Microchip Technology Inc 24LCS21A-P, 24LCS21AT-I-SN, 24LCS21AT-I-P, 24LCS21AT-SN, 24LCS21AT-P Datasheet



C 

24LCS21A

2

1K 2.5V Dual Mode I



C

Serial EEPROM

FEATURES

• Single supply with operation down to 2.5V

• Completely implements DDC1  /DDC2 
interface for monitor identification, including
recovery to DDC1

• Low power CMOS technology

- 1 mA typical active current

- 10 µ A standby current typical at 5.5V

• 2-wire serial interface bus, I

• 100 kHz (2.5V) and 400 kHz (5V) compatibility

• Self-timed write cycle (including auto-erase)

• Hardware write-protect pin

• Page-write buffer for up to eight bytes

• 10,000,000 erase/write cycles guaranteed

• Data retention > 200 years

• ESD Protection > 4000V

• 8-pin PDIP and SOIC package

• Available for extended temperature ranges

- Commercial (C): 0 ° C to +70 ° C

- Industrial (I): -40 ° C to +70 ° C

2

compatible

DESCRIPTION

The Microchip Technology Inc. 24LCS21A is a 128 x 8­bit dual-mode Electrically Erasable PROM. This device
is designed for use in applications requiring storage
and serial transmission of configuration and control
information. Two modes of operation have been imple­mented: Transmit-Only Mode and Bi-directional Mode.
Upon power-up, the device will be in the Transmit-Only
Mode, sending a serial bit stream of the memory array
from 00h to 7Fh, clocked by the VCLK pin. A valid high
to low transition on the SCL pin will cause the device to
enter the transition mode, and look for a valid control
byte on the I
the master, it will switch into Bi-directional Mode, with
byte selectable read/write capability of the memory
array using SCL. If no control byte is received, the
device will revert to the Transmit-Only Mode after it
receives 128 consecutive VCLK pulses while the SCL
pin is idle. The 24LCS21A also enables the user to
write-protect the entire memory array using its write­protect pin. The 24LCS21A is available in a standard
8-pin PDIP and SOIC package in both commercial and
industrial temperature ranges.

2

C bus. If it detects a valid control byte from

PACKA GE TYPES

PDIP

NC

1

NC

2

WP

3

4

VSS

SOIC

NC
NC

WP

VSS

1
2

3

4

BLOCK DIAGRAM

WP

I/O

CONTROL

LOGIC

SDA SCL

VCLK

V

CC

VSS

MEMORY

CONTROL

LOGIC

8

24LCS21A

7

6

5

8

24LCS21A

7

6

5

XDEC

V

CC

VCLK

SCL

SDA

V

CC

VCLK

SCL

SDA

HV GENERATOR

EEPROM

ARRAY

PAGE LATCHES

YDEC

SENSE AMP

CONTROL

R/W

DDC is a trademark of the Video Electronics Standards Association.

2

I

C is a trademark of Philips Corporation.

1996 Microchip Technology Inc.

Preliminary

DS21161C-page 1

24LCS21A



≥

µ

µ

µ A µ

1.0 ELECTRICAL CHARACTERISTICS

1.1 Maxim

V

........................................................................7.0V

CC

All inputs and outputs w.r.t. V

Storage temperature ..........................-65 ° C to +150 ° C

Ambient temp. with power applied .....-65 ° C to +125 ° C

Soldering temperature of leads (10 seconds) ..+300 ° C

ESD protection on all pins .....................................≥ 4 kV

*Notice: Stresses above those listed under “Maximum ratings”

may cause permanent damage to the device. This is a stress rat­ing only and functional operation of the device at those or any
other conditions above those indicated in the operational listings
of this specification is not implied. Exposure to maximum rating
conditions for extended periods may affect device reliability.

TABLE 1-2: DC CHARACTERISTICS

V

= +2.5V to 5.5V

CC

Commercial (C): Tamb = 0 ° C to +70 ° C
Industrial (I): Tamb =-40 ° C to +85 ° C

um Ratings*

SS

.... -0.6V to V

CC

+1.0V

TABLE 1-1: PIN FUNCTION TABLE

Name Function

WP

SS

V

SDA Serial Address/Data I/O

SCL Serial Clock (Bi-directional Mode)

VCLK Serial Clock (Transmit-Only Mode)

CC

V

NC No Connection

Write Protect (active low)
Ground

+2.5V to 5.5V Power Supply

Parameter Symbol Min Max Units Conditions

SCL and SDA pins:

High level input voltage
Low level input voltage

V
V

0.7 V

IH
IL

—

CC

—

0.3 V

CC

V
V

Input levels on VCLK pin:

High level input voltage

Low level input voltage
Hysteresis of Schmitt trigger inputs V
Low level output voltage V
Low level output voltage V
Input leakage current I
Output leakage current I

V
V

HYS
OL1
OL2

LO

IH
IL

2.0
—

.05 V

CC

—

0.2 V

CC

V
V

— V (Note)
— 0.4 V I
— 0.6 V I

LI

-10 10

-10 10

AV
AV

Pin capacitance (all inputs/outputs) Cin, Cout — 10 pF V

Operating current I

Standby current I

CC

I

CC

Write
Read

CCS

—
—

—
—

3
1

30

100

mAmAV

A

Note: This parameter is periodically sampled and not 100% tested.

CC

V

2.7V (Note)

CC

V

< 2.7V (Note)

OL

= 3 mA, V

OL

= 6 mA, V

= 0.1V to V

IN

= 0.1V to V

OUT

= 5.0V (Note)

CC

Tamb = 25 ° C, F

= 5.5V

CC

V

CC

= 5.5V, SCL = 400 kHz

V

= 3.0V, SDA = SCL = V

CC
CC

V

= 5.5V, SDA = SCL = V

CC

= 2.5V (Note)

CC

= 2.5V

CC

CC

CLK

= 1 MHz

CC
CC

DS21161C-page 2

Preliminary

1996 Microchip Technology Inc.

TABLE 1-3: AC CHARACTERISTICS



24LCS21A

≤

Parameter Symbol

Vcc= 2.5-4.5V

Standard Mode

Vcc= 4.5 - 5.5V

Fast Mode

Units Remarks

Min Max Min Max

Clock frequency F
Clock high time T
Clock low time T
SDA and SCL rise time T
SDA and SCL fall time T
START condition hold time T

HD

CLK
HIGH
LOW

R
F

:

STA

— 100 — 400 kHz
4000 — 600 — ns
4700 — 1300 — ns

— 1000 — 300 ns

— 300 — 300 ns

(Note 1)
(Note 1)

4000 — 600 — ns After this period the first clock

pulse is generated

START condition setup
time

Data input hold time T
Data input setup time T
STOP condition setup time T
Output valid from clock T
Bus free time T

T

SU

STA

:

4700 — 600 — ns Only relevant for repeated

START condition

HD

DAT
SU
SU

:
:

DAT
STO

:

AA

BUF

0—0—ns

(Note 2)

250 — 100 — ns

4000 — 600 — ns

— 3500 — 900 ns

(Note 2)

4700 — 1300 — ns Time the bus must be free

before a new transmission
can start

Output fall time from V
minimum to V

IL

Input filter spike suppres-

IH

maximum

OF

T

T

SP

— 250 20 +

0.1 C

250 ns

B

— 50 — 50 ns

(Note 1), C

(Note 3)

B

100 pF

sion (SDA and SCL pins)
Write cycle time T

WR

— 10 — 10 ms Byte or Page mode

Transmit-Only Mode Parameters

Output valid from VCLK T
VCLK high time T

VAA

VHIGH

— 2000 — 1000 ns

4000 — 600 — ns
VCLK low time TVLOW 4700 — 1300 — ns
VCLK setup time T
VCLK hold time T
Mode transition time T
Transmit-Only power up

VHST 0—0—ns
SPVL 4000 — 600 — ns

VHZ — 1000 — 500 ns

T

VPU 0—0—ns

time
Input filter spike suppres-

SPV — 100 — 100 ns

T

sion (VCLK pin)
Endurance — 10M — 10M — cycles 25°C, Vcc = 5.0V , Block Mode

(Note 4)

Note 1: Not 100% tested. C

B = Total capacitance of one bus line in pF.

2: As a transmitter , the device must provide an internal minimum delay time to bridge the undefined region (min-

imum 300 ns) of the falling edge of SCL to avoid unintended generation of START or STOP conditions.

3: The combined T

suppression. This eliminates the need for a T

SP and VHYS specifications are due to Schmitt trigger inputs which provide noise and spike

I specification for standard operation.

4: This parameter is not tested but guaranteed by characterization. For endurance estimates in a specific appli-

cation, please consult the Total Endurance Model which can be obtained on our BBS or website.

1996 Microchip Technology Inc.

Preliminary

DS21161C-page 3

24LCS21A

2.0 FUNCTIONAL DESCRIPTION

The 24LCS21A is designed to comply to the DDC Stan­dard proposed by VESA (Figure 3-3) with the exception
that it is not Access.bus capable. It operates in two
modes, the Transmit-Only Mode and the Bi-directional
Mode. There is a separate 2-wire protocol to support
each mode, each having a separate clock input but
sharing a common data line (SDA). The device enters
the Transmit-Only Mode upon power-up. In this mode,
the device transmits data bits on the SDA pin in
response to a clock signal on the VCLK pin. The device
will remain in this mode until a valid high to low transi­tion is placed on the SCL input. When a valid transition
on SCL is recognized, the device will switch into the Bi­directional Mode and look for its control byte to be sent
by the master. If it detects its control byte, it will stay in
the Bi-directional Mode. Otherwise, it will revert to the
Transmit-Only Mode after it sees 128 VCLK pulses.

2.1 Transmit-Only Mode

The device will power up in the Transmit-Only Mode at
address 00H. This mode supports a unidirectional
2-wire protocol for continuous transmission of the
contents of the memory array. This device requires that
it be initialized prior to valid data being sent in the Trans-

mit-Only Mode (Section 2.2). In this mode, data is
transmitted on the SDA pin in 8-bit bytes, with each byte
followed by a ninth, null bit (Figure 2-1). The clock
source for the Transmit-Only Mode is provided on the
VCLK pin, and a data bit is output on the rising edge on
this pin. The eight bits in each byte are transmitted most
significant bit first. Each byte within the memory array
will be output in sequence. After address 7Fh in the
memory array is transmitted, the internal address point­ers will wrap around to the first memory location (00h)
and continue. The Bi-directional Mode Clock (SCL) pin
must be held high for the device to remain in the
Transmit-Only Mode.

2.2 Initialization Procedure

After VCC has stabilized, the device will be in the
Transmit-Only Mode. Nine clock cycles on the VCLK pin
must be given to the device for it to perform internal
sychronization. During this period, the SDA pin will be
in a high impedance state. On the rising edge of the
tenth clock cycle, the device will output the first valid
data bit which will be the most significant bit in address
00h. (Figure 2-2).

FIGURE 2-1: TRANSMIT-ONLY MODE

SCL

Tvaa Tvaa

SDA

Bit 1 (LSB)

VCLK

TvlowTvhigh

FIGURE 2-2: DEVICE INITIALIZATION

Vcc
SCL

SDA

Tvpu

VCLK

12 891011

Null Bit

Bit 1 (MSB) Bit 7

Tvaa Tvaa

Bit 8 Bit 7High Impedance for 9 clock cycles

DS21161C-page 4 Preliminary  1996 Microchip Technology Inc.

24LCS21A

3.0 BI-DIRECTIONAL MODE

Before the 24LCS21A can be switched into the Bi­directional Mode (Figure 3-1), it must enter the transi­tion mode, which is done by applying a valid high to low
transition on the Bi-directional Mode Clock (SCL). As
soon it enters the transition mode, it looks for a control
byte 1010 000X on the I
pulses on VCLK. Any high to low transition on the SCL
line will reset the count. If it sees a pulse count of 128
on VCLK while the SCL line is idle, it will revert back to
the Transmit-Only Mode, and transmit its contents start­ing with the most significant bit in address 00h. How­ever, if it detects the control byte on the I
(Figure 3-2) it will switch to the in the Bi-directional
Mode. Once the device has made the transition to the
Bi-directional mode, the only way to switch the device
back to the Transmit-Only Mode is to remove power
from the device. The mode transition process is shown
in detail in Figure 3-3.

2

C bus, and starts to count

2

C bus,

Once the device has switched into the Bi-directional
Mode, the VCLK input is disregarded, with the excep­tion that a logic high level is required to enable write
capability. This mode supports a two-wire Bi-directional
data transmission protocol (I
device that sends data on the bus is defined to be the
transmitter, and a device that receives data from the
bus is defined to be the receiver. The bus must be con­trolled by a master device that generates the Bi-direc­tional Mode Clock (SCL), controls access to the bus
and generates the START and STOP conditions, while
the 24LCS21A acts as the slave. Both master and
slave can operate as transmitter or receiver, but the
master device determines which mode is activated. In
the Bi-directional mode, the 24LCS21A only responds
to commands for device 1010 000X.

2

C). In this protocol, a

FIGURE 3-1: MODE TRANSITION WITH RECOVERY TO TRANSMIT-ONLY MODE

MODE

Transmit

Only

Bi-directional

TVHZ

Recovery to Transmit-Only Mode

SCL

(MSB of data in 00h)

SDA

VCLK count = 1 2 3 4 127 128

VCLK

Bit8

FIGURE 3-2: SUCCESSFUL MODE TRANSITION TO BI-DIRECTIONAL MODE

Transmit
Only Mode

MODE
SCL

SDA

VCLK count = 1 2 n 0

VCLK

Transition Mode with possibility to return to Transmit-Only Mode

S1010 00 0 0 ACK

n < 128

Bi-directional

permanently

 1996 Microchip Technology Inc. Preliminary DS21161C-page 5