FAIRCHILD FSDL0365RL

www.fairchildsemi.com
FSDH321, FSDL321
Green Mode Fairchild Power Switch (FPSTM)
Features
• Internal Avalanche Rugged Sense FET
• Consumes only 0.65W at 240VAC & 0.3W load with
Advanced Burst-Mode Operation
• Frequency Modulation for EMI Reduction
• Precision Fixed Operating Frequency
• Internal Start-up Circuit
• Pulse-by-Pulse Current Limiting
• Abnormal Over Current Protection (AOCP)
• Over Voltage Protection (OVP)
• Over Load Protection (OLP)
• Internal Thermal Shutdown Function (TSD)
• Auto-Restart Mode
• Under Voltage Lockout (UVLO)
• Low Operating Current (max 3mA)
• Adjustable Peak Current Limit
• Built-in Soft Start
Applications
• SMPS for STB, Low cost DVD Player
• Auxiliary Power for PC
• Adapter & Charger
Related Application Notes
• AN-4137, 4141, 4147(Flyback) / AN-4134(Forward)
Description
Each product in the FSDx321 (x for H, L) family consists of
an integrated Pulse Width Modulator (PWM) and Sense
FET, and is specifically designed for high performance offline Switch Mode Power Supplies (SMPS) with minimal
external components. Both devices are integrated high voltage power switching regulators which combine an avalanche
rugged Sense FET with a current mode PWM control block.
The integrated PWM controller features include: a fixed
oscillator with frequency modulation for reduced EMI,
Under Voltage Lock Out (UVLO) protection, Leading Edge
Blanking (LEB), an optimized gate turn-on/turn-off driver,
Thermal Shut Down (TSD) protection, Abnormal Over Current Protection (AOCP) and temperature compensated precision current sources for loop compensation and fault
protection circuitry. When compared to a discrete MOSFET
and controller or RCC switching converter solution, the
FSDx321 devices reduce total component count, design size,
weight while increasing efficiency, productivity and system
reliability. Both devices provide a basic platform that is well
suited for the design of cost-effective flyback converters.
FPSTM is a trademark of Fairchild Semiconductor Corporation.
©2005 Fairchild Semiconductor Corporation
OUTPUT POWER TABLE
230VAC ±15%(3)
85-265VAC
PRODUCT
Adapter(1)
Open
Frame(2)
Adapter(1)
Open
Frame(2)
FSDL321
11W
17W
8W
12W
FSDH321
11W
17W
8W
12W
FSDL0165RN
13W
23W
11W
17W
FSDM0265RN
16W
27W
13W
20W
FSDH0265RN
16W
27W
13W
20W
FSDL0365RN
19W
30W
16W
24W
FSDM0365RN
19W
30W
16W
24W
FSDL321L
11W
17W
8W
12W
FSDH321L
11W
17W
8W
12W
FSDL0165RL
13W
23W
11W
17W
FSDM0265RL
16W
27W
13W
20W
FSDH0265RL
16W
27W
13W
20W
FSDL0365RL
19W
30W
16W
24W
FSDM0365RL
19W
30W
16W
24W
Notes:
1. Typical continuous power in a non-ventilated enclosed
adapter with sufficient drain pattern as a heat sinker, at
50°C ambient.
2. Maximum practical continuous power in an open frame
design with sufficient drain pattern as a heat sinker, at 50°C
ambient.
3. 230 VAC or 100/115 VAC with doubler.
Typical Circuit
AC
IN
DC
OUT
Vstr
Ipk
Drain
PWM
Vfb
Vcc
Source
Figure 1. Typical Flyback Application
Rev.1.0.5
FSDH321, FSDL321
Internal Block Diagram
Vstr
5
Vcc
2
ICH
+
V BURH
-
8V/12V
Vcc good
Vcc
V BURL /V BURH
IBUR(pk)
Vcc
Drain
6,7,8
Internal
Bias
Vref
Freq.
Modulation
Vcc
OSC
IDELAY
Vfb
I FB
Normal
3
2.5R
Ipk
4
Soft
Start
PWM
Burst
S
Q
R
Q
Gate
driver
R
LEB
V SD
1 GND
Vcc
S
Q
R
Q
Vovp
Vcc good
AOCP
Vocp
TSD
Figure 2. Functional Block Diagram of FSDx321
2
FSDH321, FSDL321
Pin Definitions
Pin Number
Pin Name
1
GND
Sense FET source terminal on primary side and internal control ground.
Vcc
Positive supply voltage input. Although connected to an auxiliary transformer winding, current is supplied from pin 5 (Vstr) via an internal switch during
startup (see Internal Block Diagram section). It is not until Vcc reaches the
UVLO upper threshold (12V) that the internal start-up switch opens and device power is supplied via the auxiliary transformer winding.
Vfb
The feedback voltage pin is the non-inverting input to the PWM comparator.
It has a 0.9mA current source connected internally while a capacitor and optocoupler are typically connected externally. A feedback voltage of 6V triggers over load protection (OLP). There is a time delay while charging
external capacitor Cfb from 3V to 6V using an internal 5uA current source.
This time delay prevents false triggering under transient conditions, but still
allows the protection mechanism to operate under true overload conditions.
Ipk
This pin adjusts the peak current limit of the Sense FET. The feedback
0.9mA current source is diverted to the parallel combination of an internal
2.8kΩ resistor and any external resistor to GND on this pin to determine the
peak current limit. If this pin is tied to Vcc or left floating, the typical peak current limit will be 0.7A.
Vstr
This pin connects directly to the rectified AC line voltage source. At start up
the internal switch supplies internal bias and charges an external storage
capacitor placed between the Vcc pin and ground. Once the Vcc reaches
12V, the internal switch is opened.
Drain
The drain pins are designed to connect directly to the primary lead of the
transformer and are capable of switching a maximum of 650V. Minimizing
the length of the trace connecting these pins to the transformer will decrease
leakage inductance.
2
3
4
5
6, 7, 8
Pin Function Description
Pin Configuration
8DIP
8LSOP
GND 1
8 Drain
Vcc 2
7 Drain
Vfb 3
6 Drain
Ipk 4
5 Vstr
Figure 3. Pin Configuration (Top View)
3
FSDH321, FSDL321
Absolute Maximum Ratings
(Ta=25°C, unless otherwise specified)
Characteristic
Symbol
Value
Unit
Drain Pin Voltage
VDRAIN
650
V
Vstr Pin Voltage
VSTR
650
V
Drain-Gate Voltage
VDG
650
V
Gate-Source Voltage
VGS
Drain Current Pulsed(1)
IDM
± 20
1.5
A
Continuous Drain Current (Tc=25℃)
ID
0.7
A
Continuous Drain Current (Tc=100℃)
ID
0.32
A
EAS
10
mJ
Single Pulsed Avalanche Energy
(2)
V
Supply Voltage
VCC
20
V
Feedback Voltage Range
VFB
-0.3 to VCC
V
Total Power Dissipation
PD
1.40
W
Operating Junction Temperature
TJ
Internally limited
°C
Operating Ambient Temperature
TA
-25 to +85
°C
TSTG
-55 to +150
°C
Storage Temperature
Note:
1. Repetitive rating: Pulse width is limited by maximum junction temperature
2. L = 24mH, starting Tj = 25°C
Thermal Impedance
(Ta=25°C, unless otherwise specified)
Parameter
Symbol
Value
Unit
θJA
θJC
88.84
°C/W
13.94
°C/W
8DIP
Junction-to-Ambient Thermal(1)
Junction-to-Case Thermal(2)
Note:
1. Free standing with no heatsink; Without copper clad.
/ Measurement Condition : Just before junction temperature TJ enters into OTP.
2. Measured on the DRAIN pin close to plastic interface.
- all items are tested with the standards JESD 51-2 and 51-10 (DIP).
4
FSDH321, FSDL321
Electrical Characteristics
(Ta = 25°C unless otherwise specified)
Parameter
SENSE FET SECTION
Zero-Gate-Voltage Drain Current
Drain-Source On-State Resistance
Forward Trans-Conductance(1)
Input Capacitance
Output Capacitance
Reverse Transfer Capacitance
Turn-On Delay Time
Rise Time
Turn-Off Delay Time
Fall Time
Total Gate Charge
Gate-Source Charge
Gate-Drain (Miller) Charge
CONTROL SECTION
Switching Frequency
Switching Frequency Modulation
Switching Frequency
Switching Frequency Modulation
Switching Frequency Variation(2)
Maximum Duty Cycle
UVLO Threshold Voltage
Feedback Source Current
Internal Soft Start Time
BURST MODE SECTION
Burst Mode Voltage
Symbol
Condition
Min.
Typ.
Max.
IDSS
VDS=650V, VGS=0V
VDS=520V, VGS=0V, TC=125°C
1.0
-
14
1.3
162
18
3.8
9.5
19
33
42
7.0
3.1
0.4
25
200
19
-
90
±2.5
45
±1.0
62
71
11
7
0.7
10
100
±3.0
50
±1.5
±5
67
77
12
8
0.9
15
110
±3.5
55
±2.0
±10
72
83
13
9
1.1
20
KHz
KHz
KHz
KHz
%
%
%
V
V
mA
ms
0.4
0.25
-
0.5
0.35
150
0.6
0.45
-
V
V
mV
Tj=25°C, ∆i/∆t=250mA/us 0.60
Tj=25°C
125
5.5
18
VFB=4V
3.5
200
0.70
600
145
6.0
19
5.0
-
0.80
6.5
20
6.5
-
A
ns
°C
V
V
µA
ns
VCC=14V, VFB=0V
VCC=0V
VCC=0V
3
0.85
-
5
1.0
-
mA
mA
V
RDS(ON)
gfs
CISS
COSS
CRSS
td(on)
tr
td(off)
tf
Qg
Qgs
Qgd
fOSC
∆fMOD
fOSC
∆fMOD
∆fOSC
DMAX
VSTART
VSTOP
IFB
tS/S
VBURH
VBURL
VGS=10V, ID=0.5A
VDS=50V, ID=0.5A
VGS=0V, VDS=25V,
f=1MHz
VDS=325V, ID=1.0A
VGS=10V, ID=1.0A,
VDS=325V
FSDH321
FSDL321
-25°C ≤ Ta ≤ 85°C
FSDH321
FSDL321
VFB=GND
VFB=GND
VFB=GND
VFB=4V
Tj=25°C
VBUR(HYS) Hysteresis
PROTECTION SECTION
Peak Current Limit
Current Limit Delay Time(3)
Thermal Shutdown Temperature(3)
Shutdown Feedback Voltage
Over Voltage Protection
Shutdown Delay Current
Leading Edge Blanking Time
TOTAL DEVICE SECTION
Operating Supply Current (control part only)
Start-Up Charging Current
Vstr Supply Voltage
ILIM
tCLD
TSD
VSD
VOVP
IDELAY
tLEB
IOP
ICH
VSTR
1
0.7
35
Unit
µA
Ω
S
pF
ns
nC
Note:
1. Pulse test: Pulse width ≤ 300us, duty ≤ 2%
2. These parameters, although guaranteed, are tested in EDS (wafer test) process
3. These parameters, although guaranteed, are not 100% tested in production
5
FSDH321, FSDL321
Comparison Between FSDM311 and FSDx321
Function
6
FSDM311
FSDx321
FSDx321 Advantages
Soft-Start
15ms
15ms
(same for both devices)
• Gradually increasing current limit
during soft-start further reduces peak
current and voltage stresses
• Eliminates external components used
for soft-start in most applications
• Reduces or eliminates output
overshoot
External Current Limit
not applicable
Programmable of
default current limit
• Smaller transformer
• Allows power limiting (constant overload power)
• Allows use of larger device for lower
losses and higher efficiency.
Frequency Modulation
not applicable
±3.0KHz @100KHz
±1.5KHz @50KHz
• Reduces conducted EMI
Burst Mode Operation
Built into controller
Built into controller
(same for both devices)
• Improves light load efficiency
• Reduces power consumption at noload
• Transformer audible noise reduction
Drain Creepage at
Package
7.62mm
7.62mm
(same for both devices)
• Greater immunity to arcing provoked
by dust, debris and other contaminants
FSDH321, FSDL321
Typical Performance Characteristics (Control Part)
1.20
1.20
1.00
1.00
Normalized
Normalized
(These characteristic graphs are normalized at Ta = 25°C)
0.80
0.60
0.40
0.80
0.60
0.40
0.20
0.20
0.00
0.00
-50
0
50
100
-50
150
0
150
Frequency Modulation (∆FMOD) vs. Ta
Operating Frequency (Fosc) vs. Ta
1.20
1.20
1.00
1.00
0.80
0.80
Normalized
Normalized
100
T emp[℃]
T emp[ ℃]
0.60
0.40
0.20
0.60
0.40
0.20
0.00
0.00
-50
0
50
100
150
-50
0
T emp[℃]
50
100
150
T emp[ ℃]
Operating Supply Current (IOP) vs. Ta
Maximum Duty Cycle (DMAX) vs. Ta
1.20
1.20
1.00
1.00
0.80
0.80
Normalized
Normalized
50
0.60
0.40
0.20
0.60
0.40
0.20
0.00
0.00
-50
0
50
100
T emp[℃]
Start Threshold Voltage (VSTART) vs. Ta
150
-50
0
50
100
150
T emp[℃]
Stop Threshold Voltage (VSTOP) vs. Ta
7
FSDH321, FSDL321
1.20
1.20
1.00
1.00
0.80
Normalized
Normalized
Typical Performance Characteristics (Continued)
0.60
0.40
0.20
0.80
0.60
0.40
0.20
0.00
0.00
-50
0
50
100
150
-50
0
T emp[℃]
1.20
1.20
1.00
1.00
0.80
0.80
Normalized
Normalized
150
Start Up Charging Current (ICH) vs. Ta
0.60
0.40
0.20
0.60
0.40
0.20
0.00
0.00
-50
0
50
100
150
T emp[℃]
1.00
0.80
0.60
0.40
0.20
0.00
0
50
0
50
100
Burst Peak Current (IBUR(pk)) vs. Ta
1.20
-50
-50
T emp[ ℃]
Peak Current Limit (ILIM) vs. Ta
Normalized
100
T emp[℃]
Feedback Source Current (IFB) vs. Ta
100
T emp[℃]
Over Voltage Protection (VOVP) vs. Ta
8
50
150
150
FSDH321, FSDL321
Functional Description
1. Startup : In previous generations of Fairchild Power
Switches (FPSTM) the Vstr pin had an external resistor to the
DC input voltage line. In this generation the startup resistor
is replaced by an internal high voltage current source and a
switch that shuts off when 15ms goes by after the supply
voltage, Vcc, gets above 12V. The source turns back on if
Vcc drops below 8V.
3. Leading Edge Blanking (LEB) : At the instant the internal Sense FET is turned on, the primary side capacitance and
secondary side rectifier diode reverse recovery typically
cause a high current spike through the Sense FET. Excessive
voltage across the Rsense resistor leads to incorrect feedback
operation in the current mode PWM control. To counter this
effect, the FPS employs a leading edge blanking (LEB) circuit. This circuit inhibits the PWM comparator for a short
time (tLEB) after the Sense FET is turned on.
Vin,dc
ISTR
Vstr
Vcc
Vcc<8V
UVLO on
J-FET
ICH
15ms after
Vcc≥12V
UVLO off
Figure 4. High Voltage Current Source
2. Feedback Control : The FSDx321 employs current mode
control, as shown in Figure 5. An opto-coupler (such as the
H11A817A) and shunt regulator (such as the KA431) are
typically used to implement the feedback network. Comparing the feedback voltage with the voltage across the Rsense
resistor plus an offset voltage makes it possible to control the
switching duty cycle. When the KA431 reference pin voltage exceeds the internal reference voltage of 2.5V, the optocoupler LED current increases, the feedback voltage Vfb is
pulled down and it reduces the duty cycle. This event typically happens when the input voltage is increased or the output load is decreased.
Vcc
Vcc
5uA
Vo
0.9mA
Vfb
3
CFB
OSC
+
VFB
-
D1
D2
2.5R
VFB,in
Gate
driver
R
431
VSD
OLP
4. Protection Circuits : The FPS has several protective
functions such as over load protection (OLP), over voltage
protection (OVP), abnormal over current protection
(AOCP), under voltage lock out (UVLO) and thermal shutdown (TSD). Because these protection circuits are fully integrated inside the IC without external components, the
reliability is improved without increasing cost. Once a fault
condition occurs, switching is terminated and the Sense FET
remains off. This causes Vcc to fall. When Vcc reaches the
UVLO stop voltage VSTOP (8V), the protection is reset and
the internal high voltage current source charges the Vcc
capacitor via the Vstr pin. When Vcc reaches the UVLO
start voltage VSTART (12V), the FPS resumes its normal
operation. In this manner, the auto-restart can alternately
enable and disable the switching of the power Sense FET
until the fault condition is eliminated.
4.1 Over Load Protection (OLP) : Overload is defined as
the load current exceeding a pre-set level due to an unexpected event. In this situation, the protection circuit should
be activated in order to protect the SMPS. However, even
when the SMPS is operating normally, the over load protection (OLP) circuit can be activated during the load transition.
In order to avoid this undesired operation, the OLP circuit is
designed to be activated after a specified time to determine
whether it is a transient situation or an overload situation. In
conjunction with the Ipk current limit pin (if used) the current mode feedback path would limit the current in the Sense
FET when the maximum PWM duty cycle is attained. If the
output consumes more than this maximum power, the output
voltage (Vo) decreases below its rating voltage. This reduces
the current through the opto-coupler LED, which also
reduces the opto-coupler transistor current, thus increasing
the feedback voltage (VFB). If VFB exceeds 3V, the feedback input diode is blocked and the 5uA current source (IDELAY) starts to charge Cfb slowly up to Vcc. In this condition,
VFB increases until it reaches 6V, when the switching operation is terminated as shown in Figure 6. The shutdown delay
time is the time required to charge Cfb from 3V to 6V with
5uA current source.
Figure 5. Pulse Width Modulation (PWM) Circuit
9
FSDH321, FSDL321
PWM
COMPARATOR
VFB
VFB,in
Over Load Protection
6V
LEB
CLK
Drain
Gate Driver
Vsense
AOCP
COMPARATOR
S
Q
R
3V
VAOCP
t12= CFB×(V(t2)-V(t1)) / IDELAY
t1
t12 = C FB
t2
Rsense
t
V (t 2 ) − V (t1 )
; I DELAY = 5 µA, V (t1 ) = 3V , V (t 2 ) = 6V
I DELAY
Figure 7. Abnormal Over Current Protection (AOCP)
Figure 6. Over Load Protection (OLP)
4.2 Thermal Shutdown (TSD) : The Sense FET and the
control IC are integrated, making it easier for the control IC
to detect the temperature of the Sense FET. When the temperature exceeds approximately 145°C, thermal shutdown is
activated.
4.3 Abnormal Over Current Protection (AOCP) : Even
though the FPS has OLP (Over Load Protection) and current
mode PWM feedback, these are not enough to protect the
FPS when a secondary side diode short or a transformer pin
short occurs. In addition to start-up, soft-start is also
activated at each restart attempt during auto-restart and when
restarting after latch mode is activated. The FPS has an
internal AOCP (Abnormal Over Current Protection) circuit,
as shown in Figure 7. When the gate turn-on signal is applied
to the power Sense FET, the AOCP block is enabled and
monitors the current through the sensing resistor. The
voltage across the resistor is then compared with a preset
AOCP level. If the sensing resistor voltage is greater than the
AOCP level, pulse-by-pulse AOCP is triggered regardless of
uncontrollable LEB time. Here, pulse-by-pulse AOCP stops
the Sense FET within 350ns after it is activated.
10
4.4 Over Voltage Protection (OVP) : In the event of a malfunction in the secondary side feedback circuit, or an open
feedback loop caused by a soldering defect, the current
through the opto-coupler transistor becomes almost zero
(refer to Figure 5). Then, VFB climbs up in a similar manner
to the over load situation, forcing the preset maximum current to be supplied to the SMPS until the over load protection
is activated. Because excess energy is provided to the output,
the output voltage may exceed the rated voltage before the
over load protection is activated, resulting in the breakdown
of the devices in the secondary side. In order to prevent this
situation, an over voltage protection (OVP) circuit is
employed. In general, Vcc is proportional to the output voltage and the FPS uses Vcc instead of directly monitoring the
output voltage. If VCC exceeds 19V, OVP circuit is activated
resulting in termination of the switching operation. In order
to avoid undesired activation of OVP during normal operation, Vcc should be properly designed to be below 19V.
FSDH321, FSDL321
5. Soft Start : The FPS has an internal soft start circuit that
slowly increases the feedback voltage together with the
Sense FET current after it starts up. The typical soft start
time is 15msec, as shown in Figure 8, where progressive
increments of the Sense FET current are allowed during the
start-up phase. The pulse width to the power switching
device is progressively increased to establish the correct
working conditions for transformers, inductors, and capacitors. The voltage on the output capacitors is progressively
increased with the intention of smoothly establishing the
required output voltage. It also helps to prevent transformer
saturation and reduce the stress on the secondary diode.
Burst
Operation
Burst
Operation
Normal
Operation
VFB
VBURH
VBURL
Current
Waveform
Switching
OFF
Switching
OFF
+
VBURH
-
Drain current
Vcc
VBURL/VBURH
0.7A
IBUR(pk)
1ms
Vcc
15steps
Vfb
Current limit
Vcc
IFB
IDELAY
3
0.4A
Normal
2.5R
PWM
Burst
R
MOSFET
Current
t
Figure 8. Soft Start Function
Figure 9. Burst Operation Function
6. Burst Operation : In order to minimize power dissipation
in standby mode, the FPS enters burst mode operation. As
the load decreases, the feedback voltage decreases. As
shown in Figure 9, the device automatically enters burst
mode when the feedback voltage drops below
VBURH(500mV). Switching still continues but the current
limit is set to a fixed limit internally to minimize flux density
in the transformer. The fixed current limit is larger than that
defined by VFB = VBURH and therefore, VFB is driven
down further. Switching continues until the feedback voltage
drops below VBURL(350mV). At this point switching stops
and the output voltages start to drop at a rate dependent on
the standby current load. This causes the feedback voltage to
rise. Once it passes VBURH(500mV), switching resumes.
The feedback voltage then falls and the process repeats.
Burst mode operation alternately enables and disables
switching of the power Sense FET thereby reducing switching loss in Standby mode.
7. Frequency Modulation : Modulating the switching frequency of a switched power supply can reduce EMI. Frequency modulation can reduce EMI by spreading the energy
over a wider frequency range than the bandwidth measured
by the EMI test equipment. The amount of EMI reduction is
directly related to the depth of the reference frequency. As
can be seen in Figure 10, the frequency changes from 97KHz
to 103KHz in 4ms for the FSDH321 (48.5KHz to 51.5KHz
for FSDL321). Frequency modulation allows the use of a
cost effective inductor instead of an AC input mode choke to
satisfy the requirements of world wide EMI limits.
Drain
Current
ts
fs=1/ts
103kHz
100kHz
97kHz
4ms
t
Figure 10. Frequency Modulation Waveform
11
FSDH321, FSDL321
Amplitude (dBµV)
8. Adjusting Peak Current Limit : As shown in Figure 13,
a combined 2.8kΩ internal resistance is connected to the
non-inverting lead on the PWM comparator. A external
resistance of Rx on the current limit pin forms a parallel
resistance with the 2.8kΩ when the internal diodes are
biased by the main current source of 900uA.
Vcc
IDELAY
Vfb
Vcc
5uA
IFB
900uA
2k Ω
PWM
Comparator
3
0.8kΩ
Ipk
Frequency (MHz)
Figure 11. KA5-series FPS Full Range EMI scan(67KHz,
no Frequency Modulation) with DVD Player SET
4
Rx
SenseFET
Current
Sense
Figure 13. Peak Current Limit Adjustment
Amplitude (dBµV)
For example, FSDx321 has a typical Sense FET peak current
limit (ILIM) of 0.7A. ILIM can be adjusted to 0.5A by inserting Rx between the Ipk pin and the ground. The value of the
Rx can be estimated by the following equations:
0.7A : 0.5A = 2.8kΩ : XkΩ ,
X = Rx || 2.8kΩ .
(X represents the resistance of the parallel network)
Frequency (MHz)
Figure 12. FSDX-series FPS Full Range EMI Scan (67KHz,
with Frequency Modulation) with DVD Player SET
12
FSDH321, FSDL321
Application Tips
1. Methods of Reducing Audible Noise
Switching mode power converters have electronic and
magnetic components, which generate audible noises when
the operating frequency is in the range of 20~20,000 Hz.
Even though they operate above 20 kHz, they can make
noise depending on the load condition. Designers can
employ several methods to reduce these noises. Here are
three of these methods:
Glue or Varnish
The most common method involves using glue or varnish
to tighten magnetic components. The motion of core, bobbin
and coil and the chattering or magnetostriction of core can
cause the transformer to produce audible noise. The use of
rigid glue and varnish helps reduce the transformer noise.
But, it also can crack the core. This is because sudden
changes in the ambient temperature cause the core and the
glue to expand or shrink in a different ratio according to the
temperature.
Figure 14. Equal Loudness Curves
Ceramic Capacitor
Using a film capacitor instead of a ceramic capacitor as a
snubber capacitor is another noise reduction solution. Some
dielectric materials show a piezoelectric effect depending on
the electric field intensity. Hence, a snubber capacitor
becomes one of the most significant sources of audible
noise. It is considerable to use a zener clamp circuit instead
of an RCD snubber for higher efficiency as well as lower
audible noise.
Figure 15. Typical Feedback Network of FPS
Adjusting Sound Frequency
Moving the fundamental frequency of noise out of 2~4 kHz
range is the third method. Generally, humans are more sensitive to noise in the range of 2~4 kHz. When the fundamental
frequency of noise is located in this range, one perceives the
noise as louder although the noise intensity level is identical.
Refer to Figure 14. Equal Loudness Curves.
When FPS acts in Burst mode and the Burst operation is
suspected to be a source of noise, this method may be helpful. If the frequency of Burst mode operation lies in the
range of 2~4 kHz, adjusting feedback loop can shift the
Burst operation frequency. In order to reduce the Burst operation frequency, increase a feedback gain capacitor (CF),
opto-coupler supply resistor (RD) and feedback capacitor
(CB) and decrease a feedback gain resistor (RF) as shown in
Figure 15. Typical Feedback Network of FPS.
2. Other Reference Materials
AN-4134: Design Guidelines for Off-line Forward Converters Using Fairchild Power Switch (FPSTM)
AN-4137: Design Guidelines for Off-line Flyback Converters Using Fairchild Power Switch (FPS)
AN-4140: Transformer Design Consideration for Off-line
Flyback Converters using Fairchild Power Switch
(FPSTM)
AN-4141: Troubleshooting and Design Tips for Fairchild
Power Switch (FPSTM) Flyback Applications
AN-4147: Design Guidelines for RCD Snubber of Flyback
AN-4148: Audible Noise Reduction Techniques for FPS
Applications
13
FSDH321, FSDL321
Typical Application Circuit
Application
Output power
Input voltage
Output voltage (Max current)
10W
DC 140~375V
5.0V (2.0A)
PC Auxiliary
Power Supply
Features
•
•
•
•
•
•
High efficiency (>70% at full load, full input range)
Low standby mode power consumption (<1W at DC 375V input and 0.5W load)
Low component count
Enhanced system reliability through various protection functions
Low EMI through frequency modulation
Internal soft-start (15ms)
Key Design Notes
• The delay time for over load protection is designed to be about 13ms with C104 of 22nF. If faster/slower triggering of OLP
is required, C104 can be changed to a smaller/larger value(eg. 47nF for about 30ms).
• The pule-by-pulse peak current limit level(ILIM) is set to default value 0.7A by floating the Ipk pin (#4).
• R102 and C101 clamp the DRAIN voltage of MOSFET below 650V under all conditions.
1. Schematic
R 102
100kΩ
1W
R 101
680kΩ
1W
C 101
10nF
630V
L 201
10uH
D 201
SB360
T1
EE1625
140~ 375
VDC
INPUT
1
10
2
7
C 203
470uF
16V
C 201
1000uF
16V
D 101
UF 4007
3
M Vcc
5
IC101
FSDx321
3
Vstr
Drain 6,7,8
Vcc
ZD1
18V
C104
22nF
D 103
1N 4937
Vfb
2
D 102
1N 4937
R 103
10Ω
4
C 102
47uF
50V R 104
10Ω
5
GND
1
ZD2
18V
6
IC 301
H11A 817A
R 202
330Ω
C 103
10uF
50V
R 201
1kΩ
C301
2.2nF
IC201
KA431
10W PC Auxiliary Power Circuit
14
R 203
2kΩ
C 202
100nF
R 204
2kΩ
5V
(+/-5%)
2A
FSDH321, FSDL321
2. Transformer Schematic Diagram
EE1625
Np/2 1
Na
Np/2 2
10
3
9
NM Vcc 4
8
N5V
5
7
Np/2
Na
N5V
Np/2
NM Vcc
6
3. Winding Specification
P in (S → F )
W ire
T u rn s
W in d in g M e th o d
3 → 2
0 .1 5 φ × 1
80
S o le n o id w in d in g
N p /2
In s u la tio n : P o ly e s te r T a p e t = 0 .0 5 0 m m , 3 L a y e rs
N 5V
10 → 7
0 .5 5 φ × 1
12
S o le n o id w in d in g
In s u la tio n : P o ly e s te r T a p e t = 0 .0 5 0 m m , 3 L a y e rs
N M V cc
4 → 6
0 .2 0 φ × 1
40
S o le n o id w in d in g
In s u la tio n : P o ly e s te r T a p e t = 0 .0 5 0 m m , 3 L a y e rs
N P /2
2 → 1
0 .1 5 φ × 1
80
S o le n o id w in d in g
In s u la tio n : P o ly e s te r T a p e t = 0 .0 5 0 m m , 3 L a y e rs
Na
5 → 6
0 .2 0 φ × 1
34
S o le n o id w in d in g
O u te r In s u la tio n : P o ly e s te r T a p e t = 0 .0 5 0 m m , 3 L a y e rs
4. Electrical Characteristics
P in
Spec.
R e m a rk
In d u c ta n c e
1－ 3
1 .8 m H
1kH z, 1V
Leakage
1－ 3
100 uH
2 n d s id e a ll s h o r t
5. Core & Bobbin
Core : EER1625
Bobbin : EER1625
15
FSDH321, FSDL321
6. Demo Circuit Part List
Part
Value
Note
Part
Resistor
Value
Note
Inductor
R101
680K
1W
L201
10uH
-
R102
100K
1W
R103
10
1/4W
R104
10
1/4W
D101
UF4007
PN Ultra Fast
R201
1K
1/4W
D102
1N4937
PN Ultra Fast
R202
330
1/4W
D103
1N4937
PN Ultra Fast
R203
2K
1/4W
D201
SB360
Schottky
R204
2K
1/4W
ZD1
1N4746A
18V Zener
ZD2
1N4746A
18V Zener
Diode
Capacitor
16
IC
C101
10nF/630V
Film
C102
47uF/50V
Electrolytic
IC101
FSDH321
C103
10uF/50V
Electrolytic
IC201
KA431(TL431)
C104
22nF/50V
Film
IC301
H11A817A
C201
1000uF/16V
Electrolytic
C202
100nF/50V
Ceramic
C203
1uF/100V
Electrolytic
C204
470uF/16V
Electrolytic
C301
2.2nF/35V
Ceramic
FPS™
Voltage
reference
Opto-Coupler
FSDH321, FSDL321
Package Dimensions
8DIP
17
FSDH321, FSDL321
Package Dimensions (Continued)
8LSOP
18
FSDH321, FSDL321
Ordering Information
Product Number
Package
Marking Code
BVDSS
fOSC
RDS(ON)
FSDH321
8DIP
DH321
650V
100KHz
14Ω
FSDL321
8DIP
DL321
650V
50KHz
14Ω
FSDH321L
8LSOP
DH321
650V
100KHz
14Ω
FSDL321L
8LSOP
DL321
650V
50KHz
14Ω
19
FSDH321, FSDL321
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY
PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY
LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER
DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, and (c) whose failure to
perform when properly used in accordance with
instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of the
user.
2. A critical component in any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
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