FUJITSU MB3879PFV

FUJITSU SEMICONDUCTOR
DATA SHEET
DS04-27708-2E
ASSP for Power Supply Application (for secondary battery)
DC/DC Converter IC for Parallel Charging
of 3/4 cell Li-ion & NiMH Batteries
MB3879
■ DESCRIPTION
The MB3879 is a DC/DC converter IC for parallel charging of 3/4 cell Li-ion & NiMH batteries, which uses the
pulse-width modulation (PWM) for controlling output voltages and output currents independently.
This IC can dynamically control secondary batterie’s charge current, which detects voltage dropping in an AC
adapter in order to keep its power constant (Dynamically controlled charging). This operation allows quick charging
by variable charging current in accordance with operating status of a notebook PC.
Moreover, the total current of the system current and control IC input current are detected, and control of the
secondary battery is enabled.
An efficient charge becomes possible because of the charge current comes in changeability according to the
operation state of notebook PC by this operation.
The IC also allows parallel charging that charges two batteries simultaneously, reducing charging time dramatically.
The IC, using a built-in output voltage setting resistor, allows high-precision setting of output voltages. With its
output-voltage switching function that is ready for both graphite-type and coke-type Li-ion batteries as well as
NiMH battery, the IC is best suited to a built-in charger of a notebook PC.
This product is covered by US Patent Number 6,147,477.
■ FEATURES
• Detecting a voltage dropping in the AC adapter, and dynamically controlling the charge current (Dynamicallycontrolled charging)
• Detecting total current of system current and control-IC input current (Differential-charging)
(Continued)
■ PACKAGE
48-pin plastic LQFP
(FPT-48P-M05)
MB3879
(Continued)
• Selection of output voltages by 4-bit decoder:
12.3V (3 cells: 4.1V), 12.6V (3 cells: 4.2V), 16.4V (4 cells: 4.1V), 16.8V (4 cells: 4.2V)
• High efficiency: 94% (using reverse current preventive diode)
• Wide range of power supply voltage: 8 V to 25 V
• Setting precision of output voltage (built-in output voltage setting resistor): ± 0.8% (Ta = +25 °C)
• Setting precision of charge current: ±5%
• Setting of frequency for only external capacitor, using built-in frequency setting resistor.
• Oscillation frequency range: 100 kHz to 500 kHz
• Built-in current detect amplifier with wide range of in-phase input voltages: 0 V to Vcc
• Stand-by current: 0 µA
• Built-in load-independent soft-start circuit
• Built-in charge mode detection function
• Built-in totem-pole outputs supporting Pch MOS FET
2
MB3879
■ PIN ASSIGNMENT
+INC1
-INC1
FB1
OUTC1
-INE1
+INE1
FB2
-INE2
+INE2
DTC
GND
CT
48
47
46
45
44
43
42
41
40
39
38
37
(TOP VIEW)
CTL
7
30
FB5
VDD
8
29
-INE5
VB
9
28
TEST
OUT-EV
10
27
GNDO
OUT-EC
11
26
VH
OUT-EA2
12
25
VCCO
24
+INE4
OUT
31
23
6
CS1
VSS
22
-INE4
CS2
32
21
5
-INE6
D3
20
OUTC3
FB6
33
19
4
+INE3
D2
18
FB4
-INE3
34
17
3
OUTC2
D1
16
+INC3
FB3
35
15
2
+INC2
D0
14
IN2
IN1
36
13
1
OUT-EA1
VCC
(FPT-48P- 05)
3
MB3879
■ PIN DESCRIPTION
Pin No.
Symbol
I/O
1
VCC

2
D0
I
VDD logic input terminal
3
D1
I
VDD logic input terminal
4
D2
I
VDD logic input terminal
5
D3
I
VDD logic input terminal
6
VSS

7
CTL
I
8
VDD

VDD logic power supply terminal
9
VB
O
Reference voltage output terminal
O
Constant-voltage charging distinction signal output terminal
H level: Dynamically-controlled charging, Differential charging, or
Constant-voltage charging mode
L level: BATT1 or BATT2 Constant-voltage charging mode
O
Constant-current charge distinction signal output terminal
H level: Dynamically-controlled charging, Differential charging, or
Constant-voltage charging mode
L level: BATT1 or BATT2 Constant-current charging mode
O
Differential-charging distinction signal output terminal
H level: Dynamically-controlled-charging, Constant-voltaging, or
Constant-current charging mode
L level: Differential-charging mode
10
11
12
OUT-EV
OUT-EC
OUT-EA2
Descriptions
Power supply terminal
VDD logic ground terminal
Power supply control terminal. Setting “L” level on CTL terminal
places the IC in standby mode.
13
OUT-EA1
O
Dynamically-controlled charging distinction signal output terminal
H level: Dynamically-controlled charging, Constant-voltage charging,
or Constant-current charging mode
L level: Dynamically-controlled charging mode
14
IN1
I
<BATT1> Current detection amplifier (Current Amp2) input terminal
Output voltage feedback input terminal
15
+INC2
I
<BATT1> Current detection amplifier (Current Amp2) input terminal
16
FB3
O
<BATT1> Error amplifier (Error Amp3) output terminal
17
OUTC2
O
<BATT1> Current detection amplifier (Current Amp2) output terminal
18
−INE3
I
<BATT1> Error amplifier (Error Amp3) inverted input terminal
19
+INE3
I
<BATT1> Error amplifier (Error Amp3) non-inverted input terminal
20
FB6
O
<BATT1> Error amplifier (Error Amp6) output terminal
21
−INE6
I
<BATT1> Error amplifier (Error Amp6) inverted input terminal
22
CS2

Soft-start capacitor connection terminal
23
CS1

Soft-start capacitor connection terminal
24
OUT
O
External FET gate driving terminal
25
VCCO

Driver block power supply terminal
(Continued)
4
MB3879
(Continued)
Pin No.
Symbol
I/O
Descriptions
26
VH
O
FET driver circuit power supply terminal (VH = VCC−6V)
27
GND0

Ground terminal
28
TEST
O
Internal reference voltage for setting charge voltage
29
−INE5
I
<BATT2> Error amplifier (Error Amp5) inverted input terminal
30
FB5
O
<BATT2> Error amplifier (Error Amp5) output terminal
31
+INE4
I
<BATT2> Error amplifier (Error Amp4) non-inverted input terminal
32
−INE4
I
<BATT2> Error amplifier (Error Amp4) inverted input terminal
33
OUTC3
O
<BATT2> Current detection amplifier (Current Amp3) output terminal
34
FB4
O
<BATT2> Error amplifier (Error Amp4) output terminal
35
+INC3
I
<BATT2> Current detection amplifier (Current Amp3) input terminal
36
IN2
I
<BATT2> Current detection amplifier (Current Amp3) input terminal
Output voltage feedback input terminal
37
CT

Triangular wave oscillation frequency setting capacitor connection
terminal
38
GND

Ground terminal
39
DTC
I
External duty control input terminal
40
+INE2
I
Error amplifier (Error Amp2) non-inverted input terminal
41
−INE2
I
Error amplifier (Error Amp2) inverted input terminal
42
FB2
O
Error amplifier (Error Amp2) output terminal
43
+INE1
I
Error amplifier (Error Amp1) non-inverted input terminal
44
−INE1
I
Error amplifier (Error Amp1) inverted input terminal
45
OUTC1
O
Current detection amplifier (Current Amp2) output terminal
46
FB1
O
Error amplifier (Error Amp1) output terminal
47
−INC1
I
Current detection amplifier (Current Amp1) input terminal
48
+INC1
I
Current detection amplifier (Current Amp1) input terminal
5
MB3879
■ BLOCK DIAGRAM
VCC
1
48
−INC1
47
+INE1
43
45
<Current
+ Amp1>
×25
−
+
<Error Amp1>
<VDD>
−
−
+
13
OUT-EA1
12
OUT-EA2
11
OUT-EC
10
OUT-EV
25
VCCO
24
OUT
<MODE
Comp.2>
+
46
42
<Error Amp2>
−INE2
41
−
+INE2
40
+
−
<MODE
Comp.3>
+
−
<<Dynamically-Contorl>>
DTC
−INE3
OUTC2
+INC2
39
IN1
+INE3
FB3
−INE4
OUTC3
+INC3
14
IN2
36
+INE4
31
FB4
34
CS1
<MODE
Comp.1>
<<Differencial-Control>>
18
<MODE
Comp.4>
<<Current-Contorl>>
17
<Current
+ Amp2>
×25
−
15
+
<Error Amp3>
−
−
+
+
19
16
32
<Current
+ Amp3>
×25
−
35
<Error Amp4>
−
+
+
<PWM
Comp>
FB
Voltage
Selector
33
26
bias
(VCC − 6 V)
Voltage
<VH>
27
R1
22.4
kΩ
R1
<<Voltage-Contorl>>
22.4 kΩ
<Error Amp5>
29
FB5
30
Drive
VCC
<SOFT1>
VB
23
−INE5
<OUT>
+
+
+
−
−
+
+
R2
<UVLO>
FB
Voltage
Selector
FB1
FB2
44
FB
Voltage
Selector
−INE
OUTC1
+INC1
VH
GNDO
VCC
UVLO
VB
UVLO
R2
<Error Amp6>
−INE6
21
3V
R3
8.4
kΩ
R3
8.4
kΩ
FB6
−
+
+
2.8 kΩ 2.8 kΩ
2V
20
<SOFT2>
VB
CS2
22
(4.2 V)
D0
D1
D2
D3
2
3
4
<REF>
5
6
VSS
6
<Decoder>
8
<Larch>
VDD
(4.1 V)
<OSC>
<VB>
bias
(5 V)
37
28
CT TEST
<VR>
9
38
VB
GND
<CTL> 7
CTL
MB3879
■ ABSOLUTE MAXIMUM RATINGS
Parameter
Power supply voltage
Symbol
VCC
Conditions
VCC and VCCO terminal

VDD
Rating
Unit
Min
Max

28
V

17
V
Output current
IO
OUT terminal

60
mA
Peak output current
IOP
OUT terminal
Duty ≤ 5% (t = 1/fosc×Duty)

700
mA
Power dissipation
PD
Ta ≤ + 25 °C

860*
mW
−55
+ 125
°C
Storage temperature
Tstg

* : The package is mounted on the dual-sided epoxy board (10 cm×10 cm) .
WARNING: Semiconductor devices can be permanently damaged by application of stress (voltage, current,
temperature, etc.) in excess of absolute maximum ratings. Do not exceed these ratings.
7
MB3879
■ RECOMMENDED OPERATING CONDITIONS
Parameter
Power supply voltage
Symbol
VCC
Conditions
VCC and VCCO terminals

VDD
Value
Unit
Min
Typ
Max
8
19
25
V
2.7
5
7
V
Reference voltage output current
IB
VB terminal
−1

0
mA
VH terminal output current
IH
VH terminal
0

30
mA
VINE
−INE1 to −INE6,
+INE1 to +INE4 terminal
0

VCC−1.8
V
VINC
+INC1 to +INC3, −INC1
terminal
0

VCC
V
VINC
IN1 and IN2 terminals
0

VCC
V
VDTC
DTC terminal
0

VCC−0.9
V
Output current
IO
OUT terminal
−45

+45
mA
Peak output current
IOP
Duty ≤ 5%
(t = 1/fosc×Duty)
OUT terminal
−600

+600
mA
Input voltage
CTL terminal input voltage
VCTL
CTL terminal
0

25
V
Decoder block input voltage
VDEC
D0 to D3 terminals
0

VDD
V
Oscillation frequency
fOSC

100
300
500
kHz
Timing capacitor
CT

47
100
330
pF
Soft-start capacitor
CS


0.022
1.0
µF
VH terminal capacitor
CH


0.1
1.0
µF
CREF


0.1
1.0
µF
Ta

−30
+25
+85
°C
Reference voltage output
capacitor
Operating ambient temperature
WARNING: The recommended operating conditions are required in order to ensure the normal operation of the
semiconductor device. All of the device’s electrical characteristics are warranted when the device is
operated within these ranges.
Always use semiconductor devices within their recommended operating condition ranges. Operation
outside these ranges may adversely affect reliability and could result in device failure.
No warranty is made with respect to uses, operating conditions, or combinations not represented on
the data sheet. Users considering application outside the listed conditions are advised to contact their
FUJITSU representatives beforehand.
8
MB3879
■ ELECTRIC CHARACTERISTICS
Parameter
1.Reference
voltage block
[REF]
VTEST1
28
Charge mode = Li4C42,
4.167 4.200 4.233
Ta = +25 °C
V
VTEST2
28
Charge mode = Li4C42,
4.158 4.200 4.242
Ta = −30 °C to +85 °C
V
VTEST3
28
Charge mode = Li4C41,
4.063 4.100 4.137
Ta = +25 °C
V
VTEST4
28
Charge mode = Li4C42,
4.050 4.100 4.150
Ta = −30 °C to +85 °C
V
VB1
9
Ta = +25 °C
4.95
5.00
5.05
V
VB2
9
Ta = −30 °C to +85 °C
4.94
5.00
5.06
V
Input stability
Line
9
VCC = VCCO = 8 V to
25 V

3
10
mV
Load stability
Load
9
VB = 0 mA to −1 mA

1
10
mV
los
9
VB = 1 V
−25
−15
−5
mA
VTLH
1
VCC = VCCO =
6.0
6.2
6.4
V
VTHL
1
VCC = VCCO =
5.0
5.2
5.4
V
Output voltage
Output voltage
2.Control
circuit bias
voltage block
[VB]
short-circuit output
current
Threshold voltage
3. Under
voltage lockout Hysteresis width
protection
circuit block
Threshold voltage
[UVLO]
4. Soft-start
block
[SOFT1,
SOFT2]
(VCC = VCCO = 19 V, VDD = 5 V, Charge mode = Li4C42, Ta = +25 °C)
Value
Symbol Pin No.
Conditions
Unit
Min Typ Max


1*

V
VB =
2.5
2.7
2.9
V
VB =
2.3
2.5
2.7
V


0.2*1

V

−14
−10
−6
µA
240
300
360
kHz
Ta = −10 °C to +85 °C

5*1

%
Ta = −30 °C to +85 °C

10*1

%
VH
1
VTLH
9
VTHL
9
Hysteresis width
VH
9
Charge current
ICS
22, 23
Oscillation frequency
fOSC
24
CT = 100 pF
∆f/fdt
24
∆f/fdt
24
5. Triangular
Frequency
oscillator block temperature stability
[OSC]
Frequency
temperature stability
1
*1 : Standard design value
(Continued)
9
MB3879
Parameter
(VCC = VCCO = 19 V, VDD = 5 V, Charge mode = Li4C42, Ta = +25 °C)
Value
Symbol Pin No.
Conditions
Unit
Min
Typ Max
VIO
18, 19,
31, 32,
40, 41,
43, 44
Error Amp1 to Error
Amp4
FB1 to FB4 = 2.5 V

1
5
mV
IB
18, 19,
31, 32,
40, 41,
43, 44
−INE1 = +INE1 =
−INE2 = +INE2 =
−INE3 = +INE3 =
−INE4 = +INE4 = 0 V
−100
−30

nA
Common mode input
voltage range
VCM
16, 34,
42, 46
Error Amp1 to Error
Amp2
0

VCC−
1.8
V
Voltage gain
AV
16, 34,
42, 46
DC

100*1

dB
Frequency band width
BW
16, 34,
42, 46
AV = 0 dB

2*1

MHz
VOH
16, 20,
30, 34,
42, 46
FB1 to FB6 = −1 mA
4.5
4.7

V
VOL
16, 20,
30, 34,
42, 46
FB1 to FB6 = 1 mA

1.0
1.2
V
ISOURCE
16, 20,
30, 34,
42, 46
FB1 to FB6 = 2.5 V

−9
−4.5
mA
lSINK
16, 20,
30, 34,
42, 46
FB1 to FB6 = 2.5 V
4.5
9.0

mA
20, 30
FB5 = FB6 = 2.5 V,
Ta = +25 °C
VTH*2× VTH× VTH×
Charge mode = Li4C42, 0.992 1.000 1.008
Li3C42
V
20, 30
FB5 = FB6 = 2.5 V,
Ta = −30 °C to +85 °C VTH*2× VTH× VTH×
Charge mode = Li4C42, 0.990 1.000 1.010
Li3C42
V
20, 30
FB5 = FB6 = 2.5 V,
Ta = +25 °C
VTH*3× VTH× VTH×
Charge mode = Li4C41, 0.991 1.000 1.009
Li3C41
V
20, 30
FB5 = FB6 = 2.5 V,
Ta = −30 °C to +85 °C VTH*3× VTH× VTH×
Charge mode = Li4C41, 0.989 1.000 1.011
Li3C41
V
Input offset voltage
Input bias current
Output voltage
6. Error
amplifier block
[Error Amp1 to Output source current
Error Amp6]
Output sink current
VTH1
VTH2
Threshold voltage
VH3
VTH4
*1 : Standard design value
*2 : 16.8 V (Li4C42) , 12.6 V (Li3C42)
*3 : 16.4 V (Li4C41) , 12.3 V (Li3C41)
10
(Continued)
MB3879
Parameter
Input current
6. Error
amplifier
block
[Error Amp1 to
Error Amp6]
(VCC = VCCO = 19 V, VDD = 5 V, Charge mode = Li4C42, Ta = +25 °C)
Value
Symbol Pin No.
Conditions
Unit
Min Typ Max
IINEH1
14, 36
IN1 = IN2 = 16.8 V
Charge mode = Li4C42

500
750
µA
IINEH2
14, 36
IN1 = IN2 = 16.4 V
Charge mode = Li4C41

488
730
µA
IINL
14, 36
VCC = VCCO = 0 V,
IN1 = IN2 = 16.9 V

0
1
µA
Ra
14, 36
R1+R2
IN1 = IN2 = 16.8 V
Charge mode = Li4C42
17.6
25.2
32.8
kΩ
Rb
21, 29
R3
IN1 = IN2 = 16.8 V
Charge mode = Li4C42
5.9
8.4
10.9
kΩ
Rc
14, 36
R1
IN1 = IN2 = 12.6 V
Charge mode = Li3C42
15.7
22.4
29.1
kΩ
Rd
21, 29
R2+R3
IN1 = IN2 = 12.6 V
Charge mode = Li3C42
7.8
11.2
14.6
kΩ
I+INCH
15, 35,
48
+INC1 to +INC3
= 3 V to VCC,
∆Vin = −100 mV

20
30
µA
I−INCH
47
+INC1 = 3 V to VCC,
∆Vin = −100 mV

0.1
0.2
µA
I+INCL
15, 35,
48
+INC1 to +INC3
=0V
∆Vin = −100 mV
−180 −120

µA
I−INCL
47
+INC1 = 0 V
∆Vin = −100 mV
−195 −130

µA
VOUTC1
17, 33,
45
+INC1 to +INC3
= 3 V to VCC,
∆Vin = −100 mV
2.375 2.500 2.625
V
VOUTC2
17, 33,
45
+INC1 to +INC3
= 3 V to VCC,
∆Vin = −20 mV
0.410 0.530 0.650
V
VOUTC3
17, 33,
45
+INC1 to +INC2
= 0 V to 3 V,
∆Vin = −100 mV
2.25
2.50
2.75
V
VOUTC4
17, 33,
45
+INC1 to +INC2
= 0 V to 3 V,
∆Vin = −20 mV
0.33
0.53
0.73
V
Input resistance
Input current
7. Current
detection
amplifier block
[Current Amp1
to Current
Amp3]
Current detection
voltage
(Continued)
11
MB3879
(Continued)
Parameter
Common mode input
voltage range
VCM
17, 33,
45
Voltage gain
AV
17, 33,
45
BW
17, 33,
AV = 0 dB
45
7. Current
detection
Frequency band width
amplifier block
[Current Amp1
to Current
Output voltage
Amp3]
Output source current
Output sink current
8.PWM
comparator
block
[PWM Comp.]
9. DTC
detection
block
[DTC]

Vcc
V
23.75 25.00 26.25 V/V

2.0*1

MHz
VOUTCH
17, 33,
45

4.8
4.9

V
VOUTCL
17, 33,
45


20
200
mV
ISOURCE
17, 33, OUTC1 to OUTC3
45
=2V

−2
−1
mA
ISINK
17, 33, OUTC1 to OUTC3
45
=2V
100
200

µA
Duty cycle = 0 %
1.9
2.0

V
VTH
24
Duty cycle = 100 %

3.0
3.1
V
IDTC
39
DTC = 2.5 V

nA
VTL
24
Duty cycle = 0 %
1.9
2.0

V
VTH
24
Duty cycle = 100 %

3.0
3.1
V
ISOURCE
24
OUT = 14 V, Duty ≤ 5 %
(t = 1 / fOSC × Duty)

−400*1

mA
ISINK
24
OUT = 19 V, Duty ≤ 5 %
(t = 1 / fOSC × Duty)

400*1

mA
ROH
24
OUT = −45 mA

6.5
9.8
Ω
ROL
24
OUT = 45 mA

5.0
7.5
Ω
Rise time
tr1
24
OUT = 3300 pF
(Si4435 equivalent)

50*1

ns
Fall time
tf1
24
OUT = 3300 pF
(Si4435 equivalent)

50*1

ns
Output voltage
VH
26
VCC = VCCO =
8 V to 25 V,
VH = 0 mA to 30 mA
Threshold voltage
Input terminal current
Threshold voltage
Output on resistor
*1 : Standard design value
12
+INC1 to +INC3
= 3 V to VCC,
∆Vin = −100 mV
0
24
Output sink current
11. Bias
voltage block
[VH]

VTL
Output source current
10. Output
section
[OUT]
(VCC = VCCO = 19 V, VDD = 5 V, Charge mode = Li4C42, Ta = +25 °C)
Value
Symbol Pin No.
Conditions
Unit
Min Typ Max
−400 −200
VCC − VCC − VCC −
6.5
6.0
5.5
V
MB3879
(Continued)
Parameter
CTL input voltage
12. Control
block
[CTL]
Input current
Data output delay time
CTL signal re-input
time
(VCC = VCCO = 19 V, VDD = 5 V, Charge mode = Li4C42, Ta = +25 °C)
Value
Symbol Pin No.
Conditions
Unit
Min Typ Max
2.0

25.0
V
Standby status
0

0.8
V
7
CTL = 5 V

100
150
µA
ICTLL
7
CTL = 0 V

0
1
µA
tD0
24
CTL = “H” level→Start
charging


1
ms
tRCTL
7
CTL = “H” level→“L”
level→“H” level
2


ms
VIL
2, 3,
4, 5

0

VDD ×
0.2
V
VIH
2, 3,
4, 5

VDD ×
0.7

VDD
V
IH
2, 3,
4, 5
D3 to D0 = 5 V

50
75
µA
IL
2, 3,
4, 5
D3 to D0 = 0 V


10
µA
tDS
2, 3,
4, 5
D3 to D0→CTL
1


ms
VTH
7
Operating status
VTL
7
ICTLH
Input voltage
13. Decoder
block
[DEC]
Input current
Data setup time
VTLH
10, 11,
FB1 to FB6 =
12, 13
3.2
3.3
3.4
V
VTHL
10, 11,
FB1 to FB6 =
12, 13
2.9
3.0
3.1
V
VH
10, 11,
12, 13

0.3*1

V
VOL
OUT-EA1 = OUT-EA2 =
10, 11,
OUT-EV = OUT-EC = 2
12, 13
mA


0.4
V
VOH
OUT-EA1 = OUT-EA2 =
10, 11,
VDD −
OUT-EV = OUT-EC =
12, 13
0.4
−0.4 mA


V
Threshold voltage
14. Mode
Hysteresis width
detection
block
[MODE Comp.]
Output voltage
IDDS
8
CTL = 0 V

0
10
µA
IDD
8
CTL = 5 V,
OUT-EV = “L” level

200
300
µA
Standby current
ICCS
1, 25
CTL = 0 V

0
10
µA
Power supply current
ICC
1, 25
CTL = 5 V

8
12
mA
Standby current
15. VDD power
supply
Power supply current
16. General

*1 : Standard design value
13
MB3879
■ TYPICAL CHARACTERISTICS
Power current vs. VDD logic block
power supply voltage
12
Ta = +25 °C
CTL = 5 V
10
8
6
4
2
0
0
5
10
15
20
25
Power supply current IDD (µA)
Power supply current ICC (mA)
Power supply current vs. Power supply voltage
500
450
400
350
300
250
200
150
100
50
0
0
Power supply voltage VCC (V)
4
6
8
10
Reference voltage vs. Power supply voltage
5
Reference voltage VTEST (V)
5
4
3
2
TEST = 4.2 V setting
Ta = +25˚C
CTL = 5 V
TEST = 0 mA
1
0
0
5
10
15
20
25
4
3
2
TEST = 4.1 V setting
Ta = +25˚C
CTL = 5 V
TEST = 0 mA
1
0
0
5
10
15
20
25
Power supply voltage VCC (V)
Power supply voltage VCC (V)
Reference voltage vs. Ambient temperature
Reference voltage vs. Ambient temperature
4.15
4.25
4.24
TEST = 4.2 V specified
VCC = 19 V
CTL = 5 V
TEST = 0 mA
4.23
4.22
4.21
4.2
4.19
4.18
4.17
4.16
4.15
−40
−20
0
20
40
60
80
Ambient temperature Ta ( °C)
100
Reference voltage VTEST2 (V)
Reference voltage VTEST (V)
2
VDD logic power supply voltage VDD (V)
Reference voltage vs. Power supply voltage
Reference voltage VTEST1 (V)
Ta = +25 °C
VCC = 19 V
CTL = 5 V
4.14
TEST = 4.1 V specified
VCC = 19 V
CTL = 5 V
TEST = 0 mA
4.13
4.12
4.11
4.1
4.09
4.08
4.07
4.06
4.05
−40
−20
0
20
40
60
80
100
Ambient temperature Ta ( °C)
(Continued)
14
MB3879
Reference voltage vs. Power supply voltage
Reference voltage vs. Load current
6
Reference voltage VB (V)
5
4
3
2
Ta = +25 °C
CTL = 5 V
VB = 0 mA
1
0
0
5
10
15
20
Ta = +25 °C
VCC = 19 V
CTL = 5 V
5
4
3
2
1
0
25
0
5
5.10
CTL terminal current ICTL (µ
µA)
Reference voltage VB (V)
5.04
5.02
5.00
4.98
4.96
4.94
4.92
4.90
−40
−20
0
20
40
60
80
100
Ambient temperature Ta ( °C)
Triangular oscillation frequency fOSC (Hz)
20
25
500
VCC = 19 V
CTL = 5 V
VB = 0 mA
5.06
15
30
CTL terminal current and reference voltage
vs. CTL terminal voltage
Reference voltage vs. Ambient temperature
5.08
10
Load current IB (mA)
Power supply voltage VCC (V)
10
Ta = +25 °C
VCC = 19 V
450
400
9
8
350
7
ICT
300
6
VB
250
5
200
4
150
3
100
2
50
1
0
0
5
10
15
20
Reference voltage VB (V)
Reference voltage VB (V)
6
0
25
CTL terminal voltage VCTL (V)
Triangular oscillation frequency vs.
Timing capacitor
1M
Ta = +25 °C
VCC = 19 V
CTL = 5 V
100 k
10 k
10
100
1000
Timing capacitor CT (pF)
(Continued)
15
MB3879
Triangular oscillation frequency vs.
Ambient temperature
310
340
Ta = +25 °C
CTL = 5 V
CT = 100 pF
308
306
304
302
300
298
296
294
292
290
0
5
10
15
20
25
30
Triangular wave oscillation frequency
fOSC (kHz)
Triangular oscillation frequency fOSC (kHz)
Triangular oscillation frequency vs.
Power supply voltage
Ta = +25 °C
VCC = 19 V
CTL = 5 V
CT = 100 pF
330
320
310
300
290
280
270
260
250
240
−40
−20
Power supply voltage VCC (V)
0
20
40
60
Ambient temperature Ta ( °C)
80
100
Error amplifier threshold voltage VTH (V)
Error amplifier threshold voltage VTH (V)
Error amplifier threshold voltage vs.
Ambient temperature (Error Amp6)
17.0
VCC = 19 V
CTL = 5 V
16.9
16.8
16.7
16.6
16.5
−40
−20
0
20
40
60
80
Ambient temperature Ta ( °C)
100
Error amplifier threshold voltage vs.
Ambiennt temperature characteristics (Error Amp5)
17.0
VCC = 19 V
CTL = 5 V
16.9
16.8
16.7
16.6
16.5
−40
−20
0
20
40
60
Ambient temperature Ta ( °C)
80
100
(Continued)
16
MB3879
Error amplifier gain, phase vs.
Frequency (Error Amp2)
Ta = +25 °C
Gain AV (dB)
240 kΩ
φ
20
VCC = 19 V
180
AV
90
0
0
−20
−90
−40
−180
1k
10 k
100 k
1M
10 kΩ
1 µF
+
Phase φ (deg)
40
41
2.4 kΩ
IN
40
10 kΩ
−
42
+
2.1 V
OUT
Error Amp2
10 M
Frequency f (Hz)
Error amplifier gain, phase vs.
Frequency (Error Amp3)
Ta = +25 °C
40
180
AV
VCC = 19 V
4.2 V
240 kΩ
φ
90
0
0
Phase φ (deg)
Gain AV (dB)
20
−20
−90
−40
−180
1k
10 k
100 k
1M
10 kΩ
1 µF+
IN
10 kΩ
2.4 kΩ
18
−
23
+
19
+
2.5 V
10 kΩ
16
OUT
Error Amp2
10 kΩ
10 M
Frequency f (Hz)
(Continued)
17
MB3879
(Continued)
Current detection amplifier, phase vs. Frequency
Ta = +25 °C
Phase φ (deg)
AV
90
Gain AV (dB)
20
φ
VCC = 19 V
10 kΩ
1 µF
+
180
40
(35)
15
IN
17
14 −
(33) OUT
(36)
12.6 V
Current Amp2
(Current Amp3)
10 kΩ
0
0
−20
−90
−40
−180
1k
10 k
100 k
1M
10 M
Frequency f (Hz)
Power dissipation vs. Ambient temperature
Power dissipation PD (mW)
1000
900
860
800
700
600
500
400
300
200
100
0
−40
−20
0
20
40
60
80
Ambient temperature Ta ( °C)
18
+
100
MB3879
■ FUNCTIONS
1. DC/DC Converter Functions
(1) Reference voltage block (REF)
The reference voltage generator (REF) generates a temperature-compensated reference voltage from the voltage supplied from the VCC terminal (pin 1). The voltage is used as the reference voltage for Error Amp.
(2) Control bias voltage block (VB)
The control bias voltage block (VB) generates a temperature-compensated reference voltage using internal
reference voltage (5.0V Typ) from VB terminal. The voltage is used as the reference voltage for the IC’s internal
circuitry.
The reference voltage can be used to supply a load current of up to 1 mA to an external device through the VB
terminal
(3) Triangular waveform oscillator block (OSC)
The triangular wave oscillation frequency setting resistor is built in, and the triangular wave oscillation waveform
(amplitude of 1.6 V to 2.6 V) is generated by connecting the triangular wave oscillation frequency setting capacitor
with the CT terminal (pin 37) .
The triangular oscillation waveform is input to the PWM comparator on the IC.
(4) Error amplifier block (Error Amp1)
The error amplifier (Error Amp1) controls the charge current with the amplifier which outputs the PWM control
signal detecting the total current of the system current and control IC input current. It supports a wide range of
common mode input voltages from "0 V to Vcc - 1.8 V".
In addition, an arbitrary loop gain can be set by connecting a feedback resistor and capacitor from FB1 terminal
to -INE1 terminal, enabling stable phase compensation to be provided for the system.
This section also outputs signal to mode detection section.
(5) Error amplifier block (Error Amp2)
The error amplifier (Error Amp2) detects the dropping voltage of AC adapter by connecting an external resistor
to +INE2 terminal (pin 40), and outputs PWM control signals. It supports a wide range of common mode input
voltages from "0 V to Vcc - 1.8 V".
In addition, an arbitrary loop gain can be set by connecting a feedback resistor and capacitor from FB2 terminal
(pin 42) to −INE2 terminal (pin 41), enabling stable phase compensation to be provided for the system.
This block also outputs signal to mode detection block.
(6) Error amplifiers block (Error Amp3 and Error Amp4)
The error amplifiers (Error Amp3 and Error Amp4) detect the output voltages of current detection amplifiers
(Current Amp2 and Current Amp3) and compare the voltages with ones on +INE3 terminal (pin 19) and +INE4
terminal (pin 31), and then outputting PWM control signal. This block controls charge currents.
In addition, an arbitrary loop gain can be set by connecting a feedback resistor from FB3 terminal (pin 16) to INE3 terminal (pin 18) and from FB4 terminal (pin 34) to -INE4 terminal (pin 32) and capacitor, enabling stable
phase compensation to be provided for the system.
This block also outputs signal to mode detection block.
By connecting a soft-start capacitor to CS1 terminal (pin 23), an inrush current upon power supply startup is
prevented. By detecting soft-start with the error amplifier, soft-start time becomes constant, being independent
of output loads.
19
MB3879
(7) Error amplifiers block (Error Amp5 and Error Amp6)
The error amplifiers (Error Amp5 and Error Amp6) detect the DC/DC converter output voltage and outputs PWM
control signals. An on-chip output voltage setting resistor is provided on the IC, external output voltage setting
resistor is not needed. A 4-bit decoder selects output voltage among 12.6V (3 cells), 12.3V (3 cells), 16.8V (4
cells), and 16.4V (4 cells), which are applicable to NiMH batteries as well as Li-ion batteries.
In addition, an arbitrary loop gain can be set by connecting a feedback resistor and capacitor from FB5 terminal
(pin 30) to -INE5 terminal (pin 29)and from FB6 terminal (pin 20) to -INE6 terminal (pin 21), enabling stable
phase compensation to be provided for the system.
This block also outputs signal to mode detection block.
By connecting a soft-start capacitor to CS2 terminal (pin 22), an inrush current upon power supply startup is
prevented. By detecting soft-start with the error amplifier, soft-start time becomes constant, being independent
of output loads.
(8) Current detection amplifier block (Current Amp1)
The current detection amplifier (Current Amp1) detects voltage dropping occurring across the both sides of
output sense resistor (RS1) between +INC1 terminal (pin 48) and -INC1 terminal (pin 47), regarding total current
between system current and control IC input current. This block outputs the signal amplified 25 times to next
stage error amplifier (Error Amp1).
(9) Current detection amplifier block (Current Amp2 and Current Amp3)
The current detection amplifiers (Current Amp2 and Current Amp3) detect voltage dropping occurring across
the both sides of output sense resistor (RS2) between +INC2 terminal (pin 15) and IN1 terminal (pin 14), regarding
total current between system current and control IC input current. This block outputs the signal amplified 25
times to next stage error amplifier (Error Amp3).
The current detection amplifier (Current Amp3) detects voltage dropping occurring across the both sides of
output sense resistor (RS3) between +INC3 terminal (pin 35) and IN2 terminal (pin 36), and then outputs the
signal amplified 25 times to next stage error amplifier (Error Amp3).
(10) PWM comparator block (PWM Comp.)
The PWM comparator is a voltage-to-pulse width converter for controlling the output duty depending on the
output voltage of the error amplifiers. The comparator compares the triangular wave generated by the triangular
wave oscillator with the output voltage of error amplifier and voltage of DTC terminal (pin 39), and turns on Pch
MOS FET when triangular wave voltage is lower than output voltage of error amplifier and voltage of DTC terminal.
(11) Output block (OUT)
The output block is designed in the totem pole configuration, capable of driving an external P-channel
MOS FET. Output amplitude is set to "6V (typical)" at "L" level on output stage by using a voltage generated in
bias voltage block.
This feature allows higher conversion efficiency and low withstanding voltages on external Pch MOS FET even
under wide input voltage range.
(12) Bias voltage block (VH)
The Bias voltage block output a minimum voltage of output circuit, Vcc-6V (typical).
A same voltage as Vcc is output under standby status.
20
MB3879
2.
VDD Logic Block
(1) Control block (CTL)
The system is placed under standby mode by setting CTL terminal (pin 7) to "L" level (power supply current is
a maximum of 10 µA under standby mode). Setting "H" level at CTL terminal generates an internal reference
voltage, placing the system under output operation status.
After setting "L" level at CTL terminal, CTL signal reactivation time (tRCTL=2ms(Min)) is required to set the "H"
level signal.
(2) Decoder block (DEC)
By applying signals to D0 terminal (pin 2) through D3 terminal (pin 5), the 4-bit decoder section (DEC) selects
output voltage among 12.6V (3 cells), 12.3V (3 cells), 16.8V (4 cells), and 16.4V (4 cells). The voltages are
applicable not only to Li-ion batteries but also to NiMH batteries that require cancellation of output voltage control.
(See " DECODER SECTION OUTPUT VOLTAGE SETTING CODES" for details.)
(3) Mode detection block (MODE Comp.)
The mode detection block outputs which charge mode to OUT-EA1 terminal (pin 13), OUT-EA2 terminal (pin
12), OUT EC terminal (pin 11), and OUT-EV terminal (pin 10). For dynamically-controlled charging mode, OUTEA1 terminal is set to "L" level and OUT-EA2 terminal, OUT-EC terminal, and OUT-EV terminal are set to "H"
level. For Differential-charging mode, OUT-EA2 terminal is set to "L" level and OUT-EA1 terminal, OUT-EC
terminal, and OUT-EV terminal are set to "H" level. For Constant-current charge mode, OUT-EC terminal is set
to "L" level and OUT-EA1 terminal, OUT-EA2 terminal, and OUT-EV terminal are set to "H" level. For Constantvoltage charge mode, OUT-EV terminal is set to "L" level and OUT-EA1 terminal, OUT-EA2 terminal, and OUTEC terminal are set to "H" level.
Using DTC terminal (pin 39), duty setting from external device is allowed. In such a case, set all of OUT-EA1
terminal, OUT-EA2 terminal, OUT-EC terminal, and OUT-EV terminal to H level when FB terminal voltages of all
error amplifiers are higher than DTC terminal voltage.
3. Control Function
Specifies settings of "on" and "off" of outputs with setting conditions of CTL terminal (pin 7).
"On" and "off" settings of outputs
Voltage level of CTL terminal
"On/off" status of output
L
OFF (standby mode)
H
ON (operating mode)
4. Protection Functions
(1) Undervoltage lockout protection circuit block (UVLO)
The transient state or a momentary decrease in power supply voltage (VCC) or internal reference voltage (VB),
which occurs when the power supply is turned on, may cause the control IC to malfunction, resulting in breakdown
or degradation of the system.
To prevent such malfunctions, the undervoltage lockout protection circuit detects decrease of the internal reference voltage level with respect to the power supply voltage and internal reference voltage, and holds OUT
terminal (pin 24) on output terminals at "H" level. The circuit restores the output transistor to normal when the
supply voltage and internal reference voltage reach the threshold voltage of the undervoltage lockout protection
circuit.
21
MB3879
(2) Functions upon operation of protection circuit (UVLO)
The following table summarizes functions upon operation of VCCUVLO and VBUVLO (VCC or VB voltage is
below UVLO threshold voltage).
CS1
CS2
OUT
OUT-EA1
OUT-EA2
OUT-EV
OUT-EC
L
L
H
L
L
L
L
5. Soft-start Function
(1) Soft-start block (SOFT1 and SOFT2)
By connecting capacitors to CS1 terminal (pin 23) and CS2 terminal (pin 22), an inrush current upon power
supply startup is prevented. By detecting soft-start with the error amplifier, soft-start time becomes constant,
being independent of output loads of DC/DC converter.
(See "
SETTING SOFT-START TIME " for details.)
■ SETTING CHARGE CURRENT
Voltage values of +INE3 terminal (pin 19) and +INE4 terminal (pin 31) specify charge current (output limit current
value). If a current exceeding specified current value is about to flow, a charge voltage drops by the setting
current value.
+INE3 and +INE4 voltage setting
+INE3 (V) = 25 × I2 (A) × RS2 (Ω)
+INE4 (V) = 25 × I3 (A) × RS3 (Ω)
+INE3 : Voltage for setting charge current on battery 1
+INE4 : Voltage for setting charge current on battery 2
■ SETTING MAXIMUM CURRENT on AC ADAPTER
Voltage value of +INE1 terminal (pin 43) specifies charge current (output limit current value) so that total current
of system current and control IC input current does not exceed maximum current of AC adapter. If a current
exceeding specified current value is about to flow, system is placed under Differential-charging mode by the
specified current value, and charge current is reduced.
+INE1 voltage setting
+INE1 (V) = 25 × I1 (A) × RS1 (Ω)
+INE1 : Voltage for setting maximum current of AC adapter
22
MB3879
■ SETTING DETECTION VOLTAGE FOR AC ADAPTER VOLTAGE
By connecting an external resistor to +INE2 terminal (pin 40), the system is placed under Dynamically-controlled
charging mode when voltage at junction A of AC adapter input voltage (VCC) decreases below - INE2 terminal
voltage. This feature decreases charge current to keep on constant power of AC adapter.
AC adapter detection voltage setting : Vth
Vth = (R1 + R2) / R2 × −INE2
<Error Amp2>
−INE2
+INE2
VCC
R1
41
−
40
+
A
R2
■ SETTING TRIANGULAR WAVE OSCILLATION FREQUENCY
Triangular wave oscillation frequency is specified by connecting a timing capacitor (CT) to CT terminal (pin 37).
Triangular wave oscillation frequency : fOSC
fOSC (kHz) =: 30000 / CT (pF)
23
MB3879
■ DECODER BLOCK OUTPUT VOLTAGE SETTING CODES
The following summarizes decoder block output voltage setting codes :
Application
DC/DC output
voltage (V)
D0
D1
D2
D3
Number of
BATT type
< IN1, IN2 >
cells
0
0
0
0
12.3
Li-ion
3
4.1
Li3C41
0
0
0
1
12.6
Li-ion
3
4.2
Li3C42
0
0
1
0
12.3
none
none
none

0
0
1
1
12.3
none
none
none

0
1
0
0
12.3
none
none
none

0
1
0
1
12.3
none
none
none

0
1
1
0
16.4
Li-ion
4
4.1
Li4C41
0
1
1
1
16.8
Li-ion
4
4.2
Li4C42
1
0
0
0
12.3
none
none
none

1
0
0
1
12.3
none
none
none

1
0
1
0
12.3
none
none
none

1
0
1
1
12.3
none
none
none

1
1
0
0
12.3
none
none
none

1
1
0
1
Not controlled
NiMH
10 to 12

NiMH
1
1
1
0
12.3
none
none
none

1
1
1
1
12.3
none
none
none

< Functions of bits >
D0 : Selecting BATT type (Li-ion or NiMH)
D1 and D2 : Selecting the number of cells (3 Cell or 4 Cell)
D3 : Selecting charge voltage (4.1 V or 4.2 V)
24
Charge
voltage (V)
Charge
mode
symbol
MB3879
■ SETTING SOFT-START TIME
1. Setting Soft-start Time in Constant-current Mode
To prevent surge currents when the IC is turned on, you can set a soft-start by connecting a soft-start capacitor
(Cs1) to the CS1 terminal (pin 23).
Setting CTL terminal (pin 7) voltage to "H" level to activate the IC (Vcc ≥ UVLO threshold voltage), Q2 is turned
off and charging starts on soft-start capacitor (Cs1) connected to the CS1 terminal at 10 µA.
The error amplifier output (FB3 terminal (pin 16) or FB4 terminal (pin 34)) is determined by comparison between
the lower one of the potentials at two non-inverted input terminals (+INE3 terminal (pin 19) voltage (+INE4
terminal (pin 31) voltage, and CS1 terminal voltage). The FB3 (FB4) terminal voltage during the soft-start period
(CS1 terminal voltage < +INE3 (+INE4)) is therefore determined by comparison between the -INE3 (-INE4)
terminal and CS1 terminal voltages. The DC/DC converter output voltage rises in proportion to the CS1 terminal
voltage as the soft-start capacitor connected to the CS1 terminal is charged. The soft-start time is obtained
from the following equation:
Soft-start time : ts (time to output 100%)
ts (s) =: +INE3 (+INE4) / 10 (µA) × CS1 (µF)
CS1 terminal voltage
= 5.5 V
Error Amp block Comparison voltage to -INE3 (-INE4) voltage
= +INE3 V
(+INE4)
=0V
Soft-start time ts
VB
10 µA
10 µA
FB3
16
FB4
34
−INE3
18
−INE4
32
CS1
+INE3
CS1
+INE4
−
+
+
Error
Amp
23
19
31
Q2
UVLO
<Soft-start circuit>
25
MB3879
2. Setting Soft-start Time in Constant-voltage Mode
To prevent surge currents when the IC is turned on, you can set a soft-start by connecting a soft-start capacitor
(CS2) to the CS2 terminal (pin 22).
Setting CTL terminal (pin 7) voltage to "H" level to activate the IC (Vcc ≥ UVLO threshold voltage), Q2 is turned
off and charging starts on soft-start capacitor (CS2) connected to the CS2 terminal at 10 µA.
The error amplifier output (FB5 terminal (pin 30) or FB6 terminal (pin 20)) is determined by comparison between
the lower one of the potentials at two noninverting input terminals (TEST terminal (pin 28) voltage and CS2
terminal voltage). The FB5 (FB6) terminal voltage during the soft-start period (CS2 terminal voltage < TEST)
is therefore determined by comparison between the -INE5 (-INE6) terminal and CS2 terminal voltages.
The DC/DC converter output voltage rises in proportion to the CS2 terminal voltage as the soft-start capacitor
connected to the CS2 terminal is charged. The soft-start time is obtained from the following equation:
Soft-start time : ts (time to output 100%)
ts (s) =: TEST / 10 (µA) × CS2 (µF)
CS2 terminal voltage
= 5.5 V
Error Amp block Comparison voltage to -INE5 (-INE6) voltage
= TEST
=0V
Soft-start time ts
VB
10 µA
10 µA
FB5
30
FB6
20
−INE5
29
−INE6
21
CS2
TEST
CS2
−
+
+
22
28
Q2
<Soft-start circuit>
26
Error
Amp
UVLO
MB3879
■ USING WITH SHORT-CIRCUIT CS1 AND CS2 TERMINAL
By making a short circuit CS1 terminal (pin 23) and CS2 terminal (pin 22), the start-up of constant current
charging mode and constant voltage charging mode is allowed at the same time.
A capacitor to be connected must have a charging current at 20 µA.
■ TREATMENT WITHOUT USING THE CSCP TERMINAL
If the soft-start function is not used, open CS1 terminal (pin 23) and CS2 terminal (pin 22).
“Open”
22 CS2
“Open”
23 CS1
<Treatment without using the CSCP terminal>
27
MB3879
■ OPERATING SEQUENCE
1. Sequence of Normal Power Supply Startup and Charge Startup Completion
<AC adapter is connected with Battery 1 inserted>
*1 *2 *3
*4
*6 *7 *8
*5
*9
*10
*11
*12
VIN
VCC
VDD
Battery1
(Insert)
(Remove)
Battery2 (Insert)
(Remove)
tRCTL
tD0
CTL
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1 :Insert Battery 1
*2 :VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level
*3 :CTL signal is “L” level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4 :VIN and VCC rises by connecting AC adapter.
*5 :Charge voltage data is set by microprocessor.
*6 :CTL signal is turned on after data setup time (tDS) .
*7 :Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8 :Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H” level.
*9 :Shift from constant current charge control to constant voltage change control. OUT-EC = “H”level, OUT-EV = “L”level.
*10:With CTL signal “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC=“L” level.
*11:Data set after turning off CTL signal.
*12:After CTL signal set at “L” level, CTL signal reactivation time (tRCTL=2 ms (Min)) or longer time is required.
28
MB3879
2.
Sequence that Limitation (Differential Control) Activates by Input Current during Constant Current
Charging on BATT1
<AC adapter is connected with Battery 1 inserted, and exceeding input current>
*1
*2 *3
*4
*5
*6 *7
*8
*9
*10
*11
*12
*13
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
tRCTL
tD0
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Insert Battery 1
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level
*3:CTL signal is “L” level after resetting microprocessor (CTL = “HiZ”until microprocessor is reset) .
*4:VIN and VCC rises by connecting AC adapter.
*5:Charge voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H”level.
*9:Shift from constant current charge control to differential charge control by exceeding input current. OUT-EA1 = “L” level,
OUT-EC = “H” level.
*10:Returning to input current level within allowable range, shift to constant current charge control. OUT-EA1 = “H” level, OUTEC = “L” level.
*11:After CTL signal set at “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*12:Data set after turning off CTL signal.
*13:After CTL signal set at "L" level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
29
MB3879
3. Sequence that Limitation (Differential Control) Activates by Input Current during Constant
Voltage Charging on BATT1
<AC adapter is connected with Battery 1 inserted, exceeding input current>
*1 *2 *3
*4
*5
*6 *7
*8
*9
*10
*11 *12
*13
*14
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tRCTL
tD0
Reset microprocessor
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Insert Battery 1
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L”level
*3:CTL signal is “L”level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4:VIN and VCC rises by connecting AC adapter.
*5:Charge voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H”level.
*9:Shift from constant current charge control to constant voltage charge control. OUT-EC = “H”level, OUT-EV = “L”level.
*10:Shift to differential charge control by exceeding input current. OUT-EA1 = “L” level, OUT-EV = “H” level.
*11:Returning to input current level within allowable range, shift to constant voltage charge control. OUT-EA1 = “H”level,
OUT-EV = “L”level
*12:After CTL signal set at“L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*13:Data set after turning off CTL signal.
*14:After CTL signal set at“L” level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
30
MB3879
4. Sequence that Limitation (Dynamically-controlled Charging) Activates by Dropping Input
Current during Constant Current Charging on BATT1
<AC adapter is connected with Battery 1 inserted, under dropping input current>
*1 *2 *3
*4
*5
*6 *7 *8
*9
*10
*11
*12
*13
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
tRCTL
tD0
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Insert Battery 1
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level
*3:CTL signal is “L” level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4:VIN and VCC rises by connecting AC adapter.
*5:Charging voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H” level.
*9:Shift from constant current charge control to dynamically-controlled charge control due to dropping input voltage.
OUT-EA2 = “L” level, OUT-EC = “L” level
*10:Returning to input voltage level within allowable range, shift to constant current charge control. OUT-EA2 = “H” level,
OUT-EC = “L” level.
*11:After CTL signal set at “L” level. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*12:Data set after turning off CTL signal.
*13:After CTL signal set at “L” level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
31
MB3879
5. Sequence that Limitation (Dynamically-controlled Charging) Activates by Dropping Input
Voltage during Constant Voltage Charging on BATT1
<AC adapter is connected with Battery 1 inserted, under dropping input voltage>
*1 *2 *3
*4
*5
*6 *7
*8 *9
*10 *11 *12
*13
*14
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
tRCTL
tD0
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
tDS
Data
Data
Decoder output
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
*1:Insert Battery 1
OUT-EC
: Undefined
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level
*3:CTL signal is “L” level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4:VIN and VCC rises by connecting AC adapter.
*5:Charge voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H” level.
*9:Shift from constant current mode to constant voltage charge control. OUT-EC = “H” level, OUT-EV = “L” level.
*10:Shift to dynamically-controlled charge control due to dropping input voltage.
OUT-EA2 = “L” level, OUT-EV = “H” level.
*11:Returning to input voltage level within allowable range, shift to constant voltage charge control. OUT-EA2 = “H” level,
OUT-EV = “L”level
*12:After CTL signal set at “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level
*13:Data set after turning off CTL signal.
*14:After CTL signal set at “L” level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
32
MB3879
6. Sequence of Normal Power Supply Startup and Charge Startup Completion
<Battery 1 is inserted with AC adapter is connected, or with "0V" battery voltage, AC adapter is connected and
then Battery 1 is inserted>
*1 *2 *3
*4 *5
*6 *7
*8
*9
*10
*11
*12
VIN
VCC
VDD
Battery1
(Insert)
(Remove)
(Insert)
(Remove)
Battery2
tRCTL
tD0
CTL
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:VIN and VCC rises by connecting AC adapter.
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*3:CTL signal is “L” level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4:Insert Battery 1
*5:Charging voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0)
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H” level.
*9:Shift from constant current charge control to constant voltage change control. OUT-EC = “H” level, OUT-EV = “L”level.
*10:With CTL signal“L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*11:Data set after turning off CTL signal.
*12:After CTL signal set at “L” level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
33
MB3879
7. Sequence when Battery 2 (almost empty) is inserted during BATT1 is being charged
constant voltage , and shifting to constant current charge mode
<Battery 2 (almost empty) is inserted when AC adapter is connected and Battery 1 is inserted >
*1
*2 *3
*4 *5
*6 *7 *8
*9
*10
*11
*12
*13
VIN
VCC
VDD
Battery1
(Insert)
(Remove)
(Insert)
(Remove)
Battery2
tRCTL
tD0
CTL
Reset microprocessor
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
tDS
Data
Data
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Insert Battery 1.
*2:VDD rises. OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*3:CTL signal is “L” level after resetting microprocessor (CTL = “HiZ” until microprocessor is reset) .
*4:VIN and VCC rises by connecting AC adapter.
*5:Charging voltage data is set by microprocessor.
*6:CTL signal is turned on after data setup time (tDS) .
*7:Upon detecting CTL signal at “H” level, decoder data is set after data output delay time (tD0) .
*8:Shift to constant current mode. OUT-EA1, OUT-EA2, and OUT-EV = “H” level.
*9:Shift from BATT1 constant current charge control to constant voltage change control. OUT-EC = “H” level, OUT-EV = “L” level.
*10:Battery2 (almost empty) is inserted. Controlled by FB4 (BATT2 constant current charge) . OUT-EC = “L” level.
*11:With CTL signal “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*12:Data set after turning off CTL signal.
*13:After CTL signal set at “L” level, CTL signal reactivation time (tRCTL = 2 ms (Min) ) or longer time is required.
34
MB3879
8. Sequence of Normal Power Supply Shutoff and Completion of Charging
<Battery 1 is removed and then AC adapter is removed.>
*1
*2
*3
*4
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:With CTL signal “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*2:Voltages of BATT1 and BATT2 fall by removing Battery 1.
*3:VIN and VCC power supply falls by removing AC adapter.
*4:VDD falls. CTL, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = HiZ
35
MB3879
9. Sequence of Normal Power Supply Shutoff and Completion of Charging
< AC adapter is removed and then Battery 1 is removed.>
*1
VIN
*2
*3
*4
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:With CTL signal “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = “L” level.
*2:VIN and VCC power falls by removing AC adapter.
*3:Voltages of BATT1 and BATT2 falls by removing Battery 1.
*4:VDD falls. CTL, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC = HiZ
36
MB3879
10. Sequence of Normal Power Supply Shutoff and Completion of Charging
< Battery 1 and 2 are removed during charge operation.>
*1
*2
*3
VIN
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
Data Set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Stopping charge operation by removing Battery 1.
*2:With CTL signal “L” level, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC=“L” level.
*3:VDD falls. CTL, OUT-EA1, OUT-EA2, OUT-EV, and OUT-EC =HiZ
37
MB3879
11. Sequence of Normal Power Supply Shutoff and Completion of Charging
<AC adapter is removed during charge operation.>
*1
VIN
*2
VCC
VDD
Battery1
Battery2
(Insert)
(Remove)
(Insert)
(Remove)
CTL
BATT1 voltage
BATT2 voltage
D0-D3
Decoder output
Data set
FB1
(Differential-charging)
CT
FB2
(Dynamically-controlled charging)
CT
FB6
(BATT1 constant voltage)
CT
FB3
(BATT1 constant current)
CT
FB5
(BATT2 constant voltage)
CT
FB4
(BATT2 constant current)
CT
OUT-EA2
OUT-EA1
OUT-EV
OUT-EC
: Undefined
*1:Fall of VIN and VCC voltages due to removal of AC adapter. OUT-EA1, OUT-EA2, OUT-EV,
and OUT-EC = “L” level.
*2:CTL signal is “L” level.
38
MB3879
■ EQUIVALENT CIRCUIT DIAGRAM FOR CTL, D0 to D3, OUT-EA1, EA2, EV, EC TERMINALS
• CTL terminal
CTL
50 kΩ
Q1
D1
50 kΩ
• D0 to D3 terminals
VDD
D1
Q1
D0 to D3
D2
100 kΩ
Q2
VSS
• OUT-EA1 to OUT-EC terminal
VDD
Q1
D1
OUT-EA1
OUT-EA2
Q2
D2
OUT-EV
OUT-EC
VSS
39
MB3879
■ EQUIVALENT CIRCUIT DIAGRAM FOR DECODER BLOCK
VDD
D
D0
Q
DD0
CK XQ
R
D
D1
Q
DD1
CK XQ
R
D
D2
Decode
output
Decoder
Q
DD2
CK XQ
R
D
D3
Q
DD3
CK XQ
R
VDD
VDD
a point
Charging start
signal
CTL
Power
tDS
D0-D3
tD0
tRCTL
Data2
Data1
CTL
DD0-DD3
a point
Charging
start signal
Power
40
Data2 Set
Data1 Set
Data1 Load
Data2 Load
MB3879
■ NOTES ON USING REVERSE CURRENT PROTECTION DIODE
• If charging currents (I1 and I2) are imbalance under constant voltage control, voltages are controlled on the
basis of a lower battery voltage. Therefore, battery voltage on either side is higher for the potential occurring
on reverse current protection diodes (D1 and D2) and sense resistors (RS2 and RS3).
• Take notes and voltage and current characteristics of reverse current protection diodes (D1 and D2) so that
the voltage will not exceed overcharge halt voltage.
VCCO
DC-IN
25
A
B
OUT
24
I1
RS2
D1
VH
Battery 1
26
C
D
I2
RS3
D2
Battery 2
41
MB3879
■ APPLICATION CIRCUIT EXAMPLE
RS1 10 mΩ
R3
100 kΩ
R4
51 kΩ
R22
100 kΩ
R19
30 kΩ
R21
2.7 kΩ
Q3
SW2
R18
100 kΩ
R15
30 kΩ
R17
2.7 kΩ
Q2
SW1
<Current
+ Amp1>
×25
−
+
<Error Amp1>
−
+
OUT-EA1
13
<MODE
Comp.2>
+
<Error Amp2>
OUT-EA2
12
−
<MODE
Comp.3>
−
+
+
OUT-EC
11
−
<<Dynamically-Contorl>>
<MODE
Comp.4>
<<Current-Contorl>>
<Current
+ Amp2>
×25
−
<Current
+ Amp3>
×25
−
+
<Error Amp3>
<Error Amp4>
−
+
+
OUT-EV
10
−
−
+
+
C9
0.1
µF
<OUT>
+
+
+
−
Drive
OUT
24
VCC
<SOFT1>
VB
VH
26
bias
(VCC − 6 V)
Voltage
GNDO
<VH>
27
C3
0.1 µF
A
B
BATT1
12.6 V/
16.8 V
Q1
L1 22 µF
D1
23
+
+
D2
C4 C5
100 100
µF µF
RS2
75 mΩ
Battery 1
C
D
BATT2
12.6 V/
16.8 V
D3
RS3
75 mΩ
Battery 2
VIN
16 V/
19 V
R1
22.4
kΩ
R1
<<Voltage-Contorl>>
22.4 kΩ
<Error Amp5>
−INE5
C7
3300 pF
R14
51 kΩ
−
+
+
29
FB5
<UVLO>
R2
VCC
UVLO
VB
UVLO
30
R2
<Error Amp6>
−INE6
21
−
+
+
2.8 kΩ 2.8 kΩ
C15
3300 pF
3V
R3
8.4
kΩ
R3
8.4
kΩ
R27
51 kΩ
2V
FB6
20
<SOFT2>
VB
CS2
22
C14
0.022 µF
(4.2 V)
VDD
<REF>
D0
D1
2
D2 3
D3 4
5
VSS
6
<Decoder>
C19
0.1 µF
8
<Larch>
5V
(4.1 V)
<OSC>
CTL
<VB>
bias
(5 V)
CT
C10
100 pF
37
28
TEST
C8
0.1 µF
9
VB
C7
0.1 µF
42
C1 C2
10 µF10 µF
VCCO
25
<PWM
Comp>
CS1
C13
0.022 µF
<VDD>
−
FB
Voltage
Selector
R2
0Ω
(30 kΩ)
<MODE
Camp.1>
<<Differencial-Control>>
FB
Voltage
Selector
R11
30 kΩ
C20
0.1 µF
VCC
1
FB
Voltage
Selector
R10
150 kΩ
R25 −INE1
100 kΩ
44
OUTC1
45
+INC1
48
−INC1
C12
47
3300
+INE1
pF
43
R26
51 kΩ
FB1
46
FB2
42
R24
47 kΩ
C11
6800 pF
−INE2
41
R23 15 kΩ +INE2
40
DTC
39
R28 100 kΩ −INE3
18
OUTC2
C16
17
3300 pF
+INC2
A
15
R29
IN1
51
B
14
kΩ
+INE3
19
FB3
R20
16
30 kΩ
−INE4
R13 100 kΩ
32
OUTC3
C6
33
3300 pF
+INC3
35
C
R12
IN2
51
36
D
kΩ
+INE4
31
FB4
R16
34
30 kΩ
<VR>
GND
38
<CTL> 7
MB3879
■ PARTS LIST
COMPONENT
ITEM
SPECIFICATION
VENDOR
PARTS No.
Q1
Q2, Q3
FET
FET
VDS = 30 V, Qg = 43 nC (Typ)
VDS = 60 V
TOSHIBA
VISHAY SILICONIX
TPC8102
2N7002E
D1 to D3
Diode
With VF = 0.42 V (Max) and
IF = 3 A
ROHM
RB053L-30
L1
Inductor
22 µH
3.5 A,
31.6 mΩ
TDK
SLF12565T-220M3R5
C1, C2
C3
C4, C5
C6, C7
C8, C9
C10
C11
C12, C15, C16
C13,C14
C17, C19, C20
Ceramics Condenser
Ceramics Condenser
Electrolytic Condenser
Ceramics Condenser
Ceramics Condenser
Ceramics Condenser
Ceramics Condenser
Ceramics Condenser
Ceramics Condenser
Ceramics Condenser
10 µF
0.1 µF
100 µF
3300 pF
0.1 µF
100 pF
6800 pF
3300 pF
0.022 µF
0.1 µF
25 V
50 V
25 V
50 V
50 V
50 V
50 V
50 V
50 V
50 V
TDK
TDK
SANYO
MURATA
TDK
TDK
MURATA
MURATA
TDK
TDK
C3225JF1E106Z
C1608JB1H104K
25CV100AX
GRM39B322K50
C1608JB1H104K
C1608CH1H101J
GRM39B682K50
GRM39B332K50
C1608JB1H223K
C1608JB1H104K
RS1
R2
Resistor
Jumper
Resistor*
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
Resistor
10 mΩ
0Ω
30 kΩ
100 kΩ
51 kΩ
75 mΩ
150 kΩ
30 kΩ
51 kΩ
100 kΩ
30 kΩ
2.7 kΩ
100 kΩ
30 kΩ
15 kΩ
47 kΩ
100 kΩ
51 kΩ
1%
50 mΩ Max
0.5 %
0.5 %
0.5 %
1%
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
0.5 %
KOA
KOA
ssm
ssm
ssm
KOA
ssm
ssm
ssm
ssm
ssm
ssm
ssm
ssm
ssm
ssm
ssm
ssm
SL1TE10mF
RK73ZJ1J
RR0816P303D
RR0816P104D
RR0816P513D
SL1TE75mF
RR0816P154D
RR0816P303D
RR0816P513D
RR0816P104D
RR0816P303D
RR0816P272D
RR0816P104D
RR0816P303D
RR0816P153D
RR0816P473D
RR0816P104D
RR0816P513D
R3
R4
RS2,RS3
R10
R11
R12, R14
R13
R15, R16
R17, R21
R18, R22
R19, R20
R23
R24
R25, R28
R26, R27, R29
* : 30 kΩ for 4 cells
Notes : TOSHIBA : Toshiba Corporation
ROHM : ROHM CO., LTD.
TDK : TDK Corporation
SANYO : SANYO Electric Co., Ltd.
MURATA : Murata Manufacturing Co., Ltd.
KOA : KOA Corporation
ssm : SUSUMU Co., Ltd.
43
MB3879
■ REFERENCE DATA
Conversion efficiency η (%)
Conversion efficiency − Charge current
(constant voltage mode Li3C42)
100
Ta = +25 °C
VIN = 16 V
BATT charge voltage = 12.6 V
setting
BATT2 = OPEN
SW1 = SW2 = ON
η (%) = (VBATT1 × IBATT1)
/ (VIN × IIN) × 100
98
96
94
92
90
88
86
84
82
80
10 m
100 m
1
10
BATT1 charge current IBATT1 (A)
Conversion efficiency η (%)
Conversion efficiency − Charge current
(constant current mode Li3C42)
100
Ta = +25 °C
VIN = 16 V
BATT charge voltage = 12.6 V
setting
BATT2 = OPEN
SW1 = SW2 = ON
η (%) = (VBATT1 × IBATT1)
/ (VIN × IIN) × 100
98
96
94
92
90
88
86
84
82
80
0
2
4
6
8
10
12
14
16
BATT1 charge voltage VBATT1 (V)
(Continued)
44
MB3879
Conversion efficiency − Charge current
(constant current mode Li4C42)
Conversion efficiency η (%)
100
Ta = +25 °C
VIN = 19 V
BATT charge voltage = 16.8 V
setting
BATT2 = OPEN
SW1 = SW2 = ON
η (%) = (VBATT1 × IBATT1) /
(VIN × IIN) × 100
98
96
94
92
90
88
86
84
82
80
10 m
100 m
1
10
BATT1 charge current IBATT1 (A)
Conversion efficiency η (%)
Conversion efficiency − Charge current
(constant current mode Li4C42)
100
Ta = +25 °C
VIN = 19 V
BATTcharge voltage = 16.8 V
setting
BATT2 = OPEN
SW1 = SW2 = ON
η (%) = (VBATT1 × IBATT1) /
(VIN × IIN) × 100
98
96
94
92
90
88
86
84
82
80
0
2
4
6
8
10
12
14
16
18
20
BATT1 charge voltage VBATT1 (V)
(Continued)
45
MB3879
Conversion efficiency − Charge current
(constant voltage mode Li3C42)
Conversion efficiency η (%)
100
Parallel charging
98 Ta = +25 °C, VIN = 16 V
96 BATT charging voltage = 12.6 V setting
SW1 = SW2 = ON
94
η (%) = (VBATT1 × IBATT1 +
92
VBATT2 × IBATT2)
/ (VIN × IIN)
90
× 100
88 IBATT1 = IBATT2
86
84
82
80
10 m
100 m
1
10
BATT1 charge current IBATT1 (A)
Conversion efficiency η (%)
Conversion efficiency − Charge current
(constant current mode Li3C42)
100
Parallel charging
98 Ta = +25 °C
VIN = 16 V
96 BATT charging voltage = 12.6 V setting
94 SW1 = SW2 = ON
η (%) = (VBATT1 × IBATT1 + VBATT2
92
× IBATT2) / (VIN × IIN)
× 100
90
IBATT1 = IBATT2
88
86
84
82
80
0
2
4
6
8
10
12
14
16
BATT1 charge voltage VBATT1 (V)
(Continued)
46
MB3879
Conversion efficiency η (%)
Conversion efficiency − Charge current
(constant voltage mode Li4C42)
100
Parallel charging
98 Ta = +25 °C, VIN = 19 V
96 BATT charging voltage = 16.8 V setting
SW1 = SW2 = ON
94 η (%) = (VBATT1 × IBATT1 +
VBATT2 × IBATT2)
92
/ (VIN × IIN)
90
× 100
88 IBATT1 = IBATT2
86
84
82
80
10 m
100 m
1
10
BATT1 charge current IBATT1 (A)
Conversion efficiency − Charge current
(constant current mode Li4C42)
Conversion efficiency η (%)
100
Parallel charging
98 Ta = +25 °C
96 VIN = 19 V
BATT charging voltage = 16.8 V specified
94 SW1 = SW2 = ON
92 η (%) = (VBATT1 × IBATT1 +
VBATT2 × IBATT2) /
90
(VIN × IIN)
88
× 100
86 IBATT1 = IBATT2
84
82
80
0
2
4
6
8
10
12
14
16
18
20
BATT1 charge voltage VBATT1 (V)
(Continued)
47
MB3879
BATT voltage − BATT charge current
(Li3C42)
BATT1 voltage VBATT1 (V)
18
Ta = +25 °C
VIN = 16 V
BATT1 : Electric load
(Made by KIKUSUI :
PLZ-150W)
BATT2 : OPEN
16
14
12
10
Dead Battery MODE
DCC MODE
8
6
4
2
DCC : Dynamically-Controlled Charging
0
0
0.5
1
1.5
2
BATT1 charge current IBATT1 (A)
BATT voltage − BATT charge current
(Li4C42)
BATT1 voltage VBATT1 (V)
20
Ta = +25 °C
VIN = 19 V
BATT1 : Electric load
(Made by KIKUSUI :
PLZ-150W)
BATT2 : OPEN
18
16
14
12
Dead Battery MODE
10
DCC MODE
8
6
4
2
DCC : Dynamically-Controlled Charging
0
0
0.5
1
1.5
2
BATT1 charge current IBATT1 (A)
(Continued)
48
MB3879
BATT voltage − BATT charge current
(Li3C42)
BATT1 voltage VBATT1 (V)
18
Parallel charging
Ta = +25 °C
VIN = 16 V
BATT1 : Electric load
(Made by KIKUSUI :
PLZ-150W)
IBATT1 = IBATT2
16
14
12
10
Dead Battery MODE
8
DCC MODE
6
4
2
DCC : Dynamically-Controlled Charging
0
0
0.5
1
1.5
2
BATT1 charge current IBATT1 (A)
BATT voltage − BATT charge current
(Li4C42)
BATT1 voltage VBATT1 (V)
20
Parallel charging
Ta = +25 °C
VIN = 19 V
BATT1 : Electric load
(Made by KIKUSUI :
PLZ-150W)
IBATT1 = IBATT2
18
16
14
12
Dead Battery MODE
10
DCC MODE
8
6
4
2
DCC : Dynamically-Controlled Charging
0
0
0.5
1
1.5
2
BATT1 charge current IBATT1 (A)
(Continued)
49
MB3879
Switching waveform voltage mode (Li3C42)
Ta = +25 °C
VIN = 16 V
BATT1 = 20 Ω
BATT2 = OPEN
VD (V)
20
Switching waveform current mode (Li3C42)
Ta = +25 °C
VIN = 16 V
BATT1 = 8 Ω
BATT2 = OPEN
VD (V)
20
VD
VD
10
10
0
VOUT (V)
20
0
VOUT (V)
20
VOUT
10
VOUT
10
0
0
0
1
2
3
4
5
6
7
8
Switching waveform voltage mode (Li4C42)
Ta = +25 °C VIN = 19 V
BATT1 = 20 Ω
BATT2 = OPEN
VD
VD (V)
20
0
9 10
(µs)
1
2
3
4
5
6
7
8
9 10
(µs)
Switching waveform current mode (Li4C42)
Ta = +25 °C VIN = 19 V
BATT1 = 8 Ω
BATT2 = OPEN
VD
VD (V)
20
10
10
0
VOUT (V)
20
0
VOUT (V)
20
VOUT
10
10
0
0
0
1
2
3
4
5
6
7
8
9 10
(µs)
VOUT
0
1
2
3
4
5
6
7
8
9 10
(µs)
(Continued)
50
MB3879
(Continued)
Soft-start operation waveform voltage mode
(Li3C42)
VBATT1 (V) Ta = +25 °C VIN = 16 V
BATT1 = 20 Ω
15
BATT2 = OPEN
10
VBATT1
VBATT2
VBATT2 (V)
15
5
0
ts
0
2
VBATT2
10
5
10
5
0
5
9 ms
VCTL
0
Ta = +25 °C
VIN = 16 V
BATT1 = 20 Ω VBATT2 (V)
BATT2 = OPEN
15
VBATT1 (V)
VBATT1
15
10
0
VCTL (V)
5
Discharge operation waveform current mode
(Li3C42)
0
VCTL (V) VCTL
5
0
4
6
0
8 10 12 14 16 18 20
(ms)
2
4
6
8 10 12 14 16 18 20
(ms)
Soft-start operation waveform voltage mode
(Li4C42)
Discharge operation waveform current mode
(Li4C42)
VBATT1 (V)
20
VBATT1 (V)
20
15
10
Ta = +25 °C
VIN = 19 V
BATT1 = 20 Ω
BATT2 = OPEN
VBATT1
VBATT2 (V)
20
15
VBATT1
VBATT2
Ta = +25 °C
VIN = 19 V
BATT1 = 20 Ω
BATT2 = OPEN
VBATT2 (V)
20
15
10
5
10
5
10
0
5
0
5
VCTL (V)
5
ts
VBATT2
8.8 ms
VCTL
0
0
15
0
VCTL (V) VCTL
5
0
0
2
4
6
8 10 12 14 16 18 20
(ms)
0
2
4
6
8 10 12 14 16 18 20
(ms)
51
MB3879
■ NOTES ON USE
• Design ground lines on printed circuit with regard to common impedance.
• Be sure to take measures against electrostatics.
• Use static protection products or conductive containers for storing semiconductor devices.
• Use conductive bag or conductive containers for storing or carrying printed boards with semiconductor devices
mounted.
• Be sure to connect ground lines of work table, tools and measurement devices.
• Establish a ground for human body of a worker using a resistor of 250 kΩ to 1 MΩ serially connected between
the body and the ground.
• Do not apply a negative voltage.
• If a negative voltage lower than -0.3V, a parasitic transistor may appear on LSI, causing malfunction.
■ ORDERING INFORMATION
Part number
MB3879PFV
52
Package
48-pin Plastic LQFP
(FPT-48P-M05)
Remarks
MB3879
■ PACKAGE DIMENSION
48-pin Plastic LQFP
(FPT-48P-M05)
Note 1) * : These dimensions include resin protrusion.
Note 2) Pins width and pins thickness include plating thickness.
9.00±0.20(.354±.008)SQ
+0.40
+.016
*7.00 –0.10 (.276 –.004 )SQ
36
0.145±0.055
(.006±.002)
25
24
37
0.08(.003)
Details of "A" part
+0.20
1.50 –0.10
+.008
13
48
"A"
0˚~8˚
LEAD No.
1
0.50(.020)
C
(Mounting height)
.059 –.004
INDEX
0.10±0.10
(.004±.004)
(Stand off)
12
0.20±0.05
(.008±.002)
0.08(.003)
M
0.50±0.20
(.020±.008)
0.60±0.15
(.024±.006)
0.25(.010)
2002 FUJITSU LIMITED F48013S-c-5-9
Dimensions in mm (inches)
53
MB3879
FUJITSU LIMITED
All Rights Reserved.
The contents of this document are subject to change without notice.
Customers are advised to consult with FUJITSU sales
representatives before ordering.
The information and circuit diagrams in this document are
presented as examples of semiconductor device applications, and
are not intended to be incorporated in devices for actual use. Also,
FUJITSU is unable to assume responsibility for infringement of
any patent rights or other rights of third parties arising from the use
of this information or circuit diagrams.
The products described in this document are designed, developed
and manufactured as contemplated for general use, including
without limitation, ordinary industrial use, general office use,
personal use, and household use, but are not designed, developed
and manufactured as contemplated (1) for use accompanying fatal
risks or dangers that, unless extremely high safety is secured, could
have a serious effect to the public, and could lead directly to death,
personal injury, severe physical damage or other loss (i.e., nuclear
reaction control in nuclear facility, aircraft flight control, air traffic
control, mass transport control, medical life support system, missile
launch control in weapon system), or (2) for use requiring
extremely high reliability (i.e., submersible repeater and artificial
satellite).
Please note that Fujitsu will not be liable against you and/or any
third party for any claims or damages arising in connection with
above-mentioned uses of the products.
Any semiconductor devices have an inherent chance of failure. You
must protect against injury, damage or loss from such failures by
incorporating safety design measures into your facility and
equipment such as redundancy, fire protection, and prevention of
over-current levels and other abnormal operating conditions.
If any products described in this document represent goods or
technologies subject to certain restrictions on export under the
Foreign Exchange and Foreign Trade Law of Japan, the prior
authorization by Japanese government will be required for export
of those products from Japan.
F0209
 FUJITSU LIMITED Printed in Japan