End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
Dual-Cell Lithium Ion Battery Control IC
DESCRIPTION
FEATURES
The Si9730 monitors the charging and discharging of dualcell lithium-ion battery packs (carbon or coke chemistry)
ensuring that battery capacity is fully utilized while ensuring
safe operation. The Si9730 provides protection against overcharge, over-discharge, and short circuit conditions which
are hazardous to the battery and the environment.
•
•
•
•
•
•
•
•
Battery voltages of each individual cell are monitored at the
center-tap connection by an internal A/D converter through
the VC pin. If one or both of the cells is determined to be
overcharged, an internal cell balancing network "bleeds" off
current at 15 µA until both cells are charged to the same
maximum level. Depending on the condition of each cell, the
Si9730 will switch two external source-connected N-Channel
MOSFETs on or off to allow the cells to be charged or to provide current to the load.
•
•
•
•
Over-Charge Protection
Over-Discharge Protection
Short Circuit Current Limiting
Battery Open-Circuit Center Tap Protection
Cell Voltage Balancing
Undervoltage Lockout
Individual Cell Voltage Monitoring
Low Operating Current (30 µA) and Shutdown Current
(1 µA)
Internal N-Channel MOSFET Driver
High Noise Immunity
Accurate (± 1.19 %) Over-Charge Voltage Detection
Four Different Cell Types Covered
The Si9730 is available in an 8-pin SOIC package with an
operating temperature range of - 25 to 85 °C. The Si9730 is
available in both standard and lead (Pb)-free packages.
FUNCTIONAL BLOCK DIAGRAM AND PIN CONFIGURATION
C
VDD
+
VC1
Undervoltage
Lockout
Cell Balancing
Network
−
A/D
Converter
VC
Timer
CDELAY
Time Out
CLK
Control
Logic
OUT
+
VC2
−
Oscillator
SOUT
1.2 VREF
VSS
VSS
DCO
VM
ILIMIT
GS Generator
IS
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
VM
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Si9730
End of Life. Last Available Purchase Date is 31-Dec-2014
Vishay Siliconix
ABSOLUTE MAXIMUM RATINGS
Parameter
VM
VDD
VC
Limit
VDD - 1.5 V to VDD + 15 V
VSS - 0.3 V to VSS + 12 V
VSS - 0.3 V to VDD + 0.3 V
VM - 0.3 V to VDD + 0.3 V
VSS - 0.3 V to VDD + 0.3 V
125
200
80
- 55 to 150
(VSS VM)
(VM VSS )
IS
Maximum Operating Junction Temperature
Power Dissipation
Thermal Impedance (PJA)
Storage Temperature
Unit
V
°C
mW
°C/W
°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation
of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum
rating conditions for extended periods may affect device reliability.
RECOMMENDED OPERATING RANGE
Parameter
CVC < 10 pF from VC to VDD and VSS , Total
CD
RIS series resistance to sense resistor
DCO Load Capacitance
VDD to VSS
VDD to VM
Operating Temperature Range
Limit
Unit
Open to 1.0
< 27
0 to 2000
9
12
- 25 to 85
µF
k
pF
V
°C
SPECIFICATIONS
Parameter
Power Supply
Supply Current, Charging Operation
Supply Current, Normal Operation
Undervoltage Lockout Threshold
Symbol
IDD_C
IDD
IDD_UVL
VUVL
Test Conditions
Unless Otherwise Specified
VC1 = VC2 = 2.6 V, VDD - VM = 8.4 V
VC1 = VC2 = 4.05 V, VM = VSS
VM = VDD, VC1 = VC2 = 1.7 V
Measured at VDD - VSS (Falling)
VC1 = VC2, VDD - VM = 5.5 V
Limits
TA = - 25 to 85 °C
Mina
3.5
Typb
3.7
Unit
Maxa
60
30
1
µA
4.0
V
VM Leakage Current
IVM_UVL
VC1 = VC2 = 1.7 V, VDD = VM
1
VM Operating Current
IVM
VC1 = VC2 = 2.6 V, VDD - VM = 8.4 V
30
VOH
IOH = - 10 µA, VC1 = VC2 = 3.3 V
VDD - VM = 6.6 V
tr
tf
VC1 = 2 V, VC2 = 2.4 V
VDD - VM = 8.4 V CL = 500 pF, DCO to VSS
µA
Control Logic
DCO Output High Voltage
DCO Rise Time (10 % to 80 %)
DCO Fall Time (80 % to 10 %)
DCO Output Low Voltage
VOL
IOL = 10 µA
VDD - 0.1
V
7.5
1
VM = VDD
VC1 = 2 V, VC2 = 2.4 V
VSS + 0.4
VM = VSS
VC1 = VC2 = 4.4 V, IS = VDD
VM + 0.52
µs
V
Analog Section
Current-Limit
Comparator Trip Point
Current-Limit
Comparator Temperature Coefficient
Current-Limit
Comparator Response Time
Current Limit
Comparator Input Bias Current
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VILIMIT
VC1 = VC2 = 4.05 V, VM = VSS + 0.25 V
IS Rising, TA = 25 °C
25.5
dVILIMIT/dT
28
32
0.18
tILIMIT
VC1 = VC2 = 3.3 V, VM = VSS + 0.25 V
CL = 50 pF, DCO to VSS, See Figure 2
IIS
VC1 = VC2 = 3.3 V, VDD = VM, VIS = VSS
%/°C
25
- 125
mV
µs
nA
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
SPECIFICATIONS
Parameter
Symbol
Test Conditions
Unless Otherwise Specified
Limits
TA = - 25 to 85 °C
Mina
Typb
Maxa
4.15
4.1
4.1
4.15
4.1
4.1
4.2
4.15
4.15
4.2
4.15
4.15
4.18
4.12
4.12
4.18
4.12
4.12
4.28
4.22
4.22
4.28
4.22
4.22
4.20
4.25
4.27
4.27
4.25
4.27
4.27
4.30
4.32
4.32
4.30
4.32
4.32
4.25
4.30
4.25
4.25
4.30
4.25
4.35
4.40
4.35
4.35
4.40
4.35
20
10
10
2.3
2.3
30
30
Unit
Analog Section (cont’d)
VOC1
Cell 1
VC2 = 4.05 V
VDD - VM = 8.6 V
VOC2
Cell 2
VC1 = 4.05 V
VDD - VM = 8.6 V
VOC1
Cell 1
VC2 = 4.05 V
VDD - VM = 8.6 V
VOC2
Cell 2
VC1 = 4.05 V
VDD - VM = 8.6 V
VOC1
Cell 1
VC2 = 4.05 V
VDD - VM = 8.6 V
VOC2
Cell 2
VC1 = 4.05 V
VDD - VM = 8.6 V
VOC1
Cell 1
VC2 = 4.05 V
VDD - VM = 8.6 V
VOC2
Cell 2
VC1 = 4.05 V
VDD - VM = 8.6 V
A
Suffix
B
Suffix
Over-Charge Detect
Threshold (Rising)
C
Suffix
D
Suffix
Over-Charge Threshold Difference
Cell 1
Over-Charge Detect
Threshold Hysteresisc
Cell 2
Cell 1
Over-Discharge Detect
Threshold (Falling)
Cell 2
Cell 1
Cell Balancing Current
Cell 2
Timer Charge Current
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
TA = 25 °C
TA = - 25 °C
TA = 85 °C
|VOC1 - VOC2|
VOC_H1
VC2 = 4.05 V
VDD - VM = 8 6 V
VOC_H2
VC1 = 4.05 V
VODC1
VC2 = 2.6 V
VODC2
VC1= 2.6 V
VM = VSS
VC1 = 4.4 V, VC2 = 4.05 V
IBAL1
IBAL2
VC2 = 4.4 V, VC1 = 4.05 V
VC2 = 3.3 V, VM = VSS
ITIMER(C)
VC = VSS, TA = 25 °C
2.1
2.1
9
9
4.20
4.25
4.25
4.22
4.22
4.32
4.32
2.2
2.2
15
15
V
mV
V
µA
- 0.5
Timer Discharge Current
ITIMER(D)
VC1 = VC2 = 3.3 V, VDD = VM
VDD - VC = 6.1 V, TA = 25 °C
DL2 Time (Over-Charge)
tDL2OC
VC1 = 4.05 V, VDD - VM = 10 V
CD = 500 pF, TA = 25 °C, See Figure 4
27
40
60
DL2 Time (Over-Discharge)
tDL2ODC
VC1 = 2.6 V, VM = VSS, CD = 500 pF
TA = 25 °C, See Figure 5
27
40
60
30
42
-2
60
300
100
2
µA
mV
µA
40
µs
1.1
V
External Short Circuit Sense Current
Reset Threshold
Center Tap, Average Bias Current
Overcharge Load Detect
Power-Down Charger Detect
Threshold
IVMSHORT
VRTH
IVC
tOCC
VCHPD
VC1 = VC2 = 4.4 V, VM = VDD
VC1 = VC2 = 4.05 V, See Figure 3
VC1 = VC2 = 4.05 V, VM = VDD
VC1 = VC2 = 4.4 V, CD = 500 pF
CL = 500 pF, DCO to VSS, See Figure 1
1.0
ms
VC1 = 2 V, VC2 = 2.4 V, See Figure 6
CL = 500 pF, DCO to VSS, See Figure 7
tPW
DCO Pulse Width
Notes:
a. The algebraic convention whereby the most negative value is a minimum and the most positive a maximum.
b. Typical values are for DESIGN AID ONLY, not guaranteed nor subject to production testing.
c. Guaranteed by design, not subject to production test.
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
mA
520
µs
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End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
TIMING DIAGRAMS
200 mV
VM Waveform
50 %
tr
VSS
100 nS
High
DCO Waveform
50 %
VSS
tOCC
Figure 1. OC Load Detect
50 %
VSS
tr
VRTH
VSS
100 nS
VDD
tILIMIT
DCO Waveform
VDD
VSS
50 %
DCO Waveform
VDD
VM Waveform
(After Short is
Removed)
60 mV
IS Input
VSS
VRTH = VM - VSS at DCO Transition
Figure 3. Reset Threshold
Figure 2. Current-Limit Comparator Response Time
2.6 V
VC2 Waveform
2.0 V
4.4 V
VC2 Waveform
4.0 V
t30
t30
C Waveform
C Waveform
VSS
VSS
1
1
31
31
32
x t 30
30
32
x t 30
t DL20C =
30
t DL20DC =
Figure 4. DL2 Time (Over-Charge)
Figure 5. DL2 Time (Over-Discharge)
VSS
VM Waveform
+
VCHPD
−
VM Waveform
VSS
^VRTH
High
DCO Waveform
Low
VCHPD = VSS - VM at DCO Transition
Figure 6. Power-Down Charger Detect Threshold
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VDD
DCO Waveform
tpw
VSS
Figure 7. Load Detection in Overcharge Mode
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted
100.0
100.0
25 °C
10.0
t DL20C - Time (s)
t DL20C - Time (s)
25 °C
TA = 85 °C
- 25 °C
1.0
0.1
10.0
1.0
0.1
0.01
0.1
1
0.01
0.1
CD - Capacitance (µF)
DL2 Period (Over Discharge) vs. Capacitance
1.08
100
1.06
V R T H - Threshold (Normalized)
120
t I L I M I T (µS)
80
60
40
20
0
20
40
60
1
CD - Capacitance (µF)
DL2 Period (Over Charge) vs. Capacitance
80
1.04
1.02
1.00
0.98
0.96
0.94
- 25
100
VIS - VSS (mV)
0
25
50
75
100
Temperature (°C)
Reset Threshold vs. Temperature
Over Current Sense Voltage
vs. Current Sense Time
4.2050
6.5
Overcharge Threshold V OCC (V)
6.0
5.5
t O C C (µs)
- 25 °C
TA = 85 °C
5.0
4.5
4.0
3.5
50
75
100
125
150
175
200
4.2025
4.2000
4.1975
4.1950
2.5
3.0
3.5
4.0
Opposing Cell Voltage (V)
VM - VSS (mV)
Load Detect Time vs. VM - VSS
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
Overcharge Threshold
vs. Opposing Cell Voltage
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End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted
1000.00
100.00
Time (µs)
10.00
Rise
1.00
Fall
TA = 85 °C
0.10
TA = - 25 °C
0.01
100
1000
10000
DCO Capacitance (pF)
DCO Rise and Fall Times vs. Capacitance
PIN CONFIGURATION
ORDERING INFORMATION
Part Number
SO-8
Si9730ABY-T1
Si9730ABY-T1-E3 (Lead Free)
VM
1
8
DCO
NC
2
7
VSS
VDD
3
6
IS
Si9730CBY-T1
CD
4
5
VC
Si9730CBY-T1-E3 (Lead Free)
Si9730BBY-T1
Si9730BBY-T1-E3 (Lead Free)
Si9730DBY-T1
Top View
Si9730DBY-T1-E3 (Lead Free)
VOC1/2 Typ.
Temp Range
4.20 V
4.25 V
- 25° to 85 °C
4.22 V
4.32 V
PIN DESCRIPTION
Pin Number
Symbol
1
VM
Negative Battery Pack Terminal - connection for external negative terminal of the battery pack.
2
NC
No Connection, do not connect this pin.
3
VDD
Dual Cell Positive Terminal - connection for positive terminal of dual series connected LiI+ cells.
4
CD
Delay Capacitor Connection - an external capacitor connected across CD and Vss allows additional charge time
(DL2, see Detailed Description ) after a charge error has occurred. Suggested capacitor values are shown in
DL2 Period vs. Capacitance Curves.
5
VC
Dual Cell Center Tap Connection - monitors individual battery voltages for overcharge and overdischarge errors.
6
Is
Current Sense Comparator Input - monitors load current for short circuit conditions . If VILIMIT is exceeded, then
DCO opens the low-side switch, disconnecting the cell
7
VSS
Dual Cell Negative Terminal - connection for negative terminal of dual series connected LiI+ cells.
8
DCO
Low-side Switch Gate Driver Output - drives the gate of two external source connected N-Channel MOSFETs.
DCO swings from VOL to VDD.
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Description
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
DETAILED DESCRIPTION
Overview
Normal Discharging
The purpose of the Si9730 is to safely and reliably control the
charging and discharging of a two-cell lithium-ion battery
(carbon or coke chemistry). It provides protection against all
possible fault conditions, including:
The cells are in normal discharging conditions if a, b, and c
above are satisfied, and if in addition d) the load current is
less than the discharge current limit. With no charger present, the switch will be on, discharging the cells and powering
the load.
•
external short circuits
•
reversed charger
•
overcharged cell or cells
•
undervoltage
•
battery open center-tap
General Concepts
The Si9730 operates by connecting or disconnecting the
negative terminal of the battery to the negative side of the
load and/or charger (see Figure 8); that is, it does ground
side switching. It is important to bear the distinction between
these two "grounds" in mind in order to understand the operation of the Si9730. The switching is accomplished by controlling two "back-to-back" MOSFETs: having the two
MOSFETs in this arrangement is mandatory to ensure that
current cannot flow in either direction when the MOSFETs
are off. To turn the switch on, the Si9730 applies a gatesource voltage to both MOSFETs (from the DCO pin) that is
high with respect to the sources. The Si9730 DCO signal is
referenced to the VM pin while the battery is being charged,
and to the Vss pin while the battery is being discharged. The
Si9730 causes the DCO to be referenced to the lower of the
two voltages. This prevents the switch from turning on or off
unintentionally.
The Si9730 is designed to operate only with a current-limited
lithium-ion battery charger. Specifically, the battery charger
must have an open-circuit voltage that does not exceed the
absolute maximum IC voltage, and it must have a limited
short-circuit current that does not exceed the allowed
charging current of the battery.
The following descriptions cover all the common operational
scenarios; additional information on unusual battery conditions can be found in the state transition table.
Normal Charging
The cells are in normal charging conditions if a) both cells are
above the Over-Discharge Detect Threshold (VODC ~ 2.2 V);
b) both cells are under the Over-Charge Detect Threshold
(VOC ~ 4.2 V); and c) the center tap is connected to the VC
pin. When a charger is present in these conditions, the switch
will be on, charging the cells at the current limit of the charger.
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
Overcharged Cell(s) Charging
The most destructive condition that a LiI+ cell can experience
is overcharging. If the cell becomes overcharged beyond its
recommended limits, it can become permanently disabled.
If one or both cells rise above the over-charge detect threshold (VOC1 and VOC2), and a charger is present, the Si9730
will open the switch (to prevent further charging) and begin
bleeding off charge (15 µA typical) from the overcharged cell
or cells.
The details of this operation depend on the fact that the voltage level of lithium-ion batteries drops for a short time after
charging ceases (due to momentary changes in battery
chemistry, ESR, etc.). Because of this recovery, the Si9730
allows the battery to continue charging for a short time (the
overcharge time, tDL2OC). This additional charge time only
occurs if the overcharge condition persists for more than
8 msec (two periods of an internal 4msec oscillator). TDL2OC
is determined by the capacitor attached to the CD pin, see
Figure 8.
Once the overcharge time has ended, the switch is opened,
preventing the battery from further overcharging. Now, the
Si9730 begins bleeding current off the overcharged cell or
cells (IBAL1 and IBAL2), as long as a charger is present. Eventually, the cell(s) will return into their normal range, and
charging will begin, starting the whole cycle over again.
Overcharged Cell(s) Discharging
If one or more cells is overcharged, and a load is connected,
the switch is turned on, permitting the battery to power the
load.
Over-Discharged Cell(s) Discharging
Repeated over-discharging of LiI+ cells can cause irreversible reactions in the cells which lead to decreased cycle life.
To avoid this, if one or both cells becomes over-discharged
(VCELL < VODC) and no charger is present, the Si9730 opens
the switch to prevent further discharging, and goes into a
shutdown mode in which it draws minute power from the battery (IDD_UVL < 1 µA).
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Si9730
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Vishay Siliconix
Over-Discharged Cell(s) Charging
Open Center Tap
If one or both cells is over-discharged, and a charger is present, charging can begin, and so the Si9730 closes the switch.
However, removal of the charger in this condition could
potentially damage the battery if the removal is not recognized and the cells are discharged. Since the voltage drop
across the switch is small, the Si9730 actually cycles the
switch at a 7/8 duty cycle; during the 1/8 time when the
switch is open, the IC checks that the charger is still present.
Once both cells are back into the normal operating range,
normal charging resumes.
An open center tap is a mechanical failure of the battery pack
such that the Si9730’s VC pin is disconnected from the center
point of the two-cell battery. If this connection is open, the IC
opens the switch, as it cannot measure the cell voltages in
this condition. The switch is left open until connection is reestablished. If the battery is under-voltaged and the charger
is present in this case, the battery is allowed to charge even
with the center tap open. In this state, batteries are almost
impossible to damage by 1/8 duty cycle charging. Once the
battery voltage reaches the over-discharged voltage, the
switch is turned off.
Undervoltage Charging
State Transition Table
If for some reason the battery drops below about 3.7 V
(VUVL), there is insufficient voltage for the Si9730 to properly
monitor fault conditions. Of course, the switch is already
open, since VUVL < VODC x 2. However, when a charger is
detected, the Si9730 recovers and goes into an undervoltage
mode. (A charger is detected if the VS pin is higher than the
VM pin by at least VCHPD = 1.1 V, see Figure 6). In this undervoltage mode, the switch is on at a 1/8 duty cycle, to limit the
power dissipation across the switch, and, again, to detect the
continuing presence of the charger.
The number of different states of the Si9730 can seem overwhelming at first. This state transition table will help to organize thinking about the different operational conditions of the
IC, by listing each possible transition from one condition to
another.
Once the battery voltage is above VUVL, the charging continues in the over-discharged state.
Reading the table is straightforward. There are two cells constituting the battery, one with its positive terminal connected
to VDD and its negative terminal connected to VC, referred to
as the high cell (see Figure 8); and one cell with its positive
terminal connected to VC and its negative terminal connected to VSS, referred to as the low cell. Each cell can be in
one of three voltages:
Output Short
• Over-discharge (ODC), where VCELL < VODC;
If too much current is drawn from the battery due to a load
short, the switch must be opened quickly to prevent damage
to the battery. The Si9730 monitors the load current by looking at the voltage across an external sense resistor (see Figure 8). If the voltage across the sense resistor exceeds
VILIMIT ~ 28 mV, the switch is opened. The Si9730 leaves the
switch open until the load is completely removed.
Of course, the IC must have some way of detecting that the
load has been removed. For this purpose, a small current
(IVMSHORT) passes through the Si9730, from pin VM to pin
VSS once the short is detected and the switch is turned off.
The IVMSHORT current causes the voltage on the VM pin to
equal the voltage on the VDD pin while the short is present,
or the voltage on the VM pin to equal the voltage on the VSS
pin if the short is removed. If the short is not removed, IVMSHORT current will continue to flow until the battery voltage
becomes overdischarged. Once the short is removed, the IC
is allowed to turn the switch back on.
The current limit threshold has a temperature coefficient of
0.18 %/°C. This can partially compensate for a copper circuit
board trace being used as the sense resistor.
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8
• Normal Operation (NO), where
VODC < VCELL < VOC;
or
• Overcharge (OC), where VOC < VCELL.
Additionally, the battery as a whole can be undervoltage
(UV), where VBATTERY < VUVL. Note that this final condition
is not necessarily (though normally) mutually exclusive with
the other cell conditions: if one cell were at 0 V, the other cell
could be in NO, and the battery could still be in UV.
The charger can be either present (ON) or not present (OFF);
the "X" in the table means the condition is true regardless of
the state of the charger. The load current can be either 0,
normal (0 < ILOAD < IILIMIT) or a short (IILIMIT< ILOAD) where
IILIMIT is set by VILIMIT/RSENSE; the "X" in the table refers to
a load current that can be either 0 or normal. Finally, the
switch can be either ON, OFF, or cycling at either 1/8 or 7/8
duty cycle, where the duty cycle refers to the portion of the
period when the switch is on; the notation On->On simply
means that the switch does not change state, it remains on;
the notation ->Off means that the switch turns off regardless
of its previous state.
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
STATE TRANSITION TABLE
High-Cell Voltage
Low-Cell Voltage
Charger On/Off
Load Current
Switch State
NO
NO
Off>On
X
On->On
NO->OC
NO
Off
0
On->Off
NO
NO->OC
Off
0
On->Off
NO->OC
NO
Off
Normal
Cycles at very high duty cycle
NO
NO->OC
Off
Normal
Cycles at very high duty cycle
OC
NO
Off->On
X
Off->Off
NO
OC
Off->On
X
Off->Off
OC
OC
Off->On
X
Off->Off
NO
NO
Off
Normal->Short
On->Off
OC
NO
Off
Normal->Short
On->Off
NO
OC
Off
Normal->Short
On->Off
NO->ODC
NO
Off
0
On->Off
NO
NO->ODC
Off
0
On->Off
NO->ODC
NO
Off
Normal
On->Off
NO
NO->ODC
Off
Normal
On->Off
ODC
NO
Off->On
X
Off->Cycle at 7/8 duty cycle
NO
ODC
Off->On
X
Off->Cycle at 7/8 duty cycle
ODC
ODC
Off->On
X
Off->Cycle at 7/8 duty cycle
Off->On
X
Off->Cycle at 1/8 duty cycle
NO->ODC
UV
OC
Off
0
Cycle->Off
OC
NO->OC
Off
0
Off
NO
NO
VOpen
Cycle at 1/8 duty cycle
ODC
UV
ODC
X
Center Tap->Open
-.>Off
NO
ODC
X
Center Tap->Open
-.>Off
ODC
NO
X
Center Tap->Open
-.>Off
NO
NO
X
Center Tap->Open
-.>Off
OC
OC
X
Center Tap->Open
-.>Off
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
www.vishay.com
9
Si9730
End of Life. Last Available Purchase Date is 31-Dec-2014
Vishay Siliconix
APPLICATION CIRCUIT
+
10 µF
Si9730
100 Ω
VDD
C
4
3
CD
Cell 1
VC1
C1
0.1 µF
Undervoltage
Lockout
Cell Balancing
Network
100 Ω
VC
5
A/D
Converter
Timer
CDELAY
Time Out
CLK
Control
Logic
OUT
Load
Cell 2
VC2
100 Ω
Current
Sense
14 MΩ
Chgr.
8.4 V
1A
Oscillator
VSS
7
SOUT
1.2 VREF
VSS
GS Gen.
Comparator
C2
0.47 µF
VM
ILIMIT
Filter
IS
6
8
RIS
47 kΩ
1
VM
DCO
Si9936DY
Figure 8. Typical 2 -Cell Circuit
GENERAL CONSIDERATIONS
Figure 8 shows a typical application of the Si9730, controlling
a 2-cell lithium-ion battery (carbon or coke chemistry). Specifics of the selection of MOSFETs, current sensing resistor,
and output capacitor are detailed below. In addition, there
are several typical features of this circuit to be observed.
First, each connection from a cell to the IC has a 100 resistor in series with it. The purpose of the resistor is to ensure
that in the unlikely event of the IC shorting, the cells themselves will not see a short. The maximum size of this resistance is set by the current drain of the IC; for example, the
VDD pin draws a maximum of 60 µA, which will drop
V = 60 µA * 100 = 6 mV across the resistor. This drop con-
www.vishay.com
10
stitutes an error in the measured cell voltage, and so the
resistor must be small enough that the error voltage is
acceptable.
A second typical feature demonstrated in Figure 8 is the current sense filter formed by RIS and C2. This provides a noise
filter, to prevent the Si9730 from opening the connection to
the battery if there is noise on its current sense pin. It also
causes a delay in the response of the IC to a genuine overcurrent, the amount of the delay being inversely proportional
to the amount of overcurrent, since the Is pin senses a voltage. Increasing this filter’s time constant could be used to
allow short-time surges of current out of the battery without
compromising its ability to protect the battery.
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
Output Capacitor
MOSFET Selection
Depending on the MOSFET selected, the Si9730 can open
the switch quite rapidly, in a matter of a few microseconds.
However, the various monitoring operations take 10-100
times longer than this, and the basic period of the Si9730’s
oscillator is 4 msec. In order to prevent false readings by the
Si9730, it is necessary to attach a capacitor across the output of the battery charger/load (this is not in parallel with the
battery, because of the switch). A 10 µF capacitor is recommended for this purpose; see Figure 8.
Two MOSFETs in series, with their sources and gates connected together, are used as the switch. This prevents current from flowing in either direction when the gate is low; if
only one MOSFET were used, the body diode could conduct
current in the opposing direction.
Selecting a Current Sense Resistor
The current sense resistor should be selected based on the
maximum current the battery can source or charge at; above
this current, the Si9730 will open the switch, disconnecting
the battery from its load or charger.
Rsense = VILIMIT/IILIMIT 28 mV/IILIMIT
Of course, the resistor must be rated to take the power dissipated in it as well:
PRSENSE = IILIMIT* VILIMIT 28 mV * IILIMIT
For example, suppose that the maximum current the battery
will see is 1.8 A. Then, ILIMIT might be chosen to be 2 A. We
would then select a resistor of
RSENSE = 28 mV/2 A = 14 m.
The power dissipation in this resistor is
PRSENSE = 28 mV * 2 A = 56 mW
and so a 100 mW surface mount resistor would be suitable.
Another possibility is to use a thin copper trace as the
sense resistor. The copper has a temperature coefficient of
0.39 %/°C, but this is partially compensated for by the temperature coefficient of the current limit comparator in the
Si9730, which is 0.18 %/°C. A simple formula for selecting a
trace to act as a current sensor is:
R
0.5 mΩ x
length
1 oz. Copper
width
LITTLE FOOT MOSFETs are recommended for this application, because of their size, performance and cost benefits.
SO-8 and TSSOP-8 MOSFETs allow for space efficient
designs with performance equal to or better than their DPAK
and TO-220 predecessors. Further, their availability from
multiple sources permits a cost effective solution.
There are two important parameters to consider in MOSFET
selection: gate threshold voltage; and on-resistance, which
determines power dissipation.
Even when the DCO pin of the Si9730 is low, the specification allows its value to be as high as 0.4 V. If this voltage were
close to the gate threshold voltage, leakage current through
the MOSFETs could be hundreds of microamps, which
would result in the battery quickly becoming discharged. To
ensure that leakage is minimized, N-Channel MOSFETs with
a minimum gate threshold voltage of 0.8 V should be chosen.
On resistance of the MOSFETs needs to be selected to limit
power dissipation into the MOSFETs’ package. For example,
a dual MOSFET SO-8 package is rated at 2 W, and a dual
MOSFET TSSOP-8 package is rated at 1 W (both at 25 °C;
if the ambient temperature is higher, the allowable power dissipation in these packages is less). For example, if the maximum current is 2 A, and a dual MOSFET SO-8 package is
being used, the maximum on-resistance of the two MOSFETs in series must not exceed
1 W = (2 A)2 * RON
or RON = 0.25 ; each MOSFET can be allotted half of this,
RON = 125 m. Account must also be taken of the fact that
MOSFETs’ on-resistance is a function of temperature; a conservative approach would give a discount of 1/3,
RON = 125 m * (2/3) = 80 m per MOSFET.
A list of recommended MOSFETs, which Vishay Siliconix
supplies, follows.
For example, to get a 14 m. resistor, we need length/width
= 28; with a trace width of 0.01", the length of the trace
should be 0.28".
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
www.vishay.com
11
Si9730
End of Life. Last Available Purchase Date is 31-Dec-2014
Vishay Siliconix
N-CHANNEL MOSFET SELECTION GUIDE
Recommended
Application Current
(A) at 25 °C
Part Number
rDS (on) () at
VGS = 10 V
rDS(on) () at
VGS = 4.5 V
ID (A)
VGS(th) (V)
Config.
Si4410DY
0.0135
0.020
10
1.0
Single
SO-8
9
Si4412DY
0.028
0.042
7
1.0
Single
SO-8
6.3
Package
Si6434DQ
0.028
0.042
5.6
1.0
Single
TSSOP-8
4.9
Si4936DY
0.037
0.055
5.8
1.0
Dual
SO-8
3.5
Si9936DY
0.050
0.080
5
1.0
Dual
SO-8
2.9
Si6954DQ
0.065
0.095
3.9
1.0
Dual
TSSOP-8
1.9
V+
100 Ω
Si9730
1 VM
DCO
2 NC
3 VDD
100 Ω
8
VSS 7
4 CD
IS 6
VC
5
10 nF
100 Ω
+
15 MΩ
470 nF
47 kΩ
100 µF
Si9936
100 Ω
Si9730
1 VM
DCO
2 NC
4 CD
100 µF
VSS 7
3 VDD
100 Ω
+
8
IS 6
VC
5
470 nF
10 nF
100 Ω
47 kΩ
15 MΩ
V-
Si9936
Figure 9. 4-Cell Battery Circuit
www.vishay.com
12
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
End of Life. Last Available Purchase Date is 31-Dec-2014
Si9730
Vishay Siliconix
observing that the current through it is limited by the 100
resistor. A trade off can be made here between the power
rating of the zener, which can be decreased by increasing
the resistor value, and the accuracy of the voltage measurement by the Si9730, which can be increased by decreasing
the resistor value.
Four Cell Application
Figure 9 shows a method for using the Si9730 in a 4-cell
application. Basically, this is two complete 2-cell circuits
stacked in series. Each half of the complete circuit monitors
its own 2-cell portion of the battery, and opens its own MOSFET switch under any of the appropriate conditions. Observe
that the total percent power loss in this circuit is identical to
that in the 2-cell application; although there are now two sets
of MOSFETs in series, there is also double the battery voltage, and so total efficiency is the same.
Reset from Shutdown
There are two specialized conditions that can place the
Si9730 in shutdown mode. The first condition can occur
when the circuit is first attached to a battery in the factory.
When the IC comes up, it will be in the undervoltage shutdown mode. The Si9730 may also enter this mode when the
ambient temperature drops and the battery is nearly in UV.
When the temperature drops, the battery pack voltage will
drop and the IC may enter the shutdown mode. In either
case, the Si9730 must be reset by raising the VSS pin higher
than the VM pin by VCPHD. Figure 10 shows a circuit that
resets the circuit once it has entered the shutdown mode.
One novel feature of this 4-cell circuit is the increase in the
size of the bypass capacitors. Each half of the circuit retains
its own output cap, to reduce noise seen by the circuit. Since
the two halves interact with each other (when one opens its
switch, the other one is also opened), there can be additional
noise, which must be rejected for proper operation. The
capacitors have been increased to 100 µF for this reason;
remember that they must be rated to take the full maximum
voltage rating of the charger, not half of it, since if one switch
is closed and the other open, the charger (minus two cells’
voltage drop, which might be zero) is applied across the
other capacitor.
The circuit works by initially connecting the 0.1 µF capacitor
to the battery’s center tap and placing the switch in position
#1. Although the MOSFETs are open, the 1 m resistor is
sufficient to allow the capacitor to charge up in about 300 400 msec. Once the capacitor is charged, the switch is
placed in position #2, momentarily making VSS higher than
VM, thus placing the Si9730 in the normal operating mode.
The entire circuit provides a leakage of only a few microamps, which is much lower than the self discharge current of
the LiIon battery.
A second addition on this circuit is the (optional) two zeners,
one each for each Si9730, placed from VDD to VM. These are
necessary only if the charger voltage is higher than the 15 V
absolute maximum of the IC plus two cells’ voltage drop. Just
as with the capacitor, if one switch is open and the other
closed, the IC will see this charger voltage, and must be protected. The power rating of the zener can be inferred by
Si9730
1 VM
2 NC
3 VDD
4 CD
DCO
8
#2
#1
VSS 7
IS 6
VC
SPDT
5
15 MΩ
1 MΩ
0.1 µF
Figure 10. Factory Startup Circuit
Vishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, and reliability
data, see http://www.vishay.com/ppg?70658.
Document Number: 70658
S-40135-Rev. F, 16-Feb-04
www.vishay.com
13
Package Information
Vishay Siliconix
SOIC (NARROW): 8-LEAD
JEDEC Part Number: MS-012
8
6
7
5
E
1
3
2
H
4
S
h x 45
D
C
0.25 mm (Gage Plane)
A
e
B
All Leads
q
A1
L
0.004"
MILLIMETERS
INCHES
DIM
Min
Max
Min
Max
A
1.35
1.75
0.053
0.069
A1
0.10
0.20
0.004
0.008
B
0.35
0.51
0.014
0.020
C
0.19
0.25
0.0075
0.010
D
4.80
5.00
0.189
0.196
E
3.80
4.00
0.150
e
0.101 mm
1.27 BSC
0.157
0.050 BSC
H
5.80
6.20
0.228
0.244
h
0.25
0.50
0.010
0.020
L
0.50
0.93
0.020
0.037
q
0°
8°
0°
8°
S
0.44
0.64
0.018
0.026
ECN: C-06527-Rev. I, 11-Sep-06
DWG: 5498
Document Number: 71192
11-Sep-06
www.vishay.com
1
Legal Disclaimer Notice
www.vishay.com
Vishay
Disclaimer
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RELIABILITY, FUNCTION OR DESIGN OR OTHERWISE.
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© 2022 VISHAY INTERTECHNOLOGY, INC. ALL RIGHTS RESERVED
Revision: 01-Jan-2022
1
Document Number: 91000