0.350
0.020
0.437
0.358
11.00
9.00
0.433
0.354
E
D1
E1
e
8.80 BSC
7.20 BSC
0.8 BSC
—
0.346 BSC
0.283 BSC
0.031 BSC
—
—
—
ccc
0.10
0.004
Controlling dimension : Millimeter.
Elite Semiconductor Memory Technology Inc.
Publication Date: May 2019
Revision: 0.2 80/82
ESMT
(Preliminary)
F59L8G81XSB (2X)
Revision History
Revision
Date
Description
0.1
2019.05.02
Original
1. Modify the table of Command Definitions and READ ID Parameter
2. Remove the description of READ PARAMETER PAGE (ECh)
0.2
2019.05.23
Elite Semiconductor Memory Technology Inc.
Publication Date: May 2019
Revision: 0.2
81/82
ESMT
(Preliminary)
F59L8G81XSB (2X)
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others.
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To minimize risks associated with customer's application, adequate
design and operating safeguards against injury, damage, or loss from
such failure, should be provided by the customer when making
application designs.
ESMT's products are not authorized for use in critical applications such
as, but not limited to, life support devices or system, where failure or
abnormal operation may directly affect human lives or cause physical
injury or property damage. If products described here are to be used for
such kinds of application, purchaser must do its own quality assurance
testing appropriate to such applications.
Elite Semiconductor Memory Technology Inc.
Publication Date: May 2019
Revision: 0.2 82/82
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