S-8204BAD-TCT1U - Seiko Semiconductors

S-8204B Series

www.ablicinc.com

BATTERY PROTECTION IC

FOR 3-SERIES OR 4-SERIES CELL PACK

The S-8204B Series includes high-accuracy voltage detection circuits and delay circuits, in single use, makes it possible for

users to monitor the status of 3-series or 4-series cell lithium-ion rechargeable battery. By switching the voltage level which

is applied to the SEL pin, users are able to use the S-8204B Series either for 3-series or 4-series cell pack.

By cascade connection using the S-8204B Series, it is also possible to protect 6-series or more cells*1 lithium-ion

rechargeable battery pack.

*1. Refer to the application note for connection examples of protection circuit for 6-series or more cells.

In case of protecting 5-series cell lithium-ion rechargeable battery pack, contact our sales office.

 Features

 High-accuracy voltage detection function for each cell

Overcharge detection voltage n (n = 1 to 4) 3.65 V to 4.6 V (50 mV step) Accuracy 25 mV

Overcharge release voltage n (n = 1 to 4) 3.5 V to 4.6 V*1 Accuracy 50 mV

Overdischarge detection voltage n (n = 1 to 4) 2.0 V to 3.0 V (100 mV step) Accuracy 80 mV

Overdischarge release voltage n (n = 1 to 4) 2.0 V to 3.4 V*2 Accuracy 100 mV

 Discharge overcurrent detection in 3-step

Discharge overcurrent detection voltage 1 0.05 V to 0.30 V (50 mV step) Accuracy 15 mV

Discharge overcurrent detection voltage 2 0.5 V (fixed) Accuracy 100 mV

Load short-circuit detection voltage 1.0 V (fixed) Accuracy 300 mV

 Settable by external capacitor; overcharge detection delay time, overdischarge detection delay time, discharge

overcurrent detection delay time 1, discharge overcurrent detection delay time 2

(Load short-circuit detection delay time is internally fixed.)

 Switchable between 3-series and 4-series cell by using the SEL pin

 Independent charge and discharge control by the control pins

 Power-down function "available" / "unavailable" is selectable

 High-withstand voltage Absolute maximum rating: 24 V

 Wide operation voltage range 2 V to 22 V

 Wide operation temperature range Ta = 40C to 85C

 Low current consumption

During operation 33 A max. (Ta = 25C)

During power-down 0.1 A max. (Ta = 25C)

 Lead-free, Sn 100%, halogen-free*3

*1. Overcharge hysteresis voltage n (n = 1 to 4) is selectable in 0 V, or in 0.1 V to 0.4 V in 50 mV step.

(Overcharge hysteresis voltage = Overcharge detection voltage  Overcharge release voltage)

*2. Overdischarge hysteresis voltage n (n = 1 to 4) is selectable in 0 V, or in 0.2 V to 0.7 V in 100 mV step.

(Overdischarge hysteresis voltage = Overdischarge release voltage  Overdischarge detection voltage)

*3. Refer to " Product Name Structure" for details.

 Application

 Rechargeable lithium-ion battery pack

 Package

 16-Pin TSSOP

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BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

 Block Diagram

COP

VMP

DOP





VINI

Discharge

overcurrent 1

CDT

CCT

CIT VSS

Control circuit

VMD

VMS

VDD

VC1

VC2

VC3

VC4

CTLC

CTLD

Overcharge

SEL

Delay circuit



































Delay circuit

Over-

discharge 1

Overcharge

Over-

discharge 2

Overcharge

Over-

discharge 3

Overcharge

Over-

discharge 4

Discharge

overcurrent 2

Load short circuit

Delay circuit

Remark Diodes in the figure are parasitic diodes.

Figure 1

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Product Name Structure

1. Product name

S-8204B xx - xxxx x

Environmental code

U: Lead-free (Sn 100%), halogen-free

S: Lead-free, halogen-free

Package name (abbreviation) and packing specifications*1

TCT1: 16-Pin TSSOP, Tape

Serial code*2

Sequentially set from AA to ZZ

*1. Refer to the tape drawing.

*2. Refer to "3. Product name list".

2. Package

Table 1 Package Drawing Codes

Package Name Dimension Tape Reel

16-Pin TSSOP Environmental code = S FT016-A-P-SD FT016-A-C-SD FT016-A-R-SD

Environmental code = U FT016-A-P-SD FT016-A-C-SD FT016-A-R-S1

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

3. Product name list

Table 2

Product Name

Overcharge

Detection

Voltage

[VCU]

Overcharge

Release

Voltage

[VCL]

Overdischarge

Detection

Voltage

[VDL]

Overdischarge

Release

Voltage

[VDU]

Discharge

Overcurrent

Detection

Voltage 1

[VDIOV1]

0 V Battery

Charge

Function

Power-down

Function

S-8204BAB-TCT1y 4.350 V 4.150 V 2.00 V 2.70 V 0.250 V Available Available

S-8204BAC-TCT1y 4.225 V 4.075 V 2.30 V 3.00 V 0.100 V Available Available

S-8204BAD-TCT1y 3.800 V 3.600 V 2.00 V 2.30 V 0.300 V Available Available

S-8204BAE-TCT1y 4.350 V 4.150 V 2.50 V 3.00 V 0.250 V Available Available

S-8204BAF-TCT1y 4.350 V 4.150 V 2.30 V 3.00 V 0.100 V Available Available

S-8204BAG-TCT1y 4.350 V 4.150 V 2.80 V 3.30 V 0.100 V Available Available

S-8204BAH-TCT1y 4.200 V 4.000 V 2.60 V 3.00 V 0.100 V Available Available

S-8204BAI-TCT1y 3.900 V 3.800 V 2.00 V 2.00 V 0.150 V Unavailable Available

S-8204BAJ-TCT1y 4.300 V 4.100 V 2.50 V 2.90 V 0.250 V Available Available

S-8204BAK-TCT1y 3.650 V 3.500 V 2.40 V 3.00 V 0.100 V Available Available

S-8204BAL-TCT1y 4.200 V 4.100 V 2.70 V 2.90 V 0.250 V Available Available

S-8204BAM-TCT1y 4.400 V 4.200 V 2.00 V 2.70 V 0.250 V Available Available

S-8204BAN-TCT1y 4.100 V 4.100 V 2.00 V 2.50 V 0.150 V Unavailable Available

S-8204BAO-TCT1y 3.900 V 3.600 V 2.50 V 2.70 V 0.100 V Unavailable Available

S-8204BAP-TCT1y 4.320 V 4.120 V 2.40 V 3.00 V 0.100 V Unavailable Available

S-8204BAQ-TCT1y 3.800 V 3.600 V 2.00 V 2.30 V 0.150 V Available Available

S-8204BAR-TCT1y 3.850 V 3.650 V 2.50 V 2.70 V 0.150 V Available Available

S-8204BAS-TCT1y 4.250 V 4.150 V 2.80 V 3.00 V 0.150 V Available Available

S-8204BAT-TCT1y 3.650 V 3.500 V 2.00 V 2.70 V 0.100 V Available Available

S-8204BAU-TCT1y 4.200 V 4.100 V 2.70 V 2.90 V 0.100 V Available Available

S-8204BAV-TCT1y 3.900 V 3.600 V 2.00 V 2.70 V 0.100 V Available Available

S-8204BAW-TCT1y 3.800 V 3.650 V 2.20 V 2.50 V 0.100 V Available Available

S-8204BAX-TCT1y 4.250 V 4.250 V 2.00 V 2.00 V 0.100 V Unavailable Available

S-8204BAY-TCT1y 3.900 V 3.600 V 2.30 V 2.50 V 0.100 V Available Available

S-8204BAZ-TCT1y 4.250 V 4.100 V 3.00 V 3.30 V 0.100 V Available Available

S-8204BBA-TCT1y 4.250 V 4.150 V 2.50 V 3.00 V 0.100 V Available Available

S-8204BBB-TCT1y 4.250 V 4.150 V 2.70 V 3.00 V 0.250 V Unavailable Available

S-8204BBC-TCT1y 4.250 V 4.100 V 2.80 V 3.20 V 0.250 V Unavailable Available

S-8204BBD-TCT1y 4.300 V 4.200 V 2.30 V 3.00 V 0.100 V Available Available

S-8204BBE-TCT1y 3.800 V 3.600 V 2.00 V 2.30 V 0.100 V Available Available

S-8204BBF-TCT1y 3.800 V 3.600 V 2.00 V 2.30 V 0.050 V Available Available

S-8204BBG-TCT1y 4.250 V 4.100 V 2.80 V 3.30 V 0.100 V Unavailable Available

S-8204BBH-TCT1y 4.250 V 4.150 V 2.70 V 3.00 V 0.125 V Unavailable Available

S-8204BBI-TCT1U 4.250 V 4.150 V 2.70 V 3.00 V 0.125 V Unavailable Unavailable

S-8204BBJ-TCT1U 4.250 V 4.150 V 2.70 V 3.00 V 0.150 V Unavailable Unavailable

S-8204BBK-TCT1U 4.250 V 4.190 V 2.80 V 3.00 V 0.150 V Available Available

S-8204BBL-TCT1U 4.230 V 4.230 V 2.80 V 3.00 V 0.150 V Available Available

S-8204BBU-TCT1U 4.350 V 4.150 V 2.30 V 3.00 V 0.100 V Unavailable Available

S-8204BBV-TCT1U 4.450 V 4.300 V 2.70 V 3.00 V 0.100 V Unavailable Available

Remark 1. Please contact our sales office for products with detection voltage values other than those specified above.

2. y: S or U

3. Please select products of environmental code = U for Sn 100%, halogen-free products.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Pin Configuration

1. 16-Pin TSSOP

Top view

Figure 2

Table 3

Pin No. Symbol Description

1 COP Connection pin of charge control FET gate (Pch open-drain output)

2 VMP Voltage detection pin between VDD pin and VMP pin

3 DOP Connection pin of discharge control FET gate (CMOS output)

4 VINI Voltage detection pin between VSS pin and VINI pin,

discharge overcurrent 1 / 2 detection pin, load short-circuit detection pin

5 CDT Capacitor connection pin for delay for overdischarge detection

6 CCT Capacitor connection pin for delay for overcharge detection

7 CIT Capacitor connection pin for delay for discharge overcurrent 1 / 2

8 SEL

Pin for switching 3-series or 4-series cell

 VSS level: 3-series cell

 VDD level: 4-series cell

9 VSS Input pin for negative power supply,

connection pin for negative voltage of battery 4

10 VC4 Connection pin for negative voltage of battery 3,

connection pin for positive voltage of battery 4

11 VC3 Connection pin for negative voltage of battery 2,

connection pin for positive voltage of battery 3

12 VC2 Connection pin for negative voltage of battery 1,

connection pin for positive voltage of battery 2

13 VC1 Connection pin for positive voltage of battery 1

14 VDD Input pin for positive power supply,

connection pin for positive voltage of battery 1

15 CTLD Discharge FET control pin

16 CTLC Charge FET control pin

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

 Absolute Maximum Ratings

Table 4

(Ta = 25C unless otherwise specified)

Item Symbol Applied Pin Absolute Maximum Rating Unit

Input voltage between VDD pin and

VSS pin VDS  V

SS  0.3 to VSS  24 V

Input pin voltage VIN

VC1, VC2, VC3, VC4,

CTLC, CTLD, SEL, CCT,

CDT, CIT, VINI

VSS  0.3 to VDD  0.3 V

VMP pin input voltage VVMP VMP VSS  0.3 to VSS  24 V

DOP pin output voltage VDOP DOP VSS  0.3 to VDD  0.3 V

COP pin output voltage VCOP COP VDD  24 to VDD  0.3 V

Power dissipation PD  1100*1 mW

Operation ambient temperature To

 40 to 85 C

Storage temperature Tst

 40 to 125 C

*1. When mounted on board

[Mounted board]

(1) Board size: 114.3 mm  76.2 mm  t1.6 mm

(2) Board name: JEDEC STANDARD51-7

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

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

0 50 100

150

800

400

Power Dissipation (P

) [mW]

Ambient Temperature (Ta) [C]

1000

600

200

1200

Figure 3 Power Dissipation of Package (When Mounted on Board)

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Electrical Characteristics

Table 5 (1 / 2)

(Ta = 25C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Detection Voltage

Overcharge detection voltage n

(n = 1, 2, 3, 4) VCUn 3.65 V to 4.6 V, adjustable,

50 mV step

VCUn

 0.025 VCUn VCUn

 0.025 V 2

Overcharge release voltage n

(n = 1, 2, 3, 4) VCLn

3.5 V to 4.6 V,

adjustable,

50 mV step

VCL  VCU VCLn

 0.05 VCLn VCLn

 0.05 V 2

VCL = VCU VCLn

 0.025 VCLn VCLn

 0.025 V 2

Overdischarge detection voltage n

(n = 1, 2, 3, 4) VDLn 2.0 V to 3.0 V, adjustable,

100 mV step

VDLn

 0.08 VDLn VDLn

 0.08 V 2

Overdischarge release voltage n

(n = 1, 2, 3, 4) VDUn

2.0 V to 3.4 V,

adjustable,

100 mV step

VDL  VDU VDUn

 0.10 VDUn VDUn

 0.10 V 2

VDL = VDU VDUn

 0.08 VDUn VDUn

 0.08 V 2

Discharge overcurrent detection

voltage 1 VDIOV1 0.05 V to 0.30 V, adjustable VDIOV1

 0.015 VDIOV1 VDIOV1

 0.015 V 2

Discharge overcurrent detection

voltage 2 VDIOV2  0.4 0.5 0.6 V 2

Load short-circuit detection

voltage VSHORT  0.7 1.0 1.3 V 2

Temperature coefficient 1*1 TCOE1 Ta = 0°C to 50°C

1.0 0 1.0 mV/°C 2

Temperature coefficient 2*2 TCOE2 Ta = 0°C to 50°C

0.5 0 0.5 mV/°C 2

Delay Time Function

CCT pin internal resistance RINC V1 = 4.7 V, V2 = V3 = V4 = 3.5 V 6.15 8.31 10.2 M 3

CDT pin internal resistance RIND V1 = 1.5 V, V2 = V3 = V4 = 3.5 V 615 831 1020

k 3

CIT pin internal resistance 1 RINI1 V1 = V2 = V3 = V4 = 3.5 V 123 166 204 k 3

CIT pin internal resistance 2 RINI2 V1 = V2 = V3 = V4 = 3.5 V 12.3 16.6 20.4 k 3

CCT pin detection voltage VCCT VDS = 15.2 V,

V1 = 4.7 V, V2 = V3 = V4 = 3.5 V

VDS

 0.68

VDS

 0.70

VDS

 0.72 V 3

CDT pin detection voltage VCDT VDS = 12.0 V,

V1 = 1.5 V, V2 = V3 = V4 = 3.5 V

VDS

 0.68

VDS

 0.70

VDS

 0.72 V 3

CIT pin detection voltage VCIT VDS = 14.0 V,

V1 = V2 = V3 = V4 = 3.5 V

VDS

 0.68

VDS

 0.70

VDS

 0.72 V 3

Load short-circuit detection

delay time tSHORT FET gate capacitance = 2000 pF 100 300 600 s 3

0 V Battery Charge Function

0 V battery charge starting

voltage V0CHA 0 V battery charge function

"available"  1.2 2.0 V 2

0 V battery charge inhibition

battery voltage V0INH 0 V battery charge function

"unavailable" 0.4 0.7 1.1 V 2

Internal Resistance

Resistance between

VMP pin and VDD pin RVMD  0.5 1 1.5 M 4

Resistance between

VMP pin and VSS pin RVMS With power-down function 450 900 1800 k 4

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

Table 5 (2 / 2)

(Ta = 25C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Input Voltage

Operation voltage between VDD

pin and VSS pin VDSOP Fixed output voltage of DOP pin and

COP pin 2  22 V 2

CTLC pin input voltage "H" VCTLCH V1 = V2 = V3 = V4 = 3.5 V   13.2 V 2

CTLC pin input voltage "L" VCTLCL V1 = V2 = V3 = V4 = 3.5 V 10.1   V 2

CTLD pin input voltage "H" VCTLDH V1 = V2 = V3 = V4 = 3.5 V   13.2 V 2

CTLD pin input voltage "L" VCTLDL V1 = V2 = V3 = V4 = 3.5 V 10.1   V 2

SEL pin input voltage "H" VSELH VDS = 14.0 V,

V1 = V2 = V3 = V4 = 3.5 V

VDS

 0.8   V 2

SEL pin input voltage "L" VSELL VDS = 14.0 V,

V1 = V2 = V3 = V4 = 3.5 V   VDS

 0.2 V 2

Input Current

Current consumption

during operation IOPE V1 = V2 = V3 = V4 = 3.5 V  15 33 A 1

Current consumption

during power-down IPDN With power-down function,

V1 = V2 = V3 = V4 = 1.5 V   0.1 A 1

Current consumption

during overdischarge IOPED Without power-down function,

V1 = V2 = V3 = V4 = 1.5 V  14 32 A 1

VC1 pin current IVC1 V1 = V2 = V3 = V4 = 3.5 V 0.5 1.5 3.0 A 4

VC2 pin current IVC2 V1 = V2 = V3 = V4 = 3.5 V 0.3 0 0.3 A 4

VC3 pin current IVC3 V1 = V2 = V3 = V4 = 3.5 V 0.3 0 0.3 A 4

VC4 pin current IVC4 V1 = V2 = V3 = V4 = 3.5 V 0.3 0 0.3 A 4

CTLC pin current "H" ICTLCH V1 = V2 = V3 = V4 = 3.5 V,

VCTLC = VDD 0.4 0.6 0.8 A 4

CTLC pin current "L" ICTLCL V1 = V2 = V3 = V4 = 3.5 V,

maximum current flowing from CTLC pin

20.0 10.0 3.0 A 4

CTLD pin current "H" ICTLDH V1 = V2 = V3 = V4 = 3.5 V,

VCTLD = VDD 0.4 0.6 0.8 A 4

CTLD pin current "L" ICTLDL V1 = V2 = V3 = V4 = 3.5 V,

maximum current flowing from CTLD pin

20.0 10.0 3.0 A 4

SEL pin current "H" ISELH V1 = V2 = V3 = V4 = 3.5 V,

VSEL = VDD   0.1 A 4

SEL pin current "L" ISELL V1 = V2 = V3 = V4 = 3.5 V,

VSEL = VSS 0.1   A 4

Output Current

COP pin source current ICOH V

COP = VDD  0.5 V 10   A 4

COP pin leakage current ICOL V

COP = 0 V   0.1 A 4

DOP pin source current IDOH V

DOP = VDD  0.5 V 10   A 4

DOP pin sink current IDOL V

DOP = VSS  0.5 V 10   A 4

*1. Voltage temperature coefficient 1: Overcharge detection voltage

*2. Voltage temperature coefficient 2: Discharge overcurrent detection voltage 1

*3. Since products are not screened at high and low temperature, the specification for this temperature range is guaranteed

by design, not tested in production.

*4. Details of delay time function is described in " Operation".

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Test Circuit

This chapter describes how to test the S-8204B Series. In case of selecting to use it for 4-series cell battery, set SEL pin

= VDD. For 3-series cell battery, set SEL pin = VSS and short between the VC4 pin and the VSS pin.

1. Current consumption during operation and power-down

(Test circuit 1)

1. 1 Current consumption during operation (IOPE)

The current at the VSS pin when V1 = V2 = V3 = V4 = 3.5 V and VVMP = VDD is the current consumption during

operation (IOPE).

1. 2 Current Consumption during power-down (IPDN) (with power-down function)

The current at the VSS pin when V1 = V2 = V3 = V4 = 1.5 V and VVMP = VSS is the current consumption during

power-down (IPDN).

1. 3 Current consumption during overdischarge (IOPED) (without power-down function)

The current at the VSS pin when V1 = V2 = V3 = V4 = 1.5 V and VVMP = VSS is the current consumption during

overdischarge (IOPED).

2. Overcharge detection voltage, overcharge release voltage, overdischarge detection voltage,

overdischarge release voltage, discharge overcurrent detection voltage 1, discharge overcurrent

detection voltage 2, load short-circuit detection voltage, CTLC pin input voltage "H", CTLC pin

input voltage "L", CTLD pin input voltage "H", CTLD pin input voltage "L", SEL pin input voltage

"H", SEL pin input voltage "L"

(Test circuit 2)

Confirm both the COP pin and the DOP pin are in "H" (its voltage level is VDS  0.9 V or more) after setting VVMP =

VSEL = VCTLC = VCTLD = VDD, VVINI = VSS, CCT pin = Open, CDT pin = Open, CIT pin = Open, V1 = V2 = V3 = V4 =

3.5 V. (This status is referred to as initial status.)

2. 1 Overcharge detection voltage (VCU1), overcharge release voltage (VCL1)

The overcharge detection voltage (VCU1) is a voltage at V1; when the COP pin's voltage is set to "L" (its voltage

level is VDD  0.1 V or less) after increasing a voltage at V1 gradually from the initial status. After that, decreasing

a voltage at V1 gradually, a voltage at V1 when the COP pin's voltage is set to "H"; is the overcharge release

voltage (VCL1).

2. 2 Overdischarge detection voltage (VDL1), overdischarge release voltage (VDU1)

The overdischarge detection voltage (VDL1) is a voltage at V1; when the DOP pin's voltage is set to "L" after

decreasing a voltage at V1 gradually from the initial status. After that, increasing a voltage at V1 gradually, a

voltage at V1 when the DOP pin’s voltage is set to "H"; is the overdischarge release voltage (VDU1).

By changing the voltage at Vn (n = 2 to 4), users can define the overcharge detection voltage (VCUn), the

overcharge release voltage (VCLn), the overdischarge detection voltage (VDLn), the overdischarge release voltage

(VDUn) as well when n = 1.

2. 3 Discharge overcurrent detection voltage 1 (VDIOV1)

The discharge overcurrent detection voltage 1 (VDIOV1) is the VINI pin's voltage; when the DOP pin's voltage is set

to "L" after increasing the VINI pin’s voltage gradually from the initial status.

2. 4 Discharge overcurrent detection voltage 2 (VDIOV2)

The discharge overcurrent detection voltage 2 (VDIOV2) is a voltage at the VINI pin; when a flowing current from

the CIT pin reaches 500 A or more after increasing the VINI pin's voltage gradually from the initial status.

2. 5 Load short-circuit detection voltage (VSHORT)

The load short-circuit detection voltage (VSHORT) is the VINI pin's voltage; when the DOP pin's voltage is set to "L"

after increasing the VINI pin's voltage gradually after setting the CIT pin's voltage VSS level from the initial status.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

2. 6 CTLC pin input voltage "H" (VCTLCH), CTLC pin input voltage "L" (VCTLCL)

The CTLC pin input voltage "L" (VCTLCL) is the CTLC pin's voltage; when the COP pin's voltage is set to "L" after

decreasing the CTLC pin's voltage gradually from the initial status. After that, increasing the CTLC pin's voltage

gradually, the CTLC pin's voltage when the COP pin's voltage is set to "H"; is the CTLC pin input voltage "H"

(VCTLCH).

2. 7 CTLD pin input voltage "H" (VCTLDH), CTLD pin input voltage "L" (VCTLDL)

The CTLD pin input voltage "L" (VCTLDL) is the CTLD pin's voltage; when the DOP pin's voltage is set to "L" after

decreasing the CTLD pin's voltage gradually from the initial status. After that, increasing the CTLD pin's voltage

gradually, the CTLD pin's voltage when the DOP pin's voltage is set to "H"; is the CTLD pin input voltage "H"

(VCTLDH).

2. 8 SEL pin input voltage "H" (VSELH), SEL pin input voltage "L" (VSELL)

Start from the initial status, set V4 = 0 V. Confirm the DOP pin is in "L". After that, decreasing the SEL pin's

voltage gradually, the SEL pin's voltage when the DOP pin's voltage is set to "H"; is the SEL pin input voltage "L"

(VSELL). After that, increasing the SEL pin's voltage gradually, the SEL pin's voltage when the DOP pin's voltage is

set to "L"; is the SEL pin input voltage "H" (VSELH).

3. CCT pin internal resistance, CDT pin internal resistance, CIT pin internal resistance 1, CIT pin

internal resistance 2, CCT pin detection voltage, CDT pin detection voltage, CIT pin detection

voltage, load short-circuit detection delay time

(Test circuit 3)

Confirm both the COP pin and the DOP pin are in "H" (its voltage level is VDS  0.9 V or more) after setting VVMP =

VSEL = VCTLC = VCTLD = VDD, VVINI = CCT = CDT = CIT = VSS, V1 = V2 = V3 = V4 = 3.5 V. (This status is referred to

as initial status.)

3. 1 CCT pin internal resistance (RINC)

The CCT pin internal resistance (RINC) is RINC = VDS / ICCT, ICCT is the current which flows from the CCT pin when

setting V1 = 4.7 V from the initial status.

3. 2 CDT pin internal resistance (RIND)

The CDT pin internal resistance (RIND) is RIND = VDS / ICDT, ICDT is the current which flows from the CDT pin when

setting V1 = 1.5 V from the initial status.

3. 3 CIT pin internal resistance 1 (RINI1)

The CIT pin internal resistance 1 (RINI1) is RINI1 = VDS / ICIT1, ICIT1 is the current which flows from the CIT pin when

setting VVINI = VDIOV1 max.0.05 V from the initial status.

3. 4 CIT pin internal resistance 2 (RINI2)

The CIT pin internal resistance 2 (RINI2) is RINI2 = VDS / ICIT2, ICIT2 is the current which flows from the CIT pin when

setting VVINI = VDIOV2 max0.05 V from the initial status.

3. 5 CCT pin detection voltage (VCCT)

The CCT pin detection voltage (VCCT) is the voltage at the CCT pin when the COP pin's voltage is set to "L"

(voltage VDS  0.1 V or less) after increasing the CCT pin's voltage gradually, after setting V1 = 4.7 V from the

initial status.

3. 6 CDT pin detection voltage (VCDT)

The CDT pin detection voltage (VCDT) is the voltage at the CDT pin when the DOP pin's voltage is set to "L"

(voltage VDS  0.1 V or less) after increasing the CDT pin's voltage gradually, after setting V1 = 1.5 V from the

initial status.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

3. 7 CIT pin detection voltage (VCIT)

The CIT pin detection voltage (VCIT) is the voltage at the CIT pin when the DOP pin's voltage is set to "L" (voltage

VDS  0.1 V or less) after increasing the CIT pin's voltage gradually, after setting VVINI = VDIOV1 max.0.05 V from

the initial status.

3. 8 Load short-circuit detection delay time (tSHORT)

Load short-circuit detection delay time (tSHORT) is a period in which the VINI pin's voltage changes from "H" to "L"

by changing the VINI pin's voltage instantaneously from the initial status to VSHORT max.0.05 V.

4. 0 V battery charge starting voltage (0 V battery charge function "available"), 0 V battery charge

inhibition battery voltage (0 V battery charge function "unavailable")

(Test circuit 2)

Confirm both COP pin and DOP pin are in "H" (its voltage level is VDS  0.9 V or more) after setting VVMP = VSEL =

VCTLC = VCTLD = VDD, VVINI = VSS, CCT pin = Open, CDT pin = Open, CIT pin = Open, V1 = V2 = V3 = V4 = 3.5 V.

(This status is referred to as initial status.)

According to user's selection of the function to charge 0 V battery, either function of voltage for start charging 0 V

battery or battery voltage for inhibit charging 0 V battery is applied to each product.

4. 1 0 V battery charge starting voltage (V0CHA) (0 V battery charge function "available")

0 V battery charge starting voltage (V0CHA) is a voltage at V1; when a voltage at the COP pin is set to "H" after

increasing a voltage at V1 gradually, after setting V1 = V2 = V3 = V4 = 0 V from the initial status.

4. 2 0 V battery charge inhibition battery voltage (V0INH) (0 V battery charge function "unavailable")

0 V battery charge inhibition battery voltage (V0INH) is a voltage at V1; when a voltage at the COP pin is set to "L"

after decreasing a voltage at V1 gradually from the initial status.

5. Resistance between VMP pin and VDD pin, resistance between VMP pin and VSS pin, VC1 pin

current, VC2 pin current, VC3 pin current, VC4 pin current, CTLC pin current "H", CTLC pin

current "L", CTLD pin current "H", CTLD pin current "L", SEL pin current "H", SEL pin current

"L", COP pin source current, COP pin leakage current, DOP pin source current, DOP pin sink

current

(Test circuit 4)

Set VCTLC = VCTLD = VVMP = VSEL = VDD, VVINI = VSS, V1 = V2 = V3 = V4 = 3.5 V, set other pins open. (This status is

referred to as initial status.)

5. 1 Resistance between VMP pin and VDD pin (RVMD)

The value of resistance between VMP pin and VDD pin (RVMD) can be defined by RVMD = VDS / IVMD by using the

VMP pin's current (IVMD) when VVINI = 1.5 V and VVMP = VSS after the initial status.

5. 2 Resistance between VMP pin and VSS pin (RVMS)

The value of resistance between VMP pin and VSS pin (RVMS) can be defined by RVMS = VDS / IVMS by using the

VMP pin's current (IVMS) when V1 = V2 = V3 = V4 = 1.8 V after the initial status.

5. 3 VC1 pin current (IVC1), VC2 pin current (IVC2), VC3 pin current (IVC3), VC4 pin current (IVC4)

In the initial status, each current flows in the VC1 pin, VC2 pin, VC3 pin, VC4 pin is the VC1 pin current (IVC1), the

VC2 pin current (IVC2), the VC3 pin current (IVC3), the VC4 pin current (IVC4), respectively.

5. 4 CTLC pin current "H" (ICTLCH), CTLC pin current "L" (ICTLCL)

In the initial status, a current which flows in the CTLC pin is the CTLC pin current "H" (ICTLCH). After that,

decreasing a voltage at the CTLC pin gradually, the maximum current which flows in the CTLC pin is; the CTLC

pin current "L" (ICTLCL).

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

5. 5 CTLD pin current "H" (ICTLDH), CTLD pin current "L" (ICTLDL)

In the initial status, a current which flows in the CTLD pin is the CTLD pin current "H" (ICTLDH). After that,

decreasing a voltage at the CTLD pin gradually, the maximum current which flows in the CTLD pin is; the CTLD

pin current "L" (ICTLDL).

5. 6 SEL pin current "H" (ISELH), SEL pin current "L" (ISELL)

In the initial status, a current which flows in the SEL pin is the SEL pin current "H" (ISELH). After that, a current

which flows in the SEL pin when setting VSEL = VSS is; the SEL pin current "L" (ISELL).

5. 7 COP pin source current (ICOH), COP pin leakage current (ICOL)

Start from the initial status, set VCOP = VDD  0.5 V, a current which flows in the COP pin is the COP pin source

current (ICOH). After that, a current which flows in the COP pin when setting V1 = V2 = V3 = V4 = 5.5 V, VCOP =

VSS is; the COP pin leakage current (ICOL).

5. 8 DOP pin source current (IDOH), DOP pin sink current (IDOL)

Start from the initial status, set VDOP = VDD  0.5 V, a current which flows in the DOP pin is the DOP pin source

current (IDOH). After that, a current which flows in the DOP pin when setting V1 = V2 = V3 = V4 = 1.8 V, VDOP =

VSS0.5 V is; the DOP pin sink current (IDOL).

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

C1 =

0.1 F

1COP

2VMP

3DOP

4VINI

5 CDT

6 CCT

7CIT

VDD

VC1

VC2

VC3

VC4

CTLC

CTLD

VSS 9

S-8204B

SEL

Figure 4 Test Circuit 1

C1 =

0.1 F

1COP

2VMP

3DOP

4VINI

5 CDT

6CCT

7CIT

VDD

VC1

VC2

VC3

VC4

CTLC

CTLD

VSS 9

S-8204B

SEL

Figure 5 Test Circuit 2

C1 =

0.1 F

1COP

2VMP

3DOP

4VINI

5 CDT

6 CCT

7CIT

VDD

VC1

VC2

VC3

VC4

CTLC

CTLD

VSS 9

S-8204B

SEL

Figure 6 Test Circuit 3

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

C1 =

0.1 F

1 COP

2 VMP

3 DOP

4 VINI

5 CDT

6 CCT

7 CIT

VDD

VC1

VC2

VC3

VC4

CTLC

CTLD

VSS 9

S-8204B

SEL

Figure 7 Test Circuit 4

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Operation

Remark Refer to " Connection Examples of Battery Protection IC".

1. Normal status

In the S-8204B Series, both of the COP pin and the DOP pin get the VDD level; when the voltage of each of the

batteries is in the range of overdischarge detection voltage (VDLn) to overcharge detection voltage (VCUn), and due to

the discharge current, the VINI pin's voltage is discharge overcurrent detection voltage (VDIOV1) or less. This is the

normal status. At this time, the charge FET and discharge FET are on.

2. Overcharge status

In the S-8204B Series, the voltage of one of the batteries increases to the level of more than VCUn, the COP pin is set

in high impedance. This is the overcharge status. The COP pin is pulled down to EB by an external resistor so that

the charge FET is turned off and it stops charging.

This overcharge status is released if either condition mentioned below is satisfied;

(1) In case that the VMP pin voltage is 39 / 40  VDS or more; the voltage of each of the batteries is in the level of

overcharge release voltage (VCLn) or less.

(2) In case that the VMP pin voltage is 39 / 40  VDS or less; the voltage of each of the batteries is in the level of

VCUn or less.

3. Overdischarge status

In the S-8204B Series, when the voltage of one of the batteries decreases to the level of less than VDLn, the DOP pin

voltage gets the VSS level. This is the overdischarge status. The discharge FET is turned off and it stops discharging.

This overcharge status is released if either condition mentioned below is satisfied;

(1) To release; the VMP pin voltage is in the level of more than VDD, the voltage of each of the batteries is in the

VDLn level or more.

(2) To release; the VMP pin voltage is VDS / 2 or more and the VMP pin voltage is in the level of less than VDD,

the voltage of each of the batteries is in the level of overdischarge release voltage (VDUn) or more.

3. 1 Power-down function

In the S-8204B Series, power-down function "available" / "unavailable" is selectable.

3. 1. 1 With power-down function

When the S-8204B Series reaches the overdischarge status, the VMP pin is pulled down to the VSS level by

a resistor between the VMP pin and the VSS pin (RVMS). If the VMP pin voltage decreases to the level of

VDS / 2 or less, the power-down function starts to operate and almost every circuit in the S-8204B Series

stops working.

The power-down function is released if the following condition is satisfied.

(1) The VMP pin voltage gets VDS / 2 or more.

3. 1. 2 Without power-down function

The VMP pin is not pulled down even when the S-8204B Series reaches the overdischarge status. The

overdischarge status is maintained even If the VMP pin voltage decreases to the level of VDS / 2 or less, and

the current consumption decreases to the level of current consumption during overdischarge (IOPED) or less.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

4. Discharge overcurrent status

In the S-8204B Series, in batteries in the normal status, the discharging current increases more than a certain value.

As a result, if the status in which the VINI pin voltage increases to the level of VDIOV1 or more, the DOP pin gets the

VSS level. This is the discharge overcurrent status. At this time, the discharge control FET is turned off and it stops

discharging.

The S-8204B Series has three levels for discharge overcurrent detection (VDIOV1, VDIOV2, VSHORT). In the status of

discharge overcurrent, the COP pin is set in high impedance. The VMP pin is pulled up to the VDD level by a resistor

between the VMP pin and the VDD pin (RVMD).

The S-8204B Series' operations against discharge overcurrent detection voltage 2 (VDIOV2) and load short-circuit

detection voltage (VSHORT) are as well in VDIOV1.

The discharge overcurrent status is released if the following condition is satisfied.

(1) The VMP pin voltage gets VDS 1.2 V (typ.) or more.

5. 0 V battery charge function

In the S-8204B Series, regarding how to charge a discharged battery (0 V battery), users are able to select either

function mentioned below.

(1) Allow to charge a 0 V battery (enable to charge a 0 V battery)

A 0 V battery is charged when the voltage between the VDD pin and the VSS pin (VDS) is 0 V battery charge

starting voltage (V0CHA) or more.

(2) Inhibit charging a 0 V battery (unable to charge a 0 V battery)

A 0 V battery is not charged when the battery voltage is 0 V battery charge inhibition battery voltage (V0INH) or

less.

Caution When the VDD pin voltage is less than the minimum value of operation voltage between the VDD

pin and the VSS pin (VDSOP), the operation of the S-8204B Series is not assured.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

6. Delay time setting

In the S-8204B Series, users are able to set delay time for the period; from detecting the voltage of one of the

batteries or detecting changes in the voltage at the VINI pin, to the output to the COP pin and the DOP pin. Each

delay time is determined by a resistor in the S-8204B Series and an external capacitor.

In the overchage detection, when the voltage of one of the batteries gets VCUn or more, the S-8204B Series starts

charging to the CCT pin's capacitor (CCCT) via the CCT pin's internal resistor (RINC). After a certain period, the COP

pin is set in high impedance if the voltage at the CCT pin reaches the CCT pin detection voltage (VCCT). This period is

overcharge detection delay time (tCU).

tCU is calculated using the following equation (VDS = V1V2V3V4).

tCU [s] = ln (1VCCT / VDS )  CCCT [F]  RINC [M]

= ln (10.7 (typ.))  CCCT [F]  8.31 [M] (typ.)

= 10.0 [M] (typ.)  CCCT [F]

Overdischarge detection delay time (tDL), discharge overcurrent detection delay time 1 (tDIOV1), discharge overcurrent

detection delay time 2 (tDIOV2) are calculated using the following equations as well.

tDL [ms] = ln (1VCDT / VDS)  CCDT [F]  RIND [k]

tDIOV1 [ms] = ln (1VCIT / VDS)  CCIT [F]  RINI1 [k]

tDIOV2 [ms] = ln (1VCIT / VDS)  CCIT [F]  RINI2 [k]

In case CCCT = CCDT = CCIT = 0.1 [F], each delay time tCU, tDL, tDIOV1, tDIOV2 is calculated as follows.

tCU [s] = 10.0 [M] (typ.)  0.1 [F] = 1.0 [s] (typ.)

tDL [ms] = 1000 [k] (typ.)  0.1 [F] = 100 [ms] (typ.)

tDIOV1 [ms] = 200 [k] (typ.)  0.1 [F] = 20 [ms] (typ.)

tDIOV2 [ms] = 20 [k] (typ.)  0.1 [F] = 2.0 [ms] (typ.)

Load short-circuit detection delay time (tSHORT) is fixed internally.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

7. CTLC pin and CTLD pin

The S-8204B Series has two pins to control.

The CTLC pin controls the output voltage from the COP pin, the CTLD pin controls the output voltage from the DOP

pin. Thus it is possible for users to control the output voltages from the COP pin and DOP pin independently. These

controls precede the battery protection circuit.

Table 6 Conditions Set by CTLC Pin

CTLC Pin COP Pin

"H"*1 Normal status*4

Open*2 "High-Z"

"L"*3 "High-Z"

*1. "H"; CTLC  VCTLCH

*2. Pulled down by ICTLCH

*3. "L"; CTLC  VCTLCL

*4. The status is controlled by the voltage detection circuit.

Table 7 Conditions Set by CTLD Pin

CTLD Pin DOP Pin

"H"*1 Normal status*4

Open*2 VSS level

"L"*3 VSS level

*1. "H"; CTLD  VCTLDH

*2. Pulled down by ICTLDH

*3. "L"; CTLD  VCTLDL

*4. The status is controlled by the voltage detection circuit.

Caution Note that when the power supply fluctuates, unexpected behavior might occur if an electrical

potential is generated between the potentials of "H" level input to the CTLC pin / the CTLD pin and

IC's VDD by external filters RVDD1 and CVDD1.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

8. SEL pin

The S-8204B Series has a pin to switch-control the protection for 3-cell or 4-cell battery.

The overdischarge detection for V4-cell is inhibited by setting the SEL pin "L", so that short-circuiting the V4 cell does

not allow the overdischarge detection. This setting makes it possible to use the S-8204B Series for 3-cell protection.

The control by this SEL pin precedes the battery protection circuit. Be sure to use the SEL pin in "H" or "L".

Table 8 Conditions Set by SEL Pin

SEL Pin Condition

"H"*1 4-cell protection

Open Indefinite

"L"*2 3-cell protection

*1. "H"; SEL  VSELH

*2. "L"; SEL  VSELL

In cascade connection, it is possible to use the S-8204B Series for protecting 6-cell, 7-cell or 8-cell battery by

combining the electrical level of the SEL pin.

Table 9 Conditions Set by SEL Pin in Cascade Connection

SEL pin in S-8204B (1) SEL pin in S-8204B (2) Condition

"L"*1 "L"*1 6-series cell protection

"L"*1 "H"*2 7-series cell protection

"H"*2 "H"*2 8-series cell protection

*1. "L"; SEL  VSELL

*2. "H"; SEL  VSELH

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

 Timing Chart (Circuit in Figure 11)

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

(n = 1 to 4)

VCUn

VDUn

VDLn

VCLn

Battery voltage

VEB-

COP pin voltage

DOP pin voltage

VSS

Charger connection

Load connection

Status

Overcharge detection

delay time (tCU)

Overdischarge detection

delay time (tDL)

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

39 / 40  VDD

VSS

VMP pin voltage 1 / 2



VDD

High-Z

VDD

(4)

High-Z

(3)

*1. (1): Normal status

(2): Overcharge status

(3): Overdischarge status

(4): Power-down status

Remark The charger is assumed to charge with a constant current. VEB- indicates the open voltage of the charger.

Figure 8

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

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

(n = 1 to 4)

VCUn

VDUn

VDLn

VCLn

Battery voltage

VEB-

COP pin voltage

DOP pin voltage

VSS

Charger connection

Load connection

Status

Overcharge detection

delay time (tCU) Overdischarge detection

delay time (tDL)

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

39 / 40VDD

VSS

VMP pin voltage 1 / 2



VDD

High-Z

VDD

(3)

*1. (1): Normal status

(2): Overcharge status

(3): Overdischarge status

Remark The charger is assumed to charge with a constant current. VEB- indicates the open voltage of the charger.

Figure 9

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

3. Discharge overcurrent detection

VCUn

VDUn

VDLn

(n = 1 to 4)

VCLn

Battery voltage

VHC

VHD

VDD

DOP pin voltage

VSS

High-Z

VDD

VEB-

COP pin voltage High-Z

High-Z

VDD

VSS

VMP pin voltage

VSHORT

VDIOV2

INI pin voltage

VDD

VDIOV1

Load connection

Status

Discharge overcurrent

detecion delay time 1 (t

DIOV1

)

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

Discharge overcurrent

detecion delay time 2 (t

DIOV2

)

Load short-circuit detecion

delay time (t

SHORT

)

(2) (1) (2)

Charger connection

VSS

*1. (1): Normal status

(2): Discharge overcurrent status

Remark The charger is assumed to charge with a constant current. VEB- indicates the open voltage of the charger.

Figure 10

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Connection Examples of Battery Protection IC

1. 4-series cell (with overcurrent protection function)

ATL

EB

EB

1 COP

2 VMP

3 DOP

4 VINI

5 CDT

6 CCT

7 CIT

8 SEL

VC3 11

VC4 10

VSS 9

VC2 12

VC1 13

VDD 14

CTLD 15

CTLC 16

SEL

CDT

CCT

VC1

VC2

VC3

VC4

VC3

VC2

VC1

VDD

COP

Nch FET1

(Charge FET)

Nch FET2

(Discharge FET)

DOP

VINI

VMP

EB

CIT

SENSE

S-8204B

CTLC

CTLD

Figure 11

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

Table 10 Constants for External Components (Circuit in Figure 11)

Symbol Min. Typ. Max. Unit

RVC1*1 0.51 1 1 k

RVC2*1 0.51 1 1 k

RVC3*1 0.51 1 1 k

RVC4*1 0.51 1 1 k

RDOP 2 5.1 10 k

RCOP 0.1 1 1 M

RVMP 1 5.1 10 k

RCTLC 1 1 10 k

RCTLD 1 1 10 k

RVINI 1 1 10 k

RSEL 1 1 100 k

RVDD*1 22 47 100 

CVC1*1 0 47 100 nF

CVC2*1 0 47 100 nF

CVC3*1 0 47 100 nF

CVC4*1 0 47 100 nF

CCCT 0.01 0.1  F

CCDT 0.01 0.1  F

CVDD*1 0 1 2.2 F

CCIT  0.1



F

RSENSE 



M1 



M2 



ZD1 



REB  1



M

RATL  20



M

Nch FET1 



Nch FET2 



*1. Set up a filter constant to be RVDD  CVDD = 47 F   or more, and to be RVC1  CVC1 = RVC2  CVC2 =

VC3  CVC3 = RVC4  CVC4 = RVDD  CVDD.

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

2. It is recommended that filter constants between the VDD pin and the VSS pin should be set to

approximately 47 F  .

e.g., CVDD  RVDD = 1.0 F  47  = 47 F  

Sufficient evaluation of transient power supply fluctuation and overcurrent protection function with

the actual application is needed to determine the proper constants. Contact our sales office in case

the constants should be set to other than 47 F  .

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

of connection. In addition, the example of connection shown above and the constants do not

guarantee proper operation. Perform thorough evaluation using an actual application to set the

constant.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

2. 7-series cell (cascade connection without overcurrent protection function)

VMP1

EB+

EB

1COP

2VMP

3DOP

4VINI

5 CDT

6 CCT

7CIT

8SEL

VC3 11

VC4 10

VSS 9

VC2 12

VC1 13

VDD 14

CTLD 15

CTLC 16

VINI1

SEL1

VDD1

VC4

VC3

VC2

VC1

1COP

2 VMP

3 DOP

4 VINI

5 CDT

6 CCT

7 CIT

8 SEL

VC3 11

VC4 10

VSS 9

VC2 12

VC1 13

VDD 14

CTLD 15

CTLC 16

SEL2

CDT2

CCT2

VMP2

VINI2

VC3

VDD1

VC5

VC6

VC7

VC8

VC7

VC6

VC5

VDD2

CTLC

CTLD

CDT1

CCT1

CIT1

CIT2

IFC

IFD

COP

Charge FET

VC1

VC2

Discharge FET

DOP

S-8204B

(1)

S-8204B

(2)

Figure 12

Caution 1. It is recommended that filter constants between the VDD pin and the VSS pin should be set to

approximately 47 F  .

e.g., CVDD  RVDD = 1.0 F  47  = 47 F  

Sufficient evaluation of transient power supply fluctuation and overcurrent protection function with

the actual application is needed to determine the proper constants. Contact our sales office in case

the constants should be set to other than 47 F  .

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

of connection. In addition, the example of connection shown above and the constants do not

guarantee proper operation. Perform thorough evaluation using an actual application to set the

constant.

Remark Refer to the application note for constants of each external component.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

3. 8-series cell (cascade connection with overcurrent protection function)

ATL

EB+

EB

1 COP

2 VMP

3DOP

4 VINI

5 CDT

6 CCT

7 CIT

8 SEL

VC3 11

VC4 10

VSS 9

VC2 12

VC1 13

VDD 14

CTLD 15

CTLC 16

VINI1

SEL1

VDD1

VC4

VC3

VC2

VC1

1 COP

2 VMP

3 DOP

4 VINI

5 CDT

6 CCT

7 CIT

8 SEL

VC3 11

VC4 10

VSS 9

VC2 12

VC1 13

VDD 14

CTLD 15

CTLC 16

SEL2

CDT2

CCT2

VC3

VDD1

VC5

VC6

VC7

VC8

VC7

VC6

VC5

VDD2

CTLC

CTLD

CDT1

CCT1

CIT1

IFC

IFD

COP

Charge FET

VC1

VC2

VC4

Discharge FET

DOP

VINI2

INV2

INV1

EB

CIT2

SENSE

S-8204B

(1)

S-8204B

(2)

Figure 13

Caution 1. It is recommended that filter constants between the VDD pin and the VSS pin should be set to

approximately 47 F  .

e.g., CVDD  RVDD = 1.0 F  47  = 47 F  

Sufficient evaluation of transient power supply fluctuation and overcurrent protection function with

the actual application is needed to determine the proper constants. Contact our sales office in case

the constants should be set to other than 47 F  .

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

of connection. In addition, the example of connection shown above and the constants do not

guarantee proper operation. Perform thorough evaluation using an actual application to set the

constant.

Remark Refer to the application note for constants of each external component.

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

 Precautions

 The application conditions for the input voltage, output voltage, and load current should not exceed the package

power dissipation.

 Batteries can be connected in any order; however, there may be cases when discharging cannot be performed when

a battery is connected. In such a case, short the VMP pin and the VDD pin to return the IC to the normal mode.

 If both an overcharge battery and an overdischarge battery are included among the whole batteries, the condition is

set in overcharge status and overdischarge status. Therefore either charging or discharging is impossible.

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

protection circuit.

 ABLIC Inc. claims no responsibility for any 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 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

 Characteristics (Typical Data)

1. Current consumption

1. 1 IOPE vs. VDS 1. 2 IOPE vs. Ta

01520

IOPE [μA]

VDS [V]

522

40 0 25 50 75

OPE

[μA]

Ta [ C]

25 85

1. 3 IPDN vs. VDS 1. 4 IPDN vs. Ta

01520

PDN

[μA]

0.06

0.04

0.02

[V]

0.10

522

0.05

0.03

0.01

0.07

0.08

0.09

40 0 25 50 75

IPDN [μA]

0.06

0.04

0.02

Ta [ C]

0.10

25 85

0.01

0.03

0.05

0.09

0.07

0.08

2. Overcharge detection / release voltage, overdischarge detection / release voltage, overcurrent

detection voltage

2. 1 VCU vs. Ta 2. 2 VCL vs. Ta

40 0 25 50 75

[V]

4.355

4.345

4.335

4.325

Ta [ C]

4.375

25 85

4.330

4.340

4.350

4.370

4.360

4.365

40 0 25 50 75

VCL [V]

4.16

4.14

4.12

4.10

Ta [ C]

4.20

25 85

4.18

2. 3 VDU vs. Ta 2. 4 VDL vs. Ta

40 0 25 50 75

VDU [V]

2.72

2.68

2.64

2.60

Ta [ C]

2.80

25 85

2.62

2.66

2.70

2.78

2.74

2.76

40 0 25 50 75

[V]

2.04

2.00

1.96

1.92

Ta [ C]

2.08

25 85

1.94

1.98

2.02

2.06

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

2. 5 VDIOV1 vs. VDS 2. 6 VDIOV1 vs. Ta

10 12 13 14 15

VDIOV1 [V]

0.27

0.25

0.23

0.21

VDS [V]

0.29

11 16

0.22

0.24

0.26

0.28

40 0 25 50 75

DIOV1

[V]

0.27

0.25

0.23

0.21

Ta [ C]

0.29

25 85

0.22

0.24

0.26

0.28

2. 7 VDIOV2 vs. VDS 2. 8 VDIOV2 vs. Ta

10 12 13 14 15

DIOV2

[V]

0.54

0.50

0.46

0.42

[V]

0.58

11 16

0.44

0.48

0.52

0.56

40 0 25 50 75

VDIOV2 [V]

0.54

0.50

0.46

0.42

Ta [ C]

0.58

25 85

0.44

0.48

0.52

0.56

2. 9 VSHORT vs. VDS 2. 10 VSHORT vs. Ta

10 12 13 14 15

VSHORT [V]

1.0

0.7

VDS [V]

1.3

11 16

0.8

0.9

1.1

1.2

40 0 25 50 75

SHORT

[V]

1.0

0.7

Ta [ C]

1.3

25 85

0.8

0.9

1.1

1.2

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

S-8204B Series Rev.3.9_01

3. CCT pin internal resistance / detection voltage, CDT pin internal resistance / detection voltage, CIT

pin internal resistance / detection voltage and load short-circuit detection delay time

3. 1 RINC vs. Ta 3. 2 VCCT vs. Ta (VDS = 15.2 V)

40 0 25 50 75

RINC [M



]

9.0

6.0

Ta [ C]

12.0

25 85

7.0

8.0

10.0

11.0

40 0 25 50 75

VCCT [V]

10.7

10.4

Ta [ C]

10.9

25 85

10.5

10.6

10.8

3. 3 RIND vs. Ta 3. 4 VCDT vs. Ta (VDS = 12.0 V)

40 0 25 50 75

IND



]

900

600

Ta [ C]

1200

25 85

700

800

1000

1100

40 0 25 50 75

CDT

[V]

8.2

Ta [ C]

8.6

25 85

8.3

8.4

8.5

3. 5 RINI1 vs. Ta 3. 6 VCIT vs. Ta (VDS = 14.0 V)

40 0 25 50 75

RINI1 [k



]

180

120

Ta [ C]

240

25 85

140

160

200

220

40 0 25 50 75

VCIT [V]

9.6

Ta [ C]

10.0

25 85

9.7

9.8

9.9

3. 7 RINI2 vs. Ta 3. 8 tSHORT vs. Ta

40 0 25 50 75

RINI2 [k



]

18.0

12.0

Ta [ C]

24.0

25 85

14.0

16.0

20.0

22.0

40 0 25 50 75

tSHORT [μs]

300

Ta [ C]

600

25 85

100

200

400

500

BATTERY PROTECTION IC FOR 3-SERIES OR 4-SERIES CELL PACK

Rev.3.9_01 S-8204B Series

4. COP pin / DOP pin

4. 1 ICOH vs. VCOP 4. 2 ICOL vs. VCOP

0 3.5 7 14

COH

[mA]

COP

[V]

10.5

0 5 10 20

COL

[μA]

0.07

0.05

0.03

0.00

COP

[V]

0.09

0.08

0.06

0.04

0.10

0.01

0.02

4. 3 IDOH vs. VDOP 4. 4 IDOL vs. VDOP

0 3.5 7 14

DOH

[mA]

DOP

[V]

10.5

0 1.8 3.6 7.2

DOL

[mA]

DOP

[V]

5.4

3.5

2.5

1.5

4.5

4.0

3.0

2.0

5.0

0.5

1.0

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

0.17±0.05

5.1±0.2

0.22±0.08

0.65

No. FT016-A-P-SD-1.2

FT016-A-P-SD-1.2

TSSOP16-A-PKG Dimensions

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

4.0±0.1

2.0±0.1

ø1.5+0.1

-0

ø1.6±0.1

8.0±0.1

4.2±0.2

6.5 +0.4

-0.2

0.3±0.05

1.5±0.1

(7.2)

No. FT016-A-C-SD-1.1

FT016-A-C-SD-1.1

TSSOP16-A-Carrier Tape

Feed direction

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

17.4±1.0

No. FT016-A-R-SD-2.0

FT016-A-R-SD-2.0

TSSOP16-A- Reel

QTY. 2,000

Enlarged drawing in the central part

2±0.5

ø13±0.2

ø21±0.8

21.4±1.0

17.4 +2.0

-1.5

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

17.4±1.0

No. FT016-A-R-S1-1.0

FT016-A-R-S1-1.0

TSSOP16-A- Reel

QTY. 4,000

Enlarged drawing in the central part

2±0.5

ø13±0.2

ø21±0.8

21.4±1.0

17.4 +2.0

-1.5

Disclaimers (Handling Precautions)

1. All the information described herein

(product data,

specifications,

figures,

tables,

programs,

algorithms and application

circuit examples,

etc.)

is current as of publishing date of this document and is subject to change without notice.

2. The circuit examples and the usages described herein are for reference only, and do not guarantee the success of

any specific mass-production design.

ABLIC Inc. is not responsible for damages caused by the reasons other than the products described herein

(hereinafter "the products") or infringement of third-party intellectual property right and any other right due to the use

of the information described herein.

3. ABLIC Inc. is not responsible for damages caused by the incorrect information described herein.

4. Be careful to use the products within their specified ranges. Pay special attention to the absolute maximum ratings,

operation voltage range and electrical characteristics, etc.

ABLIC Inc. is not responsible for damages caused by failures and / or accidents, etc. that occur due to the use of the

products outside their specified ranges.

5. When using the products, confirm their applications, and the laws and regulations of the region or country where they

are used and verify suitability, safety and other factors for the intended use.

6. When exporting the products, comply with the Foreign Exchange and Foreign Trade Act and all other export-related

laws, and follow the required procedures.

7. The products must not be used or provided (exported) for the purposes of the development of weapons of mass

destruction or military use. ABLIC Inc. is not responsible for any provision (export) to those whose purpose is to

develop, manufacture, use or store nuclear, biological or chemical weapons, missiles, or other military use.

8. The products are not designed to be used as part of any device or equipment that may affect the human body, human

life, or assets (such as medical equipment, disaster prevention systems, security systems, combustion control

systems, infrastructure control systems, vehicle equipment, traffic systems, in-vehicle equipment, aviation equipment,

aerospace equipment, and nuclear-related equipment), excluding when specified for in-vehicle use or other uses. Do

not apply the products to the above listed devices and equipments without prior written permission by ABLIC Inc.

Especially, the products cannot be used for life support devices, devices implanted in the human body and devices

that directly affect human life, etc.

Prior consultation with our sales office is required when considering the above uses.

ABLIC Inc. is not responsible for damages caused by unauthorized or unspecified use of our products.

9. Semiconductor products may fail or malfunction with some probability.

The user of the products should therefore take responsibility to give thorough consideration to safety design including

redundancy, fire spread prevention measures, and malfunction prevention to prevent accidents causing injury or

death, fires and social damage, etc. that may ensue from the products' failure or malfunction.

The entire system must be sufficiently evaluated and applied on customer's own responsibility.

10. The products are not designed to be radiation-proof. The necessary radiation measures should be taken in the

product design by the customer depending on the intended use.

11. The products do not affect human health under normal use. However, they contain chemical substances and heavy

metals and should therefore not be put in the mouth. The fracture surfaces of wafers and chips may be sharp. Be

careful when handling these with the bare hands to prevent injuries, etc.

12. When disposing of the products, comply with the laws and ordinances of the country or region where they are used.

13. The information described herein contains copyright information and know-how of ABLIC Inc.

The information described herein does not convey any license under any intellectual property rights or any other

rights belonging to ABLIC Inc. or a third party. Reproduction or copying of the information from this document or any

part of this document described herein for the purpose of disclosing it to a third-party without the express permission

of ABLIC Inc. is strictly prohibited.

14. For more details on the information described herein, contact our sales office.

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