ETC FA5311BS

Bipolar IC
For Switching Power Supply
FA531XControl
series
FA531X series
■ Dimensions, mm
Á SOP-8
5
8
■ Description
5.3
The FA531X series are bipolar ICs for switching power supply
control that can drive a power MOSFET.
These ICs contain many functions in a small 8-pin package.
With these ICs, a high-performance and compact power
supply can be created because not many external discrete
components are needed.
8.2±0.3
FA5310BP(S), FA5314P(S), FA5316P(S)
FA5311BP(S), FA5315P(S), FA5317P(S)
4
1
°
0~10
Á DIP-8
5
8
1
4
9.3
1.5
3.4
• Switching power supply for general equipment
■ Block diagram
Á FA5310BP(S)/FA5311BP(S)/FA5316P(S)/FA5317P(S)
0.6
2.54±0.25
3.0min 4.5max
■ Applications
1.27±0.2
0.4±0.1
6.5
• Drive circuit for connecting a power MOSFET
• Wide operating frequency range (5 to 600kHz)
• Pulse-by-pulse overcurrent limiting function
• Overload cutoff function (Latch or non-protection mode
selectable)
• Output ON/OFF control function by external signal
• Overvoltage cutoff function in latch mode
• Undervoltage malfunction prevention function
• Low standby current (90µA typical)
• Exclusive choices by circuits (See selection guide on page 25)
• 8-pin package (DIP/SOP)
0.20
■ Features
2.0max
+0.1
–0.05
6.05
0.5±0.1
0.3
+0.1 5
–0.0
7.6
0~15
˚
5˚
0~1
Pin
No.
Pin
symbol
Description
1
RT
FB
Oscillator timing resistor
Overcurrent (+) detection
7
IS (+)
GND
OUT
VCC
CT
8
CS
Soft-start and ON/OFF control
Pin
No.
Pin
symbol
Description
1
RT
Oscillator timing resistor
2
FB
IS (–)
GND
OUT
VCC
Feedback
CT
CS
Oscillator timing capacitor
2
3
4
5
6
Feedback
Ground
Output
Power supply
Oscillator timing capacitor
Á FA5314P(S)/FA5315P(S)
3
4
5
6
7
8
Overcurrent (–) detection
Ground
Output
Power supply
Soft-start and ON/OFF control
25
FA531X series
■ Selection guide
Type
Max. duty
cycle (typ.)
UVLO (typ.)
Polarity of overcurrent
detection
ON threshold
OFF threshold
Max. output
current
Application
FA5310BP(S)
46%
+
16.0V
8.70V
1.5A
Forward type
FA5311BP(S)
70%
+
16.0V
8.70V
1.5A
Flyback type
FA5314P(S)
46%
–
15.5V
8.40V
1.5A
Forward type
FA5315P(S)
70%
–
15.5V
8.40V
1.5A
Flyback type
FA5316P(S)
46%
+
15.5V
8.40V
1.0A
Forward type
FA5317P(S)
70%
+
15.5V
8.40V
1.0A
Flyback type
■ Absolute maximum ratings
■ Recommended operating conditions
Item
Symbol
Rating
Unit
Item
Symbol
Min.
Max.
Unit
Supply voltage
VCC
31
V
Supply voltage
VCC
10
30
V
RT
3.3
1
10
10
kΩ
CS
fOSC
0.1
1
µF
5
600
kHz
IO
±1.5
±1.0
A
Oscillator timing resistance
FA5310/11
FA5314/15/16/17
VFB
VIS
4
V
Soft-start capacitor
–0.3 to +4
V
Oscillation frequency
CS terminal input current
ICS
2
mA
Total power dissipation
Pd
800 (DIP-8) * 1
mW
Output current
FA5310/11/14/15
FA5316/17
Feedback terminal input voltage
Overcurrent detection
terminal input voltage
550 (SOP-8) *2
(Ta=25°C)
Operating temperature
Junction temperature
Storage temperature
Topr
Tj
Tstg
–30 to +85
°C
125
°C
–40 to +150
°C
Notes:
*1 Derating factor Ta > 25°C : 8.0mW/°C (on PC board )
*2 Derating factor Ta > 25°C : 5.5mW/°C (on PC board )
■ Electrical characteristics (Ta=25°C, Vcc=18V, fOSC=135kHz)
Oscillator section
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
Oscillation frequency
fOSC
RT=5.1kΩ, CT=360pF
125
135
145
kHz
Frequency variation 1 (due to supply voltage change)
fdV
fdr
VCC=10 to 30V
±1
%
Ta=–30 to +85°C
±1.5
%
Frequency variation 1 (due to temperature change)
Pulse width modulation circuit section
Item
Symbol
Test condition
FA5310/14/16
Min.
Typ.
FA5311/15/17
Max. Min.
Typ.
Unit
Max.
–660 –800 –960 –660 –800 –960 µA
IFB
VTH FBO
VFB=0
Input threshold voltage (Pin 2)
Duty cycle =0%
0.75
0.75
V
Duty cycle =DMAX
1.80
2.30
V
Maximum duty cycle
VTH FBM
DMAX
Symbol
Test condition
Feedback terminal source current
43
46
49
66
70
74
%
Soft-start circuit section
Item
FA5310/14/16
FA5311/15/17
Unit
Min.
Typ.
Max. Min.
Typ.
Max.
–15
–10
–5
–10
–5
µA
Charge current (Pin 8)
ICHG
Pin 8=0V
Input threshold voltage (Pin 8)
VTH CSO
VTH CSM
Duty cycle =0%
0.90
0.90
V
Duty cycle =DMAX
1.90
2.30
V
26
–15
FA531X series
Overcurrent limiting circuit section
Item
Symbol
Input threshold voltage (Pin 3)
VTH IS
Overcurrent detection terminal source current
IIS
TPD IS
Pin 3=0V
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
CS terminal sink current
ISINK CS
VTH CS
Pin 8=6V, Pin 2=1V
25
45
65
µA
6.5
7.0
7.5
V
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
Cutoff-start voltage (Pin 2)
VTH FB
2.6
2.8
3.1
V
Delay time
Test condition
FA5310/11/16/17
FA5314/15
Min.
Typ.
Max. Min.
0.21
0.24
0.27
Typ.
Unit
Max.
–0.21 –0.17 –0.14 V
–300 –200 –100 –240 –160 –80
150
200
µA
ns
Latch-mode cutoff circuit section
Cutoff threshold voltage (Pin 8)
Overload cutoff circuit section
Undervoltage lockout circuit section
Item
Symbol
Test condition
FA5310/11
FA5314/15/16/17
Min.
Typ.
Max. Min.
Typ.
Max.
Unit
OFF-to-ON threshold voltage
VCC ON
15.5
16.0
16.5
14.8
15.5
16.2
V
ON-to-OFF threshold voltage
VCC OFF
8.20
8.70
9.20
7.70
8.40
9.10
V
Output section
Item
Symbol
Test condition
Min.
FA5310/11/14/15
FA5316/17
L-level output Voltage
H-level output Voltage
VOL
VOH
IO=100mA
IO=–100mA
VCC=18V
IO=50mA
IO=–50mA
VCC=18V
Rise time
tr
No load
Fall time
tf
No load
Item
Symbol
Test condition
Min.
Typ.
Max.
Unit
CS terminal source current
Isource cs Pin 8=0V
VTH ON
CS terminal voltage OFF→ON
VTH OFF CS terminal voltage ON→OFF
–15
–10
–5
µA
Item
Symbol
Test condition
Min.
Standby current
ICC ST
ICC OP
ICC OFF
ICCL
VCC=14V
16.0
Typ.
Max.
Unit
1.30
1.80
V
16.5
V
No load
50
ns
No load
50
ns
Output ON/OFF circuit section
OFF-to-ON threshold Voltage (Pin 8)
ON-to-OFF threshold Voltage (Pin 8)
0.56
V
0.42
V
Overall device
Operating-state supply current
OFF-state supply current
Cutoff-state supply current
Typ.
Max.
Unit
90
150
µA
9
15
mA
1.1
1.8
mA
1.1
1.8
mA
27
FA531X series
■ Description of each circuit
1. Oscillator (See block diagram)
The oscillator generates a triangular waveform by charging and
discharging a capacitor. CT pin voltage oscillates
between an upper limit of approx. 3.0V and a lower limit of
approx. 1.0V. The oscillation frequency is determined by a
external resistance and capacitance shown in figure 1, and
approximately given by the following equation:
106
.........(1)
4RT (kΩ) • CT (pF)
The recommended oscillation range is between 5k and
600kHz.
The oscillator output is connected to a PWM comparator.
f (kHZ) =
Fig. 1 Oscillator
2. Feedback pin circuit
Figure 2 gives an example of connection in which an
optocoupler is used to couple the feedback signal to the FB pin.
It is designed to be strong against noise and will not create
parasitic oscillation so much, because the output impedance at
the FB pin is as low as 4k to 5k. If this circuit causes power
supply instability, the frequency gain can be decreased by
connecting R4 and C4 as shown in figure 2. R4 should be
between several tens of ohms to several kiloohms and C4
should be between several thousand picofarads to one
microfarads.
3. PWM comparator
The PWM comparator has four inputs as shown in Figure 3.
Oscillator output ① is compared with CS pin voltage ➁, FB pin
voltage ➂, and DT voltage ④. The lowest of three inputs ➁, ➂,
and ④ is compared with output ①. If it is lower than the
oscillator output, the PWM comparator output is high, and if it is
higher than the oscillator output, the PWM comparator
output is low (see Fig. 4).
The IC output voltage is high during when the comparator
output is low, and the IC output voltage is low during when the
comparator output is high.
When the IC is powered up, CS pin voltage ➁ 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 set by DT voltage ④ under the
condition set by feedback signal ➂, to stabilize the output
voltage.
Fig. 2 Configuration with optocoupler (FB pin input)
Fig. 3 PWM comparator
Fig. 4 PWM comparator timing chart
28
FA531X series
4. CS pin circuit
As shown in Figure 5 capacitor CS is connected to the CS pin.
When power is turned on, the constant current source (10µA)
begins to charge capacitor CS. Accordingly, the CS pin
voltage rises as shown in Figure 6. The CS pin is connected to
an input of the PWM comparator. The device is in soft-start
mode while the CS pin voltage is between 0.9V and 1.9V
(FA5310/14/16) and between 0.9V and 2.3V(FA5311/15/17).
During normal operation, the CS pin is clamped at 3.6V by
internal zener diode Zn. If the output voltage drops due to an
overload, etc., the clamp voltage shifts from 3.6V to 8.0V. As a
result, the CS pin voltage rises to 8.0V. The CS pin is also
connected to latch comparator C2. If the pin voltage rises
above 7.0V, the output of comparator C2 goes high to turn off
the bias circuit, thereby shutting the output down. Comparator
C2 can be used not only for shutdown in response to an
overload, but also for shutdown in response to an overvoltage.
Comparator C1 is also connected to the CS pin, and the bias
circuit is turned off and the output is shut down if the CS pin
voltage drops below 0.42V. In this way, comparator C1 can
also be used for output on/off control.
As explained above, the CS pin can be used for soft-start
operation, overload and overvoltage output shutdown and
output on/off control.
Further details on the four functions of the CS pin are given
below.
4.1 Soft start function
Figure 7 shows the soft start circuit. Figure 8 is the soft-start
operation timing chart. The CS pin is connected to capacitor
CS. When power is turned on, a 10µA constant-current source
begins to charge the capacitor. As shown in the timing chart,
the CS pin voltage rises slowly in response to the charging
current. The CS pin is connected internally to the PWM
comparator. The comparator output pulse slowly widens as
shown in the timing chart.
The soft start period can be approximately evaluated by the
period ts from the time the IC is activated to the time the output
pulse width widens to 30%. Period ts is given by the following
equation:
Fig. 5 CS pin circuit
Fig. 6 CS pin waveform
tS (mS)=160CS(µF)...................................(2)
Fig. 7 Soft-start circuit
Fig. 8 Soft-start timing chart
29
FA531X series
4.2 Overload shutdown
Figure 9 shows the overload shutdown circuit, and Figure 10 is
a timing chart which illustrates overload shutdown operation.
If the output voltage drops due to an overload or short-circuit,
the output voltage of the FB pin rises. If FB pin voltage
exceeds the reference voltage (2.8V) of comparator C3, the
output of comparator C3 switches low to turn transistor Q off.
In normal operation, transistor Q is on and the CS pin is
clamped at 3.6V by zener diode Zn. With Q off, the clamp is
released and the 10µA constant-current source begins to
charge capacitor CS again and the CS pin voltage rises. When
the CS pin voltage exceeds the reference voltage (7.0V) of
comparator C2, the output of comparator C2 switches high to
turn the bias circuit off. The IC then enters the latched mode
and shuts the output down. Shutdown current consumption is
400µA(VCC=9V). This current must be supplied through the
startup resistor. The IC then discharges the MOSFET gates.
Shutdown operation initiated by an overload can be reset by
lowering supply voltage VCC below VCC OFF or forcing the CS
pin voltage below 7.0V.
The period tOL from the time that the output is short-circuited to
the time that the bias circuit turns off is given by the following
equation:
Fig. 9 Overload shutdown circuit
tOL(mS)=340Cs(µF)................................ ........... (3)
4.3 Overvoltage shutdown
Figure 11 shows the overvoltage shutdown circuit, and Figure
12 is a timing chart which illustrates overvoltage shutdown
operation.
The optocoupler PC1 is connected between the CS and VCC
pins. If the output voltage rises too high, the PC1 turns on to
raise the voltage at the CS pin via resistor R6. When the CS
pin voltage exceeds the reference voltage (7.0V) of
comparator C2, comparator C2 switches high to turn the bias
circuit off. The IC then enters the latched mode and shuts the
output down. The shutdown current consumption of the IC is
400µA(VCC=9V). This current must be applied via startup
resistor R5.
The IC then discharges the MOSFET gates.
The shutdown operation initiated by an overvoltage condition
can be reset by lowering supply voltage VCC below V CC OFF or
forcing the CS pin voltage below 7.0V.
During normal operation, the CS pin is clamped by a 3.6V
zener diode with a sink current of 65µA max. Therefore, a
current of 65µA or more must be supplied by the optocoupler
in order to raise the CS pin voltage above 7.0V.
Fig. 10 Overload shutdown timing chart
Fig. 11 Overvoltage shutdown circuit
Fig. 12 Overvoltage shutdown timing chart
30
FA531X series
4.4 Output ON/OFF control
The IC can be turned on and off by an external signal applied
to the CS pin.
Figure 13 shows the external output on/off control circuit, and
Figure 14 is the timing chart.
The IC is turned off if the CS pin voltage falls below 0.42V. The
output of comparator C1 switches high to turn the bias circuit
off. This shuts the output down. The IC then discharges the
MOSFET gates.
The IC turns on if the CS pin is opened for automatic soft start.
The power supply then restarts operation.
5. Overcurrent limiting circuit
The overcurrent limiting circuit detects the peak value of every
drain current pulse of the main switching MOSFET to limit the
overcurrent.
The detection threshold is + 0.24V for FA5310B/11B/16/17
with respect to ground as shown in Figure 15.
The drain current of the MOSFET is converted to voltage by
resistor R7 and fed to the IS pin of the IC. If the voltage
exceeds the reference voltage (0.24V) of comparator C4, the
output of comparator C4 goes high to set flip-flop output Q
high. The output is immediately turned off to shut off the
current. Flip-flop output Q is reset on the next cycle by the
output of the oscillator to turn the output on 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 the MOSFET.
Figure 16 is a timing chart which illustrates current-limiting
operations.
Fig. 13 External output on/off control circuit
Fig. 14 Timing chart for external output on/off control
Fig. 15 Overcurrent limiting circuit for FA5310/11/16/17
Fig. 16 Overcurrent timing chart for FA5310/11/16/17
31
FA531X series
The detection threshold is -0.17V for FA5314/15 with respect to
ground as shown in Figure 17.
The operation is similar to that of FA5310B/11B/16/17 except
the threshold is minus voltage compared to that which is plus
voltage for FA5310B/11B/16/17.
Figure 18 is a timing chart which illustrates current limiting
operations.
6. Undervoltage lockout circuit
The IC incorporates a circuit which prevents the IC from
malfunctioning when the supply voltage drops. When the
supply voltage is raised from 0V, the IC starts operation with
VCC=VCC ON.
If the supply voltage drops, the IC shuts its output down when
VCC=VCC OFF. When the undervoltage lockout circuit operates,
the CS pin goes low to reset the IC.
7. Output circuit
As shown in Figure 19, the IC's totem-pole output can directly
drive the MOSFET. The OUT pin can source and sink currents
of up to 1.5A or 1.0A.
If IC operation stops when the undervoltage lockout circuit
operates, the gate voltage of the MOSFET goes low and the
MOSFET is shut down.
Fig. 17 Overcurrent limiting circuit for FA5314/15
CS pin voltage (3.6V)
DT voltage
Oscillator output
OUT pin output
FB pin voltage
H
L
IS ( – ) pin voltage
Minus
detection
Comparator C4
Reference
voltage (– 0.17V)
Bias voltage
OFF
Overcurrent limiting
Fig. 18 Overcurrent timing chart for FA5314/15
Fig. 19 Output circuit
32
FA531X series
■ Design advice
1. Startup circuit
It is necessary to start-up IC that the voltage inclination of
VCC terminal “dVcc/dt” satisfies the following equation(4).
dVcc/dt(V/s)>1.8/Cs(µF)...............................(4)
Cs : Capacitor connected between CS terminal and GND
Note that equation (4) must be satisfied in any condition. Also,
it is necessary to keep “latch mode” for overload protection or
overvoltage protection that the current supplied to VCC
terminal through startup resistor satisfies the following
equation(5).
Icc(Lat)> 0.4mA for Vcc % 9.2V ..................(5)
Icc(Lat) : Cutoff-state( = Latch mode ) supply current
The detail is explained as follows.
Fig. 20 Startup circuit example(1)
(1) Startup circuit connected to AC line directly
Fig. 20 shows a typical startup circuit that a startup
resistor Rc is connected to AC line directly. The period from
power-on to startup is determined by Rc, RD and CA. Rc, R D
and CA must be designed to satisfy the following equations.
dVcc/dt(V/s)=
(1/CA ) • {(VAVE–Vccon )/RC–Vccon/RD–Iccst} >
1.8/(Cs(µF))................................................(6)
Rc(kΩ)< (VAVE–9.2(V))/{0.4 (mA) + (9.2(V)/RD(kΩ) } ...........(7)
VAVE = Vac •E2/π : Average voltage applied to AC line side of Rc
Vac:
AC input effective voltage
Vccon: ON threshold of UVLO, 16.5V(max.) or 16.2V(max.)
Iccst: Standby current, 0.15 mA(max.)
In this method, Vcc voltage includes ripple voltage influenced
by AC voltage. Therefore, enough dVcc/dt required by
equation (6) tend to be achieved easily when Vcc reaches to
Vccon even if Vcc goes up very slowly. After power-off, Vcc
does not rise up because a voltage applied from bias winding
to VCC terminal decreases and the current flowing R C becomes zero, therefore, re-startup does not occur after Vcc falls
down below OFF threshold of UVLO until next power-on.
33
FA531X series
(2) Startup circuit connected to rectified line
This method is not suitable for FA531X, especially concerned
with re-startup operation just after power-off or startup which
AC input voltage goes up slowly. Fig. 21 shows a startup
circuit that a startup resistor RA is connected to rectified line
directly.
The period from power-on to startup is determined by RA , RB
and CA. RA, RB and CA must be designed to satisfy the
following equations.
dVcc/dt(V/s)=
(1/CA)•{( VIN –Vccon )/RA – Vccon/RB–Iccst } >
1.8/(Cs(µF))..........................................(8)
RA(kΩ) < ( VIN– 9.2(V) )/{ 0.4(mA) + ( 9.2(V)/RB(kΩ) ) }....(9)
VIN : E2 • (AC input effective voltage)
After power-off, once VCC falls down below OFF threshold
voltage, VCC rises up again and re-startup occurs while the
capacitor C1 is discharged until approximately zero because
VCC voltage rises up by the current flowing RA.
This operation is repeated several times.
After the repeated operation, IC stops in the condition that VCC
voltage is equal to Vccon (=ON threshold) because capacitor
C1 is discharged gradually and the decreased VCC inclination
is out of the condition required by equation (4). After that, restartup by power-on can not be guaranteed even when
equation (8) is satisfied.
The image of that the startup is impossible is shown in Fig. 22.
It is necessary to startup IC that supply current Icc(startup) to
VCC is over 4mA in the condition of Tj < 100°C during Vcc is
kept at Vccon(616V, balance state at Vccon after the repeated
operation.
Fig. 21 Startup circuit example(2)
Startup is impossible (dVcc/dt <1.8/Cs
just before Vcc reaches Vccon).
Icc>4mA is necessary for startup at
Tj <100°C and dVcc/dt=0.
Power OFF
Power ON
Vccon
Startup is impossible
Icc(start-up) > 4mA
at Vcc=Vccon, Tj<100°C, after power-off
This balance state that startup is impossible tends to occur at
higher temperature. If power-on is done when Vcc is not kept
at Vccon (for example:power-off is done and after enough time
that C1 is discharged until Vcc can not be pulled up to Vccon),
the IC can startup in the condition given by equation(8).
Vccoff
Fig. 22 A image of waveform when re-startup is impossible
In some cases, such as when the load current of power supply
is changed rapidly, you may want to prolong the hold time of
the power supply output by means of maintaining Vcc over the
off threshold.
For this purpose, connect diode D4 and electrolytic capacitor
C4 as shown in Fig. 23. This prolongs the hold time of the
power supply voltage Vcc regardless of the period from poweron to startup.
Fig. 23 Startup circuit example(3)
34
FA531X series
2. Disabling overload shutdown function
As shown in Figure 24, connect a 11kΩ resistor between the
FB pin and ground. Then, the CS pin voltage does not rise
high enough to reach the reference voltage (7.0V) of the latch
comparator, and the IC does not enter the OFF latch mode.
With this connection, the overvoltage shutdown function is
available.
3. Setting soft start period and OFF latch delay
independently
Figure 25 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 and
overvoltage shutdown functions raise the CS pin voltage to
around 5V, zener diode Zn becomes conductive to charge C L.
The OFF latch delay can be thus prolonged by CL.
Fig. 25 Independent setting of soft-start period
and OFF latch delay
4. Laying out VCC and ground lines
Figure 26 and 27 show the recommended layouts of VCC and
ground lines. The bold lines represent paths carrying large
currents. The lines must have an adequate thickness.
5.Sink current setting for CS terminal
A sink current to CS terminal must be satisfied the following
condition to prevent from the malfunction which uncontrolled
pulse output generates at OUT terminal when latch-mode
protection should be operated for overvoltage.
65µA < Ics(sink) < 500µA at Vcs= 6.5(V)
Ics(sink) : Sink current to CS terminal
Example (for the circuit shown in Fig. 28 )
Ics(sink) = (28(V)–18(V)– 6.5(V) )/7.5(kΩ)
6 467 (µA) < 500 (µA)
Fig. 26 Vcc line and ground line (1) for FA5310B/11B/16/17
Fig. 27 Vcc line and ground line (2) for FA5314/15
7.5kΩ
18V Zener diode
CS
Fig. 24 Disabling overload shutdown function
Under 500µA
VCC
Fig. 28 Setting sink current for CS terminal
35
FA531X series
6. Notice for high frequency operation
(1) The final pulse
These ICs have the original characteristics about the pulse
width at OUT terminal when the IC is stopped by undervoltage
lockout, ON/OFF function, or latched mode for overload or
overvoltage.
When the IC is stopped, the final pulse width is 2µs(max.)
longer than normal pulse width as shown in Figure. 29.
Here, normal pulse width "Aµs" is determined by measured
condition of the power supply unit, and whole width of final
pulse is "A+2µs(max.)".
Take care of a longer pulse mentioned above for designing or
testing the circuit of power supply units.
(2) Power dissipation and heating
The power dissipation of IC increases and the temperature
becomes higher in proportion to the operating frequency,
because the driving power of a switching device and the
through current of output stage of IC increase.
Determine the oscillation frequency so that the junction
temperature (Tj) does not rise to 125˚C.
Tj is calculated as following equation roughly.
Tj = Tc + θj - c • Vcc • Icc
Tc: Case temperature
Vcc: VCC voltage
36
θj-c: Thermal resistance between the junction
and the case (=50˚C/W)
I CC : Supply current at the VCC terminal
Fig. 29 OUT terminal voltage wavefrom
FA531X series
■ Characteristic curves (Ta=25°C)
Oscillation frequency (fOSC ) vs.
timing capacitor capacitance (C T)
Oscillation frequency (fOSC ) vs. ambient temperature (Ta)
Output duty cycle vs. FB terminal voltage (VFB)
Output duty cycle vs. FB terminal source current
(ISOURCE)
Output duty cycle vs. CS terminal voltage (VCS )
CS terminal sink current (ISINK CS) vs.
CS terminal voltage (VCS )
37
FA531X series
H-level output voltage (VOH) vs. output source current (ISOURCE)
FA5310/11/14/15
FA5316/17
5
VCC=18V
VCC–VOH [V]
4
3
2
1
0 –2
10
2
5
10–1
2
5
100
2
100
2
ISOURCE [A]
L-level output voltage(VOL) vs. output sink current (ISINK )
FA5310/11/14/15
FA5316/17
5
VCC=18V
4
VOL [V]
3
2
1
0 –2
10
2
5
10–1
5
2
ISINK [A]
IS (+) terminal threshold voltage (VTH IS(+)) vs.
ambient temperature (Ta)
FA5310/11/16/17
IS (–) terminal threshold voltage (VTH IS(–)) vs.
ambient temperature (Ta)
FA5314/15
–190
VTHIS(–) [mV]
–180
–170
–160
–150
–140
–25
0
25
Ta [˚C]
38
50
75
100
FA531X series
IS (+) terminal current (IIS(+)) vs.
IS (+) terminal voltage (VIS(+))
FA5310/11/16/17
IS (-) terminal current (IIS(-) ) vs.
IS (-) terminal voltage (IIS(-) )
FA5314/15
600
–200
500
–180
400
–160
–140
IIS(–) [µA]
IIS(+) [µA]
300
200
100
–120
–100
–80
0
–60
–100
–40
–200
–300
–20
0
0.1
0.2
0.3
0.4
0.5
0.6
0
–0.1
–0.2
VIS(+) [V]
Supply current (ICC ) vs. supply voltage (VCC)
Ordinary operation
FA5310/11
–0.5
11
fosc=600kHz
fosc=600kHz
10
10
9
9
fosc=135kHz
8
8
7
7
6
6
ICC [mA]
ICC [mA]
–0.4
FA5314/15/16/17
11
5
0.2
0.1
0.1
5
10
15
20
25
fosc=135kHz
5
0.2
0
0
30
5
10
Supply current (ICC ) vs. supply voltage (VCC)
OFF or OFF latch mode
FA5310/11
1.8
1.8
1.6
1.6
1.4
1.4
1.2
1.2
ICC [mA]
2.0
1.0
0.8
0.6
0.6
0.4
0.4
0.2
0.2
10
15
VCC [V]
25
30
20
25
30
1.0
0.8
5
20
FA5314/15/16/17
2.0
0
15
VCC [V]
VCC [V]
ICC [mA]
–0.3
VIS(–) [V]
20
25
30
0
5
10
15
VCC [V]
39
FA531X series
■ Application circuit
Á Example of FA5310B application circuit
Á Example of FA5311B application circuit
40
FA531X series
Á Example of FA5314 application circuit
Á Example of FA5315 application circuit
41
FA531X series
Á Example of FA5316 application circuit
Á Example of FA5317 application circuit
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
safe and economical operation.
42