FUJITSU MB3817_03

FUJITSU SEMICONDUCTOR
DATA SHEET
DS04-27216-4E
ASSP For Power Supply Applications
BIPOLAR
Switching Regulator Controller
MB3817
■ DESCRIPTION
The MB3817 is a pulse width modulator (PWM) type switching regulator controller IC designed for low-voltage
and high-speed operation. This can be used in applications as down-conversion or down/up-conversion (Zeta
method) .
With fewer external components and faster operating speed, the MB3817 enables reduction in power supply unit
size, making it ideal for use with internal power supplies in compact, high-performance portable devices.
■ FEATURES
•
•
•
•
•
•
•
•
•
Wide range of operating power supply voltages : 2.5 V to 18 V
Built-in high-precision reference voltage generator : 1.5 V ± 2%
High speed operation is possible : Max 500 kHz
Wide input voltage range of error amplifier : 0 V to VCC − 0.9 V
Built-in soft start function
Built-in timer/latch-actuated short-circuiting protection circuit
Totem-pole type output with adjustable on/off current (for PNP transistors)
Built-in standby function
Small package : SSOP-16P (FPT-16P-M05)
■ PACKAGE
16-pin Plastic SSOP
(FPT-16P-M05)
MB3817
■ PIN ASSIGNMENT
(TOP VIEW)
CT
1
16
VREF
RT
2
15
CTL
+IN
3
14
CSCP
−IN
4
13
CS
FB
5
12
GND
DTC
6
11
VE
CB1
7
10
OUT
CB2
8
9
VCC
(FPT-16P-M05)
2
MB3817
■ PIN DESCRIPTION
Pin no.
Pin name
I/O
Descriptions
1
CT

This terminal connects to a capacitor for setting the triangular-wave frequency.
2
RT

This terminal connects to a resistor for setting the triangular-wave frequency.
3
+IN
I
Error amplifier non-inverted input terminal
4
−IN
I
Error amplifier inverted input terminal
5
FB
O
Error amplifier output terminal
6
DTC
I
Dead time control terminal
7
CB1

Boot capacitor connection terminal
8
CB2

Boot capacitor connection terminal
9
VCC

Power supply terminal
10
OUT
O
Totem-pole type output terminal
11
VE

Output current setting terminal
12
GND

Ground terminal
13
CS

Soft start setting capacitor connection terminal
14
CSCP

Short detection setting capacitor connection terminal
15
CTL
I
Power supply control terminal
When this terminal is High, IC is inactive state
When this terminal is Low, IC is standby state
16
VREF
O
Reference voltage output terminal
3
MB3817
■ BLOCK DIAGRAM
CB1
OUT
7
FB
8
5
−IN
+IN
DTC
CB2
4
Error
− Amp.
3
+
PWM
+ Comp.
+
+
−
OFF
current
setting
block
9
VCC
Q4
10
6
OUT
CS
CS
13
Q6
1 µA
Soft Start
−
Comp.
+
Q1
(0.9 V)
−
D1
(0.5 V)
Q5
SCP
Comp.
11
VE
+
1.5 V
SCP
1 µA
−1.4 V
−1.0 V
RS
Latch
OSC
1
2
CT
4
bias
RT
bias
UVLO
Q2
Q3
VCC
Power
Ref
(1.5 V) ON/OFF
14
16
CSCP VREF
12
GND
15
CTL
MB3817
■ ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
Condition
Power supply voltage
VCC
Power dissipation
Storage temperature
Rating
Unit
Min
Max


20
V
PD
Ta ≤ +25 °C

440*
mW
Tstg

−55
+125
°C
* : The package is mounted on the 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
Symbol
Condition
Power supply voltage
VCC
Reference voltage output
current
Value
Unit
Min
Typ
Max

2.5
6.0
18
V
IOR

−1

0
mA
Error amp. input voltage
VIN

0

VCC − 0.9
V
Control input voltage
VCTL

0

18
V
Output current
IO

3

30
mA
Timing capacitance
CT

150

1500
pF
Timing resistance
RT

5.1

100
kΩ
Oscillation frequency
fOSC

10
200
500
kHz
Soft start capacitance
CS


0.1
1.0
µF
CSCP


0.1
1.0
µF
Boot capacitance
CB



0.1
µF
Operating temperature
Ta

−40
+25
+85
°C
Short detection capacitance
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.
5
MB3817
■ ELECTRICAL CHARACTERISTICS
(VCC = 6 V, Ta = +25 °C)
Symbol
Pin
no.
Condition
VREF
16
∆VREF/
VREF
Input stability
Load stability
Parameter
Typ
Max

1.47
1.50
1.53
V
16
Ta = −40°C to +85°C

0.5*

%
Line
16
VCC = 2.5 V to 18 V

2
10
mV
Load
16
IOR = 0 mA to −1 mA

2
10
mV
IOS
16
VREF = 1 V
−10
−5
−2
mA
VTH
13
VCC =

2.0
2.3
V
VTL
13
VCC =
1.5
1.8

V
VH
13

0.1
0.2

V
VR
13

0.6
1.0

V
VT0
10
Duty cycle = 0%
0.9
1.0

V
VT100
10
Duty cycle = 100%

1.4
1.5
V
Input standby
voltage
VSTB
13


50
100
mV
Charge current
ICHG
13

−1.4
−1.0
−0.6
µA
Threshold voltage
VTH
14

0.60
0.65
0.70
V
Input standby
voltage
VSTB
14


50
100
mV
Input latch voltage
VI
14


50
100
mV
Input source current
II
14

−1.4
−1.0
−0.6
µA
Oscillator frequency
fOSC
10
CT = 330 pF
RT = 6.2 kΩ
450
500
550
kHz
Frequency voltage
stability
∆f/fdv
10
VCC = 3.6 V to 16 V

1
10
%
Frequency
temperature stability
∆f/fdt
10
Ta = −40°C to +85°C

1*

%
Output temperature
stability
Short circuit output
current
Under voltage
Threshold voltage
lockout
protection
Hysteresis width
section (UVLO)
Reset voltage
Threshold voltage
Soft start
section (CS)
Short circuit
detection
section (SCP)
Triangular
waveform
oscillator
section (OSC)
Unit
Min
Output voltage
Reference
section (Ref)
Value
* : Standard design value.
(Continued)
6
MB3817
(Continued)
(VCC = 6 V, Ta = +25 °C)
Parameter
Symbol
Pin
no.
Condition
Value
Min
Typ
Max
Unit
Input offset voltage
VIO
3, 4 VFB = 1.2 V


10
mV
Input offset current
IIO
3, 4 VFB = 1.2 V


100
nA
Input bias current
II
3, 4 VFB = 1.2 V
−200
−100

nA
0

VCC −
0.9
V
Common mode
input voltage range

VCM
3, 4
CMRR
5
DC
60
100

dB
Voltage gain
AV
5
DC
60
100

dB
Frequency
bandwidth
BW
5
AV = 0 dB

800*

kHz
VOM+
5

1.8
2.0

V
OM−
5


50
500
mV
Output sink current
O+
I
5
VFB = 1.2 V
60
120

µA
Output source
current
IO−
5
VFB = 1.2 V

−2.0
−0.6
mA
VT0
10
Duty cycle = 0%
0.9
1.0

V
VT100
10
Duty cycle = 100%

1.4
1.5
V
ON duty cycle
Dtr
10
VDTC = VREF × 0.88
CT = 330 pF,
RT = 6.2 kΩ
70
80
90
%
Input current
IDTC
6
VDTC = 0 V
−500
−250

nA
VT0
10
Duty cycle = 0%
0.9
1.0

V
VT100
10
Duty cycle = 100%

1.4
1.5
V
Input sink current
I+
I
5

60
120

µA
Input source current
II−
5


−2.0
−0.6
mA
Output sink current
IO+
10
RE = 15 kΩ
18
30
42
mA
Output source
current
IO−
10
Duty ≤ 5 %

−100
−50
mA
Standby leakage
current
ILO
10
VCC = 18 V,
VO = 18 V


10
µA
Input on condition
VON
11

2.1

18
V
Input off condition
VOFF
11

0

0.7
V
II
15
VCTL = 5 V

100
200
µA
Standby current
ICCS
9
VCTL = 0 V


10
µA
Power supply current
ICC
9
Output “H”

2.7
4.0
mA
Error amp.
section (Error
Amp.)
Common mode
rejection ratio
Maximum output
voltage width
Threshold voltage
Dead time
control section
(DTC)
PWM
comparator
section (PWM
Comp.)
Output section
(OUT)
Control section
(CTL)
Threshold voltage
Input current
V
* : Standard design value.
7
MB3817
■ TYPICAL CHARACTERISTICS
Power supply current vs. power supply voltage
2.0
Ta = +25 °C
Reference voltage VREF (V)
Power supply current ICC (mA)
5
Reference voltage vs. power supply voltage
4
3
2
1
Ta = +25 °C
IOR = 0 mA
1.5
1.0
0.5
0.0
0
0
2
4
6
8
10 12 14 16
Power supply voltage VCC (V)
18
0
20
2
4
6
8
10 12 14 16
Power supply voltage VCC (V)
18
20
Reference voltage vs. ambient temperature
1.55
VCC = 6 V
IOR = 0 mA
Reference voltage VREF (V)
1.54
1.53
1.52
1.51
1.50
1.49
1.48
1.47
1.46
1.45
−60
−40
−20
0
20
40
60
80
100
Ambient temperature Ta (°C)
Control current vs. control voltage
Reference voltage vs. control voltage
500
Reference voltage VREF (V)
Control current ICTL (µA)
VCC = 6 V
Ta = +25 °C
IOR = 0 mA
1.7
1.6
1.5
1.4
VCC = 6 V
Ta = +25 °C
400
300
200
100
1.3
0
0
1
2
3
Control voltage VCTL (V)
4
5
0
4
8
12
16
20
Control voltage VCTL (V)
(Continued)
8
Triangular wave frequency fOSC (Hz)
Triangular wave frequency vs.
timing resistance
10 M
VCC = 6 V
Ta = +25 °C
1M
100 k
CT = 150 pF
CT = 1500 pF
10 k
CT = 15000 pF
1k
1k
10 k
100 k
1M
Timing resistance RT (Ω)
Triangular wave maximum amplitude voltage VCT (V)
MB3817
Triangular wave maximum amplitude voltage vs.
timing capacitance
1.8
1.4
1.2
1.0
0.8
0.6
10
103
105
104
Triangular wave cycle vs. timing capacitance
1000
Triangular wave cycle tOSC (µs)
100
80
VCC = 6 V
Ta = +25 °C
RT = 6.2 kΩ
VDTC = VREF × 0.88
60
40
20
100
VCC = 6 V
Ta = +25 °C
RT = 6.2 kΩ
10
1
0.1
1k
10 k
100 k
1M
102
10
10 M
103
104
105
Timing capacitance CT (pF)
Triangular wave frequency fOSC (Hz)
Frequency stability vs. ambient temperature
10.00
Frequency stability (%)
Duty Dtr (%)
102
Timing capacitance CT (pF)
Duty vs. triangular wave frequency
0
VCC = 6 V
Ta = +25 °C
RT = 6.2 kΩ
1.6
VCC = 6 V
fOSC = 500 kHz
(CT = 330 pF, RT = 6.2 kΩ)
5.00
0.00
−5.00
−10.00
−60
−40
−20
0
20
40
60
80
100
Ambient temperature Ta (°C)
(Continued)
9
MB3817
(Continued)
Error amp. frequency
50
Ta = +25 °C
40
180
30
135
φ
10
VCC = 6 V
11 kΩ
90
45
AV
0
φ (deg)
AV (dB)
20
• Measurement circuit
225
0
−10
−45
−20
−90
−30
−135
−40
−180
−50
1k
10 k
100 k
240 kΩ
2.4 kΩ
− +
4
−
3
+
10 µF
5
VREF
11 kΩ
Error Amp.
−225
10 M
1M
Frequency fOSC (Hz)
1.0
500
VCC = 6 V
Ta = +25 °C
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
−10
−20
−30
−40
Output current setting pin current IE (mA)
10
Power dissipation vs. ambient temperature
Power dissipation PD (mW)
Output current setting pin voltage VE (V)
Output current setting pin voltage vs.
output current setting pin current
−50
440
400
300
200
100
0
−40
−20
0
20
40
60
80
Ambient temperature Ta (°C)
100
120
MB3817
■ FUNCTIONAL DESCRIPTION
1. Switching Regulator Functions
(1) Reference voltage circuit (Ref)
The reference voltage circuit generates a temperature-compensated stable voltage ( =: 1.50 V) . This reference
voltage is used as the reference voltage and bias level for the power control unit.
(2) Triangular-wave oscillator circuit
By connecting a timing capacitor and a resistor to the CT (pin1) and the RT (pin2) terminals, it is possible to
generate any desired triangular oscillation waveform.
(3) Error amplifier
The error amp. is an amplifier circuit that detects the output voltage from the switching regulator and produces
the PWM control signal. The broad in-phase input voltage range of 0 V to Vcc − 0.9 V provides easy setting from
external power supplies and enables use with applications such as DC motor speed control systems.
Also, it is possible to provide stable phase compensation for a system by setting up any desired level of loop
gain, by connecting feedback resistance and a capacitor between the error amp. output terminal (FB terminal
(pin 5) ) and the inverse input terminal (−IN terminal (pin 4) ) .
(4) PWM comparator (PWM Comp.)
This is a voltage comparator with one inverted input and three non-inverted inputs, and operates as a voltagepulse width modulator controlling output duty in relation to input voltage.
The output transistor is turned on during the interval in which the triangular waveform is lower than any of three
voltages : the error amp. output voltage (FB terminal (pin 5) ) , soft start set voltage (CS terminal (pin 13) ) , or
dwell time setting voltage (DTC terminal (pin 6) ) .
(5) Output circuits (OUT)
The output circuit has totem pole type configuration, and can drive an external PNP transistor.
The on current value can be set up to a maximum of 30 mA using the resistance (RE) connected to the VE
terminal (pin 11) .
The off current is set by connecting a bootstrap capacitor CB between the CP1 terminal (pin 7) and CP2 terminal
(pin 8) .
2. Power Supply Control Functions
The output is switched on and off according to the voltage level at the CTL terminal (pin 15) .
CTL terminal voltage level
Channel on/off status
L ( ≤ 0.7 V)
Standby mode*
H ( ≥ 2.1 V)
Operating mode
* : Supply current in standby mode is 10 µA or less.
11
MB3817
3. Protective Circuit Functions
(1) Soft start and short protection circuits (CS, SCP)
Soft starting, by preventing a rush current at power-on, can be provided by connecting a capacitor CS to the CS
terminal (pin 13) .
After the soft start operation is completed, the CSCP terminal (pin 14) is held at “L” level (standby voltage VSTB),
which functions as short detection standby mode. If an output short causes the error amp. output to rise above
1.5 V, capacitor CSCP begins charging, and after reaching threshold voltage VTH of 0.65 V causes the OUT terminal
(pin 10) to be fixed at “H” level and the dwell time to be set to 100%, and the CSCP terminal (pin 14) is held at
“L” level.
Once the protection circuit has been activated, the power supply must be reset to restore operation.
(2) Low input voltage error prevention circuit (UVLO)
Power-on surges and momentary drops in power supply voltage can cause errors in control IC operation, which
can destroy or damage systems. The low input voltage error protection circuit compares the supply voltage to
the internal reference voltage, and sets the OUT terminal (pin 10) to “H” level in the event of a drop in supply
voltage.
Operation is restored when the power supply voltage returns above the threshold voltage of the low input voltage
error prevention circuit.
12
MB3817
■ SETTING OUTPUT VOLTAGE
• Output voltage VO is plus
VO+
R1
Error Amp.
−IN
4
−
3
+
+IN
R2
VO+ =
VREF
R2
(R1 + R2)
VREF
• Output voltage VO is minus
VREF
R2
R
Error Amp.
−IN
4
+IN
3
R1
−
+
VO− = −
VREF
2 × R2
(R1 + R2) + VREF
R
VO−
■ OSCILATOR FREQUENCY SETTING
The oscillator frequency can be set by connecting a timing capacitor (CT) to the CT terminal (pin1) and a timing
resistor (RT) to the RT terminal (pin2) .
Oscillator frequency : fOSC
fOSC (kHz) =:
1023000
CT (pF) •RT (kΩ)
13
MB3817
■ METHOD OF SETTING THE OUTPUT CURRENT
The output circuit is comprised of a totem-pole configuration. Its output current waveform is such that the ONcurrent value is set by constant current and the OFF-current value is set by a time constant. These output currents
are set using the equations below.
500
ON current : IO+ [mA] =:
(Voltage on output current-setting pin VE = 0.5 V)
RE [Ω]
OFF current : OFF-current time constant = proportional to the value of CB
• Output circuit
7
CB1
CB
8
CB2
Outside putting PNP transistor
OFF
current
setting
block
9
VCC
OFF
current
Q4
10
Q6
Q5
D1
(0.5 V)
11
OUT
ON current
RE
VE
• Output current waveform
Output current
ON current
0
OFF current
t
14
MB3817
• Voltage and current waveforms on output terminal
VCC = 3 V
4
VO (V)
2
0
−2
−4
20
0
IO (mA)
40
−20
0
2
4
6
8
10
t (µs)
• Measuring circuit diagram
7
8
9
CB1
CB
1000 pF
CB2
VCC
VCC
2S81121S
U1FWJ44N
(5.0 V)
OUT
RE 22 µF
VE 16 Ω
VO
35 kΩ
10
22 µF
15 kΩ
11
15
MB3817
■ METHOD OF SETTING THE SHORT DETECTION TIME
The error amp. output is connected to the inverted input of the short detector comparator circuit (SCP Comp.) ,
where it is constantly compared to the reference voltage of approximately 1.5 V that is connected to the noninverted input.
If the switching regulator load conditions are stabilized, the short detector comparator output is at “H” level,
transistor Q3 is on, and the CSCP terminal (pin14) holds the input standby voltage VSTB which is 50 mV.
If load conditions change rapidly due to a cause such as a load short, so that output voltage falls, the short
detector comparator circuit output changes to “L” level. When this happens, transistor Q3 turns off and the short
detector capacitor CSCP connected externally to the CSCP terminal starts charging from the input source current
II, which is −1.0 µA.
Short detection time (tPE)
tPE [s] =: 0.65 × CSCP [µF]
When the short detector capacitor CSCP has been charged to the threshold voltage VTH, which is 0.65 V, the SR
latch is set, and the external PNP transistor is turned off (setting dwell time to 100%) . At this time, the SR latch
input is closed, and the CSCP terminal is set to input latch voltage VI which is 50 mV.
• Short protection circuit
FB
5
−IN
+IN
4
−
3
+
Error Amp.
+
+
+
−
Outside putting
PNP transistor
PWM Comp.
9
OFF
current
setting
block
VCC
Q4
10
OUT
Q6
−
Q5
SCP Comp.
+
1.5 V
1 µA
bias
RS
Latch
UVLO
Q2
Q3
14
CSCP
16
D1
(0.5V)
RE
11
VE
MB3817
■ TREATMENT WHEN NOT USING CSCP
When you do not use the timer/latch-actuated short-circuiting protection circuit, connect the CSCP terminal (pin
14) to GND.
• Treatment when not using CSCP
14
CSCP
17
MB3817
■ METHOD OF SETTING SOFT START TIME
To protect against surge currents when the IC is turned on, a soft start setting can be made by connecting a soft
start capacitor (CS) to the CS terminal (pin 13) .
When the IC starts up (CTL terminal (pin 15) to “H” level, Vcc ≥ UVLO threshold voltage VTH) the transistor Q1
turns off and the soft start capacitor (CS) connected to the CS terminal begins charging from the charge current
ICHG which is −1.0 µA.
At this time, if the CS terminal voltage is less than 0.9 V, the soft start comparator circuit output goes to “H” level,
transistor Q2 turns on and the CSCP terminal (pin 14) holds input standby voltage VSTB which is 50 mV so that
the short protection circuit is not activated. When the CS terminal voltage is greater than or equal to 0.9 V,
transistor Q2 turns off, the PWM comparator circuit compares the CS terminal voltage with the triangular wave
and changes the ON duty of the OUTPUT terminal, thus achieving a soft start. Note that the soft start time is
determined by the following formula.
Soft start time (time before output ON duty reaches 50%)
tS [ms] =: 1.2 × CS [µF]
• Soft start circuit
+
+
+
−
PWM Comp.
Outside putting
PNP transistor
9
OFF
current
setting
block
VCC
Q4
10
OUT
1 µA
Q6
CS
13
Q5
Q1
−
Soft Start Comp.
+
(0.9 V)
1 µA
bias
RS
Latch
UVLO
Q2
Q3
14
CSCP
18
D1
(0.5V)
RE
11
VE
MB3817
■ TREATMENT WHEN NOT USING CS
When not using the soft start function, the CS terminal (pin 13) should be left open.
• When no soft start time is set
Open
13 CS
19
MB3817
■ METHOD OF SETTING THE DEAD TIME
When the device is set for step-up inverted output based on the flyback method, the output transistor is fixed to
a full-on state (ON-duty = 100%) at power switch-on. To prevent this problem, you may determine the voltages
on the DTC terminals (pin 6) from the VREF voltage so you can easily set the output transistor’s dead time
(maximum ON-duty) independently for each channel as shown below.
When the voltage on the DTC terminals (pin 6) is lower than the triangular-wave output voltage from the oscillator,
the output transistor turns off. The dead time calculation formula assuming that triangular-wave amplitude ≅
0.4 V and triangular-wave minimum voltage ≅ 1.4 V is given below.
Vdt − 1.0 V
× 100 [%]
Duty (ON) MAX =:
0.4
When you do not use these DTC terminals, connect them to VREF terminal.
• When using DTC to set dead time
16 VREF
Ra
6
Vdt
Rb
• When not using DTC to set dead time
16 VREF
6
20
DTC
DTC
VIN
13
1000 pF
0.1 µF
CS
6
DTC
15 kΩ
10 kΩ
5
0.047 µF
4
−IN
3
+IN
FB
18 kΩ
1
CT
OSC
Q1
CS
1 µA
+
−
2
RT
6.2 kΩ
1.0 V
1.4 V
(0.9 V)
+
+
−
1.5 V
RS
Latch
bias
Soft Start
−
Comp.
Error Amp1
UVLO
SCP
Comp.
+
+
+
−
Q5
VCC
Power
ON/OFF
1.5 V
Ref
bias
Q6
Q4
(0.5 V)
OFF
current
setting
block
9
15
11
10
14
16
12
GND
CSCP VREF
Q3
SCP
1 µA
0.1 µF
Q2
PWM
Comp.
OUT
8
7
22 µH
U1FWJ44N
22 µF
2SB1121S
4.7 µF
VO
(3.3 V)
2SB1121S: SANYO Electric Co., Ltd.
UIFWJ44N: TOSHIBA CORPORATION
(note)
Output ON/OFF signal
ON : CTL = 5 V
OFF : CTL = 0 V
CTL
VE
47 Ω
OUT 22 µF
VCC
CB2
CB1
1000 pF
15 Ω
MB3817
■ APPLICATION EXAMPLE
1. Step-down scheme
21
22
VIN
15 kΩ
18 kΩ
CS
13
6
1000 pF
0.1 µF
10 kΩ
DTC
5
0.047 µF
4
−IN
3
+IN
FB
1
CT
OSC
Q1
CS
1 µA
+
−
2
RT
6.2 kΩ
1.0 V
RS
Latch
bias
1.5 V
(0.9 V)
1.4 V
+
−
+
Soft Start
Comp.
−
Error Amp1
UVLO
SCP
Comp.
+
+
+
−
VCC
Power
ON/OFF
1.5 V
Ref
bias
Q6
(0.5 V)
OFF
current
setting
block
9
15
11
10
14
16
12
GND
CSCP VREF
Q3
SCP
1 µA
Q5
OUT
0.1 µF
Q2
PWM
Comp.
8
7
22 µF
2SB1121S: SANYO Electric Co., Ltd.
UIFWJ44N: TOSHIBA CORPORATION
U1FWJ44N
22 µH
2SB1121S 4.7 µF 22 µH
(note)
Output ON/OFF signal
ON : CTL = 5 V
OFF : CTL = 0 V
CTL
VE
47 Ω
OUT 22 µF
VCC
CB2
CB1
1000 pF
4.7 µF
VO
(3.3 V)
15 Ω
MB3817
2. Zeta scheme
VIN
15 kΩ
35 kΩ
R2
+IN
−IN
FB
1 µF
13
CT
OSC
Q1
1
1000 pF
CS
CS
1 µA
+
3
6
−
4
5
13 kΩ
1.2 kΩ DTC
0.047 µF
R1
2
6.2 kΩ
RT
1.5 V
(0.9 V)
−1.0 V
RS
Latch
bias
+
+
−1.4 V
−
Soft Start
−
Comp.
Error Amp.
UVLO
SCP
Comp.
+
+
+
−
bias
VCC
D1
(0.5 V)
Q6
Q4
Power
Ref
(1.5 V) ON/OFF
Q5
OFF
current
setting
block
9
8
7
15
11
10
14
16
12
CSCP VREF
GND
Q3
SCP
1 µA
2.2 µF
Q2
PWM
Comp.
OUT
1000 pF
22 µF
VO
(5.0 V)
2SB1121S: SANYO Electric Co., Ltd.
UIFWJ44N: TOSHIBA CORPORATION
22 µF
2SB1121S U1FWJ44N
(note)
Output ON/OFF signal
ON : CTL = 5 V
OFF : CTL = 0 V
CTL
VE
OUT 22 µF
RE
16 Ω
VCC
CB2
CB1
CB
MB3817
3. Flyback scheme
23
MB3817
■ APPLICATION
1. Equivalent series resistance and stability of smoothing capacitor
The equivalent series resistance (ESR) of the smoothing capacitor in the DC/DC converter greatly affects the
loop phase characteristic.
A smoothing capacitor with a high ESR improves system stability because the phase is advanced into the highfrequency range of an ideal capacitor (see Fig. 34 and 35) . A smoothing capacitor with a low ESR reduces
system stability. Use care when using low ESR electrolytic capacitors (OS-CONTM) and tantalum capacitors.
Note : OS-CON is the trademark of Sanyo Electric Co.,Ltd.
Figure 33
DC/DC Converter Basic Circuit
L
Tr
RC
VIN
D
RL
C
Figure 34
Gain vs. Frequency
Figure 35
0
0
−20
−60
10
24
(2)
(1) : RC = 0 Ω
(2) : RC = 31 mΩ
100
(2)
−90
−180
(1)
1k
10 k
Frequency f (Hz)
Phase φ (deg)
Gain AV (dB)
20
−40
Phase vs. Frequency
100 k
10
(1) : RC = 0 Ω
(2) : RC = 31 mΩ
100
1k
10 k
Frequency f (Hz)
(1)
100 k
MB3817
Reference data
In an aluminum electrolytic smoothing capacitor (RC =: 1.0 Ω) is replaced with a low ESR electrolytic capacitor
(OS-CONTM : RC =: 0.2 Ω) , the phase margin is reduced by half (see Fig. 37 and 38) .
Figure 36 DC/DC Converter AV vs. φ characteristic Test Circuit
VOUT
VO+
CNF
AV vs. φ characteristic
Between this point
−IN
−
FB
VIN
+IN
+
R2
R1
VREF/2
Error Amp.
DC/DC Converter +5 V output Gain vs. Phase
60
VCC = 10 V
RL = 25 Ω
CP = 0.1 µF
φ
40
20
90
62°
0
0
−20
−40
10
100
1k
Frequency f (Hz)
AI Condenser
+
220 µF (16 V)
− RC ≅ 1.0 Ω : fOSC = 1 kHz
GND
10 k
−180
100 k
DC/DC Converter +5 V output Gain vs. Phase
60
VCC = 10 V
RL = 25 Ω
CP = 0.1 µF
AV
40
20
0
180
φ
90
27°
0
−20
−40
10
VO+
−90
Figure 38
Gain AV (dB)
180
VO+
Phase φ (deg)
Gain AV (dB)
AV
Phase φ (deg)
Figure 37
−90
100
1k
Frequency f (Hz)
10 k
+
−
OS-CON TM
22 µF (16 V)
RC ≅ 0.2 Ω : fOSC = 1 kHz
GND
−180
100 k
25
MB3817
■ NOTES ON USE
• Take account of common impedance when designing the earth line on a printed wiring board.
• Take measures against static electricity.
- For semiconductors, use antistatic or conductive containers.
- When storing or carrying a printed circuit board after chip mounting, put it in a conductive bag or container.
- The work table, tools and measuring instruments must be grounded.
- The worker must put on a grounding device containing 250 kΩ to 1 MΩ resistors in series.
• Do not apply a negative voltage
- Applying a negative voltage of −0.3 V or less to an LSI may generate a parasitic transistor, resulting in
malfunction.
■ ORDERING INFORMATION
Part number
MB3817PFV
26
Package
16-pin Plastic SSOP
(FPT-16P-M05)
Remarks
MB3817
■ PACKAGE DIMENSION
Note 1) *1 : Resin protrusion. (Each side : +0.15 (.006) Max) .
Note 2) *2 : These dimensions do not include resin protrusion.
Note 3) Pins width and pins thickness include plating thickness.
Note 4) Pins width do not include tie bar cutting remainder.
16-pin Plastic SSOP
(FPT-16P-M05)
*1 5.00±0.10(.197±.004)
0.17±0.03
(.007±.001)
9
16
*2 4.40±0.10 6.40±0.20
(.173±.004) (.252±.008)
INDEX
Details of "A" part
+0.20
1.25 –0.10
+.008
.049 –.004
LEAD No.
1
8
0.65(.026)
0.10(.004)
C
(Mounting height)
"A"
0.24±0.08
(.009±.003)
0.13(.005)
M
0~8˚
0.50±0.20
(.020±.008)
0.60±0.15
(.024±.006)
0.10±0.10
(Stand off)
(.004±.004)
0.25(.010)
2003 FUJITSU LIMITED F16013S-c-4-6
Dimensions in mm (inches)
Note : The values in parentheses are reference values.
27
MB3817
FUJITSU LIMITED
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purpose of reference to show examples of operations and uses of
Fujitsu semiconductor device; Fujitsu does not warrant proper
operation of the device with respect to use based on such
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device based on such information, you must assume any
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assumes no liability for any damages whatsoever arising out of
the use of the information.
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function and schematic diagrams, shall not be construed as license
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and manufactured as contemplated for general use, including
without limitation, ordinary industrial use, general office use,
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and manufactured as contemplated (1) for use accompanying fatal
risks or dangers that, unless extremely high safety is secured, could
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reaction control in nuclear facility, aircraft flight control, air traffic
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F0308
 FUJITSU LIMITED Printed in Japan