AIC AIC1803

AIC1803
Three-Cell Lithium-Ion Battery Protection IC
n FEATURES
n DESCRIPTION
l
Ultra-Low Quiescent Current at 13µA (V CELL=3.5V).
l
Ultra-Low Power-Down Current at 1.3µA (V CELL=2.3V)
l
Wide Supply Voltage Range: 2V to 18V.
Precision Overcharge Protection Voltage:
l
The AIC1803 is designed to protect the lithiumion battery from damage or degrading the lifetime
due to overcharging, overdischarging and
overcurrent for three-cell lithium-ion battery
powered systems such as notebook PCs. It can
also provide the cell-balancing “bleeding” function
to automatically discharge the overcharged cell
until the overcharge condition is released.
4.35V± 30mV for the AIC1803A
4.30V± 30mV for the AIC1803B
4.25V± 30mV for the AIC1803C
4.20V± 30mV for the AIC1803D
l
l
l
n
l
n
Externally Set Overcharge, Overdischarge and
Overcurrent Delay Time.
Built-in Cell-balancing Bleeding Network under
Overcharge Condition.
Three Detection Levels for Overcurrent Protection.
Safe and full utilization charging is ensured by
the accurate ±30mV overcharge detection. Four
different specification values for overcharge
protection voltage are provided for various
protection requirements. The very low standby
current drains little current from the cell while in
storage.
APPLICATIONS
Protection IC for Three-Cell Lithium-Ion Battery Pack.
TYPICAL APPLICATION CIRCUIT
R8
1K
1
2
OC
VCC
CS
VC1
16
R4
C4
0.1µ F
1K
M1
FUSE
M2
15
BATT+
C1 R1 2K
0.1µ F
3
4
OD
UD1
NC
VC2
R5
1M
BAT1
14
Q1
13
R2 2K
C2
0.1µ F
5
6
CTD
82nF
CTI
2.2nF
7
CTC
82nF
8
TD
TI
UD2
VC3
TC
UD3
NC
GND
BAT2
12
R6
1M
R7
1M
11
R3 33K
10
C3
0.1µF
9
BAT3
BATT-
AIC1803
Protection Circuit for Three-Cell Lithium-Ion Battery Pack
DS-1803-01 July 14, 00
www.analog.com.tw
1
AIC1803
n ORDERING INFORMATION
AIC1803 XXX
ORDER NUMBER
PIN CONFIGURATION
TOP VIEW
PACKAGE TYPE
S: SMALL OUTLINE
AIC1803ACS
AIC1803BCS
AIC1803CCS
AIC1803DCS
(PLASTIC SO)
TEMPERATURE RANGE
C=0°C~70 °C
OVERCHARGE PROTECTION
VOLTAGE
A: 4.35V
B: 4.30V
C: 4.25V
D: 4.20V
OC
1
16 VCC
CS
2
15 VC1
OD 3
14 UD1
NC
4
13 VC2
TD
5
12 UD2
TI
6
TC
7
11 VC3
10 UD3
NC
8
9 GND
n ABSOLUTE MAXIMUM RATINGS
Supply Voltage ................................................… … … … … … ....................................... 18V
DC Voltage Applied on other Pins
.........… … … … … … … ..… ....................................... 18V
Operating Temperature Range............................… … … … … … ......................... -20°C~70°C
Storage Temperature Range .............................… … ..… … … ..................... - 65°C ~125°C
n TEST CIRCUIT
ROC
1M
I OC
S1
1
V OC
R8
V CS
2
OC
VCC
CS
VC1
16
15
I CC
IC 1
1K
3
VOD
4
OD
UD1
NC
VC2
14
13
I UD1
R4 1K
C4
µ
0.1 F
C1
0.1µF
R1 2K
V C1
I C2
VC2
R2 2K
5
6
CTD
82nF
CTI
7
2.2nF
CTC
8
TD
UD2
TI
VC3
TC
UD3
GND
NC
12
11
IUD2
C2
0.1µF
IC 3
R3 33K
10
I UD3
VC3
C3
0.1µF
9
82nF
AIC1803
2
AIC1803
n ELECTRICAL CHARACTERISTICS (Ta=25°C, unless otherwise specified.)
PARAMETER
TEST CONDITIONS
SYMBOL
MIN.
TYP. MAX. UNIT
VCC Pin Input Current in Normal VCELL=3.5V
Mode
ICC
13
20
µA
VC1 Pin Input Current in Normal VCELL=3.5V
Mode
IC1
0.4
1.0
µA
VC2 Pin Input Current in Normal VCELL=3.5V
Mode
IC2
0.4
1.0
µA
VC3 Pin Input Current in Normal VCELL=3.5V
Mode
IC3
0.2
0.5
µA
Vcc Pin Input Current in PowerDown Mode
VCELL=2.3V
ICC(PD)
1.3
2
µA
VC1,VC2,VC3 Input Current in
Power-Down Mode
VCELL=2.3V
IC(PD)
0.01
0.15
µA
4.32
4.35
4.38
4.27
4.30
4.33
AIC1803C
4.22
4.25
4.28
AIC1803D
4.17
4.20
4.23
AIC1803A
AIC1803B
VOCP
V
Overcharge Protection Voltage
Overcharge Hysteresis Voltage
VHYS
150
200
250
mV
Overdischarge Protection Voltage
VODP
2.27
2.40
2.53
V
Overdischarge Release Voltage
VODR
2.85
3.00
3.15
V
VOIP
135
150
165
mV
TOC
10
21
32
mS
TOD
10
21
32
mS
TOI1
7
15
23
mS
Overcurrent Protection Voltage
VCELL=3.5V
VCELL1 = VOCP30mV→VOCP+30mV
Overcharge Delay Time
VCELL2= VCELL3=3.5 V ,
CT C=1nF
VCELL1= 2.5V→ 2.3V
Overdischarge Delay Time
Overcurrent Delay Time (1)
VCELL2= VCELL3=3.5V ,
CTD=1nF
VCELL= 3.5V,0.15V<VCC VCS <0.3V,CTI=2.2nF
3
AIC1803
n ELECTRICAL CHARACTERISTICS (Ta=25°C, unless otherwise specified.)
PARAMETER
TEST CONDITIONS
Overcurrent Delay Time (2)
Overcurrent Delay Time (3)
SYMBOL
MIN.
TOI2
2
4
6
mS
TOI3
150
300
450
µS
IOC
2.0
2.8
3.6
mA
VC C-0.03V
V
0.15
V
VCELL=3.5V,
0.3V<VCC-V CS<1.0V
VCELL=3.5V, VCC–
VCS>1.0V
TYP. MAX. UNIT
VCELL1=4.4V,
VCELL2= VCELL3=3.5V,
OC Pin Sink Current
OC Pin Short to VCC
OD Pin Output “H” Voltage
VDH
OD Pin Output “L” Voltage
VDL
Charge Detection Threshold
Voltage
VCELL=2.3V
VC C-0.15V
0.01
VCH
VC C+0.4 VCC+0.55
V
UD1 Pin Cell-Balancing Bleeding VCELL1=4.4V,
Current
VCELL2= VCELL3=3.5V
IUD1
5.9
8.4
10.9
mA
UD2 Pin Cell-Balancing Bleeding VCELL2=4.4V,
Current
VCELL1= VCELL3=3.5V
IUD2
6.1
8.7
11.3
mA
UD3 Pin Cell-Balancing Bleeding VCELL3=4.4V,
Current
VCELL1= VCELL2=3.5V
IUD3
6.4
9.2
12.0
mA
Note: VCELL means the battery cell voltage. Therefore,
VCELL1 = VC1 – V C2
VCELL2 = VC2 – V C3
VCELL3 = VC3
n TYPICAL PERFORMANCE CHARACTERISTICS
Vcc Pin Power-Down Current vs. Supply Voltage
Vcc Pin Input Current vs. Supply Voltage
Vcc Pin Power-Down Current (µA)
Vcc Pin Input Current (µA)
15
Ta=25°C
14
13
12
11
7.8
8.4
9.0
9.6
10.2
Supply Voltage (V)
10.8
11.4
12.0
1.3
Ta=25°C
1.2
1.1
1.0
0.9
0.8
4.5
4.8
5.1
5.4
5.7
6.0
6.3
6.6
6.9
Supply Voltage (V)
4
AIC1803
n TYPICAL PERFORMANCE CHARACTERISTICS (CONTIONED)
Vcc Pin Power-Down Current vs. Temperature
Vcc Pin Input Current vs. Temperature
2.0
Vcc Pin Power-Down Current (µA)
Vcc Pin Input Current (µA)
16
VCELL =3.5V
1.8
15
1.6
14
1.4
13
1.2
12
1.0
11
10
VCELL=2.3V
-20
-10
0
10
20
30
40
Temperature (°C)
50
60
0.8
70
-20
0
10
20
30
40
50
60
70
Temperature (°C)
Overdischarge Protection Voltage vs. Temperature
Overcharge Protection Voltage vs. Temperature
2.42
Overdischarge Protection Voltage (V)
4.30
Overcharge Protection Voltage (V)
-10
AIC1803C
2.41
4.28
2.40
4.26
2.39
4.24
2.38
4.22
4.20
2.37
-20
0
20
40
60
70
2.36
Overcurrent Protection Voltage vs. Temperature
Overcurrent Protection Voltage (V)
152.0
151.5
V CELL=3.5V
151.0
150.5
150.0
149.5
149.0
148.5
148.0
-20
-10
0
10
20
30
Temperature(°C)
40
50
60
70
Overcharge/Overdischarge Delay Time (mS)
Temperature (°C)
-20
-10
0
10
20
30
40
Temperature (°C)
50
60
70
Overcharge/Overdischarge Delay Time vs. Temperature
26
CTC /CTD=1nF
24
22
20
18
16
14
-20
-10
0
10
20
30
40
50
60
70
Temperature(° C)
5
AIC1803
n TYPICAL PERFORMANCE CHARACTERISTICS (CONTIONED)
Overcurrent Delay Time 1 vs. Temperature
Overcharge Release Voltage vs. Temperature
4.08
Overcharge Release Voltage (V)
Overcurrent Delay Time 1 (mS)
22
20
VCELL =3.5V
18
16
14
12
10
-20
-10
0
10
20
30
40
50
60
70
Temperature (°C)
4.07
4.06
4.05
4.04
4.03
4.02
-20
-10
0
10
20
30
40
50
60
70
Temperature (° C)
Overdischarge Release Voltage vs. Temperature
Overdischarge Release Voltage (V)
3.01
3.00
2.99
2.98
2.97
-20
-10
0
10
20
30
40
50
60
70
o
Temperature (°C)
6
AIC1803
n BLOCK DIAGRAM
CS
2
VC1
15
Battery
Voltage
Sense
Circuit
VC2 13
VC3
UD1
16
VCC
VCC-0.15V
Overcurrent
Delay Circuit
11
VCC-0.3V
14
3
350
VCC-1V
UD2 12
Overdischarge
Delay Circuit
400
UD3
Wake-up
Control
VCC+0.4V
10
Power-Down
Control
1
OD
OC
Overcharge
Delay Circuit
450
1.2V
GND
9
7
5 6
TC
TD TI
7
AIC1803
n PIN DESCRIPTIONS
PIN 1: OC-
PIN 2: CS-
NMOS open drain output for
control of the charge control
MOSFET M2. When overcharge
occurs, this pin sinks current to
switch the external PNP Q1 on,
and charging is inhibited by
turning off the charge control
MOSFET M2.
Input pin for current sensing.
Using the drain-source voltage of
the discharge
control
MOSFET M1 (voltage between
VCC and CS),
it senses
discharge
current
during
normal
mode
and
detects
whether charging
current
is
present
during power-down
mode.
connected to the
negative
terminal of the battery cell BAT3.
PIN10: UD3 -
This pin is to be connected to the
positive terminal of the battery
cell BAT3
for
cell-balancing
bleeding
function
under
overcharge condition.
PIN11: VC3-
Input pin for battery BAT3
voltage sensing. This pin is to be
connected
to
the
positive
terminal of the battery cell BAT3.
PIN12: UD2 -
This pin is to be connected to the
positive terminal of the battery
cell BAT2 for cell-balancing
bleeding
function
under
overcharge condition.
PIN13: VC2-
PIN 3: OD -
Output pin for control of discharge control MOSFET M1.
PIN 4: NC -
No connection
PIN 5: TD -
Overdischarge delay time setting
pin.
PIN 6: TI -
Overcurrent delay
pin.
PIN 7: TC -
Overcharge delay time setting
pin.
Input pin for battery BAT2
voltage sensing. This pin is to be
When overdischarge occurs, this pin goes high
connected
to
the
positive
terminal of the battery cell BAT2.
PIN14: UD1-
This pin is to be connected to the positive ter
PIN15: VC1-
Input pin for battery BAT1
voltage sensing. This pin is to be
connected
to
the
positive
terminal of the battery cell BAT1.
PIN16: VCC -
Power supply pin. This pin is to
be connected to the positive
terminal of the battery cell BAT1.
time setting
PIN 8: NC -
No connection.
PIN 9: GND -
Ground pin. This pin is to be
n APPLICATION INFORMATIONS
l
THE OPERATION
Initialization
beyond the overcharge delay time (TOC ) period,
charging is inhibited by the turning-off of the
charge control MOSFET M2. The overcharge
On initial power-up , such as connecting the
delay time is set by the external capacitor CTC.
battery pack for the first time to the AIC1803 , the
Inhibition of charging is immediately released
AIC1803 enters the power-down mode . A charger
when the voltage of the overcharged cell becomes
must be applied to the AIC1803 circuit to enable
lower than
the pack.
VOCP-V HYS) through discharging.
Overcharge Protection
Overdischarge Protection
When the voltage of either of the battery cells
When the voltage of either of the battery cells falls
exceeds the overcharge protection voltage (V OCP)
below the overdischarge protection voltage (V ODP)
overcharge release voltage (V OCR or
8
AIC1803
beyond the overdischarge delay time (TOD) period,
(V OCR or VOCP-vHYS ). This function is accomplished
discharging is inhibited by the turning-off of the
by connecting UD1, UD2, UD3 pins to the positive
discharge
terminals of battery cells BAT1, BAT2, BAT3
control
MOSFET
M1.
The
overdischarge delay time is set by the external
respectively. The bleeding
capacitor
CTD.
Inhibition
of
discharging
current can be
is
decreased by inserting resistors along UD1 pin to
immediately released when the voltage of the
BAT1 positive terminal path and UD3 pin to BAT3
overdischarge cell becomes higher than the
positive terminal path.
overdischarge release voltage (V ODR)
through
charging.
Power-Down after Overdischarge
When overdischarge occurs, the AIC1803 will go
Overcurrent Protection
continuously
into power-down mode, turning off all the timing
monitors the discharge current by sensing the
generation and detection circuitry to reduce the
voltage of CS pin. If the voltage VCC-V CS exceeds
quiescent current to about 1.3µA (V CC =6.9V). In
the overcurrent protection voltage (V OIP) beyond
the unusual case where one battery cell is
the overcurrent delay time (TOI) period,
the
overdischarged
overcurrent
and
overcharge condition, the AIC1803 will turn off all
discharging is inhibited by the turning-off of the
the detection circuitry except the overcharge
discharge control MOSFET M1. Discharging must
detection circuit for the cell under overcharge
be inhibited for at least 256mS after overcurrent
condition.
In normal
mode,
the
protection
AIC1803
circuit
operates
while
another
one
under
takes place to avoid damage to external control
MOSFETs due to rapidly switching transient
Charge Detection after Overdischarge
between
The
When overdischarge occurs, the discharge control
overcurrent condition returns to normal mode
MOSFET M1 turns off and discharging is inhibited.
when the load is released and the impedance
However, charging is still permitted through the
between the BATT+ and BATT- terminals is
parasitic diode of M1. Once the charger is
20MΩ or higher.
connected to the battery pack, the AIC1803
The
BATT+
AIC1803
and
is
BATT-
provided
terminals.
with
the
three
overcurrent detection levels (0.15V, 0.3V and
1.0V) and the three overcurrent delay time (TOI1,
TOI2 and TOI3) corresponding to each overcurrent
detection level. TOI1 is set by the external capacitor
immediately turns on all the timing generation and
detection circuitry and goes into normal mode.
Charging is determined to be in progress if the CS
pin voltage is higher than VCC + 0.4V (charge
detection threshold voltage VCH).
CTI. TOI2 and TOI3 default to 4mS and 300µs
respectively, and can not be adjusted due to
protection of external MOSFETs
Cell-Balancing
Overcharge
Bleeding
after
•
DESIGN GUIDE
Setting
the
Overcharge
Overdischarge Delay Time
and
When either of the battery cells is overcharged,
The overcharge delay time is set by the external
the AIC1803 provides the cell-balancing bleeding
capacitor CTC and the overdischarge delay time is
function to discharge the overcharged cell at
set by the external capacitor CTD. The relationship
about 9mA until the voltage of the overcharged
between capacitance of the external capacitors
cell decreases to overcharge release voltage
and delay time is tabulated as below.
9
AIC1803
CTC ‚CT D(F)
TOC ‚T OD(S)
CTC ‚CT D(F)
TOC ‚T OD(S)
1n
21m
47n
617m
5n
52m
10n
132m
68n
748m
22n
253m
33n
347m
be aware that turn-on resistance of the MOSFET
changes with temperature variation due to heat
dissipation. It changes with the voltage between
82n
100n
1004m 1630m
gate and source as well. (Turn-on resistance of a
MOSFET increases as the voltage between gate
The delay time can also be approximately
and
calculated by the following equations (if CTC , CTD
resistance of the external MOSFET changes, the
≤ 82nF) :
source
overcurrent
decreases).
current
the
turn-on
will
change
Suppressing
the
Ripple
Disturbance from Charger
and
Setting the Overcurrent Delay Time 1
The overcurrent delay time 1 (TOI1) at 0.15V <
To suppress the ripple and disturbance from
VCC-VCS < 0.3V is set by the external capacitor CTI,
charger, connecting R1 to R4 and C1 to C4 is
while the overcurrent delay time 2 and 3 (TOI2 and
recommended.
TOC (mS) = 11.8 x CTC(nF)
threshold
Once
accordingly.
TOD (mS) = 11.8 x CTD(nF)
TOI3) is fixed by IC internal circuit.The relationship
between capacitance of the external capacitor and
delay time is tabulated as below.
CTI(F)
1n
2.2n 3.3n
5n
TOI(mS) 4.8
15.0 18.8 23.6
6.8n
31.0
10n
61.8
Controlling
MOSFET
the
Charge
Control
R5, R6, R7 and NPN transistor Q1 are used to
switch
the
charge
control
MOSFET
M2.
If
overcharge does not occur, no current flows into
Selection
MOSFETs
of
External
Control
Because the overcurrent protection voltage is
OC pin and Q1 is turned off, then M2 is turned on.
When overcharge occurs, current flows into OC
pin and Q1 is turned on, which turns off M2 in turn.
preset, the threshold current for overcurrent
detection is determined by the turn-on resistance
of the discharge control MOSFET M1. The turn-on
Protection at CS Pin
resistance of the external control MOSFETs can
R8 is used for protection of IC when charger is
be determined by the equation: RON=VOIP/IT (IT is
connected in reverse. The charge detection
the overcurrent threshold current). For example, if
function after overdischarge is possibly disabled
the overcurrent threshold current IT is designed to
by larger value of R8. Resistance of 1KΩ is
be 5A, the turn-on resistance of the external
recommended.
control MOSFETs must be 30mΩ. Users should
10
AIC1803
n TIMING DIAGRAM
l Overcharge and Overdischarge Protection (VCS=VCC )
<TOC
TOC
V BAT1
V OCP
V OCP - VHYS
VCELL
V BAT2
V BAT3
V ODR
V ODP
TOD
<T OD
VOC
VOD
Hi-Z
Hi-Z
0V
V CC
0V
l Overcurrent Protection (VCELL=3.5V)
<256ms
>256ms
VCC
VCC- 0.15V
VCC - 0.3V
VCS
VCC - 1V
0V
TOI1
<TOI2
VOD
<T
TOI3
OI1
VCC
0V
256ms
<256ms
VOC
Hi-Z
11
AIC1803
n PHYSICAL DIMENSIONS
l 16 LEAD PLASTIC SO (150 mil) (unit: mm)
D
H
E
SYMBOL
MIN
MAX
A
1.35
1.75
A1
0.10
0.25
B
0.33
0.51
C
0.19
0.25
D
9.80
10.00
E
3.80
4.00
e
e
H
5.80
6.20
L
0.40
1.27
A1
A
1.27 (TYP)
B
C
L
12