HY27SA081G1M-TPIS - Hynix Semiconductor, Inc.

This document is a general product description and is subject to change without notice. Hynix does not assume any responsibility for

use of circuits described. No patent licenses are implied.

Rev 0.3 / May. 2004 1

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Document Title

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash Memory

Revision History

No. History Draft Date Remark

0.0 1) Initial Draft Nov. 28. 2003 Preliminary

0.1 1) Add 1.8V Operation Product to Data sheet Mar. 11. 2004 Preliminary

0.2

1) Change AC Characteristics

- tWP(25ns->40ns), tWC(50ns->60ns),

- tRP(30ns->40ns), tRC(50ns->60ns),

- tREADID(35ns->45ns)

Apr. 29. 2004 Preliminary

0.3

1) Add Errata (3V Product)

2) Add Applicaiton Note

Reset command must be issued when the controller writes data to

another 512Mb.(i.e. When A26 is changed during program.)

3) Modify the description of Device Operations

- /CE Don’t Care Enabled(Disabled) -> Sequential Row Read Disabled

(Enabled) (Page23)

4) Add the description of System Interface Using /CE don’t care (Page40)

May. 14. 2004 Preliminary

tWH tREH

Specification 15 15

Relaxed value 20 20

This document is a general product description and is subject to change without notice. Hynix does not assume any responsibility for

use of circuits described. No patent licenses are implied.

Rev 0.3 / May. 2004 2

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

FEATURES SUMMARY

HIGH DENSITY NAND FLASH MEMORIES

- Cost effective solutions for mass storage applications

NAND INTERFACE

- x8 or x16 bus width.

- Multiplexed Address/ Data

- Pinout compatibility for all densities

SUPPLY VOLTAGE

- 3.3V device: VCC = 2.7 to 3.6V : HY27UAXX1G1M

- 1.8V device: VCC = 1.7 to 1.95V : HY27SAXX1G1M

1.8V Operation Product : TBD

Memory Cell Array

- 1056Mbit = 528 Bytes x 32 Pages x 8,192 Blocks

PAGE SIZE

- x8 device: (512 + 16 spare) Bytes

: HY27(U/S)A081G1M

- x16 device: (256 + 8 spare) Words

: HY27(U/S)A161G1M

BLOCK SIZE

- x8 device: (16K + 512 spare) Bytes

: HY27(U/S)A081G1M

- x16 device: (8K + 256 spare) Words

: HY27(U/S)A161G1M

PAGE READ / PROGRAM

- Random access: 12us (max)

- Sequential access: 50ns (min)

- Page program time: 200us (typ)

COPY BACK PROGRAM MODE

- Fast page copy without external buffering

CACHE PROGRAM MODE

- Internal Cache Register to improve the program

throughput

FAST BLOCK ERASE

- Block erase time: 2ms (Typ)

STATUS REGISTER

ELECTRONIC SIGNATURE

CHIP ENABLE DON'T CARE OPTION

- Simple interface with microcontroller

AUTOMATIC PAGE 0 READ AT POWER-UP

OPTION

- Boot from NAND support

- Automatic Memory Download

SERIAL NUMBER OPTION

HARDWARE DATA PROTECTION

- Program/Erase locked during Power transitions

DATA INTEGRITY

- 100,000 Program/Erase cycles

- 10 years Data Retention

PACKAGE

- HY27(U/S)A(08/16)1G1M-T(P)

: 48-Pin TSOP1 (12 x 20 x 1.2 mm)

- HY27(U/S)A(08/16)1G1M-T (Lead)

- HY27(U/S)A(08/16)1G1M-TP (Lead Free)

- HY27(U/S)A08121A-V(P)

: 48-Pin WSOP1 (12 x 17 x 0.7 mm)

- HY27(U/S)A081G1M-V (Lead)

- HY27(U/S)A081G1M-VP (Lead Free)

- HY27(U/S)A(08/16)121M-F(P)

: 63-Ball FBGA (8.5 x 15 x 1.2 mm)

- HY27(U/S)A(08/16)1G1M-F (Lead)

- HY27(U/S)A(08/16)1G1M-FP (Lead Free)

Rev 0.3 / May. 2004 3

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

DESCRIPTION

The HYNIX HY27(U/S)A(08/16)1G1M series is a family of non-volatile Flash memories that use NAND cell technology.

The devices operate 3.3V and 1.8V voltage supply. The size of a Page is either 528 Bytes (512 + 16 spare) or 264

Words (256 + 8 spare) depending on whether the device has a x8 or x16 bus width.

The address lines are multiplexed with the Data Input/ Output signals on a multiplexed x8 or x16 Input/ Output bus.

This interface reduces the pin count and makes it possible to migrate to other densities without changing the footprint.

Each block can be programmed and erased over 100,000 cycles. To extend the lifetime of NAND Flash devices it is

strongly recommended to implement an Error Correction Code (ECC). A Write Protect pin is available to give a hard-

ware protection against program and erase operations.

The devices feature an open-drain Ready/Busy output that can be used to identify if the Program/ Erase/Read (PER)

Controller is currently active. The use of an open-drain output allows the Ready/ Busy pins from several memories to

be connected to a single pull-up resistor.

A Copy Back command is available to optimize the management of defective blocks. When a Page Program operation

fails, the data can be programmed in another page without having to resend the data to be programmed.

Each device has a Cache Program feature which improves the program throughput for large files. It loads the data in a

Cache Register while the previous data is transferred to the Page Buffer and programmed into the memory array.

The devices are available in the following packages:

- 48-TSOP1 (12 x 20 x 1.2 mm)

- 48-WSOP1 (12 x 17 x 0.7 mm)

- 63-FBGA (8.5 x 15 x 1.2 mm, 6 x 8 ball array, 0.8mm pitch)

Three options are available for the NAND Flash family:

- Automatic Page 0 Read after Power-up, which allows the microcontroller to directly download the boot code from

page 0.

- Chip Enable Dont Care, which allows code to be directly downloaded by a microcontroller, as Chip Enable transitions

during the latency time do not stop the read operation.

- A Serial Number, which allows each device to be uniquely identified. The Serial Number options is subject to an NDA

(Non Disclosure Agreement) and so not described in the datasheet. For more details of this option contact your near-

est HYNIX Sales office.

Devices are shipped from the factory with Block 0 always valid and the memory content bits, in valid blocks, erased to

'1'.

Rev 0.3 / May. 2004 4

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

I/O8-15 Data Input/Outputs for x16 Device

I/O0-7

Data Input/Output, Address Inputs, or Com-

mand Inputs for x8 and x16 device

ALE Address Latch Enable

CLE Command Latch Enable

CE Chip Enable

RE Read Enable

RB Read/Busy (open-drain output)

WE Write Enable

WP Write Protect

VCC Supply Voltage

VSS Ground

NC Not Connected Internally

DU Do Not Use

Table 1: Signal Name

Figure 1: Logic Diagram

Figure 2. LOGIC BLOCK DIAGRAM

NAND

Flash

Vcc

Vss

ALE

CLE

I/O8-I/O15, x16

I/O0-I/O7, x8/x16

I/O Buffers &

Latches

Page Buffer

Cache Register

Y Decoder

NAND Flash

Memory Array

Address

Command

Interface

Logic

Command Register

P/E/R

Controller,

High Voltage

Generator

X Decoder

ALE

CLE

I/O0-I/O7, x8/x16

I/O8-I/O15, x16

Rev 0.3 / May. 2004 5

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 3. 48-TSOP1 Contactions, x8(x16) Device

Figure 4. 48-WSOP1 Contactions, x8 Device

I/O7

I/O6

I/O5

I/O4

Vcc

Vss

I/O3

I/O2

I/O1

I/O0

Vcc

Vss

CLE

ALE

NAND Flash

(x8)

Vss

I/O15

I/O7

I/O14

I/O6

I/O13

I/O5

I/O12

I/O4

Vcc

I/O11

I/O3

I/O10

I/O2

I/O9

I/O1

I/O8

I/O0

Vss

Vcc

Vss

CLE

ALE

NAND Flash

(x16)

I/O7

I/O6

I/O5

I/O4

Vcc

Vss

I/O3

I/O2

I/O1

I/O0

Vcc

Vss

CLE

ALE

NAND Flash

(x8)

I/O7

I/O6

I/O5

I/O4

Vcc

Vss

I/O3

I/O2

I/O1

I/O0

Vcc

Vss

CLE

ALE

RBRB

RERE

WEWE

WPWP

NAND Flash

(x8)

Vss

I/O15

I/O7

I/O14

I/O6

I/O13

I/O5

I/O12

I/O4

Vcc

I/O11

I/O3

I/O10

I/O2

I/O9

I/O1

I/O8

I/O0

Vss

Vcc

Vss

CLE

ALE

NAND Flash

(x16)

Vss

I/O15

I/O7

I/O14

I/O6

I/O13

I/O5

I/O12

I/O4

Vcc

I/O11

I/O3

I/O10

I/O2

I/O9

I/O1

I/O8

I/O0

Vss

Vcc

Vss

CLE

ALE

RBRB

RERE

WEWE

WPWP

NAND Flash

(x16)

NAND Flash

WSOP1

(x8)

I/O7

I/O6

I/O5

I/O4

Vcc

Vss

I/O3

I/O2

I/O1

I/O0

Vcc

Vss

CLE

ALE

148

NAND Flash

WSOP1

(x8)

I/O7

I/O6

I/O5

I/O4

Vcc

Vss

I/O3

I/O2

I/O1

I/O0

Vcc

Vss

CLE

ALE

148

Rev 0.3 / May. 2004 6

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 5. 63-FBGA Contactions, x8 Device (Top view through package)

Figure 6. 63-FBGA Contactions, x16 Device (Top view through package)

654321

ALE VSS CE WE RB

NC RE CLE NC NC NC

NC NC NC NC NC NC

NC I/O0 NC NC NC VCC

NC I/O1 NC VCC I/O5 I/O7

VSS I/O2 I/O3 I/O4 I/O6 VSS

NC NC

10987

654321

ALE VSS CE WE RB

NC RE CLE NC NC NC

NC NC NC NC NC NC

NC NC NC I/O5 NC

I/O1

VCC

VCC I/O6

I/O15

VSS I/O2

I/O11 I/O4 I/O13

VSS

NC NC

10987

I/O7

I/O8

I/O10 I/O12 I/O14

I/O0 I/O9 I/O3

Rev 0.3 / May. 2004 7

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

MEMORY ARRAY ORGANIZATION

The memory array is made up of NAND structures where 16 cells are connected in series.

The memory array is organized in blocks where each block contains 32 pages. The array is split into two areas, the

main area and the spare area. The main area of the array is used to store data whereas the spare area is typically used

to store Error Correction Codes, software flags or Bad Block identification.

In x8 devices the pages are split into a main area with two half pages of 256 Bytes each and a spare area of 16 Bytes.

In the x16 devices the pages are split into a 256 Word main area and an 8 Word spare area. Refer to Figure 8, Memory

Array Organization.

Bad Blocks

The NAND Flash 528 Byte/ 264 Word Page devices may contain Bad Blocks, that is blocks that contain one or more

invalid bits whose reliability is not guaranteed. Additional Bad Blocks may develop during the lifetime of the device.

The Bad Block Information is written prior to shipping (refer to Bad Block Management section for more details).

The values shown include both the Bad Blocks that are present when the device is shipped and the Bad Blocks that

could develop later on.

These blocks need to be managed using Bad Blocks Management, Block Replacement or Error Correction Codes.

Figure 7. Memory Array Organization

1st half Page

(256 bytes)

2nd half Page

(256 bytes)

Block

Page

512 Bytes 16

Bytes

8 bits

512 Bytes 16

Bytes

Page Buffer, 528 Bytes

x8 DEVICES

Block= 32 Pages

Page= 528 Bytes (512+16)

Main Area

Block

Page

256 Words 8

Words

16 bits

256 Words 8

Words

Page Buffer, 264 Words

x16 DEVICES

Block= 32 Pages

Page= 264 Bytes (256+8)

Spare Area

Rev 0.3 / May. 2004 8

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

SIGNAL DESCRIPTIONS

See Figure 1, Logic Diagram and Table 1, Signal Names, for a brief overview of the signals connected to this device.

Inputs/Outputs (I/O0-I/O7)

Input/Outputs 0 to 7 are used to input the selected address, output the data during a Read opertion or input a com-

mand or data during a Write operation. The inputs are latched on the rising edge of Write Enable. I/O0-I/O7 can be left

floating when the device is deselected or the outputs are disabled.

Inputs/Outputs (I/O8-I/O15)

Input/Outputs 8 to 15 are only available in x16 devices. They are used to output the data during a Read operation or

input data during a Write operation. Command and Address Inputs only require I/O0 to I/O7.

The inputs are latched on the rising edge of Write Enable. I/O8-I/O15 can be left floating when the device is deselected

or the outputs are disabled.

Address Latch Enable (ALE)

The Address Latch Enable activates the latching of the Address inputs in the Command Interface. When ALE is high,

the inputs are latched on the rising edge of Write Enable.

Command Latch Enable (CLE)

The Command Latch Enable activates the latching of the Command inputs in the Command Interface. When CLE is

high, the inputs are latched on the rising edge of Write Enable.

Chip Enable (CE)

The Chip Enable input activates the memory control logic, input buffers, decoders and sense amplifiers. When Chip En-

able is low, VIL, the device is selected. If Chip Enable goes high, VIH, while the device is busy, the device remains se-

lected and does not go into standby mode.

When the device is executing a Sequential Row Read operation, Chip Enable must be held low (from the second page

read onwards) during the time that the device is busy (tBLBH1). If Chip Enable goes high during tBLBH1 the operation is

aborted.

Read Enable (RE)

The Read Enable, RE, controls the sequential data output during Read operations. Data is valid tRLQV after the falling

edge of RE. The falling edge of RE also increments the internal column address counter by one.

Write Enable (WE). The Write Enable input, WE, controls writing to the Command Interface, Input Address and Data

latches. Both addresses and data are latched on the rising edge of Write Enable.

During power-up and power-down a recovery time of 1us (min) is required before the Command Interface is ready to

accept a command. It is recommended to keep Write Enable high during the recovery time.

Write Protect (WP).

The Write Protect pin is an input that gives a hardware protection against unwanted program or erase operations.

When Write Protect is Low, VIL, the device does not accept any program or erase operations.

It is recommended to keep the Write Protect pin Low, VIL, during power-up and power-down.

Rev 0.3 / May. 2004 9

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Ready/Busy (RB)

The Ready/Busy output, RB, is an open-drain output that can be used to identify if the Program/ Erase/ Read (PER)

Controller is currently active.

When Ready/Busy is Low, VOL, a read, program or erase operation is in progress. When the operation completes

Ready/Busy goes High, VOH.

The use of an open-drain output allows the Ready/ Busy pins from several memories to be connected to a single pull-

up resistor. A Low will then indicate that one, or more, of the memories is busy.

Refer to the Ready/Busy Signal Electrical Characteristics section for details on how to calculate the value of the pull-up

resistor.

VCC Supply Voltage

VCC provides the power supply to the internal core of the memory device. It is the main power supply for all operations

(read,program and erase).

An internal voltage detector disables all functions whenever VCC is below 2.5V (for 3V devices) or 1.5V (for 1.8V

devices) to protect the device from any involuntary program/erase during power-transitions.

Each device in a system should have VCC decoupled with a 0.1uF capacitor. The PCB track widths should be sufficient

to carry the required program and erase currents

VSS Ground

Ground, VSS, is the reference for the power supply. It must be connected to the system ground.

BUS OPERATIONS

There are six standard bus operations that control the memory. Each of these is described in this section, see Tables 2,

Bus Operations, for a summary.

Command Input

Command Input bus operations are used to give commands to the memory. Command are accepted when Chip Enable

is Low, Command Latch Enable is High, Address Latch Enable is Low and Read Enable is High. They are latched on the

rising edge of the Write Enable signal.

Only I/O0 to I/O7 are used to input commands. See Figure 21 and Table 14 for details of the timings requirements.

Address Input

Address Input bus operations are used to input the memory address. Four bus cycles are required to input the

addresses for the 512Mb devices (refer to Tables 3 and 4, Address Insertion). The addresses are accepted when Chip

Enable is Low, Address Latch Enable is High, Command Latch Enable is Low and Read Enable is High. They are latched

on the rising edge of the Write Enable signal. Only I/O0 to I/O7 are used to input addresses.

See Figure 22 and Table 14 for details of the timings requirements.

Data Input

Data Input bus operations are used to input the data to be programmed.

Data is accepted only when Chip Enable is Low, Address Latch Enable is Low, Command Latch Enable is Low and Read

Enable is High. The data is latched on the rising edge of the Write Enable signal. The data is input sequentially using

the Write Enable signal.

See Figure 23 and Tables 14 and 15 for details of the timings requirements.

Rev 0.3 / May. 2004 10

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Data Output

Data Output bus operations are used to read: the data in the memory array, the Status Register, the Electronic Signa-

ture and the Serial Number. Data is output when Chip Enable is Low, Write Enable is High, Address Latch Enable is

Low, and Command Latch Enable is Low. The data is output sequentially using the Read Enable signal.

See Figure 24 and Table 15 for details of the timings requirements.

Write Protect

Write Protect bus operations are used to protect the memory against program or erase operations. When the Write

Protect signal is Low the device will not accept program or erase operations and so the contents of the memory array

cannot be altered. The Write Protect signal is not latched by Write Enable to ensure protection even during power-up.

Standby

When Chip Enable is High the memory enters Standby mode, the device is deselected, outputs are disabled and power

consumption is reduced.

Rev 0.3 / May. 2004 11

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 2. Bus Operation

Note : (1) Only for x16 devices.

(2) WP must be VIH when issuing a program or erase command.

Table 3: Address Insertion, x8 Devices

Note: (1). A8 is set Low or High by the 00h or 01h Command, see Pointer Operations section.

(2). Any additional address input cycles will be ignored.

Table4: Address Insertion, x16 Devices

Note: (1). A8 is Don't Care in x16 devices.

(2). Any additional address input cycles will be ignored.

(3). A1 is the Least Significant Address for x16 devices.

(4). The 01h Command is not used in x16 devices.

BUS Operation CE ALE CLE RE WE WP I/O0 - I/O7I/O8 - I/O15(1)

Command Input VIL VIL VIH VIH Rising X(2) Command X

Address Input VIL VIH VIL VIH Rising X Address X

Data Input VIL VIL VIL VIH Rising X Data Input Data Input

Data Output VIL VIL VIL Falling VIH X Data Output Data Output

Write Protect XXXXXV

IL XX

Standby VIH XXXXX X X

Bus Cycle I/O7I/O6I/O5I/O4I/O3I/O2I/O1I/O0

1st Cycle A7 A6 A5 A4 A3 A2 A1 A0

2nd Cycle A16 A15 A14 A13 A12 A11 A10 A9

3rd Cycle A24 A23 A22 A21 A20 A19 A18 A17

4th Cycle VIL VIL VIL VIL VIL VIL A26 A25

Bus Cycle I/O8-I/

O15

I/O7I/O6I/O5I/O4I/O3I/O2I/O1I/O0

1st Cycle X A7 A6 A5 A4A3A2A1A0

2nd Cycle X A16 A15 A14 A13 A12 A11 A10 A9

3rd Cycle X A24 A23 A22 A21 A20 A19 A18 A17

4th Cycle VIL VIL VIL VIL VIL VIL VIL A26 A25

Rev 0.3 / May. 2004 12

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

COMMAND SET

All bus write operations to the device are interpreted by the Command Interface. The Commands are input on I/O0-I/

O7 and are latched on the rising edge of Write Enable when the Command Latch Enable signal is high. Device opera-

tions are selected by writing specific commands to the Command Register. The two-step command sequences for pro-

gram and erase operations are imposed to maximize data security.

The Commands are summarized in Table 5, Commands.

Table 5: Command Set

Note: (1). Any undefined command sequence will be ignored by the device.

(2). Bus Write Operation(1st, 2nd and 3rd Cycle) : The bus cycles are only shown for issuing the codes. The cycles required to

input the addresses or input/output data are not shown.

DEVICE OPERATIONS

Pointer Operations

As the NAND Flash memories contain two different areas for x16 devices and three different areas for x8 devices (see

Figure 8) the read command codes (00h, 01h, 50h) are used to act as pointers to the different areas of the memory

array (they select the most significant column address).

The Read A and Read B commands act as pointers to the main memory area. Their use depends on the bus width of

the device.

- In x16 devices the Read A command (00h) sets the pointer to Area A (the whole of the main area) that is Words 0

to 255.

- In x8 devices the Read A command (00h) sets the pointer to Area A (the first half of the main area) that is Bytes 0

to 255, and the Read B command (01h) sets the pointer to Area B (the second half of the main area) that is Bytes 256

to 511.

In both the x8 and x16 devices the Read C command (50h), acts as a pointer to Area C (the spare memory area) that

is Bytes 512 to 527 or Words 256 to 263.

FUNCTION 1st CYCLE 2nd CYCLE 3rd CYCLE Command accepted during busy

READ A 00h - -

READ B 01h - -

READ C 50h - -

READ ELECTRINIC SIGNATURE 90h - -

READ STATUS REGISTER 70h - - Yes

PAGE PROGRAM 80h 10h -

COPY BACK PROGRAM 00h 8Ah 10h

CACHE PROGRAM 80h 15h -

BLOCK ERASE 60h D0h -

RESET FFh - - Yes

Rev 0.3 / May. 2004 13

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Once the Read A and Read C commands have been issued the pointer remains in the respective areas until another

pointer code is issued. However, the Read B command is effective for only one operation, once an operation has been

executed in Area B the pointer returns automatically to Area A.

The pointer operations can also be used before a program operation, that is the appropriate code (00h, 01h or 50h)

can be issued before the program command 80h is issued (see Figure 9).

Figure 8. Pointer Operation

Figure 9. Pointer Operations for Programming

Area A

(00h)

Area B

(01h)

Area C

(50h)

Bytes 0-255 Bytes 256-511 Bytes

512-527

A B C

Pointer

(00h, 01h, 50h)

x8 Devices

Page Buffer

Area C

(50h)

Words

256-263

x16 Devices

Page Buffer

Area A

(00h)

Word 0-256

Pointer

(00h, 50h)

10h80h01h Address

Inputs

80h Data

Input 10h Address

Inputs

01h Data

Input

AREA B

AREA B, C can be programmed depending on how much data is input.

The 01h command must be re-issued before each program.

10h80h00h Address

Inputs

80h Data

Input 10h Address

Inputs

00h Data

Input

AREA A

AREA A, B, C can be programmed depending on how much data is input.

Subsequent 00h commands can be omitted.

10h80h50h Address

Inputs

80h Data

Input 10h Address

Inputs

50h Data

Input

AREA C

Only Areas C can be programmed.

Subsequent 50h commands can be omitted.

I/O

Rev 0.3 / May. 2004 14

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Read Memory Array

Each operation to read the memory area starts with a pointer operation as shown in the Pointer Operations section.

Once the area (main or spare) has been selected using the Read A, Read B or Read C commands four bus cycles.

The device defaults to Read A mode after powerup or a Reset operation. Devices, where page0 is read automatically at

power-up, are available on request.

When reading the spare area addresses:

- A0 to A3 (x8 devices)

- A0 to A2 (x16 devices)

are used to set the start address of the spare area while addresses:

- A4 to A7 (x8 devices)

- A3 to A7 (x16 devices)

are ignored.

Once the Read A or Read C commands have been issued they do not need to be reissued for subsequent read opera-

tions as the pointer remains in the respective area. However, the Read B command is effective for only one operation,

once an operation has been executed in Area B the pointer returns automatically to Area A and so another Read B

command is required to start another read operation in Area B.

Once a read command is issued three types of operations are available: Random Read, Page Read and Sequential Row

Read.

Random Read

Each time the command is issued the first read is Random Read.

Page Read

After the Random Read access the page data is transferred to the Page Buffer in a time of tWHBH (refer to Table 15 for

value). Once the transfer is complete the Ready/Busy signal goes High. The data can then be read out sequentially

(from selected column address to last column address) by pulsing the Read Enable signal.

Sequential Row Read

After the data in last column of the page is output, if the Read Enable signal is pulsed and Chip Enable remains Low

then the next page is automatically loaded into the Page Buffer and the read operation continues. A Sequential Row

Read operation can only be used to read within a block. If the block changes a new read command must be issued.

Refer to Figures 12 and 13 for details of Sequential Row Read operations. To terminate a Sequential Row Read opera-

tion set the Chip Enable signal to High for more than tEHEL. Sequential Row Read is not available when the Chip Enable

Don't Care option is enabled.

Rev 0.3 / May. 2004 15

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Note: 1. If tELWL is less than 10ns, tWLWH must be minimum 35ns, otherwise, tWLWH may be minimum 25ns.

Note: 1. Highest address depends on device density.

Figure 10. Read (A, B, C) Operation

Figure 11. Read Block Diagrams

CLE

ALE

I/O

tBLBH1

(read)

00h/

01h/ 50h

Command

Code

Address Input Data Output (sequentially)

Busy

Area A

(1st half Page)

Area B

(2nd half

Page)

Area C

(Spare)

Read A Command, x8 Devices

A9-A26(1)

A0-A7

Area C

(50h)

Read A Command, x16 Devices

Area A

(main area)

A9-A26(1)

A0-A7

Area A Area C

(Spare)

Read C Command, x8/x16 Devices

A9-A26(1)

A0-A3 (x8)

A0-A2 (x16)

Area A/B

A4-A7 (x8), A3-A7 (x16) are don't care

Area A

(1st half Page)

Area C

(Spare)

Read B Command, x8 Devices

A9-A26(1)

A0-A7

Area B

(2nd half

Page)

Rev 0.3 / May. 2004 16

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 12. Sequential Row Read Operation

Figure 13. Sequential Row Read Block Diagrams

Busy Busy Busy

tBLBH1

(Read Busy time) tBLBH1 tBLBH1

Address InputsI/O 00h/

01h/50h

1st

Page Output

2nd

Page Output

Nth

Page Output

Command

Code

Area A

(1st half Page)

Area B Area C

Read A Command, x8 Devices

(2nd half Page) (Spare)

Block 1st Page

2nd Page

Nth Page

Read B Command, x8 Devices

Area A

(1st half Page)

Area B

(2nd half Page)

Area C

(Spare)

Block 1st Page

2nd Page

Nth Page

Area A Area C

(Spare)

Read A Command, x16 Devices

(main area)

1st Page

2nd Page

Nth Page

Block

Area A Area A/B Area C

(Spare)

Read C Command, x8/x16 Devices

1st Page

2nd Page

Nth Page

Block

Area A

(1st half Page)

Area B Area C

Read A Command, x8 Devices

(2nd half Page) (Spare)

Block 1st Page

2nd Page

Nth Page

Area A

(1st half Page)

Area A

(1st half Page)

Area B Area C

Read A Command, x8 Devices

(2nd half Page) (Spare)

Block 1st Page

2nd Page

Nth Page

Block 1st Page

2nd Page

Nth Page

Read B Command, x8 Devices

Area A

(1st half Page)

Area B

(2nd half Page)

Area C

(Spare)

Block 1st Page

2nd Page

Nth Page

Read B Command, x8 Devices

Area A

(1st half Page)

Area A

(1st half Page)

Area B

(2nd half Page)

Area C

(Spare)

Block 1st Page

2nd Page

Nth Page

Block 1st Page

2nd Page

Nth Page

Area A Area C

(Spare)

Read A Command, x16 Devices

(main area)

1st Page

2nd Page

Nth Page

Block

Area A Area C

(Spare)

Read A Command, x16 Devices

(main area)

1st Page

2nd Page

Nth Page

BlockBlock

Area A Area A/B Area C

(Spare)

Read C Command, x8/x16 Devices

1st Page

2nd Page

Nth Page

Block

Area A Area A/B Area C

(Spare)

Read C Command, x8/x16 Devices

1st Page

2nd Page

Nth Page

Block 1st Page

2nd Page

Nth Page

Block

Rev 0.3 / May. 2004 17

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Page Program

The Page Program operation is the standard operation to program data to the memory array. The main area of the

memory array is programmed by page, however partial page programming is allowed where any number of bytes (1 to

528) or words (1 to 264) can be programmed.

The max number of consecutive partial page program operations allowed in the same page is one in the main area and

two in the spare area. After exceeding this a Block Erase command must be issued before any further program opera-

tions can take place in that page.

Before starting a Page Program operation a Pointer operation can be performed to point to the area to be pro-

grammed. Refer to the Pointer Operations section and Figure 9 for details.

Each Page Program operation consists of five steps (see Figure 14):

1. one bus cycle is required to setup the Page Program command

2. four bus cycles are then required to input the program address (refer to Table 3)

3. the data is then input (up to 528 Bytes/ 264 Words) and loaded into the Page Buffer

4. one bus cycle is required to issue the confirm command to start the Program/ Erase/Read Controller.

5. The Program/ Erase/Read Controller then programs the data into the array.

Once the program operation has started the Status Register can be read using the Read Status Register command.

During program operations the Status Register will only flag errors for bits set to '1' that have not been successfully

programmed to '0'.

During the program operation, only the Read Status Register and Reset commands will be accepted, all other com-

mands will be ignored.

Once the program operation has completed the Program/ Erase/Read Controller bit SR6 is set to '1' and the Ready/

Busy signal goes High.

The device remains in Read Status Register mode until another valid command is written to the Command Interface.

Note: Before starting a Page Program operation a Pointer operation can be performed. Refer to Pointer section for details.

Figure 14. Page Program Operation

Address Inputs

I/O

80h

Page Program

Setup Code

Data Input 10h 70h SR0

Confirm

Code

Read Status Register

Busy

tBLBH2

(Program Busy time)

Rev 0.3 / May. 2004 18

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Copy Back Program

The Copy Back Program operation is used to copy the data stored in one page and reprogram it in another page.

The Copy Back Program operation does not require external memory and so the operation is faster and more efficient

because the reading and loading cycles are not required. The operation is particularly useful when a portion of a block

is updated and the rest of the block needs to be copied to the newly assigned block.

If the Copy Back Program operation fails an error is signalled in the Status Register. However as the standard external

ECC cannot be used with the Copy Back operation bit error due to charge loss cannot be detected. For this reason it is

recommended to limit the number of Copy Back operations on the same data and/or to improve the performance of

the ECC.

The Copy Back Program operation requires three steps:

- 1. The source page must be read using the Read A command (one bus write cycle to setup the command and then

4 bus write cycles to input the source page address). This operation copies all 264 Words/ 528 Bytes from the page

into the Page Buffer.

- 2. When the device returns to the ready state (Ready/Busy High), the second bus write cycle of the command is

given with the 4 bus cycles to input the target page address.

A25 & A26

must be the same for the Source and Target

Pages.

- 3. Then the confirm command is issued to start the P/E/R Controller.

After a Copy Back Program operation, a partial page program is not allowed in the target page until the block has been

erased.

See Figure 15 for an example of the Copy Back operation.

Cache Program

The Cache Program operation is used to improve the programming throughput by programming data using the Cache

input while the previous data that was transferred to the Page Buffer is programmed into the memory array.

Before starting a Cache Program operation a Pointer operation is necessary to point to the area to be programmed.

Only the 00h or 50h Pointer operations are valid for the Cache Program operation. Refer to the Pointer Operations sec-

tion and Figure 9 for details. Each Cache Program operation consists of five steps (refer to Figure 16):

1. First of all the program setup command is issued (one bus cycle to issue the program setup command then four bus

Figure 15. Copy Back Operation

Source

Address Inputs

I/O 00h

Copy Back

Code

Target

Address Inputs

8Ah 10h 70h

Read

Code Read Status Register

SR0

Busy

tBLBH2

(Program Busy time)

tBLBH1

(Read Busy time)

Rev 0.3 / May. 2004 19

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

write cycles to input the address), the data is then input (up to 528 Bytes/ 264 Words) and loaded into the Cache Reg-

ister.

2. One bus cycle is required to issue the confirm command to start the P/E/R Controller.

3. The P/E/R Controller then transfers the data to the Page Buffer. During this the device is busy for a time of tBLBH5.

4. Once the data is loaded into the Page Buffer the P/E/R Controller programs the data into the memory array. As soon

as the Cache Registers are empty (after tBLBH5) a new Cache program command can be issued, while the internal pro-

gramming is still executing. Once the program operation has started the Status Register can be read using the Read

Status Register command. During Cache Program operations SR5 can be read to find out whether the internal pro-

gramming is ongoing (SR5 = '0') or has completed (SR5 = '1') while SR6 indicates whether the Cache Register is ready

to accept new data. If any errors have been detected on the previous page (Page N-1), the Cache Program Error Bit

SR1 will be set to '1', while if the error has been detected on Page N the Error Bit SR0 will be set to '1'. When the next

page ( Page N) of data is input with the Cache Program command, tBLBH5 is affected by the pending internal program-

ming. The data will only be transferred from the Cache Register to the Page Buffer when the pending program cycle is

finished and the Page Buffer is available. If the system monitors the progress of the operation using only the Ready/

Busy signal, the last page of data must be programmed with the Page Program confirm command (10h).

If the Cache Program confirm command (15h) is used instead, Status Register bit SR5 must be polled to find out if the

last programming is finished before starting any other operations.

Note: (1). tX is a fraction of the Program Busy Time and is less than tBLBH2.

(2). Up to 32 pages can be programmed in one Cache Program operation.

Block Erase

Erase operations are done one block at a time. An erase operation sets all of the bits in the addressed block to '1'. All

previous data in the block is lost. An erase operation consists of three steps (refer to Figure 17):

1. One bus cycle is required to setup the Block Erase command.

2. Only three bus cycles for the devices are required to input the block address. The first cycle (A0 to A7) is not

required as only addresses A14 to A26 (highest address depends on device density) are valid, A9 to A13 are ignored.

In the last address cycle I/O0 to I/O7 must be set to VIL.

3. One bus cycle is required to issue the confirm command to start the P/E/R Controller.

Figure 16. Cashe Program Operation

Page

Program

Code

Cache

Program

Code

Cache Program

Confirm Code

Page

Program

Code

Page

Program

Confirm Code

Read Status

First Page Last Page

Second Page

(can be repeated up to 30 times)

BusyBusy Busy

tBLBH5

(Cache Busy time)

(1)

+tBLBH5 tX

(1)

+tBLBH5+tBLBH2

(Program Busy Time)

80h 15h

Data

Input 15h

Input

Address

80h Input

Address

80h Data

Input 10h 70h

Input

Address SR0

Data

Input

I/O

Rev 0.3 / May. 2004 20

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Once the erase operation has completed the Status Register can be checked for errors.

Reset

The Reset command is used to reset the Command Interface and Status Register. If the Reset command is issued dur-

ing any operation, the operation will be aborted. If it was a program or erase operation that was aborted, the contents

of the memory locations being modified will no longer be valid as the data will be partially programmed or erased.

If the device has already been reset then the new Reset command will not be accepted. The Ready/Busy signal goes

Low for tBLBH4 after the Reset command is issued. The value of tBLBH4 depends on the operation that the device was

performing when the command was issued, refer to Table 15 for the values.

Read Status Register

The device contains a Status Register which provides information on the current or previous Program or Erase opera-

tion. The various bits in the Status Register convey information and errors on the operation.

The Status Register is read by issuing the Read Status Register command. The Status Register information is present

on the output data bus (I/O0- I/O7) on the falling edge of Chip Enable or Read Enable, whichever occurs last. When

several memories are connected in a system, the use of Chip Enable and Read Enable signals allows the system to poll

each device separately, even when the Ready/Busy pins are common-wired. It is not necessary to toggle the Chip

Enable or Read Enable signals to update the contents of the Status Register.

After the Read Status Register command has been issued, the device remains in Read Status Register mode until

another command is issued. Therefore if a Read Status Register command is issued during a Random Read cycle a

new read command must be issued to continue with a Page Read or Sequential Row Read operation.

The Status Register bits are summarized in Table 6, Status Register Bits. Refer to Table 6 in conjunction with the fol-

lowing text descriptions.

Write Protection Bit (SR7)

The Write Protection bit can be used to identify if the device is protected or not. If the Write Protection bit is set to '1'

the device is not protected and program or erase operations are allowed. If the Write Protection bit is set to '0' the

device is protected and program or erase operations are not allowed.

Figure 17. Block Erase Operation

Block Address

Inputs

I/O 60h

Confirm

Code

D0h SR0

Block Erase

Setup Code

Busy

tBLBH3

(Erase Busy time)

70h

Read Status Register

Rev 0.3 / May. 2004 21

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

P/E/R Controller and Cache Ready/Busy Bit (SR6)

Status Register bit SR6 has two different functions depending on the current operation.

During Cache Program operations SR6 acts as a Cache Program Ready/Busy bit, which indicates whether the Cache

Cache Register is ready to accept new data.

During all other operations SR6 acts as a P/E/R Controller bit, which indicates whether the P/E/R Controller is active or

inactive. When the P/E/R Controller bit is set to '0', the P/E/R Controller is active (device is busy); when the bit is set

to '1', the P/E/R Controller is inactive (device is ready).

P/E/R Controller Bit (SR5)

The Program/Erase/Read Controller bit indicates whether the P/E/R Controller is active or inactive. When the P/E/R

Controller bit is set to '0', the P/E/R Controller is active (device is busy); when the bit is set to '1', the P/E/R Controller

is inactive (device is ready).

Cache Program Error Bit (SR1)

The Cache Program Error bit can be used to identify if the previous page (page N-1) has been successfully programed

or not in a Cache Program operation. SR1 is set to '1' when the Cache Program operation has failed to program the

previous page (page N-1) correctly. If SR1 is set to '0' the operation has completed successfully.

The Cache Program Error bit is only valid during Cache Program operations, during other operations it is Don't Care.

Error Bit (SR0)

The Error bit is used to identify if any errors have been detected by the P/E/R Controller. The Error Bit is set to '1' when

a program or erase operation has failed to write the correct data to the memory. If the Error Bit is set to '0' the opera-

tion has completed successfully. The Error Bit SR0, in a Cache Program operation, indicates a failure on Page N.

SR4, SR3 and SR2 are Reserved

Rev 0.3 / May. 2004 22

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 6: Status Register Bit

Note: (1). The SR6 bit and SR0 bit have a different meaning during Cache Program operations.

(2). Only valid for Cache Program operations, for other operations it is same as SR6.

(3). Only valid for Cache Program operations, for other operations it is Don't Care.

Read Electronic Signature

The device contains a Manufacturer Code and Device Code. To read these codes two steps are required:

1. first use one Bus Write cycle to issue the Read Electronic Signature command (90h)

2. then subsequent Bus Read operations will read the Manufacturer Code and the Device Code until another command

is issued.

Refer to Table, Read Electronic Signature for information on the addresses.

Automatic Page 0 Read at Power-Up

Automatic Page 0 Read at Power-Up is an option available on all devices belonging to the NAND Flash 528 Byte/264

Word Page family. It allows the microcontroller to directly download boot code from page 0, without requiring any

command or address input sequence. The Automatic Page 0 Read option is particularly suited for applications that

boot from the NAND.

Devices delivered with Automatic Page 0 Read at Power-Up can have the Sequential Row Read option either enabled

or disabled.

Bit NAME Logic Level Definition

SR7 Write Protection

'1' Not Protected

'0' Protected

SR6(1)

Program/Erase/Read

Controller

'1' P/E/R C Inactive, device ready

'0' P/E/R C active, device busy

Cache Read/Busy

'1' Cache Register ready (Cache Program only)

'0' Cache Register busy (Cache Program only)

SR5 Program/ Erase/ Read

Controller(2)

'1' P/E/R C inactive, device ready

'0' P/E/R C active, device busy

SR4, SR3, SR2 Reserved Don't Care

SR1 Cache Program Error(3) '1' Page N-1 failed in Cache Program operation

'0' Page N-1 programmed successfully

SR0(1)

Generic Error

'1' Error - Operation failed

'0' No Error - Operation successful

Cache Program Error

'1' Page N failed in Cache Program operation

'0' Page N programmed successfully

Part Number Manufacture Code Device Code Bus Width

HY27(U/S)A081G1M ADh 79h x8

HY27(U/S)A161G1M 00ADh 0074h x16

Rev 0.3 / May. 2004 23

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Automatic Page 0 Read Description.

At powerup, once the supply voltage has reached the threshold level, VCCth, all digital outputs revert to their reset

state and the internal NAND device functions (reading, writing, erasing) are enabled.

The device then automatically switches to read mode where, as in any read operation, the device is busy for a time

tBLBH1 during the data is transferred to the Page Buffer. Once the data transfer is complete the Ready/Busy signal goes

High. The data can then be read out sequentially on the I/O bus by pulsing the Read Enable, RE, signal. Figures 18

and 19 show the power-up waveforms for devices featuring the Automatic Page 0 Read option.

Sequential Row Read Disabled

If the device is delivered with Sequential row read disabled and Automatic Read Page 0 at Power-up, only the first

page (Page 0) will be automatically read after the power-on sequence. Refer to Figure 18.

Sequential Row Read Enabled

If the device is delivered with the Automatic Page 0 Read option only (Sequential Row Read Enable), the device will

automatically enter Sequential Row Read mode after the power-up sequence, and start reading Page 0, Page 1, etc.,

until the last memory location is reached, each new page being accessed after a time tBLBH1.

The Sequential Row Read operation can be inhibited or interrupted by de-asserting E (set to VIH) or by issuing a com-

mand. Refer to Figure 19.

Note: (1). VCCth is equal to 2.5V for 3V Power Supply devices.

Figure 18. Sequential Row Read Disabled and Automatic Page 0 Read at power-up

Data

N+1

Data

Last

Data

N+2

tBLBH1

Busy

Vccth (1)

Vcc

ALE

CLE

I/O

Data Output

from Address N to Last Byte or Word in Page

Rev 0.3 / May. 2004 25

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Bad Block Management

Devices with Bad Blocks have the same quality level and the same AC and DC characteristics as devices where all the

blocks are valid. A Bad Block does not affect the performance of valid blocks because it is isolated from the bit line and

common source line by a select transistor.

The devices are supplied with all the locations inside valid blocks erased (FFh). The Bad Block Information is written

prior to shipping. Any block where the 6th Byte/ 1st Word in the spare area of the 1st or 2nd page (if the 1st page is

Bad) does not contain FFh is a Bad Block.

The Bad Block Information must be read before any erase is attempted as the Bad Block Information may be erased.

For the system to be able to recognize the Bad Blocks based on the original information it is recommended to create a

Bad Block table following the flowchart shown in Figure 20.

Block Replacement

Over the lifetime of the device additional Bad Blocks may develop. In this case the block has to be replaced by copying

the data to a valid block.

These additional Bad Blocks can be identified as attempts to program or erase them will give errors in the Status Reg-

ister.

As the failure of a page program operation does not affect the data in other pages in the same block, the block can be

replaced by re-programming the current data and copying the rest of the replaced block to an available valid block.

The Copy Back Program command can be used to copy the data to a valid block.

See the “Copy Back Program” section for more details.

Refer to Table 7 for the recommended procedure to follow if an error occurs during an operation.

Table 7: Block Failure

Operation Recommended Procedure

Erase Block Replacement

Program Block Replacement or ECC

Read ECC

Note: (1). VCCth is equal to 2.5V for 3V Power Supply devices.

Figure 19. Automatic Page 0 Read at power-up (Sequential Row Read Enable)

Vccth(1)

Vcc

ALE

CLE

I/O

tBLBH1

(Read Busy time)

Busy Busy Busy Busy

tBLBH1 tBLBH1 tBLBH1

Page 0

Data Out

Page 1

Data Out

Page 2

Data Out

Page Nth

Data Out

Rev 0.3 / May. 2004 26

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

System Interface Using CE don’t care

To simplify system interface, CE may be deasserted during data loading or sequential data-leading as shown below. So, it is possible

to connect NAND Flash to a microprocessor. The only function that was removed from standard NAND Flash to make CE don't care

read operation was disabling of the automatic sequential read function.

Figure 32. Program Operation with CE don’t-care.

Figure 33. Read Operation with CE don’t-care.

CLE

ALE

I/Ox

CE don't-care

00h Start Add(4Cycle) Data Output(sequential)

R/B

If sequential row read enabled,

CE must be held low during tR.

CLE

CE don't-care

ALE

80h Start Add(4Cycle) Data Input Data Input 10h

I/Ox

Rev 0.3 / May. 2004 27

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 8: Valid Block

PROGRAM AND ERASE TIMES AND ENDURANCE CYCLES

The Program and Erase times and the number of Program/ Erase cycles per block are shown in Table 9.

Symbol Para. Min Max Unit

NVB # of Valid Block 8052 8192 Blocks

Figure 20. Bad Block Management Flowchart

START

Block Address=

Block 0

Data

=FFh?

Last

block?

END

Update

Bad Block table

Increment

Block Address

YES

Rev 0.3 / May. 2004 28

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 9: Program, Erase Time and Program Erase Endurance Cycles

MAXIMUM RATING

Stressing the device above the ratings listed in Table 10, Absolute Maximum Ratings, may cause permanent damage to

the device. These are stress ratings only and operation of the device at these or any other conditions above those indi-

cated in the Operating sections of this specification is not implied. Exposure to Absolute Maximum Rating conditions

for extended periods may affect device reliability.

Table 10: Absolution Maximum Rating

Note: (1). Minimum Voltage may undershoot to -2V for less than 20ns during transitions on input and I/O pins. Maximum voltage

may overshoot to VCC + 2V for less than 20ns during transitions on I/O pins.

DC AND AC PARAMETERS

This section summarizes the operating and measurement conditions, and the DC and AC characteristics of the device.

The parameters in the DC and AC characteristics Tables that follow, are derived from tests performed under the Mea-

surement Conditions summarized in Table 11, Operating and AC Measurement Conditions. Designers should check that

the operating conditions in their circuit match the measurement conditions when relying on the quoted parameters.

Parameters

NAND Flash

Unit

Min Typ Max

Page Program Time 200 500 us

Block Erase Time 2 3 ms

Program/Erase Cycles (per block) 100,000 cycles

Data Retention 10 years

Symbol Parameter

NAND Flash

Unit

Min Max

TBIAS Temperature Under Bias -50 125 oC

TSTG Storage Temperature -65 150 oC

VIO(1) Input or Output Voltage

1.8V devices -0.6 2.7 V

3.3 V devices -0.6 4.6 V

VCC Supply Voltage

1.8V devices -0.6 2.7 V

3.3 V devices -0.6 4.6 V

Rev 0.3 / May. 2004 29

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 11: Operating and AC Measurement Conditions

Note : (1). TBD

Table 12: Capacitance

Note: TA = 25oC, f = 1 MHz. CIN and CI/O are not 100% tested.

Parameter

NAND Flash

Unit

Min Max

Supply Voltage (VCC)

1.8V devices(1) 1.7 1.95 V

2.6V devices(1) 2.4 2.8 V

3.3V devices 2.7 3.6 V

Ambient Temperature (TA)

Commercial Temp. 0 70 oC

Indurstrial Temp. -40 85 oC

Load Capacitance (CL) (1 TTL GATE and CL)

1.8V devices(1) 30 pF

2.6V devices(1) 30 pF

3.3V devices 100 pF

Input Pulses Voltages

1.8V devices(1) 0V

CC V

2.6V devices(1) 0V

CC V

3.3V devices 0.4 2.4 V

Input and Output Timing Ref. Voltages

1.8V devices(1)

VCC/2

2.6V devices(1) V

3.3V devices 1.5 V

Input Rise and Fall Times 5 ns

Symbol Parameter Test Condition Typ Max Unit

CIN Input Capacitance VIN = 0V 10 pF

CI/O Input/Output Capacitance VIL = 0V 10 pF

Rev 0.3 / May. 2004 30

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 13: DC Characteristics, 3.3V Device and 1.8V Device

Symbol Parameter Test Condition

3.3V 1.8V

Unit

Min Typ Max Min Typ Max

ICC1

Operating

Current

Sequential Read tRLRL minimum

CE=VIL, IOUT = 0 mA - 15 30 - 10 20 mA

ICC2 Program - - 15 30 - 10 20 mA

ICC3 Erase - - 15 30 - 10 20 mA

ICC4 Stand-by Current (TTL) CE=VIH, WP=0V/

VCC

-- 1 - - 1 mA

ICC5 Stand-By Current (CMOS) CE=VCC-0.2, WP=0/

VCC

- 20 100 - 20 100 uA

ILI Input Leakage Current VIN= 0 to VCCmax - - ±20 - - ±20 uA

ILO Output Leakage Current VOUT= 0 to VCCmax - - ±20 - - ±20 uA

VIH Input High Voltage - 2.0 - VCC+0.3 VCC+0.4 VCC+0.3 V

VIL Input Low Voltage - -0.3 - 0.8 -0.3 0.4 V

VOH Output High Voltage Level IOH = -400uA 2.4 - - VCC-0.1 - - V

VOL Output Low Voltage Level IOL = 2.1mA - - 0.4 - - 0.1 V

IOL(RB) Output Low Current (RB) V

OL = 0.1V 8 10 - 3 4 - mA

VLKO

VDD Supply Voltage

(Erase and Program lockout) ---2.5--1.5V

Rev 0.3 / May. 2004 31

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 14: AC Characteristics for Command, Address, Data Input (3.3V Device and 1.8V Device)

Note 1: If tELWL is less than 10ns, tWLWH must be minimum 35ns, otherwise, tWLWH may be minimum 25ns.

Symbol Alt.

Symbol Parameter 3.3V

Device

1.8V

Device Unit

tALLWL

tALS

Address Latch Low to Write Enable Low

ALE Setup time Min 0 ns

tALHWL Address Latch Hith to Write Enable Low

tCLHWL

tCLS

Command Latch High to Write Enable Low

CL Setup time Min 0 ns

tCLLWL Command Latch Low to Write Enable Low

tDVWH tDS Data Valid to Write Enable High Data Setup time Min 20 ns

tELWL tCS Chip Enable Low to Write Enable Low CE Setup time Min 0 ns

tWHALH

tALH

Write Enable High to Address Latch High

ALE Hold time Min 10 ns

tWHALL Write Enable High to Address Latch Low

tWHCLH

tCLH

Write Enable High to Command Latch High

CLE hold time Min 10 ns

tWHCLL Write Enable High to Command Latch Low

tWHDX tDH Write Enable High to Data Transition Data Hold time Min 10 ns

tWHEH tCH Write Enable High to Chip Enable High CE Hold time Min 10 ns

tWHWH tWH Write Enable High to Write Enable Low WE High Hold

time Min 15 20 ns

tWLWH tWP Write Enable Low to Write Enable High WE Pulse Width Min 40 60 ns

tWLWL tWC Write Enable Low to Write Enable Low Write Cycle time Min 60 80 ns

Rev 0.3 / May. 2004 32

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 15: AC Characteristics for Operation (3.3V Device and 1.8V Device)

Alt.

Symbol Symbol Parameter 3.3V

Device

1.8V

Device Unit

tALLRL1 tAR1 Address Latch Low to

Read Enable Low

Read Electronic Signature Min 10 25 ns

tALLRL2 tAR2 Read cycle Min 50 80 ns

tBHRL tRR Ready/Busy High to Read Enable Low Min 20 ns

tBLBH1 tR

Ready/Busy Low to

Ready/Busy High

1Gb : Dual Die Max 12 15 us

tBLBH2 tPROG Program Busy time Max 500 us

tBLBH3 tBERS Erase Busy time Max 3 ms

tBLBH4 tRST

Reset Busy time, during ready Max 5 us

Reset Busy time, during read Max 5 us

Reset Busy time, during program Max 10 us

Reset Busy time, during erase Max 500 us

tBLBH5 tCBSY Cache Busy time

Typ 3 us

Max 500 us

tCLLRL tCLR Command Latch Low to Read Enable Low Min 10 ns

tDZRL tIR Data Hi-Z to Read Enable Low Min 0 ns

tEHBH tCRY Chip Enable High to Ready/Busy High (CE intercepted read) Max 60+tr(1) ns

tEHEL tCEH Chip Enable High to Chip Enable Low(2) Min 100 ns

tEHQZ tCHZ Chip Enable High to Output Hi-Z Max 20 ns

tELQV tCEA Chip Enable Low to Output Valid Max 45 75 ns

tRHBL tRB

Read Enable High to

Ready/Busy Low

Max 100 ns

tRHRL tREH

Read Enable High to

Read Enable Low Read Enable High Hold time Min 15 20 ns

tRHQZ tRHZ

Read Enable High to

Output Hi-Z

Min 15

Max 30

tRLRH tRP

Read Enable Low to

Read Enable High

Read Enable Pulse Width Min 40 60 ns

tRLRL tRC

Read Enable Low to

Read Enable Low Read Cycle time Min 60 80 ns

Rev 0.3 / May. 2004 33

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Note: (1). The time to Ready depends on the value of the pull-up resistor tied to the Ready/Busy pin. See Figures 32, 33 and 34.

(2). To break the sequential read cycle, CE must be held High for longer than tEHEL.

(3). ES = Electronic Signature.

tRLQV

tREA Read Enable Low to

Output Valid

Read Enable Access time

Max

35 60

tREADID Read ES(3) Access time 45 60

tWHBH tRWrite Enable High to Ready/Busy High Max 12 15 us

tWHBL tWB Write Enable High to Ready/Busy Low Max 100 ns

tWHRL tWHR Write Enable High to Read Enable Low Min 60 ns

tWLWL tWC

Write Enable Low to

Write Enable Low Write Cycle time Min 60 80 ns

Alt.

Symbol Symbol Parameter 3.3V

Device

1.8V

Device Unit

Figure 21. Command Latch AC Waveforms

Command

tCLHWL

(CLE Setup time)

tHWCLL

(CLE Hold time)

tELWL

(CE Setup time)

tWHEH

(CE Hold time)

tWLWH

tALLWL

(ALE Setup time)

tWHALH

(ALE Hold time)

tDVWH

(Data Setup time)

tWHDX

(Data Hold time)

CLE

ALE

I/O

Rev 0.3 / May. 2004 34

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 22. Address Latch AC Waveforms

Figure 23. Data Input Latch AC Waveforms

I/O

CLE

ALE

Address

cycle 1

Address

cycle 3

Address

cycle 2

Address

cycle 4

tCLLWL

(CLE Setup time)

tELWL

(CE Setup time)

tWLWL tWLWL tWLWL

tWLWH tWLWH tWLWH tWLWH

tALHWL

(ALE Setup time)

tWHWL tWHWL tWHWL

tWHALL

(ALE Hold time)

tWHALL tWHALL

tDVWH

(Data Setup time)

tDVWH tDVWH tDVWH

tWHDX

(Data Hold time)

tWHDX tWHDX tWHDX

I/O

Data In 0 Data In 1 Data In

Last

tWHCLH

(CLE Hold time)

tWHEH

(CE Hold time)

tWLWH

tWLWL

tALLWL

(ALE Setup time)

tWLWHtWLWH

tDVWH

(Data Setup time)

tDVWH tDVWH

tWHDX

(Data Hold time)

tWHDX tWHDX

CLE

ALE

Rev 0.3 / May. 2004 35

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Note:1. CLE = Low, ALE = Low, WE = High.

Figure 24. Sequential Data Output after Read AC Waveforms

Figure 25. Read Status Register AC Waveform

I/O

Data Out Data Out Data Out

tRLRL

(Read Cycle time)

tEHQZ

tRHQZ

tRLQV

tRHQZ

tRLQV

tBHRL

tRHRL

(RE High Holdtime)

tRLQV

(RE Accesstime)

I/O

CLE

Status Register

Output

70h

tCLLRL

tWHCLL

tWHEH

tCLHWL

tELWL tWLWH

tELQV

tWHRL

tEHQZ

tRHQZtRLQV

tDZRL

tDVWH

(Data Setup time)

tWHDX

(Data Hold time)

Rev 0.3 / May. 2004 36

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Note: Refer to table(To see Page 21) for the values of the manufacture and device codes.

Figure 26. Read Electronic Signature AC Waveform

Figure 27. Read Read A/ Read B Operation AC Waveform

I/O

Man.

code

90h Device

code

Don't

Care

Don't

Care

00h

ALE

CLE

Read Electronic

Signature Command

1st Cycle

Address

Manufacturer and

Device Code

Reserved For

Future Use

tALLRL1

tRLQV

(Read ES Access time)

I/O

ALE

CLE

Busy Data Output

from Address N to Last Byte or Word in Page

Data

Add.N

cycle 1

Add.N

cycle 2

Add.N

cycle 3

Add.N

cycle 4

00h or

01h

Data

N+1

Data

N+2

Data

Last

Address N Input

Command

Code

tEHEL

tWHWL

tWHBL

tWHBH

tALLRL2 tRLRL

(Read Cycle time)

tRHQZ

tRHBL

tRLRH

tBLBH1

tEHQZ

tEHBH

Rev 0.3 / May. 2004 37

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Note: 1. A0-A7 is the address in the Spare Memory area, where A0-A3 are valid and A4-A7 are don't care.

2. Only address cycle 4 is required.

Figure 28. Read C Operation, One Page AC Waveform

I/O

CLE

ALE

Add. M

cycle 1

50h Data M

Add. M

cycle 2

Add. M

cycle 3

Add. M

cycle 4

Data

Last

tWHBH

tWHALL

tBHRL

tALLRL2

Command

Code Address M Input

Busy

Data Output from M to

Last Byte or Word in Area C

Rev 0.3 / May. 2004 38

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 29. Page Program AC Waveform

I/O

CLE

ALE

Last 10h 70h SR0

tWLWL

(Write Cycle time)

tWLWL tWLWL

tWHBL

tBLBH2

(Program Busy time)

Address Input Data Input Confirm

Code

Page

Program

Read Status

80h

Add. N

cycle 1

Add. N

cycle 2

Add. N

cycle 3

Page Program

Setup Code

Rev 0.3 / May. 2004 39

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 30. Block Erase AC Waveform

Figure 31. Reset AC Waveform

I/O

CLE

ALE

70h SR060h Add. N

cycle 1

Add. N

cycle 2

Add. N

cycle 3 D0h

tBLBH3

(Erase Busy time)

tWLWL

(Write Cycle time)

Block Erase

Setup Command Block Address Input Confirm

Code Block Erase Read Status Register

FFh

tBLBH4

(Reset Busy time)

ALE

I/O

CLE

Rev 0.3 / May. 2004 40

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

System Interface Using CE don’t care

To simplify system interface, CE may be deasserted during data loading or sequential data-reading as shown below. So, it is possible

to connect NAND Flash to a microprocessor. The only function that was removed from standard NAND Flash to make CE don't care

read operation was disabling of the automatic sequential read function.

Figure 32. Program Operation with CE don’t-care.

Figure 33. Read Operation with CE don’t-care.

CLE

ALE

I/Ox

CE don't-care

00h Start Add(4Cycle) Data Output(sequential)

R/B

If sequential row read enabled,

CE must be held low during tR.

CLE

CE don't-care

ALE

80h Start Add(4Cycle) Data Input Data Input 10h

I/Ox

Rev 0.3 / May. 2004 41

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Ready/Busy Signal Electrical Characteristics

Figures 32, 33 and 34 show the electrical characteristics for the Ready/Busy signal. The value required for the resistor

RP can be calculated using the following equation:

where IL is the sum of the input currents of all the devices tied to the Ready/Busy signal. RP max is determined by the

maximum value of tr.

Figure 32. Ready/Busy AC Waveform

Figure 34. Ready/Busy Load Circuit

ready

Vcc

trtf

busy

Vcc

Device

Vss

ibusy

Open Drain Output

Rev 0.3 / May. 2004 42

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

* Application Note

Reset command must be issued when the controller writes data to another 512Mb.(i.e. When A26 is changed

during program.)

Figure 35. Resistor Value Waveform Timings for Ready/Busy Signal

400

300

200

100

1234

1.7

1.7 1.7

1.7

30 60

120

0.85

0.57 0.43

Vcc=1.8, CL=30pF

Rp(KΩ)

tr, tf(ns)

ibusy(mA)

400

300

200

100

1234

3.6

3.6 3.6

2.4

3.6

100 1.2

0.8

400

200

300

0.6

Vcc=3.3, CL=100pF

Rp(KΩ)

tr, tf(ns)

ibusy(mA)

tf ibus

Rev 0.3 / May. 2004 43

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 16: 48-TSOP1 - 48-lead Plastic Thin Small Outline, 12 x 20mm, Package Mechanical Data

Symbol

millimeters inches

Min Typ Max Min Typ Max

A 1.200 0.0472

A1 0.050 0.100 0.150 0.0020 0.0039 0.0059

A2 0.950 1.000 1.050 0.0374 0.0394 0.0413

B 0.170 0.220 0.270 0.0067 0.0087 0.0106

C 0.100 0.210 0.0039 0.0083

CP 0.080 0.0031

D1 11.900 12.000 12.100 0.4685 0.4724 0.4764

E 19.800 20.000 20.200 0.7795 0.7874 0.7953

E1 18.300 18.400 18.500 0.7205 0.7244 0.7283

e - 0.500 - - 0.0197 -

L 0.500 0.600 0.700 0.0197 0.0236 0.0276

L1 - 0.800 - - 0.0315 -

alpha035035

Figure 36. 48-TSOP1 - 48-lead Plastic Thin Small Outline, 12 x 20mm, Package Outline

Rev 0.3 / May. 2004 44

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Table 17: 48-WSOP1- 48-lead Plastic Thin Small Outline, 12 x 17mm, Package Mechanical Data

Symbol millimeters inches

Min Typ Max Min Typ Max

A 0.70 0.0276

A2 0.540 0.580 0.620 0.0213 0.0229 0.0244

A3 0.10 0.0039

B 0.170 0.200 0.270 0.0067 0.0079 0.0106

B1 0.130 0.160 0.230 0.0051 0.0063 0.0091

C 0.065 0.10 0.135 0.0026 0.0039 0.0053

C1 0.45 0.75 0.018 0.0300

D 16.80 17.00 17.20 0.6619 0.6698 0.6777

D1 11.90 12.00 12.10 0.4689 0.4728 0.4767

E 15.30 15.40 15.50 0.6028 0.6068 0.6107

e 0.44 0.50 0.56 0.0173 0.0197 0.0221

alpha 0 8 0 8

Figure 37. 48-WSOP1 - 48-lead Plastic Very Very Thin Small Outline, 12 x 17mm, Package Outline

WTSOP1

TOP View

WTSOP1 SIDE View

Angle=alpha

WTSOP1 SIDE View

WTSOP1

TOP View

WTSOP1 SIDE View

Angle=alpha

WTSOP1 SIDE View

Rev 0.3 / May. 2004 45

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

Figure 38. 63-FBGA - 8.5 x 15mm, 6 x 8 ball array 0.8mm pitch, Pakage Outline

Note: Drawing is not to scale.

Rev 0.3 / May. 2004 46

Preliminary

HY27UA(08/16)1G1M Series

HY27SA(08/16)1G1M Series

1Gbit (128Mx8bit / 64Mx16bit) NAND Flash

MARKING INFORMATION

Packag Marking Example

TSOP1

WSOP1

FBGA

K O R

H Y 2 7 x A x x 1 G 1 M

x x x x Y W W x x

- hynix

- KOR

- HY27xAxx121mTxB

HY:

HYNIX

27:

NAND Flash

Power Supply

Classification

xx:

Bit Organization

1G:

Density

Mode

Version

Package Type

Package Material

Operating Temperature

Bad Block

- Y:

Year (ex: 4=year 2004, 05= year 2005)

- ww:

Work Week (ex: 12= work week 12)

- xx:

Process Code

Note

- Capital Letter

- Small Letter

: Hynix Symbol

: Origin Country

: U(2.7V~3.6V), S(1.7V~2.2V)

: Single Level Cell+Double Die

: 08(x8), 16(x16)

: 1Gb

: 1nCE & 1R/nB; CE don't care

: 1st Generation

: T(TSOP1), V(WSOP1), F(FBGA)

: Blank(Normal), P(Lead Free)

: C(0

℃

~70

℃

), E(-25

℃

~85

℃

)

I(-40

℃

~85

℃

)

: B(Included Bad Block), S(1~5 Bad Block),

P(All Good Block)

: Fixed Item

: Non-fixed Item

: Part Number