ETC FAN6982

FAN6982
CCM Power Factor Correction Controller
Features
Description
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Continuous Conduction Mode
The FAN6982 is a 14-pin, Continuous Conduction Mode
(CCM) PFC controller IC intended for Power Factor
Correction (PFC) pre-regulators. The FAN6982 includes
circuits for the implementation of leading edge, average
current, “boost”-type power factor correction, and
results in a power supply that fully complies with the
IEC1000-3-2 specification.
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Power-On Sequence Control
Innovative Switching-Charge Multiplier-Divider
Average-Current-Mode for Input-Current Shaping
TriFault Detect™ Prevent Abnormal Operation for
Feedback Loop
Soft-Start Capability
Brownout Protection
Cycle-by-Cycle Peak Current Limiting.
Improves Light-Load Efficiency
Fulfills Class-D Requirements of IEC 1000-3-2
Wide Range Universal AC Input Voltage
A TriFault Detect™ function helps reduce external
components and provides full protection for feedback
loops such as open, short, and over voltage. An overvoltage comparator shuts down the PFC stage in the
event of a sudden load decrease. The RDY signal can
be used for power-on sequence control. The EN
function can choose to enable or disable the range
function. FAN6982 also includes PFC soft-start, peak
current limiting, and input voltage brownout protection.
Maximum Duty Cycle 97%
VDD Under-Voltage Lockout (UVLO)
Applications
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Desktop PC Power Supply
Internet Server Power Supply
LCD TV/Monitor Power Supply
DC Motor Power Supply
Ordering Information
Part Number
FAN6982MY
Operating Temperature Range
Package
Packing Method
-40°C to +105°C
14-Pin Small Outline Package (SOP)
Tape & Reel
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
FAN6982 — CCM Power Factor Correction Controller
July 2010
FAN6982 — CCM Power Factor Correction Controller
Application Diagram
Figure 1. Typical Application
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
2
14
1
Low-Power
Detect Comparator
FBPFC 2.5V
0.3V
13
6
EN
RM
GmI
2
3
0.5V
PFC UVP
2.75V/2.5V
PFC OVP
VDD
28V/27V
GmV
S
VDD OVP
R
CLR
1.05V/1.9V
VRMS
Q
10
VIN UVP
IM O
Gain Modulator
12
Q
PFC ILIMIT
S
SET
R
CLR
Q
k
2
x
IAC
SET
VREF
OPFC
ISENSE
Range
VDD
7.5V
REFERENCE
-1.15V
VRMS
4
11
IEA
VEA
PGND
VEA
9
Q
RM
2.8V
ISENSE
VDD
UVLO
RDY
5
7
RT/CT
FBPFC
2.4V/1.15V
OSCILLATOR
SGND
8
FAN6982 — CCM Power Factor Correction Controller
Block Diagram
Figure 2. Functional Block Diagram
Marking Information
F – Fairchild Logo
Z – Plant Code
X – 1-Digit Year Code
Y – 1-Digit Week Code
TT – 2-Digit Die-Run Code
T – Package Type (M: SOP)
P – Y: Green Package
M – Manufacture Flow Code
Figure 3. Top Mark
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
3
FAN6982 — CCM Power Factor Correction Controller
Pin Configuration
Figure 4. Pin Configuration
Pin Definitions
Pin #
Name
Description
1
IEA
Output of Current Amplifier. This is the output of the PFC current amplifier. The signal from
this pin is compared with sawtooth and determines the pulsewidth for PFC gate drive.
2
IAC
Input AC Current. For normal operation, this input is used to provide current reference for the
multiplier. The suggested maximum IAC is 100µA.
3
ISENSE
4
VRMS
5
RDY
6
EN
7
RT/CT
Oscillator RC Timing Connection. Oscillator timing node; timing set by RT and CT.
8
SGND
Signal Ground.
9
PGND
Power Ground.
10
OPFC
Gate Drive. The totem-pole output drive for PFC MOSFET. This pin is internally clamped
under 15V to protect the MOSFET.
11
VDD
Power Supply. The threshold voltages for startup and turn-off are 11V and 9.3V, respectively.
The operating current is lower than 10mA.
12
VREF
Reference Voltage. Buffered output for the internal 7.5V reference.
13
FBPFC
14
VEA
Current Sense. The non-inverting input of the PFC current amplifier and the output of
multiplier and PFC ILIMIT comparator.
Line-Voltage Detection. The pin is used for PFC multiplier.
Ready Signal. This pin controls the power-on sequence. Once the FAN6982 is turned on and
the FBPFC voltage exceeds in 2.4V, the RDY pin pulls LOW impedance. If the FBPFC voltage
is lower than 1.15V, the RDY pin pulls HIGH impedance.
Enable Range Function. The range function is enabled when EN is connected to VREF.
The range function is disabled when EN is connected to GND.
Voltage Feedback Input. The feedback input for PFC voltage loop. The inverting input of PFC
error amplifier. This pin is connected to the PFC output through a divider network.
Output of Voltage Amplifier. The error-amplifier output for PFC voltage feedback loop.
A compensation network is connected between this pin and ground.
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
4
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
VDD
Parameter
Min.
DC Supply Voltage
Max.
Unit
30
V
VH
OPFC, RDY, EN, VREF
-0.3
30.0
V
VL
IAC, VRMS, RT/CT, FBPFC, VEA
-0.3
7.0
V
0
VVREF+0.3
V
-5.0
VIEA
IEA
VN
ISENSE
0.7
V
IAC
Input AC Current
1
mA
IREF
VREF Output Current
5
mA
0.5
A
IPFC-OUT
PD
Peak PFC OUT Current, Source or Sink
800
mW
RΘ j-a
Thermal Resistance (Junction-to-Air)
104.10
°C/W
RΘ j-c
Thermal Resistance (Junction-to-Case)
40.61
°C/W
TJ
TSTG
TL
ESD
Power Dissipation, TA < 50°C
Operating Junction Temperature
-40
+125
°C
Storage Temperature Range
-55
+150
°C
+260
°C
Lead Temperature (Soldering)
Electrostatic Discharge Capability
Human Body Model,
JESD22-A114
4.5
Charged Device Model,
JESD22-C101
1.0
FAN6982 — CCM Power Factor Correction Controller
Absolute Maximum Ratings
kV
Notes:
1. All voltage values, except differential voltage, are given with respect to the GND pin.
2. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.
Recommended Operating Conditions
The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended
operating conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not
recommend exceeding them or designing to Absolute Maximum Ratings.
Symbol
TA
Parameter
Operating Ambient Temperature
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
Min.
Max.
Unit
-40
+105
°C
www.fairchildsemi.com
5
Unless otherwise noted; VDD=15V, TA= 25°C, TA=TJ, RT=27kΩ, and CT=1000pF.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
22
V
30
80
µA
2.0
2.3
3.0
mA
10
11
12
V
1.90
V
29
V
VDD Section
VDD-OP
Continuously Operating
Voltage
IDD ST
Startup Current
VDD=VTH-ON-0.1V; OPFC Open
VDD=13V; OPFC Open
IDD-OP
Operating Current
VTH-ON
Turn-on Threshold Voltage
△VTH
Hysteresis
VDD-OVP
△VDD-OVP
1.35
VDD OVP
27
VDD OVP Hysteresis
28
1
V
Oscillator
fOSC
PFC Frequency
RT=27kΩ, CT=1000pF
(3)
fDV
Voltage Stability
Temperature Stability
fDT
(3)
67
kHz
11V ≦ VDD ≦ 22V
2
%
-40°C ~ +105°C
2
%
70
kHz
fTV
Total Variation
Line, Temperature
fRV
Ramp Voltage
Valley-to-Peak
IOSC-DIS
Discharge Current
VRAMP=0V, VRT/CT=2.5V
fRANGE
Frequency Range
tPFC-DEAD
60
64
58
2.8
V
6.5
15.0
mA
50
75
kHz
PFC Dead Time
RT=27kΩ, CT=1000pF
400
600
800
ns
VVREF
Reference Voltage
IREF=0mA, CREF=0.1µF
7.4
7.5
7.6
V
△VVREF1
Load Regulation of
Reference Voltage
CREF=0.1µF, IREF=0mA to 3.5mA
VVDD=14V, Rise/Fall Time > 20µs
30
50
mV
△VVREF2
Line Regulation of Reference
CREF=0.1µF, VVDD=11V to 22V
Voltage
25
mV
0.5
%
FAN6982 — CCM Power Factor Correction Controller
Electrical Characteristics
VREF
△VVREF-DT
(3)
Temperature Stability
Total Variation
(3)
-40°C ~ +105°C
0.4
Line, Load, Temperature
7.35
7.65
V
Long-Term Stability
TJ=125°C, 0 ~ 1000HRs
5
25
mV
Maximum Current
VVREF > 7.35V
5
VRMS-UVL
VRMS Threshold Low
When VRMS=1.05V at 75 VRMS
1.00
1.05
1.10
V
VRMS-UVH
VRMS Threshold High
When VRMS=1.9V at 85 • 1.414
1.85
1.90
1.95
V
750
850
950
mV
340
410
480
ms
2.3
2.4
2.5
V
1.15
1.25
1.35
V
VFBPFC<2.4V
500
nA
ISINK=2mA
0.5
V
△VVREF-TV
△VVREF-LS
IREF-MAX
(3)
mA
Brownout
△VRMS-UVP
tUVP
Hysteresis
Under-Voltage Protection
Debounce Time
RDY Section
VFBPFC-RD
△VFBPFC-RD
IRDY-LEK
VRDY-L
FBPFC Voltage Level to Pull
Low Impedance with RDY Pin
Hysteresis
Leakage Current of RDY
High Impedance
RDY Low Voltage
Continued on the following page…
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
6
Unless otherwise noted; VDD=15V, TA= 25°C, TA=TJ, RT=27kΩ, and CT=1000pF.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
2.45
2.50
2.55
V
90
µmho
Voltage Error Amplifier
VREF
AV
Reference Voltage
At TA=25°C
35
42
Transconductance
VNONINV=VINV, VVEA=3.75V at TA=25°C
50
70
IFBPFC-L
Maximum Source Current
VFBPFC=2V, VVEA=1.5V
40
50
IFBPFC-H
Maximum Sink Current
VFBPFC=3V, VVEA=6V
GmV
IBS
Open-Loop Gain
(3)
-50
Input Bias Current
-1
VVEA-H
Output High Voltage on VVEA
5.8
VVEA-L
Output Low Voltage on VVEA
dB
µA
-40
µA
1
µA
6.0
0.1
V
0.4
V
0.7
V
Current Error Amplifier
VISENSE
AI
GmI
Input Voltage Range
Open-Loop Gain
(3)
-1.5
At TA=25°C
40
50
88
Transconductance
VNONINV=VINV, VIEA=3.75V
75
VOFFSET
Input Offset Voltage
VVEA=0V, IAC Open
-10
VIEA-H
Output High Voltage
VIEA-L
Output Low Voltage
6.8
IL
Source Current
VISENSE= -0.6V, VIEA=1.5V
IH
Sink Current
VISENSE= +0.6V, VIEA=4.0V
35
dB
100
µmho
10
mV
7.4
8.0
V
0.1
0.4
50
V
FAN6982 — CCM Power Factor Correction Controller
Electrical Characteristics (Continued)
µA
-50
-35
µA
2.70
2.75
2.80
V
200
250
300
mV
0.2
0.3
0.4
V
PFC OVP Comparator
VFBPFC-OVP
Over Voltage Protection
△VFBPFC-OVP PFC OVP Hysteresis
Low-Power Detect Comparator
VVEA-OFF
VEA Voltage Off OPFC
PFC Soft-Start
VVEA_CLAMP
PFC Soft-Start
VFBPFC < 2.4V
2.2
2.8
3.3
V
VEN-H
High Voltage Level of VEN
VEN=VVREF
7.4
7.5
7.6
V
VEN-L
Low Voltage Level of VEN
VEN=GND
VVRMS-L
RMS AC Voltage Low
When VVRMS=1.95V at 132VRMS
1.90
1.95
20.00
V
VVRMS-H
RMS AC Voltage High
When VVRMS=2.45V at 150 VRMS
2.40
2.45
2.50
V
VEA Low
When VVEA=1.95V at 30% Loading
1.90
1.95
2.00
V
VEA High
When VVEA=2.45V at 40% Loading
2.40
2.45
2.50
V
18
20
22
µA
EN Section
0
V
Range
VVEA-L
VVEA-H
ITC
Source Current from FBPFC
Continued on the following page…
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
7
Unless otherwise noted; VDD=15V, TA= 25°C, TA=TJ, RT=27kΩ, and CT=1000pF.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
100
µA
Gain Modulator
IAC
GAIN
BW
VO(GM)
Input for AC Current
Gain Modulator
(3)(4)
Multiplier Linear Range
0
IIAC=17.67µA, VVRMS=1.080V
VFBPFC=2.25V, at TA=25°C
7.500
9.000
10.500
IIAC=20µA, VVRMS=1.224V
VFBPFC=2.25V, at TA=25°C
6.367
7.004
7.704
IIAC=25.69µA, VVRMS=1.585V
VFBPFC=2.25V, at TA=25°C
3.801
4.182
4.600
IIAC=51.62µA, VVRMS=3.169V
VFBPFC=2.25V, at TA=25°C
0.950
1.045
1.149
IIAC=62.23µA, VVRMS=3.803V
VFBPFC=2.25V, at TA=25°C
0.660
0.726
0.798
Bandwidth
IIAC=40µA
Output Voltage=5.7kΩ ×
(ISENSE-IOFFSET)
IAC=20µA, VRMS=1.224V
VFBPFC=2.25V, at TA=25°C
2
0.710
0.798
kHz
0.885
V
-1.05
V
PFC ILIMIT Comparator
VPFC-ILIMIT
△Vpk
Peak Current Limit
Threshold Voltage
Cycle-by-Cycle Limit
PFC ILIMIT-Gain Modulator
Output
-1.25
IIAC=17.67µA, VVRMS=1.08V
VFBPFC=2.25V, at TA=25°C
200
Gate Output Clamping
Voltage
VDD=22V
13
-1.15
FAN6982 — CCM Power Factor Correction Controller
Electrical Characteristics (Continued)
mV
PFC Output Driver
VGATE-CLAMP
15
17
V
1.5
V
VGATE-L
Gate Low Voltage
VDD=15V; IO=100mA
VGATE-H
Gate High Voltage
VDD=13V; IO=100mA
8
tR
Gate Rising Time
VDD=15V; CL=4.7nF;
O/P= 2V to 9V
40
70
120
ns
tF
Gate Falling Time
VDD=15V; CL=4.7nF;
O/P= 9V to 2V
40
60
110
ns
DPFC-MAX
Maximum Duty Cycle
VIEA<1.2V
94
97
DPFC-MIN
Minimum Duty Cycle
VIEA>4.5V
V
%
0
%
2
4
ms
0.5
0.6
V
Tri-Fault Detect
tFBPFC_OPEN
Time to FBPFC Open
VPFC-UVP
PFC Feedback UnderVoltage Protection
VFBPFC=VFBPFC-OVP to FBPFC
OPEN, 470pF from FBPFC to GND
0.4
Notes:
3. This parameter, although guaranteed by design, is not 100% production tested.
4. This gain is the maximum gain of modulation with a given VRMS voltage when VEA is saturated to high.
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
8
29.0
2.9
28.8
2.8
28.6
2.7
28.4
V D D-O V P (V)
I DD-O P (µA)
3.0
2.6
2.5
2.4
28.2
28.0
27.8
2.3
27.6
2.2
27.4
2.1
27.2
27.0
2.0
-40
-25
-10
5
20
Figure 5.
35
50
65
80
95
110
-40
12 5
IDD-OP vs. Temperature
74
7 .6 5
72
7 .6 0
5
20
35
50
65
80
95
11 0
125
95
11 0
12 5
95
110
125
11 0
125
7 .5 5
V VREF (V )
(k H z )
-10
Figure 6. VDD-OVP vs. Temperature
70
68
66
f
O SC
-25
7 .5 0
7 .4 5
64
7 .4 0
62
7 .3 5
60
-4 0
-2 5
-1 0
5
20
50
65
80
95
110
-4 0
125
fOSC vs. Temperature
-2 5
-1 0
5
20
35
50
65
80
Figure 8. VVREF vs. Temperature
1 .1 0
1 .9 5
1 .0 8
1 .9 3
V RM S-UVH (V )
V R M S-UVL (V )
Figure 7.
35
FAN6982 — CCM Power Factor Correction Controller
Typical Performance Characteristics
1 .0 6
1 .0 4
1 .0 2
1 .9 1
1 .8 9
1 .8 7
1 .0 0
1 .8 5
-4 0
-2 5
-1 0
5
20
35
50
65
80
95
11 0
-4 0
125
Figure 9. VRMS-UVL vs. Temperature
-2 5
-1 0
5
20
35
50
65
80
Figure 10. VRMS-UVH vs. Temperature
2 .5 0
500
450
400
350
I R DY-LE K (n A )
V F BPF C -R D (V )
2 .4 5
2 .4 0
2 .3 5
300
250
200
150
100
50
2 .3 0
0
-4 0
-2 5
-1 0
Figure 11.
5
20
35
50
65
80
95
11 0
12 5
-4 0
VFBPFC-RD vs. Temperature
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
-2 5
-1 0
5
20
35
50
65
80
95
Figure 12. IRDY-LEK vs. Temperature
www.fairchildsemi.com
9
2 .6 0
90
2 .5 8
85
2 .5 6
80
G m V (µm h o )
2 .5 4
V REF (V )
2 .5 2
2 .5 0
2 .4 8
2 .4 6
75
70
65
60
2 .4 4
55
2 .4 2
50
2 .4 0
-4 0
-2 5
-1 0
5
Figure 13.
20
35
50
65
80
95
11 0
-4 0
125
VREF vs. Temperature
-2 5
-1 0
5
20
Figure 14.
35
50
65
80
95
11 0
125
95
11 0
125
95
11 0
125
95
11 0
125
GmV vs. Temperature
10
12 0
8
6
11 0
G m I (µm h o )
V O F FS ET (m V )
4
2
0
-2
-4
10 0
90
80
70
-6
60
-8
50
-10
-4 0
-2 5
-1 0
Figure 15.
5
20
35
50
65
80
95
11 0
-4 0
125
VOFFSET vs. Temperature
-1 0
5
20
35
50
65
80
Figure 16. GmI vs. Temperature
2 .8 0
2 2 .0
2 .7 9
2 1 .5
2 .7 8
2 1 .0
2 .7 7
2 0 .5
2 .7 6
I T C (µA )
V F BPF C-OV P (V )
-2 5
FAN6982 — CCM Power Factor Correction Controller
Typical Performance Characteristics (Continued)
2 .7 5
2 .7 4
2 .7 3
2 0 .0
1 9 .5
1 9 .0
2 .7 2
1 8 .5
2 .7 1
1 8 .0
2 .7 0
-4 0
-2 5
-1 0
5
20
35
50
65
80
95
11 0
-4 0
125
Figure 17. VFBPFC-OVP vs. Temperature
-2 5
-1 0
5
Figure 18.
20
35
50
65
80
ITC vs. Temperature
-1 .0 5
0 .8 7
-1 .0 7
0 .8 5
-1 .0 9
-1 .11
V PF C-ILIM IT (V )
V O (G M ) (V )
0 .8 3
0 .8 1
0 .7 9
0 .7 7
0 .7 5
-1 .1 3
-1 .1 5
-1 .1 7
-1 .1 9
-1 .2 1
0 .7 3
-1 .2 3
-1 .2 5
0 .7 1
-4 0
-2 5
-1 0
5
20
35
50
65
80
95
11 0
-4 0
125
Figure 19. VO(GM) vs. Temperature
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
-2 5
-1 0
5
20
35
50
65
80
Figure 20. VPFC-ILIMIT vs. Temperature
www.fairchildsemi.com
10
17
0 .6 0
17
0 .5 5
16
V PF C-U VP (V )
V G AT E-C LAM P (V )
16
15
15
0 .5 0
0 .4 5
14
14
0 .4 0
13
-4 0
-2 5
-1 0
5
20
35
50
65
80
95
11 0
-4 0
125
Figure 21. VGATE-CLAMP vs. Temperature
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
-2 5
-1 0
Figure 22.
5
20
35
50
65
80
95
VPFC-UVP vs. Temperature
11 0
125
FAN6982 — CCM Power Factor Correction Controller
Typical Performance Characteristics (Continued)
www.fairchildsemi.com
11
G∝
Oscillator
The internal oscillator frequency of FAN6982 is
determined by the timing resistor and capacitor on the
RT/CT pin, but note that the optimum operation for
FAN6982 is between 50 and 75kHz. The frequency of
the internal oscillator is given by:
f OSC =
1
0.56 ⋅ RT ⋅ CT + 360CT
1
VRMS 2
(1)
The dead time for the PFC gate drive signal is
determined by
tDEAD = 360CT
VRMS
(2)
VRMS-UVP
The dead time should be smaller than 2% of switching
period to minimize line current distortion around line
zero crossing.
Figure 24. Modulation Gain Characteristics
VIN
Gain Modulator
Gain modulator is the key block for PFC stage because
it provides the reference to the current control error
amplifier for the input current shaping, as shown in
Figure 23. The output current of gain modulator is a
function of VEA, IAC and VRMS. The gain of the gain
modulator is given as a ratio between IMO and IAC with a
given VRMS when VEA is saturated to high. The gain is
2
inversely proportional to VRMS , as shown in Figure 24,
to implement line feed-forward. This automatically
adjusts the reference of current control error amplifier
according to the line voltage such that the input power
of PFC converter is not changed with line voltage, as
shown in, Figure 25.
VEA
FAN6982 — CCM Power Factor Correction Controller
Functional Description
IL
Figure 25. Line Feed-Forward Operation
To sense the RMS value of the line voltage, an
averaging circuit with two poles is typically employed as
shown in Figure 23. Notice that the input voltage of
PFC is clamped at the peak of the line voltage once
PFC stops switching since the junction capacitance of
bridge diode is not discharged, as shown in Figure 26.
Therefore, the voltage divider for VRMS should be
designed considering the brownout protection trip point
and minimum operation line voltage.
IMO = G ⋅ I AC
= I AC ⋅
K ⋅ (VEA − 0.6)
VRMS 2 (VEAMAX − 0.6)
PFC runs
PFC stops
VIN
Figure 23. Gain Modulator Block
VRMS
Figure 26. VRMS According to the PFC Operation
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
12
2VLINE .BO MAX
⋅G
< 159μ A
RIAC
The current-control feedback loop also has a pulse-bypulse current limit comparator that forces the PFC
switch to turn off if the ISENSE pin voltage drops below
-1.15V until the next switching cycle.
Voltage-Control of Boost Stage
(3)
The voltage-control loop regulates PFC output voltage
using internal error amplifier such that the FBPFC
voltage is same as internal reference of 2.5V.
where VLINE.BO is the line voltage that trips brownout
MAX
protection, G
is the maximum modulator gain when
VRMS is 1.08V, and 159µA is the maximum output
current of the gain modulator.
To improve system efficiency at low AC line voltage
and light-load condition, FAN6982 provides adjustable
PFC output voltage. As shown in Figure 29, FAN6982
monitors VEA and VRMS to adjust the PFC output
voltage. When VEA and VRMS are lower than thresholds,
internal current source of 20µA is enabled that flows
through RFB2, increasing the voltage of the FBPFC pin.
This causes the PFC output voltage to reduce when
20µA is enabled as:
Current-Control of Boost Stage
As shown in Figure 27 the FAN6982 employs two
control loops for power factor correction, a currentcontrol loop and a voltage-control loop. The currentcontrol loop shapes inductor current, as shown in
Figure 28, based on the reference signal obtained at
IAC pin as:
I L ⋅ RCS 1 = I MO ⋅ RM = I AC ⋅ G ⋅ RM
VOPFC 2 =
(4)
VIN
RFB1 + RFB 2
× (2.5 - 20 μA × RFB 2 )
RFB 2
(5)
VO
IL
FAN6982 — CCM Power Factor Correction Controller
The rectified sinusoidal signal is obtained by the current
flowing into the IAC pin. The resistor RIAC should be
large enough to prevent saturation of the gain
modulator as:
RCS1
RF1
RM
ISENSE
RRMS1
IEA
RM
RIC
CF1
IMO
RIAC
CIC2
IAC
CRMS1
RRMS2
IAC
CRMS2
RRMS3
VRMS
+
VEA
-
Drive
logic
RVC
CVC2
CIC1
VREF
OPFC
RT/CT
CVC1
2.5V
Figure 29. Block of Adjustable PFC Output
Brownout Protection
RFB1
FAN6982 has a built-in internal brownout protection
comparator monitoring the voltage of the VRMS pin.
Once the VRMS pin voltage is lower than 1.05V, the
PFC stage is shutdown to protect the system from over
current. FAN6982 starts up the boost stage once the
VRMS voltage increases above 1.9V.
FBPFC
RFB2
Figure 27. Gain Modulation Block
TriFault Detect™
To improve power supply reliability, reduce system
component count, and simplify compliance to UL 1950
safety standards; the FAN6982 includes TriFault Detect
technology. This feature monitors FBPFC for certain
PFC fault conditions.
IAC
I MO
RM
RCS1
In the case of a feedback path failure, the output of the
PFC could exceed operating limits. Should FBPFC go
too low, or too high, or open; TriFault Detect senses the
error and terminates the PFC output drive.
IL
TriFault detect is an entirely internal circuit. It requires
no external components to serve its protective function.
Figure 28. Inductor Current Shaping
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
13
RDY Function
The FAN6982 PFC soft-start function is shown in
Figure 30. When bulk voltage is under the 96% of
setting voltage; VEA clamps to 2.8V, the output current
of multiplier cuts half, the rectifier line current is limited
by current loop, and PFC output rise time increases.
The FAN6982 RDY function, is shown in Figure 31, is
controlled by voltage of FBPFC. If the voltage of
FBPFC is over than 96% of 2.5V, the RDY pin is
connected to SGND. If the FBPFC is under the 46% of
2.5V, the RDY appears open-drain situation. Usually
the capacitor is parallel with the RDY pin to prevent the
layout noise.
When bulk voltage is over 96%, the clamping function
is disabled, and the bulk voltage can be regulated by
voltage error amplifier.
The PNP transistor can control the AHB LLC or dualforward controller on the same side or the “op-to” to
control the LLC controller on the other side.
There have two advantages with PFC soft-start: one is
the MOSFET experience of current is reduced, which
can obtain more de-rating with MOSFET current level.
The other one is to reduce the overshoot of PFC bulk
voltage at the rising time because the charge current
becomes small, the bulk voltage can not exceed to
setting voltage easily.
Figure 31. RDY Application Circuit
FAN6982 — CCM Power Factor Correction Controller
PFC Soft-Start Function
Figure 30. PFC Soft-Start
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
14
FAN6982 — CCM Power Factor Correction Controller
Physical Dimensions
Figure 32. 14-Pin Small Outline Package (SOIC)
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/.
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
15
FAN6982 — CCM Power Factor Correction Controller
© 2009 Fairchild Semiconductor Corporation
FAN6982 • Rev. 1.0.3
www.fairchildsemi.com
16