FUJITSU MB3893APFT

FUJITSU SEMICONDUCTOR
DATA SHEET
DS04-27800-2E
ASSP For Power Management Applications (Mobile Phones)
Power Management IC for Mobile Phone
MB3893A
■ DESCRIPTION
MB3893A is a multi-function power management IC chip with built-in 4-channel series regulator providing the
output control functions and power supply drop detection circuits required for mobile phones. The MB3893A
includes lithium-ion battery charge control functions and functions as a built-in power management system ideal
for mobile phone devices.
■ FEATURES
[Power Supply Control Unit]
• Supply voltage range
: VCC = 3.1 V to 4.8 V
• Low power consumption current during standby
: 110 µA (Max.)
• Built-in 4-channel low-saturation voltage type series regulator
: 2.5 V/2 channels, 1.8 V/1 channels,
2.0 V/1 channels (1.9 V and 2.2 V available as mask options)
• Built-in interruption detection and supply recovery functions eliminate need for supplementary power supply
• Built-in On/Off switch circuit with accidental operation prevention function
• Accurate supply voltage drop detection
• Built-in power-on reset (OUT1) function
• Detection voltage with hysteresis
[Charge Control Unit]
• Supply voltage range
: VIN = 3.4 V to 5.9 V
• Built-in lithium-ion battery charge control functions
• Charging voltage
: 4.1 V/4.2 V (switchable)
• Built-in preliminary charging function
• Built-in re-charging function
• Built-in timer functions
• Built-in battery temperature detection function
■ PACKAGES
48-pin plastic LQFP
48-pin plastic TQFP
(FPT-48P-M05)
(FPT-48P-M24)
MB3893A
■ PIN ASSIGNMENT
(TOP VIEW)
25 : LED
26 : CONT2
27 : OUT3
28 : VCC1
29 : OUT1
30 : OUT2
31 : FULL
32 : CHARGE
33 : VBDET2
34 : VBDET1
35 : XRST
36 : ICONT
[Power Supply Control Unit]
LEDG : 37
24 : LEDEN
LEDR : 38
23 : SW1
GND2 : 39
22 : OUT4
VCC : 40
21 : VCC2
INTV : 41
20 : TEST
CVC : 42
19 : VFIL
BATSENSE : 43
18 : POFF
COSC : 44
17 : ONOFF2
ROSC : 45
16 : VCONT
[Charge Control Unit]
(FPT-48P-M05)
(FPT-48P-M24)
2
CR1 : 12
XON : 11
VREF1M : 10
ONOFF1 : 9
GND1 : 8
C1 : 7
CONT5 : 6
13 : CR2
DRST : 5
TSENSE : 48
ISENSE− : 4
14 : CONT1
ISENSE+ : 3
VREFTH : 47
CONT : 2
15 : RC1
VIN : 1
BATSEL : 46
MB3893A
■ PIN DESCRIPTION
Pin No.
Symbol
I/O
Description
1
VIN

Power supply pin for the charge control unit.
2
CONT
O
External P-ch MOS FET output control pin.
3
ISENSE+
I
Charge current detection input pin.
4
ISENSE−
I
Charge current/voltage detection input pin.
5
DRST
I
Power supply drop detection reset input pin. 100 kΩ pull-down.
6
CONT5
I
Battery voltage measurement setting pin. 100 kΩ pull-down.
7
C1
I
POR delay time setting capacitor connection pin.
8
GND1

9
ONOFF1
I
REG ON control pin. 100 kΩ pull-up: VCC (edge input)
10
VREF1M
O
Reference voltage output pin. (Power supply control unit)
11
XON
I
REG On control pin. 100 kΩ pull-up: VCC (with delay)
12
CR1
I
Power supply drop detection judgement capacitor-resistor connection pin.
13
CR2
I
Cutoff detection judgement capacitor-resistor connection pin.
14
CONT1
I
REG ON control pin. 100 kΩ pull-up: VCC
15
RC1
I
XON delay time setting capacitor-resistor connection pin.
470 kΩ pull-up: VCC (XON = LO)
16
VCONT
O
REG rise signal output pin.
17
ONOFF2
I
REG ON control pin. 100 kΩ pull-up: VCC (edge input)
18
POFF
I
REG OFF control pin. 100 kΩ pull-down (OFF)
19
VFIL
O
REG reference pin.
20
TEST

Testing auxiliary pin. (normally GND connection)
21
VCC2

REG4 power supply pin.
22
OUT4
O
REG4 output pin.
23
SW1
O
Battery voltage measurement output pin.
24
LEDEN
I
LED input pin. 100 kΩ pull-down (LEDR : “L” = ON, “H” = OFF)
25
LED
I
LED input pin. 100 kΩ pull-down (LEDG : “H” = ON, “L” = OFF)
26
CONT2
I
REG3 On/Off control pin. 470 kΩ pull-up : OUT1
27
OUT3
O
REG3 output pin.
28
VCC1

REG1, 2, 3 supply pin.
29
OUT1
O
REG1 output pin.
(2.5 V Typ.)
30
OUT2
O
REG2 output pin.
(1.8 V Typ.)
31
FULL
O
Charge state detection signal output pin. (full charge)
32
CHARGE
O
Charge state detection signal output pin. (charging)
33
VBDET2
O
Power supply drop detection output signal pin.
Ground pin.
(2.5 V Typ.)
(2.0 V Typ.)
(Continued)
3
MB3893A
4
(Continued)
Pin No.
Symbol
I/O
34
VBDET1
O
Power supply drop detection output signal pin. (10 s Typ.)
35
XRST
O
POR reset output pin.
36
ICONT
I
REG output mode switching pin. 100 kΩ pull-down
37
LEDG
O
LED output pin. (open drain)
38
LEDR
O
LED output pin. (open drain)
39
GND2

Ground pin.
40
VCC

Power supply pin for the power supply control unit
41
INTV

Internal power supply pin.
42
CVC
I
Phase compensation capacitor connection pin.
43
BATSENSE
I
Battery connection verification input pin. 100 kΩ pull-up : VIN
44
COSC
I
Oscillator frequency setting capacitor connection pin.
100 pF + 19 pF (reference capacitance)
45
ROSC
I
Oscillator frequency setting resistance connection pin.
46
BATSEL
I
Charge setting voltage switching pin.
100 kΩ pull-up : VIN (OPEN = 4.1 V, “L” = 4.2 V)
47
VREFTH
O
Temperature detection reference voltage pin
48
TSENSE
I
Temperature detection input pin.
Description
MB3893A
■ BLOCK DIAGRAM
• Overall
VCC
40
RC1
XON
POFF
CONT1
ONOFF1
ONOFF2
DRST
Power supply control unit
36
15
11
Time
constant
16
18
28
Power
supply
control
14
9
OUT
29
17
5
POR
Power
supply
detector
CR1
CR2
CONT5
VIN
35
ISENSE+
ISENSE−
CONT
CVC
ROSC
COSC
LEDR
LEDG
TSENSE
BATSENSE
BATSEL
CHARGE
FULL
LEDEN
LED
VREFTH
TEST
GND2
GND1
VCC1
OUT1
OUT
30
OUT
27
XRST
C1
OUT2
ON
REG2
26
12
13
6
Charge control unit
OUT3
ON
REG3
1
21
INTV
VCONT
ON
REG1
7
CONT2
ICONT
41
OUT
22
Initial power supply/
Power supply drop
detection circuit
34
3
VCC2
OUT4
ON
REG4
4
2
42
45
44
38
37
Charge
control
33
VBDET1
VBDET2
48
43
46
32
31
VCC
23
SW1
24
25
BGR
19
VFIL
47
20
+
−
10
VREF1M
39
8
5
MB3893A
• Charge control unit
VIN
Stabilized
power
supply
CONT
CVC
Charge status control
VREFTH
BATSEL
ROSC
COSC
OSC
LED
LED
drive1
LEDG
Constant
voltage
control
Constant
current
control
ISENSE+
ISENSE−
Thermal Shutdown
LEDEN
LED
drive2
LEDR
TIMER1
TIMER2
Battery
temperature
TSENSE
BATSENSE
FULL
Microprocessor
6
CHARGE
INTV
TEST
GND
PTC
MB3893A
■ ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
Power supply voltage
Input voltage
Power dissipation
Rating
Min.
Max.
Unit
VCC
21, 28, 40 pin
−0.3
7
V
VIN
1 pin
−0.3
15
V
VIN1
2, 37, 38, 42 to 48 pin
−0.3
VIN + 0.3
V
VIN2
3 to 7, 9 to 20, 22 to 27,
29 to 36, 41 pin
−0.3
VCC + 0.3
V
Ta ≤ +25 °C (LQFP-48P)

860*
mW
Ta ≤ +25 °C (TQFP-48P)

1230*
mW

−55
+125
°C
PD
Storage temperature
Condition
Tstg
* : The packages are 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.
■ RECOMMENDED OPERATING CONDITIONS
Parameter
Power supply voltage
REG capacitor
guarantee value
REG capacitor
ESR guarantee value
Symbol
Condition
VCC
VIN
CO
VREF1M capacitor
guarantee value
CO
Operating ambient
temperature
Ta
Unit
Min.
Typ.
Max.

3.1

4.8
V

3.4
5.3
5.9
V
0.8
1.0

µF
0.02

0.6
Ω


100
pF
−30
+25
+85
°C
OUT1 to OUT4 pin

RESR
Value
VREF1M pin

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.
7
MB3893A
■ ELECTRICAL CHARACTERISTICS
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
Reference
voltage block
Parameter
Symbol
Pin No.
VFIL
19
VO1S
Value
Unit
Min.
Typ.
Max.
VFIL = 0 mA
1.19
1.23
1.27
V
29
OUT1 = 0 to −500 µA,
ICONT = “L” level
2.41
2.50
2.59
V
VO1F
29
OUT1 = 0 to −70 mA,
ICONT = “H” level
2.41
2.50
2.59
V
Input stability
Line
29
OUT1 = 0 to −70 mA,
ICONT = “H” level


20
mV
Load stability
Load
29
OUT1 = 0 to −70 mA,
ICONT = “H” level
−30

0
mV
VIN = 0.2 Vrms,
f = 1 kHz,
OUT1 = 0 to −70 mA,
ICONT = “H” level
50


dB
VIN = 0.2 Vrms,
f = 10 kHz,
OUT1 = 0 to −70 mA,
ICONT = “H” level
50


dB


95
µVrms
100
200
400
mA
Reference voltage
Output voltage
Constant voltage control block [REG1]
Conditions
Ripple rejection
Noise
Overcurrent
protection value
R.R
29
VNOVL1
29
f = 10 Hz to 20 kHz,
VCC = 3.6 V,
OUT1 = −70 mA,
ICONT = “H” level
IL1
29
OUT1 = 90 %,
ICONT = “H” level
29
Pin 9, 14, 17 control
OUT1 = 1.0 µF,
OUT1 = 36 Ω,
OUT1 = 90 %


200
µs
29
VCC control
OUT1 = 1.0 µF,
OUT1 = 36 Ω,
OUT1 = 90 %


150
ms
tR1
Rise time
tR2
(Continued)
8
MB3893A
(Continued)
Parameter
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
Symbol
Pin No.
VO2S
30
VO2F
Input stability
Load stability
Constant voltage control block [REG2]
Noise
Overcurrent
protection value
Value
Unit
Min.
Typ.
Max.
OUT2 = 0 to −500 µA,
ICONT = “L” level
1.71
1.80
1.89
V
30
OUT2 = 0 to −50 mA,
ICONT = “H” level
1.71
1.80
1.89
V
Line
30
OUT2 = 0 to −50 mA,
ICONT = “H” level


20
mV
Load
30
OUT2 = 0 to −50 mA,
ICONT = “H” level
−30

0
mV
VIN = 0.2 Vrms,
f = 1 kHz,
OUT2 = 0 to −50 mA,
ICONT = “H” level
50


dB
VIN = 0.2 Vrms,
f = 10 kHz,
OUT2 = 0 to −50 mA,
ICONT = “H” level
50


dB


95
µVrms
Output voltage
Ripple rejection
Conditions
R.R
30
VNOVL2
30
f = 10 Hz to 20 kHz,
VCC = 3.6 V,
OUT2 = −50 mA,
ICONT = “H” level
IL2
30
OUT2 = 90 %,
ICONT = “H” level
65
130
260
mA
30
Pin 9, 14, 17 control
OUT2 = 1.0 µF,
OUT2 = 36 Ω,
OUT2 = 90 %


200
µs
30
VCC control
OUT2 = 1.0 µF,
OUT2 = 36 Ω,
OUT2 = 90 %


150
ms
tR1
Rise time
tR2
(Continued)
9
MB3893A
(Continued)
Parameter
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
Symbol
Pin No.
VO3S
27
VO3F
Input stability
Load stability
Constant voltage control block [REG3]
Noise
Overcurrent
protection value
Value
Unit
Min.
Typ.
Max.
OUT3 = 0 to −500 µA,
ICONT = “L” level,
CONT2 = “L” level
(1.81)
1.91
(2.11)
(1.90)
2.00
(2.20)
(1.99)
2.09
(2.29)
V
27
OUT3 = 0 to −70 mA,
ICONT = “H” level,
CONT2 = “L” level
(1.81)
1.91
(2.11)
(1.90)
2.00
(2.20)
(1.99)
2.09
(2.29)
V
Line
27
OUT3 = 0 to −70 mA,
ICONT = “H” level,
CONT2 = “L” level


20
mV
Load
27
OUT3 = 0 to −70 mA,
ICONT = “H” level,
CONT2 = “L” level
−30

0
mV
VIN = 0.2 Vrms,
f = 1 kHz,
OUT3 = 0 to −70 mA,
ICONT = “H” level,
CONT2 = “L” level
50


dB
VIN = 0.2 Vrms,
f = 10 kHz,
OUT3 = 0 to −70 mA,
ICONT = “H” level,
CONT2 = “L” level
50


dB


95
µVrms
Output voltage
Ripple rejection
Conditions
R.R
27
VNOVL3
27
f = 10 Hz to 20 kHz,
VCC = 3.6 V,
OUT3 = −70 mA,
ICONT = “H” level,
CONT2 = “L” level,
IL2
27
OUT3 = 90 %,
ICONT = “H” level,
CONT2 = “L” level
65
170
340
mA
27
Pin 9, 14, 17 control
OUT3 = 1.0 µF,
OUT3 = 27 Ω,
OUT3 = 90 %,
CONT2 = “L” level


200
µs
27
VCC control
OUT3 = 1.0 µF,
OUT3 = 27 Ω,
OUT3 = 90 %,
CONT2 = “L” level


150
ms
tR1
Rise time
tR2
(Continued)
10
MB3893A
(Continued)
Parameter
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
Symbol Pin No.
Constant voltage control block [REG4]
Value
Min.
Typ.
Max.
Unit
VO4S
22
OUT4 = 0 to −500 µA,
ICONT = “L” level
2.41
2.50
2.59
V
VO4F
22
OUT4 = 0 to −60 mA,
ICONT = “H” level
2.41
2.50
2.59
V
Input stability
Line
22
OUT4 = 0 to −60 mA,
ICONT = “H” level


20
mV
Load stability
Load
22
OUT4 = 0 to −60 mA,
ICONT = “H” level
−30

0
mV
VIN = 0.2 Vrms, f = 1 kHz,
OUT4 = 0 to −60 mA,
ICONT = “H” level
50


dB
VIN = 0.2 Vrms, f = 10 kHz,
OUT4 = 0 to −60 mA,
ICONT = “H” level
50


dB


95
µVrms
Output voltage
Ripple rejection
R.R
22
VNOVL4
22
f = 10 Hz to 20 kHz,
VCC = 3.6 V,
OUT4 = −60 mA,
ICONT = “H” level
IL4
22
OUT4 = 90 %,
ICONT = “H” level
80
160
320
mA
22
Pin 9, 14, 17 control
OUT4 = 1.0 µF,
OUT4 = 42 Ω,
OUT4 = 90 %


200
µs
tR2
22
VCC control
OUT4 = 1.0 µF,
OUT4 = 42 Ω,
OUT4 = 90 %


150
ms
Output voltage
VO
10
VREF1M = 0 mA,
CONT5 = “H” level
1.19
1.23
1.27
V
Output current
IO
10
CONT5 = “H” level
−1


mA
Invalid current
ICCVR
40
VREF1M = −1 mA,
VCC = 3.6 V,
CONT5 = “H” level

0.3
1.4
mA
Input stability
Line
10
VREF1M = 0 to −1 mA,
CONT5 = “H” level


20
mV
Load stability
Load
10
VREF1M = 0 to −1 mA,
CONT5 = “H” level
−30

0
mV
Noise
Overvoltage
protection value
tR1
Rise time
VREF1M
Conditions
(Continued)
11
MB3893A
(Continued)
Parameter
VREF1M
Symbol
Pin No.
Conditions
10
Value
Unit
Min.
Typ.
Max.
VIN = 0.2 Vrms, f = 1 kHz,
VREF1M = 0 to −1 mA,
CONT5 = “H” level
50


dB
10
VIN = 0.2 Vrms, f = 1 kHz,
VREF1M = 0 to −1 mA,
CONT5 = “H” level
44
49

dB
VNOVL
10
f = 10 Hz to 20 kHz,
VCC = 3.6 V,
VREF1M = 0 to −1 mA,
CONT5 = “H” level


95
µVrms
tR
10
VREF1M = 1.2 kΩ,
VREF1M = 90 %,
CONT5 = “H” level

10
30
µs
VIL
5, 6, 18,
24, 25, 26

0.0

0.3
V
VIH
5, 6, 18,
24, 25, 26

0.7 × OUT1

OUT1
V
VIL
9, 11,
14, 17

0.0

0.3 × VCC
V
VIH
9, 11,
14, 17

0.7 × VCC

VCC
V
VIL
36
Ta = −20 °C to +75 °C
0.0

0.3
V
VIH
36
Ta = −20 °C to +75 °C
1.62

OUT1
V
VOL
16
VCONT = 1 mA
0.0

0.4
V
VOH
16
VCONT = −1 mA
2.0

VCC
V
VOL
35
XRST = 20 µA
0.0

0.2
V
VOH
35
XRST = −100 µA
OUT1 − 0.2

OUT1
V
VOL
34
VBDET1 = 20 µA
0.0

0.2
V
VOH
34
VBDET1 = −20 µA
OUT1 − 0.2

OUT1
V
VOL
33
VBDET2 = 20 µA
0.0

0.2
V
VOH
33
VBDET2 = −20 µA
OUT1 − 0.2

OUT1
V
VOL
32
CHARGE = 20 µA
0.0

0.2
V
VOH
32
CHARGE = −20 µA
OUT1 − 0.2

OUT1
V
VOL
31
FULL = 20 µA
0.0

0.2
V
VOH
31
FULL = −20 µA
OUT1 − 0.2

OUT1
V
SW1 ON
resistance
RON
23
SW1 = −600 µA,
CONT5 = “H” level


500
Ω
XON delay
tXON
300
600
900
ms
Ripple rejection
Noise
Rise time
Input voltage
ON/OFF control Block
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
VCONT pin
output voltage
XRST pin
output voltage
VBDET1 pin
output voltage
VBDET2 pin
output voltage
CHARGE pin
output voltage
FULL pin
output voltage
R.R
11, 15, 16 RC1 = 1 µF
(Continued)
12
MB3893A
(Continued)
Power supply drop detection block
POR
Parameter
Symbol
Pin No.
Conditions
Detection voltage (rise)
VSH
29
Detection voltage (fall)
VSL
29
Rise delay
tPOR
29, 35
VCCE
40
VCCD
Detection
voltage
VCCF temperature
correlation
Power supply
drop detection
time
Standby supply
current
Power supply control unit overall
(Ta = −30 to +85 °C, VCC = 3.1 V to 4.8 V)
Power-on
invalid current
(receiving
standby)
Value
Unit
Min.
Typ.
Max.


2.3*

V

2.15
2.2
2.25
V
34
85
136
ms
Initial power detected
2.62
2.75
2.87
V
40
Power supply dorop detected
2.38
2.50
2.61
V
VCCR
40
Power supply recovery detected
3.35
3.50
3.65
V
VCCF
40
Initial or power supply drop
determined
Ta = +25 °C

2.0*

V
VCCt
40

−2.2

mV/ °C
tDET1
34
CR1 = 10 µF,
CR1 = 1.8 MΩ
5
10
15
s
tDET2
33
CR2 = 1.5 µF,
CR2 = 1.8 MΩ
0.75
1.5
2.25
s
40
REG1 to REG4 : OFF,
CONT5 = “L” level,
ICONT = “L” level,
VCC = 4.8 V

22
50
µA
REG3 : OFF,
CONT5 = “L” level,
ICONT = “L” level,
VCC = 4.8 V,
OUT1 = −200 µA,
OUT2 = −100 µA,
OUT4 = −100 µA,

60
110
µA

260
600
µA
ICC1
ICC2
40
C1 = 0.1 µF

Excluding OUT1, 2, 4 load current
Power-on
invalid current
(call in progress)
ICC3
40
REG1 to REG4 : ON,
CONT5 = “L” level,
ICONT = “H” level,
CONT2 = “L” level,
VCC = 4.8 V,
OUT1 = −70 mA,
OUT2 = −50 mA,
OUT3 = −70 mA,
OUT4 = −60 mA,
Excluding OUT1, 2, 4 load current
*: Standard setting value
(Continued)
13
MB3893A
(Continued)
Charge control unit
Parameter
(Ta = +3 to +48 °C, VIN = 5.3 V, BATSENESE = GND)
Symbol
Pin No.
Conditions
Value
Min.
Typ.
Max.
Unit
1
Ta = −10 °C to +60 °C,
BATSENSE = OPEN


5.5
V
1
During charging
3.4
5.3
5.9
V
VADL
1
Ta = −10 °C to +60 °C,
BATSENSE = OPEN/GND
2.70
3.05
3.40
V
VADH
1
Ta = −10 °C to +60 °C,
BATSENSE = OPEN/GND
5.9
6.2
6.5
V
Reference voltage VREFTH
47
Ta = 0 °C to +50 °C,
VREFTH = 0 to −1 mA
1.64
1.70
1.76
V
Output current
IREFTH
47
Ta = 0 °C to +50 °C
−1


mA
VBAT1
4
Ta = −10 °C to +60 °C,
BATSEL = OPEN
4.070
4.112
4.154
V
VBAT2
4
Ta = −10 °C to +60 °C,
BATSEL = “L” level
4.170
4.212
4.254
V
VBPT
4
Overvoltage stop
4.257
4.327
4.397
V
VBFT
4
Rapid charging start voltage
3.015
3.115
3.215
V
VBRC
4
Recharging start voltage
3.877
3.942
4.007
V
VBPC
4
Preliminary charging start voltage
2.015
2.115
2.215
V
∆VB
4
VBAT2 − VBRC
0.215
0.271
0.327
V
IFT
3, 4
Rapid charging current
VBFT < VBAT < VBPT,
RSENSE = 0.333 Ω
565
590
615
mA
ICMP
3, 4
Charge control current
VBFT < VBAT < VBPT,
RSENSE = 0.333 Ω
46
53
60
mA
IPC
3, 4
Preliminary charging current
VBPC < VBAT < VBFT,
RSENSE = 0.333 Ω
72
80
95
mA
3, 4
Over discharge recovery
charging current
VBAT < VBPC,
VIN = 5.6 ± 0.2 V
0.8
2.1
10.0
mA
Range of charging
operation
VIN
Low voltage stop
Over voltage stop
Output voltage
Output current
IRECO
(Continued)
14
MB3893A
(Continued)
Parameter
Symbol Pin No.
4
ROSC = 56 kΩ,
COSC = 100 pF + 19 pF,
Rapid charging
VBFT< VBAT < VBPT
216
240
264
min
4
ROSC = 56 kΩ,
COSC = 100 pF + 19 pF,
Preliminary charging
VBPC < VBAT < VBFT
14.4
16.0
17.6
min
tRECO
4
ROSC = 56 kΩ,
COSC = 100 pF + 19 pF,
Over discharge recovery
charging
VBAT < VBPC
13.5
15.0
16.5
s
Initial determination
delay
tDD
1
ROSC = 56 kΩ,
COSC = 100 pF + 19 pF,
Ta = −10 °C to +60 °C
30
45
60
ms
Full charge
determination delay
tDIC

ROSC = 56 kΩ,
COSC = 100 pF + 19 pF
78
117
156
ms
Overvoltage stop
determination delay
tBOV

ROSC = 56 kΩ,
COSC = 100 pF + 19 pF
0.30
0.46
0.62
s
Charging restart
determination delay
tRC

ROSC = 56 kΩ,
COSC = 100 pF + 19 pF
153
230
312
ms
THLT
48
VREFTH = 1.7 V,
Ta = −10 °C to +60 °C,
3 °C detected
1.154
0
1.189
3
1.223
6
V
°C
THSU
48
VREFTH = 1.7 V,
Ta = −10 °C to +60 °C,
41 °C detected (initial)
0.539
38
0.571
41
0.601
45
V
°C
THOM1
48
VREFTH = 1.7 V,
Ta = −10 °C to +60 °C,
48 °C detected
0.463
45
0.488
48
0.511
51
V
°C
THOM1
48
VREFTH = 1.7 V,
Ta = −10 °C to +60 °C,
41 °C detecxted (restart)
0.539
38
0.571
41
0.601
45
V
°C
VIL
43
Battery present
0.0

0.3 × VIN
V
VIH
43
Battery not present
0.7 × VIN

VIN
V
tFT
Timer
Charge control unit
(Ta = +3 to +48 °C, VIN = 5.3 V, BATSENESE = GND)
Value
Conditions
Unit
Min.
Typ.
Max.
tPC
Battery temperature detection
BATSENSE pin
input voltage
(Continued)
15
MB3893A
(Continued)
Parameter
VIL
46
4.2 V battery selected
0.0

0.3 × VIN
V
VIH
46
4.1 V battery selected
0.7 × VIN

VIN
V
LEDR pin ON
resistance
Ron
38
LEDR = 5 mA


80
Ω
LEDG pin ON
resistance
Ron
37
LEDG = 5 mA


80
Ω
LEDR, LEDG pin
output current
IO
37, 38


10
mA
Supply current
IVIN
1
VIN = 5.8 V,
Fast charging

1.5
3.0
mA
Leak current
ISEN
3, 4
ISENSE+ = ISENSE− = 4.8 V,
VCC = 4.8 V,
VIN = CONT = GND


1
µA
Test mode
ISENSE- pin
clamp voltage
VPR
4
BATSENSE = OPEN,
VADL < VIN < VADH,
Ta = −10 °C to +60 °C
4.75
4.88
5.01
V
2
BATSENSE = OPEN,
VADL < VIN < VADH,
VISENSE− = 2.5 V,
CONT = 10 µA


0.1
V

BATSENSE = OPEN,
external FET,
gate capacitor < 1000 pF,
Ta = −10 °C to +60 °C


100
µs
RTTOVR

BATSENSE =
GND→OPEN
or OPEN→GND,
external FET,
gate capacitor< 1000 pF,
Ta = −10 °C to +60 °C


30
ms
TH+

VADL < VIN < VADH
125

158
°C
Charge control unit
BATSEL pin input
voltage
Test mode CONT
pin voltage
Test mode
response time
BATSENSE
response time
Thermal protection
16
Symbol Pin No.
(Ta = +3 to +48 °C, VIN = 5.3 V, BATSENESE = GND)
Value
Conditions
Unit
Min.
Typ.
Max.
VTHR
RTOP

MB3893A
■ TYPICAL CHARACTERISTICS
• Power Supply Control Unit Overall
GND current vs. Power supply voltage
100
REG 1, 2, 4 = ON
REG 3 = OFF
80 ICONT = "L"
CONT5 = "L"
Ta = −30 °C
60
Ta = +25 °C
40
Ta = +85 °C
250
GND current IGND (µA)
Power supply current ICC (µA)
Power supply current vs. Power supply voltage
20
0
Ta = +25 °C
REG 1 ∼ 4 = ON
OUT1 = 36 Ω
OUT2 = 36 Ω
OUT3 = 27 Ω
OUT4 = 42 Ω
ICONT = "H"
CONT5 = "L"
200
150
100
50
0
0
1
2
3
4
0
5
1
Power supply voltage VCC (V)
2
3
4
5
Power supply voltage VCC (V)
• Reference Voltage Block
Reference voltage vs. Ambient temperature
1.4
Ta = +25 °C
1.2
Reference voltage VFIL (V)
Reference voltage VFIL (V)
Reference voltage vs. Power supply voltage
Ta = −30 °C
Ta = +85 °C
1.0
0.8
0.6
VFIL = 0.1 µF
REG 1, 2, 4 = ON
REG 3 = OFF
ICONT = "H"
CONT5 = "L"
0.4
0.2
0.0
0
1
2
3
4
5
1.27
1.26
1.25
1.24
1.23
1.22
1.21
1.2
VCC = 3.6 V
VFIL = 0.1 µF
REG 1, 2, 4 = ON
REG 3 = OFF
ICONT = "H"
CONT5 = "L"
1.19
−40
−20
0
20
40
60
80
100
Ambient temperature Ta ( °C)
Power supply voltage VCC (V)
• Constant Voltage Control Block
Output voltage vs. Ambient temperature (REG1)
3.0
VCC = 3.6 V
ICONT = "H"
2.5
2.0
Ta = +85 °C
1.5
Ta = +25 °C
Ta = −30 °C
1.0
0.5
0.0
0
50
100
150
200
250
Short output current IOS1 (mA)
300
2.59
Output voltage VOUT1 (V)
Output voltage VOUT1 (V)
Output voltage vs. Short output current (REG1)
VCC = 3.6 V
ICONT = "H"
2.57
2.55
2.53
2.51
2.49
2.47
2.45
2.43
2.41
−40
−20
0
20
40
60
80
100
Ambient temperature Ta ( °C)
(Continued)
17
MB3893A
(Continued)
−20
−30
0
Ta = +25 °C
VCC = 3.6 V (VIN = 0.2 Vrms)
VFIL = 0.1 µF
ICONT = "H"
−40
−50
−60
−70
OUT1 = 0.66 µF
OUT1 = 1.00 µF
OUT1 = 10.0 µF
−80
100
1k
10 k
100 k
1M
−10
−20
−30
−40
Ta = +25 °C
VCC = 3.6 V (VIN = 0.2 Vrms)
OUT1 = 36 Ω
VFIL = 0.1 µF
ICONT = "H"
−50
OUT1 = 1.00 µF
OUT1 = 0.66 µF
−60
OUT1 = 10.0 µF
−70
−80
100
1k
Frequency f (Hz)
VFIL = 0.1 µF
0
1
2
3
4
5
6
7
Power supply voltage VCC (V)
Output voltage VOUT1 (V)
Output voltage VOUT1 (V)
VFIL = 0.01 µF
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
VFIL = 0.001 µF
100
80
60
VFIL = 0.01 µF
40
VFIL = 0.1 µF
20
0
1µ
10 µ
100 µ
1m
10 m
Load current ILOAD (A)
100 m
120
Noise VNOVL (µVrms)
Noise VNOVL (µVrms)
120
0.0
0.5
1.0
1.5
2.0
2.5
3.0
Noise vs. VFIL capacitor (REG1)
Ta = +25 °C
VCC = 3.6 V
OUT1 = 1.0 µF
ICONT = "H"
140
OUT1
Time t (s)
Noise vs. Load current (REG1)
160
4
3
2
Ta = +25 °C
1
VCC = 3.6 V
OUT1 = 1.0 µF 0
ICONT = "H"
POFF
Time t (ms)
180
1M
Output voltage falling waveforms
(REG1 ON/OFF Control)
4
3
Ta = +25 °C
OUT1 = 1.0 µF 2
ICONT = "H"
1
0
VCC
100 k
Frequency f (Hz)
Output voltage rising waveforms
(REG1 Battery Load)
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
10 k
ON/OFF control VPOFF (V)
0
−10
Ripple rejection vs. Frequency (2) (REG1 Load)
Ripple rejection R.R (dBm)
Ripple rejection R.R (dBm)
Ripple rejection vs. Frequency (1) (REG1 No-Load)
100
80
Ta = +25 °C
VCC = 3.6 V
OUT1 = 1.0 µF
OUT2 = 36 Ω (−70 mA)
ICONT = "H"
60
40
20
0
0.001
0.01
0.1
VFIL capacitor CFIL (µF)
(Continued)
18
MB3893A
(Continued)
GND current vs. Load current (REG1)
GND current IGND (µA)
160
158
156
154
152
150
148
146
144
142
140
Ta = +25 °C
VCC = 3.6 V
REG 1, 2, 4 = ON
REG 3 = OFF
ICONT = "H"
CONT5 = "L"
0
20
40
60
80
100
Load current ILOAD (mA)
Output waveform at power supply change (1)
(REG1)
4.0
2.50
3.5
2.48
OUT1
2.46
2.44
2.42
0
5.0
Ta = +25 °C
VCC = 4 V 5 V
OUT1 = 36 Ω
ICONT = "H"
4.5
VCC
4.0
3.5
2.50
2.48
OUT1
2.46
2.44
2.42
20 40 60 80 100 120 140 160 180 200
0
20 40 60 80 100 120 140 160 180 200
t (µs)
t (µs)
Waveform at rapid change of output load (1) (REG1)
Waveform at rapid change of output load (1)
(REG1) - time axis enlarged
2.5
Ta = +25 °C
VCC = 3.6 V
OUT1 = 0 A −50 mA
ICONT = "H"
2.4
2.3
3.0
2.2
VC
2.0
1.0
0.0
0
10 20 30 40
50 60 70 80 90 100
t (µs)
OUT1
2.5
Pk - Pk
Ta = +25 °C 132 mV
VCC = 3.6 V
OUT1 = 0 A −50 mA
ICONT = "H"
2.4
2.3
2.2
3.0
VC
2.0
1.0
0.0
0
2
4
6
8
10 12 14 16 18 20
NPN collector voltage VC (V)
Pk - Pk
132 mV
OUT1
NPN collector voltage VC (V)
Output voltage VOUT1 (V)
2.6
2.6
Output voltage VOUT1 (V)
Output voltage VOUT1 (V)
4.5
Power supply voltage VCC (V)
5.0
5.5
Ta = +25 °C
VCC = 5 V 4 V
OUT1 = 36 Ω
ICONT = "H"
VCC
Output voltage VOUT1 (V)
Power supply voltage VCC (V)
5.5
Output waveform at power supply change (2)
(REG1)
t (µs)
(Continued)
19
MB3893A
(Continued)
Waveform at rapid change of output load (2) (REG1)
Waveform at rapid change of output load (2) (REG1)
- time axis enlarged
Pk - Pk
76 mV
2.4
Ta = +25 °C
VCC = 3.6 V
OUT1 = −50 mA
ICONT = "H"
2.3
2.2
0A
3.0
2.0
1.0
VC
0.0
0
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
OUT1
2.5
Pk - Pk
80 mV
Ta = +25 °C
VCC = 3.6 V
OUT1 = −50 mA 0 A
ICONT = "H"
2.4
2.3
3.0
2.2
2.0
1.0
VC
0
2
t (µs)
[Measurement Diagram for Rapid Change of Output Load]
0.0
4
6
8
10 12 14 16 18 20
NPN collector voltage VC (V)
2.5
Output voltage VOUT1 (V)
2.6
OUT1
NPN collector voltage VC (V)
Output voltage VOUT1 (V)
2.6
t (µs)
VCC = 3.6 V
VREF = 1.23 V
(IC internal)
+
REG
−
OUT
50 mA
1.0 µF VC
4V
0V
(Continued)
20
MB3893A
(Continued)
• Charge control unit
Fast charge current vs.
Ambient temperature
1.74
1.72
1.70
1.68
1.66
0
10
20
30
40
50
60
Ambient temperature Ta ( °C)
Ta = + 25 °C
VIN = 5.3 V
ISENSE− = 2.5 V
TSENSE = 0.8 V
85
80
75
70
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
65
60
55
50
−10
0
10
20
30
40
50
Ta = + 25 °C
VIN = 5.3 V
TSENSE = 0.8 V
52
50
48
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
46
44
42
40
−10
0
10
20
30
40
50
Ambient temperature Ta ( °C)
0
10
20
30
40
50
60
Ta = + 25 °C
VIN = 5.3 V
ISENSE− = 1.8 V
TSENSE = 0.8 V
3.5
3.0
2.5
2.0
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
1.5
1.0
0.5
0
10
20
30
40
50
60
Ambient temperature Ta ( °C)
Charge control current vs.
Ambient temperature
54
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
4.0
0.0
−10
60
Ambient temperature Ta ( °C)
56
Ta = + 25 °C
VIN = 5.3 V
ISENSE− = 3.5 V
TSENSE = 0.8 V
Over discharge recovery charge current vs.
Ambient temperature
Preliminary charge current vs.
Ambient temperature
90
615
610
605
600
595
590
585
580
575
570
565
−10
Ambient temperature Ta ( °C)
Over discharge recovery
charge current IRECO (mA)
Preliminary charge current IPC (mA)
1.64
−10
Charge control current ICMP (mA)
Ta = + 25 °C
VIN = 5.3 V
BATSENSE = GND
TSENSE = 0.8 V
60
Battery terminal output voltage VBAT1 (V)
Charge block reference
voltage VREFTH (V)
1.76
Fast charge current IFT (mA)
Charge control reference voltage vs.
Ambient temperature
Battery terminal output voltage vs.
Ambient temperature
4.14
4.13
4.12
4.11
4.10
4.09
4.08
4.07
4.06
4.05
4.04
−20 −10
Ta = + 25 °C
VIN = 5.3 V
TSENSE = 0.8 V
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = OPEN
0
10
20
30
40
50
60
70
Ambient temperature Ta ( °C)
(Continued)
21
MB3893A
Battery terminal output voltage vs.
Ambient temperature
4.24
4.23
4.22
4.21
4.20
4.19
4.18
4.17
4.16
4.15
4.14
−20 −10
Recharge start voltage vs. Ambient temperature
Ta = + 25 °C
VIN = 5.3 V
TSENSE = 0.8 V
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
0
10
20
30
40
50
60
70
Recharge start voltage VBRC (V)
Battery terminal output voltage VBAT2 (V)
(Continued)
4.00
3.99
3.98
3.97
3.96
3.95
3.94
3.93
3.92
3.91
3.90
3.89
3.88
−10
Ambient temperature Ta ( °C)
Ta = + 25 °C
VIN = 5.3 V
TSENSE = 0.8 V
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
0
10
20
30
40
50
60
Ambient temperature Ta ( °C)
Overvoltage stop VBPT (V)
Overvoltage stop vs. Ambient temperature
4.40
4.39
4.38
4.37
4.36
4.35
4.34
4.33
4.32
4.31
4.30
4.29
4.28
4.27
4.26
−10
Ta = + 25 °C
VIN = 5.3 V
TSENSE = 0.8 V
VREFTH − TSENSE = 10 kΩ
ROSC = 56 kΩ
COSC = 100 pF
BATSENSE = GND
BATSEL = GND
0
10
20
30
40
50
60
Ambient temperature Ta ( °C)
6
Ta = + 25 °C
BATSENSE = OPEN
5
4
3
2
1
0
0
1
2
3
LED output voltage vs. LED output current
LED output voltage VLED (V)
Power supply control unit
power supply voltage VCC (V)
Power supply control unit power supply voltage vs.
Charge control unit power supply voltage
(Transparent Mode)
4
5
6
7
8
Charge control unit power supply voltage VIN (V)
3.5
Ta = + 25 °C
3.0 VIN = 5.3 V
ISENSE− = 3.5 V
2.5
LEDR
2.0
1.5
LEDG
1.0
0.5
0.0
0
5
10
15
20
25
30
LED output current ILED (mA)
(Continued)
22
MB3893A
(Continued)
Oscillator frequency vs. Timing resistor
ROSC = 27 kΩ
Oscillator frequency fOSC (kHz)
Oscillator frequency fOSC (kHz)
Oscillator frequency vs. Timing capacitor
450
Ta = + 25 °C
VIN = 5.3 V
BATSENSE = OPEN
400
350
300
250 ROSC = 56 kΩ
200
150
100
50 ROSC = 110 kΩ
0
40
60
80
100
120
140
160
180
200
450
400
350
300 COSC
= 100 pF
250
200
150
COSC
100 = 180 pF
50
0
20
30
40
600
80
Ta = + 25 °C
70
VIN = 5.3 V
BATSENSE = OPEN 60
500
50
400
40
Fast charge time
300
30
200
20
100 Preliminary
charge time
10
0
0
0
50 100 150 200 250 300 350 400 450 500
Power dissipation vs.
Ambient temperature (LQFP-48P)
Power dissipation PD (mW)
Power dissipation PD (mW)
Oscillatory frequency fOSC (kHz)
1000
860
800
600
400
200
0
−40
−20
0
20
40
60
80
Ambient temperature Ta ( °C)
Over discharge recovery charge time tRECO (s)
Fast charge time tFT (min)
Preliminary charge - fast charge time vs.
Oscillator frequency
700
50
60
70
80
90 100 110 120
Timing resistor ROSC (kΩ)
Preliminary charge time tPC (min)
Timing capacitor COSC (pF)
800
Ta = + 25 °C
VIN = 5.3 V
BATSENSE = OPEN
COSC = 56 pF
100
Over discharge recovery charge time vs.
Oscillator frequency
45
Ta = + 25 °C
VIN = 5.3 V
BATSENSE = OPEN
40
35
30
Over discharge
recovery charge
time
25
20
15
10
5
0
0
50 100 150 200 250 300 350 400 450 500
Oscillator frequency fOSC (kHz)
Power dissipation vs.
Ambient temperature (TQFP-48P)
1000
800
710
600
400
200
0
−40
−20
0
20
40
60
80
100
Ambient temperature Ta ( °C)
23
MB3893A
■ FUNCTIONAL DESCRIPTION
1. Power Supply Control Unit
(1) Reference Voltage Block
The reference voltage circuit uses the voltage supplied from the VCC terminal (pin 40) and generates a temperature compensated reference voltage (1.23 V (Typ.)), for use as the reference voltage for the power supply control
unit.
(2) Constant Voltage Control Block (REG1)
This constant voltage control block (REG1) uses the voltage supplied from the reference voltage and generates
the output voltage (2.5 V) from the OUT1 terminal (pin 29).
An external load current can be obtained from the OUT1 terminal up to a maximum of 70 mA.
Also, by setting the ICONT terminal (pin 36) to “L” level the MB3893A can be placed in low current consumption
(standby) mode. In standby mode, REG1 is On with a maximum output load of 500 µA, and REG3 is Off. In this
state, ripple rejection and noise levels are not assured.
(3) Constant Voltage Control Block (REG2)
This constant voltage control block (REG2) uses the voltage supplied from the reference voltage and generates
the output voltage (1.8 V) from the OUT2 terminal (pin 30).
An external load current can be obtained from the OUT2 terminal up to a maximum of 50 mA.
Also, by setting the ICONT terminal (pin 36) to “L” level the MB3893A can be placed in low current consumption
(standby) mode. In standby mode, REG2 is On with a maximum output load of 500 µA, and REG3 is Off. In this
state, ripple rejection and noise levels are not assured.
(4) Constant Voltage Control Block (REG3)
This constant voltage control block (REG3) uses the voltage supplied from the reference voltage and generates
the output voltage from the OUT3 terminal (pin 27).
An external load current can be obtained from the OUT3 terminal up to a maximum of 70 mA.
Also, the output voltage can be changed to 1.9V or 2.2 V by mask option.
(5) Constant Voltage Control Block (REG4)
This constant voltage control block (REG4) uses the voltage supplied from the reference voltage and generates
the output voltage (2.5 V) from the OUT4 terminal (pin 22).
An external load current can be obtained from the OUT4 terminal up to a maximum of 60 mA.
Also, by setting the ICONT terminal (pin 36) to “L” level the MB3893A can be placed in low current consumption
(standby) mode. In standby mode, REG4 is On with a maximum output load of 500 µA, and REG3 is Off. In this
state, ripple rejection and noise levels are not assured.
(6) VREF1M
This block takes the reference voltage (1.23 V (Typ.)) generated by the reference voltage block, and uses a
voltage follower to produce a temperature compensated reference voltage (1.23 V (Typ.)) at the VREF1M terminal
(pin 10).
Also, an external load current can be obtained from the VREF1M terminal up to a maximum of 1 mA.
(7) ON/OFF Control Block
This block controls regulator On/Off switching according to the voltage levels of the POFF terminal (pin 18),
CONT2 terminal (pin 26), CONT5 terminal (pin 6), ICONT terminal (pin 36), DRST terminal (pin 5), XON terminal
(pin 11), ONOFF1 terminal (pin 9), ONOFF2 terminal (pin 17), and CONT1 terminal (pin 14).
24
MB3893A
(8) POR Block
When the output voltage from the regulator (OUT1) exceeds 2.3 V (Typ.), the XRST terminal (pin 35) goes to
“H” level following a delay time (85 ms (Typ.)) set by capacitors (0.1 µF (Typ.)) connected between the C1 terminal
(pin 7) and the GND1 terminal (pin 8) and GND2 terminal (pin 39). Also, when the regulator (OUT1) output
voltage falls below 2.2 V ((Typ.)), the XRST terminal goes back to “L” level.
(9) Initial Power Supply Drop Detection 1
This block controls MB3893A operation when VCC startup occurs at VCC voltage of 2.0V (Typ.) or greater. When
VCC voltage exceeds 2.75V (Typ.) the VCONT terminal (pin 16) voltage goes to “H” level, and the regulated
voltage is output from the OUT1 terminal (pin 29), OUT2 terminal (pin 30), and OUT4 terminal (pin 22). When
VCC voltage falls below 3.1V (Typ.), the voltage at the OUT1, OUT2, and OUT4 terminals is outside of rated
values. Then when VCC voltage falls below 2.5V (Typ.), the VCONT terminal (pin 16) voltage goes to “L” level,
and the OUT1, OUT2, and OUT4 terminals go to “L” level (regulator “OFF” state). Hereafter this is referred to
as “L” level. As long as the VCC voltage rises again before dropping below 2.0V (Typ.), the VCONT pin voltage
will return to “H” level once VCC reaches 3.5 V (Typ.), and the regulated voltage is output from the OUT1, OUT2,
and OUT4 terminals.
(10) Transient Power Supply Drop Detection 2
This block detects two types of power supply drop times according to the time constants CR1 and CR2, and
produces the related output at the VBDET1 terminal (pin 34) and VBDET2 terminal (pin 33).
2. Charge Control Block
The charge control block checks VIN, battery voltage, and battery temperature before charging. If the results
are within normal ranges, charging begins. During charging, the charging times and current levels are varied
according to battery voltage. The VIN and battery temperature are monitored, and if either exceeds the normal
range charging is stopped. Conditions are then monitored for a fixed time (16 min (Typ.)) and a resume charging/
abnormal termination determination is made.
The MB3893A also provides an overcharge protection function, as well as a function that stops charging when
a rise in IC junction temperature is detected.
Once charging has stopped due to any of these abnormal conditions, it can be resumed by re-input of VIN, or
by removing and replacing the battery.
(1) Constant Current/Constant Voltage Charging
The MB3893A applies a constant current charge according to the battery voltage level, selecting over discharge
recovery charging (2.1 mA (Typ.)), preliminary charging (80 mA (Typ.)) or rapid charging (590 mA (Typ.)). Once
battery voltage reaches 4.1 V (4.2 V), constant voltage charging is applied until the charge current falls to 53
mA (Typ.) at constant voltage.
(2) Timer Function
The timer switches the charging time according to the battery voltage level, between over discharge recovery
charging (15 s (Typ.)), preliminary charging (16 min (Typ.)), and rapid charging (240 min (Typ.)).
(3) Temperature/AC Adapter Voltage Detection
This block detects the battery temperature and AC adapter voltage, and stops charging if either is outside of the
normal charging range. If normal conditions are restored within a set time (16 min (Typ.)), charging is resumed,
otherwise an abnormal termination is determined.
(4) Over-Charge Protection
If battery voltage exceeds 4.3 V (Typ.) this block determines an abnormal condition, and stops charging.
25
MB3893A
■ SETTING THE XON DELAY TIME
When the XON terminal (pin 11) voltage changes from “H” to “L” level, the VCONT signal (pin 16) rises. The
time constant of the capacitor (CRC1) and resistor (RRC1) connected to the RC1 terminal (pin 15) determine the
delay time before the rise of the VCONT signal (pin 16).
XON delay time : tXON (ms) =: 598.3 × CRC1 (µF)
■ SETTING THE XRST DELAY TIME
The time constant of the capacitor (CC1) connected to the C1 terminal (pin 7) determines the delay time between
the rise of the OUT1 terminal (pin 29) voltage above 2.3 V (Typ.) and the rise of the XRST terminal (pin 35) voltage.
XRST delay time : tPOR (s) =: 1.23 (V) × CC1 (µF)
1.45 (µA)
■ SETTING THE POWER SUPPLY DROP DETECTION TIME
When the VCC terminal (pin 40) voltage falls below 2.0 V (Typ.) the CR1 terminal (pin 12) and CR2 terminal (pin
13) are opened, and the capacitors (CCR1, CCR2) connected to the CR1 and CR2 terminals are discharged through
the respective resistors (RCR1, RCR2). The discharge time (cutoff detection time) of the CR1 and CR2 pins can
be set according to the time constants of the capacitors and resistors connected to the CR1 and CR2 terminals
respectively, between 0.89 V (Typ.) to 0.51 V (Typ.).
Cutoff detection time : tDET1 (s) =: −CCR1 (µF) × RCR1 (MΩ) × ln (0.51 (V) /0.89 (V) )
tDET2 (s) =: −CCR2 (µF) × RCR2 (MΩ) × ln (0.51 (V) /0.89 (V) )
■ BATTERY TEMPERATURE DETECTION
The battery temperature sensor uses the thermistor shown below. The thermistor temperature coefficient is set
by the following formula.
Thermistor temperature coefficient : B =
T1 : 276 (K) = 3 ( °C)
R1 : 23.27 (kΩ)
T2 : 321 (K) = 48 ( °C)
R2 : 4.026 (kΩ)
26
lnR1 − lnR2
= 3454 (K)
1 / T1 − 1 / T2
VREFTH
10 kΩ
TSENSE
Thermistor
B = 3454 (K)
MB3893A
■ SETTING THE OSCILLATOR PERIOD
The oscillator period is set by connecting a timing capacitor (COSC) to the COSC terminal (pin 44), and a timing
resistor (ROSC) to the ROSC terminal (pin 45).
Oscillator period : tOSC (µs) =: 1.073 × 10−3 × {COSC (pF) + CP (pF) } × ROSC (kΩ)
CP : Board capacitor =: 19 (pF)
■ SETTING THE OVER DISCHARGE RECOVERY CHARGE TIME
When battery voltage is less than the preliminary charge start voltage (2.115 V (Typ.)), the over discharge
recovery charge time is set by the following formula.
Over discharge recovery charge time : tRECO (s) =: TOSC (s) × 221
■ PRELIMINARY CHARGE TIME
When battery voltage is higher than the preliminary charge start voltage (2.115 V (Typ.)), and lower than the
fast charge start voltage (3.115 V (Typ.)), the preliminary charge time is set by the following formula.
Preliminary charge time : tPC (min) =:
tOSC (s) × 227
60
■ RAPID CHARGE TIME
When battery voltage is higher then the fast charge start voltage (2.115 V (Typ.)), and lower than the overvoltage
stop voltage (4.325 V (Typ.)), the rapid charging time is determined by the following formula.
27
28
29
30
Rapid charging time : tFT (min) =: tOSC (s) × (2 + 2 + 2 + 2 )
60
27
MB3893A
■ POWER SUPPLY CONTROL UNIT TIMING CHART
1. Power Supply Drop Detection 1
As Figure 1 shows, there is a “don’t care zone” where VCC voltage is below 2 V. When VCC voltage is above
VCCE voltage (2.75 V (Typ.)), the VCONT terminal (pin 16) goes to “H” level, and after a delay time (tR) the
OUT1 terminal (pin 29), the OUT2 terminal (pin 30), and the OUT4 terminal (pin 22) output their regulated
voltages. When VCC voltage falls below VCCD voltage (2.50 V (Typ.)), a power supply drop detection is determined and the VCONT terminal goes to “L” level, and therefore the OUT1, OUT2, and OUT4 terminals also go
to “L” level. If the VCC voltage rises again before falling below 2 V, the OUT1, OUT2, and OUT4 terminals will
once again output their regulated voltages once VCC exceeds the VCCR voltage (3.50 V (Typ.))
VCCR
3.1 V
VCC
VCCE
VCCD
2.0 V ∗1
0V
VDET
(IC internal)
VCONT
tR ∗2
tR ∗2
OUT1,
OUT2,
OUT4
: Don't care zone
: Out of regulation
*1: Initial cutoff determination level
*2: tR1 < tR < tR2
Figure 1. Power Supply Cutoff Sensor 1
28
MB3893A
2. Delayed ON Input Operation (XON)
As Figure 2 shows, When the XON terminal (pin 11) changes from “H” to “L” level, the capacitor connected to
the RC1 terminal (pin 15) starts to charge. After the delay interval (tXON : 600ms (Typ.)), once the RC1 terminal
exceeds the internal threshold voltage the VCONT terminal (pin 16) goes to “H” level, and the OUT1 (pin 29),
OUT2 (pin 30), OUT3 (pin 27), and OUT4 (pin 22) terminals then output their respective regulated voltages after
a delay interval (tR1). Note however that for the OUT3 terminal to output its regulated voltage, it is necessary for
the CONT2 terminal (pin 26) to be at “L” level. Also, for the XON pin to return from “L” level to “H” level, a delay
interval (tXON : 600 ms (Typ.)) is required.
tL > tXON
XON
tXON
tXON : 600 ms (Typ.)
RC1
CONT2
RC1 charging
internal
VTH
VCC
Low
VCONT
tR1
OUT1, OUT2,
OUT3, OUT4
Reg on
Reg off
Figure 2. Delayed ON Input Operation (XON)
3. CONT1 Input Operation
As Figure 3 shows, when the CONT1 terminal (pin 14) goes from “H” to “L” level, the VCONT terminal (pin 16)
goes to “H” level, and the OUT1 (pin 29), OUT2 (pin 30), OUT3 (pin 27), and OUT4 (pin 22) terminals then output
their respective regulated voltages after a delay interval (tR1). Note however that for the OUT3 terminal to output
its regulated voltage, it is necessary for the CONT2 terminal (pin 26) to be at “L” level. Also once the OUT1,
OUT2, OUT3, and OUT4 terminals have started to output their regulated voltages, the voltage at the OUT1,
OUT2, OUT3, and OUT4 terminals will not change even if the CONT1 terminal goes from “L” to “H” level, or
from “H” level to “L” level.
CONT1
CONT2
Low
VCONT
tR1
OUT1, OUT2,
OUT3, OUT4
Reg on
Reg off
Figure 3.
CONT1 Input Operation
29
MB3893A
4. POFF Input Operation
As Figure 4 shows, once when the POFF terminal (pin 18) goes to “H” level, then after a delay interval (0 < delay
< 100 µs) the VCONT terminal (pin 16) goes to “L” level, and the OUT1 (pin 29), OUT2 (pin 30), and OUT4 (pin
22) terminals then after a delay interval (t) go to “L” level. Also, a minimum of 10 µs is required to set the POFF
signal to “H” level.
POFF
10 µs (Min.)
VCONT
0 < delay < 100 µs
t*
Reg on
OUT1,
OUT2,
OUT4
Reg off
*: t : Varies according to the output status of each regulator.
Figure 4. POFF Input Operation
5. CONT2 Input Operation
As Figure 5 shows, when the CONT2 terminal (pin 26) goes from “H” to “L” level, the OUT3 terminal (pin 27)
after a delay interval (tR1) outputs its regulated voltage. When the CONT2 terminal goes from “L” to “H” level,
then the OUT3 terminal returns to “L” level after the required fall time (t).
CONT2
tR1
Reg on
OUT3
Reg off
*: t : Varies according to the output status of the regulator.
Figure 5. CONT2 Input Operation
30
t*
Reg off
MB3893A
6. ONOFF1, 2 Input Operation
As Figure 6 shows, when the ONOFF1 terminal (pin 9) goes from “L” level to “H” level, the VCONT terminal (pin
16) goes to “H” level, and the OUT1 (pin 29), OUT2 (pin 30), OUT3 (pin 27), and OUT4 (pin 22) terminals output
their respective regulated voltages.
The next time the POFF terminal (pin 18) goes from “L” level to “H” level, the VCONT terminal (pin 16) goes to
“L” level, and the OUT1 (pin 29), OUT2 (pin 30), and OUT4 (pin 22) terminals go to “L” level. Then when the
ONOFF2 terminal (pin 17) goes from “L” level to “H” level, the VCONT terminal returns to “H” level, and the
OUT1, OUT2, OUT3 and OUT4 terminals output their respective regulated voltages.
The next time the POFF terminal goes from “L” level to “H” level, the VCONT terminal goes to “L” level, and the
OUT1, OUT2, and OUT4 terminals go to “L” level. Then when the ONOFF1 terminal goes from “L” level to “H”
level, the VCONT terminal returns to “H” level, and the OUT1, OUT2 and OUT4 terminals output their respective
regulated voltages.
The next time the POFF terminal goes from “L” level to “H” level, the VCONT terminal goes to “L” level, and the
OUT1, OUT2, and OUT4 terminals go to “L” level. Then when the ONOFF2 terminal goes from “H” level to “L”
level, the VCONT terminal returns to “H” level, and the OUT1, OUT2 and OUT4 terminals output their respective
regulated voltages.
The next time the POFF terminal goes from “L” level to “H” level, the VCONT terminal goes to “L” level, and the
OUT1, OUT2, and OUT4 terminals go to “L” level.
ONOFF1
ONOFF2
POFF
VCONT
OUT1,
OUT2,
OUT4
Figure 6. ONOFF1, 2 Input Operation
31
MB3893A
7. Power-On Reset (OUT1)
As Figure 7 shows, when the OUT1 terminal (pin 29) exceeds 2.3 V (Typ.), then after a delay interval (85 ms
(Typ.)) the XRST terminal (pin 35) goes to “H” level.
When the OUT1 terminal falls back below 2.2 V (Typ.), the XRST terminal returns to “L” level.
OUT1
XRST
POR
C1
VCONT
• OUT1 Signal Rise
OUT1
2.3 V
85 ms (Typ.)
(delay external capacitor : C1 = 0.1 µF)
XRST
• OUT1 Signal Fall
Min. : 2.15 V
Typ. : 2.2 V
Max. : 2.25 V
OUT1
XRST
Figure 7. Power-On Reset (OUT1)
32
MB3893A
8. ICONT Input Operation
As Figure 8 shows, when the VCONT terminal (pin 16) goes from “L” level to “H” level, the OUT1 terminal (pin
29) outputs its regulated voltage. Then, after a delay interval (85 ms (Typ.)) the XRST terminal (pin 35) goes to
“H” level.
If after the XRST terminal has gone to “H” level the ICONT terminal (pin 36) goes to “L” level, the MB3893A
goes into standby mode, reducing the IC internal current consumption. When the ICONT terminal returns to “H”
level normal operation is restored.
When the VCONT terminal goes from “H” level to “L” level, the OUT1 terminal goes to “L” level. At this time the
XRST terminal also goes to “L” level.
ICONT (Low = Stand-by)
STDBY (internal, High = Stand-by)
XRST
VCONT
OUT1
85 ms (Typ.)
XRST
ICONT
(Low
= Stand-by)
STDBY
(internal)
(High
= Stand-by)
ICONT
(Low
= Stand-by)
Hold > 0 µs
Setup > 100 µs
Full load current
stand-by current
stand-by current
0 mA
Regulator
Stand by
Normal
Stand by
mode
Figure 8. ICONT Input Operation
33
MB3893A
9. Power Supply Drop Detector 2 (Initial power supply detector/power supply drop detector)
a) t > 10 s
The MB3893A power supply drop detection intervals are set to tDET1 (10 s (Typ.)) and tDET2 (1.5 s (Typ.)) so that,
as shown in Figure 9(a), when VCC goes from “H” level to “L” level, the OUT1 (pin 29), OUT2 (pin 30), and OUT4
(pin 22) terminals go to “L” level, and the XRST terminal (pin 35) also goes to “L” level. At this time, the VBDET1
terminal (pin 34) and VBDET2 terminal (pin 33) also go to “L” level. When VCC drops for a fixed interval (t > 10
s), and then returns to “H” level, the OUT1, OUT2, and OUT4 terminals after a delay interval (tR2) output their
regulated voltages, and the XRST terminal after a delay interval (tPOR) goes to “H” level. During the interval
between the VCC drop and XRST terminal return to “H” level the VBDET1 terminal and VBDET2 terminal are
in undefined state. Also once the XRST terminal returns to “H” level the VBDET1 terminal is at “L” level and the
VBDET2 terminal is at “H” level. At this time, if the DRST terminal (pin 5) goes to “H” level, the VBDET1 terminal
also goes to “H” level. Note that the DRST terminal must be at “H” level for at least an interval of 10 µs.
VCC
CR1
SUPPLY DROP
DETECTOR (10 s)
VBDET1
(to µp)
DRST
t DROP
VCC
VDET
(IC internal)
DON'T CARE
tR2
tPOR
OUT1,
OUT2,
OUT4
XRST
VBDET2
DON'T CARE
VBDET1
DON'T CARE
10 µs (Min.)
DRST
Figure 9. Power Supply Drop Detector 2 (Initial power supply detector/Power supply drop detector)
a) t > 10 s
34
MB3893A
b) 1.5 < t < 0 s
The MB3893A power supply drop detection intervals are set to tDET1 (10 s (Typ.)) and tDET2(1.5 s (Typ.)) so that,
as shown in Figure 9(b), when VCC goes from “H” level to “L” level, the OUT1 (pin 29), OUT2 (pin 30), and OUT4
(pin 22) terminals go to “L” level, and the XRST terminal (pin 35) also goes to “L” level. At this time, the VBDET1
terminal (pin 34) and VBDET2 terminal (pin 33) also go to “L” level. When VCC drops for a fixed interval (1.5 s
< t < 10 s), and then returns to “H” level, the OUT1, OUT2, and OUT4 terminals after a delay interval (tR2) output
their regulated voltages, and the XRST terminal after a delay interval (tPOR) goes to “H” level. During the interval
between the VCC drop and XRST terminal return to “H” level the VBDET1 terminal and VBDET2 terminal are
in undefined state. Also once the XRST terminal returns to “H” level the VBDET1 terminal is at “H” level and the
VBDET2 terminal is also at “H” level. At this time, if the DRST terminal (pin 5) goes to “H” level, the VBDET1
and VBDET2 terminals remain at “H” level. Note that the DRST terminal must be at “H” level for at least an
interval of 10 µs.
tDROP
VCC
VDET
(IC internal)
DON'T CARE
tR2
tPOR
OUT1,
OUT2,
OUT4
XRST
VBDET2
DON'T CARE
VBDET1
DON'T CARE
10 µs (Min.)
DRST
Figure 9. Power Supply Drop Detector 2 (Initial power supply detector/Power supply drop detector)
b) 1.5 < t < 10 s
35
MB3893A
c) t < 1.5 s
The MB3893A power supply drop detection intervals are set to tDET1 (10 s (Typ.)) and tDET2 (1.5 s (Typ.)) so that, as
shown in Figure 9(c), when VCC goes from “H” level to “L” level, the OUT1 (pin 29), OUT2 (pin 30), and OUT4 (pin
22) terminals go to “L” level, and the XRST terminal (pin 35) also goes to “L” level. At this time, the VBDET1 terminal (pin 34) and VBDET2 terminal (pin 33) also go to “L” level. When VCC drops for a fixed interval (t < 1.5 s),
and then returns to “H” level, the OUT1, OUT2, and OUT4 terminals after a delay interval (tR2) output their regulated
voltages, and the XRST terminal after a delay interval (tPOR) goes to “H” level. During the interval between the VCC
drop and XRST terminal return to “H” level the VBDET1 terminal and VBDET2 terminal are in undefined state. Also
once the XRST terminal returns to “H” level the VBDET1 terminal is at “H” level and the VBDET2 terminal is at “L”
level. At this time, if the DRST terminal (pin 5) goes to “H” level, the VBDET2 terminal goes to “H” level. Note that
the DRST terminal must be at “H” level for at least an interval of 10 µs.
VCC
CR2
SUPPLY DROP
DETECTOR (1.5 s)
VBDET2
(to µp)
DRST
tDROP
VCC
VDET
(IC internal)
DON'T CARE
tR2
tPOR
OUT1,
OUT2,
OUT4
XRST
VBDET2
DON'T CARE
VBDET1
DON'T CARE
10 µs (Min.)
DRST
Figure 9. Power Supply Drop Detector 2 (Initial power supply detector/Power supply drop detector)
c) t < 1.5 s
36
MB3893A
■ CHARGE CONTROL UNIT OPERATION FLOWCHART
Start
Recovery condition: VIN re-input or remove/replace battery
Check battery
Reset
Check VIN
3.05 V to 6.20 V
OSC
Normal
timer
Check temperature
TBATT = +3 °C to +41 °C
Judge
charging
45 ms
TBATT < +3 °C or
+41 °C < TBATT
,,,
,,,
,,,
,,,
Stop charging
15 s
VBAT < 2.115 V
Charge at 2.1mA *1
16 min
Abnormal
condition
2.115 V < VBAT < 3.115 V
Charge at 80mA *2
(77.9 mA + 2.1 mA)
Resume
charging,
Restart timer
240 min
3.115 V < VBAT < 3.935 V
< 16 min
Charge at 590mA
3.935 V < VBAT< 4.215 V
(4.115 V)
,,,,,,
,,,,,,
VBAT = 4.215 V (4.115 V)
I = 53 mA
Stop charging
TBATT < +3 °C or
+48 °C < TBATT
16 min
over
Wait
Start
charging
standby
timer
(16 min)
VIN < 3.05 V
or 6.2 V < VIN
Stop charging,
Stop timer
117 ms
VBAT > 4.325 V
or Thermal protection
230 ms
VBAT< 3.935 V
,,,,,,,
,,,,,,,
,,,,,,,
0.46 s
Normal end
TBATT: Battery temperature
*1 : The 2.1 mA current is supplied from the IC internally
*2 : The 80 mA current is supplied from the external P-ch MOSFET (77.9 mA) plus the IC internal
current of 2.1 mA.
37
MB3893A
■ CHARGE CONTROL UNIT LED OPERATION TABLE
• FULL, CHARGE, LEDR Operation Table
Switch
Signal pin
FULL
CHARGE
OUT1
ON
ON
ON
ON/OFF
LEDEN


H
L
VIN OFF
H
H


VIN ON, BATSENSE open
H
H
H
H
Over discharge recovery charging 2.1 mA



L
Preliminary charging 80 mA
H
L
H
L
Rapid charging 590 mA
H
L
H
L
Charging completed
L
H
H
H
3.935 V recharging
H
L
H
L
2.1 mA



H
80 mA
H
H
H
H
590 mA
H
H
H
H
2.1 mA



H
80 mA
H
H
H
H
590 mA
H
H
H
H
2.1 mA



H
80 mA
H
H
H
H
590 mA
H
H
H
H
2.1 mA



H
80 mA
H
H
H
H
590 mA
H
H
H
H
15 s Time out



L↔H
16 min Time out
H
L↔H
H
L↔H
VCC < 3.935 V
240 min Time out
H
L↔H
H
L↔H
VCC > 3.935 V
240 min Time out
L
H
H
H
VCC > 4.325 V
H
L↔H
H
L↔H
Operating condition
No operation
Temperature detection
3 °C or lower
Temperature detection
41 °C or 48 °C or greater
VIN Low < 3.05 V
VCC < VIN
VIN High > 6.20 V
Battery abnormal
LEDR
LEDR, CHARGE = L↔H : Blinking, LEDR = L : ON, H : OFF
LEDEN, FULL, CHARGE : Power supply is OUT1, therefore undefined when OUT1 = OFF.
OUT1=OFF during over discharge recovery charging (2.1 mA) and 15 s time out
38
MB3893A
• LEDG Operation Table
LED
LEDG
L
H
H
L
LEDG = L : ON, H : OFF
LED, LEDG: Power supply is OUT1, therefore undefined when OUT1 = OFF.
■ ABOUT CAPACITOR CONNECTED TO VCC PIN
When the VCC voltage exceeds 2.75 V (Typ.), the VCONT terminal (pin 16) goes to “H” level, and the OUT1
(pin 29), OUT2 (pin 30), and OUT4 (pin 22) terminals rise. When each of these respective OUT terminals rises,
a rush current flows to the capacitor connected to that OUT terminal. At this time the internal impedance of the
battery causes VCC to drop, and if VCC voltage goes below 2.5 V (Typ.), the OUT terminal voltage regurns to
“L” level (regulator OFF mode).t is necessary to set the capacitor connected between VCC and GND taking into
consideration the internal impedance of the battery, so that the VCC drop does not go below 2.5 V.
39
MB3893A
■ APPLICATION EXAMPLE
C1
2.2 µF
40
VCC1 28
VCC
OUT1 29
11 XON
OUT2 30
C13
1 µF
15 RC1
OUT3 27
36 ICONT
C2
1 µF
C3
1 µF
C4
1 µF
VCC2 21
18 POFF
OUT4 22
14 CONT1
C5
1 µF
VCONT 16
26 CONT2
VFIL 19
C1 7
23 SW1
CR1 12
10 VREF1M
CR2 13
35 XRST
C6
0.1 µF
C7
0.1 µF
C8
10 µF
R1
1.8 MΩ
C9
1.5 µF
R2
1.8 MΩ
ROSC 45
R3
56 kΩ
34 VBDET1
33 VBDET2
COSC 44
6 CONT5
VIN 1
5 DRST
19 pF
C10
100 pF
* Board capacitor =: 19 pF
C11
1 µF
Q1
Si3441DV
CONT 2
9 ONOFF1
D1
CRS03
17 ONOFF2
25 LED
ISENSE+ 3
24 LEDEN
ISENSE− 4
CVC 42
31 FULL
R4
0.333 Ω
C12
0.033 µF
BATSEL 46
32 CHARGE
VREFTH 47
PTC
38 LEDR
TSENSE 48
37 LEDG
BATSENSE
41 INTV
GND1
8
TEST
20
GND2
39
43
Si3441DV : VISHAY Intertechnology, Inc.
CRS03
: TOSHIBA CORPORATION
40
MB3893A
■ USAGE PRECAUTIONS
1. Never use settings exceeding maximum rated conditions.
Exceeding maximum rated conditions may cause permanent damage to the LSI.
Also, it is recommended that recommended operating conditions be observed in normal use.
Exceeding recommended operating conditions may adversely affect LSI reliability.
2. Use this device within recommended operating conditions.
Recommended operating conditions are values within which normal LSI operation is warranted. Standard electrical characteristics are warranted within the range of recommended operating conditions and within the listed
conditions for each parameter.
3. Printed circuit board ground lines should be set up with consideration for common impedance.
4. Take appropriate static electricity measures.
•
•
•
•
Containers for semiconductor materials should have anti-static protection or be made of conductive material.
After mounting, printed circuit boards should be stored and shipped in conductive bags or containers.
Work platforms, tools, and instruments should be properly grounded.
Working personal should be grounded with resistance of 250 kΩ to 1 MΩ between body and ground.
5. Do not apply negative voltages.
The use of negative voltages below –0.3 V may create parasitic transistors on LSI lines, which can cause
abnormal operation.
■ ORDERING INFORMATION
Part number
Package
MB3893APFV
48-pin plastic LQFP
(FPT-48P-M05)
MB3893APFT
48-pin plastic TQFP
(FPT-48P-M24)
Remarks
41
MB3893A
■ PACKAGE DIMENSIONS
48-pin plastic LQFP
(FPT-48P-M05)
Note: Pins width and pins thickness includes plating thickness.
9.00±0.20(.354±.008)SQ
7.00±0.10(.276±.004)SQ
36
25
37
24
0.08(.003)
INDEX
Details of "A" part
+0.20
1.50 –0.10
48
13
+.008
(Mounting height)
.059 –.004
"A"
LEAD No.
1
0.50±0.08
(.020±.003)
12
+0.08
0.18 –0.03
.007
+.003
–.001
0.08(.003)
M
0.145±0.055
(.006±.002)
0~8°
0.50±0.20
(.020±.008)
0.45/0.75
(.018/.030)
C
0.10±0.10
(.004±.004)
(Stand off)
0.25(.010)
2000 FUJITSU LIMITED F48013S-3C-7
Dimensions in mm (inches)
(Continued)
42
MB3893A
(Continued)
48-pin plastic TQFP
(FPT-48P-M24)
9.00±0.20(.354±.008)
7.00±0.15(.276±.006)
1.00±0.10
(.039±.004)
1.10±0.10
(.043±.004)
0.10±0.10
(.004±.004)
"A"
0.10(.004)
Details of "A" part
3.50°±0.20
(3.50°±.008)
0.18(.007)
C
0.50(.020)
0.127±0.01
(.0050±.0004)
0.50±0.20
(.020±.008)
2000 FUJITSU LIMITED F48042S-1C-1
Dimensions in: mm (inches)
43
MB3893A
FUJITSU LIMITED
For further information please contact:
Japan
FUJITSU LIMITED
Corporate Global Business Support Division
Electronic Devices
Shinjuku Dai-Ichi Seimei Bldg. 7-1,
Nishishinjuku 2-chome, Shinjuku-ku,
Tokyo 163-0721, Japan
Tel: +81-3-5322-3347
Fax: +81-3-5322-3386
http://edevice.fujitsu.com/
North and South America
FUJITSU MICROELECTRONICS, INC.
3545 North First Street,
San Jose, CA 95134-1804, U.S.A.
Tel: +1-408-922-9000
Fax: +1-408-922-9179
Customer Response Center
Mon. - Fri.: 7 am - 5 pm (PST)
Tel: +1-800-866-8608
Fax: +1-408-922-9179
http://www.fujitsumicro.com/
Europe
FUJITSU MICROELECTRONICS EUROPE GmbH
Am Siebenstein 6-10,
D-63303 Dreieich-Buchschlag,
Germany
Tel: +49-6103-690-0
Fax: +49-6103-690-122
http://www.fujitsu-fme.com/
Asia Pacific
FUJITSU MICROELECTRONICS ASIA PTE. LTD.
#05-08, 151 Lorong Chuan,
New Tech Park,
Singapore 556741
Tel: +65-281-0770
Fax: +65-281-0220
http://www.fmap.com.sg/
Korea
FUJITSU MICROELECTRONICS KOREA LTD.
1702 KOSMO TOWER, 1002 Daechi-Dong,
Kangnam-Gu,Seoul 135-280
Korea
Tel: +82-2-3484-7100
Fax: +82-2-3484-7111
F0012
 FUJITSU LIMITED Printed in Japan
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 contents of this document may not be reproduced or copied
without the permission of FUJITSU LIMITED.
FUJITSU semiconductor devices are intended for use in standard
applications (computers, office automation and other office
equipments, industrial, communications, and measurement
equipments, personal or household devices, etc.).
CAUTION:
Customers considering the use of our products in special
applications where failure or abnormal operation may directly
affect human lives or cause physical injury or property damage, or
where extremely high levels of reliability are demanded (such as
aerospace systems, atomic energy controls, sea floor repeaters,
vehicle operating controls, medical devices for life support, etc.)
are requested to consult with FUJITSU sales representatives before
such use. The company will not be responsible for damages arising
from such use without prior approval.
Any semiconductor devices have inherently a certain rate 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 Control Law of Japan, the
prior authorization by Japanese government should be required for
export of those products from Japan.