BR24G04FVM-3AGTTR - ROHM Co., Ltd.

1/20

www.rohm.com

20

1

2.2

-

Rev.C

High Reliability Series Serial EEPROM Series

I

2

C BUS

Serial EEPROMs

BR24G□□

□□□□

□□□

□□

□-3A Series

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BR24G01-3A,

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BR24G02-3A,

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BR24G04-3A,

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BR24G08-3A,

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BR24G16-3A,

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BR24G32-3A,

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BR24G64-3A, BR24G128-3A, BR24G256-3A,

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BR24G512-3A,

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BR24G1M-3A

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☆:BR24G01/02/04/08/16/32/64/512/1M-3A are model, the description matters are target all specifications because of the

model under development.

ROHM's series of serial EEPROMs represent the highest level of reliability on the market. A double cell structure provides a

failsafe method of data reliability, while a double reset function prevents data miswriting, pushing the boundaries of reliability

to the limit.

Contents

BR24G□□

□□□□

□□□

□□

□-3A Series

BR24G01-3A, BR24G02-3A, BR24G04-3A, BR24G08-3A,

BR24G16-3A, BR24G32-3A, BR24G64-3A, BR24G128-3A,

BR24G256-3A, BR24G512-3A, BR24G1M-3A

Technical Note

2/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

I

2

C BUS Serial EEPROMs

BR24G□

□□

□-3A Series

BR24G01-3A, BR24G02-3A, BR24G04-3A, BR24G08-3A, BR24G16-3A, BR24G32-3A,

BR24G64-3A, BR24G128-3A, BR24G256-3A, BR24G512-3A, BR24G1M-3A

●Description

BR24G□□□-3A series is a serial EEPROM of I

2

C BUS interface method

●Features

・ All controls available by 2 ports of serial clock(SCL) and serial data(SDA)

・ Other devices than EEPROM can be connected to the same port, saving microcontroller port

・ 1.7V～5.5V single power source action most suitable for battery use

・ 1.7V～5.5Ｖwide limit of action voltage, possible 1MHz action

・ Page write mode useful for initial value write at factory shipment

・ Auto erase and auto end function at data write

・ Low current consumption

・ Write mistake prevention function

Write (write protect) function added

Write mistake prevention function at low voltage

・ DIP-T8/SOP8/SOP-J8/SSOP-B8/TSSOP-B8/TSSOP-B8J/MSOP8/VSON008X2030 various package

・ Data rewrite up to 1,000,000 times

・ Data kept for 40 years

・ Noise filter built in SCL / SDA terminal

・ Shipment data all address FFh

●BR24G series

Capacity

Bit format Type

Power source

Voltage DIP-T8 SOP8 SOP-J8 SSOP-B8 TSSOP-B8

TSSOP-B8J MSOP8 VSON008

X2030

1Kbit 128×8 BR24G01-3A 1.7～5.5V

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2Kbit 256×8 BR24G02-3A 1.7～5.5V

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4Kbit 512×8 BR24G04-3A 1.7～5.5V

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8Kbit 1K×8 BR24G08-3A 1.7～5.5V

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16Kbit 2K×8 BR24G16-3A 1.7～5.5V

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32Kbit 4K×8 BR24G32-3A 1.7～5.5V

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64Kbit 8K×8 BR24G64-3A 1.7～5.5V

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128Kbit 16K×8 BR24G128-3A 1.7～5.5V

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256Kbit 32K×8 BR24G256-3A 1.7～5.5V

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512Kbit 64K×8 BR24G512-3A 1.7～5.5V

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1024Kbit

128K×8 BR24G1M-3A 1.7～5.5V

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☆:Developing

Technical Note

3/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

SCL

SDA

(input)

SDA

(output)

tR tF1 tHIGH

tSU:DAT tLOW tHD:DAT

tDH

tPD

tBUF

tHD:STA

70%

30%

70%

30%

70% 70%

30% 30%

70% 70%

30%

70% 70%

70%

30%

30% 30%

tF2

●Sync data input / output timing

○

Input read at the rise edge of SCL

○

Data output in sync with the fall of SCL

Fig.1-(a) Sync data input / output timing

Fig.1-(b) Start-stop bit timing

Fig.1-(c) Write cycle timing

Fig.1-(d) WP timing at write execution

Fig.1-(e) WP timing at write cancel

●Absolute maximum ratings (Ta=25℃)

Parameter symbol Limits Unit

Impressed voltage V

CC

-0.3～+6.5 V

Permissible

dissipation Pd

450 (SOP8)

*1

mW

450 (SOP-J8)

*2

300 (SSOP-B8)

*3

330 (TSSOP-B8)

*4

310 (TSSOP-B8J)

*5

310 (MSOP8)

*6

300 (VSON008X2030)

*7

800 (DIP-T8)

*8

Storage temperature range Tstg －65～+150 ℃

Action temperature range Topr －40～+85 ℃

Terminal voltage ‐ －0.3～Vcc+1.0

*9

V

Junction Temperature

*10

Tjmax 150 ℃

●Memory cell characteristics (Ta=25℃, Vcc=1.7～5.5V)

Parameter Limits Unit

Min. Typ. Max

Number of data rewrite times *1 1,000,000 －－ Times

Data hold years *1 40 －－ Years

*1

Not 100% TESTED

●Recommended operating conditions

Parameter Symbol Limits Unit

Power source voltage Vcc 1.7～5.5 V

Input voltage V

IN

0～Vcc

When using at Ta=25℃ or higher, 8.0mW(*8), 4.5mW(*1,*2),

3.0mW(*3,*7), 3.3mW(*4), 3.1mW(*5, *6) to be reduced per 1℃.

*9 The Max value of Terminal Voltage is not over 6.5V.

When the pulse width is 50ns or less,

the Min value of Terminal Voltage is not under -1.0V. (BR24G16/32/64/128/256/512/1M-3A)

the Min value of Terminal Voltage is not under -0.8V. (BR24G01/02/04/08-3A)

*10 Junction temperature at the storage condition.

●Electrical characteristics

(

Unless otherwise specified, Ta=－40～+85

℃、

VCC=1.7～5.5V

)

Parameter

Symbol

Limits

Unit

Conditions

Min. Typ. Max.

“H” input voltage 1 V

IH1

0.7Vcc － Vcc+1.0 V

“L” input voltage 1 V

IL1

－0.3

*1

－ 0.3Vcc V

“L” output voltage 1 V

OL1

－－ 0.4 V I

OL

=3.0mA, 2.5V≦Vcc≦5.5V (SDA)

“L” output voltage 2 V

OL2

－－ 0.2 V I

OL

=0.7mA, 1.7V≦Vcc＜2.5V (SDA)

Input leak current I

LI

－1 － 1 µA V

IN

=0～Vcc

Output leak current I

LO

－1 － 1 µA V

OUT

=0～Vcc (SDA)

Current consumption

at action

I

CC1

－－ 2.0 mA Vcc=5.5V,f

SCL

=400kHz, t

WR

=5ms,

Byte write, Page write

BR24G01/02/04/08/16/32/64-3A

－－ 2.5 mA Vcc=5.5V,f

SCL

=400kHz, t

WR

=5ms,

Byte write, Page write

BR24G128/256-3A

－－ 4.5 mA Vcc=5.5V,f

SCL

=400kHz, t

WR

=5ms,

Byte write, Page write

BR24G512/1M-3A

I

CC2

－－ 0.5 mA

Vcc=5.5V,f

SCL

=1MHz

Random read, current read,

sequential read

BR24G01/02/04/08/16/32/64-3A

－－ 2.0 mA

Vcc=5.5V,f

SCL

=1MHz

Random read, current read,

sequential read

BR24G128/256/512/1M-3A

Standby current I

SB

－－ 2.0

µA

Vcc=5.5V, SDA・SCL=Vcc

A0,A1,A2=GND,WP=GND

BR24G01/02/04/08/16/32/64/128/256-3A

－－ 3.0

µA

Vcc=5.5V, SDA・SCL=Vcc

A0,A1,A2=GND,WP=GND

BR24G512/1M-3A

○Radiation resistance design is not made.

*1

When the pulse width is 50ns or less, it is -1.0V. (BR24G16/32/64/128/256/512/1M-3A)

When the pulse width is 50ns or less, it is -0.8V. (BR24G01/02/04/08-3A)

◇ AC OPERATING CHARACTERISTICS

(Unless otherwise specified, Ta=－40～+85℃, VCC=1.7～5.5V)

Parameter Symbol Limit Unit

Min. Typ. Max.

SCL frequency fSCL －－ 1000 kHz

Data clock “HIGH“ time tHIGH 0.3 －－ μs

Data clock “LOW“ time tLOW 0.5 －－ μs

SDA and SCL rise time

*1

tR －－ 0.12 μs

SDA and SCL fall time

*1

tF1 －－ 0.12 μs

SDA (OUT) fall time

*1

tF2 －－ 0.12 μs

Start condition hold time tHD:STA 0.25 －－ μs

Start condition setup time tSU:STA 0.25 －－ μs

Input data hold time tHD:DAT 0 －－ μs

Input data setup time tSU:DAT 50 －－ ns

Output data delay time tPD 0.05 － 0.45 μs

Output data hold time tDH 0.05 －－ μs

Stop condition setup time tSU:STO 0.25 －－ μs

Bus release time before transfer start tBUF 0.5 －－ μs

Internal write cycle time tWR －－ 5 ms

Noise removal valid period (SDA, SCL terminal) tI －－ 0.05 μs

WP hold time tHD:WP 1.0 －－ μs

WP setup time tSU:WP 0.1 －－ μs

WP valid time tHIGH:WP 1.0 －－ μs

*1 Not 100% TESTED.

●AC TIMING CHARACTERISTICS CONDITION

Parameter

Symbol

Condition

Unit

Load Capacitance

CL 100 pF

SDA and SCL rise time

tR 20 ns

SDA and SCL fall time

tF1 20 ns

Input Data Level

VIL/VIH 0.2Vcc/0.8Vcc V

Input/Output Data Timing Refence Level

－ 0.3Vcc/0.7Vcc V

*1

70% 70%

tSU:STA tHD:STA

START CONDITION

tSU:STO

STOP CONDITION

30%

70%

D0 ACK

tWRwrite data

(n-th address)

START CONDITION

STOP CONDITION

70%

DATA(1)

D0 ACK

D1

DATA(n)

ACK tWR

30%

70%

STOP CONDITION

tHD:WP

tSU:WP

30%

70%

DATA(1)

D0

D1 ACK

DATA(n)

ACK

tHIGH:WP

70% 70%

tWR

70%

Technical Note

4/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●Block diagram

●Pin assignment and description

●Characteristic data (The following values are Typ. ones.)

0

1

2

3

4

5

6

0123456

SUPPLY VOLTAGE : Vcc(V)

H INPUT VOLTAGE : VIH1(V)

0

0.2

0.4

0.6

0.8

1

1.2

0 1 2 3 4 5 6

SUPPLYVOLTAGE : Vcc(V)

INPUT LEAK CURRENT : ILI(uA)

0

0.2

0.4

0.6

0.8

1

0123456

L OUTPUT CURRENT : IOL(mA)

L OUTPUT VOLTAGE : VOL2(V)

0

0.2

0.4

0.6

0.8

1

1.2

0123456

SUPPLY VOLTAGE : Vcc(V)

OUTPUT LEAK CURRENT : I LO(uA)

0

0.2

0.4

0.6

0.8

1

0123456

L OUTPUT CURRENT : IOL(mA)

L OUTPUT VOLTAGE : VOL1(V)

Fig.5 'L' output voltage VOL1-IOL(Vcc=1.7V)

0

1

2

3

4

5

6

0123456

SUPPLY VOLTAGE : Vcc(V)

L INPUT VOLTAGE : VIL1(V)

Fig.6　'L' output voltage VOL2-IOL(Vcc=2.5V) Fig.7　Input leak current ILI

(A0,A1,A2,SCL,WP) Fig.8　Output leak current ILO(SDA)

Fig.4　'L' input voltage VIL1

(A0,A1,A2,SCL,SDA,WP)

Fig.3　'H' input voltage VIH1

(A0,A1,A2,SCL,SDA,WP)

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

SPEC

SPEC SPEC

8

7

6

5

4

3

2

1

SDA

SCL

WP

V

cc

GND

A2

A1

A0

Address

decoder

Word

address

register

Data

register

Control circuit

High voltage

generating circuit

Power source

voltage detection

8bit

ACK

START

STOP

1

Kbit

～

1024

Kbit EEPROM

array

*1

*2

14bit

8bit

9

bit

1

0

bit

1

bit

1

2

13bit

Fig.2

Block diagram

＊

1 7bit: BR24G01-3A

8bit: BR24G02-3A

9bit: BR24G04-3A

10bit: BR24G08-3A

11bit: BR24G16-3A

12bit: BR24G32-3A

Vcc

SCL

GND

BR

24G

01

-

3A

BR

24G

02

-

3A

BR

24G

04

-

3A

BR

24G

08

-

3A

BR

24G

16

-

3A

BR

24G

32

-

3A

BR

24G

64

-

3A

1

2

3

4

5

6

7

8

WP

SDA

A2

A1

A0

Terminal

Name Input/

Output BR24G01-3A

BR24G02-3A

BR24G04-3A

BR24G08-3A

BR24G16-3A BR24G32/64/128/256/512-3A BR24G1M-3A

A0 Input Slave address setting Don’t use＊ Slave address setting Don’t use＊

A1 Input Slave address setting Don’t use＊ Slave address setting

A2 Input Slave address setting Don’t use＊ Slave address setting

GND － Reference voltage of all input / output, 0V

SDA

Input/

output

Serial data input serial data output

SCL Input Serial clock input

WP Input Write protect terminal

Vcc － Connect the power source.

＊Pins not used as device address may be set to any of ‘H’, 'L', and 'Hi-Z'.

13bit: BR24G64-3A

14bit: BR24G128-3A

15bit: BR24G256-3A

16bit: BR24G512-3A

17bit: BR24G1M-3A

*2 A0= Don't use : BR24G04/1M-3A

A0, A1=Don't use : BR24G08-3A

A0, A1, A2=Don't use : BR24G16-3A

BR

24G

128

256

512

1M

-

3A

7bit

15bit

16bit

17bit

Technical Note

5/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

0

0.5

1

1.5

2

2.5

0123456

STANBY CURRENT : I

SB

(uA)

SUPPLY VOLTAGE : Vcc(V)

0

0.5

1

1.5

2

2.5

3

3.5

0123456

CURRENT CONSUMPTION

AT WRITING : Icc1(mA)

SUPPLY VOLTAGE : Vcc(V)

0

0.5

1

1.5

2

2.5

0123456

STANBY CURRENT : I

SB

(uA)

SUPPLY VOLTAGE : Vcc(V)

-0.1

0.1

0.3

0.5

0.7

0.9

1.1

0 1 2 3 4 5 6

START CONDITION

SET UP TIME : tSU:STA(us)

SUPPLY VOLTAGE : Vcc(V)

0.1

1

10

100

1000

10000

0123456

SCL FREQUENCY : fｓｃｌ（ｋHZ）

SUPPLY VOLTAGE : Vcc(V)

-200

-150

-100

-50

0

50

0 1 2 3 4 5 6

INPUT DATA HOLD TIME : t

HD: STA

(ns)

SUPPLY VOLTAGE : Vcc(V)

0

0.2

0.4

0.6

0.8

1

0 1 2 3 4 5 6

DATA CLK H TIME : t

HIGH

(us)

SUPPLY VOLTAGE : Vcc(V)

0

0.5

1

1.5

2

2.5

0123456

CURRENT CONSUMPTION

AT WRITING : Icc1(mA)

SUPPLY VOLTAGE : Vcc(V)

Fig.9 Current consumption at WRITE operation I

CC

1

(fscl=1MHz BR24G01/02/04/08/16/32/64-3A) Fig.10 Current consumption at WRITE operation Icc1

(fscl=1MHz BR24G128/256-3A)

Fig.14 Standby operation I

SB

(BR24G01/02/04/08/16/32/64/128/256-3A)

Fig.17 Data clock High Period t

HIGH

0

0.3

0.6

0.9

1.2

1.5

0123456

ＤＡＴＡ CLK L TIME : tLOW(us)

SUPPLY VOLTAGE : Vcc（V）

Fig.18 Data clock Low Period t

LOW

0

0.2

0.4

0.6

0.8

1

0 1 2 3 4 5 6

START CONDITION HOLD TIME : t

HD : STA

(us)

SUPPLY VOLTAGE : Vcc(V)

Fig.19 Start Condition Hold Time t

HD : STA

Fig.20 Start Condition Setup Time t

SU : STA

Fig.21 Input Data Hold Time t

HD : DAT

（HIGH） Fig.23 Input Data Setup Time ｔ

SU: DAT

(HIGH)

-200

-150

-100

-50

0

50

0123456

INPUT DATA HOLD TIME : t

HD :DAT

(ns)

SUPPLY VOLTAGE : Vcc(V)

-200

-100

0

100

200

300

0123456

INPUT DATA SET UP TIME : t

SU: DAT

(ns)

SUPPLY VOLTAGE : Vcc(V)

Fig.16 SCL frequency f

SCL

Fig.12 Current consumption at READ operation I

CC

2

(fscl=1MHz BR24G01/02/04/08/16/32/64/-3A)

0

1

2

3

4

5

6

0123456

CURRENT CONSUMPTION

AT WRITING : Icc1(mA)

SUPPLY VOLTAGE : Vcc(V)

Fig.11 Current consumption at WRITE operation Icc1

(fscl=1MHz BR24G512/1M-3A)

0

0.1

0.2

0.3

0.4

0.5

0.6

0123456

CURRENT CONSUMPTION

AT READING : Icc2(mA)

SUPPLY VOLTAGE : Vcc(V)

Fig.13 Current consumption at READ operation I

CC

2

(fscl=1MHz BR24G128/256/512/1M-W)

Fig.15 Standby operation I

SB

(BR24G512/1M-3A)

0

0.1

0.2

0.3

0.4

0.5

0.6

0123456

CURRENT CONSUMPTION

AT READING : Icc2(mA)

SUPPLY VOLTAGE : Vcc(V)

SPEC

The plan for

inserting data.

(BR24G128/256/512/

1M-3A)

The plan for

inserting data.

(BR24G512/1M-3A)

Ta=-40℃

Ta=25℃

Ta=85℃

Ta=-40℃

Ta=25℃

Ta=85℃

The plan for

inserting data.

(BR24G512/1M-3A)

The plan for

inserting data.

(BR24G01/02/08/16/

32/64-3A)

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data. The plan for

inserting data.

The plan for

inserting data. The plan for

inserting data.

Ta=-40℃

Ta=25℃

Ta=85℃

Fig.22 Input Data Hold Time ｔ

HD : DAT

(LOW）

●Characteristic data (The following values are Typ. ones.)

Technical Note

6/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

0

0.5

1

1.5

2

0 1 2 3 4 5 6

BUS OPEN TIME

BEFORE TRANSMISSION : t

BUF

(us)

SUPPLY VOLTAGE : Vcc(V)

0

1

2

3

4

5

6

0123456

INTERNAL WRITING

CYCLE TIME : t

WR

(ms)

SUPPLY VOLTAGE : Vcc(V)

-200

-100

0

100

200

300

0123456

INPUT DATA SET UP TIME : t

SU : DAT

(ns)

SUPPLY VOLTAGE : Vcc(V)

0.0

0.5

1.0

1.5

2.0

0123456

OUTPUT DATA DELAY TIME : t

PD

(us)

SUPPLY VOLTAGE : Vcc(V)

Fig.24 Input Data setup time t

SU : DAT

(LOW) Fig.25 'L' Data output delay time t

PD

0Fig.26 'H' Data output delay time ｔ

PD

1

Fig.28 BUS open time before transmission ｔ

BUF

Fig.29 Internal writing cycle time ｔ

WR

0

0.1

0.2

0.3

0.4

0.5

0.6

0123456

NOISE REDUCTION

EFECTIVE TIME : t

l

(SCL H) (us)

SUPPLY VOLTAGE : Vcc(V)

Fig.30 Noise reduction efection time t

l

（SCL H） Fig.31 Noise reduction efective time t

l

（SCL L）

0

0.1

0.2

0.3

0.4

0.5

0.6

0 1 2 3 4 5 6

NOISE REDUCTION

EFECTIVE TIME : t

l

(SCL L)(us)

SUPPLY VOLTAGE : Vcc(V)

Fig.32 Noise resuction efecctive time ｔ

ｌ

（SDA H）

0

0.1

0.2

0.3

0.4

0.5

0.6

0123456

NOISE REDUCTION

EFECTIVE TIME : t

l

(SDA H)(us)

SUPPLY VOLATGE : Vcc(V)

Fig.33 Noise reduction efective time t

l

（SDA L）

0

0.1

0.2

0.3

0.4

0.5

0.6

0123456

NOISE REDUCTION

EFFECTIVE TIME : t

l

(SAD L)(us)

SUPPLY VOLTAGE : Vcc(V)

Fig.35 WP setup time t

SU : WP

-0.6

-0.5

-0.4

-0.3

-0.2

-0.1

0.0

0.1

0.2

0 1 2 3 4 5 6

WP SET UP TIME : t

SU : WP

(us)

SUPPLY VOLTAGE : Vcc(V)

Fig.36 WP efective time t

HIGH : WP

0.0

0.2

0.4

0.6

0.8

1.0

1.2

0 1 2 3 4 5 6

WP EFFECTIVE TIME : t

HIGH : WP

(us)

SUPPLYVOLTAGE : Vcc(V)

SPEC

0.0

0.5

1.0

1.5

2.0

0123456

OUTPUT DATA DELAY TIME : t

PD

(us)

SUPPLY VOLTAGE : Vcc(V)

-0.5

0.0

0.5

1.0

1.5

2.0

0123456

STOP CONDITION SETUP TIME : t

su

:STO(us)

SUPPLY VOLTAGE : Vcc(V)

0.0

0.2

0.4

0.6

0.8

1.0

1.2

0123456

WP DATA HOLD TIME : t

HD : WP

(us)

SUPPLYVOLTAGE : Vcc(V)

Fig.27 Stop condition setup time

ｔ

SU

:STO

Ta=-40℃

Ta=25℃

Ta=85℃

Fig.34 WP data hold time tHD:WP

SPEC

The plan for

inserting data. The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

The plan for

inserting data.

Ta=-40℃

Ta=25℃

Ta=85℃

●Characteristic data (The following values are Typ. ones.)

Technical Note

7/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●I

2

C BUS communication

○I

2

C BUS data communication

I

2

C BUS data communication starts by start condition input, and ends by stop condition input. Data is always 8bit long, and

acknowledge is always required after each byte. I

2

C BUS carries out data transmission with plural devices connected by 2

communication lines of serial data (SDA) and serial clock (SCL).

Among devices, there are “master” that generates clock and control communication start and end, and “slave” that is

controlled by address peculiar to devices. EEPROM becomes “slave”. And the device that outputs data to bus during data

communication is called “transmitter”, and the device that receives data is called “receiver”.

○Start condition (Start bit recognition)

・Before executing each command, start condition (start bit) where SDA goes from 'HIGH' down to 'LOW' when SCL is

'HIGH' is necessary.

・This IC always detects whether SDA and SCL are in start condition (start bit) or not, therefore, unless this condition is

satisfied, any command is executed.

○Stop condition (stop bit recongnition)

・Each command can be ended by SDA rising from 'LOW' to 'HIGH' when stop condition (stop bit), namely, SCL is 'HIGH'

○Acknowledge (ACK) signal

・This acknowledge (ACK) signal is a software rule to show whether data transfer has been made normally or not. In

master and slave, the device (μ-COM at slave address input of write command, read command, and this IC at data

output of read command) at the transmitter (sending) side releases the bus after output of 8bit data.

・The device (this IC at slave address input of write command, read command, and μ-COM at data output of read

command) at the receiver (receiving) side sets SDA 'LOW' during 9 clock cycles, and outputs acknowledge signal (ACK

signal) showing that it has received the 8bit data.

・This IC, after recognizing start condition and slave address (8bit), outputs acknowledge signal (ACK signal) 'LOW'.

・Each write action outputs acknowledge signal (ACK signal) 'LOW', at receiving 8bit data (word address and write data).

・Each read action outputs 8bit data (read data), and detects acknowledge signal (ACK signal) 'LOW'. When acknowledge

signal (ACK signal) is detected, and stop condition is not sent from the master (μ-COM) side, this IC continues data

output. When acknowledge signal (ACK signal) is not detected, this IC stops data transfer, and recognizes stop condition

(stop bit), and ends read action. And this IC gets in status.

○Device addressing

・Output slave address after start condition from master.

・The significant 4 bits of slave address are used for recognizing a device type.

The device code of this IC is fixed to '1010'.

・Next slave addresses (A2 A1 A0 --- device address) are for selecting devices, and plural ones can be used on a same

bus according to the number of device addresses.

・ The most insignificant bit (R/W --- READ / WRITE) of slave address is used for designating write or read action, and is

as shown below.

Setting R /

W

――

to 0 ------- write (setting 0 to word address setting of random read)

Setting R /

W

――

to 1 ------- read

P0

～

P2 are page select bits.

Type

Slave address

Maximum number of

Connected buses

BR24G01-3A,BR24G02-3A 1 0 1 0 A2 A1 A0 R/

W

――

8

BR24G04-3A 1 0 1 0 A2 A1 P0 R/

W

――

4

BR24G08-3A 1 0 1 0 A2 P1 P0 R/

W

――

2

BR24G16-3A 1 0 1 0 P2 P1 P0 R/

W

――

1

BR24G32-3A, BR24G64-3A,

BR24G128-3A,BR24G256-3A,

BR24G512-3A 1 0 1 0 A2 A1 A0 R/

W

――

8

BR24G1M-3A 1 0 1 0 A2 A1 P0 R/

W

――

4

8 9 8 9 8 9

S P

condition condition

ACK STOPACKDATA DATA

ADDRESS

START R/W ACK

1-7

SDA

SCL 1-7 1-7

Fig.37 Data transfer timing

Technical Note

8/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●Write Command

○Write cycle

・Arbitrary data is written to EEPROM. When to write only 1 byte, byte write is normally used, and when to write continuous data of 2 bytes or

more, simultaneous write is possible by page write cycle. The maximum number of write bytes is specified per device of each capacity.

up to 256 arbitrary bytes can be written. (In the case of BR24G1M-3A)

W

R

I

T

E

S

T

A

R

T

R

/

W

A

C

K

S

T

O

P

WORD

ADDRESS(n)

DATA(n)

SDA

LINE

A

C

K

A

C

K

DATA(n+15)

A

C

K

SLAVE

ADDRESS

1

0

1

0

A0

A1

A2

WA

7

D0

D7

D0

WA

0

A1 A2 WA

7 D7

1 1 0 0

W

R

I

T

E

S

T

A

R

T

R

/

W

S

T

O

P

WORD

ADDRESS DATA

SLAVE

ADDRESS

A0 WA

0 D0

A

C

K

SDA

LINE

A

C

K

A

C

K

Note

)

Fig.38

Byte write cycle

(BR24G01/02/04/08/16-3A)

A1 A2

WA

14

1 1 0 0

W

R

I

T

E

S

T

A

R

T

R

/

W

S

T

O

P

1st WORD

ADDRESS DATA

SLAVE

ADDRESS

A0 D0

A

C

K

SDA

LINE

A

C

K

A

C

K

Note

)

WA

13 WA

12 WA

11 WA

0

A

C

K

2nd WORD

ADDRESS

D7

*1

WA

15

*1 As for WA12, BR24G32-3A becomes Don't care.

As for WA13, BR24G32/64-3A becomes Don't care.

As for WA14, BR24G32/64/128-3A becomes Don't care.

As for WA15, BR24G32/64/128/256-3A becomes Don't care.

Fig.39

Byte write cycle

(BR24G32/64/128/256/512/1M -3A)

Fig.40

Page write cycle

(BR24G01/02/04/08/16-3A)

Fig.41

Page write cycle

(BR24G32/64/128/256/512/1M -3A)

*1 As for WA12, BR24G32-3A becomes Don't care.

As for WA13, BR24G32/64-3A becomes Don't care.

As for WA14, BR24G32/64/128-3A becomes Don't care.

As for WA15, BR24G32/64/128/256-3A becomes Don't care.

*2 As for BR24G128/256-3A becomes (n+63)

As for BR24G128/256-3A becomes (n+127)

As for BR24G128/256-3A becomes (n+255)

W

R

I

T

E

S

T

A

R

T

R

/

W

A

C

K

S

T

O

P

1st WORD

ADDRESS(n)

SDA

LINE

A

C

K

A

C

K

DATA(n+31)

A

C

K

SLAVE

ADDRESS

1

0

1

0

A0

A1

A2

WA

14

D0

*1

DATA(n)

D0

D7

A

C

K

2nd WORD

ADDRESS(n)

WA

0

WA

13

WA

12

WA

11

10

0

1 A0

A1

A2

*1 *2 *3

Note)

Fig.42 Difference of slave address of each type

As for

WA7, BR24G01-3A becomes Don't care.

*1

As for

WA7, BR24G01-3A becomes Don't care.

*2

As for

BR24G01/02-3A becomes (n+7)

*2

*1

WA

15

*1 In BR24G16-3A, A2 becomes P2.

*2 In BR24G08/16-3A, A1 becomes P1.

*3 In BR24G04/08/16/1M-3A A0 becomes P0.

Note)

*2

Technical Note

9/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

・During internal write execution, all input commands are ignored, therefore ACK is not sent back.

・Data is written to the address designated by word address (n-th address)

・By issuing stop bit after 8bit data input, write to memory cell inside starts.

・When internal write is started, command is not accepted for tWR (5ms at maximum).

・By page write cycle, the following can be written in bulk : Up to 8Byte (BR24G01-3A, BR24G02-3A）

Up to 16Byte (BR24G04-3A, BR24G08-3A, BR24G16-3A）

Up to 32Byte (BR24G32-3A, BR24G64-3A）

Up to 64Byte (BR24G128-3A, BR24G256-3A）

Up to 128Byte (BR24G512 -3A）

Up to 256Byte (BR24G1M-3A）

And when data of the maximum bytes or higher is sent, data from the first byte is overwritten.

(Refer to "Internal address increment" of "Notes on page write cycle" in P10.)

・ As for page write cycle of BR24G01-3A and BR24G02-3A, after the significant 4 bits (in the case of BR24G01-3A) of word address,

or the significant 5 bits (in the case of BR24G02-3A) of word address are designated arbitrarily, by continuing data input of 2 bytes

or more, the address of insignificant 3 bits is incremented internally, and data up to 8 bytes can be written.

・ As for page write command of BR24G04-3A, BR24G08-3A and BR24G16-3A, after page select bit ’P0’(in the case of

BR24G04-3A), after page select bit ’P0,P1’(in the case of BR24G08-3A), after page select bit ’P0,P1,P2’(in the case of

BR24G16-3A) of slave address are designated arbitrarily, by continuing data input of 2 bytes or more, the address of insignificant 4

bits is incremented internally, and data up to 16 bytes can be written.

・ As for page write cycle of BR24G32-3A and BR24G64-3A, after the significant 7 bits (in the case of BR24G32-3A) of word address,

or the significant 8 bits (in the case of BR24G64-3A) of word address are designated arbitrarily, by continuing data input of 2 bytes

or more, the address of insignificant 5 bits is incremented internally, and data up to 32 bytes can be written.

・ As for page write cycle of BR24G128-3A and BR24G256-3A, after the significant 8 bits (in the case of BR24G128-3) of word

address, or the significant 9 bits (in the case of BR24G256-3A) of word address are designated arbitrarily, by continuing data input

of 2 bytes or more, the address of insignificant 6 bits is incremented internally, and data up to 64 bytes can be written.

・ As for page write cycle of BR24G512-3A after the significant 9 bits of word address are designated arbitrarily, by continuing data

input of 2 bytes or more, the address of insignificant 7 bits is incremented internally, and data up to 128 bytes can be written.

・ As for page write cycle of BR24G1M-3A after page select bit ‘P0’ and the significant 8 bits of word address are designated

arbitrarily, by continuing data input of 2 bytes or more, the address of insignificant 8 bits is incremented internally, and data up to

256 bytes can be written.

Technical Note

10/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

○Notes on page write cycle

List of numbers of page write

Number of

Pages 8Byte 16Byte 32Byte 64Byte 128Byte 256Byte

Product

number BR24G01-3A

BR24G02-3A

BR24G04-3A

BR24G08-3A

BR24G16-3A

BR24G32-3A

BR24G64-3A BR24G128-3A

BR24G256-3A BR24G512-3A BR24G1M-3A

The above numbers are maximum bytes for respective types.

Any bytes below these can be written.

In the case BR24G256-3A, 1 page=64bytes, but the page

write cycle time is 5ms at maximum for 64byte bulk write.

It does not stand 5ms at maximum × 64byte=320ms(Max.)

○Internal address increment

Page write mode (in the case of BR24G16-3A）

○Write protect (WP) terminal

・Write protect (WP) function

When WP terminal is set Vcc (H level), data rewrite of all addresses is prohibited. When it is set GND (L level), data rewrite of all

address is enabled. Be sure to connect this terminal to Vcc or GND, or control it to H level or L level. Do not use it open.

In the case of use it as an ROM, it is recommended to connect it to pull up or Vcc.

At extremely low voltage at power ON / OFF, by setting the WP terminal 'H', mistake write can be prevented.

For example, when it is started from address 0Eh,

therefore, increment is made as below,

0Eh→0Fh→00h→01h･･･ which please note.

※0Eh･･･0E in hexadecimal, therefore, 00001110 becomes a

binary number.

WA7 WA4 WA3 WA2 WA1 WA0

0 00000

0 00001

0 00010

0 01110

0 01111

0 00000

Increment

0Eh

Significant bit is fixed.

No digit up

Technical Note

11/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●Read Command

○Read cycle

Data of EEPROM is read. In read cycle, there are random read cycle and current read cycle.

Random read cycle is a command to read data by designating address, and is used generally.

Current read cycle is a command to read data of internal address register without designating address, and is used when to verify just

after write cycle. In both the read cycles, sequential read cycle is available, and the next address data can be read in succession.

・In random read cycle, data of designated word address can be read.

・When the command just before current read cycle is random read cycle, current read cycle (each including sequential read cycle), data of

incremented last read address (n)-th address, i.e., data of the (n+1)-th address is output.

・When ACK signal 'LOW' after D0 is detected, and stop condition is not sent from master (μ-COM) side, the next address data can be

read in succession.

・Read cycle is ended by stop condition where 'H' is input to ACK signal after D0 and SDA signal is started at SCL signal 'H' .

・When 'H' is not input to ACK signal after D0, sequential read gets in, and the next data is output.

Therefore, read command cycle cannot be ended. When to end read command cycle, be sure input stop condition to input 'H' to ACK

signal after D0, and to start SDA at SCL signal 'H'.

・Sequential read is ended by stop condition where 'H' is input to ACK signal after arbitrary D0 and SDA is started at SCL signal 'H'.

W

R

I

T

E

S

T

A

R

T

R

/

W

A

C

K

S

T

O

P

WORD

ADDRESS(n)

SDA

LINE

A

C

K

A

C

K

DATA(n)

A

C

K

SLAVE

ADDRESS

1 0

0

1

A0

A1

A2

WA

7 A0

D0

SLAVE

ADDRESS

1 0

0

1 A1

A2

S

T

A

R

T

D7

R

/

W

R

E

A

D

WA

0

Note)

*1

Fig.43 Random read cycle (BR24G01/02/04/08/16-3A)

W

R

I

T

E

S

T

A

R

T

R

/

W

A

C

K

S

T

O

P

1st WORD

ADDRESS（ｎ）

SDA

LINE

A

C

K

A

C

K

DATA(n)

A

C

K

SLAVE

ADDRESS

10

0

1A0 A1

A2

WA

14

D7 D0

2nd WORD

ADDRESS（ｎ）

A

C

K

S

T

A

R

T

SLAVE

ADDRESS

10

0

1A2

A1

R

/

W

R

E

A

D

A0

WA

0

Note

)

*1

WA

13

WA

12

WA

11

WA

15

Fig.44 Random read cycle (BR24G32/64/128/256/512/1M-3A)

*1

As for WA12, BR24G32-3A become Don’t care.

As for WA13, BR24G32/64-3A become Don’t care.

As for WA14, BR24G32/64/128-3A become Don’t care.

As for WA15, BR24G32/64/128/256-3A become Don’t care.

S

T

A

R

T

S

T

O

P

SDA

LINE

A

C

K

DATA(n)

A

C

K

SLAVE

ADDRESS

1 0 0 1 A0 A1 A2 D0 D7

R

/

W

R

E

A

D

Note)

Fig.45 Current read cycle

R

E

A

D

S

T

A

R

T

R

/

W

A

C

K

S

T

O

P

DATA(n)

SDA

LINE

A

C

K

A

C

K

DATA(n+x)

A

C

K

SLAVE

ADDRESS

1 0

0

1A0

A1

A2

D0

D7

D0

D7

Note）

Fig.46 Sequential read cycle (in the case of current read cycle)

10

0

1 A0

A1

A2

*1 *2 *3

*1

In BR24G16

-

3

A

, A2 becomes P2.

*2 In BR24G08/16-3A, A1 becomes P1.

*3 In BR24G08/16/1M-3A, A0 becomes P0.

Note)

*1

As for WA7,BR24G01-3A become Don’t care.

Fig.47 Difference of slave address of each type

Technical Note

12/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●Software reset

Software reset is executed when to avoid malfunction after power on, and to reset during command input. Software reset has several kinds,

and 3 kinds of them are shown in the figure below. (Refer to Fig.45-(a), Fig.45-(b), Fig.45-(c).) In dummy clock input area, release the

SDA bus ('H' by pull up). In dummy clock area, ACK output and read data '0' (both 'L' level) may be output from EEPROM, therefore, if 'H' is

input forcibly, output may conflict and over current may flow, leading to instantaneous power failure of system power source or influence

upon devices.

●

Acknowledge polling

During internal write execution, all input commands are ignored, therefore ACK is not sent back. During internal automatic write execution

after write cycle input, next command (slave address) is sent, and if the first ACK signal sends back 'L', then it means end of write action,

while if it sends back 'H', it means now in writing. By use of acknowledge polling, next command can be executed without waiting for tWR =

5ms.

When to write continuously, R/W = 0, when to carry out current read cycle after write, slave address R/W = 1 is sent, and if ACK signal

sends back 'L', then execute word address input and data output and so forth.

1 2 13 14

SCL

Dummy clock×14 Start×2

SCL

Fig.48-(a) The case of dummy clock +START+START+ command input

スタート

※Start command from START input.

2 1 8 9

Dummy clock×9

Start

Fig.48-(b) The case of START +9 dummy clocks +START+ command input

Start

Normal command

Start×9

SDA

SCL

SD

1 2 3 8 9 7

Fig.48-(c) START×9+ command input

Normal command

SDA

Slave

address

Word

address

…

S

T

A

R

T

First write command

A

C

K

H

A

C

K

L

Slave

address

Slave

address

Slave

address Data

Write command

During internal write,

ACK = HIGH is sent back.

After completion of internal write,

ACK=LOW is sent back, so input

next word address and data in

succession.

tWR

Second write command

S

T

A

R

T

S

T

A

R

T

S

T

A

R

T

S

T

A

R

T

S

T

O

P

S

T

O

P

A

C

K

H

A

C

K

H

A

C

K

L

A

C

K

L

Fig.49 Case to continuously write by acknowledge polling

Technical Note

13/20

BR24G□□□

□□□□□□

□□□-3A Series

www.rohm.com

20

1

2.2

-

Rev.C

●

WP valid timing (write cancel)

WP is usually fixed to 'H' or 'L', but when WP is used to cancel write cycle and so forth, pay attention to the following WP valid timing. During

write cycle execution, in cancel valid area, by setting WP='H', write cycle can be cancelled. In both byte write cycle and page write cycle, the

area from the first start condition of command to the rise of clock to taken in D0 of data(in page write cycle, the first byte data) is cancel

invalid area.

WP input in this area becomes Don't care. The area from the rise of SCL to take in D0 to input the stop condition is cancel valid area. And,

after execution of forced end by WP, standby status gets in.

●

Command cancel by start condition and stop condition

During command input, by continuously inputting start condition and stop condition, command can be cancelled. (Fig.51)

However, in ACK output area and during data read, SDA bus may output 'L', and in this case, start condition and stop condition cannot be

input, so reset is not available. Therefore, execute software reset. And when command is cancelled by start, stop condition, during random

read cycle, sequential read cycle, or current read cycle, internal setting address is not determined, therefore, it is not possible to carry out

current read cycle in succession. When to carry out read cycle in succession, carry out random read cycle.

・

Rise of D0 taken clock

SCL

D0 ACK

Enlarged view

SCL

SDA ACK D0

・Rise of SDA

SDA

WP

WP cancel invalid area WP cancel valid area

Data is not written.

Fig.50 WP valid timing

Slave

address D7 D6 D5 D4 D3 D2 D1 D0 Data tWR

SDA D1

S

T

A

R

T

A

C

K

L

A

C

K

L

A

C

K

L

A

C

K

L

S

T

O

P

Word

address

Fig.51 Case of cancel by start, stop condition during slave address input

SCL

SDA 1 1 0 0

Start condition

Stop condition

Enlarged view

WP cancel invalid area

Technical Note

14/20

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20

1

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●

I/O peripheral circuit

○Pull up resistance of SDA terminal

SDA is NMOS open drain, so requires pull up resistance. As for this resistance value (R

PU

), select an appropriate value to this resistance

value from microcontroller V

IL

, I

L

,

and V

OL

-I

OL

characteristics of this IC. If R

PU

is large, action frequency is limited. The smaller the R

PU

, the

larger the consumption current at action.

○Maximum value of R

PU

The maximum value of R

PU

is determined by the following factors.

①SDA rise time to be determined by the capacitance (CBUS) of bus line of R

PU

and SDA should be tR or below.

And AC timing should be satisfied even when SDA rise time is late.

②The bus electric potential A to be determined by input leak total (I

L

) of device connected to bus at output of 'H' to SDA bus and R

PU

should sufficiently secure the input 'H' level (V

IH

) of microcontroller and EEPROM including recommended noise margin 0.2Vcc.

V

CC

－

I

L

R

PU

－

0.2 V

CC

≧ V

IH

∴R

PU

≦0.8V

CC－

V

IH

I

L

Ex.) V

CC

=3V I

L

=10µA V

IH

=0.7 V

CC

from②

≦

300 ［kΩ］

R

PU

≦

0.8×3－0.7×3

10×10

-6

○ Minimum value of R

PU

The minimum value of R

PU

is determined by the following factors.

When IC outputs LOW, it should be satisfied that V

OLMAX

=0.4V and I

OLMAX

=3mA.

②V

OLMAX

= should secure the input 'L' level (V

IL

) of microcontroller and EEPROM including recommended noise margin 0.1Vcc.

V

OLMAX

≦ V

IL

－

0.1 V

CC

Ex.) V

CC

=3V、V

OL

=0.4V、I

OL

=3mA、microcontroller, EEPROM V

IL

=0.3Vcc

And V

OL

=0.4［V］

V

IL

=0.3×3

=0.9［V］

Therefore, the condition ② is satisfied.

○Pull up resistance of SCL terminal

When SCL control is made at CMOS output port, there is no need, but in the case there is timing where SCL becomes 'Hi-Z', add a pull

up resistance. As for the pull up resistance, one of several kΩ ~ several ten kΩ is recommended in consideration of drive performance

of output port of microcontroller.

I

OL

R

PU

≧V

CC－

V

OL

I

OL

∴

V

CC－

V

OL

R

PU

≦

≧867 ［Ω］

R

PU

≧3－0.4

3×10

-3

from①

Microcontroller

R

PU

A SDA

terminal

I

L

I

L

Bus line

capacity

CBUS

Fig.52 I/O circuit diagram

BR24GXX

Technical Note

15/20

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Rev.C

●Cautions on microcontroller connection

○R

S

In I

2

C BUS, it is recommended that SDA port is of open drain input/output. However, when using CMOS input / output of tri state to SDA

port, insert a series resistance Rs between the pull up resistance Rpu and the SDA terminal of EEPROM. This controls over current that

occurs when PMOS of the microcontroller and NMOS of EEPROM are turned ON simultaneously. Rs also plays the role of protection of

SDA terminal against surge. Therefore, even when SDA port is open drain input/output, Rs can be used.

○Maximum value of Rs

The maximum value of Rs is determined by the following relations.

①SDA rise time to be determined by the capacity (CBUS) of bus line of Rpu and SDA should be tR or below.

And AC timing should be satisfied even when SDA rise time is late.

②The bus electric potential A to be determined by Rpu and Rs the moment when EEPROM outputs 'L' to SDA bus sufficiently secure

the input 'L' level (V

IL

) of microcontroller including recommended noise margin 0.1Vcc.

○Minimum value of Rs

The minimum value of Rs is determined by over current at bus collision. When over current flows, noises in power source line, and

instantaneous power failure of power source may occur. When allowable over current is defined as I, the following relation must be

satisfied. Determine the allowable current in consideration of impedance of power source line in set and so forth. Set the over current to

EEPROM 10mA or below.

R

PU

Microcontroller

R

S

EEPROM

Fig.53 I/O circuit diagram Fig.54 Input / output collision timing

ACK

'L' output of EEPROM

'H' output of microcontroller

Over current flows to SDA line by 'H'

output of microcontroller and 'L'

output of EEPROM.

SCL

SDA

Microcontroller EEPROM

'L'output

R

S

R

PU

'H' output

Over current I

Fig.56 I/O circuit diagram

≦1.67［kΩ］

≦0.3×3－0.4－0.1×3 ×20×10

3

1.1×3－0.3×3

R

S

× R

PU

1.1V

CC

-V

IL

Ex.）V

CC

=3V　V

IL

=0.3V

CC

　V

OL

=0.4V　R

PU

=20kΩ

∴R

S

≦V

IL－

V

OL－

0.1V

CC

(V

CC－

V

OL

)×R

S

+ V

OL

+0.1V

CC

≦V

IL

R

PU

+R

S

V

CC

R

S

V

CC

I

≧300［Ω］

∴

Ex.) VCC=3V, I=10mA

RS≧3

10×10

-3

≦I

RS≧

R

PU

Micro controller

R

S

EEPROM

I

OL

A

Bus line

capacity

CBUS

V

OL

V

CC

V

IL

Fig.55 I/O Circuit Diagram

Technical Note

16/20

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20

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-

Rev.C

●I

2

C BUS input / output circuit

○Input (A0, A1, A2, SCL, WP)

○Input / output (SDA)

Fig.57 Input pin circuit diagram

Fig.58 Input / output pin circuit diagram

Technical Note

17/20

BR24G□□□

□□□□□□

□□□-3A Series

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20

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Rev.C

●Notes on power ON

At power on, in IC internal circuit and set, Vcc rises through unstable low voltage area, and IC inside is not completely reset, and

malfunction may occur. To prevent this, functions of POR circuit and LVCC circuit are equipped. To assure the action, observe the following

conditions at power on.

1. Set SDA = 'H' and SCL ='L' or 'H’

2. Start power source so as to satisfy the recommended conditions of t

R

, t

OFF

, and Vbot for operating POR circuit.

tOFF

tR

Vbot

0

V

CC

3. Set SDA and SCL so as not to become 'Hi-Z'.

When the above conditions 1 and 2 cannot be observed, take the following countermeasures.

a) In the case when the above condition 1 cannot be observed. When SDA becomes 'L' at power on .

→Control SCL and SDA as shown below, to make SCL and SDA, 'H' and 'H'.

ｂ)

In the case when the above condition 2 cannot be observed.

→After power source becomes stable, execute software reset(P12).

ｃ)

In the case when the above conditions 1 and 2 cannot be observed.

→Carry out a), and then carry out b).

● Low voltage malfunction prevention function

LVCC circuit prevents data rewrite action at low power, and prevents wrong write. At LVCC voltage (Typ. =1.2V) or below, it prevent data

rewrite.

●Vcc noise countermeasures

○Bypass capacitor

When noise or surge gets in the power source line, malfunction may occur, therefore, for removing these, it is recommended to attach a by

pass capacitor (0.1µF) between IC Vcc and GND. At that moment, attach it as close to IC as possible.

And, it is also recommended to attach a bypass capacitor between board Vcc and GND.

● Cautions on use

(1)

Described numeric values and data are design representative values, and the values are not guaranteed.

(2) We believe that application circuit examples are recommendable, however, in actual use, confirm characteristics further sufficiently. In the

case of use by changing the fixed number of external parts, make your decision with sufficient margin in consideration of static

characteristics and transition characteristics and fluctuations of external parts and our LSI.

(3)

Absolute maximum ratings

If the absolute maximum ratings such as impressed voltage and action temperature range and so forth are exceeded, LSI may be

destructed. Do not impress voltage and temperature exceeding the absolute maximum ratings. In the case of fear exceeding the absolute

maximum ratings, take physical safety countermeasures such as fuses, and see to it that conditions exceeding the absolute maximum

ratings should not be impressed to LSI.

(4) GND electric potential

Set the voltage of GND terminal lowest at any action condition. Make sure that each terminal voltage is lower than that of GND terminal.

(5) Terminal design

In consideration of permissible loss in actual use condition, carry out heat design with sufficient margin.

(6) Terminal to terminal shortcircuit and wrong packaging

When to package LSI onto a board, pay sufficient attention to LSI direction and displacement. Wrong packaging may destruct LSI. And in

the case of shortcircuit between LSI terminals and terminals and power source, terminal and GND owing to foreign matter, LSI may be

destructed.

(7)

Use in a strong electromagnetic field may cause malfunction, therefore, evaluate design sufficiently.

Fig.59 Rise waveform diagram

Recommended conditions of tR, tOFF,Vbot

tR tOFF Vbot

10ms or below

10ms or larger 0.3V or below

100 or below 10ms or larger 0.2V or below

Fig.60 When SCL=’H’ and SDA=’L’ Fig.61 When SCL=’L’ and SDA=’L’

Technical Note

18/20

www.rohm.com

20

1

2.2

-

Rev.C

BR24G□□

□□□□

□□-3A Series

●Order part number

●

●●

●Package specifications

B R

2 4

G

5

F

3

ROHM type

name

BUS type

24：I

2

C

Operating

temperature/

Power source

Voltage

G:-40℃～+85℃/

1.7V～5.5V

White Reel

Process Code

E

Package specifications

E2：reel shape emboss taping

TR：reel shape emboss taping

2

Package

Blank

:DIP-T8

F :SOP8

FJ :SOP-J8

FV : SSOP-B8

FVT : TSSOP-B8

FVJ : TSSOP-B8J

FVM : MSOP8

NUX : VSON008X2030

A

G

2

Revision

Halogen free

6

Capacity

01=1K 64＝64K

02=2K 128=128K

04=4K 256=256K

08=8K 512=512K

16=16K 1M=1024K

32＝32K

T

100% Sn

Technical Note

19/20

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20

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BR24G□□

□□□□

□□-3A Series

Technical Note

20/20

www.rohm.com

20

1

2.2

-

Rev.C

BR24G□□

□□□□

□□-3A Series