S-8241ACKMC-GCK-T2 - Seiko Instruments USA, Inc.

Rev.4.1_01

BATTERY PROTECTION IC

FOR 1- CELL PACK S-8241 Series

Seiko Instruments Inc. 1

The S-8241 Series is a series of lithium-ion/lithium polymer rechargeable

battery protection ICs incorporating high-accuracy voltage detection

circuits and delay circuits.

These ICs are suitable for protection of single-cell lithium ion/lithium

polymer battery packs from overcharge, overdischarge and overcurrent.

 Features

(1) Internal high-accuracy voltage detection circuit

• Overcharge detection voltage: 3.9 V to 4.4 V (5 mV-step)

Accuracy of ± 25 mV(+25°C) and ± 30 mV(−5°C to +55°C)

• Overcharge release voltage 3.8 V to 4.4 V *1 Accuracy of ±50 mV

*1. Overcharge release voltage = Overcharge detection voltage - Overcharge hysteresis

The overcharge hysteresis can be selected in the range 0.0, or 0.1 to 0.4 V in 50mV steps.

(However, selection "Overcharge release voltage<3.8 V" is enabled.)

• Overdischarge detection voltage: 2.0 V to 3.0 V (100 mV-step) Accuracy of ±80 mV

• Overdischarge release voltage: 2.0 V to 3.4 V *2 Accuracy of ±100 mV

*2. Overdischarge release voltage = Overdischarge detection voltage + Overdischarge hysteresis

The overdischarge hysteresis can be selected in the range 0.0 to 0.7 V in 100mV steps.

(However, selection "Overdischarge release voltage>3.4 V" is enabled.)

• Overcurrent 1 detection voltage: 0.05 V to 0.3 V (5 mV-step) Accuracy of ±20 mV

• Overcurrent 2 detection voltage: 0. 5 V (fixed) Accuracy of ±100 mV

(2) A high voltage withstand device is used for charger connection pins

(VM and CO pins: Absolute maximum rating = 26 V)

(3) Delay times (overcharge: tCU; overdischarge: tDL; overcurrent 1: tlOV1; overcurrent 2: tlOV2) are generated

by an internal circuit. (External capacitors are unnecessary.) Accuracy of ±30 %

(4) Internal three-step overcurrent detection circuit (overcurrent 1, overcurrent 2, and load short-circuiting)

(5) Either the 0 V battery charging function or 0 V battery charge inhibiting function can be selected.

(6) Products with and without a power-down function can be selected.

(7) Charger detection function and abnormal charge current detection function

• The overdischarge hysterisis is released by detecting a negative VM pin voltage (typ. -1.3 V). (Charger

detection function)

• If the output voltage at DO pin is high and the VM pin voltage becomes equal to or lower than the

charger detection voltage (typ. -1.3 V), the output voltage at CO pin goes low. (Abnormal charge current

detection function)

(8) Low current consumption

• Operation: 3.0 µA typ. 5.0 µA max.

• Power-down mode: 0.1 µA max.

(9) Wide operating temperature range: −40 to +85 °C

(10) Small package SOT-23-5, 5-Pin SON(A)

 Applications

• Lithium-ion rechargeable battery packs

• Lithium- polymer rechargeable battery packs

 Packages

Package name Drawing code

Package Tape Reel

SOT-23-5 MP005-A MP005-A MP005-A

5-Pin SON(A) PN005-A PN005-A PN005-A

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Block Diagram

−

VSS

Overcharge

detection

comparator

Overcurrent 1

detection comparator

−

Overdischarge

detection

comparator

Overcurrent 2

detection comparator

Delay circuit

RVMD

RVMS

Counter circuit

Clock generation circuit

The overdischarge hysterisis

is released when a charger

is detected.

RCOL

Load short-

circuiting

detection circuit

Level conversion circuit

0V battery charging circuit

0V battery charge

inhibition circuit

Charger

detection circuit

Remark The diodes in the IC are parasitic diodes.

Figure 1 Block Diagram

 Product Code Structure

1. Product Name

IC direction in tape specifications

T2 : SOT-23-5

TF : 5-Pin SON(A)

Product name (abbreviation)*2

Package name (abbreviation)

MC : SOT-23-5

PN : 5-Pin SON(A)

Serial code

Assigned from BA to ZZ in alphabetical order

S-8241A xx xx - xxx xx

*1 Refer to the taping specifications at the end of this book.

*2 Refer to the product name list.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 3

2. Product Name List

Model No./Item Over-

charge

detection

voltage

]

Over-

charge

release

voltage

]

Over-

discharge

detection

voltage

]

Over-

discharge

release

voltage

]

Over-

current 1

detection

voltage

IOV1

]

0V battery

charging

function

Delay

time

combi-

nation

Power down

function

S-8241ABAMC-GBA-T2 4.275 V 4.075 V 2.3 V 2.9 V 0.100 V Unavailable (1) Available

S-8241ABBMC-GBB-T2 4.280 V 3.980 V 2.3 V 2.4 V 0.125 V Available (2) Available

S-8241ABCMC-GBC-T2 4.350 V 4.100 V 2.3 V 2.8 V 0.075 V Unavailable (1) Available

S-8241ABDMC-GBD-T2

S-8241ABDPN-KBD-TF 4.275 V 4.175 V 2.3 V 2.4 V 0.100 V Available (1) Available

S-8241ABEMC-GBE-T2 4.295 V 4.095 V 2.3 V 3.0 V 0.200 V Unavailable (1) Available

S-8241ABFMC-GBF-T2 4.325 V 4.075 V 2.5 V 2.9 V 0.100 V Unavailable (1) Available

S-8241ABGMC-GBG-T2 4.200 V 4.100 V 2.3 V 3.0 V 0.100 V Unavailable (1) Available

S-8241ABHMC-GBH-T2 4.325 V 4.125 V 2.3 V 2.3 V 0.100 V Available (1) Available

S-8241ABIMC-GBI-T2 4.280 V 4.080 V 2.3 V 2.3 V 0.160 V Unavailable (1) Available

S-8241ABKMC-GBK-T2 4.325 V 4.075 V 2.5 V 2.9 V 0.150 V Unavailable (1) Available

S-8241ABLMC-GBL-T2 4.320 V 4.070 V 2.5 V 2.9 V 0.100 V Unavailable (1) Available

S-8241ABNPN-KBN-TF 4.350 V 4.050 V 2.35 V 2.65 V 0.150 V Available (1) Available

S-8241ABOMC-GBO-T2 4.350 V 4.15 V 2.3 V 3.0 V 0.150 V Available (2) Available

S-8241ABPMC-GBP-T2 4.350 V 4.15 V 2.3 V 3.0 V 0.200 V Available (2) Available

S-8241ABQMC-GBQ-T2 4.280 V 4.080 V 2.3 V 2.3 V 0.130 V Unavailable (1) Available

S-8241ABSPN-KBS-TF 4.350 V 4.150 V 2.35 V 2.65 V 0.200 V Available (2) Available

S-8241ABTPN-KBT-TF 4.300 V 4.100 V 2.3 V 2.3 V 0.100 V Available (1) Available

S-8241ABUMC-GBU-T2 4.200 V 4.100 V 2.3 V 2.3 V 0.150 V Unavailable (1) Available

S-8241ABVMC-GBV-T2 4.295 V 4.095 V 2.3 V 2.3 V 0.130 V Available (1) Available

S-8241ABWMC-GBW-T2 4.280 V 4.080 V 2.3 V 2.3 V 0.130 V Unavailable (3) Available

S-8241ABXMC-GBX-T2

S-8241ABXPN-KBX-TF 4.350 V 4.000 V 2.6 V 3.3 V 0.200 V Unavailable (1) Available

S-8241ABYMC-GBY-T2 4.220 V 4.220 V 2.3 V 2.3 V 0.200 V Available (3) Available

S-8241ABZPN-KBZ-TF 4.275 V 4.075 V 2.3 V 2.4 V 0.140 V Available (1) Available

S-8241ACAMC-GCA-T2

S-8241ACAPN-KCA-TF 4.280 V 4.080 V 2.3 V 2.3 V 0.200 V Available (1) Available

S-8241ACBMC-GCB-T2 4.300 V 4.100 V 2.3 V 2.3 V 0.150 V Available (1) Available

S-8241ACDMC-GCD-T2 4.275 V 4.075 V 2.3 V 2.3 V 0.100 V Unavailable (4) Available

S-8241ACEMC-GCE-T2 4.295 V 4.095 V 2.3 V 2.3 V 0.080 V Available (1) Available

S-8241ACFMC-GCF-T2 4.295 V 4.095 V 2.3 V 2.3 V 0.090 V Available (1) Available

S-8241ACGMC-GCG-T2

S-8241ACGPN-KCG-TF 4.295 V 4.095 V 2.3 V 2.3 V 0.060 V Available (1) Available

S-8241ACHMC-GCH-T2 4.280 V 4.080 V 2.6 V 2.6 V 0.200 V Available (1) Available

S-8241ACIMC-GCI-T2 4.350 V 4.150 V 2.05 V 2.75 V 0.200 V Available (2) Available

S-8241ACJPN-KCJ-TF 4.300 V 4.100 V 2.3 V 2.3 V 0.120 V Available (1) Available

S-8241ACKMC-GCK-T2 4.350 V 4.150 V 2.0 V 2.0 V 0.200 V Available (2) Available

S-8241ACLMC-GCL-T2 4.200 V 4.200 V 2.5 V 3.0 V 0.100 V Available (1) Available

S-8241ACNMC-GCN-T2

S-8241ACNPN-KCN-TF 4.350 V 4.150 V 2.1 V 2.2 V 0.200 V Available (2) Available

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

Model No./Item Over-

charge

detection

voltage

]

Over-

charge

release

voltage

]

Over-

discharge

detection

voltage

]

Over-

discharge

release

voltage

]

Over-

current 1

detection

voltage

IOV1

]

0V battery

charging

function

Delay

time

combi-

nation

Power down

function

S-8241ACOMC-GCO-T2 4.100 V 3.850 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACPMC-GCP-T2 4.325 V 4.075 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACQMC-GCQ-T2 4.275 V 4.175 V 2.3 V 2.4 V 0.100 V Available (1) Unavailable

S-8241ACRMC-GCR-T2 4.350 V 4.150 V 2.3 V 3.0 V 0.100 V Available (1) Unavailable

S-8241ACSMC-GCS-T2 4.180 V 3.930 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACTMC-GCT-T2 4.100 V 4.000 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACUMC-GCU-T2 4.180 V 4.080 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACXMC-GCX-T2 4.275 V 4.075 V 2.5 V 2.9 V 0.150 V Unavailable (1) Unavailable

S-8241ACYMC-GCY-T2 4.275 V 4.075 V 2.6 V 2.9 V 0.100 V Unavailable (1) Unavailable

S-8241ACZPN-KCZ-TF 4.350 V 4.150 V 2.7 V 2.7 V 0.200 V Unavailable (2) Available

S-8241ADAMC-GDA-T2 4.350 V 4.150 V 2.3 V 3.0 V 0.100 V Available (1) Available

S-8241ADBPN-KDB-TF 4.280 V 4.080 V 2.3 V 2.3 V 0.250 V Unavailable (2) Available

*1. The delay time combination (1), (2), (3), (4) is as follows.

Delay time

combination

Overcharge detection

delay time

Overdischarge detection

delay time

Overcurrent 1 detection

delay time

(1) 1.0 s 125 ms 8 ms

(2) 0.125 s 31 ms 16 ms

(3) 0.25 s 125 ms 8 ms

(4) 2.0 s 125 ms 8 ms

It is possible to change the detection voltage for products other than those listed above. Also, delay time can be

changed within the following range. For details, please contact our sales office.

Delay time Symbol Optional range Remarks

Overcharge detection

delay time tCU 0.25 s 0.5 s 1.0 s Choose from the list at left.

Overdischarge detection

delay time tDL 31 ms 62.5 ms 125 ms Choose from the list at left.

Overcurrent 1 detection

delay time tlOV1 4 ms 8 ms 16 ms Choose from the list at left.

Shaded boxes indicate standard values.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 5

 Pin Configurations

Pin No. Symbol Pin Description

1 VM

Voltage detection pin between VM and VSS

(Overcurrent detection pin)

2 VDD Positive power input pin

3 VSS Negative power input pin

4 DO

FET gate connection pin for discharge control

(CMOS output)

5 CO

FET gate connection pin for charge control

(CMOS output)

5 4

1 3 2

SOT-23-5

Top view

Figure 2

Pin No. Symbol Pin Description

1 VM

Voltage detection pin between VM and VSS

(Overcurrent detection pin)

2 VDD Positive power input pin

3 CO

FET gate connection pin for charge control

(CMOS output)

4 DO

FET gate connection pin for discharge control

(CMOS output)

5 VSS Negative power input pin

Remark Pin assignment of SOT-23-5 and of 5-Pin SON(A) are different.

3 2 1

4 5

5-Pin SON(A)

Top view

Figure 3

 Absolute Maximum Ratings

(Ta = 25°C unless otherwise specified)

Item Symbol Applicable pin Rating Unit

Input voltage between VDD and VSS *1 V

DS VDD VSS −0.3 to VSS +12 V

VM Input pin voltage VVM VM VDD −26 to VDD +0.3 V

CO output pin voltage VCO CO VVM −0.3 to VDD +0.3 V

DO output pin voltage VDO DO VSS −0.3 to VDD +0.3 V

Power dissipation SOT-23-5 PD − 250 mW

5-Pin SON(B) 150

Operation ambient temperature Topr − −40 to +85 °C

Storage temperature Tstg − −40 to +125 °C

*1. Do not apply pulse-like noise of µs order exceeding the above input voltage (VSS + 12 V). The noise

causes damage to the IC.

Caution The absolute maximum ratings are rated values exceeding which the product could suffer

physical damage. These values must therefore not be exceeded under any conditions.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Electrical Characteristics (1) Other than detection delay time (25°C)

(Ta = 25

C unless otherwise specified)

Item Symbol

Measure-

ment

conditions

Remarks Min. Typ. Max. Unit

Measure-

ment

circuit

DETECTION VOLTAGE

−

-0.025 V

+0.025 V 1

Overcharge detection voltage

=3.9 to 4.4 V, 5 mV Step Ta= -5

C to 55

-0.030 V

+0.030

1 When V

≠

-0.050 V

+0.050 V 1

Overcharge release voltage

−

=0 to 0.4 V, 50mV Step When V

= V

-0.025 V

+0.025

Overdischarge detection voltage

=2.0 to 3.0 V, 100mV Step V

−

-0.080 V

+0.080 V 1

1 When V

≠

-0.100 V

+0.100

Overdischarge release voltage

−

=0 to 0.7 V, 100mV Step When V

= V

-0.080 V

+0.080 V 1

Overcurrent 1 detection voltage

IOV1

=0.05 to 0.3V, 5mV Step V

IOV1

−

IOV1

-0.02

0 V

IOV1

+0.02

0 V 1

Overcurrent 2 detection voltage V

IOV2

−

0.4 0.5 0.6 V 1

Load short-circuiting detection

voltage V

SHORT

2 VM voltage based on V

-1.7 -1.3 -0.9 V 1

Charger detection voltage V

CHA

−

-2.0 -1.3 -0.6 V 1

Overcharge detection voltage

temperature factor

COE1

−

Ta= -5

C to 55

C -0.5 0 0.5

mV/

−

Overcurrent 1 detection voltage

temperature factor

COE2

−

Ta= -5

C to 55

C -0.1 0 0.1

mV/

−

INPUT VOLTAGE, OPERATING VOLTAGE

Input voltage between VDD and

VSS V

DS1

−

absolute maximum rating -0.3

−

12 V

−

Input voltage between VDD and

VM V

DS2

−

absolute maximum rating -0.3

−

26 V

−

Operating voltage between VDD

and VSS V

DSOP1

−

Internal circuit operating

voltage 1.5

−

8 V

−

Operating voltage between VDD

and VM V

DSOP2

−

Internal circuit operating

voltage 1.5

−

24 V

−

CURRENT CONSUMPTION

Power-down function available

Current consumption during

normal operation I

OPE

4 V

=3.5V, V

=0 V 1.0 3.0 5.0

A 1

Current consumption at power

down I

PDN

4 V

=1.5 V

−

0.1

A 1

CURRENT CONSUMPTION

Power-down function unavailable

Current consumption during

normal operation I

OPE

4 V

=3.5 V, V

=0 V 1.0 3.0 5.0

A 1

Overdischarge current

consumption I

OPED

4 V

=1.5 V 1.0 2.0 3.5

A 1

OUTPUT RESISTANCE

CO pin H resistance R

COH

6 V

=3.0 V,V

=3.5 V,V

=0 V 0.1 2 10 k

Ω

CO pin L resistance R

COL

6 V

=0.5 V,V

=4.5 V,V

=0 V 150 600 2400 k

Ω

DO pin H resistance R

DOH

7 V

=3.0 V,V

=3.5 V,V

=0 V 0.1 1.3 6.0 k

Ω

DO pin L resistance R

DOL

7 V

=0.5 V,V

=1.8 V 0.1 0.5 2.0 k

Ω

VM INTERNAL RESISTANCE

Internal resistance between VM

and VDD R

VMD

5 V

=1.8 V, V

=0 V 100 300 900 k

Ω

Internal resistance between VM

and VSS R

VMS

5 V

=3.5 V 50 100 150 k

Ω

0 V BATTERY CHARGING FUNCTION

The 0 V battery function is either "0 V battery charging function" or "0 V battery charge inhibiting function"

depending upon the product type.

0 V battery charge starting

charger voltage V

0CHA

10 0 V battery charging Available 0.0 0.8 1.5 V 1

0 V battery charge inhibiting

battery voltage V

0INH

0 V battery charging

Unavailable 0.6 0.9 1.2 V 1

*1.

Since products are not screened at high and low temperatures, the specification for this temperature range is guaranteed by design, not tested in

production.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 7

 Electrical Characteristics (2) Other than detection delay time (-40 to 85°C*1)

(Ta = (-40 to 85

)unless otherwise specified)

Item Symbol

Measure-

ment

conditions

Remarks Min. Typ. Max. Unit

Measure-

ment

circuit

DETECTION VOLTAGE

Overcharge detection voltage

=3.9 to 4.4 V, 5mV Step V

−

-0.055 V

+0.040 V 1

1 When V

≠

-0.095 V

+0.060 V 1

Overcharge release voltage

−

=0 to 0.4 V, 50mV Step When V

= V

-0.055 V

+0.040

Overdischarge detection voltage

=2.0 to 3.0 V, 100mV Step V

−

-0.120 V

+0.120 V 1

1 When V

≠

-0.140 V

+0.140 V 1

Overdischarge release voltage

−

=0 to 0.7 V, 100mV Step When V

= V

-0.120 V

+0.120

Overcurrent 1 detection voltage

IOV1

=0.05 to 0.3V, 5mV Step V

IOV1

−

IOV1

-0.02

6 V

IOV1

+0.026 V 1

Overcurrent 2 detection voltage V

IOV2

−

0.37 0.5 0.63 V 1

Load short-circuiting detection

voltage V

SHORT

2 VM voltage based on V

-1.9 -1.3 -0.7 V 1

Charger detection voltage V

CHA

−

-2.2 -1.3 -0.4 V 1

Overcharge detection voltage

temperature factor

COE1

−

Ta= -40

C to 85

C -0.7 0 0.7

mV/

−

Overcurrent 1 detection voltage

temperature factor

COE2

−

Ta= -40

C to 85

C -0.2 0 0.2

mV/

−

INPUT VOLTAGE, OPERATING VOLTAGE

Input voltage between VDD and

VSS V

DS1

−

absolute maximum rating -0.3

−

12 V

−

Input voltage between VDD and

VM V

DS2

−

absolute maximum rating -0.3

−

26 V

−

Operating voltage between VDD

and VSS V

DSOP1

−

Internal circuit operating

voltage 1.5

−

8 V

−

Operating voltage between VDD

and VM V

DSOP2

−

Internal circuit operating

voltage 1.5

−

24 V

−

CURRENT CONSUMPTION

Power-down function available

Current consumption during

normal operation I

OPE

4 V

=3.5 V, V

=0 V 0.7 3.0 6.0

A 1

Current consumption at power

down I

PDN

4 V

=1.5 V

−

0.1

A 1

CURRENT CONSUMPTION

Power-down function unavailable

Current consumption during

normal operation I

OPE

4 V

=3.5 V, V

=0 V 0.7 3.0 6.0

A 1

Overdischarge current

consumption I

OPED

4 V

=1.5 V 0.6 2.0 4.5

A 1

OUTPUT RESISTANCE

CO pin H resistance R

COH

6 V

=3.0 V,V

=3.5 V,V

=0 V 0.07 2 13 k

Ω

CO pin L resistance R

COL

6 V

=0.5 V,V

=4.5 V,V

=0 V 100 600 3500 k

Ω

DO pin H resistance R

DOH

7 V

=3.0 V,V

=3.5 V,V

=0 V 0.07 1.3 7.3 k

Ω

DO pin L resistance R

DOL

7 V

=0.5 V,V

=1.8 V 0.07 0.5 2.5 k

Ω

VM INTERNAL RESISTANCE

Internal resistance between VM

and VDD R

VMD

5 V

=1.8 V, V

=0 V 78 300 1310 k

Ω

Internal resistance between VM

and VSS R

VMS

5 V

=3.5 V 39 100 220 k

Ω

0 V BATTERY CHARGING FUNCTION

The 0 V battery function is either "0 V battery charging function" or "0 V battery charge inhibiting function"

depending upon the product type.

0 V battery charge starting

charger voltage V

0CHA

10 0 V battery charging Available 0.0 0.8 1.7 V 1

0 V battery charge inhibiting

battery voltage V

0INH

0 V battery charging

Unavailable 0.4 0.9 1.4 V 1

*1.

Since products are not screened at high and low temperatures, the specification for this temperature range is guaranteed by design,

not tested in production.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Electrical Characteristics (3) Detection delay time (25°C)

(Ta = 25

C unless otherwise specified)

Item Symbol

Measurement

conditions Remarks Min. Typ. Max. Unit

Measurement

circuit

DELAY TIME

(1)

Overcharge detection delay time t

−

0.7 1.0 1.3 s 1

Overdischarge detection delay time t

−

87.5 125 162.5 ms 1

Overcurrent 1 detection delay time t

lOV1

−

5.6 8 10.4 ms 1

Overcurrent 2 detection delay time t

lOV2

−

1.4 2 2.6 ms 1

Load short-circuiting detection delay

time

SHORT

−

10 50

s 1

DELAY TIME

(2)

Overcharge detection delay time t

−

87.5 125 162.5 ms 1

Overdischarge detection delay time t

−

21 31 41 ms 1

Overcurrent 1 detection delay time t

lOV1

−

11 16 21 ms 1

Overcurrent 2 detection delay time t

lOV2

−

1.4 2 2.6 ms 1

Load short-circuiting detection delay

time

SHORT

−

10 50

s 1

DELAY TIME

(3)

Overcharge detection delay time t

−

0.175 0.25 0.325 s 1

Overdischarge detection delay time t

−

87.5 125 162.5 ms 1

Overcurrent 1 detection delay time t

lOV1

−

5.6 8 10.4 ms 1

Overcurrent 2 detection delay time t

lOV2

−

1.4 2 2.6 ms 1

DELAY TIME

(4)

Overcharge detection delay time t

−

1.4 2.0 2.6 s 1

Overdischarge detection delay time t

−

87.5 125 162.5 ms 1

Overcurrent 1 detection delay time t

lOV1

−

5.6 8 10.4 ms 1

Overcurrent 2 detection delay time t

lOV2

−

1.4 2 2.6 ms 1

Load short-circuiting detection delay

time

SHORT

−

10 50

s 1

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 9

 Electrical Characteristics (4) Detection delay time (-40 to 85°C*1)

(Ta = -40 to 85

unless otherwise specified)

Item Symbol

Measurement

conditions Remarks Min. Typ. Max. Unit

Measurement

circuit

DELAY TIME

(1)

Overcharge detection delay time t

−

0.55 1.0 1.7 s 1

Overdischarge detection delay time t

−

69 125 212 ms 1

Overcurrent 1 detection delay time t

IOV1

−

4.4 8 14 ms 1

Overcurrent 2 detection delay time t

IOV2

−

1.1 2 3.4 ms 1

Load short-circuiting detection delay

time t

SHORT

−

10 73

s 1

DELAY TIME

(2)

Overcharge detection delay time t

−

69 125 212 ms 1

Overdischarge detection delay time t

−

17 31 53 ms 1

Overcurrent 1 detection delay time t

IOV1

−

9 16 27 ms 1

Overcurrent 2 detection delay time t

IOV2

−

1.1 2 3.4 ms 1

Load short-circuiting detection delay

time t

SHORT

−

10 73

s 1

DELAY TIME

(3)

Overcharge detection delay time t

−

0.138 0.25 0.425 s 1

Overdischarge detection delay time t

−

69 125 212 ms 1

Overcurrent 1 detection delay time t

IOV1

−

4.4 8 14 ms 1

Overcurrent 2 detection delay time t

IOV2

−

1.1 2 3.4 ms 1

Load short-circuiting detection delay

time t

SHORT

−

10 73

s 1

DELAY TIME

(4)

Overcharge detection delay time t

−

1.1 2.0 3.4 s 1

Overdischarge detection delay time t

−

69 125 212 ms 1

Overcurrent 1 detection delay time t

IOV1

−

4.4 8 14 ms 1

Overcurrent 2 detection delay time t

IOV2

−

1.1 2 3.4 ms 1

Load short-circuiting detection delay

time t

SHORT

−

10 73

s 1

*1.

Since products are not screened at high and low temperatures, the specification for this temperature range is guaranteed by design, not

tested in production.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Measurement Circuits

Unless otherwise specified, the output voltage levels "H" and "L" at CO and DO pins are judged by the

threshold voltage (1.0 V) of a Nch FET. Judge the CO pin level with respect to VVM and the DO pin level with

respect to VSS. Voltages V1 to V4 are shown in the figure 4.

(1) Measurement Condition 1, Measurement Circuit 1

〈〈 Overcharge detection voltage, Overcharge release voltage, Overdischarge detection voltage,

Overdischarge release voltage〉〉

The overcharge detection voltage (VCU) is defined by the voltage between VDD and VSS at which VCO goes

″L″ from ″H″ when the voltage V1 is gradually increased from the normal condition V1=3.5 V and

V2=0 V. The overcharge release voltage (VCL) is defined by the voltage between VDD and VSS at which

VCO goes ″H″ from ″L″ when the voltage V1 is then gradually decreased.

Gradually decreasing the voltage V1, the overdischarge detection voltage (VDL) is defined by the voltage

between VDD and VSS at which VDO goes ″L″ from ″H″. The overdischarge release voltage (VDU) is

defined by the voltage between VDD and VSS at which VDO goes ″H″ from ″L″ when the voltage V1 is then

gradually increased.

(2) Measurement Condition 2, Measurement Circuit 1

〈〈 Overcurrent 1 detection voltage, Overcurrent 2 detection voltage, Load short-circuiting detection voltage 〉〉

The overcurrent 1 detection voltage (VIOV1) is defined by the voltage between VDD and VSS at which VDO

goes ″L″ from ″H″ when the voltage V2 is gradually increased from the normal condition V1=3.5 V and

V2=0 V.

The overcurrent 2 detection voltage (VIOV2) is defined by the voltage between VDD and VSS at which VDO

goes ″L″ from ″H″ when the voltage V2 is increased at the speed between 1 ms and 4 ms from the normal

condition V1=3.5 V and V2=0 V.

The load short-circuiting detection voltage (VSHORT) is defined by the voltage between VDD and VSS at

which VDO goes ″L″ from ″H″ when the voltage V2 is increased at the speed between 1 µs and 50 µs from

the normal condition V1=3.5 V and V2=0 V.

(3) Measurement Condition 3, Measurement Circuit 1

〈〈 Charger detection voltage, (=abnormal charge current detection voltage) 〉〉

• Applied only for products with overdischarge hysteresis

Set V1=1.8 V and V2=0 V under overdischarge condition. Increase V1 gradually, set V1=(VDU+VDL)/2

(within overdischarge hysteresis, overdischarge condition), then decrease V2 from 0 V gradually. The

voltage between VM and VSS at which VDO goes ″H″ from ″L″ is the charger detection voltage (VCHA).

• Applied only for products without overdischarge hysteresis

Set V1=3.5 V and V2=0 V under normal condition. Decrease V2 from 0 V gradually. The voltage

between VM and VSS at which VCO goes ″L″ from ″H″ is the abnormal charge current detection voltage.

The abnormal charge current detection voltage has the same value as the charger detection voltage

(VCHA).

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 11

(4) Measurement Condition 4, Measurement Circuit 1

〈〈 Normal operation current consumption, Power-down current consumption, Overdischarge current

consumption 〉〉

Set V1=3.5 V and V2=0 V under normal condition. The current IDD flowing through VDD pin is the normal

operation consumption current (IOPE).

• For products with power-down function

Set V1=V2=1.5 V under overdischarge condition. The current IDD flowing through VDD pin is the

power-down current consumption (IPDN).

• For products without power-down function

Set V1=V2=1.5 V under overdischarge condition. The current IDD flowing through VDD pin is the

overdischarge current consumption (IOPED).

(5) Measurement Condition 5, Measurement Circuit 1

〈〈 Internal resistance between VM and VDD, Internal resistance between VM and VSS 〉〉

Set V1=1.8 V and V2=0 V under overdischarge condition. Measure current IVM flowing through VM pin.

1.8V/|IVM| gives the internal resistance (RVMD) between VM and VDD.

Set V1=V2=3.5 V under overcurrent condition. Measure current IVM flowing through VM pin. 3.5 V/|IVM|

gives the internal resistance (RVMS) between VM and VSS.

(6) Measurement Condition 6, Measurement Circuit 1

〈〈 CO pin H resistance, CO pin L resistance 〉〉

Set V1=3.5 V, V2=0 V and V3=3.0 V under normal condition. Measure current ICO flowing through CO pin.

0.5 V/|ICO| is the CO pin H resistance (RCOH).

Set V1=4.5 V, V2=0 V and V3=0.5 V under overcharge condition. Measure current ICO flowing through CO

pin. 0.5 V/|ICO| is the CO pin L resistance (RCOL).

(7) Measurement Condition 7, Measurement Circuit 1

〈〈 DO pin H resistance, DO pin L resistance 〉〉

Set V1=3.5 V, V2=0 V and V4=3.0 V under normal condition. Measure current IDO flowing through DO pin.

0.5V/|IDO| gives the DO pin H resistance (RDOH).

Set V1=1.8 V, V2=0 V and V4=0.5 V under overdischarge condition. Measure current IDO flowing through

DO pin. 0.5 V/|IDO| gives the DO pin L resistance (RDOL).

(8) Measurement Condition 8, Measurement Circuit 1

〈〈 Overcharge detection delay time, Overdischarge detection delay time 〉〉

Set V1=3.5 V and V2=0 V under normal condition. Increase V1 gradually to overcharge detection voltage

VCU - 0.2 V and increase V1 to the overcharge detection voltage VCU + 0.2 V momentarily (within 10 µs).

The time after V1 becomes the overcharge detection voltage until VCO goes "L" is the overcharge detection

delay time (tCU).

Set V1=3.5 V and V2=0 V under normal condition. Decrease V1 gradually to overdischarge detection

voltage VDL + 0.2 V and decrease V1 to the overdischarge detection voltage VDL - 0.2 V momentarily (within

10 µs). The time after V1 becomes the overdischarge detection voltage VDL until VDO goes "L" is the

overdischarge detection delay time (tDL).

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

(9) Measurement Condition 9, Measurement Circuit 1

〈〈 Overcurrent 1 detection delay time, Overcurrent 2 detection delay time, Load short-circuiting detection delay

time, Abnormal charge current detection delay time 〉〉

Set V1=3.5V and V2=0V under normal condition. Increase V2 from 0 V to 0.35 V momentarily (within

10 µs). The time after V2 becomes overcurrent 1 detection voltage (VIOV1) until VDO goes "L" is overcurrent

1 detection delay time (tIOV1).

Set V1=3.5 V and V2=0 V under normal condition. Increase V2 from 0 V to 0.7 V momentarily (within

1 µs). The time after V2 becomes overcurrent 1 detection voltage (VIOV1) until VDO goes "L" is overcurrent 2

detection delay time (tIOV2).

Note: The overcurrent 2 detection delay time starts when the overcurrent 1 is detected, since the delay circuit is

common.

Set V1=3.5 V and V2=0 V under normal condition. Increase V2 from 0 V to 3.0 V momentarily (within

1 µs). The time after V2 becomes the load short-circuiting detection voltage (VSHORT) until VDO goes "L" is

the load short-circuiting detection delay time (tSHORT).

Set V1=3.5 V and V2=0 V under normal condition. Decrease V2 from 0 V to -2.5 V momentarily (within

10 µs). The time after V2 becomes the charger detection voltage (VCHA) until VCO goes "L" is the abnormal

charge current detection delay time. The abnormal charge current detection delay time has the same value

as the overcharge detection delay time.

(10) Measurement Condition 10, Measurement Circuit 1 (Product with 0V battery charging function)

〈〈 0V battery charge start charger voltage 〉〉

Set V1=V2=0 V and decrease V2 gradually. The voltage between VDD and VM at which VCO goes ″H″ (VVM

+ 0.1 V or higher) is the 0 V battery charge start charger voltage (V0CHA).

(11) Measurement Condition 11, Measurement Circuit 1 (Product with 0V battery charge inhibiting function)

〈〈 0V battery charge inhibiting battery voltage 〉〉

Set V1=0 V and V2=-4 V. Increase V1 gradually. The voltage between VDD and VSS at which VCO goes

″H″ (VVM + 0.1 V or higher) is the 0V battery charge inhibiting battery voltage (V0INH).

VSS

DO CO

VDD

S-8241 series

IDD

Measurement circuit 1

IVM

VDO

COM

IDO

VCO A ICO

V4 V3

Figure 4

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 13

 Operation

Remark Refer to the “ Battery Protection IC Connection Example”.

Normal Condition

The S-8241 monitors the voltage of the battery connected to VDD and VSS pins and the voltage difference

between VM and VSS pins to control charging and discharging. When the battery voltage is in the range

from the overdischarge detection voltage (VDL) to the overcharge detection voltage (VCU), and the VM pin

voltage is in the range from the charger detection voltage (VCHA) to the overcurrent 1 detection voltage

(VIOV1) (the current flowing through the battery is equal to or lower than a specified value), the IC turns both

the charging and discharging control FETs on. This condition is called normal condition and in this condition

charging and discharging can be carried out freely.

Overcurrent Condition

When the discharging current becomes equal to or higher than a specified value (the VM pin voltage is

equal to or higher than the overcurrent detection voltage) during discharging under normal condition and

the state continues for the overcurrent detection delay time or longer, the S-8241 turns the discharging

control FET off to stop discharging. This condition is called overcurrent condition. (The overcurrent

includes overcurrent 1, overcurrent 2, or load short-circuiting.)

The VM and VSS pins are shorted internally by the RVMS resistor under the overcurrent condition. When a

load is connected, the VM pin voltage equals the VDD voltage due to the load.

The overcurrent condition returns to the normal condition when the load is released and the impedance

between the EB+ and EB- pins (see the figure 10 for a connection example) becomes higher than the

automatic recoverable impedance (see the equation [1] below). When the load is removed, the VM pin

goes back to the VSS potential since the VM pin is shorted the VSS pin with the RVMS resistor. Detecting that

the VM pin potential is lower than the overcurrent 1 detection voltage (VIOV1), the IC returns to the normal

condition.

Automatic recoverable impedance = {Battery voltage / (Minimum value of overcurrent 1 detection voltage) -

1} x (RVMS maximum value) --- [1]

Example: Battery voltage = 3.5 V and overcurrent 1 detection voltage (VIOV1) = 0.1 V

Automatic recoverable impedance = (3.5 V / 0.07 V -1) x 200 kΩ = 9.8 MΩ

Remark The automatic recoverable impedance varies with the battery voltage and overcurrent 1 detection voltage

settings. Determine the minimum value of the open load using the above equation [1] to have automatic

recovery from the overcurrent condition work after checking the overcurrent 1 detection voltage setting for the

IC.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

Overcharge Condition

When the battery voltage becomes higher than the overcharge detection voltage (VCU) during charging under

normal condition and the state continues for the overcharge detection delay time (tCU) or longer, the S-8241

turns the charging control FET off to stop charging. This condition is called the overcharge condition.

The overcharge condition is released in the following two cases (c and d) depending on the products with

and without overcharge hysteresis:

♦ Products with overcharge hysteresis (overcharge detection voltage (VCU) > overcharge release voltage

(VCL))

c When the battery voltage drops below the overcharge release voltage (VCL), the S-8241 turns the

charging control FET on and returns to the normal condition.

d When a load is connected and discharging starts, the S-8241 turns the charging control FET on and

returns to the normal condition. The release mechanism is as follows: the discharging current flows

through an internal parasitic diode of the charging FET immediately after a load is connected and

discharging starts, and the VM pin voltage increases about 0.7 V (Vf voltage of the diode) from the VSS

pin voltage momentarily. The IC detects this voltage (being higher than the overcurrent 1 detection

voltage) and releases the overcharge condition. Consequently, in the case that the battery voltage is

equal to or lower than the overcharge detection voltage (VCU), the IC returns to the normal condition

immediately, but in the case the battery voltage is higher than the overcharge detection voltage (VCU),

the IC does not return to the normal condition until the battery voltage drops below the overcharge

detection voltage (VCU) even if the load is connected. In addition If the VM pin voltage is equal to or

lower than the overcurrent 1 detection voltage when a load is connected and discharging starts, the IC

does not return to the normal condition.

Remark If the battery is charged to a voltage higher than the overcharge detection voltage (VCU) and the battery voltage

does not drops below the overcharge detection voltage (VCU) even when a heavy load, which causes an

overcurrent, is connected, the overcurrent 1 and overcurrent 2 do not work until the battery voltage drops

below the overcharge detection voltage (VCU). Since an actual battery has, however, an internal impedance of

several dozens of mΩ, and the battery voltage drops immediately after a heavy load which causes an

overcurrent is connected, the overcurrent 1 and overcurrent 2 work. Detection of load short-circuiting works

regardless of the battery voltage.

♦ Products without overcharge hysteresis (Overcharge detection voltage (VCU) = Overcharge release voltage

(VCL))

c When the battery voltage drops below the overcharge release voltage (VCL), the S-8241 turn the

charging control FET on and returns to the normal condition.

d When a load is connected and discharging starts, the S-8241 turns the charging control FET on and

returns to the normal condition. The release mechanism is explained as follows : the discharging

current flows through an internal parasitic diode of the charging FET immediately after a load is

connected and discharging starts, and the VM pin voltage increases about 0.7 V (Vf voltage of the

diode) from the VSS pin voltage momentarily. Detecting this voltage (being higher than the

overcurrent 1 detection voltage), the IC increases the overcharge detection voltage about 50 mV, and

releases the overcharge condition. Consequently, when the battery voltage is equal to or lower than

the overcharge detection voltage (VCU)

+ 50 mV, the S-8241 immediately returns to the normal condition. But the battery voltage is higher

than the overcharge detection voltage (VCU) + 50 mV, the S-8241 does not return to the normal

condition until the battery voltage drops below the overcharge detection voltage (VCU) + 50 mV even if

a load is connected. If the VM pin voltage is equal to or lower than the overcurrent 1 detection voltage

when a load is connected and discharging starts, the S-8241 does not return to the normal condition.

Remark If the battery is charged to a voltage higher than the overcharge detection voltage (VCU) and the battery voltage

does not drop below the overcharge detection voltage (VCU) + 50 mV even when a heavy load, which causes an

overcurrent, is connected, the overcurrent 1 and overcurrent 2 do not work until the battery voltage drops bellow

the overcharge detection voltage (VCU) + 50 mV. Since an actual battery has, however, an internal impedance

of several dozens of mΩ, and the battery voltage drops immediately after a heavy load which causes an

overcurrent is connected, the overcurrent 1 and overcurrent 2 work. Detection of load short-circuiting works

regardless of the battery voltage.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 15

Overdischarge Condition (for products with power-down function)

When the battery voltage drops below the overdischarge detection voltage (VDL) during discharging under

normal condition and it continues for the overdischarge detection delay time (tDL) or longer, the S-8241

turns the discharging control FET off and stops discharging. This condition is called overdischarge

condition. After the discharging control FET is turned off, the VM pin is pulled up by the RVMD resistor

between VM and VDD in the IC. Meanwhile the potential difference between VM and VDD drops below 1.3

V (typ.) (the load short-circuiting detection voltage), current consumption of the IC is reduced to the

power-down current consumption (IPDN). This condition is called power-down condition. The VM and VDD

pins are shorted by the RVMD resistor in the IC under the overdischarge and power-down conditions.

The power-down condition is released when a charger is connected and the potential difference between

VM and VDD becomes 1.3 V (typ.) or higher (load short-circuiting detection voltage). At this time, the FET

is still off. When the battery voltage becomes the overdischarge detection voltage (VDL) or higher (see

note), the S-8241 turns the FET on and changes to the normal condition from the overdischarge condition.

Remark If the VM pin voltage is no less than the charger detection voltage (VCHA), when the battery under

overdischarge condition is connected to a charger, the overdischarge condition is released (the discharging

control FET is turned on) as usual, provided that the battery voltage reaches the overdischarge release

voltage (VDU) or higher.

Overdischarge Condition (for products without power-down function)

When the battery voltage drops below the overdischarge detection voltage (VDL) during discharging under

normal condition and it continues for the overdischarge detection delay time (tDL) or longer, the S-8241

turns the discharging control FET off and stops discharging. When the discharging control FET is turned

off, the VM pin is pulled up by the RVMD resistor between VM and VDD in the IC. Meanwhile the potential

difference between VM and VDD drops below 1.3 V (typ.) (the load short-circuiting detection voltage),

current consumption of the IC is reduced to the overdischarge current consumption (IOPED). This condition

is called overdischarge condition. The VM and VDD pins are shorted by the RVMD resistor in the IC under

the overdischarge condition.

When a charger is connected, the overdischarge condition is released in the same way as explained above

in respect to products having the power-down function. For products without the power-down function, in

addition, even if the charger is not connected, the S-8241 turns the discharging control FET on and

changes to the normal condition from the overdischarge condition provided that the load is disconnected

and that the potential difference between VM and VSS drops below the overcurrent 1 detection voltage

(VIOV1), since the VM pin is pulled down by the RVMS resistor between VM and VSS in the IC when the

battery voltage reaches the overdischarge release voltage (VDU) or higher.

Charger Detection

If the VM pin voltage is lower than the charger detection voltage (VCHA) when a battery in overdischarge

condition is connected to a charger, overdischarge hysteresis is released, and when the battery voltage

becomes equal to or higher than the overdischarge detection voltage (VDL), the overdischarge condition is

released (the discharging control FET is turned on). This action is called charger detection. (The charger

detection reduces the time for charging in which charging current flows through the internal parasitic diode

in the discharging control FET.)

If the VM pin voltage is not lower than the charger detection voltage (VCHA) when a battery in overdischarge

condition is connected to a charger, the overdischarge condition is released (the discharging control FET is

turned on) as usual, when the battery voltage reaches the overdischarge release voltage (VDU) or higher.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

Abnormal Charge Current Detection

If the VM pin voltage drops below the charger detection voltage (VCHA) during charging under the normal

condition and it continues for the overcharge detection delay time (tCU) or longer, the S-8241 turns the

charging control FET off and stops charging. This action is called abnormal charge current detection.

Abnormal charge current detection works when the discharging control FET is on (DO pin voltage is “H”)

and the VM pin voltage drops below the charger detection voltage (VCHA). When an abnormal charge

current flows into a battery in the overdischarge condition, the S-8241 consequently turns the charging

control FET off and stops charging after the battery voltage becomes the overdischarge detection voltage

or higher (DO pin voltage becomes “H”) and the overcharge detection delay time (tCU) elapses.

Abnormal charge current detection is released when the voltage difference between VM pin and VSS pin

becomes lower than the charger detection voltage (VCHA) by separating the charger.

Since the 0 V battery charging function has higher priority than the abnormal charge current detection

function, abnormal charge current may not be detected by the product with the 0 V battery charging

function while the battery voltage is low.

Delay Circuits

The following detection delay times are generated by dividing the approximate 2 kHz clock with a counter.

[Example] Overcharge detection delay time (= abnormal charge current detection delay time): 1.0s

Overdischarge detection delay time: 125 ms

Overcurrent 1 detection delay time: 8 ms

Overcurrent 2 detection delay time: 2 ms

Caution 1. After having detected an overcurrent (overcurrent 1, overcurrent 2, short-circuiting), the state is

held for the overdischarge detection delay time or longer without releasing the load, the condition

changes to the power-down condition when the battery voltage drops below the overdischarge

detection voltage. If the battery voltage drops below the overdischarge detection voltage due to

overcurrent, the discharging control FET is turned off when the overcurrent is detected. If the

battery voltage recovers slowly and if the battery voltage after the overdischarge detection delay

time is equal to or lower than the overdischarge detection voltage, the S-8241 changes to the

power-down condition.

DO pin

VDD

Time

VIOV1

VSS

VIOV2

Overcurrent 2 detection dela

time

(

tIOV2

)

Figure 5

2. Counting for the overcurrent 2 detection delay time starts when the overcurrent 1 is detected.

Having detected the overcurrent 1, if the overcurrent 2 is detected after the overcurrent 2 detection

delay time, the S-8241 turns the discharging control FET off as shown in the figure 5. In this case,

the overcurrent 2 detection delay time may seem to be longer or overcurrent 1 detection delay time

may seem to be shorter than expected.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 17

0V Battery Charging Function (1) (2) (3)

This function enables the charging of a connected battery whose voltage is 0 V by self-discharge. When a

charger having 0 V battery start charging charger voltage (V0CHA) or higher is connected between EB+ and

EB- pins, the charging control FET gate is fixed to VDD potential. When the voltage between the gate and

the source of the charging control FET becomes equal to or higher than the turn-on voltage by the charger

voltage, the charging control FET is turned on to start charging. At this time, the discharging control FET is

off and the charging current flows through the internal parasitic diode in the discharging control FET. If the

battery voltage becomes equal to or higher than the overdischarge release voltage (VDU), the normal

condition returns.

0V Battery Charge Inhibiting Function (1) (3)

This function forbids the charging of a connected battery which is short-circuited internally (0V battery).

When the battery voltage becomes 0.9 V (typ.) or lower, the charging control FET gate is fixed to EB-

potential to forbid charging. Charging can be performed, when the battery voltage is the 0 V battery charge

inhibiting voltage (V0INH) or higher.

(1) Some battery providers do not recommend charging of completely discharged batteries. Please refer to battery

providers before the selection of 0 V battery charging function.

(2) The 0V battery charging function has higher priority than the abnormal charge current detection function.

Consequently, a product with the 0 V battery charging function charges a battery and abnormal charge current

cannot be detected during the battery voltage is low (at most 1.8 V or lower).

(3) When a battery is connected to the IC for the first time, the IC may not enter the normal condition in which

discharging is possible. In this case, set the VM pin voltage equal to the VSS voltage (short the VM and VSS pins or

connect a charger) to enter the normal condition.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Timing Chart

1-1. Overcharge and overdischarge detection (for products with power-down function)

VCU

VCL

VDU

VDL

VDD

VSS

VDD

VSS

VDD

VIOV1

VSS

VCHA

Mode

(2)

(1) (1)

Note: (1) Normal mode, (2) Overcharge mode, (3) Overdischarge mode, (4) Overcurrent mode

The charger is assumed to charge with a constant current.

Battery

voltage

DO pin

CO pin

VM pin

Charger

connected

Load

connected

Overcharge detection delay time (tCU) Overdischarge detection delay time (tDL)

(3) (1)

Figure 6

1-2. Overcharge and overdischarge detection (for products without power-down function)

VCU

VCL

VDU

VDL

Battery

voltage

DO pin

VDD

VSS

VDD

VSS

VDD

VIO V 1

VSS

VCHA

CO pin

VM pin

Charger

connected

Overcharge detection delay time (tCU)

Load

connected

Mode

(2)

(

)

Note: (1) N orm al m ode, (2) O vercharge m ode, (3) O verdischarge m ode, (4) O vercurrent m ode

The charger is assum ed to charge with a constant cu rrent.

(

)

(3)

(

)

(3)

(

)

Overdischarge detection delay time (tDL) Overdischarge detection delay time (tDL)

Figure 7

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 19

2. Overcurrent detection

Figure 8

3. Charger detection

VCU

VCL

VDU

VDL

VDD

VSS

VDD

VSS

VDD

VSS

VCHA

Overdischarge detection delay time (tDL)

If VM pin voltage < VCHA

Overdischarge is released at

overdischarge detection voltage (VDL)

(1)

(3)

(1)

Battery

voltage

DO pin

CO pin

VM pin

Charger connection

Load connection

Mode

Note: (1) Normal mode, (2) Overcharge mode, (3) Overdischarge mode, (4) Overcurrent mode

The charger is assumed to charge with constant current.

Figure 9

(1)

(4)

(1)

(4)

(1)

(4)

(1)

IOV1

SHORT

IOV2

Overcurrent 2 detection delay time (tIOV2)

Load short-circuiting detection delay time (t SHORT)

Battery

voltage

DO pin

CO pin

VM pin

Charger connection

Load connection

Mode

Note: (1) Normal mode, (2) Overcharge mode, (3) Overdischarge mode, (4) Overcurrent mode

The charger is assumed to charge with constant current.

Overcurrent 1 detection delay time (tIOV1)

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

4. Abnormal charge current detection

bnormal charging current detection delay time

( = Overcharge detection delay time (tCU))

Overdischarge detection delay time (tDL)

(3) (1) (2) (1)

(1)

Battery

voltage

DO pin

CO pin

VM pin

Charger connection

Load connection

Mode

Note: (1) Normal mode, (2) Overcharge mode, (3) Overdischarge mode, (4) Overcurrent mode

The charger is assumed to charge with constant current.

VCU

VCL

VDU

VDL

VDD

VSS

VDD

VSS

VDD

VSS

VCHA

Figure 10

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 21

 Battery Protection IC Connection Example

EB+

EB−

S-8241Series

470 Ω

VSS

Battery

VDD

CO VM

FET1 FET2

0.1 µF

1 kΩ

Figure 11

Table 1 Constants for External Components

Symbol Parts Purpose Typ. min. max. Remarks

FET1 Nch

MOS_FET Discharge control



0.4 V

≤

Threshold voltage

≤

overdischarge detection voltage.

Withstand voltage between gate and

source

≥

Charger voltage

FET2 Nch

MOS_FET Charge control



0.4 V

≤

Threshold voltage

≤

overdischarge detection voltage.

Withstand voltage between gate and

source

≥

Charger voltage

R1 Resistor

Protection for ESD and

power fluctuation 470

Ω

300

Ω

R2 value Relation R1

≤

R2 should be

maintained.

C1 Capacitor

Protection for power

fluctuation 0.1

F 0.01

F 1.0

F Install a capacitor of 0.01

F or

higher between VDD and VSS.

R2 Resistor

Protection for charger

reverse connection 1 k

Ω

300

Ω

1.3 k

Ω

To suppress current flow caused by

reverse connection of a charger, set the

resistance within the range from 300

Ω

1.3 k

Ω

*1.

If an FET with a threshold voltage of 0.4 V or lower is used, the FET may fail to cut the charging current.

If an FET with a threshold voltage equal to or higher than the overdischarge detection voltage is used, discharging may stop

before overdischarge is detected.

*2.

If the withstand voltage between the gate and source is lower than the charger voltage, the FET may break.

*3.

If R1 has a higher resistance than R2 and if a charger is connected reversely, current flows from the charger to the IC and the

voltage between VDD and VSS may exceed the absolute maximum rating. Install a resistor of 300

Ω

or higher as R1 for ESD

protection.

If R1 has a high resistance, the overcharge detection voltage increases by IC current consumption.

*4.

If a capacitor C1 is less than 0.0 1

F, DO may oscillate when load short-circuiting is detected, a charger is connected

reversely, or overcurrent 1 or 2 is detected.

A capacitor of 0.01

F or higher as C1 should be installed. In some types of batteries DO oscillation may not stop unless the

C1 capacity is increased. Set the C1 capacity by evaluating the actual application.

*5.

If R2 is set to less than 300

Ω

, a current which is bigger than the power dissipation flows through the IC and the IC may break

when a charger is connected reversely. If a resistor bigger than 1.3 k

Ω

is installed as R2, the charging current may not be cut

when a high-voltage charger is connected.

Caution 1. The above constants may be changed without notice.

2. It has not been confirmed whether the operation is normal or not in circuits other than the above example of

connection. In addition, the example of connection shown above and the constant do not guarantee proper

operation. Perform through evaluation using the

actual application to set the constant.

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

 Precautions

• Pay attention to the operating conditions for input/output voltage and load current so that the power loss in

the IC does not exceed the power dissipation of the package.

• Do not apply an electrostatic discharge to this IC that exceeds the performance ratings of the built-in

electrostatic protection circuit.

• SII claims no responsibility for any and all disputes arising out of or in connection with any infringement by

products including this IC of patents owned by a third party.

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 23

 Typical Characteristics

1. Detection/release voltage temperature characteristics

4.23

4.25

4.27

4.29

4.31

4.33

-50 -25 0 25 50 75 100

Ta(°C)

VCU (V)

Overcharge detection voltage vs. temperature

4.13

4.15

4.17

4.19

4.21

4.23

-50 -25 0 25 50 75 100

Ta(°C)

VCL (V)

Overcharge release voltage vs. temperature

2.20

2.24

2.28

2.32

2.36

2.40

-50 -25 0 25 50 75 100

Ta(°C)

VDL (V)

Overdischarge detection voltage vs. temperature

2.30

2.34

2.38

2.42

2.46

2.50

-50 -25 0 25 50 75 100

Ta(°C)

VDU (V)

Overdischarge release voltage vs. temperature

0.090

0.095

0.100

0.105

0.110

-50 -25 0 25 50 75 100

Ta(°C)

VIOV1 (V)

Overcurrent 1 detection voltage vs. temperature

0.40

0.45

0.50

0.55

0.60

-50 -25 0 25 50 75 100

Ta(°C)

VIOV2 (V)

Overcurrent 2 detection voltage vs. temperature

2. Current consumption temperature characteristics

-25 0 25 50 75

Ta(°C)

IOPE (

Current consumption vs. Temperature in normal mode

-50 100

0.00

0.02

0.04

0.06

0.08

0.10

-50 -25 0 25 50 75 100

Ta(°C)

IPDN (µA)

Current consumption vs. Temperature in power-down mode

BATTERY PROTECTION IC FOR 1-CELL PACK

S-8241 Series Rev.4.1_01

Seiko Instruments Inc.

3. Current consumption Power voltage characteristics (Ta=25°C)

Current consumption - -

power supply volatge dependency

0 2 4 6 8 10

VDD(V)

IOPE (µA)

VM=VSS

4. Detection/release delay time temperature characteristics

0.0

0.5

1.0

1.5

2.0

-50 -25 0 25 50 75 100

Ta(°C)

tcu (s)

Overcharge detection delay time vs. temperature

0.0

0.2

0.4

0.6

0.8

1.0

-50 -25 0 25 50 75 100

Ta(°C)

tCL (ms)

Overcharge release delay time vs. temperature

100

150

200

250

-50 -25 0 25 50 100

Ta(°C)

tDL (ms)

Overdischarge detection delay time vs. temperature

0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

2.0

-50 -25 0 25 50 75 100

Ta(°C)

tcu (s)

Overdischarge release delay time vs. temperature

-50 -25 0 25 50 75

100

Ta(°C)

tIOV1 (ms)

Overcurrent 1 detection delay time vs. temperature

100

200

300

400

500

-50 -25 0 25 50 75 100

Ta(°C)

tIOV1 (

s) Release

Overcurrent 1 release delay time vs. temperature

BATTERY PROTECTION IC FOR 1-CELL PACK

Rev.4.1_01 S-8241 Series

Seiko Instruments Inc. 25

-50 -25 0 25 50 75 100

Ta(°C)

tIOV2 (ms)

Overcurrent 2 detection delay time vs. temperature

-50 -25 0 25 50 75 100

Ta(°C)

tSHORT (µs)

Load short-circuiting delay time vs. temperature

5. Delay time power-voltage characteristics(Ta=25°C)

Overcurrent 1 detection delay time vs. power supply

voltage dependency

2.0 2.5 3.0 3.5 4.0 4.5 5.0

VDD(V)

tIOV1 (ms)

Overcurrent 2 detection delay time vs. power supply

voltage dependency

2.0 2.5 3.0 3.5 4.0 4.5 5.0

VDD(V)

tIOV2 (ms)

6. CO pin/DO pin output current characteristics(Ta=25°C)

CO pin source current characteristics

-1.4

-1.2

-1.0

-0.8

-0.6

-0.4

-0.2

0.0

0 1 2 3 4

VCO(V)

ICO (mA)

VDD=3.5V,VSS=VM=0V

CO pin sink current characteristics

0 1 2 3 4 5

VCO(V)

ICO (µA)

VDD=4.5V,VSS=VM=0V

DO pin source current characteristics

-1.8

-1.6

-1.4

-1.2

-1.0

-0.8

-0.6

-0.4

-0.2

0.0

0 1 2 3 4

VDO(V)

IDO (mA)

VDD=3.5V,VSS=VM=0V

DO pin sink current characteristics

0.0

0.5

1.0

1.5

2.0

2.5

0.0 0.5 1.0 1.5 2.0

VDO(V)

IDO (mA)

VDD=1.8V,VSS=VM=0V

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

2.9±0.2

1.9±0.2

0.95±0.1

0.4±0.1

0.16 +0.1

-0.06

123

No. MP005-A-P-SD-1.2

MP005-A-P-SD-1.2

SOT235-A-PKG Dimensions

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

ø1.5 +0.1

-0 2.0±0.05

ø1.0 +0.2

-0 4.0±0.1

1.4±0.2

0.25±0.1

3.2±0.2

123

No. MP005-A-C-SD-2.1

MP005-A-C-SD-2.1

SOT235-A-Carrier Tape

Feed direction

4.0±0.1(10 pitches:40.0±0.2)

No.

TITLE

SCALE

UNIT mm

Seiko Instruments Inc.

12.5max.

9.0±0.3

ø13±0.2

(60°) (60°)

QTY. 3,000

No. MP005-A-R-SD-1.1

MP005-A-R-SD-1.1

SOT235-A-Reel

Enlarged drawing in the central part

2.0±0.2

0.2

0.65

No.

TITLE

SCALE

UNIT mm

+0.1

-0.05

0.65

1.3±0.1

No. PN005-A-P-SD-1.1

PN005-A-P-SD-1.1

SON5A-A-PKG Dimensions

Seiko Instruments Inc.

ø1.55±0.05

ø1.05±0.1

4.0±0.1

4.0±0.1 0.2±0.05

1.1±0.1

2.05±0.1

(2.25)

No.

TITLE

SCALE

UNIT mm

2.0±0.1

No. PN005-A-C-SD-1.1

PN005-A-C-SD-1.1

SON5A-A-Carrier Tape

Feed direction

Seiko Instruments Inc.

No.

TITLE

SCALE

UNIT mm

QTY. 3000

12.5max.

9.0±0.3

Seiko Instruments Inc.

Enlarged drawing in the central part

No. PN005-A-R-SD-1.1

PN005-A-R-SD-1.1

SON5A-A-Reel

•

The information described herein is subject to change without notice.

• Seiko Instruments Inc. is not responsible for any problems caused by circuits or diagrams described herein

whose related industrial properties, patents, or other rights belong to third parties. The application circuit

examples explain typical applications of the products, and do not guarantee the success of any specific

mass-production design.

• When the products described herein are regulated products subject to the Wassenaar Arrangement or other

agreements, they may not be exported without authorization from the appropriate governmental authority.

• Use of the information described herein for other purposes and/or reproduction or copying without the

express permission of Seiko Instruments Inc. is strictly prohibited.

• The products described herein cannot be used as part of any device or equipment affecting the human

body, such as exercise equipment, medical equipment, security systems, gas equipment, or any apparatus

installed in airplanes and other vehicles, without prior written permission of Seiko Instruments Inc.

• Although Seiko Instruments Inc. exerts the greatest possible effort to ensure high quality and reliability, the

failure or malfunction of semiconductor products may occur. The user of these products should therefore

give thorough consideration to safety design, including redundancy, fire-prevention measures, and

malfunction prevention, to prevent any accidents, fires, or community damage that may ensue.