SII S-8261ABEBD-G3E-TF

Rev.1.9_00
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
The S-8261 series are lithium-ion / lithium polymer
rechargeable battery protection ICs incorporating highaccuracy voltage detection circuit and delay circuit.
The S-8261 series 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 (applicable in 5 mV step)
Accuracy: ±25 mV (+25 °C) and ±30 mV (−5 °C to +55 °C)
• Overcharge hysteresis voltage
0.0 V to 0.4 V*1 Accuracy: ±25 mV
The overcharge hysteresis voltage can be selected from the range 0.0 V to 0.4 V in 50 mV step.
• Overdischarge detection voltage
2.0 V to 3.0 V (applicable in 10 mV step) Accuracy: ±50 mV
• Overdischarge hysteresis voltage 0.0 V to 0.7 V*2 Accuracy: ±50 mV
The overdischarge hysteresis voltage can be selected from the range 0.0 V to 0.7 V in 100 mV step.
• Overcurrent 1 detection voltage
0.05 V to 0.3 V (applicable in 10 mV step) Accuracy: ±15 mV
• Overcurrent 2 detection voltage
0.5 V (fixed) Accuracy: ±100 mV
(2) High voltage device is used for charger connection pins
(VM and CO pins: absolute maximum rating = 28 V)
(3) Delay times (overcharge: tCU, overdischarge: tDL, overcurrent 1: tlOV1, overcurrent 2: tlOV2) are generated
by an internal circuit. No external capacitor is necessary.
Accuracy: ±20%
(4) Three-step overcurrent detection circuit is included.
(overcurrent 1, overcurrent 2 and load short-circuiting)
(5) 0 V battery charge function “available” / “unavailable” are selectable.
(6) Charger detection function and abnormal charge current detection function
• The overdischarge hysteresis is released by detecting negative voltage at the VM pin (−0.7 V typ.).
(Charger detection function)
• When the output voltage of the DO pin is high and the voltage at the VM pin is equal to or lower than
the charger detection voltage (−0.7 V typ.), the output voltage of the CO pin goes low. (Abnormal
charge current detection function)
(7) Low current consumption
• Operation mode
3.5 µA typ., 7.0 µA max.
• Power-down mode
0.1 µA max.
(8) Wide operating temperature range −40 °C to +85 °C
(9) Small package SOT-23-6, 6-Pin SNB(B)
*1. Overcharge release voltage = Overcharge detection voltage − Overcharge hysteresis voltage
(where overcharge release voltage < 3.8 V is prohibited.)
*2. Overdischarge release voltage = Overdischarge detection voltage + Overdischarge hysteresis voltage
(where overdischarge release voltage > 3.4 V is prohibited.)
„ Applications
• Lithium-ion rechargeable battery packs
• Lithium polymer rechargeable battery packs
Seiko Instruments Inc.
1
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Packages
Package name
SOT-23-6
6-Pin SNB(B)
2
Package
MP006-A
BD006-A
Drawing code
Tape
MP006-A
BD006-A
Seiko Instruments Inc.
Reel
MP006-A
BD006-A
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Block Diagrams
1. Product with 0 V Battery Charge Function
DP
Output control circuit
Oscillator control circuit
0 V battery charge
Divider
control
logic
VDD
circuit
DO
Charger
detection circuit
+
CO
−
Overcharge
detection
comparator
+
−
Overcurrent 1
detection comparator
Overdischarge
detection
comparator
RVMD
+
VM
−
Overcurrent 2
detection comparator
+
−
RVMS
+
Load short-circuiting
detection comparator
VSS
Remark
−
All the diodes shown in the figure are parasitic diodes.
Figure 1
2. Product with 0 V Battery Charge Inhibition Function
DP
Output control circuit
Oscillator control circuit
VDD
0 V battery charge
Divider
control
logic
inhibition circuit
DO
Charger
detection circuit
+
CO
−
Overcharge
detection
comparator
+
−
Overcurrent 1
detection comparator
Overdischarge
detection
comparator
+
−
RVMD
+
VM
−
Overcurrent 2
detection comparator
RVMS
+
VSS
Remark
Load short-circuiting
detection comparator
−
All the diodes shown in the figure are parasitic diodes.
Figure 2
Seiko Instruments Inc.
3
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Product Name Structure
1. Product Name
S−8261A
xx
xx
− xxx
−
xx
IC direction in tape specifications*1
T2: SOT-23-6
TF: 6-Pin SNB(B)
Product name (abbreviation)*2
Package name (abbreviation)
MD: SOT-23-6
BD: 6-Pin SNB(B)
Serial code
Assigned from AA to ZZ in alphabetical order
*1. Refer to the taping specifications.
*2. Refer to the Product Name List.
4
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
2. Product Name List
Table 1 (1 / 2)
Model No.
S-8261AAGMD-G2G-T2
S-8261AAHMD-G2H-T2
S-8261AAJBD-G2J-TF
S-8261AAJMD-G2J-T2
S-8261AALMD-G2L-T2
S-8261AAMMD-G2M-T2
S-8261AANMD-G2N-T2
S-8261AAOMD-G2O-T2
S-8261AAPMD-G2P-T2
S-8261AARBD-G2R-TF
S-8261AARMD-G2R-T2
S-8261AASMD-G2S-T2
S-8261AAUMD-G2U-T2
S-8261AAVBD-G2V-TF
S-8261AAXMD-G2X-T2
S-8261AAZMD-G2Z-T2
S-8261ABAMD-G3A-T2
S-8261ABBMD-G3B-T2
S-8261ABCMD-G3C-T2
S-8261ABDBD-G3D-TF
S-8261ABEBD-G3E-TF
S-8261ABGBD-G3G-TF
S-8261ABHBD-G3H-TF
S-8261ABIBD-G3I-TF
S-8261ABJMD-G3J-T2
S-8261ABKMD-G3K-T2
S-8261ABLBD-G3L-TF
S-8261ABMMD-G3M-T2
S-8261ABNMD-G3N-T2
S-8261ABOBD-G3O-TF
S-8261ABPMD-G3P-T2
S-8261ABRMD-G3R-T2
S-8261ABSMD-G3S-T2
Overcharge
detection
voltage [VCU]
4.28 V
4.28 V
4.325 V
4.325 V
4.30 V
4.30 V
4.275 V
4.28 V
4.325 V
4.28 V
4.28 V
4.28 V
4.275 V
4.3 V
4.35 V
4.28 V
4.35 V
4.275 V
4.30 V
4.28 V
4.275 V
4.275 V
4.20 V
4.275 V
4.28 V
4.10 V
4.275 V
4.28 V
4.30 V
4.28 V
4.20 V
4.275 V
4.28 V
Overcharge Overdischarge Overdischarge Overcurrent 1
hysteresis
hysteresis
detection
detection
voltage [VHC] voltage [VDL] voltage [VHD] voltage [VIOV1]
0.2 V
2.3 V
0V
0.16 V
0.2 V
2.3 V
0V
0.08 V
0.25 V
2.5 V
0.4 V
0.15 V
0.25 V
2.5 V
0.4 V
0.15 V
0.1 V
2.3 V
0V
0.08 V
0.1 V
2.3 V
0V
0.2 V
0.1 V
2.3 V
0.1 V
0.1 V
0.2 V
2.3 V
0V
0.13 V
0.25 V
2.5 V
0.4 V
0.1 V
0.2 V
2.3 V
0V
0.1 V
0.2 V
2.3 V
0V
0.1 V
0.2 V
2.3 V
0V
0.15 V
0.1 V
2.3 V
0.1 V
0.1 V
0.2 V
2.3 V
0V
0.13 V
0.1 V
2.3 V
0.1 V
0.1 V
0.25 V
2.5 V
0.4 V
0.1 V
0.2 V
2.5 V
0V
0.2 V
0.2 V
2.3 V
0V
0.13 V
0.2 V
2.3 V
0V
0.13 V
0.2 V
2.3 V
0V
0.13 V
0.2 V
2.3 V
0V
0.1 V
0.2 V
2.3 V
0V
0.1 V
0V
2.3 V
0V
0.1 V
0.2 V
2.3 V
0V
0.2 V
0.2 V
3.0 V
0V
0.08 V
0.25 V
2.5 V
0.4 V
0.15 V
0.2 V
2.3 V
0V
0.05 V
0.2 V
2.8 V
0V
0.1 V
0.2 V
2.3 V
0V
0.06 V
0.2 V
2.3 V
0V
0.04 V
0.1 V
2.8 V
0.1 V
0.15 V
0.2 V
2.5 V
0.4 V
0.15 V
0.1 V
2.5 V
0.5 V
0.18 V
Seiko Instruments Inc.
0 V battery
charge
function
Available
Available
Unavailable
Unavailable
Unavailable
Unavailable
Available
Unavailable
Unavailable
Available
Available
Unavailable
Available
Available
Available
Unavailable
Available
Available
Available
Available
Available
Unavailable
Available
Unavailable
Available
Unavailable
Unavailable
Available
Available
Available
Unavailable
Unavailable
Unavailable
5
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
Table 1 (2 / 2)
Overcharge
Overdischarge
Overcurrent 1
detection delay time
detection delay time
detection delay time
S-8261AAGMD-G2G-T2
1.2 s
144 ms
9 ms
S-8261AAHMD-G2H-T2
1.2 s
144 ms
9 ms
S-8261AAJBD-G2J-TF
1.2 s
144 ms
9 ms
S-8261AAJMD-G2J-T2
1.2 s
144 ms
9 ms
S-8261AALMD-G2L-T2
1.2 s
144 ms
9 ms
S-8261AAMMD-G2M-T2
1.2 s
144 ms
9 ms
S-8261AANMD-G2N-T2
1.2 s
144 ms
9 ms
S-8261AAOMD-G2O-T2
1.2 s
144 ms
9 ms
S-8261AAPMD-G2P-T2
1.2 s
144 ms
9 ms
S-8261AARBD-G2R-TF
1.2 s
144 ms
9 ms
S-8261AARMD-G2R-T2
1.2 s
144 ms
9 ms
S-8261AASMD-G2S-T2
1.2 s
144 ms
4.5 ms
S-8261AAUMD-G2U-T2
4.6 s
144 ms
9 ms
S-8261AAVBD-G2V-TF
4.6 s
144 ms
9 ms
S-8261AAXMD-G2X-T2
4.6 s
144 ms
9 ms
S-8261AAZMD-G2Z-T2
1.2 s
144 ms
9 ms
S-8261ABAMD-G3A-T2
4.6 s
144 ms
9 ms
S-8261ABBMD-G3B-T2
1.2 s
144 ms
9 ms
S-8261ABCMD-G3C-T2
1.2 s
144 ms
9 ms
S-8261ABDBD-G3D-TF
1.84 s
115 ms
7.2 ms
S-8261ABEBD-G3E-TF
1.2 s
144 ms
9 ms
S-8261ABGBD-G3G-TF
1.2 s
36 ms
9 ms
S-8261ABHBD-G3H-TF
0.3 s
36 ms
18 ms
S-8261ABIBD-G3I-TF
1.2 s
36 ms
9 ms
S-8261ABJMD-G3J-T2
1.2 s
144 ms
9 ms
S-8261ABKMD-G3K-T2
1.2 s
144 ms
9 ms
S-8261ABLBD-G3L-TF
1.2 s
36 ms
9 ms
S-8261ABMMD-G3M-T2
1.2 s
144 ms
9 ms
S-8261ABNMD-G3N-T2
1.2 s
144 ms
9 ms
S-8261ABOBD-G3O-TF
1.2 s
144 ms
9 ms
S-8261ABPMD-G3P-T2
1.2 s
144 ms
9 ms
S-8261ABRMD-G3R-T2
1.2 s
144 ms
9 ms
S-8261ABSMD-G3S-T2
1.2 s
144 ms
9 ms
Remark It is possible to change the detection voltages of the product other than above. The delay times
can also be changed within the range listed bellow. For details, please contact SII marketing
department.
Model No.
Delay time
Symbol
Selection range
Remarks
Overcharge detection delay time
tCU
0.15 s
1.2 s
4.6 s
Choose from the left.
Overdischarge detection delay time
tDL
36 ms
144 ms 290 ms Choose from the left.
Overcurrent 1 detection delay time
tlOV1
4.5 ms
9 ms
18 ms
Choose from the left.
Remark The values surrounded by bold lines are the delay time of the standard products.
6
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Pin Configurations
Table 2
SOT-23-6
Top view
6 5 4
1
2
3
Figure 3
2
Symbol
1
DO
2
VM
3
CO
4
5
6
DP
VDD
VSS
Pin description
FET gate control pin for discharge
(CMOS output)
Voltage detection pin between VM and VSS
(Overcurrent detection pin)
FET gate control pin for charge
(CMOS output)
Test pin for delay time measurement
Positive power input pin
Negative power input pin
Table 3
6-Pin SNB(B)
Top view
6 5 4
1
Pin No.
3
Bottom view
1 2 3
Pin No.
Symbol
1
CO
2
VM
3
DO
4
5
6
VSS
DP
VDD
Pin description
FET gate control pin for charge
(CMOS output)
Voltage detection pin between VM and VSS
(Overcurrent detection pin)
FET gate control pin for discharge
(CMOS output)
Negative power input pin
Test pin for delay time measurement
Positive power input pin
*1
6
*1.
5
4
Connect the heatsink of back
side at shadowed area to the
board,
and
set
electric
potential open or VDD.
However, do not use it as
the function of electrode.
Figure 4
Seiko Instruments Inc.
7
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Absolute Maximum Ratings
Table 4
(Ta = 25 °C unless otherwise specified)
Parameter
Symbol Applied pin
Rating
Unit
Input voltage between VDD and VSS*1
VDS
VDD
V
VSS −0.3 to VSS +12
Input pin voltage for VM
VVM
VM
V
VDD −28 to VDD +0.3
Output pin voltage for CO
VCO
CO
V
VVM −0.3 to VDD+0.3
Output pin voltage for DO
VDO
DO
V
VSS −0.3 to VDD +0.3
Power dissipation
SOT-23-6
PD
250
mW

6-pin SNB(B)
PD
90
mW

Operating temperature range
Topr

−40 to +85
°C
Storage temperature range
Tstg

−55 to +125
°C
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.
*1.
8
Even pulse (µs) noise exceeding the above input voltage (VSS + 12 V) may damage the IC, so do not
allow such noise to be applied.
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Electrical Characteristics
1. Except Detection Delay Time (25 °C)
Table 5
Parameter
[DETECTION VOLTAGE]
Overcharge detection voltage
VCU = 3.9 V to 4.4 V, 5 mV Step
Test
Symbol
condition
VCU
1
Remark
(Ta = 25 °C unless otherwise specified)
Test
Min. Typ. Max. Unit
circuit

Ta = −5 °C to 55 °C*1
Overcharge hysteresis voltage
VHC
VHC = 0.0 V to 0.4 V, 50 mV Step
Overdischarge detection voltage
VDL
VDL = 2.0 V to 3.0 V, 10 mV Step
Overdischarge hysteresis voltage
VHD
VHD = 0.0 V to 0.7 V, 100 mV Step
Overcurrent 1 detection voltage
VIOV1
VIOV1 = 0.05 V to 0.3 V, 10 mV Step
Overcurrent 2 detection voltage
VIOV2
Load short-circuiting detection
VSHORT
voltage
Charger detection voltage
VCHA
[INPUT VOLTAGE, OPERATION VOLTAGE]
Operation voltage between VDD
VDSOP1
and VSS
Operation voltage between VDD
VDSOP2
and VM
[CURRENT CONSUMPTION]
Current consumption in normal
I OPE
operation
Current consumption at power
I PDN
down
[OUTPUT RESISTANCE]
CO pin resistance “H”
RCOH
CO pin resistance “L”
RCOL
DO pin resistance “H”
RDOH
VCU
VCU
−0.025
VCU
VCU
−0.030
VHC
VHC
−0.025
VDL
VDL
−0.050
VHD
VHD
−0.050
VIOV1 VIOV1
−0.015
0.4
0.5
VCU
+0.025
VCU
+0.030
VHC
+0.025
VDL
+0.050
VHD
+0.050
VIOV1
+0.015
0.6
V
1
V
1
V
2
V
2
V
2
V
2
1

2

2

3

3

3

0.9
1.2
1.5
V
2
4

−1.0
−0.7
−0.4
V
2

Internal circuit operating voltage
1.5

8
V


Internal circuit operating voltage
1.5

28
V

5
VDD = 3.5 V, VVM = 0 V
1.0
3.5
7.0
µA
2
5
VDD = VVM = 1.5 V


0.1
µA
2
7
7
VCO = 3.0 V, VDD = 3.5 V, VVM = 0 V
VCO = 0.5 V, VDD = 4.5 V, VVM = 0 V
2.5
2.5
5
5
10
10
kΩ
kΩ
4
4
8
VDO = 3.0 V, VDD = 3.5 V, VVM = 0 V
2.5
5
10
kΩ
4
DO pin resistance “L”
RDOL
8
2.5
5
10
4
VDO = 0.5 V, VDD = VVM = 1.8 V
kΩ
[VM INTERNAL RESISTANCE]
Internal resistance between VM
RVMD
6
100
300
900
3
VDD = 1.8 V, VVM = 0 V
kΩ
and VDD
Internal resistance between VM
RVMS
6
10
20
40
3
VDD = 3.5 V, VVM = 1.0 V
kΩ
and VSS
[0 V BATTERY CHARGING FUNCTION]
0 V battery charge starting charger
V0CHA
11
0 V battery charging available
1.2
V
2


voltage
0 V battery charge inhibition battery
V0INH
12
0 V battery charging unavailable
0.5
V
2


voltage
*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.
Seiko Instruments Inc.
9
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
2. Except Detection Delay Time (−40 to +85 °C*1)
Table 6
Parameter
Symbol
Test
condition
Remark
(Ta = −40 to +85 °C*1 unless otherwise specified)
Test
Min. Typ. Max. Unit
circuit
[DETECTION VOLTAGE]
VCU
Overcharge detection voltage
VCU VCU
VCU
V
1
1

−0.055
+0.040
VCU = 3.9 V to 4.4 V, 5 mV Step
VHC
Overcharge hysteresis voltage
VHC VHC
VHC
V
1
1

VHC = 0.0 V to 0.4 V, 50 mV Step
−0.025
+0.025
VDL
Overdischarge detection voltage
VDL
VDL
VDL
V
2
2

VDL = 2.0 V to 3.0 V, 10 mV Step
−0.080
+0.080
VHD
Overdischarge hysteresis voltage
VHD VHD
VHD
V
2
2

−0.050
+0.050
VHD = 0.0 V to 0.7 V, 100 mV Step
VIOV1 VIOV1 VIOV1
Overcurrent 1 detection voltage
VIOV1
V
2
3

VIOV1 = 0.05 V to 0.3 V, 10 mV Step
−0.021
+0.021
Overcurrent 2 detection voltage
VIOV2
3
0.37 0.5 0.63
V
2

Load short-circuiting detection
VSHORT
3
0.7
1.2
1.7
V
2

voltage
Charger detection voltage
VCHA
4
V
2

−1.2 −0.7 −0.2
[INPUT VOLTAGE, OPERATION VOLTAGE]
Operation voltage between VDD
VDSOP1
Internal circuit operating voltage
1.5
8
V



and VSS
Operation voltage between VDD
Internal circuit operating voltage
1.5
28
V
VDSOP2



and VM
[CURRENT CONSUMPTION]
Current consumption in normal
5
0.7
3.5
8.0
2
I OPE
VDD = 3.5 V, VVM = 0 V
µA
operation
Current consumption at power
5
0.1
2
I PDN
VDD = VVM = 1.5 V
µA


down
[OUTPUT RESISTANCE]
CO pin resistance “H”
RCOH
7
1.2
5
15
4
VCO = 3.0 V, VDD = 3.5 V, VVM = 0 V
kΩ
CO pin resistance “L”
RCOL
7
1.2
5
15
4
VCO = 0.5 V, VDD = 4.5 V, VVM = 0 V
kΩ
DO pin resistance “H”
RDOH
8
1.2
5
15
4
VDO = 3.0 V, VDD = 3.5 V, VVM = 0 V
kΩ
DO pin resistance “L”
RDOL
8
1.2
5
15
4
VDO = 0.5 V, VDD = VVM = 1.8 V
kΩ
[VM INTERNAL RESISTANCE]
Internal resistance between VM
RVMD
6
78
300 1310 kΩ
3
VDD = 1.8 V, VVM = 0 V
and VDD
Internal resistance between VM
RVMS
6
7.2
20
44
3
VDD = 3.5 V, VVM = 1.0 V
kΩ
and VSS
[0 V BATTERY CHARGING FUNCTION]
0 V battery charge starting charger
11
0 V battery charging available
1.7
V
2
V0CHA


voltage
0 V battery charge inhibition battery
V0INH
12
0 V battery charging unavailable
0.3
V
2


voltage
*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.
10
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
3. Detection Delay Time
Table 7
S-8261AAG, S-8261AAH, S-8261AAJ, S-8261AAL, S-8261AAM, S-8261AAN, S-8261AAO, S-8261AAP,
S-8261AAR, S-8261AAZ, S-8261ABB, S-8261ABC, S-8261ABE, S-8261ABJ, S-8261ABK, S-8261ABM,
S-8261ABN, S-8261ABO, S-8261ABP, S-8261ABR, S-8261ABS
Test
Test
Parameter
Symbol
Remark
Min. Typ. Max. Unit
condition
circuit
[DELAY TIME] 25 °C
Overcharge detection delay time
tCU
9
0.96 1.2
1.4
s
5

Overdischarge detection delay time
tDL
9
115 144 173
ms
5

Overcurrent 1 detection delay time
tlOV1
10
7.2
9
11
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.8 2.24 2.7
ms
5

Load short-circuiting detection delay
tSHORT
10
220 320 380
5
µs

time
[DELAY TIME] −40 °C to +85 °C*1
Overcharge detection delay time
tCU
9
0.7
1.2
2.0
s
5

Overdischarge detection delay time
tDL
9
80
144
245
ms
5

Overcurrent 1 detection delay time
tlOV1
10
5
9
15
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.2 2.24 3.8
ms
5

Load short-circuiting detection delay
10
150 320 540
5
tSHORT
µs

time
*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.
Table 8
S-8261AAS
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25 °C
Overcharge detection delay time
tCU
9
0.96 1.2
1.4
s
5

Overdischarge detection delay time
tDL
9
115 144 173
ms
5

Overcurrent 1 detection delay time
tlOV1
10
3.6
4.5
5.4
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.8 2.24 2.7
ms
5

Load short-circuiting detection delay
tSHORT
10
220 320 380
5
µs

time
[DELAY TIME] −40 °C to +85 °C*1
Overcharge detection delay time
tCU
9
0.7
1.2
2.0
s
5

Overdischarge detection delay time
tDL
9
80
144
245
ms
5

Overcurrent 1 detection delay time
tlOV1
10
2.5
4.5
7.7
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.2 2.24 3.8
ms
5

Load short-circuiting detection delay
tSHORT
10
150 320 540
5
µs

time
*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.
Seiko Instruments Inc.
11
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
Table 9
S-8261AAU, S-8261AAX, S-8261ABA
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25 °C
Overcharge detection delay time
tCU
9
3.7
4.6
5.5
s
5

Overdischarge detection delay time
tDL
9
115 144 173
ms
5

Overcurrent 1 detection delay time
tlOV1
10
7.2
9
11
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.8 2.24 2.7
ms
5

Load short-circuiting detection delay
tSHORT
10
220 320 380
5
µs

time
*1
[DELAY TIME] −40 °C to +85 °C
Overcharge detection delay time
tCU
9
2.5
4.6
7.8
s
5

Overdischarge detection delay time
tDL
9
80
144 245
ms
5

Overcurrent 1 detection delay time
tlOV1
10
5
9
15
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.2 2.24 3.8
ms
5

Load short-circuiting detection delay
10
150 320 540
5
tSHORT
µs

time
*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.
Table 10
S-8261AAV
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25 °C
Overcharge detection delay time
tCU
9
3.7
4.6
5.5
s
5

Overdischarge detection delay time
tDL
9
115 144 173
ms
5

Overcurrent 1 detection delay time
tlOV1
10
7.2
9
11
ms
5

Overcurrent 2 detection delay time
tlOV2
10
3.6
4.5
5.4
ms
5

Load short-circuiting detection delay
10
450 600 720
5
tSHORT
µs

time
*1
[DELAY TIME] −40 °C to +85 °C
Overcharge detection delay time
tCU
9
2.5
4.6
7.8
s
5

Overdischarge detection delay time
tDL
9
80
144 245
ms
5

Overcurrent 1 detection delay time
tlOV1
10
5
9
15
ms
5

Overcurrent 2 detection delay time
tlOV2
10
2.5
4.5
7.7
ms
5

Load short-circuiting detection delay
10
310 600 1020 µs
5
tSHORT

time
*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.
12
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
Table 11
S-8261ABD
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25°C
Overcharge detection delay time
tCU
9
1.48 1.84 2.2
s
5

Overdischarge detection delay time
tDL
9
92
115 138
ms
5

Overcurrent 1 detection delay time
tlOV1
10
5.76 7.2
8.8
ms
5

Overcurrent 2 detection delay time
tlOV2
10
2.88 3.6 4.32 ms
5

Load short-circuiting detection delay
tSHORT
10
358 488 586
5
µs

time
*1
[DELAY TIME] −40°C to +85°C
Overcharge detection delay time
tCU
9
1.11 1.84 2.89
s
5

Overdischarge detection delay time
tDL
9
68.9 115 182.3 ms
5

Overcurrent 1 detection delay time
tlOV1
10
4.31 7.2 11.59 ms
5

Overcurrent 2 detection delay time
tlOV2
10
2.16
3.6
5.68
ms
5

Load short-circuiting detection delay
10
268 488 770
5
tSHORT
µs

time
*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.
Table 12
S-8261ABG, S-8261ABI, S-8261ABL
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25°C
Overcharge detection delay time
tCU
9
0.96 1.2
1.4
s
5

Overdischarge detection delay time
tDL
9
29
36
43
ms
5

Overcurrent 1 detection delay time
tlOV1
10
7.2
9
11
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.8 2.24 2.7
ms
5

Load short-circuiting detection delay
10
220 320 380
5
tSHORT
µs

time
*1
[DELAY TIME] −40°C to +85°C
Overcharge detection delay time
tCU
9
0.7
1.2
2.0
s
5

Overdischarge detection delay time
tDL
9
20
36
61
ms
5

Overcurrent 1 detection delay time
tlOV1
10
5
9
15
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.2
2.24
3.8
ms
5

Load short-circuiting detection delay
tSHORT
10
150 320 540
5
µs

time
*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.
Seiko Instruments Inc.
13
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
Table 13
S-8261ABH
Parameter
Symbol
Test
condition
Remark
Min.
Typ.
Max.
Unit
Test
circuit
[DELAY TIME] 25°C
Overcharge detection delay time
tCU
9
0.24 0.3 0.36
s
5

Overdischarge detection delay time
tDL
9
29
36
43
ms
5

Overcurrent 1 detection delay time
tlOV1
10
14
18
22
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.8 2.24 2.7
ms
5

Load short-circuiting detection delay
10
220 320 380
5
tSHORT
µs

time
*1
[DELAY TIME] −40°C to +85°C
Overcharge detection delay time
tCU
9
0.17 0.3 0.51
s
5

Overdischarge detection delay time
tDL
9
20
36
61
ms
5

Overcurrent 1 detection delay time
tlOV1
10
10
18
31
ms
5

Overcurrent 2 detection delay time
tlOV2
10
1.2 2.24 3.8
ms
5

Load short-circuiting detection delay
10
150 320 540
5
tSHORT
µs

time
*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.
14
Seiko Instruments Inc.
Rev.1.9_00
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
„ Test Circuits
Remark Unless otherwise specified, the output voltage levels “H” and “L” at CO pin (VCO) and DO pin (VDO) are
judged by the threshold voltage (1.0 V) of the N-channel FET. Judge the CO pin level with respect to
VVM and the DO pin level with respect to VSS.
(1) Test Condition 1, Test Circuit 1
〈〈 Overcharge Detection Voltage, Overcharge Hysteresis Voltage〉〉
The overcharge detection voltage (VCU) is defined by the voltage between VDD and VSS at which VCO goes
from “H” to “L” when the voltage V1 is gradually increased from the starting condition of V1 = 3.5 V. The
overcharge hysteresis voltage (VHC) is then defined as the difference between the overcharge detection
voltage (VCU) and the voltage between VDD and VSS at which VCO goes from “H” to “L” when the voltage V1
is gradually decreased.
(2) Test Condition 2, Test Circuit 2
〈〈Overdischarge Detection Voltage, Overdischarge Hysteresis Voltage〉〉
The overdischarge detection voltage (VDL) is defined as the voltage between VDD and VSS at which VDO
goes from “H” to “L” when the voltage V1 is gradually decreased from the starting condition of V1 = 3.5 V and
V2 = 0 V. The overdischarge hysteresis voltage (VHD) is then defined as the difference between the
overdischarge detection voltage (VDL) and the voltage between VDD and VSS at which VDO goes from “H” to
“L” when the voltage V1 is gradually increased.
(3) Test Condition 3, Test Circuit 2
〈〈 Overcurrent 1 Detection Voltage, Overcurrent 2 Detection Voltage, Load Short-Circuiting Detection
Voltage 〉〉
The overcurrent 1 detection voltage (VIOV1) is defined as the voltage between VM and VSS whose delay time
for changing VDO from “H” to “L” lies between the minimum and the maximum value of the overcurrent 1
detection delay time when the voltage V2 is increased rapidly (within 10 µs) from the starting condition V1 =
3.5 V and V2 = 0 V.
The overcurrent 2 detection voltage (VIOV2) is defined as the voltage between VM and VSS whose delay time
for changing VDO from “H” to “L” lies between the minimum and the maximum value of the overcurrent 2
detection delay time when the voltage V2 is increased rapidly (within 10 µs) from the starting condition V1 =
3.5 V and V2 = 0 V.
The load short-circuiting detection voltage (VSHORT) is defined as the voltage between VM and VSS whose
delay time for changing VDO from “H” to “L” lies between the minimum and the maximum value of the load
short-circuiting detection delay time when the voltage V2 is increased rapidly (within 10 µs) from the starting
condition V1 = 3.5 V and V2 = 0 V.
(4) Test Condition 4, Test Circuit 2
〈〈 Charger Detection Voltage, Abnormal Charge Current Detection Voltage 〉〉
The charger detection voltage (VCHA) is defined as the voltage between VM and VSS at which VDO goes from
“L” to “H” when the voltage V3 is gradually decreased from 0 V after the voltage V1 is gradually increased
from the starting condition of V1 = 1.8 V and V2 = 0 V until the voltage V1 becomes V1 = VDL + (VHD / 2).
The charger detection voltage can be measured only in the product whose overdischarge hysteresis VHD ≠ 0.
Set V1 = 3.5 V and V2 = 0 V. Decrease V2 from 0 V gradually. The voltage between VM and VSS when
VCO goes from “H” to “L” is the abnormal charge current detection voltage. The abnormal charge current
detection voltage has the same value as the charger detection voltage (VCHA).
(5) Test Condition 5, Test Circuit 2
〈〈 Normal Operation Current Consumption, Power-Down Current Consumption〉〉
The operating current consumption (IOPE) is the current that flows through the VDD pin (IDD) under the set
conditions of V1 = 3.5 V and V2 = 0 V (Normal condition).
The power-down current consumption (IPDN) is the current that flows through the VDD pin (IDD) under the set
conditions of V1 = V2 = 1.5 V (Overdischarge condition).
Seiko Instruments Inc.
15
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
(6) Test Condition 6, Test Circuit 3
〈〈 Internal Resistance between VM and VDD, Internal Resistance between VM and VSS 〉〉
The resistance between VM and VDD (RVMD) is the internal resistance between VM and VDD under the set
conditions of V1 = 1.8 V and V2 = 0 V.
The resistance between VM and VSS (RVMS) is the internal resistance between VM and VDD under the set
conditions of V1 = 3.5 V and V2 = 1.0 V.
(7) Test Condition 7, Test Circuit 4
〈〈 CO Pin Resistance “H”, CO Pin Resistance “L” 〉〉
The CO pin resistance “H” (RCOH) is the resistance t the CO pin under the set condition of V1 = 3.5 V, V2 =
0 V and V3 = 3.0 V.
The CO pin resistance “L” (RCOL) is the resistance t the CO pin under the set condition of V1 = 4.5 V, V2 = 0 V
and V3 = 0.5 V.
(8) Test Condition 8, Test Circuit 4
〈〈 DO Pin Resistance “H”, DO Pin Resistance “L” 〉〉
The DO pin resistance “H” (RDOH) is the resistance t the DO pin under the set condition of V1 = 3.5 V, V2 =
0 V and V4 = 3.0 V.
The DO pin resistance “L” (RDOL) is the resistance t the DO pin under the set condition of V1 = 1.8 V, V2 = 0 V
and V4 = 0.5 V.
(9) Test Condition 9, Test Circuit 5
〈〈 Overcharge Detection Delay Time, Overdischarge Detection Delay Time 〉〉
The overcharge detection delay time (tCU) is the time needed for VCO to change from “H” to “L” just after the
voltage V1 momentarily increases (within 10 µs) from the overcharge detection voltage (VCU) − 0.2 V to the
overcharge detection voltage (VCU) + 0.2 V under the set condition of V2 = 0 V.
The overdischarge detection delay time (tDL) is the time needed for VDO to change from “H” to “L” just after the
voltage V1 momentarily decreases (within 10 µs) from the overdischarge detection voltage (VDL) +0.2 V to the
overdischarge detection voltage (VDL) − 0.2 V under the set condition of V2 = 0 V.
(10) Test Condition 10, Test Circuit 5
〈〈 Overcurrent 1 Detection Delay Time, Overcurrent 2 Detection Delay Time, Load Short-circuiting
Detection Delay Time, Abnormal Charge Current Detection Delay Time 〉〉
The overcurrent 1 detection delay time (tIOV1) is the time needed for VDO to go “L” after the voltage V2
momentarily increases (within 10 µs) from 0 V to 0.35 V under the set condition of V1 = 3.5 V and V2=0 V.
The overcurrent 2 detection delay time (tIOV2) is the time needed for VDO to go “L” after the voltage V2
momentarily increases (within 10 µs) from 0 V to 0.7 V under the set condition of V1 = 3.5 V and V2 = 0 V.
The load short-circuiting detection delay time (tSHORT) is the time needed for VDO to go “L” after the voltage V2
momentarily increases (within 10 µs) from 0 V to 1.6 V under the set condition of V1 = 3.5 V and V2 = 0 V.
The abnormal charge current detection delay time is the time needed for VCO to go from “H” to “L” after the
voltage V2 momentarily decreases (within 10 µs) from 0 V to −1.1 V under the set condition of V1 = 3.5 V and
V2 = 0 V. The abnormal charge current detection delay time has the same value as the overcharge detection
delay time.
(11) Test Condition 11, Test Circuit 2 (Product with 0 V battery charge function)
〈〈 0 V Battery Charge Starting Charger Voltage 〉〉
The 0 V battery charge starting charger voltage (V0CHA) is defined as the voltage between VDD and VM at
which VCO goes “H” (VVM + 0.1 V or higher) when the voltage V2 is gradually decreased from the starting
condition of V1 = V2 = 0 V.
16
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
(12) Test Condition 12, Test Circuit 2 (Product with 0 V battery charge inhibition function)
〈〈 0 V Battery Charge Inhibition Battery Voltage 〉〉
The 0 V battery charge inhibition battery voltage (V0INH) is defined as the voltage between VDD and VSS at
which VCO goes “H” (VVM + 0.1 V or higher) when the voltage V1 is gradually increased from the starting
condition of V1 = 0 V and V2 = −4 V.
IDD
A
R1 = 470 Ω
VDD
VDD
DP
DP
S-8261 series
V1
V1
S-8261 series
VM
VSS
VSS
DO
CO
DO
V VDO
VCO
VDO V
V
V2
VCO V
Test Circuit 2
Test Circuit 1
VDD
VDD
DP
DP
V1
CO
COM
COM
IDD
A
VM
V1
S-8261 series
VSS
DO
VSS
DO
VM
A IVM
CO
S-8261 series
VM
CO
IDO A
V2
V4
COM
COM
Test Circuit 3
A ICO
V2
V3
Test Circuit 4
VDD
DP
V1
S-8261 series
VSS
DO
VM
CO
V2
Oscilloscope Oscilloscope
COM
Test Circuit 5
Figure 5
Seiko Instruments Inc.
17
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Operation
Remark
Refer to the “Battery Protection IC Connection Example”.
1. Normal Condition
The S-8261 Series monitors the voltage of the battery connected between VDD pin and VSS pin and the
voltage difference between VM pin and VSS pin 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 IC turns both the charging and discharging control FETs on. This
condition is called the normal condition, and in this condition charging and discharging can be carried out
freely.
Remark
When a battery is connected to the IC for the first time, discharging may not be enabled. In
this case, short the VM pin and VSS pin or connect the charger to restore the normal
condition.
2. Overcurrent Condition (Detection of Overcurrent 1, Overcurrent 2 and Load Short-circuiting)
When a battery in the normal status is in the status where the voltage of the VM pin is equal to or higher
than the overcurrent detection voltage because the discharge current is higher than the specified value
and the status lasts for the overcurrent detection delay time, the discharge control FET is turned off and
discharging is stopped. This status is called the overcurrent status.
In the overcurrent status, the VM and VSS pins are shorted by the resistor between VM and VSS (RVMS)
in the IC. However, the voltage of the VM pin is at the VDD potential due to the load as long as the load
is connected. When the load is disconnected, the VM pin returns to the VSS potential.
This IC detects the status when the impedance between the EB+ pin and EB− pin (Refer to Figure 11)
increases and is equal to the impedance that enables automatic restoration and the voltage at the VM pin
returns to overcurrent detection voltage 1 (VIOV1) or lower and the overcurrent status is restored to the
normal status.
Remark
The impedance that enables automatic restoration varies depending on the battery voltage and
the set value of overcurrent 1 detection voltage.
3. Overcharge Condition
When the battery voltage becomes higher than the overcharge detection voltage (VCU) during charging
under the normal condition and the detection continues for the overcharge detection delay time (tCU) or
longer, the S-8261 Series turns the charging control FET off to stop charging. This condition is called
the overcharge condition.
The overcharge condition is released by the following two cases ((1) and (2)):
(1) When the battery voltage falls below the overcharge release voltage (VCU) − overcharge detection
hysteresis voltage (VHC), the S-8261 Series turns the charging control FET on and turns to the normal
condition.
(2) When a load is connected and discharging starts, the S-8261 Series turns the charging control FET
on and returns to the normal condition. Just after the load is connected and discharging starts, the
discharging current flows through the parasitic diode in the charging control FET. At this moment the
VM pin potential becomes Vf, the voltage for the parasitic diode, higher than VSS level. When the
battery voltage goes under the overcharge detection voltage (VCU) and provided that the VM pin
voltage is higher than the overcurrent 1 detection voltage, the S-8261 Series releases the overcharge
condition.
18
Remark 1.
If the battery is charged to a voltage higher than the overcharge detection voltage (VCU) and
the battery voltage does not fall below the overcharge detection voltage (VCU) even when a
heavy load is connected, the detection of overcurrent 1, overcurrent 2 and load shortcircuiting do not function until the battery voltage falls below over charge detection voltage
(VCU). Since an actual battery has an internal impedance of several dozens of mΩ, the
battery voltage drops immediately after a heavy load that causes overcurrent is connected,
and the detection of overcurrent 1, overcurrent 2 and load short-circuiting function.
2.
When a charger is connected after the overcharge detection, the overcharge condition is
not released even if the battery voltage is below the overcharge release voltage (VCL).
The overcharge condition is released when the VM pin voltage goes over the charger
detection voltage (VCHA) by removing the charger.
Seiko Instruments Inc.
Rev.1.9_00
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
4. Overdischarge Condition
When the battery voltage falls below the overdischarge detection voltage (VDL) during discharging under
the normal condition and the detection continues for the overdischarge detection delay time (tDL) or
longer, the S-8261 Series turns the discharging control FET off to stop discharging. This condition is
called the overdischarge condition. When the discharging control FET is turned off, the VM pin voltage
is pulled up by the resistor between VM and VDD in the IC (RVMD). When the voltage difference between
the VM and VDD then is 1.3 V (typ.) or lower, the current consumption is reduced to the power-down
current consumption (IPDN). This condition is called the power-down condition.
The power-down condition is released when a charger is connected and the voltage difference between
the VM and VDD becomes 1.3 V (typ.) or higher. Moreover when the battery voltage becomes the
overdischarge detection voltage (VDL) or higher, the S-8261 Series turns the discharging FET on and
returns to the normal condition.
5. Charger Detection
When a battery in the overdischarge condition is connected to a charger and provided that the VM pin
voltage is lower than the charger detection voltage (VCHA), the S-8261 Series releases the overdischarge
condition and turns the discharging control FET on when the battery voltage becomes equal to or higher
than the overdischarge detection voltage (VDL) since the charger detection function works. This action is
called charger detection.
When a battery in the overdischarge condition is connected to a charger and provided that the VM pin
voltage is not lower than the charger detection voltage (VCHA), the S-8261 Series releases the
overdischarge condition when the battery voltage reaches the overdischarge detection voltage (VDL) +
overdischarge hysteresis (VHD) or higher.
6. Abnormal Charge Current Detection
If the VM pin voltage falls below the charger detection voltage (VCHA) during charging under normal
condition and it continues for the overcharge detection delay time (tCU) or longer, the charging control
FET turns off and charging stops. This action is called the abnormal charge current detection.
Abnormal charge current detection works when the DO pin voltage is “H” and the VM pin voltage falls
below the charger detection voltage (VCHA). Consequently, if an abnormal charge current flows to an
over-discharged battery, the S-8261 Series turns the charging control FET off and stops charging after
the battery voltage becomes higher than the overdischarge detection voltage which make the DO pin
voltage “H”, and still after the overcharge detection delay time (tCU) elapses.
Abnormal charge current detection is released when the voltage difference between VM pin and VSS pin
becomes less than charger detection voltage (VCHA).
Seiko Instruments Inc.
19
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
7. Delay Circuits
The detection delay times are determined by dividing a clock of the approximately 3.5 kHz with the
counter.
Remark 1. The detection delay time for overcurrent 2 (tIOV2) and load short-circuiting (tSHORT) start when
the overcurrent 1 (VIOV1) is detected. When the overcurrent 2 (VIOV2) or load short-circuiting
(VSHORT) is detected over the detection delay time for each of them (= tIOV2 or tSHORT) after the
detection of overcurrent 1 (VIOV1), the S-8261 Series turns the FET off within tIOV2 or tSHORT of
each detection.
VDD
DO pin
tD
VSS
Overcurrent 2 detection delay time (tIOV2)
VDD
0≦tD≦tIOV2
Time
VIOV2
VM pin
VIOV1
VSS
Time
Figure 6
2. When the overcurrent is detected and continues for longer than the overdischarge detection
delay time (tDL) without releasing the load, the condition changes to the power-down condition
when the battery voltage falls below the overdischarge detection voltage (VDL). When the
battery voltage falls below the overdischarge detection voltage (VDL) due to the overcurrent,
the S-8261 Series turns the discharging control FET off by the overcurrent detection. In this
case the recovery of the battery voltage is so slow that if the battery voltage after the
overdischarge detection delay time (tDL) is still lower than the over discharge detection
voltage (VDL), the S-8261 Series shifts to the power-down condition.
8. DP Pin
The DP pin is a test pin for delay time measurement and it should be open in the actual application. If a
capacitor whose capacitance is larger than 1000 pF or a resister whose resistance is less than 1 MΩ is
connected to this pin, error may occur in the delay times or in the detection voltages.
9. 0 V Battery Charging Function “Available”
This function is used to recharge the connected battery whose voltage is 0 V due to the self-discharge.
When the 0 V battery charge starting charger voltage (V0CHA) or higher is applied between EB+ pin and
EB− pin by connecting a charger, the charging control FET gate is fixed to VDD pin voltage. When the
voltage between the gate and source of the charging control FET becomes equal to or higher than the
turn-on voltage due to 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. When the battery voltage becomes equal to or higher than the
overdischarge release voltage (VDU), the S-8261 Series enters the normal condition.
20
Caution
Some battery providers do not recommend charging for completely self-discharged
battery. Please ask battery providers before determine whether to enable or inhibit the
0 V battery charging function.
Remark
The 0 V battery charge function has higher priority than the abnormal charge current detection
function. Consequently, a product with the 0 V battery charging function is enabled charges
a battery forcibly and abnormal charge current cannot be detected when the battery voltage is
low.
Seiko Instruments Inc.
Rev.1.9_00
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
10. 0 V Battery Charging Function “Unavailable”
This function inhibits the recharging when a battery that is short-circuited (0 V battery) internally is
connected. When the battery voltage is the 0 V battery charge inhibition battery voltage (V0INH) or lower,
the charging control FET gate is fixed to EB− pin voltage to inhibit charging. When the battery voltage is
the 0 V battery charge inhibition battery voltage (V0INH) or higher, charging can be performed.
Caution
Some battery providers do not recommend charging for completely self-discharged
battery. Please ask battery providers before determining the 0 V battery charging
function.
Seiko Instruments Inc.
21
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Operation Timing Chart
1. Overcharge and Overdischarge Detection
VCU
VCU–VHC
Battery
voltage
VDL+VHD
VDL
VDD
DO pin
VSS
VDD
CO pin
VSS
VDD
VM pin
VIOV1
VSS
VCHA
Charger connection
Load connection
Overcharge detection delay time (tCU)
Mode
(1)
(2)
Overdischarge detection delay time (tDL)
(1)
(3)
(1)
Remark (1) Normal condition, (2) Overcharge condition, (3) Overdischarge condition, (4) Overcurrent condition
The charger is supposed to charge with constant current.
Figure 7
2. Overcurrent Detection
Battery
voltage
VCU
VCU−VHC
VDL+VHD
VDL
VDD
DO pin
VSS
VDD
CO pin
VSS
VM pin
VDD
VSHORT
VIOV2
VIOV1
VSS
Charger connection
Load connection
Overcurrent 1 detection delay time (tIOV1)
Mode
(1)
(4)
Overcurrent 2 detection delay time (tIOV2)
(1)
(4)
(1)
Load short-circuiting detection delay time (tSHORT)
(4)
Remark (1) Normal condition, (2) Overcharge condition, (3) Overdischarge condition, (4) Overcurrent condition
The charger is supposed to charge with constant current.
Figure 8
22
Seiko Instruments Inc.
(1)
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
3. Charger Detection
Battery
voltage
VCU
VCU−VHC
VDL+VHD
VDL
DO pin
VDD
VSS
CO pin
VDD
VSS
VM pin
VDD
VSS
VCHA
Charger connection
Load connection
In case VM pin voltage < VCHA
Overdischarge is released at the overdischarge
detection voltage (VDL)
Overdischarge detection delay time (tDL)
Mode
(1)
(1)
(3)
Remark (1) Normal condition, (2) Overcharge condition, (3) Overdischarge condition, (4) Overcurrent condition
The charger is supposed to charge with constant current.
Figure 9
4. Abnormal Charge Current Detection
Battery
voltage
VCU
VCU−VHC
VDL+VHD
VDL
VDD
DO pin
VSS
CO pin
VDD
VSS
VM pin
VDD
VSS
VCHA
Charger connection
Load connection
Abnormal charging current detection delay time
( = Overcharge detection delay time (tCU))
Overdischarge detection delay time (tDL)
Mode
(1)
(3)
(1)
(2)
(1)
Remark (1) Normal condition, (2) Overcharge condition, (3) Overdischarge condition, (4) Overcurrent condition
The charger is supposed to charge with constant current.
Figure 10
Seiko Instruments Inc.
23
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Battery Protection IC Connection Example
EB+
R1
VDD
470 Ω
Battery
C1
S-8261 Series
0.1 µF
DP
VSS
DO
CO
VM
R2
2 kΩ
FET2
FET1
EB−
Figure 11
Table 14
Symbol
Part
Purpose
N-channel
FET1
Discharge control
MOS FET
Constant for External Components
Typ.

Min.

Max.
Remarks

Threshold voltage ≤ Overdischarge detection voltage*1
Gate to source withstanding voltage ≥ Charger voltage*2
Threshold voltage ≤ Overdischarge detection voltage*1
Gate to source withstanding voltage ≥ Charger voltage*2
Resistance should be as small as possible to avoid
ESD protection,
R1
Resistor
470 Ω 300 Ω
1 kΩ lowering of the overcharge detection accuracy caused
For power fluctuation
by VDD pin current.*3
Install a capacitor of 0.022 µF or higher between VDD
C1
Capacitor For power fluctuation
0.1 µF 0.022 µF 1.0 µF
and VSS.*4
Select as large a resistance as large as possible to
Protection for reverse
R2
Resistor
2 kΩ
300 Ω
4 kΩ prevent current when a charger is connected in
connection of a charger
reverse.*5
*1. If the threshold voltage of an FET is low, the FET may not cut the charging current.
If an FET with a threshold voltage equal to or higher than the overdischarge detection voltage is used,
discharging may be stoped before overdischarge is detected.
*2. If the withstanding voltage between the gate and source is lower than the charger voltage, the FET may
be destroyed.
*3. If R1 has a high resistance, the voltage between VDD and VSS may exceed the absolute maximum
rating when a charger is connected in reverse since the current flows from the charger to the IC. Insert a
resistor of 300 Ω or higher to R1 for ESD protection.
*4. If a capacitor of less than 0.022 µF is connected to C1, DO may oscillate when load short-circuiting is
detected.
Be sure to connect a capacitor of 0.022 µF or higher to C1.
*5. If R2 has a resistance higher than 4 kΩ, the charging current may not be cut when a high-voltage charger
is connected.
FET2
24
N-channel
Charge control
MOS FET



Seiko Instruments Inc.
Rev.1.9_00
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Caution1. The above constants may be changed without notice.
2. The DP pin should be open.
3. 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.
„ Precautions
•
The application conditions for the input voltage, output voltage, and load current should not exceed the
package power dissipation.
•
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.
Seiko Instruments Inc.
25
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
„ Characteristics (Typical Data)
1. Detection / Release Voltage Temperature Characteristics
Overcharge release voltage vs. temperature
4.02
4.42
4.00
4.40
3.98
VCL [V]
VCU [V]
Overcharge detection voltage vs. temperature
4.44
4.38
4.36
4.34
−50
3.94
−25
0
25
50
Ta [°C]
75
3.92
−50
100
Overdischarge detection voltage vs. temperature
3.04
VDU [V]
VDL [V]
2.98
2.96
−25
0
25
50
Ta [°C]
75
3.38
−25
0
25
50
Ta [°C]
75
100
0.60
0.35
VIOV2 [V]
VIOV1 [V]
100
Overcurrent 2 detection voltage vs. temperature
0.65
0.30
0.25
0.55
0.50
0.45
0.20
−25
0
25
50
Ta [°C]
75
100
0.40
−50
Load short-circuiting detection voltage vs.temperature
1.5
1.4
VSHORT [V]
75
3.40
3.34
−50
100
0.40
1.3
1.2
1.1
26
25
50
Ta [°C]
3.36
Overcurrent 1 detection voltage vs. temperature
0.45
1.0
−50
0
3.42
3.00
0.15
−50
−25
Overdischarge release voltage vs. temperature
3.44
3.02
2.94
−50
3.96
−25
0
25
50
Ta [°C]
75
100
Seiko Instruments Inc.
−25
0
25
Ta [°C]
50
75
100
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
2. Current Consumption Temperature Characteristics
Current consumption vs. temperature in normal
mode
5
Current consumption vs. temperature in power-down
mode
0.10
0.08
IPDN [µA]
IOPE [µA]
4
3
2
1
0
−50
0.06
0.04
0.02
−25
0
25
50
Ta [°C]
75
0
−50
100
−25
0
25
50
Ta [°C]
75
100
3. Current Consumption Power Voltage Characteristics (Ta=25°C)
Current consumption power supply voltage dependency
6
IOPE [µA]
5
4
3
2
1
0
0
2
4
6
VDD [V]
8
10
12
4. Detection / Release Delay Time Temperature Characteristics
Overcharge detection delay time vs. temperature
1.50
Overcharge release delay time vs. temperature
60
50
tCL [ms]
tCU [s]
1.25
1.00
0.75
0.50
−50
40
30
20
−25
0
25
50
Ta [°C]
75
100
10
−50
−25
0
25
50
Ta [°C]
75
100
Overdischarge detection delay time vs. temperature
200
tDL [ms]
180
160
140
120
100
−50
−25
0
25
50
Ta [°C]
75
100
Seiko Instruments Inc.
27
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Overcurrent 1 detection delay time vs. temperature
15
Overcurrent 2 detection delay time vs. temperature
3.4
3.0
tIOV2 [ms]
tIOV1 [ms]
13
11
9
2.6
2.2
1.8
7
5
−50
Rev.1.9_00
−25
0
25
50
Ta [°C]
75
1.4
−50
100
−25
0
25
50
Ta [°C]
75
100
Load short-circuiting delay time vs. temperature
0.40
tSHORT [ms]
0.36
0.32
0.28
0.24
0.20
0.16
−50
−25
0
25
50
Ta [°C]
75
100
5. Delay Time Power-Voltage Characteristics (Ta=25°C)
Overcurrent 1 detection delay time vs. power supply
voltage dependency
15
Overcurrent 2 detection delay time vs. power supply
voltage dependency
3.4
3.0
tIOV2 [ms]
tIOV1 [V]
13
11
9
7
5
2
2.6
2.2
1.8
2.5
3
3.5
VDD [V]
4
4.5
1.4
2
tSHORT [ms]
Load short-circuiting delay time vs. power supply
voltage dependency
0.32
0.28
0.24
0.2
0.16
2.5
28
3
3.5
VDD [V]
4
4.5
Seiko Instruments Inc.
2.5
3
3.5
VDD [V]
4
4.5
BATTERY PROTECTION IC FOR SINGLE-CELL PACK
S-8261 Series
Rev.1.9_00
6. CO Pin / DO Pin Output Current Characteristics (Ta = 25°C)
CO pin source current characteristics
VDD = 3.5 V, VM = VSS = 0 V
−0.5
CO pin sink current characteristics
VDD = 4.5 V, VM = VSS = 0 V
0.5
0.4
ICO [mA]
ICO [mA]
−0.4
−0.3
−0.2
−0.1
0
0
0.3
0.2
0.1
1
2
3
0
0
4
1
2
3
VCO [V]
VCO [V]
DO pin source current characteristics
VDD = 3.5 V, VM = VSS = 0 V
−0.5
1.5
2
0.4
IDO [mA]
IDO [mA]
5
DO pin sink current characteristics
VDD = 1.8 V, VM = VSS = 0 V
0.5
−0.4
−0.3
−0.2
−0.1
0
0
4
0.3
0.2
0.1
1
2
3
4
0
0
VDO [V]
Seiko Instruments Inc.
0.5
1
VDO [V]
29
2.9±0.2
1.9±0.2
6
0.95
5
1
4
2
3
+0.1
0.15 -0.05
0.95
0.35±0.15
No. MP006-A-P-SD-1.1
TITLE
SOT236-A-PKG Dimensions
No.
MP006-A-P-SD-1.1
SCALE
UNIT
mm
Seiko Instruments Inc.
4.0±0.1(10 pitches:40.0±0.2)
+0.1
ø1.5 -0
2.0±0.05
+0.2
ø1.0 -0
0.25±0.1
4.0±0.1
1.4±0.2
3.2±0.2
3 2 1
4 5 6
Feed direction
No. MP006-A-C-SD-3.1
TITLE
SOT236-A-Carrier Tape
No.
MP006-A-C-SD-3.1
SCALE
UNIT
mm
Seiko Instruments Inc.
12.5max.
9.0±0.3
Enlarged drawing in the central part
ø13±0.2
(60°)
(60°)
No. MP006-A-R-SD-2.1
SOT236-A-Reel
TITLE
MP006-A-R-SD-2.1
No.
SCALE
UNIT
QTY
mm
Seiko Instruments Inc.
3,000
R(0.075)
6
5
4
1
2
3
(0.125)
0.14±0.05
0.2±0.08
0.2±0.08
1.8±0.15
0.5±0.1
0.8±0.05
0.5±0.1
The heatsink of back side has different electric
potential depending on the product.
Confirm specifications of each product.
Do not use it as the function of electrode.
No. BD006-A-P-SD-3.0
TITLE
SNB6B-A-PKG Dimensions
No.
BD006-A-P-SD-3.0
SCALE
UNIT
mm
Seiko Instruments Inc.
ø1.5±0.1
4.0±0.1
2.0±0.05
ø1.1±0.1
0.25±0.05
1.1±0.1
4.0±0.1
2.2±0.1
3 2 1
4 5 6
Feed direction
No. BD006-A-C-SD-2.1
TITLE
SNB6B-A-Carrier Tape
BD006-A-C-SD-2.1
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
12.5max.
9.0±0.3
Enlarged drawing in the central part
ø13±0.2
No. BD006-A-R-SD-1.1
TITLE
SNB6B-A-Reel
No.
BD006-A-R-SD-1.1
SCALE
UNIT
QTY.
mm
Seiko Instruments Inc.
3,000
•
•
•
•
•
•
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.