ETC FA5510P

FA551X series
CMOS IC
For Switching Power SupplyFA551X
Control
FA5510P (N), FA5511P (N)
FA5514P (N), FA5515P (N)
■ Dimensions, mm
SOP-8
5
8
3.9
The FA551X series are the PWM type switching power supply
control ICs that can directly drive power MOSFET. These ICs
use a CMOS device with high dielectric strength (30V) to
implement low power consumption. These ICs contain many
function in a small 8-pin package. With these ICs, a highperformance and compact power supply can be created
because not many external discrete components are needed.
6.0±0.2
■ Description
4
1
0.20
0.4±0.1
5
8
6.4
DIP-8
1.27
1
9.3
4
■ Block diagram
FA5510P (N), FA5511P (N)
CS(8)
REF
(7)
2.54
VCC(6)
0.8V/0.68V 5.2µA
5V VCC
0.95mA
ENB
5V REF
15.5V
16.5V/9V
3.5V
OUT
(5)
ENB
4V
PWM
GND
(4)
R
QB
S Q
FF
5V Controlled block
RT(1)
IS+(3)
FA5514P (N), FA5515P (N)
VCC(6)
CS(8)
REF
(7)
0.8V/0.68V 5.2µA
5V VCC
0.95mA
ENB
5V REF
15.5V
16.5V/9V
3.5V
OUT
(5)
ENB
4V
R
-0.17V
RT
Oscillator timing
resistor
Setting oscillation frequency
2
FB
Feedback
Input of PWM comparator
3
IS
Overcurrent
detection
Input of the overcurrent
limiting function
4
GND
Ground
Ground
5
OUT
Output
Output for driving a power
MOSFET
6
VCC
Power supply
Power supply
7
REF
Reference voltage
Reference voltage output (5V)
8
CS
Soft-start and
ON/OFF control
Soft-start, ON/OFF function and
latch-mode shutdown operations
Type
Max. duty
cycle (typ.)
Polarity of overcurrent Package
detection
FA5510P
46%
+
FA5510N
GND
(4)
FA5514P
FA5514N
FF
FA5515P
FA5515N
DIP-8
SOP-8
70%
+
FA5511N
QB
S Q
5V Controlled block
RT(1)
1
FA5511P
OUT
PUT
PWM
OSC
RT CT
Description
UVLO
0.8V
Dmax
FA5514: 46%
FA5515: 70%
5˚
0~1
15.5V
8.5V/7.9V
FB
(2)
˚
Pin Pin
Function
No. symbol
OUT
PUT
+0.24V
7.62
0~15
UVLO
0.8V
OSC
RT CT
+0.1
0.05
0.25 –
15.5V
8.5V/7.9V
FB
(2)
0.46±0.1
3.0min 4.5max
1.5±0.3
3.3
• Low current consumption by CMOS process with high
dielectric strength (30V)
• Standby current of 2µA or less (at Vcc=14V), and operating
current of 1.5mA (typ)
• Overvoltage protection function detecting the Vcc voltage
• A drive circuit for connecting a power MOSFET directly
• Output peak current: ±1.5A
• Pulse-by-pulse overcurrent limiting function
• Overload protection function (latch or non-latch mode selectable)
• Output ON-OFF function by external signal
• Latch-mode overvoltage shutdown function
• Undervoltage lockout function (16.5V ON / 9V OFF)
• Reference voltage output (5V)
• 8-pin package (DIP/SOP)
0~8°
■ Features
Dmax
FA5510: 46%
FA5511: 70%
1.8max
+0.1
–0.05
4.9
DIP-8
SOP-8
46%
–
70%
–
DIP-8
SOP-8
DIP-8
SOP-8
IS-(3)
1
FA551X
■ Absolute maximum ratings
Item
Output peak current
FB pin input voltage
IS pin input voltage
REF pin source current
CS pin sink current
Total power dissipation (Ta=25˚C)
Symbol
VCC1
VCC2
IOUT
VFB
VIS
IREF
ICS
Pd
Ambient temperature
Maximum junction temperature
Storage temperature
Ta
Tj
Tstg
Supply Voltage
Low impedance source (ICC>15mA)
Internal zener clamp (ICC<15mA)
Rating
30
Self limiting
±1.5
–0.3 to 5.0
–0.3 to 5.0
–10
+2.0
800 (DIP-8)
400 (SOP-8)
–30 to +85
125
–40 to +150
Unit
V
V
A
V
V
mA
mA
mW
˚C
˚C
˚C
Note: There are cases where the IC cannot output the rating current depending on Vcc voltage or temperature.
Maximum power dissipation curve
Max. power
dissipation
400mW (SOP)
800mW (DIP)
0
–30
25
125
85
Ambient temperature Ta [˚C]
■ Recommended operating conditions
Item
Symbol
Min.
Supply voltage
VCC
Oscillation frequency
fOSC
REF-GND capacitor
Cref
0.1
Soft start capacitor
CS
0.01
2
Typ.
Max.
Unit
10
28
V
10
500
0.47
kHz
µF
1
µF
FA551X
■ Electrical characteristics (VCC=18V, RT=47kΩ, Ta=25˚C)
Reference voltage section (REF pin)
Item
Symbol
Test condition
Min.
Reference voltage
VREF
Tj=25˚C
4.75
Line regulation
Vdv1
VCC=10 to 28V
Load regulation
Vdv2
IL=0 to 10mA, VCC=18V
Temperature stability
VdT
Ta=–30 to 85˚C
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
Oscillation frequency
fOSC
RT=47kΩ, Tj=25˚C
92.6
100
107.4
kHz
Voltage stability
fdv
VCC=10 to 28V
±1.0
%
Temperature stability
fdT
Ta=–30 to 85˚C
±0.02
%/˚C
FA5511/15
Unit
–40
Typ.
Max.
Unit
5.00
5.25
V
±6
±20
mV
–12
mV
±0.5
mV/˚C
Oscillator section (RT pin)
Pulse width modulation circuit section (FB pin)
Item
Symbol
Test condition
FA5510/14
FB pin source current
IFB
VFB=0
–855 –720 –585 –855 –720 –585 µA
Input threshold voltage (FB pin)
VTH FB0
Duty cycle =0%
0.9
VTH FBM
Duty cycle =DMAX
Min.
Maximum duty cycle
DMAX
Typ.
Max. Min.
1
0.9
1.92
42
46
Typ.
Max.
1
V
2.40
50
66
70
V
74
%
Overcurrent limiting circuit section (IS pin)
Item
Symbol
Input threshold voltage (IS pin)
VTHIS
Source current (IS pin)
IIS
Delay time
tpdIS
Test condition
FA5510/11
FA5514/15
Min.
Typ.
Max. Min.
220
240
260
–190 –170 –150 mV
±5
–28
VIS=0V
150
Typ.
Unit
–20
Max.
–12
150
µA
ns
Soft start circuit section (CS pin)
Item
Symbol
Test condition
FA5310/14
Min.
Max. Min.
–3.2
Charge current (CS pin)
ICHG
VCS=1V, Tj=25˚C –7.2
–5.2
Input threshold voltage (CS pin)
VTH CS0
Duty cycle =0%
1.0
VTH CSM
Duty cycle =DMAX
0.90
FA5311/15
Typ.
Unit
Typ.
Max.
–7.2
–5.2
–3.2
0.90
1.0
V
2.40
V
1.92
µA
Output ON/OFF control circuit section (CS pin)
Item
Symbol
Test condition
Min.
Source current (CS pin)
IS0CS
VCS=0V, Tj=25˚C
–7.2
ON/OFF control threshold voltage (CS pin)
VTHON
OFF→ON, Tj=25˚C
VTHOFF
ON→OFF, Tj=25C
Hysteresis voltage
VTHOHS
0.50
Typ.
Max.
Unit
–5.2
–3.2
µA
0.8
0.93
V
0.68
V
0.12
V
3
FA551X
Latch-mode cutoff circuit section (CS pin)
Item
Symbol
Test condition
Sink current (CS pin)
ISICS
VCS=6.5V, VFB=1V, Tj=25˚C
18
30
45
µA
Cutoff threshold voltage (CS pin)
VTH CSF
ON→OFF, Tj=25˚C
8.0
8.5
9.0
V
VTH CSN
OFF→ON, Tj=25˚C
7.4
7.9
8.4
V
Hysteresis voltage
Min.
VTHHIS
Typ.
Max.
0.6
Unit
V
Overload cutoff circuit section (FB pin)
Item
Symbol
Overload threshold voltage (FB pin)
VTH FB
Test condition
Min.
Typ.
Max.
Unit
3.2
3.5
3.8
V
Unit
Overvoltage cutoff circuit section (VCC pin)
Item
Symbol
Test condition
Min.
Typ.
Max.
Overvoltage threshold voltage (VCC pin)
VTH VCC
Tj=25˚C
30
31.8
34
Cutoff operating supply current (VCC pin)
IVCC
Tj=25˚C, VCC=VTHVCC
Charge current (CS pin)
IS0CS2
VCS=6.5V
14
–1.4
–0.95
V
mA
–0.5
mA
Undervoltage lockout circuit section (VCC pin)
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
OFF-to-ON threshold voltage
VCC ON
Tj=25˚C
15.5
16.5
17.5
V
ON-to-OFF threshold voltage
VCC OFF
Tj=25˚C
8.5
9.0
10.0
V
Hysteresis voltage
VHYS
Tj=25˚C
6.8
7.5
8.2
V
Item
Symbol
Test condition
Min.
Low output voltage
VOL
IOL=100mA
High output voltage
VOH
IOH=–100mA, VCC=18V
16.5
V
Rise time
tr
CL=1nF
40
ns
Fall time
tf
CL=1nF
25
ns
Output circuit section (OUT pin)
15
Typ.
Max.
Unit
0.7
1.5
V
Supply current (VCC pin)
Item
Symbol
Test condition
Stand-by current
ICCSTB
VCC=14V
Startup current
ICCST
VCC=OFF-to-ON threshold voltage
Operating-state supply current
ICCOP
OFF-state supply current
ICCOF
Latch mode supply current
ICCL
4
Min.
Typ.
Max.
Unit
2
µA
12
30
µA
No load
1.5
2.5
mA
VCC=17V, CS=0V
80
200
µA
VCC=10V
45
80
µA
FA551X
■ Characteristic curves (VCC=18V, RT=47kΩ, Ta=25˚C)
Oscillation frequency (fOSC) vs.
timing resistor resistance (RT)
Oscillation frequency (fOSC) vs. supply voltage (VCC)
100.1
1000
100.08
100.06
100.04
fosc (kHz)
fosc (kHz)
100
10
100.02
100
99.98
99.96
99.94
99.92
1
1
10
100
1000
99.9
10
RT (kΩ)
15
20
25
30
Vcc (V)
Oscillation frequency (fOSC) vs.
FB pin source current (IFB) vs. FB pin voltage (VFB)
junction temperature (Tj)
102
0
-100
101.5
-200
-300
IFB (µA)
fosc (kHz)
101
100.5
100
-400
-500
-600
99.5
-700
99
-800
98.5
–50
0
0
50
100
1
2
150
3
4
5
VFB (V)
Tj (˚C)
Maximum duty cycle (DMAX) vs. timing resitor resistance (RT)
FA5510/14
Maximum duty cycle (DMAX) vs. timing resitor resistance (RT)
FA5511/15
49
72
48
71
46
DMAX (%)
DMAX (%)
47
45
44
43
70
69
68
42
1
10
100
RT (kΩ)
1000
67
1
10
100
1000
RT (kΩ)
5
FA551X
Maximum duty cycle (DMAX) vs. junction temperature (Tj)
FA5511/15
47
71
46.8
70.8
46.6
70.6
46.4
70.4
DMAX (%)
DMAX (%)
Maximum duty cycle (DMAX) vs. junction temperature (Tj)
FA5510/14
46.2
46
45.8
70.2
70
69.8
45.6
69.6
45.4
69.4
45.2
69.2
69
45
-50
0
50
100
-50
150
0
50
100
150
Tj (˚C)
Tj (˚C)
IS (+) pin current (IIS (+)) vs. IS (+) pin voltage (VIS (+))
FA5510/11
IS (–) pin current (IIS (–)) vs. IS (–) pin voltage (VIS (–))
FA5514/15
5
0
-0.05
0
IIS (–) (µA)
-0.1
IIS (+) (µA)
-0.15
-0.2
-0.25
-5
-10
-15
-0.3
-20
-0.35
-25
-0.4
-1
0
1
2
3
-1
4
0
1
4
CS pin current (ICS) vs. CS pin voltage (VCS)
FB=0V
40
40
35
35
30
30
25
25
ICS (µA)
ICS (µA)
CS pin current (ICS) vs. CS pin voltage (VCS)
FB=open
20
15
20
15
10
10
5
5
0
0
-5
-5
-10
0
2
4
6
VCS (V)
6
3
VIS (–) (V)
VIS (+) (V)
-10
2
8
10
12
0
2
4
6
VCS (V)
8
10
12
FA551X
CS pin charge current (ICHG) vs. junction temperature (Tj)
-4.5
ICHG (µA)
-4.7
-4.9
-5.1
-5.3
-5.5
-50
0
50
100
150
Tj (˚C)
UVLO OFF-to-ON threshold voltage (VCCON) vs.
junction temperature (Tj)
UVLO ON-to-OFF threshold voltage (VCCOFF) vs.
junction temperature (Tj)
16.9
9.1
16.8
VCCOFF (V)
VCCON (V)
9.05
16.7
16.6
16.5
9
8.95
16.4
16.3
-50
0
50
100
8.9
-50
150
0
Tj (˚C)
0.75
1.6
0.7
1.5
0.65
VOL (V)
VCC-VOH (V)
0.8
1.7
1.4
1.3
0.6
0.55
1.2
0.5
1.1
0.45
1
0.4
0.9
0.35
20
VCC (V)
150
L-level output voltage (VOL) vs. supply voltage (VCC)
IO=100mA
1.8
15
100
Tj (˚C)
H-level output voltage (VOH) vs. supply voltage (VCC)
IO= –100mA
0.8
10
50
25
30
0.3
10
15
20
25
30
VCC (V)
7
FA551X
Operating state supply current (ICCOP) vs.
supply voltage (VCC)
Operating state supply current (ICCOP) vs.
junction temperature (Tj)
1.8
1.72
1.7
FB=0V
1.7
1.5
ICCOP (mA)
ICCOP (mA)
1.6
1.4
1.3
1.2
1.66
FB=0V
1.64
1.1
FB=Open
1
1.62
0.9
0.8
1.68
10
15
20
25
1.6
-50
30
0
50
VCC (V)
100
150
Tj (˚C)
OFF state supply current (ICCOFF) vs. supply voltage (VCC)
OFF state supply current (ICCOFF) vs. supply voltage (VCC)
Enlarged
3000
200
180
160
ICCOFF (µA)
ICCOFF (µA)
2500
2000
1500
1000
140
120
100
80
60
40
500
0
10
20
15
20
25
0
10
30
12
14
16
18
20
VCC (V)
VCC (V)
Latch mode supply current (ICCL) vs. supply voltage (VCC)
Latch mode supply current (ICCL) vs. supply voltage (VCC)
Enlarged
200
3000
180
2500
160
140
ICCL (µA)
ICCL (µA)
2000
1500
120
100
80
60
1000
40
20
500
0
10
0
10
15
20
VCC (V)
8
25
30
12
14
16
VCC (V)
18
20
FA551X
■ Description of each circuit
OSC
1. Oscillator
The oscillator generates a triangular waveform by charging and
discharging the built-in capacitor. A desired oscillation
frequency can be set by the value of the resistor connected to
the RT pin (See Figure 1).
The built-in capacitor voltage oscillates between about 3V and
1V, with almost the same charging and discharging gradients
(Figure 2). You can set the desired oscillation frequency by
changing the gradients using the resistor connected to the RT
pin. (Large RT=Low frequency, small RT=High frequency)
The relationship between RT and the oscillation frequency is
approximately given by:
fOSC ⱌ
4880
[kHz] ........................................................ (1)
RT + 1.4
1
RT
RT
Fig. 1
Oscillator
RT=Small
RT=Large
3V
1V
4880
RT ⱌ
– 1.4 [kΩ] ........................................................ (2)
fOSC
Fig. 2
Oscillator output
fOSC: Oscillation frequency [kHz]
RT: Timing resistance [kΩ]
The oscillator waveform cannot be observed from the outside
because the oscillator output is not pinned out. The oscillator
output is connected to a PWM comparator.
2. PWM comparator
The PWM comparator has four inputs as shown in Figure 3.
Oscillator output is compared with CS pin voltage , FB pin
voltage , and DT voltage . The lowest of three inputs ,
, and has priority and is compared with oscillator output .
While the voltage is lower than the oscillator output, the
comparator output is high. While the voltage is higher than the
oscillator output, the PWM comparator output is low (see Figure
4). The IC OUT pin voltage is high while the PWM comparator
output is low. When the IC is powered up, CS pin voltage controls soft start operation. The output pulse then begins to
widen gradually. During normal operation, the output pulse
width is determined within the maximum duty cycle (FA5510/14:
46%, FA5511/15: 70%) set by DT voltage under the
condition set by FB pin voltage , to stabilize the output
voltage.
DT voltage
FB pin voltage
CS pin voltage
Oscillator
output
Fig. 3
PWM comparator
output
PWM comparator
FB pin voltage
(4.0V)
DT voltage
Oscillator output
CS pin voltage
PWM comparator
output
OUT pin voltage
Fig. 4
PWM comparator timing chart
9
FA551X
3.1 Soft start function
Figure 7 shows the soft start circuit. Figure 8 is a soft-start
operation timing chart. The CS pin is connected to capacitor
Cs. When the power is turned on, the constant current source
(5.2µA) begins to charge the capacitor. As shown in the timing
chart, the CS pin voltage rises slowly in accordance with the
capacitor Cs charging current. The CS pin is also connected to
the IC internal PWM comparator, which has such
characteristics that the voltage is determined to output on the
basis of the lowest of input voltages. The comparator output
pulse slowly widens to cause a soft start as shown in the timing
chart.
The soft start period can be approximately estimated by the
period tS, from the time the IC is activated to the time the output
pulse width widens to 30%. The period tS is given by the
following equation:
tS [ms] ⱌ 310 ⫻ CS [ms] ..................................................... (3)
Cs: Soft start capacitor [µF]
Cs
CS VCC
8
C1
REF 7
6
0.8/0.68V
5V VCC
5.2µA
ENB
5V REF
C2
8.5/7.9V
UVLO
3.5V
C3
4V
PWM
FB 2
Output
circuit
DMAX
OSC
1
RT
Fig. 5
CS pin voltage Vcs [V]
3. CS pin circuit
As shown in Figure 5, capacitor Cs is connected to the CS pin.
The CS pin voltage varies depending on the charging voltage of
this capacitor Cs.
When the power is turned on, the constant current source
(5.2µA) begins to charge capacitor. Accordingly, the CS pin
voltage rises as shown in Figure 6. The CS pin voltage is
connected to the PWM comparator, which is characterized to
make output based on the lowest of input voltages. The device
enters soft-start mode while the CS pin voltage is between 1.0V
and VTHCSM (FA5510/14: 1.92V, FA5511/15: 2.4V).
During normal operation, the CS pin is clamped at 4.0V by
internal zener diode. If the output voltage drops due to an
overload and the FB voltage rises to 3.5V or more, the clamp
voltage 4.0V is canceled and the CS pin voltage rises to 9.5V.
The CS pin is also connected to latch comparator C2. If the CS
pin voltage rises to 8.5V or more, comparator C2 toggles to turn
off the 5V REF circuit, thereby shutting the output down.
Since the CS pin is also connected to comparator C1, the 5V
REF circuit can be turned off to shut the output down by
dropping the CS pin voltage below 0.68V. In this way,
comparator C1 can be used for output on-off control.
As explained above, the CS pin can be used for soft-start,
overload output shutdown, and output on-off control by varying
the voltage. Further details on the above three major functions
of the CS pin are given below.
CS pin circuit
9.5
8.5
Shutdown
4.0
VTHCSM
1.0
0.68/0.8
0
Momentary
overload or
overvoltage
Overload or
overvoltage
Soft start
Time t
OFF mode
Fig. 6
CS pin waveform
Cs
CS
VCC
8
6
5.2µA
PWM
FB
2
Output
circuit
DMAX
OSC
1
RT
Fig. 7
Soft start circuit
FB pin voltage
Oscillator output
DT voltage
CS pin voltage
OUT pin output
Fig. 8
10
Soft start timing chart
FA551X
3.2 Overload shutdown function
Figure 9 shows the overload shutdown circuit, and Figure 10 is
a timing chart that illustrates overload shutdown operation.
If the output voltage drops due to an overload or short circuit,
the FB pin output voltage rises. If the FB pin voltage exceeds
the reference voltage (3.5V) of comparator C3, the output of
comparator C3 goes low to turn off the switch. With the switch
off, the CS pin voltage clamped at 4.0V by zener diode in
normal operation is unclamped, and the constant current
source (5.2µA) begins to charge capacitor Cs again and the CS
pin voltage rises. When the CS pin voltage exceeds the
reference voltage (8.5V) of comparator C2, the output of
comparator C2 toggles to turn off the 5V REF circuit. The IC
then enters the latched mode and shuts down the output. IC
current consumption for shutdown is 45µA (typ) (Vcc=10V).
This current must be supplied through the startup resistor. The
IC enters output off (low voltage) state.
The overload shutdown operation can be reset by lowering the
supply voltage Vcc to below the OFF threshold voltage (9.0V)
or forcing the CS pin voltage below 7.9V.
The period tOL from the time the output is short-circuited to the
time the output circuit goes off is given by the following
equation:
(9.5V)
Comparator C2
reference voltage
(8.5V)
(4V)
CS pin voltage
DT voltage
FB pin voltage
(0V)
Oscillator output
H
OUT pin voltage
L
REF pin voltage
ON
OFF
Overload detection
Overload shutdown
Fig. 10
Overload shutdown timing chart
ON/OFF control
Cs
CS VCC
8
REF 7
5V VCC
ENB
5V REF
tOL [ms] ⱌ 870 ⫻ CS [ms] ..................................................... (4)
C1
6
0.8/0.68V
5.2µA
C2
8.5/7.9V
UVLO
Cs: Soft start capacitor [µF]
When you want to disable the overload shutdown function, see
item 9 in “Design advice”
3.3 Output ON/OFF control function
The IC can be turned on or off via an external signal applied to
the CS pin. Figure 11 shows the output on/off control circuit,
and Figure 12 is a timing chart. The IC is turned off when the
CS pin voltage is externally made to drop below 0.68V (typ).
The output of comparator C1 goes high to turn the 5V REF
circuit off. This shuts the output down. The IC enters output off
(low voltage) state. Required IC current consumption during
shutdown is 80µA (typ) (Vcc=17V). This current must be
supplied through the startup resistor. The IC goes on when the
CS pin is opened and the CS pin voltage exceeds 0.80V (typ).
This turns the 5V REF circuit on and results in automatic soft
start. The power supply then restarts operation.
PWM
FB 2
Output
circuit
DMAX
OSC
1
RT
Fig. 11
External output ON/OFF control circuit
(4V)
CS pin voltage
DT voltage
FB pin voltage
Oscillator output
Comparator C1
reference voltage
(0.8/0.68V)
H
OUT pin output
Cs
L
CS VCC
8
6
REF pin voltage
REF 7
C1
5V VCC
ON
OFF
0.8/0.68V
ON mode
OFF mode
5.2µA
ENB
5V REF
C2
Fig. 12
Output ON/OFF control circuit timing chart
8.5/7.9V
3.5V
UVLO
C3
4V
PWM
FB 2
DMAX
Output
circuit
OSC
1
RT
Fig. 9
Overload shutdown circuit
11
FA551X
4. Overcurrent limiting circuit
The overcurrent limiting circuit detects the peak value of every
drain current pulse (pulse by pulse method) of the main
switching MOSFET to limit the overcurrent. The detection
threshold voltage is +0.24V for FA5510/11 or –0.17V for
FA5514/15 with respect to the ground as shown in Figure 13
and Figure 14. The drain current of the MOSFET is converted
to voltage by resistor Rs and fed to the IS pin of the IC. If the
voltage exceeds the reference voltage +0.24V (FA5510/11) or
–0.17V (FA5514/15) of comparator C4, comparator C4 works to
set flip-flop output Q to high. The output is immediately turned
off to shut off the current. Flip-flop output Q is reset on the next
cycle to turn on the output again. This operation is repeated to
limit the overcurrent.
If the overcurrent limiting circuit malfunctions due to noise,
place an RC filter between the IS pin and MOSFET as shown in
Figure 13 and Figure 14. (See item 12 in “Design advice.”)
Figure 15 is a timing chart that illustrates overcurrent-limiting
operations.
5. Vcc overvoltage protection circuit
The IC contains a Vcc overvoltage protection circuit to protect
the IC from damage by overvoltage. Figure 16 shows the
overvoltage protection circuit. Figure 17 is a timing chart that
illustrates overvoltage protection operations. Overvoltage is
detected if the supply voltage Vcc rises to 31.8V (Icc=14mA) or
more and current flows in the built-in zener diode. The output of
comparator C5 then goes high and the constant current source
(0.95mA) raises the CS pin voltage. When the CS pin voltage
exceeds 8.5V, the output of comparator C2 goes high to turn off
the 5V REF circuit. The IC then enters the latched mode and
the IC output is put in the off (low voltage) state. When latched
mode, the IC current consumption is 45µA (typ) (Vcc=10V).
This current must be supplied through the startup resistor.
The overvoltage shutdown operation can be reset by lowering
the supply voltage to below 9.0V or forcing the CS pin voltage
below 7.9V. (When you want to enable Vcc overvoltage
shutdown at a desired voltage, see item 6 in “Design advice.”)
CS pin voltage (4V)
DT voltage
FB pin voltage
Oscillator output
H
OUT pin output
L
Comparator C4
reference voltage
FA5510/11:+0.24V
FA5514/15:-0.17V
IS pin voltage
REF pin voltage ON
OFF
Overcurrent limiting
Fig. 15
Overcurrent timing chart
~
+
~
-
Vin
Cs
8
REF 7
C1
5V VCC
CS
6
VCC
15.5V
0.8/0.68V
0.95mA
ENB
C2
5V REF
8.5/7.9V
UVLO
3.5V
15.5V
C5
0.8V
C3
4V
PWM
FB 2
DMAX
Output
circuit
OSC
1
RT
Fig. 16
Overvoltage shutdown circuit
FA5510/11
OSC UVLO
PWM
CS pin
FB pin
Oscillator
R
O.C.P.
0.24V
IS(+)
S
F.F
3
DT voltage
Rs
4
C
GND
FB pin voltage
(0V)
Osillator output
OUT pin voltage
R
REF pin voltage
Fig. 13
(4V)
CS pin voltage
Q
C4
(9.5V)
Comparator C2
reference voltage
(8.5V)
OUT
Output pin
circuit
Overcurrent limiting circuit (FA5510/11)
H
L
ON
OFF
Overvoltage
detection
Shutdown
FA5514/15
Fig. 17
OSC UVLO
PWM
CS pin
FB pin
Oscillator
OUT
Output
pin
circuit
R
O.C.P.
-0.17V
Q
S
F.F
C4
IS(-)
3
Rs
4
C
GND
R
Fig. 14
12
Overcurrent limiting circuit (FA5514/15)
Overvoltage shutdown timing chart
FA551X
6. Undervoltage lockout circuit (U.V.L.O.)
The IC incorporates a circuit that prevents the IC from
malfunctioning when the supply voltage drops. When the
supply voltage is raised from 0V, the IC starts operation with
Vcc=16.5V (typ). If the supply voltage drops, the output is shut
down when Vcc=9.0V (typ). When the undervoltage lockout
circuit operates, the outputs of the OUT and CS pins go low to
reset the IC.
7. Output circuit
The IC contains a push-pull output stage and can directly drive
the MOSFET. The absolute maximum rating of OUT pin peak
current is ±1.5A. But when using in actual circuit, the output
peak current depends on the characteristics of the MOSFET,
resistance between the OUT pin and the MOSFET, supply
voltage, temperature and so. When supply voltage is relatively
low or temperature is relatively high, the output peak current
may not reach the maximum ratings.
Note that the output current causes loss of the output stage.
The total loss caused by the operating current and the output
current should be within the ratings in actual circuit.
13
FA551X
■ Design advice
1. Deciding the startup circuit
These ICs, which use CMOS process, consume less current,
and therefore can use larger startup resistance than the
conventional bipolar type of IC. To decide the startup
resistance, the following conditions must be satisfied:
(a) The IC is started when the power is turned on.
(b) The IC consumption current is supplied during latch mode
operation to maintain the latch state.
(c) The IC consumption current is supplied during the off state
under the on/off function to maintain the off state.
DB
~
T1
+
C1
AC INPUT
~
R1
VCC
D1
C2
6
FA551X
MOSFET
5
OUT
However, these are the minimum conditions for using the IC.
The startup time required for the power supply must also be
decided on.
Fig. 18
1.1 Connecting the startup resistor before rectification
(AC line)
When the startup resistor is connected before rectification (AC
line) as shown in Figure 18, the voltage applied to the startup
resistor forms a half-wave rectified waveform of the AC input
voltage. Startup resistor R1 must satisfy the three equations
shown below. Select a smaller-side value for R1 in
consideration of the temperature characteristics.
(a) To supply startup current 30µA at ON threshold voltage
17.5V (max.) of UVLO:
았옽옽
2
⫻ Vac – 17.5 ......................................................
(5)
π
R1 ⬍
0.03
(b) To supply IC consumption current 80µA (max.) (Vcc=10V) in
latch mode:
았옽옽
2
⫻ Vac – 10 ........................................................
(6)
π
R1 ⬍
0.08
(c) To supply IC consumption current 200µA (max.) (Vcc=17V)
in the off state under the on/off function:
았옽옽
2
⫻ Vac – 17 ........................................................
(7)
π
R1 ⬍
0.2
R1: Startup resistance [kΩ]
Vac: Effective value of AC input voltage [V]
If neither the latch mode operation nor the on/off functions are
used, only the expression in (5) needs to be satisfied. In this
method, the supply current to the IC via the start-up resistor is
stopped when AC input is shut down. Therefore, after latch
mode operation, shutting the AC input down resets the latch
mode in a very short period of time.
14
Startup circuit (1)
Rs
FA551X
1.2 Connecting the startup resistor after rectification
(DC line)
When the startup resistor is connected after rectification (DC
line) as shown in Figure 19, the voltage applied to the startup
resistor becomes the peak value of the AC input voltage.
Startup resistor R1 must satisfy the three equations shown
below. Select a smaller-side value for R1 in consideration of
temperature characteristics.
DB
~–
R1
D1
VCC
았옽옽
2 ⫻ Vac – 17.5 ......................................................
(8)
0.03
C2
6
FA551X
MOSFET
5
OUT
(b) To supply IC consumption current 80µA (max.) (Vcc =10V)
in latch mode:
았옽옽
2 ⫻ Vac – 10
R1 ⬍
0.08
C1
AC INPUT
(a) To supply startup current 30µA at ON threshold voltage
17.5V (max.) of UVLO:
R1 ⬍
T1
~+
Fig. 19
Rs
Startup circuit (2)
........................................................ (9)
Vcc
(c) To supply IC consumption current 200µA (max.) (Vcc = 17V)
in the off state under the on/off function:
R1 ⬍
았옽옽
2 ⫻ Vac – 17 ......................................................
(10)
0.2
R1: Startup resistance [kΩ]
Vac: Effective value of AC input voltage [V]
If neither the latch nor the on/off functions are used, only the
expression in (8) needs to be satisfied. In this method, after
latch mode operation, smoothing capacitor C1 in the main
circuit supplies current to the IC via the startup resistor even if
the AC input is shut down. Therefore, some time must elapse
before the latch mode is reset.
UVLO
ON
Vcc must not drop to
UVLO OFF.
UVLO
OFF
Auxiliary winding
voltage
Time t
Fig. 20
Vcc voltage at startup with a adequate capacitor
Vcc
2. Determining the Vcc capacitor value
To properly start the power supply, a certain value is required
for the capacitor connected to the VCC pin. Figure 20 shows
the Vcc voltage at start-up when a proper value is given to the
capacitor. When the input power is turned on, the capacitor
connected to the VCC pin is charged via the startup resistor
and the voltage increases. The IC is then in standby state and
almost no current is consumed. (Icc<2µA) Thereafter, Vcc
reaches the ON threshold voltage of UVLO and the IC begins
operation. When the IC begins operation to make output, the IC
operates based on the voltage from the auxiliary winding.
When the IC is just starting up, however, it takes time for the
voltage from the auxiliary winding to rise enough, and Vcc
drops during this period.
Determine the Vcc capacitor value so that Vcc will not drop
down to the OFF threshold voltage of UVLO during this period.
UVLO
ON
UVLO
OFF
Time t
Fig. 21
Vcc voltage at startup with a inadequate capacitor
If the Vcc capacitor value is too small, Vcc will drop to the OFF
threshold voltage of UVLO before the auxiliary winding voltage
rises enough. If so, Vcc repeatedly goes up and down between
the UVLO threshold voltages, and the power supply cannot
start up. (Figure 21)
15
FA551X
3. The startup period
The start up period from the time the power is on to the time the
IC is turn to on is approximately given by:
(
tstart-up = –C2 ⫻ R1 ⫻ In 1 –
16.5
V1
)
R1
VCC
................................. (11)
Fig. 22
Startup circuit (3)
았옽옽
2 ⫻ Vac ..... (Connecting a startup resistor before rectification)
π
R1
았옽옽
2 ⫻ Vac ....... (Connecting a startup resistor after rectification)
VCC



To shorten the start-up period, the capacitor C2 or resistor R1
should be decreased. But in some case, such as when the
load current of the power supply is changed rapidly, you may
want to prolong the hold time of the Vcc voltage over the off
threshold. In this case the capacitor C2 cannot be decreased
and the resistor R1 should be decreased. But loss of the
resistor R1 increases.
In such case, the circuit shown in Fig. 23 is effective to shorten
start-up period without increasing the loss of the resistor R1.
The capacitor C2 is decreased to shorten the start-up period
and, after the IC starts up, Vcc voltage supplied from C3 to
prolong the hold time of the Vcc voltage.
The start-up period of this circuit also is approximately given by
the expression in (11)
4. Setting soft start period and OFF latch delay
independently
Figure 24 shows a circuit for setting the soft start period and
OFF latch delay independently. In this circuit, capacitance CS
determines the soft start period, and capacitance CL
determines the OFF latch delay. If the overload shutdown or
overvoltage shutdown functions raise the CS pin voltage to
around 5V, zener diode Zn becomes conductive to charge
capacitor CL. The OFF latch delay can be thus prolonged by
capacitance CL.
5. Overvoltage protection using the VCC pin
These ICs contain an overvoltage protection function detecting
the Vcc voltage using internal ZD (See item 5 in “Description of
each circuit”). If Vcc voltage exceed 31.8V, the current of 14mA
flows through the internal ZD and the overvoltage protection
function operates.
After this protection function operates, the IC continues to
consume the large current if high voltage continues to be
applied to the Vcc pin. Mind that total IC loss does not exceed
the rating. If the voltage source applied to Vcc pin has relatively
high impedance and cannot supply the current of 14mA,
overvoltage protection function does not operate. But the
internal ZD maintains the Vcc voltage 32V or less and protects
the IC.
16
C2
6
FA551X
Where:
R1: Startup resistor [Ω]
C2: Capacitor between VCC and GND pin [F]
Vac: Effective value of AC input voltage [V]
V1=
D1
D1
D2
C2
6
C3
FA551X
Fig. 23
Startup circuit (4)
CL
Zn
Cs
5V
CS
8
FA551X
4
GND
Fig. 24
Independent setting of soft start period and OFF latch
deley
FA551X
6. Overvoltage protection using CS pin
These ICs contain the overvoltage protection function detecting
Vcc voltage. However, the threshold voltage is fixed. Adding a
circuit to CS pin enables the overvoltage protection detecting
desired voltage.
6.1 Detecting on secondary side
Figure 25 shows the overvoltage shutdown circuit based on the
signal from the secondary side. The optocoupler output
transistor is connected between the CS and VCC pins. When
the output voltage is put in the overvoltage state, the
optocoupler output transistor goes on to raise the CS pin
voltage via resistor R2. When the CS pin voltage exceeds the
reference voltage (8.5V) of internal comparator, the IC enters
the OFF latch mode and shuts the output down. The IC
consumes current 45µA (typ) (Vcc=10V) in latch mode. This
current must be supplied via startup resistor R1. The
overvoltage protection circuit can be reset by lowering the
supply voltage Vcc to below 9.0V or forcing the CS pin voltage
below 7.9V. In normal operation, the CS pin voltage is clamped
by the 4V zener diode with maximum sink current 45µA .
Therefore, to raise the CS pin voltage to 8.5V or more, 45µA or
a higher current needs to be supplied from the optocoupler. Set
the current input to the CS pin to 1mA or less.
6.2 Detecting on primary side (detecting Vcc voltage)
To attain overvoltage protection, the CS pin voltage is forcibly
raised from outside the IC until it exceeds the reference voltage
(8.5V) of the internal comparator C2. When the reference
voltage is exceeded, the IC enters latch mode and shuts the
output down. Connect a zener diode (ZD) and resistor between
the VCC and CS pins as shown in Figure 26. When the Vcc
voltage exceeds about ZD voltage +8.5V, the IC enters the OFF
latch mode and shuts the output down. If Vcc remains high
even after shutdown and current is input to the CS pin, set the
current to 1mA or lower. Set the zener voltage of the ZD
connected to the CS pin higher than the UVLO ON threshold
voltage. Startup is disabled below this voltage.
Figure 27 shows another circuit for enabling latch mode
shutdown by detecting a desired Vcc voltage using the CS pin.
In this circuit, overvoltage shutdown works when the Vcc
voltage is about the same as the ZD voltage. For this circuit
also, use a ZD voltage higher than the UVLO ON threshold
voltage. Set the current flowing into the CS pin to 1mA or lower.
7. Feedback pin circuit
Figure 28 gives an example of connection in which a feedback
signal is input to the FB pin. If this circuit causes power supply
instability, connect R3 and C4 as shown in Figure 28 to
decrease the frequency gain. Set R3 between several tens of
ohms to several kilohms and C4 between several thousand
picofarads to one microfarad.
If noise is applied to the FB pin, the output pulses may be
lacked or disturbed.
In this case, connect a capacitor C5 as shown in Fig. 29 to
suppress the noise applied to the FB pin. Set the capacitance
of C5 less than 10% of capacitance of C4 and connect C5 as
near the IC as possible.
~ +
Vin
Vout
C1
~ –
R1
R2
PC
Cs
C2
VCC
6
8
CS
FA551X
4
GND
Fig. 25
Overvoltage shutdown circuit (1)
CS
VCC
Fig. 26
6
Overvoltage shutdown circuit (2)
VCC
6
CS
Fig. 27
R2 ZD
8
R2
8
ZD
Cs
Overvoltage shutdown circuit (3)
Vout
5
PC1
FA551X OUT
Rs
2
FB
R3
PC1
Shunt
regulator
C4
Fig. 28
FB pin circuit (1)
5
FA551X OUT
Rs
4
2
FB
GND
C5
R3
PC1
C4
Fig. 29
FB pin circuit (2)
17
FA551X
8. Simple voltage control on the primary side
In a flyback type power supply, the output voltages of the power
supply and auxiliary winding voltage are almost proportional to
the number of winding turns of the transformer. This
characteristic can be used in the circuit shown in Figure 30,
where the output voltage can easily be made constant by
detecting the auxiliary winding voltage.
However, this is an easy output voltage control method, and the
output voltage precision and regulation are therefore not as
good.
To reduce output pulse width completely to 0%, the FB pin
voltage must fall below 0.9V and R5 must be set below about
1kΩ from the characteristics of the FB pin voltage and source
current.
C1
VCC
6
10. Polarities for overcurrent detecting and their
characteristics
The FA5510/11 uses positive polarity detection for overcurrent
limiting (number 3 pin of IS pin) and the FA5514/15 uses
negative polarity detection. The characteristics of positive and
negative polarity detection are summarized below. Select one
in accordance with the circuit used. (See item 4 in “Description
of each circuit.”)
n2
Vout
7
REF
FA551X
2
GND 4 FB
Fig. 30
9. Disabling the overload shutdown function
As shown in Figure 31, connect a 10kΩ resistor R6 between
the FB pin and the ground. The FB pin voltage then does not
rise sufficiently high to reach the shutdown threshold voltage
when an overload occurs so that IC does not enter OFF latch
mode. Use a 5% or better-precision resistor for R6.
Even with this connection, the overvoltage shutdown function is
available.
n1
n3
C2
R5
Simple voltage control circuit
FA551X
GND
FB 2
4
R3
R6
10kΩ
Fig. 31
C4
Disabling overload shutdown function
DB
T1
~ +
C1
AC input
~ –
Positive detection (FA5510/11)
• Wiring is easy because the ground can be shared by the main
circuit and IC peripherals.
• It is easy to correct the current detected as overload against
the input voltage.
R7
R8
FA5510/11
IS(+)
3
Rs
Negative detection (FA5514/15)
• The MOSFET drive current does not flow to the current
detection resistor and therefore it hardly affects overcurrent
detection.
11. Correcting overload detection current (FA5510/11 only)
If the power supply output is overloaded, the overcurrent
limiting function restricts the output power and the overload
shutdown function stops the IC. The output current when an
overload occurs varies depending on the input voltage; the
higher the input voltage, the more the overload detection
current may increase. If any problems occur as a result of the
appearance of this symptom, connect resistor R8 between
current detection resistor Rs and the IS (+) pin and add resistor
R7 for correction as shown in Figure 32. The standard
resistance of R8 is several hundred ohms, and that of R7 is
from several hundred kilohms to several megohms.
Note that the above correction slightly lowers the output current
when overload even where the input voltage is low. This
correction is available only for the FA5510/11 that uses positive
polarity for overcurrent detection.
18
Fig. 32
Correction of overload detection current
FA551X
12. Preventing malfunction caused by noise
Noise applied to each pin may cause malfunction of the IC. If
noise causes malfunction, see the notes summarized below
and confirm in actual circuit to prevent malfunction.
• The IS pin for overcurrent limiting function detects the
MOSFET current converted to the voltage. The parasitic
capacitor and inductor of the MOSFET, transformer, wiring,
etc. cause a noise in switching operation. If this switching
noise causes a malfunction of overcurrent limitimg function,
insert the RC filter into IS pin as shown in Figure 13 and 14.
Connect this capacitor as near the IC as possible to suppress
noise effectively.
• Connect a noise prevention capacitor (0.1µF or more) to the
REF pin that outputs the reference voltage for each
component.
OUT
FA551X
GND
Fig. 33
5
4
SBD
Protection of OUT pin against the negative voltage
Rg1 Rg2
FA551X
Fig. 34
5
OUT
Gate circuit
• If noise is applied to the FB pin, the output pulses may be
disturbed. In this case, see item 7 in “Design advice.”
• Relatively large noise may occur at the VCC pin because
large current flows from VCC pin to drive the MOSFET. Then
this noise may cause malfunction of the IC. In addition, the IC
may stop operation when Vcc voltage drops below the off
threshold voltage by noise. Mind that capacitance and
characteristics of the capacitor connected between VCC and
GND pin not to allow the large noise at the VCC pin. To
prevent malfunction, suppress the noise width below about
0.5µs or less and noise voltage below about ±0.6V or less.
13. Preventing malfunction caused by negative voltage
applied to a pin
When large negative voltage is applied to each IC pin, a
parasitic element in the IC may operate and cause malfunction.
Be careful not to allow the voltage applied to each pin to drop
below –0.3V. Especially for the OUT pin, voltage oscillation
caused after the MOSFET turns off may be applied to the OUT
pin via the parasitic capacitance of the MOSFET, causing the
negative voltage to be applied to the OUT pin. If the voltage
falls below –0.3V, add a Schottky diode between the OUT pin
and the ground. The forward voltage of the Schottky diode can
suppress the voltage applied to the OUT pin. Use the low
forward voltage of the Schottky diode.
Similarly, be careful not to cause the voltages at other pins to
fall below –0.3V.
14. Gate circuit configuration
To adjust switching speeds or prevent oscillation at gate
terminals, resistors are normally inserted between the power
MOSFET gate terminal to be driven and the OUT pin of the IC.
You may prefer to decide on the drive current independently, to
turn the MOSFET on and off. If so, connect the MOSFET gate
terminal to the OUT pin of the IC as shown in Figure 34. In this
circuit, Rg1 and Rg2 restrict the current when the MOSFET is
turned on, and only Rg1 restricts the current when it is turned
off.
19
FA551X
15. Loss calculation
IC loss must be confirmed to use the IC within the ratings.
Since it is hard to directly measure IC loss, some examples of
calculating approximate IC loss are given below.
15.1 Calculation example 1
Suppose the supply voltage is Vcc, IC current consumption is
lccop, the total gate charge of the power MOSFET is Qg, and
the switching frequency is fSW. Total IC loss Pd can be
calculated by:
When gate resistance differs between ON and OFF as shown
in Figure 36, the loss is given by:
Pdr =
This expression calculates an approximate value of Pd, which is
normally a little larger than the actual loss. Since various
conditions such as temperature characteristics apply,
thoroughly verify the appropriateness of the calculation under
all applicable conditions.
Example:
When Vcc=18V, lccop=2.5mA (max.) is obtained from the
specifications. Suppose Qg=80nC and fsw=100kHz.
)
Example:
When Vcc=18V, Qg=80nC, fsw=100kHz, and Rg=10Ω, the
typical IC loss is given by:
Pdr =
Pd ⱌ VCC ⫻ (ICCOP + Qg ⫻ fsw) ........................................ (12)
(
1
Ron
Roff
.... (15)
⫻VCC⫻Qg⫻fsw⫻
+
2
Rg1+Rg2+Ron Rg1+Roff
(
1
15Ω
7Ω
⫻ 18V ⫻ 80nC ⫻ 100kHz ⫻
+
2
10Ω+15Ω
10Ω+7Ω
=72.8mW
15.2.3 Total loss
The total loss (Pd) of the IC is the sum of the control circuit loss
(Pop) and the output circuit loss (Pdr) calculated previously:
Pd = Pop + Pdr .................................................................. (16)
Example:
The standard IC loss under the conditions used in (1) and (2)
above are:
Pd ⱌ 18V ⫻ (2.5mA + 80nC ⫻ 100kHz)
ⱌ 189mW
15.2 Calculation example 2
The IC loss consists of the loss caused by operation of the
control circuit and the loss caused at the output circuit to drive
the power MOSFET.
Pd = Pop + Pdr = 27mW + 72.8mW = 99.8mW
15.2.1 Loss at the control circuit
The loss caused by operation of the IC control circuit is
calculated by the supply voltage and IC current consumption.
When the supply voltage is Vcc and IC current consumption is
lccop, loss Pop at the control circuit is:
6
VCC
Qon
OUT
5
Pop = VCC ⫻ ICCOP ........................................................... (13)
Rg
Qoff
Example:
When Vcc=18, lccop=1.9mA (typ) is obtained from the
specifications. The typical IC loss is given by:
15.2.2 Loss at the output circuit
The output circuit of the IC is a MOSFET push-pull circuit.
When the ON resistances of MOSFETs making up the output
circuit are Ron and Roff, the resistances can be determined as
shown below based on Vcc=18V and Tj = 25˚C obtained from
the output characteristics shown in the specifications:
20
(
6
Output Circuit (1)
VCC
Qon
OUT
5
Qoff
Rg1
Rg2
GND
When the total gate charge of the power MOSFET is Qg, the
switching frequency is fSW, the supply voltage is Vcc, and gate
resistance is Rg, the loss caused at the IC output circuit is given
by:
1
Ron
Roff
⫻V CC ⫻Qg⫻fsw⫻
+
2
Rg + Ron Rg + Roff
GND
4
Ron = 15Ω (typ), Roff=7Ω (typ)
Pdr =
4
Fig. 35
Pop = 18V ⫻ 1.5mA = 27mW
) ...... (14)
)
Fig. 36
Output Circuit (2)
FA551X
■ Application circuit
FA5510
T1
80 to
F1
C114 C103
144V AC
250V/5A 0.47µF 4700p
D1
R101
510K
R102
510K
TH1
8D11
C203
1000pF
L2
C201
2200µF
C102
D3SBA60
0.22µF
R103
100kΩ
FG
R110
R109
10Ω
D4
2.2Ω
IC1
PC1
R117
2kΩ
8 7 6 5
1 2 3 4
0.1µF
R206
1kΩ
C205
1000pF
R205 C202
R102
R107
680Ω
C107
PC1
R208
1kΩ
R112
0.05Ω
PC2
D4
ERA91-02
ZD201
27V
GND
C204
0.022µF
R207
2.4kΩ
R209
470Ω
PC2
R119
33kΩ
47kΩ
C207
0.1µF
R210
100Ω
Q1
2SK1938
R104
100kΩ
R105
ESAD92M-02
4.7kΩ
C104
4700p
+24V
0 to 8.4A
L201
150µH
D2
ERA22-10
C105
200V/1000µF
TH2
8D11
D201
IC2
R201
18kΩ
R202
1kΩ
C206
0.1µF
10kΩ 0.1µF
R203
2.2kΩ
C106
47µF
C108
2200pF
C115
1000pF
FA5510
C109
0.22µF
C110
0.22µF
R106
33Ω
FA5511
C113
2200p
C101 C103
0.22µF 470p
TH1
DB
R101
510K
R102
430K
5D11
F1
250V/3A
C104
470p
L1
R110
130kΩ
R109
10Ω
100pF
1kΩ
GND
R207
2.4kΩ
R205
33kΩ
D4
ERA91-02
IC2
R206
1kΩ
C203
0.1µF
R201
18kΩ
R202
1kΩ
R203
2.2kΩ
8 7 6 5
C108
C204
0.022µF
R112
0.1Ω
R102
IC1
1 2 3 4
R117
R107
680Ω
C107
0.1µF
C202
470µF
PC1
D5
ERA91-02
R108
100Ω
62kΩ
C201
2200µF
Q1
2SK2101
R104
R105
L201
YG902C
D2
ERA22-10
C102
D3SBA60
0.22µF
+24V
0 to 1.46A
(Peak:2.71A)
10µH
ZD1
180V
C105
400V/220µF
R103
130kΩ
FG
D201
T1
4.7kΩ
80 to
264V AC
C106
10µF
FA5511
C109
0.22µF
C110
0.22µF
R106
24Ω
21
FA551X
FA5514
T1
80 to
C114 C103
144V AC F1
250V/5A 0.47µF 4700p
D1
R101
510K
R102
510K
TH1
8D11
C203
1000pF
C201
2200µF
C102
D3SBA60
0.22µF
R103
100kΩ
FG
R109
10Ω
C205
1000pF
R205 C202
D4
ERA91-02
ZD201
27V
IC2
R201
18kΩ
R202
1kΩ
C206
0.1µF
10kΩ 0.1µF
R203
2.2kΩ
C106
47µF
FA5514
2200pF
PC1
R117
C108 820Ω
0.1µF
D4
2.2Ω
8 7 6 5
C107
R206
1kΩ
R102
IC1
1 2 3 4
C115
1000pF
PC1
R208
1kΩ
R112
0.05Ω
PC2
GND
C204
0.022µF
R207
2.4kΩ
R209
470Ω
PC2
R119
33kΩ
R107
680Ω
C207
0.1µF
R210
100Ω
Q1
2SK1938
R104
100kΩ
R105
47kΩ
ESAD92M-02
4.7kΩ
L2
R110
C104
4700p
+24V
0 to 8.4A
L201
150µH
D2
ERA22-10
C105
200V/1000µF
TH2
8D11
D201
C109
0.22µF
C110
0.22µF
R106
33Ω
FA5515
C113
2200p
C101 C103
0.22µF 470p
TH1
DB
R101
510K
R102
430K
5D11
C104
470p
L1
C105
400V/220µF
R103
130kΩ
FG
R109
10Ω
D5
ERA91-02
130kΩ
R107
680Ω
8 7 6 5
C108
100pF
R205
33kΩ
C109
0.22µF
IC2
R206
1kΩ
C203
0.1µF
R203
2.2kΩ
C106
10µF
C110
0.22µF
R106
24Ω
Parts tolerances characteristics are not defined in the circuit design
sample shown above. When designing an actual circuit for a
product, you must determine parts tolerances and characteristics for
GND
R207
2.4kΩ
D4
ERA91-02
FA5515
safe and economical operation.
C204
0.022µF
R112
0.05Ω
IC1
1 2 3 4
62kΩ
C107
0.1µF
C202
470µF
PC1
R108
100Ω
R105
C201
2200µF
Q1
2SK2101
R104
22
L201
YG902C
D2
ERA22-10
C102
D3SBA60
0.22µF
+24V
0 to 1.46A
(Peak:2.71A)
10µH
ZD1
180V
4.7kΩ
F1
250V/3A
D201
T1
R110
80 to
264V AC
R201
18kΩ
R202
1kΩ