SUMMIT S24163PA, S24163PAT, S24163PB, S24163PBT, S24163S2.7 Datasheet

SUMMIT MICROELECTRONICS, Inc. • 300 Orchard City Drive, Suite 131 • Campbell, CA 95008 • Telephone 408-378-6461 • Fax 408-378-6586 • www.summitmicro.com

1

Characteristics subject to change without notice

© SUMMIT MICROELECTRONICS, Inc. 2000
2014 2.0 3/21/00

SUMMIT

MICROELECTRONICS, Inc.

S24163S24163

S24163S24163

S24163

FEATURESFEATURES

FEATURESFEATURES

FEATURES

••

••

•

Precision Supply Voltage MonitorPrecision Supply Voltage Monitor

Precision Supply Voltage MonitorPrecision Supply Voltage Monitor

Precision Supply Voltage Monitor
— Active Low— Active Low

— Active Low— Active Low

— Active Low
— Integrated memory write lockout— Integrated memory write lockout

— Integrated memory write lockout— Integrated memory write lockout

— Integrated memory write lockout

••

••

•

Guaranteed RESET (RESET#) assertionGuaranteed RESET (RESET#) assertion

Guaranteed RESET (RESET#) assertionGuaranteed RESET (RESET#) assertion

Guaranteed RESET (RESET#) assertion
to Vto V

to Vto V

to V

CC CC

CC CC

CC

= 1V= 1V

= 1V= 1V

= 1V

••

••

•

Power-Fail Accuracy GuaranteedPower-Fail Accuracy Guaranteed

Power-Fail Accuracy GuaranteedPower-Fail Accuracy Guaranteed

Power-Fail Accuracy Guaranteed

••

••

•

No External ComponentsNo External Components

No External ComponentsNo External Components

No External Components

••

••

•

3V and 5V system versions3V and 5V system versions

3V and 5V system versions3V and 5V system versions

3V and 5V system versions

••

••

•

Low Power CMOSLow Power CMOS

Low Power CMOSLow Power CMOS

Low Power CMOS
——

——

—

Active current less than 3mAActive current less than 3mA

Active current less than 3mAActive current less than 3mA

Active current less than 3mA

——

——

—

Standby current less than 25µAStandby current less than 25µA

Standby current less than 25µAStandby current less than 25µA

Standby current less than 25µA

••

••

•

Memory Internally Organized 2k X 8Memory Internally Organized 2k X 8

Memory Internally Organized 2k X 8Memory Internally Organized 2k X 8

Memory Internally Organized 2k X 8
——

——

—

Two Wire Serial Interface (ITwo Wire Serial Interface (I

Two Wire Serial Interface (ITwo Wire Serial Interface (I

Two Wire Serial Interface (I

22

22

2

C™)C™)

C™)C™)

C™)

––

––

–

Bidirectional data transfer protocolBidirectional data transfer protocol

Bidirectional data transfer protocolBidirectional data transfer protocol

Bidirectional data transfer protocol

––

––

–

Standard 100KHz and Fast 400KHzStandard 100KHz and Fast 400KHz

Standard 100KHz and Fast 400KHzStandard 100KHz and Fast 400KHz

Standard 100KHz and Fast 400KHz

PrPr

PrPr

Pr

ecision RESET Contrecision RESET Contr

ecision RESET Contrecision RESET Contr

ecision RESET Contr

oller with 16K Ioller with 16K I

oller with 16K Ioller with 16K I

oller with 16K I

22

22

2

C MemorC Memor

C MemorC Memor

C Memor

yy

yy

y

••

••

•

High ReliabilityHigh Reliability

High ReliabilityHigh Reliability

High Reliability
——

——

—

Endurance: 100,000 erase/write cyclesEndurance: 100,000 erase/write cycles

Endurance: 100,000 erase/write cyclesEndurance: 100,000 erase/write cycles

Endurance: 100,000 erase/write cycles

——

——

—

Data retention: 100 yearsData retention: 100 years

Data retention: 100 yearsData retention: 100 years

Data retention: 100 years

••

••

•

8-Pin PDIP or SOIC Packages8-Pin PDIP or SOIC Packages

8-Pin PDIP or SOIC Packages8-Pin PDIP or SOIC Packages

8-Pin PDIP or SOIC Packages

OVERVIEWOVERVIEW

OVERVIEWOVERVIEW

OVERVIEW
The S24163 is a power supervisory device with 16,384-

bits of serial E2PROM. It is fabricated using SUMMIT's
advanced CMOS E2PROM technology and is suitable for
both 3 and 5 volt systems.

The S24163 is internally organized as 2048 x 8. It fea­tures the I2C serial interface and software protocol allow­ing operation on a simple two-wire bus.

BLOCK DIAGRAMBLOCK DIAGRAM

BLOCK DIAGRAMBLOCK DIAGRAM

BLOCK DIAGRAM

3 and 5 Volt Systems

+
–

GND

V

CC

RESET#

V

TRIP

RESET
PULSE

GENERATOR

5kHz

OSCILLATOR

RESET

CONTROL

MODE

DECODE

ADDRESS
DECODER

WRITE

CONTROL

DATA I/O

E2PROM

MEMORY

ARRAY

1.26V

SCL

6

SDA

5

2

8

2014 T BD 2.0

4

2

S24163S24163

S24163S24163

S24163

2014 2.0 3/21/00

ENDURANCE AND DATA RETENTIONENDURANCE AND DATA RETENTION

ENDURANCE AND DATA RETENTIONENDURANCE AND DATA RETENTION

ENDURANCE AND DATA RETENTION
The S24163 is designed for applications requiring up to

100,000 erase/write cycles and unlimited read cycles. It
provides 100 years of secure data retention, with or without
power applied, after the execution of 100,000 erase/write
cycles.

APPLICATIONSAPPLICATIONS

APPLICATIONSAPPLICATIONS

APPLICATIONS

The S24163 is ideal for applications requiring low voltage
and low power consumption. This device provides
microcontroller RESET control and can be manually

resettable. This device also uses a cost effective, space­saving, 8-pin SOIC or PDIP plastic package. Typical

applications include alarm devices, electronic locks,
meters, keys, pagers and cellular phones.

RESET CONTROLLER DESCRIPTIONRESET CONTROLLER DESCRIPTION

RESET CONTROLLER DESCRIPTIONRESET CONTROLLER DESCRIPTION

RESET CONTROLLER DESCRIPTION

The device provides a precise reset output to a
microcontroller and it’s associated circuitry ensuring cor­rect system operation during power-up/down conditions
and brownout situations. The output is open drain, allow­ing control of the reset function by multiple devices.

During power-up the reset output remains in a fixed active
state until VCC passes through the reset threshold and
remains above the threshold for 200ms. The reset output

is valid whenever VCC ≥ 1V. If VCC falls below the
threshold for more than t

GLITCH

the device will immediately

generate a reset and drive the output.
The reset pin is an I/O; therefore, forcing the pin to the

active state can also manually reset the device. Because
the I/O needs to be an open drain, the internal timer can
only be triggered by the leading edge of the input. The
resulting reset output will either be t

PURST

, or the exter­nally applied reset signal, whichever is longer. This can
provide an affective debounce or reset signal extender
solution.

CHARACTERISTICS OF THE ICHARACTERISTICS OF THE I

CHARACTERISTICS OF THE ICHARACTERISTICS OF THE I

CHARACTERISTICS OF THE I

22

22

2

C BUSC BUS

C BUSC BUS

C BUS

General DescriptionGeneral Description

General DescriptionGeneral Description

General Description
The I2C bus was designed for two-way, two-line serial
communication between different integrated circuits. The
two lines are a serial data line (SDA), and a serial clock line
(SCL). The SDA line must be connected to a positive
supply by a pull-up resistor, located somewhere on the
bus (See Figure 1). Data transfer between devices may
be initiated with a START condition only when SCL and
SDA are HIGH (bus is not busy).

PIN DESCRIPTIONSPIN DESCRIPTIONS

PIN DESCRIPTIONSPIN DESCRIPTIONS

PIN DESCRIPTIONS
SCL — Serial Clock: SCL — Serial Clock:

SCL — Serial Clock: SCL — Serial Clock:

SCL — Serial Clock: The SCL input is used to clock data
into and out of the device. In the WRITE mode data must
remain stable while SCL is HIGH. In the READ mode data
is clocked out on the falling edge of SCL.

SDA — SDA —

SDA — SDA —

SDA —

Serial Data: Serial Data:

Serial Data: Serial Data:

Serial Data: The SDA pin is a bidirectional pin

used to transfer data into and out of the device. Data may
change only when SCL is LOW, except START and STOP

conditions. It is an open-drain output and may be wire­ORed with any number of open-drain or open-collector

outputs.
RESET# — Reset: RESET# — Reset:

RESET# — Reset: RESET# — Reset:

RESET# — Reset: This is an active low open drain output.
It is driven low whenever VCC is below V

TRIP

. It is also an
input and can be used to debounce a switch input or
perform signal conditioning. The pin has an internal pull-up
and should be left unconnected if the signal is not used in
the system. However, an external pull-up resistor must be
connected when the pin is tied to a system RESET# line.

VV

VV

V

CCCC

CCCC

CC

— Power — Power

— Power — Power

— Power: VCC is the voltage input, typically 2.7 to 5.5

volts.
GND — GroundGND — Ground

GND — GroundGND — Ground

GND — Ground: Power return.
NCNC

NCNC

NC —

No Connect: No Connect:

No Connect: No Connect:

No Connect: The no connect inputs are not used.
However, to ensure proper operation, they can be uncon­nected or tied to ground. They must not be tied to VCC.

PIN CONFIGURATIONPIN CONFIGURATION

PIN CONFIGURATIONPIN CONFIGURATION

PIN CONFIGURATION

NC

RESET#

NC

V

SS

V

CC

NC
SCL
SDA

1
2
3
4

8
7
6
5

SMS24163

8-Pin PDIP

or 8-Pin SOIC

2014 T PCon 2.0

S24163S24163

S24163S24163

S24163

3

2014 2.0 3/21/00

FIGURE 1. TYPICAL SYSTEM CONFIGURATIONFIGURE 1. TYPICAL SYSTEM CONFIGURATION

FIGURE 1. TYPICAL SYSTEM CONFIGURATIONFIGURE 1. TYPICAL SYSTEM CONFIGURATION

FIGURE 1. TYPICAL SYSTEM CONFIGURATION

FIGURE 3. START AND STOP CONDITIONSFIGURE 3. START AND STOP CONDITIONS

FIGURE 3. START AND STOP CONDITIONSFIGURE 3. START AND STOP CONDITIONS

FIGURE 3. START AND STOP CONDITIONS

FIGURE 2. INPUT DATA PROTOCOLFIGURE 2. INPUT DATA PROTOCOL

FIGURE 2. INPUT DATA PROTOCOLFIGURE 2. INPUT DATA PROTOCOL

FIGURE 2. INPUT DATA PROTOCOL

Data must

remain stable

while clock

is HIGH.

Data must

remain stable

while clock

is HIGH.

Change

of data

allowed

SCL

SDA In

t

HD:DAT

t

SU:DAT

t

HD:DAT

2014 ILL4 1.0

SCL

SDA In

START

Condition

STOP

Condition

2014 ILL5 1.0

SDA

SCL

(µC/ µP)(24163)

2014 T fig01 2.0

RESET

V

CC

Master

Transmitter

Slave

Transmitter/

Receiver

Master

Transmitter/

Receiver

Slave

Receiver

Master

Transmitter/

Receiver

4

S24163S24163

S24163S24163

S24163

2014 2.0 3/21/00

FIGURE 4. ACKNOWLEDGE RESPONSE FROM RECEIVERFIGURE 4. ACKNOWLEDGE RESPONSE FROM RECEIVER

FIGURE 4. ACKNOWLEDGE RESPONSE FROM RECEIVERFIGURE 4. ACKNOWLEDGE RESPONSE FROM RECEIVER

FIGURE 4. ACKNOWLEDGE RESPONSE FROM RECEIVER

Input Data ProtocolInput Data Protocol

Input Data ProtocolInput Data Protocol

Input Data Protocol
One data bit is transferred during each clock pulse. The
data on the SDA line must remain stable during clock
HIGH time, because changes on the data line while SCL
is HIGH will be interpreted as start or stop condition (See
Figure 2).

START and STOP ConditionsSTART and STOP Conditions

START and STOP ConditionsSTART and STOP Conditions

START and STOP Conditions
When both the data and clock lines are HIGH, the bus is
said to be not busy. A HIGH-to-LOW transition on the data
line, while the clock is HIGH, is defined as the “START”
condition. A LOW-to-HIGH transition on the data line, while
the clock is HIGH, is defined as the “STOP” condition (See
Figure 3).

DEVICE OPERATIONDEVICE OPERATION

DEVICE OPERATIONDEVICE OPERATION

DEVICE OPERATION

The S24163 is a 16,384-bit serial E2PROM. The device
supports the I2C bidirectional data transmission protocol.
The protocol defines any device that sends data onto the
bus as a “transmitter” and any device which receives data
as a “receiver.” The device controlling data transmission
is called the “master” and the controlled device is called
the “slave.” Since it never initiates any data transfers the
S24163 is always a “slave” device.

Acknowledge (ACK)Acknowledge (ACK)

Acknowledge (ACK)Acknowledge (ACK)

Acknowledge (ACK)
Acknowledge is a software convention used to indicate

successful data transfers. The transmitting device, either
the master or the slave, will release the bus after transmit-

ting eight bits. During the ninth clock cycle, the receiver
will pull the SDA line LOW to ACKnowledge that it
received the eight bits of data (See Figure 4).

The S24163 will respond with an ACKnowledge after
recognition of a START condition and its slave address
byte. If both the device and a write operation are selected,
the S24163 will respond with an ACKnowledge after the
receipt of each subsequent 8-bit word.

FIGURE 5. SLAVE ADDRESS BYTEFIGURE 5. SLAVE ADDRESS BYTE

FIGURE 5. SLAVE ADDRESS BYTEFIGURE 5. SLAVE ADDRESS BYTE

FIGURE 5. SLAVE ADDRESS BYTE

In the READ mode the S24163 transmits eight bits of data,
then releases the SDA line, and monitors the line for an
ACKnowledge signal. If an ACKnowledge is detected,
and no STOP condition is generated by the master, the
S24163 will continue to transmit data. If an ACKnowledge is
not detected the S24163 will terminate further data transmis­sions and await a STOP condition before returning to the
standby power mode.

Device AddressingDevice Addressing

Device AddressingDevice Addressing

Device Addressing
Following a start condition the master must output the
address of the slave it is accessing. The most significant
four bits of the slave address are the device type identifier
(see figure 5). For the S24163 this is fixed as 1010[B

HEX

].

Word AddressWord Address

Word AddressWord Address

Word Address
The next three bits of the slave address are an extension
of the array’s address and are concatenated with the eight

bits of address in the word address field, providing direct
access to the 2,048 X 8 array.

Read/Write BitRead/Write Bit

Read/Write BitRead/Write Bit

Read/Write Bit
The last bit of the data stream defines the operation to be

performed. When set to “1” a read operation is selected;
when set to “0” a write operation is selected.

SCL from

Master

Data Output

from

Transmitter

Data Output

from

Receiver

Start
Condition

ACKnowledge

t

AA

t

AA

1

8

9

2014 ILL6 1.0

1 0 1 0

A10 A9 A8 R/W

DEVICE

IDENTIFIER

HIGH ORDER

WORD ADDRESS

2014 ILL7 1.0