Datasheet M29W004B, M29W004T Datasheet (SGS Thomson Microelectronics)

Low Voltage Single Supply Flash Memory

M29W004T and M29W004B are replaced
respectively by the M29W004BT and
M29W004BB

2.7 to 3.6V SUPPLY VOLTAGE for
PROGRAM, ERASE and READ OPERATIONS

FAST A CCES S TIME : 100ns
FAST PROGRAMMING TIME: 10µs typical
PROGRAM/ERASE CONTROLLER (P/E.C.)
– Program Byte-by-Byte
– Status Register bits and Ready/Busy Output
MEMOR Y BLOCKS
– Boot Block (Top or Bottom location)
– Parameter and Main blocks
BLOCK, MULTI-BLOCK and CHIP ERASE
MULTI BLOCK PROTECTION/TEMPORARY

UNPROTECTION MODES
ERASE SUSPEND and RESUME MOD ES
– Read and Program another Block during

Erase Suspend
LOW POWER CONSUMPTION
– Stand-by and Automatic Stand-by
100,000 PROGRAM/ERASE CYCLES per

BLOCK
20 YEARS DA TA RETE NT ION
– Defectivity below 1ppm/year
ELECTRONIC SIGNATURE
– Manufacturer Code: 20h
– Device Code, M29W004T: EAh
– Device Code, M29W004B: EBh

DESCRIPTION

The M29W004 is a non-volatile memory that may
be erased electrically at the block or chip level and
programmed in-system on a Byte-by-Byte basis
using only a single 2.7V to 3.6V V
Program and Erase operations the necessary high
voltages are generated internally. The device can
also be programmed in standard programmers.

The array matrix organisation allows each block to
be erased and reprogrammed without affecting
other blocks. Blocks can be protected against pro­graming and erase on programming equipment,
and temporarily unprotected to make changes in

supply. For

CC

M29W004T

M29W004B

4 Mbit (512Kb x8, Boot Block)

NOT FOR NEW DESIGN

TSOP40 (N)

10 x 20 mm

Figure 1. Logic Diagram

V

CC

A0-A18

W

RP

19

E

G

M29W004T
M29W004B

V

SS

8

DQ0-DQ7

RB

AI02063

June 1999 1/30

This is information on a product still in production but not recommended for new designs.

M29W004T, M29W004B

Figure 2. TSOP Pin Connections

A16
A15
A14
A13
A12
A11

A9
A8

W
RP
NC
RB

A18

A6
A5
A4
A3
A2
A1

Warning:

NC = Not Connected.

DESCRIPTION

1

M29W004T

10

M29W004B

11

20 21

AI02064

(Cont’d)

40

31
30

A17
V

SS

NC
NC
A10
DQ7
DQ6
DQ5
DQ4
V

CC

V

CC

NC
DQ3
DQ2A7
DQ1
DQ0
G
V

SS

E
A0

the application. Each block can be programmed
and erased over 100,000 cycles.

Instructions for Read/Reset, Auto Select for read­ing the Electronic Signature or Block Protection
status, Programming, Block and Chip Erase, Erase
Suspend and Resume are written t o the device in

Tabl e 1. Signal Names

A0-A18 Address Inputs
DQ0-DQ7 Data Input/Outputs, Command Inputs
E Chip Enable
G Output Enable
W Write Enable
RP Reset / Block Temporary Unprotect

B Ready/Busy Output

R
V

CC

V

SS

Supply Voltage
Ground

cycles of commands to a Command Interface using
standard microprocessor write timings.

The device is offered in TSOP40 (10 x 20mm)
package.

Organisation

The M29W004 is organised as 512K x8. The mem­ory uses the address inputs A0-A18 and the Data
Input/Outputs DQ0-DQ7. Memory control is pro­vided by Chip Enable
Enable

W inputs.

A Reset/Block T emporary Unprotection

E, Output Enable G and Write

RP tri-level
input provides a hardware reset when pulled Low,
and when held High (at V

) temporarily unprotects

ID

blocks previously protected allowing them to be
programed and erased. Erase and Program opera­tions are controlled by an internal Program/Erase
Controller (P/E.C.). Status Register data output on
DQ7 provides a Data Polling signal, and DQ6 and
DQ2 provide Toggle signals to indicate the state of
the P/E.C operations. A Ready/Busy R

B output

indicates the completion of the internal algorithms.

T ab le 2. Absolute Maximum Ratings

Symbol Parameter Value Unit

T

A

T

BIAS

T

STG

(2)

V

IO

V

CC

V

(A9, E, G, RP)

Notes:

1. Except for the rating "Operating Temperature Range", stresses above those listed in the Table "Absolute Maximum Ratings"
may cause permanent damage to the device. These are stress rating s only and operation of the device at these or any other
conditions above those indicated in the Operating sections of this specification is not implied. Exposure to Absolute Maximum
Rating conditions for extended periods may affect device reliability. Refer also to the STMicroelectronics SURE Program and other
relevant quality documents.

2. Minimum Voltage may undershoot to –2V during transition and for less than 20ns.

3. Depends on range.

2/30

Ambient Operating Temperature
Temperature Under Bias –50 to 125
Storage Temperature –65 to 150
Input or Output Voltages –0.6 to 5 V
Supply Voltage –0.6 to 5 V

(2)

A9, E, G, RP Voltage –0.6 to 13.5 V

(1)

(3)

–40 to 85

C

°

C

°

C

°

M29W004T, M29W004B

Memory Blocks

The devices feature asymmetrically blocked archi­tecture providing system memory integration. Both
M29W004T and M29W004B devices have an array
of 11 blocks, one Boot Block of 16K Bytes, two
Parameter Blocks of 8K Bytes, one Main Block of
32K Bytes and seven Main Blocks of 64K Bytes.
The M29W004T has the Boot Block at the top of
the memory address space and the M29W004B
locates the Boot Block starting at the bottom. The
memory maps are showed in Figure 3. E ach block
can be erased separately, any combination of
blocks can be specified for multi-block erase or the
entire chip may be erased. The Erase operations
are managed automatically by the P/E.C. The block
erase operation can be suspended in order to read
from or program to any block not being ersased,
and then resumed.

Block protection provides additional data security.
Each block can be separately protected or unpro­tected against Program or Erase on programming
equipment. All previously protected blocks can be
temporarily unprotected in the application.

Bus Operations

The following operations can be performed usi ng
the appropriate bus cycles: Read (Array , E lectronic
Signature, Block Protection Status), Write com­mand, Output Disable, Standby, Reset, Block Pro­tection, Unprotection, Protection Verify,
Unprotection Verify and Blo ck Temporary Unpro­tection. See Tables 4 and 5.

Command Interface

Instructions, made up of commands written in cy­cles, can be given to the Program/Erase Controller
through a Command Interface (C.I.). For added
data protection, program or erase execution starts
after 4 or 6 cycles. The first, second, fourth and fifth
cycles are used to input Coded cycles to the C.I.
This Coded sequence is the same for all Pro­gram/Erase Controller instructions. The ’Com­mand’ itself and its confirmation, when applicable,
are given on the third, four th or sixth cycles. Any
incorrect command or any improper command se­quence will reset the device to Read Array mode.

Instructions

Seven instructions are defined to perform Read
Array , Auto Select (to read the Electronic Signature
or Block Protection Status), Program, Block Erase,
Chip Erase, Erase Suspend and Er ase Resume.
The internal P/E.C. automatically handles all tim­ing and verification of the Program and Erase
operations. The Status Register Data Polling, Tog­gle, Error bits and the R

B output may be read at
any time, during programming or erase, to monitor
the progress of the operation.

Instructions are composed of up to six cycles. The
first two cycles input a Coded sequence to the
Command Interface which is common to all instruc­tions (see Table 8). The third cycle inputs the
instruction set-up command. Subsequent cycles
output the addressed data, Electronic Signature or
Block Protection Status for Read operations. In
order to give additional data protection, the instruc­tions for Program and Block or Chip Erase require
further command inputs. For a P rogram instruction,
the fourth command cycle inputs the address and
data to be programmed. For an Erase instruction
(Block or Chip), the fourth and fifth cycles input a
further Coded sequence before the Erase confirm
command on the sixth cycle. Erasure of a memory
block may be suspended, in order to read data from
another block or to program data in another block,
and then resumed.

When power is first applied or if Vcc falls below

, the command interface is reset to Read

V

LKO

Array.

SIGNAL DESCRIP TIONS

See Figure 1 and T able 1.

Address Inputs (A0-A18)

. The address inputs for
the memory array are latched during a write opera­tion on the falling edge of Chip E nable
Enable

W. In Word-wide organisation the address

lines are A0-A18. When A9 is raised to V

E or Write

, either

ID

a Read Electronic Signature Manufacturer or De­vice Code, Block Protection Status or a Write Block
Protection or Block Unprotection is enabled de­pending on the combination of levels on A0, A1, A6,
A12 and A15.

Data Input/Outputs (DQ0-DQ7).

The input is data
to be programmed in the memory arr ay or a com­mand to be written to t he C.I. Both are latched on
the rising edge of Chip Enable

E or Write Enable
W. The output is data from the Memory Array, the
Electronic Signature Manufacturer or Device
codes, the Block Protection Status or the Status
register Data Polling bit DQ7, the Toggle Bits DQ6
and DQ2, the Error bit DQ5 or the Erase Timer bit
DQ3. Outputs are valid when Chip Enable
Output Enable

G are active. The output is high

E and

impedance when the chip is deselected or the
outputs are disabled and when

Chip Enable (

The Chip Enable input activates

E).

RP is at a Low level.

the memory control logic, input buffers, dec oders
and sense amplifiers.

E High deselects the memory
and reduces the power consumption to the standby
level.

E can also be used to control writing to the
command register and to the memory array, while
W remains at a low level. The Chip Enable must be
forced to V

during the Block Unprotection opera-

ID

tion.

3/30

M29W004T, M29W004B

Figure 3. Memory Map and Block Address Table (x8)

7FFFFh
7C000h

7BFFFh

7A000h

79FFFh

78000h

77FFFh

70000h

6FFFFh

60000h

5FFFFh

50000h

4FFFFh

40000h

3FFFFh

30000h

2FFFFh

20000h

1FFFFh

10000h

0FFFFh

00000h

M29W004T

16K BOOT BLOCK

8K PARAMETER BLOCK

8K PARAMETER BLOCK

32K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

7FFFFh

70000h

6FFFFh

60000h

5FFFFh

50000h

4FFFFh

40000h

3FFFFh

30000h

2FFFFh

20000h

1FFFFh

10000h

0FFFFh

08000h

07FFFh

06000h

05FFFh

04000h

03FFFh

00000h

M29W004B

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

64K MAIN BLOCK

32K MAIN BLOCK

8K PARAMETER BLOCK

8K PARAMETER BLOCK

16K BOOT BLOCK

AI02093

Output Enable (

The Output Enable gates the

G).

outputs through the data buffers during a read
operation. When
impedance.

G is High the outputs are High

G must be forced to VID level during

Block Protection and Unprotection operations.

Write Enable (

This input controls writing to the

W).

Command Register and Address and Data latches.

Ready/Busy Output (R

Ready/Busy is an

B).

open-drain output and gives the internal state of the
P/E.C. of the device. When R

B is Low, the device
is Busy with a Program or Erase operation and it
will not accept any additional program or erase
instructions except the Erase Suspend instruction.
When R
Program or Erase operation. The R

B is High, the device is ready for any Read,

B will also be
High when the memory is put in E ras e S uspend or
Standby modes.

Reset/Block Temporary Unprotect Input (

The

RP Input provides hardware reset and pro-

RP).

tected block(s) temporary unprotection functions.
Reset of the memory is acheived by pulling

for at least t

V

IL

4/30

. When the reset pulse is given,

PLPX

RP to

if the memory is in Read or Standby modes, it will
be available for new operations in t
rising edge of

RP. If the memory is in Erase, Erase

PHEL

after the

Suspend or Program modes the reset will take
t

during which the RB signal will be held at VIL.

PLYH

The end of the memory reset will be indicated by
the rising edge of R

B. A hardware reset during an
Erase or Program operation will corrupt the data
being programmed or the sec tor(s) being era sed.
See Table 14 and Figure 9.

Temporary block unprotection is made by holding
RP at VID. In this condition previously protected
blocks can be programmed or erased. The transi-

RP from VIH to VID must slower than t

tion of
When

RP is returned from VID to VIH all blocks

PHPHH

temporarily unprotected will be again protected.
See Table 15 and Figure 9.

Supply Voltage.

V

CC

The power supply for all

operations (Read, Program and Erase).

is the reference for all voltage

Ground.

V

SS

V

SS

measurements.

.

M29W004T, M29W004B

T ab le 3A. M29W004T Block Address Table

Address Range A18 A17 A16 A15 A14 A13

00000h-0FFFFh 0 0 0 X X X
10000h-1FFFFh 0 0 1 X X X
20000h-2FFFFh 0 1 0 X X X
30000h-3FFFFh 0 1 1 X X X
40000h-4FFFFh 1 0 0 X X X
50000h-5FFFFh 1 0 1 X X X
60000h-6FFFFh 1 1 0 X X X
70000h-77FFFh 1110XX

78000h-79FFFh 111100
7A000h-7BFFFh 111101
7C000h-7FFFFh 11111X

T ab le 3B. M29W004B Block Address Table

Address Range A18 A17 A16 A15 A14 A13

00000h-03FFFh 00000X

04000h-05FFFh 000010

06000h-07FFFh 000011

08000h-0FFFFh 0001XX

10000h-1FFFFh 0 0 1 X X X

20000h-2FFFFh 0 1 0 X X X

30000h-3FFFFh 0 1 1 X X X

40000h-4FFFFh 1 0 0 X X X

50000h-5FFFFh 1 0 1 X X X

60000h-6FFFFh 1 1 0 X X X

70000h-7FFFFh 1 1 1 X X X

5/30

M29W004T, M29W004B

DEVICE O PERATIONS

See Tables 4, 5 and 6.

Read operations are used to output the

Read.

contents of the Memory Array, the Electronic Sig­nature, the Status Register or the Block Protection
Status. Both Chip Enable

E and Output Enable G
must be low in order to read the output of the
memory.

Write operations are used to give Instruction

Write.

Commands to the memory or to latch input data to
be programmed. A write operation is initiated when
Chip Enable
with Output Enable
on the falling edge of

E is Low and Write Enable W is Low

G High. Addresses are latched

W or E whichever occurs last.
Commands and Input Data are latched on the rising
edge of

Output Disable.

ance when the Output Enable
Enable

Standby.

Enable

W or E whichever occurs first.

The data outputs are high imped-

G is High with Write

W High.

The memory is in standby when Chip

E is High and the P/E .C. is idle. T he power
consumption is reduced to the standby level and
the outputs are high impedance, independent of
the Output Enable

Automatic Standby.

G or Write Enable W inputs.

After 150ns of bus inactivity
and when CMOS levels are driving the addresses,
the chip automatically enters a pseudo-standby
mode where consumption is reduced to the CMOS
standby value, while outputs still drive the bus.

Electronic S ignature.

Two codes identifying the
manufacturer and the device can be read from the
memory. The manufacturer’s code for STMi­croelectronics is 20h, the device code is EAh for
the M29W004T (Top Boot) and EBh for the
M29W004B (Bottom Boot). These codes allow pro­gramming equipment or applications to aut omat­ically match their interface to the characteristics of
the M29W004. The Electronic Signature is output
by a Read operation when the voltage applied to
A9 is at V

and address input A1 is Low. The

ID

manufacturer code is output when the Address
input A0 is Low and the device code when this
input is High. Other Address inputs are ignored.

The Electronic Signature can also be read, without
raising A9 to V

, by giving the m emory the Ins truc-

ID

tion AS.

Block Protection.

Each block can be separately
protected against Program or Erase on program­ming equipment. Block protection provides addi­tional data security, as it disables all program or
erase operations. This mode is activated when both
A9 and

G are raised to VID and an address in the
block is applied on A13-A18. The Block Protection
algorithm is shown in Figure 14. Block protection is
initiated on the edge of
a delay of 100µs, the edge of

W falling to VIL. Then after

W rising to VIH ends
the protection operations. Block protection verify is
achieved by bringing

, while W is at VIH and A9 at VID. Under these

to V

IH

G, E, A0 and A6 to VIL and A1

conditions, reading the data output will yield 01h if
the block defined by the inputs on A13-A18 is
protected. Any attempt to program or erase a pro­tected block will be ignored by the device.

Block Temporary Unprotection.

Any previously
protected block can be temporarily unprot ected in
order to change stored data. The temporary unpro­tection mode is activated by bringing

RP to VID.
During the temporary unprotection mode the pre­viously protected blocks are unprotected. A block
can be selected and data can be modified by
executing the Erase or Program instruction with the
RP signal held at VID. When RP is returned to VIH,
all the previously protected blocks are again pro­tected.

Block Unprotection.

All protected blocks can be
unprotected on programming equipment to allow
updating of bit contents. All blocks must first be
protected before the unprotection operation. Block
unprotection is activated when A9,

and A12, A15 at VIH. The Block Unprotection

V

ID

G and E are at

algorithm is shown in Figure 15. Unprotection is
initiated by the edge of

W falling to VIL. After a delay
of 10ms, the unprotection operation will end. Un­protection verify is achieved by bringing

while A0 is at VIL, A6 and A1 are at VIH and A9

V

IL

remains at V

. In these conditions, reading the

ID

G and E to

output data will yield 00h if the block defined by the
inputs A13-A18 has been succesfully unprotected.
Each block must be separately ver ified by giving its
address in order to ensure that it has been unpro­tected.

6/30

M29W004T, M29W004B

T ab le 4. User Bus Operations

(1)

Operation E G W RP A0 A1 A6 A9 A12 A15 DQ0-DQ7

Read Byte V
Write Byte V
Output Disable V
Standby V
Reset X X X V
Block

Protection

(2,4)

Blocks
Unprotection

VIL VIDVIL Pulse V

V

(4)

V

IL

IL

IL

IH

ID

IL

V

IH

V

IH

XXVIHXXXXXX Hi-Z

V

ID

V

IH

V

IL

V

IH

VIL Pulse V

V
V
V

A0 A1 A6 A9 A12 A15 Data Output

IH

A0 A1 A6 A9 A12 A15 Data Input

IH

IH

IH

IH

XXXXXX Hi-Z

XXXXXX Hi-Z

IL

XXXVIDXX X

XXXVIDV

V

IH

IH

Block
Protection

(2,4)

Verify

V

V

IL

IL

V

IH

V

V

IH

V

IL

V

IH

V

IL

ID

A12 A15

Protect

Status

Block
Unprotection

(2,4)

Verify

V

V

IL

IL

V

IH

V

V

IH

V

IL

V

IH

V

IH

ID

A12 A15

Protect

Status

Block
Temporary

XX XV

ID

XXXXXX X

Unprotection

Notes:

1. X = V

2. Block Address must be given on A13-A18 bits.

3. See Table 6.

4. Operation performed on programming equipment.

IL

or V

IH

X

Block

(3)

Block

(3)

T able 5. Read Electronic Signature (following AS instruction or with A9 = VID)

Org. Code Device E G WA0A1

Word-

wide

Byte-

wide

Manufact. Code V

Device Code

M29W004T V
M29W004B V

Manufact. Code V

Device Code

M29W004T V
M29W004B V

IL

IL

IL

IL

IL

IL

V

IL

V

IL

V

IL

V

IL

V

IL

V

IL

V

IH

V

IH

V

IH

V

IH

V

IH

V

IH

V

IL

V

IH

V

IH

V

IL

V

IH

V

IH

V

IL

V

IL

V

IL

V

IL

V

IL

V

IL

T ab le 6. Read Block Protection with AS Instruction

Code E G W A0 A1 A13-A18

Protected Block V
Unprotected Block V

IL

IL

V

IL

V

IL

V

IH

V

IH

V

IL

V

IL

V

IH

V

IH

Block Address Don’t Care 01h
Block Address Don’t Care 00h

Addresses

Other

Addresses

Don’t Care 20h
Don’t Care EAh
Don’t Care EBh
Don’t Care 20h
Don’t Care EAh
Don’t Care EBh

Other

DQ0-DQ7

DQ0-

DQ7

7/30

M29W004T, M29W004B

INSTRUCTIONS AND COMMANDS

The Command Interface latches commands wr it­ten to the memory. Instructions are made up from
one or more commands to perform Read Memory
Array, Read Electronic Signature, Read B lock Pro­tection, Program, Block Erase, Chip Erase, Erase
Suspend and Erase Resume. Commands are
made of address and data sequences. The in­structions require from 1 to 6 cycles, the first or first
three of which are always write operations used to
initiate the instruction. They are followed by either
further write cycles to confirm the first command or
execute the command immediately . Command se­quencing must be followed exactly. Any invalid
combination of commands will reset the device to
Read Array. The increased number of cycles has
been chosen to assure maximum data security.
Instructions are initialised by two initial Coded cy­cles which unlock the Command Interface. In addi­tion, for Erase, instruction confirmation is again
preceded by the two Coded cycles.

Status Register Bits

P/E.C. status is indicated during execution by Data
Polling on DQ7, detection of Toggle on DQ6 and
DQ2, or Error on DQ5 and Erase Timer DQ3 bits.
Any read attempt during Program or Erase com­mand execution will automatically output these five
Status Register bits. The P/E.C. automatically sets

T ab le 7. Commands

Hex Code Command

00h Invalid/Reserved
10h Chip Erase Confirm
20h Reserved
30h Block Erase Resume/Confirm
80h Set-up Erase

90h

A0h Program
B0h Erase Suspend
F0h Read Array/Reset

Read Electronic Signature/
Block Protection Status

bits DQ2, DQ3, DQ5, DQ6 and DQ7. Other bits
(DQ0, DQ1 and DQ4) are reser ved for future use
and should be masked. See Tables 9 and 10.

Data Polling Bit (DQ7).

When Programming op­erations are in progress, this bit outputs t he com­plement of the bit being programmed on DQ7.
During Erase operation, it outputs a ’0’. After com­pletion of the operation, DQ7 will output the bit last
programmed or a ’1’ after erasing. Data Polling is
valid and only effective during P/E.C. operation,
that is after the fourth
after the sixth

W pulse for erase. It must be per-

W pulse for programming or

formed at the address being programmed or at an
address within the block being erased. If all the
blocks selected for erasure are protected, DQ7 will
be set to ’0’ for about 100µs, and then return to the
previous addressed memory data value. See Fig­ure 11 for the Data Polling flowchart and Figure 10
for the Data Polling waveforms. DQ7 will also flag
the Erase Suspend mode by switching from ’0’ to
’1’ at the start of the Erase Suspend. In order to
monitor DQ7 in the Erase Suspend mode an ad­dress within a block being erased must be pro­vided. For a Read Operation in Erase Suspend
mode, DQ7 will output ’1’ if the read is attempted
on a block being erased and the data value on other
blocks. During Program operation i n Erase Sus­pend Mode, DQ7 will have the same behaviour as
in the normal program execution outside of the
suspend mode.

Toggle Bit (DQ6).

When Programming or Erasing
operations are in progress, successive attempts to
read DQ6 will output complementary data. DQ6 will
toggle following toggling of either

G, or E when G
is low. The operation is completed when two suc­cessive reads yield the same output data. The next
read will output the bit last programmed or a ’1’ after
erasing. The toggle bit DQ6 is valid only during
P/E.C. operations, that is after the fourth
for programming or after the sixth

W pulse

W pulse for
Erase. If the blocks selected for erasure are pro­tected, DQ6 will toggle for about 100µs and then
return back to Read. DQ6 will be set to ’1’ if a Read
operation is attempted on an Erase Suspend block.
When erase is suspended DQ6 will toggle during
programming operations in a block different to the
block in Erase Suspend. Either

E or G toggling will
cause DQ6 to toggle. See Figure 12 for Toggle Bit
flowchart and Figure 13 for Toggle Bit waveforms.

8/30

M29W004T, M29W004B

T ab le 8. Instructions

(1)

Mne. Instr. Cyc. 1st Cyc. 2nd Cyc. 3rd Cyc. 4th Cyc. 5th Cyc. 6th Cyc. 7th Cyc.

(3,7)

Addr.

RD

(2,4)

Read/Reset
Memory
Array

1+

3+

Data
Addr.

(3,7)

Data

(3,7)

Addr.

AS

(4)

Auto Select 3+

Data

(3,7)

Addr.

PG Program 4

Data

(3,7)

Addr.

BE Block Erase

6

Data

(3,7)

Chip Erase 6

CE

Addr.
Data

(3,7)

Addr.
Data
Addr.
Data

(3,7)

IL

ES

Notes:

Suspend

Erase

ER

Resume

1. Commands not interpreted in this table will default to read array mode.

2. A wait of t
before starting any new operation (See Table 14 and Figure 9).

3. X = Don’t Care.

4. The first cycles of the RD or AS instructions are followed by read operations. Any number of read cycles can occur after
the command cycles.

5. Signature Address bits A0, A1 at V
Device code.

6. Block Protection Address: A0 at V

7. For Coded cycles address inputs A15-A18 are don’t care.

8. Optional, additional Blocks addresses must be entered within the erase timeout delay after last write entry, timeout status
can be verified through DQ3 value (see Erase Timer Bit DQ3 description). When full command is entered, read Data Polling
or Toggle bit until Erase is completed or suspended.

9. Read Data Polling, T oggle bits or R

10.During Erase Suspend, Read and Data Program functions are allowed in blocks not being erased.

PLYH

1

1

is necessary after a Read/Reset command if the memory was in an Erase or Program mode

Erase

(10)

X

Read Memory Array until a new write cycle is initiated.

F0h

5555h 2AAAh 5555h

AAh 55h F0h

Read Memory Array until a new write cycle
is initiated.

5555h 2AAAh 5555h Read Electronic Signature or Block

Protection Status until a new write cycle is

AAh 55h 90h

5555h 2AAAh 5555h

AAh 55h A0h

5555h 2AAAh 5555h 5555h 2AAAh

initiated. See Note 5 and 6.

Program

Address

Program

Read Data Polling or Toggle Bit
until Program completes.

Data

Block

Address

AAh 55h 80h AAh 55h 30h 30h

5555h 2AAAh 5555h 5555h 2AAAh 5555h

AAh 55h 80h AAh 55h 10h

X

Read until Toggle stops, then read all the data needed from any

B0h

30h

will output Manufacturer code (20h). Address bits A0 at VIH and A1 at VIL will output

IL

, A1 at VIH and A13-A18 within the Block will output the Block Pr otec tio n st atus.

B until Erase completes.

Block(s) not being erased then Resume Erase.

X

Read Data Polling or Toggle Bits until Erase completes or Erase
is suspended another time

Additional

Block

Note 9

(8)

9/30

M29W004T, M29W004B

Table 9. Status Register Bits

DQ Name Logic Level Definition Note

Data

7

Polling

6 Toggle Bit

5 Error Bit

4 Reserved

Erase

3

Time Bit

2 Toggle Bit

’1’

’0’ Erase On-going

DQ

DQ Program On-going

’-1-0-1-0-1-0-1-’ Erase or Program On-going Successive reads output complementary

DQ Program Complete

’-1-1-1-1-1-1-1-’

’1’ Program or Erase Error
’0’ Program or Erase On-going

’1’ Erase Timeout Period Expired

’0’

’-1-0-1-0-1-0-1-’

1

DQ

Erase Complete or erase
block in Erase Suspend

Program Complete or data
of non erase block during
Erase Suspend

Erase Complete or Erase
Suspend on currently
addressed block

Erase Timeout Period
On-going

Chip Erase, Erase or Erase
Suspend on the currently
addressed block.
Erase Error due to the
currently addressed block
(when DQ5 = ’1’).

Program on-going, Erase
on-going on another block or
Erase Complete

Erase Suspend read on
non Erase Suspend block

Indicates the P/E.C. status, check during
Program or Erase, and on completion
before checking bits DQ5 for Program or
Erase Success.

data on DQ6 while Programming or Erase
operations are on-going. DQ6 remains at
constant level when P/E.C. operations are
completed or Erase Suspend is
acknowledged.

This bit is set to ’1’ in the case of
Programming or Erase failure.

P/E.C. Erase operation has started. Only
possible command entry is Erase Suspend
(ES).

An additional block to be erased in parallel
can be entered to the P/E.C.

Indicates the erase status and allows to
identify the erased block

1 Reserved
0 Reserved

Notes:

Logic level ’1’ is High, ’0’ is Low. -0-1-0-0-0-1-1-1-0- represent bit value in successive Read operations.

10/30

M29W004T, M29W004B

T able 10. Polling and T oggle Bits

Mode DQ7 DQ6 D Q2

Program
Erase 0 Toggle Note 1
Erase Suspend Read

(in Erase Suspend
block)

Erase Suspend Read
(outside Erase Suspend
block)

Erase Suspend Program

Note:

1. Toggle if the address is within a block being erased.

’1’ if the address is within a block not being erased.

Toggle Bit (DQ2).

This toggle bit, together with

DQ7 Toggle 1

1 1 Toggle

DQ7 DQ6 DQ2

DQ7 Toggle N/A

DQ6, can be used to determine the dev ice status
during the Erase operations. It can also be used to
identify the block being erased. During Erase or
Erase Suspend a read from a block being erased
will cause DQ2 to toggle. A read from a block not
being erased will set DQ2 to ’1’ during erase and
to DQ2 during Erase Suspend. During Chip Erase
a read operation will cause DQ2 to toggle as all
blocks are being erased. DQ2 will be set to ’1’
during program operation and when erase is com­plete. After erase completion and if the error bit
DQ5 is set to ’1’, DQ2 will toggle if the faulty block
is addressed.

Error Bit (DQ5).

This bit is set to ’1’ by the P/E.C.
when there is a failure of programming, block
erase, or chip erase that results in invalid data in
the memory block. In case of an er ror in block erase
or program, the block in which the error occured or
to which the programmed data belongs, must be
discarded. The DQ5 failure condition will also ap­pear if a user tries to program a ’1’ to a location that
is previously programmed to ’0’. Other Blocks may
still be used. The error bit resets after a Read/Reset
(RD) instruction. In case of success of Program or
Erase, the error bit will be set to ’0’ .

Erase Timer Bit (DQ3).

This bit is set to ’0’ by the
P/E.C. when the last block Erase command has
been entered to the Command Interface and it is
awaiting the Erase start. When the erase timeout
period is finished, after 50µs to 90µs, DQ3 returns
to ’1’.

Coded Cycles

The two Coded cycles unlock the C ommand Inter­face. They are followed by an input command or a

confirmation command. The Coded cycles consist
of writing the data AAh at address 5555h during the
first cycle. During the second cycle the Coded
cycles consist of writing the data 55h at address
2AAAh. A0 to A14 are valid, other address lines are
’don’t care’. The Coded cycles happen on first and
second cycles of the command write or on the
fourth and fifth cycles.

Instructions

See Table 8.

Read/Reset (RD) Instruction.

The Read/Reset
instruction consists of one write cycle giving the
command F0h. It can be optionally preceded by the
two Coded cycles. Subsequent read operations will
read the memory array addressed and output the
data read. A wait state of 10µs is necessary after
Read/Reset prior to any valid read if the memory
was in an Erase mode when the RD instruc tion is
given.

Auto Select (AS) Instruction.

This instruction
uses the two Coded cycles followed by one write
cycle giving the command 90h to address 5555h
for command set-up. A subsequent read will output
the manufacturer code and the device code or the
block protection status depending on the levels of
A0 and A1 The manufacturer code, 20h, is output
when the addresses lines A0 and A1 are Low, the
device code, EAh for Top Boot, EBh for Bottom
Boot is output when A0 is High with A1 Low.

The AS instruction also allows access to the block
protection status. After giving the AS instruction, A0
and A6 are set to V

with A1 at VIH, while A13-A18

IL

define the address of the bloc k to be verified. A read
in these conditions will output a 01h if the block is
protected and a 00h if the block is not protected.

Program (PG) Instruction.

This instruction uses
four write cycles. The Program command A0h is
written to address 5555h on the third cyc le after two
Coded cycles. A fourth write operation latches the
Address on the falling edge of

W or E and the Data
to be written on the rising edge and starts the
P/E.C. Read operations output the Status Register
bits after the programming has started. Memory
programming is made only by writing ’0’ in place of
’1’. Status bits DQ6 and DQ7 determine if program­ming is on-going and DQ5 allows verification of any
possible error. Programming at an address not in
blocks being erased is also possible during erase
suspend. In this case, DQ2 will toggle at the ad­dress being programmed.

11/30

M29W004T, M29W004B

T ab le 11. AC Measurement Conditions

Input Rise and Fall Times

10ns

≤

Figure 5. AC Testing Load Circuit

0.8V

Input Pulse Voltages 0 to 3V
Input and Output Timing Ref. Voltages 1.5V

Figure 4. AC Testing Input O utput Waveform

3V

1.5V

0V

AI01417

(1)

T ab le 12. Capacitance

(TA = 25 °C, f = 1 MHz )

DEVICE
UNDER

TEST

CL includes JIG capacitance

1N914

3.3kΩ

CL = 30pF or 100pF

Symbol Parameter Test Condition Min Max Unit

C

IN

C

OUT

Note:

1. Sampled only, not 100% tested.

Input Capacitance VIN = 0V 6 pF
Output Capacitance V

= 0V 12 pF

OUT

OUT

AI01968

T ab le 13. DC Characteristics

(T

= 0 to 70°C, –20 to 85°C or –40 to 85°C; VCC = 2.7V to 3.6V)

A

Symbol Parameter Test Condition Min Max Unit

I

Note:

I

I

CC1

I

CC1

I

CC3

CC4

V

V

V

V

V

V

I

LO

I

LKO

Input Leakage Current 0V ≤ VIN ≤ V

LI

Output Leakage Current 0V ≤ V

OUT

≤ V

CC

CC

Supply Current (Read) Byte E = VIL, G = VIH, f = 6MHz 10 mA
Supply Current (Read) Word E = VIL, G = VIH, f = 6MHz 10 mA
Supply Current (Standby) E = VCC ± 0.2V 50

(1)

Supply Current (Program or Erase)

Input Low Voltage –0.5 0.8 V

IL

Input High Voltage 0.7 VCC VCC + 0.3 V

IH

Output Low Voltage IOL = 4mA 0.45 V

OL

Output High Voltage CMOS IOH = –100µAV

OH

A9 Voltage (Electronic Signature) 11.0 12.0 V

ID

A9 Current (Electronic Signature) A9 = V

ID

Supply Voltage (Erase and
Program lock-out)

1. Sampled only, not 100% tested.

Byte program, Block or
Chip Erase in progress

ID

–0.4V V

CC

2.0 2.3 V

1

±

1

±

20 mA

100

A

µ

A

µ

A

µ

A

µ

12/30

T ab le 14A. Read AC Characteristics

(T

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

A

M29W004T, M29W004B

M29W004T / M29W004B

Symbol Alt Parameter

t

AVAV

t

AVQV

t

ELQX

t

ELQV

t

GLQX

t

GLQV

t

EHQX

t

EHQZ

t

GHQX

t

GHQZ

t

AXQX

t

PLYH

t

PHEL

t

PLPX

Notes:

t

Address Valid to Next Address Valid

RC

t

Address Valid to Output Valid

ACC

(1)

tLZChip Enable Low to Output Transition G = V

(2)

t

Chip Enable Low to Output Valid G = V

CE

(1)

(2)

(1)

(1)

(1,3)

1. Sampled only, not 100% tested.
G may be delayed by up to t

2.

3. To be considered only if the Reset pulse is given while the memory is in Erase mode.

Output Enable Low to Output

t

OLZ

Transition

t

Output Enable Low to Output Valid E = V

OE

t

Chip Enable High to Output Transition G = V

OH

tHZChip Enable High to Output Hi-Z G = V

Output Enable High to Output

t

OH

Transition

tDFOutput Enable High to Output Hi-Z E = V

Address Transition to Output

t

OH

Transition

t

RRB

RP Low to Read Mode 10 10

t

READY

t

RP High to Chip Enable Low 50 50 ns

RH

t

RP Pulse Width 500 500 ns

RP

- t

ELQV

after the falling edge of E without increasing t

GLQV

Test

Condition

E = VIL,

G = V

IL

E = VIL,

G = V

IL

IL

IL

E = V

IL

IL

IL

IL

E = V

IL

IL

E = VIL,

G = V

IL

-90 -100

V

= 3.0V to 3.6V

CC

C

= 30pF

L

= 2.7V to 3.6V

V

CC

C

= 30pF

L

Unit

Min Max Min Max

90 100 ns

90 100 ns

00ns

90 100 ns

00ns

35 40 ns

00ns

30 30 ns

00ns

30 30 ns

00ns

s

µ

.

ELQV

13/30

M29W004T, M29W004B

Table 14B. Read AC Characteristics

(T

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

A

Symbol Alt Parameter

t

AVAV

t

AVQV

t

ELQX

t

ELQV

t

GLQX

t

GLQV

t

EHQX

t

EHQZ

t

GHQX

t

GHQZ

t

AXQX

t

PLYH

t

PHEL

t

PLPX

Notes:

t

Address Valid to Next Address Valid

RC

t

Address Valid to Output Valid

ACC

(1)

tLZChip Enable Low to Output Transition G = V

(2)

tCEChip Enable Low to Output Valid G = V

Output Enable Low to Output

t

OLZ

Transition

t

Output Enable Low to Output Valid E = V

OE

t

Chip Enable High to Output Transition G = V

OH

tHZChip Enable High to Output Hi-Z G = V

Output Enable High to Output

t

OH

Transition

tDFOutput Enable High to Output Hi-Z E = V

Address Transition to Output

t

OH

Transition

t

RRB

RP Low to Read Mode 10 10

t

READY

t

RP High to Chip Enable Low 50 50 ns

RH

(1,3)

(1)

(2)

(1)

(1)

tRPRP Pulse Width 500 500 ns

1. Sampled only, not 100% tested.
G may be delayed by up to t

2.

3. To be considered only if the Reset pulse is given while the memory is in Erase mode.

ELQV

- t

after the falling edge of E without incr easing t

GLQV

Test

Condition

E = VIL,
G = V

IL

E = VIL,
G = V

IL

IL

IL

E = V

IL

IL

IL

IL

E = V

IL

IL

E = VIL,
G = V

IL

M29W004T / M29W004B

-120 -150

Unit

VCC = 2.7V to 3.6V VCC = 2.7V to 3.6V

Min Max Min Max

120 150 ns

120 150 ns

00ns

120 150 ns

00ns

50 55 ns

00ns

30 40 ns

00ns

30 40 ns

00ns

s

µ

.

ELQV

14/30

Figure 6. Read Mode AC Waveforms

tEHQZ

tGHQZ

tGHQX

M29W004T, M29W004B

AI02094

VALID

tAVAV

VALID

A0-A18

tAVQV tAXQX

tELQV

tGLQV

tGLQX

tELQX tEHQX

E

G

DQ0-DQ7

OUTPUT ENABLE DATA VALID

ADDRESS VALID

AND CHIP ENABLE

W) = High.

Write Enable (

Note:

15/30

M29W004T, M29W004B

Tabl e 15A. Write AC Characteristics, Write Enable Controlled

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

Symbol Alt Parameter

V

= 3.0V to 3.6V

CC

C

= 30pF

L

Min Max Min Max

t

AVAV

t

ELWL

t

WLWH

t

DVWH

t

WHDX

t

WHEH

t

WHWL

t

AVWL

t

WLAX

t

GHWL

t

VCHEL

t

WHGL

t

PHPHH

t

PLPX

t

WHRL

t

PHWL

Notes:

1. Sample only, not 100% tested.

2. This timing is for Temporary Block Unprotection operation.

t

t
t
t
t

t

WPH

t

t

t

OEH

(1,2)

t

VIDR

t

(1)

t

BUSY

(1)

t

Address Valid to Next Address Valid 90 100 ns

WC

t

Chip Enable Low to Write Enable Low 0 0 ns

CS

Write Enable Low to Write Enable High 45 50 ns

WP

Input Valid to Write Enable High 45 50 ns

DS

Write Enable High to Input Transition 0 0 ns

DH

Write Enable High to Chip Enable High 0 0 ns

CH

Write Enable High to Write Enable Low 30 30 ns

t

Address Valid to Write Enable Low 0 0 ns

AS

Write Enable Low to Address Transition 45 50 ns

AH

Output Enable High to Write Enable Low 0 0 ns

VCSVCC

High to Chip Enable Low 50 50
Write Enable High to Output Enable Low 0 0 ns
RP Rise Time to V
RP Pulse Width 500 500 ns

RP

ID

500 500 ns

Program Erase Valid to RB Delay 90 90 ns
RP High to Write Enable Low 4 4

RSP

M29W004T / M29W004B

-90 -100
= 2.7V to 3.6V

V

CC

C

= 30pF

L

Unit

µ

µ

s

s

Block Erase (BE) Instruction

. This instruction
uses a minimum of six write cycles. The Erase
Set-up command 80h is written to address 5555h
on third cycle after the two Coded cycles. The Block
Erase Confirm command 30h is similarly written on
the sixth cycle after another two Coded cycles.
During the input of the second command an ad­dress within the block to be erased is given a nd
latched into the memory. Additional block Erase
Confirm commands and block addresses can be
written subsequently to erase other blocks in par­allel, without further Coded cycles. The erase will
start after the erase timeout period (see Erase
Timer Bit DQ3 description). Thus, additional Erase

16/30

Confirm commands for other blocks must be given
within this delay . The input of a new E rase Confirm
command will restart the timeout period. The status
of the internal timer can be monitored through the
level of DQ3, if DQ3 is ’0’ the Block Erase Com­mand has been given and the timeout is running, if
DQ3 is ’1’, the timeout has expired and the P/E.C.
is erasing the Block(s). If the second command
given is not an erase confirm or if the Coded cycles
are wrong, the instruction aborts, and the device is
reset to Read Array. It is not necessary to program
the block with 00h as the P/E.C. will do t his auto­matically before to erasing to FFh. Read operations

M29W004T, M29W004B

Tabl e 15B. Write AC Characteristics, Write Enable Controlled

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

Symbol Alt Parameter

t

AVAV

t

ELWL

t

WLWH

t

DVWH

t

WHDX

t

WHEH

t

WHWL

t

AVWL

t

WLAX

t

GHWL

t

VCHEL

t

WHGL

t

PHPHH

t

PLPX

t

WHRL

t

PHWL

Notes:

1. Sample only, not 100% tested.

2. This timing is for Temporary Block Unprotection operation.

t

t
t
t
t
t

t

WPH

t

t

t

OEH

(1,2)

t

VIDR

t

(1)

t

BUSY

(1)

t

Address Valid to Next Address Valid 120 150 ns

WC

Chip Enable Low to Write Enable Low 0 0 ns

CS

Write Enable Low to Write Enable High 50 65 ns

WP

Input Valid to Write Enable High 50 65 ns

DS

Write Enable High to Input Transition 0 0 ns

DH

Write Enable High to Chip Enable High 0 0 ns

CH

Write Enable High to Write Enable Low 30 35 ns

t

Address Valid to Write Enable Low 0 0 ns

AS

Write Enable Low to Address Transition 50 65 ns

AH

Output Enable High to Write Enable Low 0 0 ns

VCSVCC

High to Chip Enable Low 50 50
Write Enable High to Output Enable Low 0 0 ns
RP Rise Time to V
RP Pulse Width 500 500 ns

RP

ID

Program Erase Valid to RB Delay 90 90 ns
RP High to Write Enable Low 4 4

RSP

-120 -150

VCC = 2.7V to 3.6V VCC = 2.7V to 3.6V

Min Max Min Max

500 500 ns

M29W004T / M29W004B

Unit

µ

µ

s

s

Chip Erase (CE ) Instruction.

This instruction uses
six write cycles. The Erase Set-up command 80h
is written to address 5555h on the third cycle after
the two Coded cycles. The Chip Erase Confirm
command 10h is similarly written on the sixth cycle
after another two Coded cycles. If the second
command given is not an erase confirm or if the
Coded cycles are wrong, the instruction aborts and
the device is reset to Read Array. It is not necessary
to program the array with 00h first as the P/E.C. will
automatically do this before erasing it to FFh. Read
operations after the sixth rising edge of

W or E
output the Status Register bits. During the execu­tion of the erase by the P/E.C., Data Polling bit DQ7
returns ’0’, then ’1’ on completion. The Toggle bits
DQ2 and DQ6 toggle during erase operation and

after the sixth rising edge of

W or E output the

status register status bits.
During the execution of the erase by the P/E.C., the

memory accepts only the Erase Suspend ES and
Read/Reset RD instructions. Data Polling bit DQ7
returns ’0’ while the erasure is in progress and ’1’
when it has completed. The Toggle bit DQ2 and
DQ6 toggle during the erase operation. They stop
when erase is completed. After completion the
Status Register bit DQ5 returns ’1’ if there has been
an erase failure. In such a situation, the Toggle bit
DQ2 can be used to determine which block is not
correctly erased. In the case of erase failure, a
Read/Reset RD instruction is necessary in order to
reset the P/E.C.

17/30

M29W004T, M29W004B

Figure 7. Write AC Waveforms, W Controlled

A0-A18

tAVWL

E

tAVAV
VALID

tWLAX

tWHEH

tELWL

G

W

DQ0-DQ7

V

CC

tVCHEL

RB

Note:

Address are latched on the falling edge of

W, Data is latched on the rising edge of W.

stop when erase is completed. After completion the
Status Register bit DQ5 returns ’1’ if there has been
an Erase Failure.

Erase Suspend (ES) Instruction.

The Block
Erase operation may be suspended by this instruc­tion which consists of writing the command B0h
without any specific address. No Coded cycles are
required. It permits reading of data fr om another
block and programming in another block while an
erase operation is in progress. Erase suspend is
accepted only during the Block Erase instruction
execution. Writing this command during Erase
timeout will, in addition to suspending the erase,
terminate the timeout. The Toggle bit DQ6 stops
toggling when the P/E.C. is suspended. The Toggle

tWHGL

tWLWHtGHWL

tWHWL

tDVWH

VALID

tWHRL

tWHDX

AI02095

bits will stop toggling between 0.1µs and 15µs after
the Erase Suspend (ES) command has been writ­ten. The device will then automatically be set to
Read Memory Array mode. When erase is sus­pended, a Read from blocks being erased will
output DQ2 toggling and DQ6 at ’1’. A Read from
a block not being erased returns valid data. During
suspension the memory will respond only to the
Erase Resume ER and the Program PG instruc­tions. A Program operation can be initiated during
erase suspend in one of the blocks not being
erased. It will result in both DQ2 and DQ 6 toggling
when the data is being programmed. A Read/Reset
command will definitively abort erasure and result
in invalid data in the blocks being erased.

18/30

M29W004T, M29W004B

T ab le 16A. Write AC Characteristics, Chip Enable Controlled

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

Symbol Alt Parameter

V

= 3.0V to 3.6V

CC

C

Min Max Min Max

t

AVAV

t

WLEL

t

ELEH

t

DVEH

t

EHDX

t

EHWH

t

EHEL

t

AVEL

t

ELAX

t

GHEL

t

VCHWL

t

EHGL

t

PHPHH

t

PLPX

(1)

t

EHRL

(1)

t

PHWL

Notes:

1. Sample only, not 100% tested.

2. This timing is for Temporary Block Unprotection operation.

(1,2)

t
t

t
t
t

t

t

CPH

t
t

t

VCS

t

OEH

t

VIDR

t

t

BUSY

t

RSP

Address Valid to Next Address Valid 90 100 ns

WC

Write Enable Low to Chip Enable Low 0 0 ns

WS

Chip Enable Low to Chip Enable High 45 50 ns

CP

Input Valid to Chip Enable High 45 5 ns

DS

Chip Enable High to Input Transition 0 0 ns

DH

Chip Enable High to Write Enable High 0 0 ns

WH

Chip Enable High to Chip Enable Low 20 20 ns
Address Valid to Chip Enable Low 0 0 ns

AS

Chip Enable Low to Address Transition 45 50 ns

AH

Output Enable High Chip Enable Low 0 0 ns
VCC High to Write Enable Low 50 50
Chip Enable High to Output Enable Low 0 0 ns
RP Rise TIme to V
RP Pulse Width 500 500 ns

RP

ID

500 500 ns

Program Erase Valid to RB Delay 90 90 ns
RP High to Write Enable Low 4 4

M29W004T / M29W004B

V

= 30pF

L

CC

= 2.7V to 3.6V

C

= 30pF

L

Unit-90 -100

s

µ

s

µ

Erase Resume (ER) Instruction.

If an Erase Sus­pend instruction was previously executed, the
erase operation may be resumed by giving the
command 30h, at any address, and without any
Coded cycles.

POWER SUPPLY
Power Up

The memory Command Interface is reset on power
up to Read Array . E ither

E or W must be tied to V

during Power Up to allow maximum security and
the possibility to write a command on the first rising
edge of
blocked when Vcc is below V

E and W. Any write cycle initiation is

.

LKO

Supply Rails

Normal precautions must be taken for supply volt­age decoupling; each device in a system should
have the V
close to the V

rail decoupled with a 0. 1µF capacitor

CC

and VSS pins. The PCB trace

CC

widths should be sufficient to carry the V
gram and erase currents required.

IH

CC

pro-

19/30

M29W004T, M29W004B

T ab le 16B. Write AC Characteristics, Chip Enable Controlled

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

Symbol Alt Parameter

V

= 2.7V to 3.6V VCC = 2.7V to 3.6V

CC

Min Max Min Max

t

AVAV

t

WLEL

t

ELEH

t

DVEH

t

EHDX

t

EHWH

t

EHEL

t

AVEL

t

ELAX

t

GHEL

t

VCHWL

t

EHGL

t

PHPHH

t

PLPX

(1)

t

EHRL

(1)

t

PHWL

Notes:

1. Sample only, not 100% tested.

2. This timing is for Temporary Block Unprotection operation.

(1,2)

t
t

t
t
t

t

t

CPH

t
t

t

VCS

t

OEH

t

VIDR

t

t

BUSY

t

RSP

Address Valid to Next Address Valid 120 150 ns

WC

Write Enable Low to Chip Enable Low 0 0 ns

WS

Chip Enable Low to Chip Enable High 50 50 ns

CP

Input Valid to Chip Enable High 50 50 ns

DS

Chip Enable High to Input Transition 0 0 ns

DH

Chip Enable High to Write Enable High 0 0 ns

WH

Chip Enable High to Chip Enable Low 20 20 ns
Address Valid to Chip Enable Low 0 0 ns

AS

Chip Enable Low to Address Transition 50 50 ns

AH

Output Enable High Chip Enable Low 0 0 ns
VCC High to Write Enable Low 50 50
Chip Enable High to Output Enable Low 0 0 ns
RP Rise TIme to V
RP Pulse Width 500 500 ns

RP

ID

500 500 ns

Program Erase Valid to RB Delay 90 90 ns
RP High to Write Enable Low 4 4

M29W004T / M29W004B

-120 -150

Unit

µ

µ

s

s

20/30

Figure 8. Write AC Waveforms, E Controlled

M29W004T, M29W004B

tAVAV

A0-A18

W

G

E

DQ0-DQ7

V

CC

tVCHWL

RB

Note:

Address are latched on the falling edge of

VALID

tAVEL

tWLEL

E, Data is latched on the rising edge of E.

tELEHtGHEL

tDVEH

VALID

tEHRL

tELAX

tEHWH

tEHGL

tEHEL

tEHDX

AI02096

Figure 9. Read and Write AC Characteristics, RP Related

E

tPHEL

W

tPHWL

RB

RP

tPLPX

tPLYH

tPHPHH

AI02091

21/30

M29W004T, M29W004B

Table 17A. Data Polling and T oggle Bit AC Characteristics

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

(1)

M29W004T / M29W004B

Sym-

bol

Parameter

V

= 3.0V to 3.6V

CC

C

L

Min Max Min Max

t

WHQ7V

t

EHQ7V

t

Q7VQV

t

WHQV

Write Enable High to DQ7 Valid
(Program,

W Controlled)

Write Enable High to DQ7 Valid
(Chip Erase,

W Controlled)

Chip Enable High to DQ7 Valid
(Program,

E Controlled)

Chip Enable High to DQ7 Valid
(Chip Erase,

E Controlled)
Q7 Valid to Output Valid (Data Polling) 35 40 ns
Write Enable High to Output Valid (Program) 10 2400 10 2400

10 2400 10 2400 ms

1.0 30 1.0 30 sec

10 2400 10 2400

1.0 30 1.0 30 sec

Write Enable High to Output Valid (Chip Erase) 1.0 30 1.0 30 sec

t

Chip Enable High to Output Valid (Program) 10 2400 10 2400

EHQV

Chip Enable High to Output Valid (Chip Erase) 1.0 30 1.0 30 sec

Note:

1. All other timings are defined in Read AC Characteristics table.

Table 17B. Data Polling and Toggle Bit AC Characteristics

= 0 to 70°C, –20 to 85°C or –40 to 85°C)

(T

A

-90 -100
= 2.7V to 3.6V

V

CC

= 30pF

(1)

C

= 30pF

L

Unit

µ

µ

µ

s

s

s

Sym-

bol

Parameter

Write Enable High to DQ7 Valid

t

WHQ7V

(Program,

W Controlled)

Write Enable High to DQ7 Valid
(Chip Erase,

W Controlled)

Chip Enable High to DQ7 Valid

t

EHQ7V

(Program,

E Controlled)

Chip Enable High to DQ7 Valid

E Controlled)

t

Q7VQV

t

WHQV

(Chip Erase,
Q7 Valid to Output Valid (Data Polling) 50 55 ns
Write Enable High to Output Valid (Program) 10 2400 10 2400
Write Enable High to Output Valid (Chip Erase) 1.0 30 1.0 30 sec

t

Chip Enable High to Output Valid (Program) 10 2400 10 2400

EHQV

Chip Enable High to Output Valid (Chip Erase) 1.0 30 1.0 30 sec

Note:

1. All other timings are defined in Read AC Characteristics table.

M29W004T / M29W004B

-120 -150

= 2.7V to 3.6V VCC = 2.7V to 3.6V

V

CC

Min Max Min Max

10 2400 10 2400 ms

1.0 30 1.0 30 sec

10 2400 10 2400

1.0 30 1.0 30 sec

Unit

s

µ

s

µ

s

µ

22/30

Figure 10. Data Polling DQ7 AC Waveforms

M29W004T, M29W004B

AI02097

ARRAY

READ CYCLE

DATA OUTPUT VALID

ADDRESS (WITHIN BLOCKS)

tELQV

tAVQV

tEHQ7V

tGLQV

VALID

DQ7

tWHQ7V

VALID

tQ7VQV

IGNORE

DATA POLLING (LAST) CYCLE MEMORY

READ CYCLES

DATA POLLING

A0-A18

PROGRAM

OR ERASE

CYCLE OF

LAST WRITE

E

G

W

DQ7

DQ0-DQ6

INSTRUCTION

23/30

M29W004T, M29W004B

Figure 11. Data Polling Flowchart

START

READ DQ5 & DQ7

at VALID ADDRESS

DQ7

DATA

NO

DQ5

READ DQ7

DQ7

DATA

FAIL PASS

= 1

YES

=

NO

YES

YES

=

NO

Figure 12. Data Toggle Flowchart

START

READ

DQ2, DQ5 & DQ6

DQ2, DQ6

=

TOGGLE

NO

DQ5

= 1

READ DQ2, DQ6

DQ2, DQ6

=

TOGGLE

FAIL PASS

NO

YES

YES

NO

YES

AI01369

AI01873

Tabl e 18. Program, Erase Times and Program, Erase Endurance Cycl es

(T

= 0 to 70°C; VCC = 2.7V to 3.6V)

A

M29W004T / M29W004B

Parameter

Min Typ

Typical after

100k W/E Cycles

Chip Erase (Preprogrammed) 1.5 1.7 sec
Chip Erase 6.7 7.0 sec
Boot Block Erase 0.7 sec
Parameter Block Erase 0.6 sec
Main Block (32Kb) Erase 0.9 sec
Main Block (64Kb) Erase 1.4 sec
Chip Program (Byte) 8.2 8.2 sec
Byte Program 10 10
Program/Erase Cycles (per Block) 100,000 cycles

Unit

s

µ

24/30

Figure 13. Data T oggle DQ6, DQ2 AC Waveforms

M29W004T, M29W004B

AI02098

VALID

tAVQV

tEHQV

tELQV

tGLQV

VALID

tWHQV

STOP TOGGLE

VALID

IGNORE

READ CYCLE

MEMORY ARRAY

READ CYCLE

DATA TOGGLE

A0-A18

DATA

TOGGLE

READ CYCLE

OF ERASE

PROGRAM

CYCLE OF

LAST WRITE

E

G

W

DQ6,DQ2

DQ0-DQ1,DQ3-DQ5,DQ7

INSTRUCTION

All other timings are as a normal Read cycle.

Note:

25/30

M29W004T, M29W004B

Figure 14. Bloc k Protection Flowc ha r t

BLOCK ADDRESS

Set-up

START

on A13-A18

W = V

IH

n = 0

G, A9 = VID,

E = V

IL

Wait 4µs

W = V

IL

Protect

Verify

Wait 100µs

W = V

IH

E, G = V

IH

VERIFY BLOCK PROTECTION

A0, A6 = VIL; A1 = VIH; A9 = V

A13-A18 IDENTIFY BLOCK

E = V

IL

Wait 4µs

G = V

IL

Wait 60ns

VERIFY BLOCK

PROTECT STATUS

=

01h

NO

YES

DATA

ID

26/30

A9 = V

PASS

IH

A9 = V

++n

= 25

FAIL

NO

YES

IH

AI02099B

Figure 15. All Blocks Unprotecting Flowchart

M29W004T, M29W004B

START

PROTECT

ALL BLOCKS

n = 0

W = V

IH

E, G, A9 = V

A12, A15 = V

Wait 10ms

E, G = V

E, A0 = VIL; A1, A6 = VIH; A9 = V

A13-A18 IDENTIFY BLOCK

Wait 4µs

W = V

W = V

Wait 4µs

G = V

ID

IH

IL

IH

IH

IL

Set-up

Unprotect

Verify

ID

NEXT

BLOCK

Wait 60ns

VERIFY BLOCK

PROTECT STATUS

YESNO

DATA

=

00h

++n

NO LAST

= 1000

A9 = V

FAIL

YES

IH

BLK.

A9 = V

PASS

NO

YES

IH

AI02100C

27/30

M29W004T, M29W004B

ORDERING INFORMATION SCHEME

Example: M29W004T -90 N 1 TR

Operating Voltage

W 2.7V to 3.6V

Array Matrix

T Top Boot
B Bottom Boot

Speed

-90 90ns

-100 100ns

-120 120ns

-150 150ns

Package

N TSOP40

10 x 20mm

Option

TR T ape & Reel

Packing

Temp. Range

1 0 to 70 °C
5 –20 to 85 °C
6 –40 to 85 °C

M29W004T and M29W004B are replaced respectively by the new version M29W004BT and
M29W004BB

Devices are shipped from the factory with the memory content erased (to FFh).

For a list of available options (Speed, Package, etc...) or for further information on any aspect of this device,
please contact the STMicroelectronics Sales Office nearest to you.

28/30

M29W004T, M29W004B

TSOP40 Normal Pi nout - 40 lead Plastic Thin Small Ou t li ne, 10 x 20mm

Symb

Typ Min Max Typ Min Max

A 1.20 0.047
A1 0.05 0.15 0.002 0.006
A2 0.95 1.05 0.037 0.041

B 0.17 0.27 0.007 0.011

C 0.10 0.21 0.004 0.008
D 19.80 20.20 0.780 0.795

D1 18.30 18.50 0.720 0.728

E 9.90 10.10 0.390 0.398

e0.50– –0.020– –

L 0.50 0.70 0.020 0.028

α

N40 40

CP 0.10 0.004

mm inches

0

°

5

°

0

°

5

°

Drawing is not to scale.

1 N

N/2

D1

D

DIE

TSOP-a

A2

e

E

B

A

CP

C

LA1 α

29/30

M29W004T, M29W004B

Information furnished is believ ed to be accura te and reliable. Ho wever, STMicroelectronics as sum es no responsibility for the consequences
of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted
by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to
change without notice. This publication supersedes and repl aces all information previously supplied. STMicroelectron ics products are not
authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.

The ST logo is a registered trademark of STMicroelect roni cs

© 1999 STMicroelectronics - All Rights Reserved

All other names are the property of their respective owners

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30/30