FAN4800ASMY - Fairchild Semiconductor

FAN4800AS/CS/01S/2S
PFC/PWM Controller Combination
Features
Description

Pin-to-Pin Compatible with ML4800 and FAN4800
and CM6800 and CM6800A

PWM Configurable for Current Mode or
Feedforward Voltage-Mode Operation

Internally Synchronized Leading-Edge PFC and
Trailing-Edge PWM in One IC
The highly integrated FAN4800AS/CS/01S/02S parts
are specially designed for power supplies that consist of
boost PFC and PWM. They require very few external
components to achieve versatile protections /
compensation. They are available in 16-pin DIP and
SOP packages.












Low Operating Current
Innovative Switching-Charge Multiplier Divider
Average-Current Mode for Input-Current Shaping
PFC Over-Voltage and Under-Voltage Protections
PFC Feedback Open-Loop Protection
Cycle-by-Cycle Current Limiting for PFC/PWM
Power-on Sequence Control and Soft-Start
Brownout Protection
Interleaved PFC/PWM Switching
Improved Efficiency at Light Load
fRTCT=4•fPFC=4•fPWM for FAN4800AS/01S
fRTCT=4•fPFC=2•fPWM for FAN4800CS/02S
The PWM can be used in either current or voltage
mode. In voltage mode, feed-forward from the PFC
output bus can reduce the secondary output ripple.
Compared with older productions, ML4800 and
FAN4800,
FAN4800AS/CS/01S/02S
have
lower
operation current that saves power consumption in
external devices. FAN4800AS/CS/01S/02S have
accurate 49.9% maximum duty of PWM that makes the
hold-up time longer. Brownout protection and PFC softstart functions available in this series are not available in
ML4800 and FAN4800.
To evaluate FAN4800AS/CS/01S/02S for replacing
existing FAN4800 and ML4800 boards, five things must
be completed before the fine-tuning procedure:
1.
Change RAC resister from the old value to a higher
resister: between 6 MΩ to 8 MΩ.
2.
Change RT/CT pin from the existing values to
RT=6.8kΩ and CT=1000 pF to have fPFC=64 kHz
and fPWM=64 kHz.
3.
The VRMS pin needs to be 1.224 V at VIN=85 VAC
for universal input application from line input from
85 VAC to 270 VAC.
4.
At full load, the average VVEA needs to be ~4.5 V
and the ripple of VVEA needs to be less than
400 mV.
5.
For the Soft-Start pin, the soft-start current has
been reduced to half the FAN4800 capacitor.
Applications









Desktop PC Power Supply
Internet Server Power Supply
LCD TV, Monitor Power Supply
UPS
Battery Charger
DC Motor Power Supply
Monitor Power Supply
Telecom System Power Supply
Distributed Power
Related Resources

There are two differences from FAN4800A/C/01/02 to
FAN4800AS/CS/01S/02S:
1.
Under-voltage protection
extended to one second.
debounce
2.
PWM gate clamp voltage is raised to 19 V.
time
is
AN-8027 - FAN480X PFC+PWM Combination
Controller Application
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
January 2014
Part Number
Operating Temperature Range
Package
FAN4800ASNY
-40°C to +105°C
16-Pin Dual Inline Package (DIP)
FAN4800ASMY
-40°C to +105°C
16-Pin Small Outline Package (SOP)
FAN4800CSNY
-40°C to +105°C
16-Pin Dual Inline Package (DIP)
FAN4800CSMY
-40°C to +105°C
16-Pin Small Outline Package (SOP)
FAN4801SNY
-40°C to +105°C
16-Pin Dual Inline Package (DIP)
FAN4801SMY
-40°C to +105°C
16-Pin Small Outline Package (SOP)
FAN4802SNY
-40°C to +105°C
16-Pin Dual Inline Package (DIP)
FAN4802SMY
-40°C to +105°C
16-Pin Small Outline Package (SOP)
Packing Method
Tube
Tape & Reel
Tube
Tape & Reel
Tube
Tape & Reel
Tube
Tape & Reel
Application Diagram
Figure 1.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
Typical Application, Current Mode
www.fairchildsemi.com
2
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Ordering Information
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Application Diagram
IEA
VEA
IAC
FBPFC
VREF
ISENSE
VRMS
VDD
SS
OPFC
FBPWM
VREF
VDD
OPWM
RT/CT
GND
RAMP
ILIMIT
VREF
Figure 2.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
Typical Application, Voltage Mode
www.fairchildsemi.com
3
VEA
IEA
16
VDD
1
7.5V
REFERENCE
PFC UVP
VDD
27V/28V
VDD OVP
0.3V
Low Power
Detect Comparator
gmv
FBPFC 15
2.5V/2.75V
2.5V
S
PFC OVP
-1.15V
Rmul
gmi
R
2
CLR
14
Q
Q
OPFC
12
S
SET
CLR
Q
VGATE-CLAMP
Q
1.05V/1.9V
VRMS
AC UVP
Gain
Modulator
VRMS 4
SET
PFC ILIMIT
R
IAC
13
VREF
0.5V
Rmul
ISENSE 3
RT/CT
7
OSCILLATOR
300
RAMP
DUTY CYCLE
LIMIT
8
1.5V
OPWM
S
FBPWM
1.15V/2.4V
FBPFC
6
VDD
10µA
R
SET
CLR
Q
11
Q
VGATE-CLAMP
VIN OK
300
SS 5
1V
VREF
ILIMIT
9
GND 10
VDD
Figure 3.
VEA
FAN4800AS/CS Function Block Diagram
IEA
16
UVLO
VDD
1
7.5V
REFERENCE
PFC UVP
VDD
27V/28V
VDD OVP
0.3V
gmv
FBPFC 15
Low Power
Detect Comparator
IAC
2.5V/2.75V
Range
2
VRMS 4
gmi
S
PFC OVP
-1.15V
Rmul
2.5V
13
VREF
0.5V
R
SET
CLR
14
Q
Q
OPFC
12
PFC ILIMIT
S
R
SET
CLR
Q
VGATE-CLAMP
Q
1.05V/1.9V
VRMS
AC UVP
Gain
Modulator
Rmul
ISENSE 3
RT/CT
7
OSCILLATOR
300
RAMP
DUTY CYCLE
LIMIT
8
1.5V
OPWM
S
FBPWM
1.15V/2.4V
FBPFC
6
VDD
10µA
R
SS 5
CLR
Q
11
Q
VGATE-CLAMP
VIN OK
300
SET
1V
VREF
ILIMIT
9
GND 10
VDD
Figure 4.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
UVLO
FAN4801S/02S Function Block Diagram
www.fairchildsemi.com
4
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Block Diagram
F – Fairchild Logo
Z – Plant Code
X – 1-Digit Year Code
YY – 2-Digit Week Code
TT – 2-Digit Die-Run Code
T – Package Type (N:DIP)
P – Y: Green Package
M – Manufacture Flow Code
Figure 5.
DIP Top Mark
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 6.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
SOP Top Mark
www.fairchildsemi.com
5
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Marking Information
Figure 7.
Pin Configuration (Top View)
Pin Definitions
Pin #
Name
Description
1
IEA
Output of PFC Current Amplifier. The signal from this pin is compared with an internal
sawtooth to determine the pulse width for PFC gate drive.
2
IAC
Input AC Current. For normal operation, this input provides current reference for the multiplier.
The suggested maximum IAC is 100 µA.
3
ISENSE
4
VRMS
5
SS
6
FBPWM
7
RT/CT
Oscillator RC Timing Connection. Oscillator timing node; timing set by RT and CT.
8
RAMP
PWM RAMP Input. In current mode, this pin functions as the current-sense input; when in
voltage mode, it is the feedforward sense input from PFC output 380 V (feedforward ramp).
Peak Current Limit Setting for PWM. The peak current limits setting for PWM.
PFC 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 the PFC multiplier.
PWM Soft-Start. During startup, the SS pin charges an external capacitor with a 10 µA
constant current source. The voltage on FBPWM is clamped by SS during startup. If a
protection condition occurs and/or PWM is disabled, the SS pin is quickly discharged.
PWM Feedback Input. The control input for voltage-loop feedback of PWM stage.
9
ILIMIT
10
GND
11
OPWM
PWM Gate Drive. The totem-pole output drive for PWM MOSFET. This pin is internally
clamped under 19 V to protect the MOSFET.
12
OPFC
PFC Gate Drive. The totem-pole output drive for PFC MOSFET. This pin is internally clamped
under 15 V to protect the MOSFET.
13
VDD
Supply. The power supply pin. The threshold voltages for startup and turn-off are 11 V and
9.3 V, respectively. The operating current is lower than 10 mA.
14
VREF
Reference Voltage. Buffered output for the internal 7.5 V reference.
15
FBPFC
16
VEA
Ground.
Voltage Feedback Input for PFC. 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 PFC Voltage Amplifier. The error amplifier output for PFC voltage feedback loop.
A compensation network is connected between this pin and ground.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
6
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Pin Configuration
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
30
V
VDD
DC Supply Voltage
VH
SS, FBPWM, RAMP, OPWM, OPFC, VREF
-0.3
30.0
V
VL
IAC, VRMS, RT/CT, ILIMIT, FBPFC, VEA
-0.3
7.0
V
0
VVREF+0.3
V
-5.0
0.7
V
1
mA
VIEA
IEA
VN
ISENSE
IAC
Input AC Current
IREF
VREF Output Current
5
mA
IPFC-OUT
Peak PFC OUT Current, Source or Sink
0.5
A
IPWM-OUT
Peak PWM OUT Current, Source or Sink
0.5
A
PD
Power Dissipation TA < 50°C
800
mW
ΘJA
Thermal Resistance (Junction-to-Air)
ΘJC
Thermal Resistance (Junction-to-Case)
TJ
DIP
80.80
SOP
104.10
DIP
35.38
SOP
40.41
°C/W
°C/W
Operating Junction Temperature
-40
+125
°C
TSTG
Storage Temperature Range
-55
+150
°C
TL
Lead Temperature(Soldering)
+260
°C
ESD
Electrostatic Discharge Capability
Human Body Model
5.0
Charged Device Model
1.5
kV
Notes:
1. All voltage values, except differential voltage, are given with respect to 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
Min.
Operating Ambient Temperature
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
-40
Typ.
Max.
Unit
+105
°C
www.fairchildsemi.com
7
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Absolute Maximum Ratings
Unless otherwise noted, VDD=15 V, TA= 25°C, TA=TJ, RT=6.8 kΩ, and CT=1000 pF.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
26
V
30
80
µA
VDD Section
VDD-OP
Continuously Operating Voltage
IDD ST
Startup Current
VDD=VTH-ON-0.1 V; OPFC OPWM
Open
IDD-OP
Operating Current
VDD=13 V; OPFC OPWM Open
2.0
2.6
5.0
mA
VTH-ON
Turn-on Threshold Voltage
10
11
12
V
Hysteresis
1.3
1.9
V
VDD OVP
27
29
V
ΔVTH
VDD-OVP
ΔVDD-OVP
VDD OVP Hysteresis
28
1
V
Oscillator
fOSC-RT/CT
fOSC
RT/CT Frequency
RT=6.8 kΩ, CT=1000 pF
240
256
268
kHz
PFC & PWM Frequency
RT=6.8 kΩ, CT=1000 pF
60
64
67
kHz
120
128
134
PWM Frequency
fDV
fDT
fTV
fRV
Voltage Stability(3)
(3)
Temperature Stability
(3)
Total Variation (PFC & PWM)
11 V ≦ VDD ≦ 22 V
2
%
-40°C ~ +105°C
2
%
70
kHz
6.5
15.0
mA
50
75
kHz
Line, Temperature
Ramp Voltage
Valley to Peak
IOSC-DIS
Discharge Current
VRAMP=0V, VRT/CT=2.5 V
fRANGE
Frequency Range
tPFC-DEAD
58
2.8
V
PFC Dead Time
RT=6.8 kΩ, CT=1000 pF
400
600
800
ns
Reference Voltage
IREF=0 mA, CREF=0.1 µF
7.4
7.5
7.6
V
ΔVVREF1
Load Regulation of Reference
Voltage
CREF=0.1 µF, IREF=0 mA to
3.5 mA VVDD=14 V, Rise/Fall Time
> 20 µs
30
50
mV
ΔVVREF2
Line Regulation of Reference
Voltage
CREF=0.1 µF, VVDD=11 V to 22 V
25
mV
VREF
VVREF
(3)
ΔVVREF-DT
Temperature Stability
-40°C ~ +105°C
ΔVVREF-TV
Total Variation(3)
Line, Load, Temp
ΔVVREF-LS
IREF-MAX
(3)
0.5
%
7.35
0.4
7.65
V
25
mV
Long-Term Stability
TJ=125°C, 0 ~ 1000 HRs
5
Maximum Current
VVREF > 7.35 V
5
mA
PFC OVP Comparator
VPFC-OVP
ΔVPFC-OVP
Over-Voltage Protection
2.70
2.75
2.80
V
PFC OVP Hysteresis
200
250
300
mV
0.2
0.3
0.4
V
Voltage Level on FBPFC to
Enable OPWM During Startup
2.3
2.4
2.5
V
Hysteresis
1.15
1.25
1.35
V
Low-Power Detect Comparator
VVEAOFF
VEA Voltage OFF OPFC
VIN OK Comparator
VRD-FBPFC
ΔVRD-FBPFC
Continued on the following page…
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
8
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Electrical Characteristics
Unless otherwise noted, VDD=15 V, TA= 25°C, TA=TJ, RT=6.8 kΩ, and CT=1000 pF.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
2.55
Unit
Voltage Error Amplifier
VREF
Reference Voltage
2.45
2.50
AV
Open-Loop Gain(3)
35
42
Gmv
Transconductance
VNONINV=VINV, VVEA=3.75 V
50
70
40
IFBPFC-L
Maximum Source Current
VFBPFC=2 V, VVEA=1.5 V
IFBPFC-H
Maximum Sink Current
VFBPFC=3 V, VVEA=6 V
IBS
90
umho
-40
µA
1
µA
0.1
0.4
V
88
100
umho
10
mV
7.4
8.0
V
0.1
0.4
V
-35
µA
50
-50
Input Bias Current
-1
VVEA-H
Output High Voltage on VVEA
5.8
VVEA-L
Output Low Voltage on VVEA
V
dB
µA
6.0
V
Current Error Amplifier
GmI
Transconductance
VNONINV=VINV, VIEA=3.75 V
78
VOFFSET
Input Offset Voltage
VVEA=0 V, IAC Open
-10
VIEA-H
Output High Voltage
VIEA-L
Output Low Voltage
6.8
IL
Source Current
VISENSE=-0.6 V, VIEA=1.5 V
IH
Sink Current
VISENSE=+0.6 V, VIEA=4.0 V
AI(3)
35
50
-50
Open-Loop Gain
40
µA
50
dB
TriFault Detect™
tFBPFC_OPEN
VPFC-UVP
Time to FBPFC Open
VFBPFC=VPFC-UVP to FBPFC OPEN,
470 pF from FBPFC to GND
PFC Feedback Under-Voltage
Protection
0.4
2
4
ms
0.5
0.6
V
100
µA
Gain Modulator
IAC
GAIN
BW
VO(gm)
Input for AC Current(3)
GAIN Modulator(4)
Bandwidth(3)
Multiplier Linear Range
0
IAC=17.67µA, VRMS=1.080V
VFBPFC=2.25V
7.500
9.000 10.500
IAC=20.00 µA, VRMS=1.224 V
VFBPFC=2.25 V
6.367
7.004
7.704
IAC=25.69 µA, VRMS=1.585 V
VFBPFC=2.25 V
3.801
4.182
4.600
IAC=51.62 µA, VRMS=3.169 V
VFBPFC=2.25 V
0.950
1.045
1.149
IAC=62.23 µA, VRMS=3.803 V
VFBPFC=2.25 V
0.660
0.726
0.798
IAC=40 µA
Output Voltage=5.7 kΩ × (ISENSE- IAC=20 µA, VRMS=1.224 V
IOFFSET)
VFBPFC=2.25 V
2
kHz
0.710
0.798
0.885
V
-1.35
-1.20
-1.05
V
PFC ILIMIT Comparator
VPFC-ILIMIT
ΔVPK
Peak Current Limit Threshold
Voltage, Cycle-by-Cycle Limit
PFC ILIMIT-Gain Modulator Output
IAC=17.67 µA, VRMS=1.08 V
VFBPFC=2.25 V
200
mV
Continued on the following page…
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
9
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Electrical Characteristics (Continued)
Unless otherwise noted, VDD=15 V, TA= 25°C, TA=TJ, RT=6.8 kΩ, and CT=1000 pF.
Symbol
Parameter
Conditions
Min.
Typ.
13
15
Max.
Unit
PFC Output Driver
VGATE-CLAMP
Gate Output Clamping Voltage
VDD=22 V
VGATE-L
Gate Low Voltage
VDD=15 V, IO=100 mA
17
V
1.5
V
VGATE-H
Gate High Voltage
VDD=13 V, IO=100 mA
8
tR
Gate Rising Time
VDD=15 V, CL=4. 7nF,
O/P= 2 V to 9 V
40
70
120
ns
tF
Gate Falling Time
VDD=15 V; CL=4.7 nF,
O/P= 9 V to 2 V
40
60
110
ns
DPFC-MAX
Maximum Duty Cycle
VIEA<1.2 V
94
97
DPFC-MIN
Minimum Duty Cycle
VIEA>4.5 V
VRMS-UVL
VRMS Threshold Low
When VRMS=1.05 V at 75 VRMS
1.03
VRMS-UVH
VRMS Threshold High
When VRMS=1.9 V at 85•1.414
V
%
0
%
1.05
1.08
V
1.88
1.90
1.94
V
Hysteresis
750
850
950
mV
Under Voltage Protection
Debounce Time
850
1000
1150
ms
9.5
10.0
10.5
Brownout
VRMS-UVP
tUVP
Soft Start
VSS-MAX
Maximum Voltage
ISS
Soft-Start Current
VDD=15 V
10
V
µA
PWM ILIMIT Comparator
VPWM-ILIMIT
Threshold Voltage
tPD
Propagation Delay to Output
tPWM-BNK
Leading-Edge Blanking Time
0.95
1.00
1.05
250
V
ns
170
250
350
ns
Range (FAN4801S/02S)
VVRMS-L
RMS AC Voltage Low
When VVRMS=1.95 V at 132 VRMS
1.90
1.95
2.00
V
VVRMS-H
RMS AC Voltage High
When VVRMS=2.45 V at 150 VRMS
When VVEA=1.95 V at 30%
Loading
When VVEA=2.45 V at 40%
Loading
2.40
2.45
2.50
V
1.90
1.95
2.00
V
2.40
2.45
2.50
V
18
20
22
µA
18
19
20
V
1.5
V
VVEA-L
VEA LOW
VVEA-H
VEA HIGH
ITC
Source Current from FBPFC
PWM Output Driver
VGATE-CLAMP
Gate Output Clamping Voltage
VDD=22 V
VGATE-L
Gate Low Voltage
VDD=15 V, IO=100 mA
VGATE-H
Gate High Voltage
VDD=13 V, IO=100 mA
8
tR
Gate Rising Time
VDD=15 V, CL=4.7 nF
30
60
120
ns
tF
Gate Falling Time
VDD=15 V, CL=4.7 nF
30
50
110
ns
Maximum Duty Cycle
49.0
49.5
50.0
%
PWM Comparator Level Shift
1.3
1.5
1.8
V
DPWM-MAX
VPWM-LS
V
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 VVEA is saturated to HIGH.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
10
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Electrical Characteristics (Continued)
20.0
28.04
18.0
28.02
16.0
28.00
VDD-OVP(V)
IDD-ST(uA)
14.0
12.0
10.0
8.0
6.0
27.94
27.92
27.90
2.0
27.88
27.86
-40℃
-25℃ -10℃
5℃
Figure 8.
20℃
35℃
50℃
65℃
80℃
95℃
-40℃ -25℃ -10℃
110℃ 125℃
IDD-ST vs. Temperature
5℃
Figure 9.
65.0
7.520
64.9
7.515
64.8
7.510
64.7
VVREF(V)
FOSC(kHz)
27.96
4.0
0.0
64.6
64.5
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
VDD-OVP vs. Temperature
7.505
7.500
7.495
7.490
64.4
7.485
64.3
7.480
64.2
7.475
-40℃ -25℃
-10℃
5℃
Figure 10.
20℃
35℃
50℃
65℃
80℃
95℃
-40℃ -25℃ -10℃
110℃ 125℃
fOSC vs. Temperature
5℃
Figure 11.
2.742
2.502
2.740
2.500
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
VVREF vs. Temperature
2.498
2.738
VREF(V)
VPFC-OVP(V)
27.98
2.736
2.734
2.496
2.494
2.492
2.732
2.490
2.730
2.488
-40℃ -25℃ -10℃
5℃
Figure 12.
20℃
35℃
50℃
65℃
80℃
95℃ 110℃ 125℃
-40℃ -25℃ -10℃
VPFC-OVP vs. Temperature
5℃
Figure 13.
20℃
35℃
50℃
65℃
80℃
95℃ 110℃ 125℃
VREF vs. Temperature
94
74
92
90
GmI(umho)
GmV(umho)
73
73
72
88
86
84
82
72
80
71
78
-40℃
-25℃ -10℃
5℃
20℃
Figure 14.
35℃
50℃
65℃
80℃
95℃
-40℃
110℃ 125℃
GmV vs. Temperature
-10℃
5℃
20℃
Figure 15.
-1.177
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
GmI vs. Temperature
1.010
1.009
VPWM-ILIMIT(V)
-1.178
VPFC-ILIMIT(V)
-25℃
-1.179
-1.180
-1.181
-1.182
1.008
1.007
1.006
1.005
1.004
1.003
1.002
-1.183
-40
-25
-10
Figure 16.
5
20
35
50
65
80
95
110
125
VPFC-ILIMIT vs. Temperature
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
-40℃ -25℃ -10℃
Figure 17.
5℃
20℃
35℃
50℃
65℃
80℃
95℃ 110℃ 125℃
VPWM-ILIMIT vs. Temperature
www.fairchildsemi.com
11
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Typical Characteristics
1.048
867.5
1.047
867.0
866.5
△VRMS-UVP(mV)
VRMS-UVP(V)
1.046
1.045
1.044
1.043
1.042
1.041
1.040
1.038
865.0
864.5
864.0
863.5
862.0
-40℃ -25℃ -10℃
5℃
Figure 18.
20℃
35℃
50℃
65℃
80℃
95℃
-40℃ -25℃ -10℃
110℃ 125℃
VRMS-UVP vs. Temperature
14.7
19.00
14.6
18.95
14.5
14.4
14.3
14.2
14.1
14.0
35℃
50℃
65℃
80℃
95℃ 110℃ 125℃
ΔVRMS-UVP vs. Temperature
18.90
18.85
18.80
18.75
18.70
18.65
18.60
18.50
-40℃ -25℃ -10℃
Figure 20.
5℃
20℃
35℃
50℃
65℃
80℃
95℃
-40℃ -25℃ -10℃
110℃ 125℃
VGATE-CLAMP-PFC vs. Temperature
Figure 21.
96.06
5℃
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
VGATE-CLAMP-PWM vs. Temperature
49.80
96.04
49.75
DPWM-MAX(%)
96.02
96.00
95.98
95.96
95.94
95.92
49.70
49.65
49.60
49.55
95.90
95.88
49.50
-40℃ -25℃ -10℃
5℃
Figure 22.
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
-40℃ -25℃
DPFC-MAX vs. Temperature
-10℃
5℃
Figure 23.
10.1
21.0
10.0
20.8
9.9
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
DPWM-MAX vs. Temperature
20.6
9.8
9.7
ITC(uA)
ISS(uA)
20℃
18.55
13.9
9.6
9.5
9.4
20.4
20.2
20.0
19.8
9.3
19.6
9.2
9.1
-40℃
5℃
Figure 19.
VGATE-CLAMP-PWM(V)
VGATE-CLAMP-PFC(V)
865.5
863.0
862.5
1.039
DPFC-MAX(%)
866.0
19.4
-25℃
-10℃
5℃
Figure 24.
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
ISS vs. Temperature
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
-40℃
-25℃ -10℃
5℃
Figure 25.
20℃
35℃
50℃
65℃
80℃
95℃
110℃ 125℃
ITC vs. Temperature
www.fairchildsemi.com
12
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Typical Characteristics
The FAN4800AS/CS/01S/02S consist of an average
current controlled, continuous-boost, Power Factor
Correction (PFC) front-end and a synchronized Pulse
Width Modulator (PWM) back-end. The PWM can be
used in current or voltage mode. In voltage mode,
feedforward from the PFC output bus can help improve
the line regulation of PWM. In either mode, the PWM
stage uses conventional trailing-edge, duty-cycle
modulation. This proprietary leading / trailing edge
modulation results in a higher usable PFC error amplifier
bandwidth and can significantly reduce the size of the
PFC DC bus capacitor.
IGAINMOD =
I AC × (VEA − 0.7 )
×K
(1)
VRMS 2
Note that the output current of the gain modulator is
limited around 159 μA and the maximum output voltage
of the gain modulator is limited to 159 μA x
5.7 k=0.906 V. This 0.906 V also determines the
maximum input power. However, IGAINMOD cannot be
measured directly from ISENSE. ISENSE=IGAINMOD –
IOFFSET and IOFFSET can only be measured when VVEA is
less than 0.5 V and IGAINMOD is 0 A. Typical IOFFSET is
around 31 μA ~ 48 μA.
The synchronization of the PWM with the PFC simplifies
the PWM compensation due to the controlled ripple on
the PFC output capacitor (the PWM input capacitor).
Selecting RAC for the IAC Pin
The IAC pin is the input of the gain modulator and also a
current mirror input that requires current input. Selecting
a proper resistor, RAC, provides a good sine wave
current derived from the line voltage and helps program
the maximum input power and minimum input line
voltage. RAC=VIN peak x 56 kΩ. For example, if the
minimum line voltage is 75 VAC, the RAC=75 x 1.414 x
56 kΩ=6 MΩ.
In addition to power factor correction, a number of
protection features are built into this series. They include
soft-start, PFC over-voltage protection, peak current
limiting, brownout protection, duty cycle limiting, and
under-voltage lockout (UVLO).
Gain Modulator
Current Amplifier Error, IEA
The gain modulator is the heart of the PFC, as the
circuit block controls the response of the current loop to
line voltage waveform and frequency, RMS line voltage,
and PFC output voltages. There are three inputs to the
gain modulator:
The current error amplifier’s output controls the PFC
duty cycle to keep the average current through the boost
inductor a linear function of the line voltage. At the
inverting input to the current error amplifier, the output
current of the gain modulator is summed with a current,
which results in a negative voltage being impressed
upon the ISENSE pin.
1. A current representing the instantaneous input
voltage (amplitude and wave shape) to the PFC. The
rectified AC input sine wave is converted to a
proportional current via a resistor and is fed into the
gain modulator at IAC. Sampling current in this way
minimizes ground noise, required in high-power,
switching-power conversion environments. The gain
modulator responds linearly to this current.
The negative voltage on ISENSE represents the sum of
all currents flowing in the PFC circuit and is typically
derived from a current-sense resistor in series with the
negative terminal of the input bridge rectifier.
2. A voltage proportional to the long-term RMS AC line
voltage, derived from the rectified line voltage after
scaling and filtering. This signal is presented to the
gain modulator at VRMS. The output of the gain
modulator is inversely proportional to VRMS (except at
unusually low values of VRMS, where special gain
contouring takes over to limit power dissipation of the
circuit components under brownout conditions).
The inverting input of the current error amplifier is a
virtual ground. Given this fact, and the arrangement of
the duty cycle modulator polarities internal to the PFC,
an increase in positive current from the gain modulator
causes the output stage to increase its duty cycle until
the voltage on ISENSE is adequately negative to cancel
this increased current. Similarly, if the gain modulator’s
output decreases, the output duty cycle decreases to
achieve a less negative voltage on the ISENSE pin.
3. The output of the voltage error amplifier, VEA. The
gain modulator responds linearly to variations in VVEA.
PFC Cycle-By-Cycle Current Limiter
In addition to being a part of the current feedback loop,
the ISENSE pin is a direct input to the cycle-by-cycle
current limiter for the PFC section. If the input voltage at
this pin is less than -1.15 V, the output of the PFC is
disabled until the protection flip-flop is reset by the clock
pulse at the start of the next PFC power cycle.
The output of the gain modulator is a current signal, in
the form of a full wave rectified sinusoid at twice the line
frequency. This current is applied to the virtual ground
(negative) input of the current error amplifier. In this way,
the gain modulator forms the reference for the current
error loop and ultimately controls the instantaneous
current draw of the PFC from the power line. The
general form of the output of the gain modulator is:
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
13
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Functional Description
Error Amplifier Compensation
To improve power supply reliability, reduce system
component count, and simplify compliance to UL1950
safety standards; the FAN4800AS/CS/01S/02S includes
TriFault Detect™ technology. This feature monitors
FBPFC for certain PFC fault conditions.
The PWM loading of the PFC can be modeled as a
negative resistor because an increase in the input voltage
to the PWM causes a decrease in the input current. This
response dictates the proper compensation of the two
transconductance error amplifiers. Figure 26 shows the
types of compensation networks most commonly used for
In a feedback path failure, the output of the PFC could the voltage and current error amplifiers, along with their
exceed safe operating limits. With such a failure, FBPFC respective return points. The current-loop compensation
exceeds its normal operating area. Should FBPFC go too is returned to VREF to produce a soft-start characteristic
low, too high, or open; TriFault Detect™ senses the error on the PFC. As the reference voltage increases from 0V,
and terminates the PFC output drive.
it creates a differentiated voltage on IEA, which prevents
TriFault Detect is an entirely internal circuit. It requires no the PFC from immediately demanding a full duty cycle on
its boost converter. Complete design is discussed in
external components to serve its protective function.
application note AN-6078SC.
PFC Over-Voltage Protection
There is an RC filter between Rsense and ISENSE pin.
In the FAN4800AS/CS/01S/02S, the PFC OVP There are two reasons to add a filter at the ISENSE pin:
comparator serves to protect the power circuit from being
subjected to excessive voltages if the load changes 1. Protection: During startup or inrush current conditions,
there is a large voltage across Rsense, the sensing
suddenly. A resistor divider from the high-voltage DC
resistor of the PFC boost converter. It requires the
output of the PFC is fed to FBPFC. When the voltage on
ISENSE filter to attenuate the energy.
FBPFC exceeds 2.75 V, the PFC output driver is shut
down. The PWM section continues to operate. The OVP 2. To reduce inductance, L, the boost inductor. The
comparator has 250 mV of hysteresis and the PFC does
ISENSE filter also can reduce the boost inductor value
not restart until the voltage at FBPFC drops below 2.5 V.
since the ISENSE filter behaves like an integrator before
VDD OVP can also serve as a redundant PFC OVP
the ISENSE pin, which is the input of the current error
protection. VDD OVP threshold is 28 V with 1 V hysteresis.
amplifier, IEA.
The ISENSE filter is an RC filter. The resistor value of the
ISENSE filter is between 100 Ω and 50 Ω because IOFFSET x
Rsense is the sensing resistor of the PFC boost converter. RFILTER can generate a negative offset voltage of IEA.
During the steady state, line input current x Rsense equals Selecting an RFILTER equal to 50 Ω keeps the offset of the
IGAINMOD x 5.7 kΩ.
IEA less than 3 mV. Design the pole of the ISENSE filter at
f /6, one sixth of the PFC switching frequency, so the
At full load, the average VVEA needs to around 4.5 V and PFC
boost inductor can be reduced six times without
ripple on the VEA pin needs to be less than 400 mV.
disturbing the stability. The capacitor of the ISENSE filter,
Choose the resistance of the sensing resistor:
CFILTER, is approximately 100 nF.
Selecting PFC Rsense
RSENSE =
( 4.5 − 0.7 ) × 5.7K Ω × IAC × Gain × VIN ×
2 × ( 5.6 − 0.7 ) × Line _ Input _ Power
2
(2)
where 5.6 is VVEA maximum output voltage.
PFC Soft-Start
PFC startup is controlled by VVEA level. Before the
FBPFC voltage reaches 2.4 V, the VVEA level is around
2.8 V. At 90 VAC, the PFC soft-start time is 90 ms.
PFC Brownout
The AC UVP comparator monitors the AC input voltage.
The PFC is disabled as AC input lowers, causing VRMS to
be less than 1.05 V.
Figure 26. Compensation Network Connection for
the Voltage and Current Error Amplifiers
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
14
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
TriFault Detect™
Pulse Width Modulator (PWM)
To improve the efficiency, the system can reduce PFC
switching loss at low line and light load by reducing the
PFC output voltage. The two-level PFC output of the
FAN4801S/02S can be programmable.
The operation of the PWM section is straightforward,
but there are several points that should be noted.
Foremost among these is the inherent synchronization
of PWM with the PFC section of the device, from which
it also derives its basic timing. The PWM is capable of
current-mode or voltage-mode operation. In currentmode applications, the PWM ramp (RAMP) is usually
derived directly from a current-sensing resistor or
current transformer in the primary side of the output
stage. It is thereby representative of the current flowing
in the converter’s output stage. ILIMIT, which provides
cycle-by-cycle current limiting, is typically connected to
RAMP in such applications. For voltage-mode operation
and certain specialized applications, RAMP can be
connected to a separate RC timing network to generate
a voltage ramp against which FBPWM is compared.
Under these conditions, the use of voltage feedforward
from the PFC bus can assist in line regulation accuracy
and response. As in current-mode operation, the ILIMIT
input is used for output stage over-current protection.
No voltage error amplifier is included in the PWM stage,
as this function is generally performed on the output
side of the PWM’s isolation boundary. To facilitate the
design of opto-coupler feedback circuitry, an offset has
been built into the PWM’s RAMP input that allows
FBPWM to command a 0% duty cycle for input voltages
below typical 1.5 V.
As Figure 27 shows, FAN4801S/02S detect the voltage
of VEA and VRMS pins to determine if the system
operates low line and light load. At the second-level
PFC, there is a current of 20 µA through RF2 from the
FBPFC pin. The second-level PFC output voltage can
be calculated as.
Output ≅
RF 1 + RF 2
× ( 2.5V − 20 μ A × RF 2 )
RF 2
(3)
For example, if the second-level PFC output voltage is
expected as 300 V and normal voltage is 387 V,
according to the equation, RF2 is 28 kΩ RF1 is 4.3 MΩ.
The programmable range of second level PFC output
voltage is 340 V ~ 300 V.
PWM Cycle-by-Cycle Current Limiter
Figure 27.
The ILIMIT pin is a direct input to the cycle-by-cycle
current limiter for the PWM section. Should the input
voltage at this pin exceed 1 V, the output flip-flop is reset
by the clock pulse at the start of the next PWM power
cycle. When the ILIMIT triggers the cycle-by-cycle bi-cycle
current, it limits the PWM duty cycle mode and the power
dissipation is reduced during the dead-short condition.
Two-Level PFC Scheme
Oscillator (RT/CT)
The oscillator frequency is determined by the values of
RT and CT, which determine the ramp and off-time of
the oscillator output clock:
VIN OK Comparator
1
fRT / CT =
(4)
tRT / CT + tDEAD
The dead time of the oscillator is derived from the
following equation:
The VIN OK comparator monitors the DC output of the
PFC and inhibits the PWM if the voltage on FBPFC is
less than its nominal 2.4 V. Once the voltage reaches
2.4 V, which corresponds to the PFC output capacitor
being charged to its rated boost voltage, soft-start begins.
 VREF − 1 
tRT / CT = CT × RT × ln 

 VREF − 3.8 
at VREF=7.5 V and tRT/CT=CT x RT x 0.56.
PWM Soft-Start (SS)
(5)
PWM startup is controlled by selection of the external
capacitor at soft-start. A current source of 10 µA
supplies the charging current for the capacitor and
startup of the PWM begins at 1.5 V.
The dead time of the oscillator is determined using:
2.8V
× CT = 360 × CT
(6)
7.78mA
The dead time is so small (tRT/CT>>tDEAD) that the
operating frequency can typically be approximated by:
tDEAD =
fRT / CT =
1
tRT / CT
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
(7)
www.fairchildsemi.com
15
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Two-Level PFC Function
Leading/Trailing Edge Modulation
When the PWM section is used in current mode, RAMP
is generally used as the sampling point for a voltage,
representing the current in the primary of the PWM’s
output transformer. The voltage is derived either from a
current-sensing resistor or a current transformer. In
voltage mode, RAMP is the input for a ramp voltage
generated by a second set of timing components (RRAMP,
CRAMP) that have a minimum value of 0V and a peak
value of approximately 6 V. In voltage mode,
feedforward from the PFC output bus is an excellent
way to derive the timing ramp for the PWM stage.
Conventional PWM techniques employ trailing-edge
modulation, in which the switch turns on right after the
trailing edge of the system clock. The error amplifier
output is then compared with the modulating ramp up.
The effective duty cycle of the trailing-edge modulation
is determined during the on-time of the switch.
In the case of leading-edge modulation, the switch is
turned off exactly at the leading edge of the system
clock. When the modulating ramp reaches the level of
the error amplifier output voltage, the switch is turned
on. The effective duty-cycle of the leading-edge
modulation is determined during off-time of the switch.
Generating VDD
After turning on the FAN4800AS/CS/01S/02S at 11 V,
the operating voltage can vary from 9.3 V to 28 V. The
threshold voltage of the VDD OVP comparator is 28 V
and its hysteresis is 1 V. When VDD reaches 28 V,
OPFC is LOW and the PWM section is not disturbed.
There are two ways to generate VDD: use auxiliary
power supply around 15 V or use bootstrap winding to
self-bias the FAN4800AS/CS/01S/02S system. The
bootstrap winding can be taped from the PFC boost
choke or the transformer of the DC-to-DC stage.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
16
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
PWM Control (RAMP)
19.69
18.67
9
16
7.11
6.10
1
8
(0.40)
TOP VIEW
0.38 MIN
5.33 MAX
8.25
7.62
1.78
1.14
0.28
0.20
4.95
2.92
3.81
2.92
2.54
0.56
0.36
10.92
0.25
C
SIDE VIEW
NOTES: UNLESS OTHERWISE SPECIFIED
A) THIS PACKAGE CONFORMS TO
JEDEC MS-001 VARIATION BB
B) ALL DIMENSIONS ARE IN MILLIMETERS.
C) DIMENSIONS ARE EXCLUSIVE OF BURRS,
MOLD FLASH, AND TIE BAR PROTRUSIONS
D) CONFORMS TO ASME Y14.5M-1994
E) DRAWING FILE NAME: N16EREV2
Figure 28.
16-Pin, Dual In-Line Package (DIP), JEDEC MS-001, .300" Wide
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/.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
17
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Physical Dimensions
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
Physical Dimensions
Figure 29.
16-Pin Small Outline Package (SOIC), JEDEC MS-012, .150", Narrow Body
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/.
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
18
FAN4800AS/CS/01S/02S — PFC/PWM Controller Combination
© 2010 Fairchild Semiconductor Corporation
FAN4800AS/CS/01S/02S • Rev. 1.0.2
www.fairchildsemi.com
19