SII S-8242BAY

Rev.1.4_00
BATTERY PROTECTION IC
FOR 2-SERIAL-CELL PACK
S-8242B Series
The S-8242B Series are protection ICs for 2-serial-cell
lithium-ion/lithium polymer rechargeable batteries and
include high-accuracy voltage detectors and delay circuits.
These ICs are suitable for protecting 2-cell rechargeable
lithium-ion / lithium polymer battery packs from overcharge,
overdischarge, and overcurrent.
„ Features
(1)
High-accuracy voltage detection for each cell
• Overcharge detection voltage n (n = 1, 2)
3.9 V to 4.5 V (50 mV steps)
Accuracy ±25 mV
• Overcharge release voltage n (n = 1, 2)
3.8 V to 4.5 V*1
Accuracy ±50 mV
• Overdischarge detection voltage n (n = 1, 2)
2.0 V to 3.0 V (100 mV steps)
Accuracy ±50 mV
*2
Accuracy ±100 mV
• Overdischarge release voltage n (n = 1, 2)
2.0 V to 3.4 V
*1. Overcharge release voltage = Overcharge detection voltage − Overcharge hysteresis voltage
(Overcharge hysteresis voltage n (n = 1, 2) can be selected as 0 V or from a range of 0.1 V to
0.4 V in 50 mV steps.)
*2. Overdischarge release voltage = Overdischarge detection voltage + Overdischarge hysteresis voltage
(Overdischarge hysteresis voltage n (n = 1, 2) can be selected as 0 V or from a range of 0.1 V to
0.7 V in 100 mV steps.)
(2) Two-level overcurrent detection (overcurrent 1, overcurrent 2)
• Overcurrent detection voltage 1
0.05 V, 0.08 V to 0.30 V (10 mV steps)
Accuracy ±15 mV
• Overcurrent detection voltage 2
1.2 V (fixed)
Accuracy ±300 mV
(3) Delay times (overcharge, overdischarge, overcurrent) are generated by an internal circuit (external capacitors are
unnecessary).
(4) 0 V battery charge function available/unavailable are selectable.
(5) Charger detection function
• The overdischarge hysteresis is released by detecting negative voltage at the VM pin (−0.7 V typ.) (Charger
detection function).
(6) High-withstanding-voltage devices
Absolute maximum rating: 28 V
(7) Wide operating temperature range
−40°C to +85 °C
(8) Low current consumption
Operation mode
10 µA max. (+25°C)
Power-down mode
0.1 µA max. (+25°C)
(9) Small package
SNT-8A, 8-Pin TSSOP
(10) Lead-free products
„ Applications
• Lithium-ion rechargeable battery packs
• Lithium polymer rechargeable battery packs
„ Packages
Package Name
SNT-8A
8-Pin TSSOP
Package
PH008-A
FT008-A
Drawing Code
Tape
Reel
PH008-A
PH008-A
FT008-E
FT008-E
Seiko Instruments Inc.
Land
PH008-A

1
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Block Diagram
Delay circuit, controller,
0 V battery charge/
charge inhibition circuit
DO
VDD
−
+
+
−
CO
+
−
+
−
300 kΩ
Charger
detector
VM
10 kΩ
Remark All the diodes in the figure are parasitic diodes.
Figure 1
2
Seiko Instruments Inc.
VC
−
+
+
−
VSS
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Product Name Structure
1. Product Name
S-8242B
xx
-
xxxx
G
Package name (abbreviation) and IC packing specifications *1
I8T1: SNT-8A, Tape
T8T1: 8-Pin TSSOP, Tape
Serial code
Sequentially set from AA to ZZ
*1. Refer to the taping drawing.
2. Product Name List
(1) SNT-8A Package
Table 1
Overcharge
Detection
Voltage
(VCU)
Overcharge
Release
Voltage
(VCL)
Overdischarge
Detection
Voltage
(VDL)
Overdischarge
Release
Voltage
(VDU)
Overcurrent
Detection
Voltage 1
(VIOV1)
0 V Battery
Charge
S-8242BAB-I8T1G
4.325 V
4.075 V
2.2 V
2.9 V
0.21 V
Unavailable
S-8242BAD-I8T1G
S-8242BAE-I8T1G
S-8242BAH-I8T1G
S-8242BAM-I8T1G
S-8242BAN-I8T1G
S-8242BAO-I8T1G
S-8242BAQ-I8T1G
S-8242BAR-I8T1G
S-8242BAU-I8T1G
S-8242BAV-I8T1G
S-8242BAW-I8T1G
S-8242BAX-I8T1G
S-8242BAY-I8T1G
S-8242BAZ-I8T1G
S-8242BBA-I8T1G
S-8242BBB-I8T1G
4.350 V
4.430 V
4.300 V
4.300 V
4.350 V
4.350 V
4.350 V
4.300 V
4.300 V
4.350 V
4.350 V
4.300 V
4.210 V
4.190 V
4.350 V
4.270 V
4.350 V
4.200 V
4.100 V
4.100 V
4.150 V
4.150 V
4.150 V
4.100 V
4.100 V
4.150 V
4.150 V
4.100 V
4.210 V
4.190 V
4.150 V
4.070 V
2.3 V
2.3 V
2.4 V
2.6 V
2.3 V
2.3 V
2.3 V
2.6 V
2.4 V
2.2 V
2.2 V
2.4 V
2.0 V
2.3 V
3.0 V
2.3 V
2.9 V
2.9 V
3.0 V
3.0 V
2.9 V
2.9 V
2.9 V
3.0 V
3.0 V
2.9 V
2.9 V
3.0 V
2.0 V
2.9 V
3.4 V
2.3 V
0.08 V
0.08 V
0.20 V
0.28 V
0.25 V
0.10 V
0.20 V
0.21 V
0.28 V
0.20 V
0.25 V
0.21 V
0.20 V
0.10 V
0.25 V
0.20 V
Available
Available
Unavailable
Unavailable
Unavailable
Available
Unavailable
Unavailable
Unavailable
Unavailable
Unavailable
Unavailable
Unavailable
Available
Unavailable
Available
Product Name / Item
Remark
Please contact our sales office for the products with detection voltage value other than those specified above.
(2) 8-Pin TSSOP Package
Table 2
Product Name / Item
S-8242BAC-T8T1G
S-8242BAH-T8T1G
S-8242BAI-T8T1G
S-8242BAP-T8T1G
S-8242BAR-T8T1G
Remark
Overcharge
Detection
Voltage
(VCU)
4.350 V
4.300 V
4.250 V
4.100 V
4.300 V
Overcharge
Release
Voltage
(VCL)
4.150 V
4.100 V
4.050 V
3.800 V
4.100 V
Overdischarge
Detection
Voltage
(VDL)
2.3 V
2.4 V
2.4 V
2.2 V
2.6 V
Overdischarge
Release
Voltage
(VDU)
3.0 V
3.0 V
3.0 V
2.4 V
3.0 V
Overcurrent
Detection
Voltage 1
(VIOV1)
0.30 V
0.20 V
0.15 V
0.30 V
0.21 V
0 V Battery
Charge
Available
Unavailable
Available
Unavailable
Unavailable
Please contact our sales office for the products with detection voltage value other than those specified above.
Seiko Instruments Inc.
3
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Pin Configurations
Table 3
SNT-8A
Top view
Pin No.
1
8
2
7
3
6
4
5
Symbol
Description
Connection of charge control FET gate
(CMOS output)
Connection of discharge control FET gate
2
DO
(CMOS output)
NC*1
3
No connection
Connection for negative power supply input
4
VSS
and negative voltage of battery 2
Connection for negative voltage of battery 1
5
VC
and positive voltage of battery 2
Connection for positive power supply input
6
VDD
and positive voltage of battery 1
NC*1
7
No connection
Voltage detection between VM and VSS
8
VM
(overcurrent/charger detection pin)
*1. The NC pin is electrically open.
The NC pin can be connected to VDD or VSS.
1
Figure 2
CO
Remark For the external views, refer to the package drawings.
Table 4
8-Pin TSSOP
Top view
1
2
3
4
Pin No.
8
7
6
5
Figure 3
Symbol
Description
Connection of charge control FET gate
(CMOS output)
Connection of discharge control FET gate
2
DO
(CMOS output)
NC*1
3
No connection
Connection for negative power supply input
4
VSS
and negative voltage of battery 2
Connection for negative voltage of battery 1
5
VC
and positive voltage of battery 2
Connection for positive power supply input
6
VDD
and positive voltage of battery 1
NC*1
7
No connection
Voltage detection between VM and VSS
8
VM
(overcurrent/charger detection pin)
*1. The NC pin is electrically open.
The NC pin can be connected to VDD or VSS.
1
CO
Remark For the external views, refer to the package drawings.
4
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Absolute Maximum Ratings
Table 5
(Ta=25°C unless otherwise specified)
Item
Symbol
Applied pin
Absolute Maximum Ratings
Unit
Input voltage between VDD and VSS
VDS
VDD
VSS−0.3 to VSS+12
V
VC input pin voltage
VVC
VC
VSS−0.3 to VDD+0.3
V
VM pin input voltage
VVM
VM
VDD−28 to VDD+0.3
V
DO pin output voltage
VDO
DO
VSS−0.3 to VDD+0.3
V
CO pin output voltage
VCO
CO
V
mW
mW
°C
°C
SNT-8A
Power dissipation
8-Pin TSSOP
Operating ambient temperature
PD

Topr

VVM−0.3 to VDD+0.3
450*1
700*1
−40 to +85
Storage temperature
Tstg

−55 to +125
*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
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.
800
Power Dissipation (PD) [mW]
Caution
600
8-Pin TSSOP
400
200
0
SNT-8A
0
100
150
50
Ambient Temperature (Ta) [°C]
Figure 4 Power Dissipation of Package (When mounted on board)
Seiko Instruments Inc.
5
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Electrical Characteristics
Table 6
(Ta=25°C unless otherwise specified)
Item
Symbol
Condition
Min.
Typ.
Max.
Unit
Test
condition
Test
circuit
V
1
1
V
1
1
V
2
2
V
2
2
[DETECTION VOLTAGE]
Overcharge detection voltage n
VCUn
3.90 to 4.50 V, Adjustable
Overcharge release voltage n
VCLn
3.80 to 4.50 V, Adjustable
Overdischarge detection voltage n
VDLn
2.0 to 3.0 V, Adjustable
Overdischarge release voltage n
VDUn
2.0 to 3.40 V, Adjustable
Overcurrent detection voltage 1
VIOV1
0.05 to 0.30 V, Adjustable
Overcurrent detection voltage 2
VIOV2

Charger detection voltage
VCHA

*1
Temperature coefficient 1
TCOE1
Ta=0 to 50°C
*2
Temperature coefficient 2
TCOE2
Ta=0 to 50°C
[DELAY TIME]
Overcharge detection delay time
tCU

Overdischarge detection delay time
tDL

Overcurrent detection delay time 1
tIOV1

Overcurrent detection delay time 2
tIOV2
FET gate capacitance =2000 pF
[0 V BATTERY CHARGE FUNCTION]
0 V charge starting charger voltage
V0CHA
0 V charge available
0 V battery charge inhibition battery voltage
V0INH
0 V charge unavailable
[INTERNAL RESISTANCE]
Resistance between VM and VDD
RVMD
V1=V2=1.5 V, VVM=0 V
Resistance between VM and VSS
RVMS
V1=V2=3.5 V, VVM=1.0 V
[INPUT VOLTAGE]
Operating voltage between VDD and VSS
VDSOP1 Internal circuit operating voltage
Operating voltage between VDD and VM
VDSOP2 Internal circuit operating voltage
[INPUT CURRENT]
Current consumption during operation
IOPE
V1=V2=3.5 V, VVM=0 V
Current consumption at power down
IPDN
V1=V2=1.5 V, VVM=3.0 V
VC pin current
IVC
V1=V2=3.5 V, VVM=0 V
[OUTPUT RESISTANCE]
CO pin H resistance
RCOH
VCO=VDD–0.5 V
CO pin L resistance
RCOL
VCO=VVM+0.5 V
DO pin H resistance
RDOH
VDO=VDD–0.5 V
DO pin L resistance
RDOL
VDO=VSS +0.5 V
*1. Voltage temperature coefficient 1: Overcharge detection voltage
*2. Voltage temperature coefficient 2: Overcurrent detection voltage 1
6
V
3
2
1.2
–0.7
0
0
VCUn
+0.025
VCLn
+0.05
VDLn
+0.05
VDUn
+0.10
VIOV1
+0.015
1.5
–0.4
1.0
0.5
V
V
mV/°C
mV/°C
3
4


2
2


0.92
115
7.2
220
1.15
144
9
300
1.38
173
11
380
s
ms
ms
µs
9
9
10
10
2
2
2
2
1.2




0.5
V
V
11
12
2
2
100
5
300
10
900
20
kΩ
kΩ
6
6
3
3
1.5
1.5


10
28
V
V






–0.3
5

0
10
0.1
0.3
µA
µA
µA
5
5
5
3
3
3
2
2
2
2
4
4
4
4
8
8
8
8
kΩ
kΩ
kΩ
kΩ
7
7
8
8
4
4
4
4
VCUn
–0.025
VCLn
–0.05
VDLn
–0.05
VDUn
–0.10
VIOV1
–0.015
0.9
–1.0
–1.0
–0.5
Seiko Instruments Inc.
VCUn
VCLn
VDLn
VDUn
VIOV1
Rev.1.4_00
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
„ Test Circuits
Caution 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. Overcharge Detection Voltage, Overcharge Release Voltage
(Test Condition 1, Test Circuit 1)
Overcharge detection voltage 1 (VCU1) is defined as the voltage between the VDD pin and VC pin at which VCO goes
from “H” to “L” when the voltage V1 is gradually increased from the starting condition of V1 = V2 = VCU–0.05 V, V3 = 0
V. Overcharge release voltage 1 (VCL1) is defined as the voltage between the VDD and VC pins at which VCO goes
from “L” to “H” when setting V2 = 3.5 V and the voltage V1 is then gradually decreased. Overcharge hysteresis
voltage 1 (VHC1) is defined as the difference between overcharge detection voltage 1 (VCU1) and overcharge release
voltage 1 (VCL1).
Overcharge detection voltage 2 (VCU2) is defined as the voltage between the VC pin and VSS pin at which VCO goes
from “H” to “L” when the voltage V2 is gradually increased from the starting condition of V1 = V2 = VCU–0.05 V, V3 = 0
V. Overcharge release voltage 2 (VCL2) is defined as the voltage between the VC and VSS pins at which VCO goes
from “L” to “H” when setting V1 = 3.5 V and the voltage V2 is then gradually decreased. Overcharge hysteresis
voltage 2 (VHC2) is defined as the difference between overcharge detection voltage 2 (VCU2) and overcharge release
voltage 2 (VCL2).
2. Overdischarge Detection Voltage, Overdischarge Release Voltage
(Test Condition 2, Test Circuit 2)
Overdischarge detection voltage 1 (VDL1) is defined as the voltage between the VDD pin and VC pin at which VDO
goes from “H” to “L” when the voltage V1 is gradually decreased from the starting condition of V1 = V2 = 3.5 V, V3 = 0
V. Overdischarge release voltage 1 (VDU1) is defined as the voltage between the VDD pin and VC pin at which VDO
goes from “L” to “H” when setting V2 = 3.5 V and the voltage V1 is then gradually increased. Overdischarge
hysteresis voltage 1 (VHD1) is defined as the difference between overdischarge release voltage 1 (VDU1) and
overdischarge detection voltage 1 (VDL1).
Overdischarge detection voltage 2 (VDL2) is defined as the voltage between the VC pin and VSS pin at which VDO
goes from “H” to “L” when the voltage V2 is gradually decreased from the starting condition of V1 = V2 = 3.5 V, V3 = 0
V. Overdischarge release voltage 2 (VDU2) is defined as the voltage between the VC pin and VSS pin at which VDO
goes from “L” to “H” when setting V1 = 3.5 V and the voltage V2 is then gradually increased. Overdischarge
hysteresis voltage 2 (VHD2) is defined as the difference between overdischarge release voltage 2 (VDU2) and
overdischarge detection voltage 2 (VDL2).
3. Overcurrent Detection Voltage 1, Overcurrent Detection Voltage 2
(Test Condition 3, Test Circuit 2)
Overcurrent detection voltage 1 (VIOV1) is defined as the voltage between the VM pin and VSS pin whose delay time
for changing VDO from “H” to “L” lies between the minimum and the maximum value of overcurrent delay time 1 when
the voltage V3 is increased rapidly within 10 µs from the starting condition of V1 = V2 = 3.5 V, V3 = 0 V.
Overcurrent detection voltage 2 (VIOV2) is defined as the voltage between the VM pin and VSS pin whose delay time
for changing VDO from “H” to “L” lies between the minimum and the maximum value of overcurrent delay time 2 when
the voltage V3 is increased rapidly within 10 µs from the starting condition of V1 = V2 = 3.5 V, V3 = 0 V.
4. Charger Detection Voltage
(Test Condition 4, Test Circuit 2)
The charger detection voltage (VCHA) is defined as the voltage between the VM pin and VSS pin 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, V2 = 3.5 V, V3 = 0 V until the voltage V1 becomes VDL1 + (VHD1/2).
The charger detection voltage can be measured only in a product whose overdischarge hysteresis VHD ≠ 0 V.
Seiko Instruments Inc.
7
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
5. Operating Current Consumption, VC Pin Current, Power-down Current Consumption
(Test Condition 5, Test Circuit 3)
The operating current consumption (IOPE) is the current ISS that flows through the VSS pin and the VC pin current (IVC)
is the current IC that flows through the VC pin under the set conditions of V1 = V2 = 3.5 V and S1:OFF, S2:ON
(normal status).
The power-down current consumption (IPDN) is the current ISS that flows through the VSS pin under the set conditions
of V1 = V2 = 1.5 V and S1:ON, S2:OFF (overdischarge status).
6. Resistance between VM and VDD, Resistance between VM and VSS
(Test Condition 6, Test Circuit 3)
The resistance between VM and VDD (RVMD) is the resistance between VM and VDD pins under the set conditions of
V1 = V2 = 1.5 V and S1:OFF, S2:ON.
The resistance between VM and VSS (RVMS) is the resistance between VM and VSS pins under the set conditions of
V1 = V2 = 3.5 V and S1:ON, S2:OFF.
7. CO Pin H Resistance, CO Pin L Resistance
(Test Condition 7, Test Circuit 4)
The CO pin H resistance (RCOH) is the resistance at the CO pin under the set conditions of V1 = V2 = 3.5 V, V4 = 6.5 V.
The CO pin L resistance (RCOL) is the resistance at the CO pin under the set conditions of V1 = V2 = 4.5 V, V4 = 0.5 V.
8. DO Pin H Resistance, DO Pin L Resistance
(Test Condition 8, Test Circuit 4)
The DO pin H resistance (RDOH) is the resistance at the DO pin under the set conditions of V1 = V2 = 3.5 V, V5 = 6.5 V.
The DO pin L resistance (RDOL) is the resistance at the DO pin under the set conditions of V1 = V2 = 1.8 V, V5 = 0.5 V.
9. Overcharge Detection Delay Time, Overdischarge Detection Delay Time
(Test Condition 9, Test Circuit 2)
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 overcharge detection voltage 1 (VCU1) − 0.2 V to overcharge detection
voltage 1 (VCU1) + 0.2 V under the set conditions of V1 = V2 = 3.5 V, V3 = 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 overdischarge detection voltage 1 (VDL1) + 0.2 V to overdischarge
detection voltage 1 (VDL1) − 0.2 V under the set condition of V1 = V2 = 3.5 V, V3 = 0 V.
10. Overcurrent Detection Delay Time 1, Overcurrent Detection Delay Time 2
(Test Condition 10, Test Circuit 2)
Overcurrent detection delay time 1 (tIOV1) is the time needed for VDO to go to “L” after the voltage V3 momentarily
increases within 10 µs from 0 V to VIOV1 + 0.1 V under the set conditions of V1 = V2 = 3.5 V, V3 = 0 V.
Overcurrent detection delay time 2 (tIOV2) is the time needed for VDO to go to “L” after the voltage V3 momentarily
increases within 10 µs from 0 V to 2.0 V under the set conditions of V1 = V2 = 3.5 V, V3 = 0 V.
11. 0 V Charge Starting Charger Voltage (Products in Which 0 V Charge Is Available)
(Test Condition 11, Test Circuit 2)
The 0 V charge starting charger voltage (V0CHA) is defined as the voltage between the VDD pin and VM pin at which
VCO goes to “H” (VVM + 0.1 V or higher) when the voltage V3 is gradually decreased from the starting condition of V1
= V2 = V3 = 0 V.
8
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
12. 0 V Charge Inhibition Battery Voltage (Products in Which 0 V Charge Is Unavailable)
(Test Condition 12, Test Circuit 2)
The 0 V charge inhibition charger voltage (V0INH) is defined as the voltage between the VDD pin and VSS pin at which
VCO goes to “H” (VVM + 0.1 V or higher) when the voltages V1 and V2 are gradually increased from the starting
condition of V1 = V2 = 0 V, V3 = −4 V.
R1=100 Ω
VDD
S-8242B Series
CO
VC
VM
V
V3
DO
C1=1 µF
V1
V2
VSS
V
Figure 5 Test circuit 1
VDD
S-8242B Series
VC
CO
A
DO
A
VM
V
VSS
V1
V2
V
V3
Figure 6 Test circuit 2
S1
A
VDD
VM
S-8242B Series
CO
VC
A
DO
VSS
A
A
VM
VDD
S-8242B Series
CO
VC
A
A
DO
A
S2
V1
V2
Figure 7 Test circuit 3
V4
VSS
V1
V2
V5
Figure 8 Test circuit 4
Seiko Instruments Inc.
9
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Operation
Remark Refer to “„ Battery Protection IC Connection Example”.
1. Normal Status
This IC monitors the voltage of the battery connected between the VDD and VSS pins and the voltage difference
between the VM and VSS pins to control charging and discharging. When the battery voltage is in the range from
overdischarge detection voltage n (VDLn) to overcharge detection voltage n (VCUn), and the VM pin voltage is in the
range from the charger detection voltage (VCHA) to overcurrent detection voltage 1 (VIOV1), the IC turns both the
charging and discharging control FETs on. This condition is called the normal status, and in this condition charging
and discharging can be carried out freely.
Caution
When the battery is connected 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 status.
2. Overcharge Status
When the battery voltage becomes higher than overcharge detection voltage n (VCUn) during charging in the normal
status and detection continues for the overcharge detection delay time (tCU) or longer, the S-8242B Series turns the
charging control FET off to stop charging. This condition is called the overcharge status.
The overcharge status is released in the following two cases ((1) and (2)).
(1)
(2)
When the battery voltage falls below overcharge release voltage n (VCLn), the S-8242B Series turns the charging
control FET on and returns to the normal status.
When a load is connected and discharging starts, the S-8242B Series turns the charging control FET on and
returns to the normal status. 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 the VSS level. When the battery voltage goes under overcharge
detection voltage n (VCUn) and provided that the VM pin voltage is higher than overcurrent detection voltage 1,
the S-8242B Series releases the overcharge condition.
Caution 1. If the battery is charged to a voltage higher than overcharge detection voltage n (VCUn) and the
battery voltage does not fall below overcharge detection voltage n (VCUn) even when a heavy
load is connected, overcurrent 1 and overcurrent 2 do not function until the battery voltage falls
below overcharge detection voltage n (VCUn). Since an actual battery has an internal impedance
of tens of mΩ, the battery voltage drops immediately after a heavy load that causes overcurrent
is connected, and overcurrent 1 and overcurrent 2 function.
2. When a charger is connected after overcharge detection, the overcharge status is not released
even if the battery voltage is below overcharge release voltage n (VCLn). The overcharge status
is released when the VM pin voltage goes over the charger detection voltage (VCHA) by removing
the charger.
10
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
3. Overdischarge Status
When the battery voltage falls below overdischarge detection voltage n (VDLn) during discharging in the normal status
and detection continues for the overdischarge detection delay time (tDL) or longer, the S-8242B Series turns the
discharging control FET off to stop discharging. This condition is called the overdischarge status. When the
discharging control FET is turned off, the VM pin voltage is pulled up by the resistor between the VM and VDD pins in
the IC (RVMD). When the voltage difference between the VM and VDD pins 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
status.
The power-down status is released when a charger is connected and the voltage difference between the VM and
VDD pins becomes 1.3 V (typ.) or higher. Moreover, when the battery voltage becomes overdischarge detection
voltage n (VDLn) or higher, the S-8242B Series turns the discharging FET on and returns to the normal status.
4. Charger Detection
When a battery in the overdischarge status is connected to a charger and provided that the VM pin voltage is lower
than the charger detection voltage (VCHA), the overdischarge hysteresis is released via the charge detection function;
therefore, the S-8242B Series releases the overdischarge status and turns the discharging control FET on when the
battery voltage becomes equal to or higher than overdischarge detection voltage n (VDLn) since the charger detection
function works. This action is called charger detection.
When a battery in the overdischarge status is connected to a charger and provided that the VM pin voltage is not
lower than the charger detection voltage (VCHA), the S-8242B Series releases the overdischarge status when the
battery voltage reaches overdischarge release voltage n (VDUn) or higher.
5. Overcurrent Status
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 13) 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.
Caution
The impedance that enables automatic restoration varies depending on the battery voltage and the
set value of overcurrent detection voltage 1.
Seiko Instruments Inc.
11
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
6. 0 V Battery Charge Function
This function is used to recharge a connected battery whose voltage is 0 V due to self-discharge. When the 0 V
battery charge starting charger voltage (V0CHA) or a higher voltage is applied between the EB+ and EB− pins by
connecting a charger, the charging control FET gate is fixed to the VDD pin voltage.
When the voltage between the gate and source of the charging control FET becomes equal to or higher than the turnon 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 overdischarge release voltage n (VDUn), the
S-8242B Series enters the normal status.
Caution
Some battery providers do not recommend charging for a completely self-discharged battery.
Please ask the battery provider to determine whether to enable or inhibit the 0 V battery charge
function.
7. 0 V Battery Charge Inhibition Function
This function inhibits recharging when a battery that is internally short-circuited (0 V) is connected. When the battery
voltage (The voltage between VDD and VSS pins) is the 0 V battery charge inhibition battery voltage (V0INH) or lower,
the charging control FET gate is fixed to the 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
12
Some battery providers do not recommend charging for a completely self-discharged battery.
Please ask the battery provider to determine whether to enable or inhibit the 0 V battery charge
function.
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
8. Delay Circuit
The detection delay times are determined by dividing a clock of approximately 3.5 kHz by the counter.
Remark1.
The overcurrent detection delay time 2 (tIOV2) starts when the overcurrent detection voltage 1 (VIOV1) is
detected. When the overcurrent detection voltage 2 (VIOV2) is detected over the overcurrent detection
delay time 2 (tIOV2) after the detection of overcurrent detection voltage 1 (VIOV1), the S-8242B turns the
discharging control FET off within tIOV2 from the time of detecting VIOV2.
VDD
DO pin
tD
VSS
Overcurrent detection delay time 2 (tIOV2)
0≦tD≦tIOV2
Time
VDD
VIOV2
VM pin
VIOV1
VSS
Time
Figure 9
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 n (VDLn). When the battery voltage falls below the
overdischarge detection voltage n (VDLn) due to the overcurrent, the S-8242B 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 overdischarge
detection voltage n (VDLn), the S-8242B Series shifts to the power-down condition.
Seiko Instruments Inc.
13
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Timing Chart
1. Overcharge Detection, Overdischarge Detection
Battery
voltage
VCUn
VCLn
VDUn
VDLn
(n= 1, 2)
VDD
DO pin
voltage
VSS
VDD
CO pin
voltage
VSS
VEB−
VDD
VM pin
voltage
VIOV1
VSS
VCHA
VEB−
Charger connection
Load connection
Mode
*1
Overcharge detection
delay time(tCU)
(1)
Overdischarge detection
delay time (tDL)
(2)
(1)
*1. (1) : Normal mode
(2) : Overcharge mode
(3) : Overdischarge mode
Remark The charger is assumed to charge with a constant current.
Figure 10
14
Seiko Instruments Inc.
(3)
(1)
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
2. Overcurrent Detection
VCUn
VCLn
Battery
voltage
VDUn
VDLn
(n= 1, 2)
VDD
DO pin
voltage
VSS
VDD
CO pin
voltage
VSS
VDD
VM pin
voltage
Charger
connection
Mode
VIOV2
VIOV1
VSS
Overcurrent detection
delay time 2 (tIOV2)
Overcurrent detection
delay time 1 (tIOV1)
*1
(1)
(2)
(1)
(2)
(1)
*1. (1) : Normal mode
(2) : Overcurrent mode
Remark The charger is assumed to charge with a constant current.
Figure 11
Seiko Instruments Inc.
15
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
3. Charger Detection
Battery
voltage
VCUn
VCLn
VDUn
VDLn
(n= 1, 2)
VDD
DO pin
voltage
VSS
VDD
CO pin
voltage
VSS
VDD
VM pin
voltage
VSS
VCHA
Charger connection
Load connection
Overdischarge detection delay time (tDL)
*1
Mode
(1)
(2)
*1. (1) : Normal mode
(2) : Overdischarge mode
Remark The charger is assumed to charge with a constant current.
Figure 12
16
Seiko Instruments Inc.
VM pin vodltage < VCHA
Overdischarge detection (VDL)
(1)
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Battery Protection IC Connection Example
EB+
R1
VDD
C1
Battery 1
R2
S-8242B Series
VC
Battery 2
C2
VSS
DO
CO
VM
FET1
FET2
R3
EB−
Figure 13
Table 7 Constants for External Components
Symbol
FET1
FET2
Parts
Purpose
N-channel
Discharge control
MOS FET
N-channel
Charge control
MOS FET
Typ.
Min.
Max.






R1
Resistor
ESD protection,
For power fluctuation
100 Ω
10 Ω
C1
Capacitor For power fluctuation
1 µF
0.47 µF
*1
*1
*1
220 Ω
*1
10 µF
Remark
*2
Threshold voltage≤Overdischarge detection voltage
*3
Gate to source withstanding voltage≥Charger voltage
*2
Threshold voltage≤Overdischarge detection voltage
*3
Gate to source withstanding voltage≥Charger voltage
Resistance should be as small as possible to avoid lowering
the overcharge detection accuracy due to current
*4
consumption.
Connect a capacitor of 0.47 µF or higher between VDD and
*5
VSS.
ESD protection,
*1
*1
300 Ω
1 kΩ

1 kΩ
For power fluctuation
*1
*1
0.022 µF
1.0 µF
C2
Capacitor For power fluctuation
0.1 µF

Protection for reverse
Select as large a resistance as possible to prevent current
R3
Resistor
300 Ω
4 kΩ
2 kΩ
*6
when a charger is connected in reverse.
connection of a charger
*1. Please set up a filter constant to be R2 × C2 ≥ 20 µF • Ω, and to be R1 × C1 = R2 × C2.
*2. If the threshold voltage of a FET is low, the FET may not cut the charging current.
If a FET with a threshold voltage equal to or higher than the overdischarge detection voltage is used, discharging may be
stopped before overdischarge is detected.
*3. If the withstanding voltage between the gate and source is lower than the charger voltage, the FET may be destroyed.
*4. 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 10 Ω or higher to R1 for ESD protection.
*5. If a capacitor of less than 0.47 µF is connected to C1, DO pin may oscillate when load short-circuiting is detected. Be
sure to connect a capacitor of 0.47 µF or higher to C1.
*6. If R3 has a resistance higher than 4 kΩ, the charging current may not be cut when a high-voltage charger is connected.
R2
Resistor
Caution 1. The above constants may be changed without notice.
2. It has not been confirmed whether the operation is normal or not in circuits other than the above
example of connection. In addition, the example of connection shown above and the constant do not
guarantee proper operation. Perform through evaluation using the actual application to set the constant.
Seiko Instruments Inc.
17
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Precautions
• The application conditions for the input voltage, output voltage, and load current should not exceed the package power
dissipation.
• When connecting a battery and the protection circuit, the output voltage of the DO pin (VDO) may become “L” (initial
state). In this case, short the VM and VSS pins or connect the battery charger to make the output voltage of the DO pin
(VDO) “H” (normal state).
• 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.
18
Seiko Instruments Inc.
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Characteristics (Typical Data)
(1) Current consumption
1. IOPE − VDD
2. IOPE − Ta
12
10
10
8
8
IOPE [µA]
IOPE [µA]
12
6
4
6
4
2
2
0
2
3
4
5
7
6
8
9
0
−40 −25
10
0
25
IPDN [µA]
50
75 85
4. IPDN − Ta
IPDN [µA]
2
75 85
Ta [°C]
VDD [V]
3. IPDN − VDD
0.10
0.09
0.08
0.07
0.06
0.05
0.04
0.03
0.02
0.01
0
50
3
4
5
6
7
8
9
10
0.10
0.09
0.08
0.07
0.06
0.05
0.04
0.03
0.02
0.01
0
−40 −25
0
25
Ta [°C]
VDD [V]
4.350
4.345
4.340
4.335
4.330
4.325
4.320
4.315
4.310
4.305
4.300
−40 −25
VCL [V]
VCU [V]
(2) Overcharge detection/release voltage, overdischarge detection/release voltage, overcurrent detection voltage, and
delay time
1. VCU − Ta
2. VCL − Ta
0
25
50
75 85
4.125
4.115
4.105
4.095
4.085
4.075
4.065
4.055
4.045
4.035
4.025
−40 −25
0
Ta [°C]
75 85
50
75 85
4. VDL − Ta
3.00
2.95
2.90
VDL [V]
VDU [V]
50
Ta [°C]
3. VDU − Ta
2.85
2.80
−40 −25
25
0
25
50
75 85
2.25
2.24
2.23
2.22
2.21
2.20
2.19
2.18
2.17
2.16
2.15
−40 −25
Ta [°C]
0
25
Ta [°C]
Seiko Instruments Inc.
19
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
6. tDL − Ta
1.42
1.37
1.32
1.27
1.22
1.17
1.12
1.07
1.02
0.97
0.92
−40 −25
185
175
165
155
tDL [ms]
tCU [s]
5. tCU − Ta
Rev.1.4_00
145
135
125
0
25
50
115
−40 −25
75 85
0
25
Ta [°C]
0.225
0.220
0.220
0.215
0.215
VIOV1 [V]
VIOV1 [V]
8. VIOV1 − Ta
0.225
0.210
0.205
0.210
0.205
0.200
0.200
4
5
6
7
8
0.195
−40 −25
9
0
1.5
1.4
1.4
1.3
1.3
VIOV2 [V]
1.5
VIOV2 [V]
10. VIOV2 − Ta
1.2
1.1
4
7
6
5
8
0.9
−40 −25
9
0
25
75 85
Ta [°C]
12. tIOV1 − Ta
tIOV1 [ms]
tIOV1 [ms]
50
1.1
VDD [V]
5
6
7
8
9
10.8
10.4
10.0
9.6
9.2
8.8
8.4
8.0
7.6
7.2
−40 −25
0
25
Ta [°C]
VDD [V]
20
75 85
1.0
11. tIOV1 − VDD
4
50
1.2
1.0
10.8
10.4
10.0
9.6
9.2
8.8
8.4
8.0
7.6
7.2
25
Ta [°C]
VDD [V]
9. VIOV2 − VDD
0.9
75 85
Ta [°C]
7. VIOV1 − VDD
0.195
50
Seiko Instruments Inc.
50
75 85
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
14. tIOV2 − Ta
0.38
0.38
0.36
0.36
0.34
0.34
0.32
0.32
tIOV2 [ms]
tIOV2 [ms]
13. tIOV2 − VDD
0.30
0.28
0.26
0.24
0.22
0.30
0.28
0.26
0.24
5
4
6
7
8
0.22
−40 −25
9
0
1.6
−0.2
1.4
−0.4
1.2
−0.6
1.0
−0.8
−1.0
−1.2
−1.4
0.8
0.6
0.4
0.2
0
1
2
3
4
5
6
0
7
0
1
3
2
VCO [V]
4
5
6
7
8
9
VCO [V]
3. IDOH − VDO
4. IDOL − VDO
0
0.30
−0.2
0.25
−0.4
−0.6
IDOL [mA]
IDOH [mA]
75 85
2. ICOL − VCO
0
ICOL [mA]
ICOH [mA]
(3) CO/DO pin
1. ICOH − VCO
−0.8
−1.0
0.20
0.15
0.10
0.05
−1.2
−1.4
50
Ta [°C]
VDD [V]
−1.6
25
0
1
2
3
4
5
6
7
VDO [V]
0
0
1
2
3
VDO [V]
Seiko Instruments Inc.
21
BATTERY PROTECTION IC FOR 2-SERIAL-CELL PACK
S-8242B Series
Rev.1.4_00
„ Marking Specifications
(1) SNT-8A
SNT-8A
Top view
(1) (2) (3) (4)
(9) (10) (11)
4
(5) (6) (7) (8)
1
8
(1)
(2) to (4)
(5), (6)
(7) to (11)
Blank
Product code (Refer to Product name vs. Product code)
Blank
Lot number
5
Product Name vs. Product Code
Product Code
(2)
(3)
(4)
S-8242BAB-I8T1G
Q
N
B
S-8242BAD-I8T1G
Q
N
D
S-8242BAE-I8T1G
Q
N
E
S-8242BAH-I8T1G
Q
N
H
S-8242BAM-I8T1G
Q
N
M
S-8242BAN-I8T1G
Q
N
N
S-8242BAO-I8T1G
Q
N
O
S-8242BAQ-I8T1G
Q
N
Q
S-8242BAR-I8T1G
Q
N
R
S-8242BAU-I8T1G
Q
N
U
S-8242BAV-I8T1G
Q
N
V
S-8242BAW-I8T1G
Q
N
W
S-8242BAX-I8T1G
Q
N
X
S-8242BAY-I8T1G
Q
N
Y
S-8242BAZ-I8T1G
Q
N
Z
S-8242BBA-I8T1G
Q
O
A
S-8242BBB-I8T1G
Q
O
B
Remark Please contact our sales office for the products with detection voltage value other than those specified above.
Product Name
(2) 8-Pin TSSOP
8-Pin TSSOP
Top view
1
(1) (2) (3) (4)
(1) to (5):
(6) to (8):
8
(9) to (14):
Product Name : S8242 (Fixed)
Function Code
(refer to Product Name vs. Function Code)
Lot number
(5) (6) (7) (8)
4
(9) (10) (11) (12) (13) (14)
5
Product Name vs. Function Code
Function Code
(6)
(7)
(8)
S-8242BAC-T8T1G
B
A
C
S-8242BAH-T8T1G
B
A
H
S-8242BAI-T8T1G
B
A
I
S-8242BAP-T8T1G
B
A
P
S-8242BAR-T8T1G
B
A
R
Remark Please contact our sales office for the products with detection voltage value other than those specified above.
Product Name
22
Seiko Instruments Inc.
1.97±0.03
8
7
6
5
3
4
+0.05
1
0.5
2
0.08 -0.02
0.48±0.02
0.2±0.05
No. PH008-A-P-SD-2.0
TITLE
SNT-8A-A-PKG Dimensions
PH008-A-P-SD-2.0
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
+0.1
ø1.5 -0
5°
2.25±0.05
4.0±0.1
2.0±0.05
ø0.5±0.1
0.25±0.05
0.65±0.05
4.0±0.1
4 321
5 6 78
Feed direction
No. PH008-A-C-SD-1.0
TITLE
SNT-8A-A-Carrier Tape
PH008-A-C-SD-1.0
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
12.5max.
9.0±0.3
Enlarged drawing in the central part
ø13±0.2
(60°)
(60°)
No. PH008-A-R-SD-1.0
TITLE
SNT-8A-A-Reel
No.
PH008-A-R-SD-1.0
SCALE
UNIT
QTY.
mm
Seiko Instruments Inc.
5,000
0.52
2.01
0.52
0.3
0.2
0.3
0.2
0.3
0.2
0.3
Caution Making the wire pattern under the package is possible. However, note that the package
may be upraised due to the thickness made by the silk screen printing and of a solder
resist on the pattern because this package does not have the standoff.
No. PH008-A-L-SD-3.0
TITLE
SNT-8A-A-Land Recommendation
PH008-A-L-SD-3.0
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
+0.3
3.00 -0.2
8
5
1
4
0.17±0.05
0.2±0.1
0.65
No. FT008-A-P-SD-1.1
TITLE
TSSOP8-E-PKG Dimensions
FT008-A-P-SD-1.1
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
4.0±0.1
2.0±0.05
ø1.55±0.05
0.3±0.05
+0.1
8.0±0.1
ø1.55 -0.05
(4.4)
+0.4
6.6 -0.2
1
8
4
5
Feed direction
No. FT008-E-C-SD-1.0
TITLE
TSSOP8-E-Carrier Tape
FT008-E-C-SD-1.0
No.
SCALE
UNIT
mm
Seiko Instruments Inc.
13.4±1.0
17.5±1.0
Enlarged drawing in the central part
ø21±0.8
2±0.5
ø13±0.5
No. FT008-E-R-SD-1.0
TSSOP8-E-Reel
TITLE
No.
FT008-E-R-SD-1.0
SCALE
QTY.
UNIT
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.