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February 2013
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
FSFR-HS Series — Advanced Fairchild Power Switch
(FPS™) for Half-Bridge Resonant Converters
Features
Variable Frequency Control with 50% Duty Cycle
for Half-Bridge Resonant Converter Topology
High Efficiency through Zero Voltage Switching (ZVS)
Built-in High-Side Gate Driver IC
Internal UniFET™s with Fast-Recovery Type Body
Diode (trr=160 ns Typical)
Fixed Dead Time (350 ns) Optimized for MOSFETs
Operating Frequency Up to 600 kHz for Soft-Start
Self Auto-Restart Operation for All Protections, Despite
External LVCC Bias
Line UVLO with Programmable Hysteresis Level
Simple On/Off with Line UVLO Pin
Easy Configuration and Compatibility with FAN7930 for
Line UVLO without External Components
Protection Functions: Over-Voltage Protection (OVP),
Over-Current Protection (OCP), Abnormal Over-
Current Protection (AOCP), Internal Thermal
Shutdown (TSD)
Applications
PDP and LCD TVs
Desktop PCs and Servers
Adapters
Telecom Power Supplies
Description
The FSFR-HS is a highly integrated power switch
designed for high-efficiency half-bridge resonant
converters. Offering everything necessary to build a
reliable and robust resonant converter, the FSFR-HS
simplifies designs while improving productivity and
performance. The FSFR-HS combines power MOSFETs,
a high-side gate-drive circuit, an accurate current-
controlled oscillator, and built-in protection functions.
The high-side gate-drive circuit has a common-mode
noise cancellation capability, which provides stable
operation with excellent noise immunity. Using zero-
voltage-switching (ZVS) technique dramatically reduces
the switching losses and significantly improves efficiency.
The ZVS also reduces the switching noise noticeably,
even though the operating frequency increases. It allows
a small Electromagnetic Interference (EMI) filter, besides
the high operating frequency, to reduce the volume of the
resonant tank and to increase power density.
The FSFR-HS can be applied to resonant converter
topologies such as series resonant, parallel resonant,
and LLC resonant converters.
Related Resources
AN4151 — Half-Bridge LLC Resonant Converter Design
Using FSFR-Series Fairchild Power Switch (FPS™)
Ordering Information
Part Number Package Operating
Junction
Temperature RDS(ON_MAX)
Maximum Output Power
without Heatsink
(VIN=350~400 V)(1,2)
Maximum Output
Power with Heatsink
(VIN=350~40 0 V)(1,2)
FSFR1800HS 9-SIP
-40 to +130°C 0.95 Ω 120 W 260 W
FSFR1800HSL 9-SIP
L-Forming
FSFR1700HS 9-SIP
-40 to +130°C 1.25 Ω 100 W 200 W
FSFR1700HSL 9-SIP
L-Forming
Notes:
1. The junction temperature can limit the maximum output power.
2. Maximum practical continuous power in an open-frame design at 50°C ambient.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 2
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Application Circuit Diagram
Figure 1. Typical Application Circuit (LLC Resonant Half-Bridge Converter)
Block Diagram
Figure 2. Internal Block Diagram
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 3
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Pin Configuration
Figure 3. Package Diagram
Pin Definitions
Pin # Name Description
1 DL This is the drain of the high-side MOSFET, typically connected to the input DC link voltage.
2 LS This is the line-sensing pin for the input voltage Under-Voltage Lockout (UVLO).
3 RT
This pin is used for controlling the switching frequency in normal operation. When any
protections are triggered, the internal Auto/Restart (A/R) circuit starts to sense the voltage on
the pin, which is discharged naturally by external resistance. The IC can be operated with
A/R when the voltage decreases 0.1 V. Typically, an opto-coupler is connected to control the
switching frequency for the output voltage regulation and resistors for setting minimum /
maximum operating frequency.
4 CS
This pin senses the current flowing through the low-side MOSFET. Typically, negative
voltage is applied to this pin.
5 SG This pin is the ground of the control part.
6 PG This pin is the power ground. This pin is connected to the source of the low-side MOSFET.
7 LVCC This pin is the supply voltage of the control IC.
8 NC No connection
9 HVCC This is the supply voltage of the high-side gate-drive circuit.
10 CTR This is the drain of the low-side MOSFET. Typically, a transformer is connected to this pin.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 4
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Absolute Maximum Ratings
Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be
operable above the recommended operating conditions and stressing the parts to these levels is not recommended. In
addition, extended exposure to stresses above the recommended operating conditions may affect device reliability. The
absolute maximum ratings are stress ratings only.
Symbol Parameter Min. Max. Unit
VDS Maximum Drain-to-Source Voltage (DL-CTR and CTR-PG) 500 V
LVCC Low-Side Supply Voltage -0.3 25.0 V
HVCC to CTR High-Side VCC Pin to Low-Side Drain Voltage -0.3 25.0 V
HVCC High-Side Floating Supply Voltage -0.3 525.0 V
VRT Timing Resistor Connecting and Auto-Restart Pin Voltage -0.3 5.0 V
VLS Line Sensing Input Voltage -0.3 LVCC V
VCS Current Sense (CS) Pin Input Voltage -5 1 V
fsw Recommended Switching Frequency 10 600 kHz
dVCTR/dt Allowable Low-Side MOSFET Drain Voltage Slew Rate 50 V/ns
PD Total Power Dissipation(4) FSFR1800HS/L 11.7
W
FSFR1700HS/L 11.6
TJ Maximum Junction Temperature(5) +150
°C
Recommended Operating Junction Temperature(5) -40 +130
TSTG Storage Temperature Range -55 +150 °C
MOSFET Section
VDGR Drain Gate Voltage (RGS=1 MΩ) 500 V
VGS Gate Source (GND) Voltage ±30 V
IDM Drain Current Pulsed(6) FSFR1800HS/L 23
A
FSFR1700HS/L 20
ID Continuous Drain Current
FSFR1800HS/L TC=25°C 7.0
A
TC=100°C 4.5
FSFR1700HS/L TC=25°C 6.0
TC=100°C 3.9
Package Section
Torque Recommended Screw Torque 5~7 kgf·cm
Notes:
3. These parameters, although guaranteed, are tested only in EDS (wafer test) process.
4. Per MOSFET when both MOSFETs are conducting.
5. The maximum value of the recommended operating junction temperature is limited by thermal shutdown.
6. Pulse width is limited by maximum junction temperature.
Thermal Impedance
TA=25°C unless otherwise specified.
Symbol Parameter Value Unit
θJC Junction-to-Case Center Thermal Impedance
(Both MOSFETs Conducting)
FSFR1800HS/L 10.7
ºC/W
FSFR1700HS/L 10.8
θJA Junction-to-Ambient Thermal Impedance FSFR1800HS/L
FSFR1700HS/L 80 ºC/W
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 5
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Electrical Characteristics
TA=25°C, LVCC, HVCC =17 VDC and RT=26 kΩ unless otherwise specified.
Symbol Parameter Conditions Min. Typ. Max. Unit
MOSFET Section
BVDSS Drain-to-Source Breakdown Voltage ID=200 μA, TA=25°C 500
V
ID=200 μA, TA=125°C 540
RDS(ON) On-State Resistance FSFR1800HS/L VGS=10 V, ID=3.0 A 0.77 0.95 Ω
FSFR1700HS/L VGS=10 V, ID=2.0 A 1.00 1.25
trr Body Diode Reverse
Recovery Time(7)
FSFR1800HS/L VGS=0 V, IDIODE=7.0 A,
dIDIODE/dt=100 A/μs 160
ns
FSFR1700HS/L VGS=0 V, IDIODE=6.0 A,
dIDIODE/dt=100 A/μs 160
CISS Input Capacitance(7) FSFR1800HS/L
VDS=25 V, VGS=0 V,
f=1.0 MHz
639 pF
FSFR1700HS/L 512 pF
COSS Output Capacitance(7) FSFR1800HS/L 82.1 pF
FSFR1700HS/L 66.5 pF
Supply Section
ILK Offset Supply Leakage Current HVCC=VCTR=500 V 50 μA
IQHVCC Quiescent HVCC Supply Current (HVCCUV+) - 0.1 V 50 120 μA
IQLVCC Quiescent LVCC Supply Current (LVCCUV+) - 0.1 V 100 200 μA
IOHVCC Operating HVCC Supply Current (RMS Value) fOSC=50 KHz 6 9 mA
No Switching 100 200 μA
IOLVCC Operating LVCC Supply Current (RMS Value) fOSC=50 KHz 7 11 mA
No Switching 2 4 mA
UVLO Section
LVCCUV+ LVCC Supply Under-Voltage Positive Going Threshold (LVCC,START) 11.2 12.5 13.8 V
LVCCUV- LVCC Supply Under-Voltage Negative Going Threshold (LVCC,STOP) 8.9 10.0 11.1 V
LVCCUVH LVCC Supply Under-Voltage Hysteresis 2.5 V
HVCCUV+ HVCC Supply Under-Voltage Positive Going Threshold (HVCC,START) 8.2 9.2 10.2 V
HVCCUV- HVCC Supply Under-Voltage Negative Going Threshold (HVCC,STOP) 7.8 8.7 9.6 V
HVCCUVH HVCC Supply Under-Voltage Hysteresis 0.5 V
Oscillator & Feedback Section
VRT Output Voltage on RT Pin
RT=26 kΩ
1.5 2.0 2.5 V
fOSC Output Oscillation Frequency 47 50 53 kHz
DC Output Duty Cycle 48 50 52 %
Continued on the following page…
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 6
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Electrical Characteristics (Continued)
TA=25°C, LVCC, HVCC =17 VDC and RT=26 kΩ unless otherwise specified.
Symbol Parameter Conditions Min. Typ. Max. Unit
Protection Section
VRT,RESET Threshold Voltage to Begin Restart 0.07 0.12 0.17 V
tDELAY,RESET Delay to Disable OSC Circuit After Protection fosc=50 kHz 20 ms
VLINE On Threshold of Input Voltage 2.38 2.50 2.62 V
ILINE Hysteresis Current for Line UVLO 7.5 9.5 11.5 μA
VOVP LVCC Over-Voltage Protection 21 23 25 V
VAOCP AOCP Threshold Voltage -1.0 -0.9 -0.8 V
tBAO AOCP Blanking Time(7) V
CS < VAOCP 50 ns
VOCP OCP Threshold Voltage -0.64 -0.58 -0.52 V
tBO OCP Blanking Time(7) V
CS < VOCP 1.0 1.5 2.0 μs
tDA Delay Time (Low-Side) Detecting from VAOCP to Switch Off(7) 250 400 ns
TSD Thermal Shutdown Temperature(7) 120 135 150
°C
Dead-Time Control Section
DT Dead Time(8) 350 ns
Notes:
7. This parameter, although guaranteed, is not tested in production.
8. These parameters, although guaranteed, are tested only in EDS (wafer test) process.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 7
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Typical Performance Characteristics
These characteristic graphs are normalized at TA=25°C.
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
0.9
0.95
1
1.05
1.1
-50-250 255075100
Figure 4. Low-Side MOSFET Duty Cycle
vs. Temperature Figure 5. Switching Frequency vs. Temperature
0.9
0.95
1
1.05
1.1
-50-250 255075100
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
Figure 6. High-Side VCC (H
V
CC) Start vs. Temperature Figure 7. High-Side VCC (H
V
CC) Stop vs. Temperature
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
Figure 8. Low-Side VCC (L
V
CC) Start vs. Temperature Figure 9. Low-Side VCC (L
V
CC) Stop vs. Temperature
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 8
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Typical Performance Characteristics (Continued)
These characteristic graphs are normalized at TA=25°C.
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
Temp (
O
C)
Normalized at 25
O
C
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
Temp (
O
C)
Normalized at 25
O
C
Figure 10. LVCC OVP Voltage vs. Temperature Figure 11. RT
V
oltage vs. Temperature
0.9
0.95
1
1.05
1.1
-50 -25 0 25 50 75 100
Temp (
O
C)
Normalized at 25
O
C
Figure 12.
V
RT,RESET vs. Temperature Figure 13. OCP Voltage vs. Temperatu
r
e
Figure 14.
V
LINE vs. Temperature Figure 15. ILINE vs. Temperature
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 9
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Typical Performance Characteristics
(Continued)
These characteristic graphs are normalized at T
A
=25°C.
Figure 16. t
DELAY,RESET
vs. Temperature Figure 17.
V
RT,RESET
vs. Temperature
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 10
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Functional Description
1. Basic Operation: FSFR-HS series is designed to drive
high-side and low-side MOSFETs complementarily with
50% duty cycle. A fixed dead time of 350 ns is introduced
between consecutive transitions, as shown in Figure 18.
Once LVCC is higher than LVCC,START = 12.5 V, the IC
starts to operate, generates the low-side gate signal, and
drives the low-side MOSFET. The bootstrap diode and
capacitor is charged by the low-side MOSFET’s
operation. After the voltage on HVCC increases up to
HVCC,START, typically 9.2 V, the high-side gate signal is
generated for the MOSFET.
Figure 18. MOSFET Gate Drive Signals
2. Internal Oscillator: FSFR-HS series employs a
current-controlled oscillator, as shown in Figure 19.
Internally, the voltage of the RT pin is regulated at 2 V
and the charging / discharging current for the oscillator
capacitor, CT, is obtained by copying the current flowing
out of the RT pin (ICTC) using a current mirror. Therefore,
the switching frequency increases as ICTC increases.
Figure 19. Current-Controlled Oscillator
3. Frequency Setting: Figure 20 shows the typical
voltage gain curve of a resonant converter, where the
gain is inversely proportional to the switching frequency
in the ZVS region. The output voltage can be regulated
by modulating the switching frequency. Figure 21 shows
the typical circuit configuration for the RT pin, where the
opto-coupler transistor is connected to the RT pin to
modulate the switching frequency. The switching
frequency may be controlled from 20 kHz to 500 kHz.
The minimum switching frequency is determined as:
]Hz[
µ.Rp
fmin
min
540792
1
+×
= (1)
Assuming the saturation voltage of opto-coupler
transistor is 0.2 V, the maximum switching frequency is
determined as:
]Hz[
µ.R||Rp
fmaxmin
max
540792
1
+×
=(2)
Figure 20. Resonant Converter Typical Gain Curve
Figure 21. Frequency Control Circuit
To prevent excessive inrush current and overshoot of
output voltage during startup, the IC needs to increase
the voltage gain of the resonant converter progressively.
Since the voltage gain of the resonant converter is
inversely proportional to the switching frequency, soft-
start is implemented by sweeping down the switching
frequency from an initial high frequency (fISS) until the
output voltage is established.
The soft-start circuit is constructed by connecting R-C
series network to the RT pin, as shown in Figure 21.
Initially, the operating frequency is set by the parallel
impedance of RSS and Rmin.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 11
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
The initial maximum frequency can be set up to 600 kHz,
which is given by:
][
54.0||792 1
min
Hz
RRp
f
SS
ss
μ
+×
=
(3)
The soft-start time, tSS, can be calculated by:
]s[CRt SSSSSS ⋅×=
3
(4)
4. Self Auto-Restart: The FSFR-HS series can restart
automatically even though any built-in protections are
triggered in case external supply voltage is applied. As
shown in Figure 22 and Figure 23; once a protection is
triggered, the power MOSFET immediately stops. The
counter starts to operate and 1008-clocks are counted,
then the V-I converter is disabled. CSS starts to be naturally
discharged with the series impedance of RSS and Rmin until
VRT drops to VRT,RESET, typically 0.1 V. Then, all protections
are reset and the V-I converter resumes. The FSFR-HS
starts switching again with soft-start.
The counter operating time for 1008-clocks after
protection activation is set by the current out of the RT
pin until VRT drops to VRT,RESET. Finally, the stop time of
FSFR-HS can be estimated, without considering the
counter operation time, as:
()
]s[RRCt minSSSSSTOP +⋅=
3
(5)
Figure 22. Internal Block for Auto -Restart
Figure 23. Self Auto-Restart Operation
5. Protection Circuits: The FSFR-HS series has several
self-protective functions; such as Over-Current Protection
(OCP), Abnormal Over-Current Protection (AOCP), Over-
Voltage Protection (OVP), Thermal Shutdown (TSD), and
Line Under-Voltage Lockout (LUVLO or Brownout).
These protections are Auto-Restart Mode protections, as
shown in Figure 24.
Once a fault condition is detected, switching is instantly
terminated and the MOSFETs remain off. When LVCC falls
to the LVCC stop voltage of 10 V and VRT is lower than
VRT,RESET of 0.1 V, the protection is reset. The FSFR-HS
resumes normal operation when LVCC reaches the start
voltage of 12.5 V.
Figure 24. Protection Blocks
5.1 Over-Current Protection (OCP): When the
sensing pin voltage drops below -0.58 V and its
duration becomes more than OCP blanking time of
1.5 µs, OCP is triggered and the MOSFETs remain off.
5.2 Abnormal Over-Current Protection (AOCP):
If the secondary rectifier diodes are shorted, large
current with extremely high di/dt can flow through the
MOSFET before OCP is triggered. AOCP is triggered
without shutdown delay if the sensing pin voltage drops
below -0.9 V.
5.3 Over-Voltage Protection (OVP): When the LVCC
reaches 23 V, OVP is triggered. This protection is used
when auxiliary winding of the transformer supplies VCC
to the FPS™.
5.4 Thermal Shutdown (TSD): The MOSFETs and
the control IC in one package make it easier for the
control IC to detect the abnormal over-temperature of
the MOSFETs. If the temperature exceeds
approximately 130°C, thermal shutdown triggers.
6. Line Under-Voltage Lockout (UVLO): FSFR-HS
includes precise line UVLO (or brownout) with
programmable hysteresis voltage. This function can start
or restart the IC when VLS for the scale-down voltage of
the DC-link by the sensing resistors, R1 and R2, is higher
than VLINE of 2.5 V as the DC-link voltage increases and
vice versa. A hysteresis voltage between the start and
stop voltage of the IC is programmable by ILINE. In normal
operation, the comparator’s output is HIGH and ILINE is
deactivated so that a voltage on LS pin, VLS, can be
obtained as a divided voltage by R1 and R2. On the
contrary, ILINE is activated when the comparator’s output
is LOW. VLS is generated by the difference between the
current through R1 and ILINE.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 12
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
CFilter can be used to reduce some noise induced from
transformer or switching transition. Generally, hundreds
of pico-farad to tens of nano-farad is adequate,
depending on the quantity of noise.
The start and stop input-voltage can be calculated as:
][
221
,V
RRR
VV LINESTOPlinkdc
+
×=
−(6)
][1
,, VRIVV LINESTOPlinkdcSTARTlinkdc ×+= −− (7)
Figure 25. Half-Wave Sensing
7. Simple Remote-On/Off: The power stage can be
shutdown with optional Auto-Restart Mode, as shown in
Figure 26.
To configure an external protection with Auto-Restart
Mode, an opto-coupler and the LS pin are used. When
the voltage on the LS pin is pulled below VLINE (2.5 V),
the IC stops during the status holds. However, the opto-
coupler stops pulling down and the IC can perform the
auto-restart operation itself.
Figure 26. External Protection Circuits
8. Current-Sensing Methods: FSFR-HS series employs
negative voltage sensing to detect the drain current of
MOSFET, which allows a low-noise resistive sensing
using a filter with low time-constant and capacitive
sensing method.
8.1 Resistive Sensing Method: The IC can sense
drain current as a negative voltage, as shown in Figure
27 and Figure 28. Half-wave sensing allows low power
dissipation in the sensing resistor; while full-wave
sensing has less switching noise in the sensing signal.
For a time constant range for the filter, 3/100~1/10 of
the operating frequency is reasonable.
Figure 27. Half-Wave Sensing
Figure 28. Full-Wave Sensing
8.2 Capacitive Sensing Method: The drain current
can be sensed using an additional capacitor parallel
with the resonant capacitor, as shown in Figure 29.
During the low-side switch turn on, the current, iCB
through CB, makes VSENSE across RSENSE. The iCB is
scale-down of ip by the impedance ratio of Cr and CB.
Generally, 1/100~1/1000 is adequate for the ratio of CB
against Cr. RD is used as a damper for reducing noise
generated by switching transition. Several hundreds of
ohm to a few of kilo-ohms can be normally used.
VSENSE can be estimated as;
][VR
Cr
C
IV sense
B
pk
Crsense ⋅= (8)
Control
IC
CS
SG PG
R
sense
IDS
V
CS
IDS
V
CS
Ns
Np Ns
C
r
Control
IC
CS
SG PG
Ns
Np Ns
Rsense
IDS
C
r
I
DS
VCS
V
CS
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 13
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Figure 29. Capacitive Sensing
9. PCB Layout Guidelines: Duty imbalance problems
may occur due to the radiated noise from the main
transformer, the inequality of the secondary side
leakage inductances of main transformer, and so on.
This is one of the reasons that the control components
in the vicinity of the RT pin are enclosed by the primary
current flow pattern on PCB layout. The direction of the
magnetic field on the components caused by the
primary current flow is changed when the high- and
low-side MOSFET turn on by turns. The magnetic fields
with opposite directions induce a current through, into,
or out of the RT pin, which makes the turn-on duration
of each MOSFET different. It is strongly recommended
to separate the control components in the vicinity of the
RT pin from the primary current flow pattern in the PCB
layout. Figure 30 shows an example for a duty-
balanced case.
Figure 30. Example of Duty Balancin g
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 14
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Physical Dimensions
Figure 31. 9-Lead, Single Inline Package (SIP)
Package drawings are provided as a service to customers considering Fairchild components. Drawings may change in any manner
without notice. Please note the revision and/or date on the drawing and contact a Fairchild Semiconductor representative to verify or
obtain the most recent revision. Package specifications do not expand the terms of Fairchild’s worldwide terms and conditions,
specifically the warranty therein, which covers Fairchild products.
Always visit Fairchild Semiconductor’s online packaging area for the most recent package drawings:
http://www.fairchildsemi.com/packaging/.
© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 15
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
Physical Dimensions
Figure 32. 9-Lead, Single Inline Package (SIP), L-Forming
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© 2011 Fairchild Semiconductor Corporation www.fairchildsemi.com
FSFR1800 / FSFR1700-HS • Rev.1.0.1 16
FSFR-HS Series — Advanced Fairchild Power Switch (FPS™) for Half-Bridge Resonant Converter
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