SGS Thomson Microelectronics M95640-W, M95640-RMN5T, M95640-RMN5, M95640-RBN5, M95640-R Datasheet

1/19

PRELIMINARY DATA

June 1999

This is preliminary information on a new product now in development or undergoing evaluation. Details are subject to change without notice.

M95640, M95320
M95160, M95080

64/32/16/8 Kbit Serial SPI Bus EEPROM

With High Speed Clock

■ SPI Bus Compatible Serial Interface

■ Supports Positive Clock SPI Modes

■ 5 MHz Clock Rate (maximum)

■ Single Supply Voltage:

– 4.5V to 5.5V for M95xxx
– 2.7V to 5.5V for M95xxx-V
– 2.5V to 5.5V for M95xxx-W
– 1.8V to 3.6V for M95xxx-R

■ Status Register

■ Hardware and Software Protection of the Status

Register

■ BYTE and PAGE WRITE (up to 32 Bytes)

■ Self-Tim ed P ro gr a m ming Cycle

■ Adjustable Size Read-Only EEPR OM Area

■ Enhanced ESD Protection

■ 100,000 Erase/Write Cycles (minimum)

■ 40 Year Data Retention (minimum)

DESCRIPTION

These electrically erasable programmable mem o­ry (EEPROM) devices are fabricated with STMi­croelectronics’ High Endurance, Double
Polysilicon, CMOS technology. This guarantees
an endurance typically well above one hundred

Figure 1. Logic Diagram

AI01789C

S

V

CC

M95xxx

HOLD

V

SS

W

Q

C

D

Table 1. Signal Names

C Serial Clock
D Serial Data Input
Q Serial Data Output

S

Chip Select

W

Write Protect

HOLD

Hold

V

CC

Supply Voltage

V

SS

Ground

PSDIP8 (BN)

0.25 mm frame

SO8 (MN)

150 mil width

TSSOP14 (DL)

169 mil width

8

1

14

1

8

1

M95640, M95320, M95160, M95080

2/19

thousand Erase/Write cycles, with a data retention
of 40 years. The memories are o rganised as 8K x
8 bits and 4K x 8 bits (M95640, M95320) and 2K x
8 bits and 1K x 8 bits (M95160, M95080), and op­erate down to 2.5 V (for the -W version of each de­vice), and down to 1.8 V (for the -R version of each
device).

The M95640, M95320 and M9 5160, M95080 are
available in Plastic Dual-in-Line, Plastic Small Out­line and Thin Shrink Small Outline packages.

Each memory device is accessed by a simp le se­rial interface that is SPI bus compatible. The bus
signals are C, D and Q, as shown in Table 1 and
Figure 3.

The device is selected when t he chip select input
(S

) is held low. Communications with the chip can

be interrupted using the hold input (HOLD

).

Figure 2A. DIP Connections

Figure 2B. SO C on ne ct i on s

DV

SS

C

HOLDQ

SV

CC

W

AI01790C

M95xxx

1
2
3
4

8
7
6
5

1

AI01791C

2
3
4

8
7
6
5

DV

SS

C

HOLDQ

SV

CC

W

M95xxx

Figure 2C. TSSOP Connections

Note: 1. NC = Not Connected

1

AI02346

2
3
4

14

9

10

8

DV

SS

WC

S

HOLD

M95128

NC

Q

NC

NC NC

NC

NC

5
6
7

12

13

11

V

CC

Table 2. Absolute Maximum Ratings

1

Note: 1. Except for t he rating “Operating Temperature Ra nge”, stresses above those listed in t he Table “A bsolute Maximum Ratings” m ay

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 t he Operating sect i ons of thi s specifi cation i s not impl i ed. Exposure to Absolute M aximum Rating c ondi­tions for extended periods may affect device reliability. Refer also to the ST SURE Program and other relevant quality documents.

2. MIL -STD-883C, 3015.7 (1 00 pF, 1500 Ω)

Symbol Parameter Value Unit

T

A

Ambient Operating Temperature -40 to 125 °C

T

STG

Storage Temperature -65 to 150 °C

T

LEAD

Lead Temperature during Soldering

PSDIP8: 10 sec
SO8: 40 sec
TSSOP14: t.b.c.

260
215

t.b.c.

°C

V

O

Output Voltage Range

-0.3 to V

CC

+0.6

V

V

I

Input Voltage Range -0.3 to 6.5 V

V

CC

Supply Voltage Range -0.3 to 6.5 V

V

ESD

Electrostatic Discharge Voltage (Human Body model)

2

4000 V

3/19

M95640, M95320, M95160, M95080

SIGNAL DESCRIPTION
Seria l O utput ( Q )

The output pin is used to transfer data serially out
of the Memory. Data is shifted out on the falling
edge of the serial clock.

Serial Inpu t ( D )

The input pin is used to transfer data serially into
the device. Instructions, addresses, and the data
to be written, are each received this way . Input is
latched on the rising edge of the serial clock.

Serial Clock (C)

The serial clock provides the timing for the serial
interface (as shown in Figure 4). Instructions, ad­dresses, or data are latched, from the input pin, on
the rising edge of the clock input. The output dat a
on the Q pin changes state after the falling edge of
the clock input.

Chip Select (S

)

When S

is high, the memory device is deselected,
and the Q output pin is held in its high impe dance
state. Unless an internal write operation is under­way, the memory device is placed in its stand-by
power mode.

After power-on, a high-to-low transition on S

is re-

quired prior to the start of any operation.

Write Protect (W

)

The protection features of t he m em ory device are
summarized in Table 3.

The hardware write protection, controlled by the W
pin, restricts write access to the Status Register

(though not to the WIP and WEL bits, which are
set or reset by the device internal logic).

Bit 7 of the status register (as shown in Table 5) is
the Status Register Write Disable bit (SRWD).
When this is set to 0 (its initial delivery state) it is
possible to write to the status register if the WEL
bit (Write Enable Latch) has been set by the
WREN instruction (irrespective of the l evel being
applied to the W

input).

When bit 7 (SRWD) of the st atus register is set to
1, the ability to write to the status register depends
on the logic level being presented at pin W

:

–If W

pin is high, it is possible to write to the sta­tus register, after having set the WEL bit using
the WREN instruction (Write Enable Latch).

–If W

pin is low, any attempt to modify the status
register is ignored by the device, even if the
WEL bit has been set. As a consequence, all the
data bytes in the EE PROM area, protected by
the BPn bits of the status register, are also hard­ware protected against data corruption, and ap­pear as a Read Only EEPROM area for the
microcontroller. This mode is called the Hard­ware Protected Mode (HPM).

It is possible to enter the Hardware Protected
Mode (HPM) either by s etting the SRWD bi t after
pulling low the W

pin, or by pulling low the W pin

after setting the SRWD bit.
The only way to abort the Hardware Protected

Mode, once entered, is to pull high the W

pin.

If W

pin is permanently t ied to the hi gh level, the
Hardware Protected Mode is never activated, and
the memory device only allows the user to protect

Figure 3. Microcontroller and Memor y Devices on the SPI Bus

AI01958B

Master

(ST6, ST7, ST9,

ST10, Others)

M95xxx

D
Q
C

CQD

S

M95xxx

CQD

S

M95xxx

CQD

S

CS3 CS2 CS1

SPI Interface with
(CPOL, CPHA) =
('0', '0') or ('1', '1')

M95640, M95320, M95160, M95080

4/19

a part of the memory, using the BPn bits of the sta­tus register, in the Software Protected Mode
(SPM).

Hold (HOLD

)

The HOLD

pin is used to pause the serial commu­nications between the SPI memory and controller,
without losing bits that have already been decoded
in the serial sequence. For a h old con dition to oc­cur, the memory dev ice must already have b een
sele cted (S

= 0). The hold condition starts when

the HOLD

pin is held low while the clock pin (C) is

also low (as shown in Figure 14).
During the hold condition, the Q output pin i s held

in its high impedance sta te, and the level s on the
input pins (D and C) are ignored by the memory
device.

It is possible to deselect the device whe n it is still
in the hold state, thereby resetting whatever trans­fer had been in progress. The memory remains in
the hold state as long as the HOLD

pin is low. To
restart communication with the device, it is neces­sary both to remove the hold condition (by taking
HOLD

high) and to select the memory (by taking S

low).

OPERATIONS

All instructions, addresses and data are shifted se­rially in and out of the chip. The most significant bit
is presented first, with the data input (D) sampled
on the first rising edge of the clock (C) after the
chip selec t ( S

) goes low.

Every instruction starts with a single-byte code, as
summarised in Table 4. This code is entered via
the data input (D), and latched on the rising edge
of the clock input (C). To enter an instruction code,
the product must have been previously selected (S
held low). If an invalid i nstruction is sent (one not
contained in Table 4), the chip automatically dese­lects itself.

Write Enable (WREN) and Write Disable (WRDI)

The write enable latch, inside the memory device,
must be set prior to each WRITE and WRSR oper­ation. The WREN instruction (write enable) sets
this latch, and the WRDI instruction (write disable)
resets it.

The latch becomes reset by any of the following
events:

– Power on
– WRDI instruction completion
– WRSR in s t ru ctio n completio n
– WRITE instruction completion.

Table 3. Write Protection Control on the M95640, M95320, M95160, M95 080

W

SRWD

Bit

Mode Status Register

Data Bytes

Protected Area Unprotected Area

0 or 1 0 Software

Protected

(SPM)

Writeable (if the WREN

instruction has set the

WEL bit)

Software write protected

by the BPn of the status

register

Writeable (if the WREN

instruction has set the

WEL bit)

11

01

Hardware
Protected

(HPM)

Hardware write protected

Hardware write protected

by the BPn bits of the

status register

Writeable (if the WREN

instruction has set the

WEL bit)

Figure 4. Dat a and Clock Timi ng

AI01438

C

C

MSB LSB

CPHA

D or Q

0

1

CPOL

0

1

5/19

M95640, M95320, M95160, M95080

Figure 5. Block Diagram

Note: 1. The c el l

An

represents the byte at the highest address in the memory

AI01792C

HOLD

S

W

Control Logic

High Voltage

Generator

I/O Shift Register

Address Register

and Counter

Data

Register

32 Bytes

X Decoder

Y Decoder

Size of the
Read only
EEPROM
area

C

D

Q

Status

Register

AnAn - 31

001Fh0000h

As soon as the WREN or WRDI instruction is re­ceived, the memory device first executes the in­struction, then enters a wait mode until the device
is deselected.

Read Status Register (RDSR)

The RDSR instruction allows the status register to
be read, and can be sent at any time, even during
a Write operation. Indeed, when a Write is in
progress, it is recommended th at the value of t he
Write-In-Progress (WIP) bit be checked. The value
in the WIP bit (whose position in the status register
is shown in Table 5) can be continuously p olled,
before sending a new WRITE instruction. This can
be performed in one of two ways:

■ Repeated RDSR instructions (each one

consisting of S

being taken low, C being clocked
8 times for the instruction and 8 times for the
read operation, and S

being taken high)

■ A single, prolonged RDSR instruction

(consisting of S

being taken low, C being
clocked 8 times for the instruction and kept
running for repeated read operations), as
shown in Figure 6.

The Write-In-Process (WIP) bit is read-only, and
indicates whether the memory is busy with a Write

M95640, M95320, M95160, M95080

6/19

operation. A ’1’ indicates that a write is in progress,
and a ’0’ that no write is in progress.

The Write Enable Latch (WEL) bit indicates the
status of the write enable latch. It, too, is read-only.
Its value can only be changed by one of the events
listed in the previous paragraph, or as a result of
executing WREN or WRDI instruction. It cannot be
changed using a WRSR instruction. A ’1’ indicates
that the latch is set (the forthcoming Write instruc­tion will be executed), and a ’0’ that it is reset (and
any forthcoming Write instructions will be ignored).

The Block Protect (BP0 and BP1) bits indicate the
amount of the memory that is to be write-protect­ed. These two bits are non-volatile. They are set
using a WRSR instruction.

During a Write operation (whether it be to the
memory area or to the status register), all bits of
the status register remain valid, and can be read

using the RDSR instruction. However, during a
Write operation, the values of the no n-vo latile bits
(SRWD, BP0, BP1) be come frozen at a constant
value. The updated value of these bi ts becomes
available when a new RDSR instruction is execut­ed, after completion of the write cycle. On the oth­er hand, the two read-only bits (WEL, WIP) are
dynamically updated during internal write cycles.
Using this facility, it is possible to poll the WIP bit
to detect the end of the internal write cycle.

Write Status Register (WRSR)

The format of the WRSR instruction is shown in
Figure 7. After the instruction and the eigh t bits of
the status register have been latched-in, the inter­nal Write cycle is triggered by the rising edge of
the S

line. This must occur after the falling edge of

the 16

th

clock pulse, and before the rising edge of

the 17

th

clock (as indicated in Figure 7), otherwise

the internal write sequence is not performed.
The WRSR instruction is used for the following:

■ to select the size of memory area that is to be

write-protected

■ to select between SPM (Software Protected

Mode) and HPM (Hardware Protected Mode).

The size of the write-protection area applies equal­ly in SPM and HPM. The BP 1 and BP0 b its of the
status register have the appropriate value (see Ta­ble 6) written into them after the contents of the
protecte d ar ea of t he EEPROM have been written.

The initial delivery state of the BP1 and BP0 bits is
00, indicating a write-protection size of 0.

Software Protected Mode (SPM)

The act of writing a non-zero value to the BP1 and
BP0 bits causes the Software Protected Mode
(SPM) to be started. All attempts to write a byte or
page in the protected area are ignored, even if the
Write Enable Latch is set. However, writing is still
allowed in the unprotected area of the memory ar-

Figure 6. RDSR: Read Status Register Sequence

C

D

S

21 3456789101112131415

INSTRUCTION

0

AI02031

Q

7 6543210

STATUS REG. OUT

HIGH IMPEDANCE

MSB

7 6543210

STATUS REG. OUT

MSB MSB

7

Table 4. Instruction Set

Table 5. Status Register Format

Note: 1. SRWD , BP0 and BP1 are Read and wri te bits.

2. WEL and WIP are Read only bits.

Instruc

tion

Description

Instruction

Format

WREN Set Write Enable Latch 0000 0110
WRDI Reset Write Enable Latch 0000 0100
RDSR Read Status Register 0000 0101
WRSR Write Status Register 0000 0001
READ Read Data from Memory Array 0000 0011
WRITE Write Data to Memory Array 0000 0010

b7 b0

SRWD X X X BP1 BP0 WEL WIP