SGS Thomson Microelectronics M14C32, M14C64 Datasheet

M14C64
M14C32

Memory Card IC

64/32 Kbit Serial I²C Bus EEPROM

■ Compat ible with I

■ Two Wire I

2

C Extended Addressing

2

C Serial Interface

Supports 400 kHz Protocol

■ Single Supply Voltage (2.5 V to 5.5 V)

■ Hardware Write Control

■ BYTE and PAGE WRITE (up to 32 Bytes)

■ BYTE, RANDOM and SEQUENTIAL READ

Modes

■ Self-Tim e d P ro g ra m ming Cycle

■ Automatic Address Incrementing

■ Enhanced ESD/Latch-Up Behaviour

■ 1 Million Erase/Write Cycles (minimum)

■ 40 Year Data Retention (minimum)

■ 5 ms Programming Time (typical)

DESCRIPTION

Each device is an electrically erasable program ­mable memory (EEPROM) fabricated with STMi-

croelectronics’s High Endurance, Single
Polysilicon, CMOS technology. This guarantees
an endurance typically well above one million
Erase/Write cycles, with a data retention of
40 years. The memory operates with a power sup­ply as low as 2.5 V.

The M14C32 is available in wafer form (either
sawn or unsawn) and in micromodule form (on
film). The M14C64 is available in micro-module

2

2

Micromodule (D20)

2

2

Wafer

Figure 1. Logic Diagram

Micromodule (D22)

Table 1. Signal Names

SDA Serial Data/Address Input/

Output
SCL Serial Clock
WC
V

CC

GND Ground

Write Control

Supply Voltage

SCL

V

CC

GND

SDA

M14xxxWC

AI02217

1/14October 1999

M14C64, M14C32

Figure 2. D20 Contact Connections

V

CC

GND

WC

SCL

SDA

AI02168

form only. For availability of the M14C64 in wafer
form, please contact your ST sales office.

Each memory is compatible with the I

2

C extended
memory standard. This is a two wire serial inter­face that uses a bi-directional data bus and serial
clock. The memory carries a built-in 7-bit unique
Device Type Identifier code (1010000) in accord­ance with the I
can be attached to each I

The memory behaves as a slave device in the I

2

C bus definition. Only one memory

2

C bus.

2

protocol, with all memory operations synchronized
by the serial clock. Read and write o perations are
initiated by a START condition, gene rated by the
bus master. The STA RT condition is followed by
the Device Select Code which is compos ed of a
stream of 7 bits (1010000), plus one read/write bit
(R/W

) and is terminated by an acknowledge bit.

When writing data to the memory, the mem ory in­serts an acknowledge bit during the 9

th

bit time,

Figure 3. D22 Contact Connections

V

CC

WC

SCL

following the bus master’s 8-bit transmission.
When data is read by the bus master, the bus
master acknowledges the receipt of the data byte
in the same way. Data transfers are terminated by
a STOP condition after an Ack for WRITE, and af­ter a NoACK for READ.

Power On Reset: V

Lock-Out Write Protect

CC

In order to prevent data corruption and inadvertent
write operations during power up, a Power On Re-

C

set (POR) circuit is included. The internal reset is
held active until the V

voltage has reached the

CC

POR threshold value, and all operations are dis­abled – the device will not respond to any com­mand. In the same way, when V

drops from the

CC

operating voltage, below the POR threshold value,
all operations are disabled and the device will not
respond to any com ma nd. A s table a nd v alid V
must be applied before applying any logic signal.

GND

SDA

AI02204

CC

Table 2. Absolute Maximum Ratings

Symbol Parameter Value Unit

T

A

T

STG

V

IO

V

CC

V

ESD

Note: 1. Exc ept for the rating “Operating Temperature Range”, stresses above those l i sted in the Table “Absolute Maximum Ratings” may

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cause permanent damage to the device. These are stress ratings only, and operation of the device at these or any other conditions
above those indica te d i n the Operating secti ons of this specification is not im plied. Exposure to Absolute Ma xim um Rating condi­tions 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 (100 pF, 1500 Ω )

3. EIA J I C-121 (Condi tion C) (200 pF, 0 Ω)

Ambient Operating Temperature 0 to 70 °C

Storage Temperature

Input or Output range -0.6 to 6.5 V
Supply Voltage -0.3 to 6.5 V

Electrostatic Discharge Voltage (Human Body model)
Electrostatic Discharge Voltage (Machine model)

1

Wafer form
Module form

2

3

-65 to 150

-40 to 120

4000 V

400 V

°C

M14C64, M14C32

SIGNAL DESCRIPTION
Serial Clock (SCL)

The SCL input pin is used to sync hronize all data
in and out of the memory. A pull up resistor can be
connected from the SCL line to V

. (Figure 4 in-

CC

dicates how the value of the pull-up resistor can be
calculated).

Serial Data (SDA)

The SDA pin is bi-directional, and is used to trans­fer data in or out of the memory. It is an open drain

output that may be wire-OR’ed with other open
drain or open collector signals on the bus. A pull
up resistor must be connected from the SDA bus
to V

. (Figure 4 indicates how the value of the

CC

pull-up resistor can be calculated).

Write Control (WC

The hardware Write Control contact (WC

)

) is useful
for protecting the entire contents of the memory
from inadvertent erase/write. The Write Control
signal is used to enable (WC
(WC

=VIH) write instructions to the entire memory
area. When unconnected, the WC
ly read as V

When WC

and write operations are allowed.

IL

=1, Device Select and Address bytes

=VIL) or disable

input is internal-

are acknowledged, Data bytes are not acknowl­edged.

Please see the Application Note

AN404

for a more

detailed description of the Write Control feature.

DEVICE OPERATION

2

The memory device supports the XI

2

I

C) protocol, as summarized in Figure 5. Any de-

C (Extended

vice that sends data on to the bus is defined to be
a transmitter, and any dev ice that reads the dat a
to be a receiver. The device that controls the data
transfer is known as the master, and the other as

the slave. A data transfer can o nly be initiated by
the master, which will also provide the serial clock
for synchronization. The memory device is always
a slave device in all communication.

Start Condition

START is identified by a high t o low transition of
the SDA line while the clock, SCL, is stable i n the
high state. A START condition must precede any
data transfer comman d. Th e m em ory devi ce con­tinuously monitors (except during a program ming
cycle) the SDA and SCL lines for a START condi­tion, and will not respond unless one is given.

Stop Condition

STOP is identified by a low to high transition of the
SDA line wh ile th e clock S CL is sta ble in the h igh
state. A STO P condition terminates c ommunica­tion between the memory device and the bus mas­ter. A STOP condition at the end of a Read
command, after (and only after) a NoACK , forces
the memory device into its standby state. A STOP
condition at the end of a Write command triggers
the internal EEPRO M writ e cycle.

Acknowledge Bit (ACK)

An acknowledge signal is used to indicate a suc­cessful data transfer. The bus transmitter, either
master or slave, will release the SDA bus after
sending 8 bits of data. During t he 9

th

clock pulse
period the receiver pulls the SDA bus low to ac­knowledge the receipt of the 8 data bits.

Data Input

During data input, the memory device samples the
SDA bus signal on the rising edge of the clock,
SCL. For correct device operation, the SDA signal
must be stable during the clock low-to-high transi­tion, and the data must change

only

when the SCL

line is low.

Figure 4. Maximum R

20

16

12

8

Maximum RP value (kΩ)

4

0

10 1000

Value versus Bus Capacitance (C

L

fc = 100kHz

fc = 400kHz

100

C

(pF)

BUS

) for an I2C Bus

BUS

V

MASTER

CC

SDA

SCL

R

R

C

BUS

L

C

BUS

AI01665

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L

M14C64, M14C32

2

Figure 5. I

C Bus Protocol

SCL

SDA

SCL

SDA

SCL

SDA

START

CONDITION

START

CONDITION

SDA

INPUT

1 23 789

MSB

1 23 789

MSB ACK

SDA

CHANGE

CONDITION

ACK

STOP

STOP

CONDITION

AI00792

Memory Addressing

To start communication betwee n the bus master
and the slave memory, the master must initiate a
START condition. Following this, the master sends
8 bits to the SDA bus line (with the most significant
bit first). These bits represent the Device Select
Code (7 bits) and a RW

bit.

The seven most s ignificant bits of the Device Se­lect Code are the Device Type Identifier, according
to the I

Table 5. Device Select Code

Note: 1. The most significant bit, b7, is sent first.

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2

C bus definition. For the mem ory device,

1

Device Code Chip Enable RW

b7 b6 b5 b4 b3 b2 b1 b0

Device Select 1010000RW

Table 3. Most Significant Byte

b15 b14 b13 b12 b11 b10 b9 b8

Note: 1. b15 to b13 are Don’t Care on the M14C6 4 series.

b15 to b12 are Don’t Care on the M 14C32 serie s.

Table 4. Least Significant Byte

b7 b6 b5 b4 b3 b2 b1 b0

M14C64, M14C32

the seven bits are fixed at 1010000b (A0h), as
shown in Table 5.

th

The 8

bit is the read or write bit (RW). This bit is

set to ‘1’ for read and ‘0’ for write operations. If a
match occurs on the Device Select Code, the cor­responding memory gives an acknowledgment on
the SDA bus during the 9

th

bit time. If the memory
does not match the Device Select code, it will de­select itself from the bus, and go into stand-by
mode.

Each data byte in the m emory has a 16-bit (two
byte wide) address. The Most Significant Byte (Ta­ble 3) is sent first, f ollowed by the Least significant
Byte (Table 4). Bits b15 to b0 form t he addre ss of
the byte in memory. Bits b15 to b13 are treated as
a Don’t Care bit on the M14C64 memory. Bits b15
to b12 are treated as Don’t Care bits on the
M14C32 me m o r y .

Write Operations

Following a START con dition the ma ster sends a
Device Select code with the RW

bit set to ’0’, as

Figure 6. Wri te Mo de S e qu e nces with WC=1

WC

shown in Table 6. The memory acknowledges it
and waits for two bytes of address, which provides
access to the memory area. After receipt of each
byte address, the memory again responds with an
acknowledge and waits for t he data byte. Writing
in the memory may be inhibited if input pin WC

is

taken high.
Any write command with WC

=1 (during a period of
time from the START condition until the end of the
two bytes address) will not modify the memory
content and will NOT be acknowledged on data
bytes, as shown in Figure 6.

Byte Write

In the Byte Write mode, after the Device Select
code and the address, the master sends one data
byte. If the addressed location is write protected by
the W C

pin, the memory replies with a NoACK,
and the location is not modified. If, instead, the WC
pin has been held at 0, as shown in F igure 7, the
memory replies with an ACK. The master termi­nates the transfer by generating a STOP condi­tion.

ACK ACK ACK NO ACK

BYTE WRITE DEV SEL BYTE ADDR BYTE ADDR DATA IN

R/W

START

WC

ACK ACK ACK NO ACK

PAGE WRITE DEV SEL BYTE ADDR BYTE ADDR DATA IN 1

R/W

START

WC (cont'd)

NO ACK NO ACK

PAGE WRITE
(cont'd)

DATA IN N

STOP

DATA IN 2

STOP

AI01120B

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