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Product Specification PFC / Flyback PWM Controller
SG6901A
very few external components to achieve versatile protections. It is available in a 20-pin SOP package. The patented interleave-switching feature synchronizes the PFC and PWM stages and reduces switching noise. For PFC stage, the proprietary multi-vector control scheme provides a fast transient response in a low-bandwidth PFC loop, in which the overshoot and undershoot of the PFC voltage are clamped. If the feedback loop is broken, the SG6901A shuts off PFC to prevent extra-high voltage on output. Programmable two-level output voltage control reduces the PFC output voltage at low line input to increase the efficiency of the power supply. For the flyback PWM, the synchronized slope compensation ensures the stability of the current loop under continuous-conduction-mode operation. Built-in line-voltage compensation maintains constant output-power limit. Hiccup operation during output overloading is also guaranteed. In addition, SG6901A provides protection functions, such as brownout and RI pin open/short protection.
FEATURES OVERVIEW
Interleaved PFC/PWM switching Low start-up and operating current Innovative switching charge multiplier-divider Multi-vector control for improved PFC output transient response Average-current-mode control for PFC Programmable two-level PFC output voltage PFC over-voltage and under-voltage protections PFC and PWM feedback open-loop protection Cycle-by-cycle current limiting for PFC/PWM Slope compensation for PWM Constant power limit for PWM Brownout protection Over-temperature protection (OTP)
APPLICATIONS
Switching Power Supplies with Active PFC and Standby Power High-Power Adaptors
DESCRIPTION
The highly integrated SG6901A is designed for power supplies with boost PFC and flyback PWM. It requires
Typical Application
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Product Specification PFC / Flyback PWM Controller SG6901A
MARKING DIAGRAMS
PIN CONFIGURATION
SG6901A TP XXXXXXXXYWWV
T: S=SOP P : Z=Lead Free Null=regular package XXXXXXXX: Wafer Lot Y: Year; WW: Week V: Assembly Location
ORDERING INFORMATION
Part Number SG6901ASZ Pb-Free Package 20-pin SOP
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Product Specification PFC / Flyback PWM Controller SG6901A
PIN DESCRIPTIONS
Name VRMS Pin No. 1 Type Line-Voltage Detection Function Line voltage detection. The pin is used for PFC multiplier, RANGE control of PFC output voltage, and brownout protection. For brownout protection, the controller is disabled after a delay time when the VRMS voltage drops below a threshold. Reference setting. One resistor connected between RI and ground determines the switching frequency. The switching frequency is equal to [1560 / RI] KHz, where RI is in K. For example, if RI is equal to 24K, the switching frequency is 65KHz. This pin supplies an over-temperature protection signal. A constant current is output from this pin. An external NTC thermistor must be connected from this pin to ground. The impedance of the NTC thermistor decreases whenever the temperature increases. Once the voltage of the OTP pin drops below the OTP threshold, the SG6901A is disabled. This is the output of the PFC current amplifier. The signal from this pin is compared with an internal sawtooth and determines the pulse width for PFC gate drive. The inverting input of the PFC current amplifier. Proper external compensation circuits result in excellent input power factor via average-current-mode control. The non-inverting input of the PFC current amplifier and the output of multiplier. Proper external compensation circuits will result in excellent input power factor via average-current-mode control. The peak-current setting for PFC. The control input for voltage-loop feedback of PWM stage. It is internally pulled high through a 6.5k resistance. Usually an external opto-coupler from secondary feedback circuit is connected to this pin. The current-sense input for the flyback PWM. Via a current sense resistor, this pin provides the control input for peak-current-mode control and cycle-by-cycle current limiting. Signal ground. During startup, the SS pin will charge an external capacitor with a 50A (RI=24K) constant current source. The voltage on FBPWM will be clamped by SS during startup. In the event of a protection condition occurring and/or PWM being disabled, the SS pin will be quickly discharged. The totem-pole output drive for the Flyback PWM MOSFET. This pin is internally clamped under 17V to protect the MOSFET. Power ground. The totem-pole output drive for the PFC MOSFET. This pin is internally clamped under 17V to protect the MOSFET. The power supply pin. Two-level output voltage setting for PFC. The PFC output voltage at low line can be reduced to improve efficiency. The RANGE pin has high impedance whenever the VRMS voltage is lower than a threshold. The PFC stage over voltage input. The comparator disables the PFC output driver if the voltage at this input exceeds a threshold. This pin can be connected to FBPFC or it can be connected to the PFC boost output through a divider network. 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. The error amplifier output for PFC voltage feedback loop. A compensation network (usually a capacitor) is connected between this pin and ground. A large capacitor value results in a narrow bandwidth and improves the power factor. This input is used to provide current reference for the multiplier.
RI
2
Oscillator Setting
OTP
3
Over Temperature Protection Output for PFC Current Amplifier Inverting Input for PFC Current Amplifier Non-inverting Input for PFC Current Amplifier Peak Current Limit Setting for PFC PWM Feedback Input PWM Current Sense Ground PWM Soft-Start
IEA
4
IPFC
5
IMP ISENS E FBPW M
6
7
8
IPWM AGND SS
9 10 11
OPWM GND OPFC VDD RANGE
12 13 14 15 16
PWM Gate Drive Ground PFC Gate Drive Supply PFC Output Voltage Control PFC Over-Voltage Input Voltage Feedback Input for PFC Error Amplifier Output for PFC Voltage Feedback Loop Input AC Current
OVP
17
FBPFC
18
VEA
19
IAC
20
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Product Specification PFC / Flyback PWM Controller SG6901A
BLOCK DIAGRAM
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Product Specification PFC / Flyback PWM Controller SG6901A
ABSOLUTE MAXIMUM RATINGS
Symbol
VVDD IAC VHigh VLow PD TJ TSTG RJC TL VESD,HBM VESD,MM
Parameter
DC Supply Voltage* Input AC Current OPWM, OPFC, IAC Others Power Dissipation at TA < 50C Operating Junction Temperature Storage Temperature Range Thermal Resistance (Junction-to-Case) Lead Temperature (Wave Soldering or Infrared, 10 Seconds) Electrostatic Discharge Capability, Human Body Model Electrostatic Discharge Capability, Machine model
Value
25 2 -0.3 to +25.0 -0.3 to +7.0 1.15 -40 to +125 -55 to +150 23.64 260 4.5 250
Unit
V mA V V W C C C/W C KV V
*All voltage values, except differential voltages, are given with respect to GND pin. *Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device.
RECOMMENDED OPERATING CONDITIONS
Symbol
TA
Parameter
Operating Ambient Temperature*
Value
-20 to +85
Unit
C
*For proper operation.
ELECTRICAL CHARACTERISTICS
VDD=15V, TA=25C unless otherwise noted.
VDD Section
Symbol
VDD-OP IDD-ST IDD-OP VDD-ON VDD-OFF VDD-OVP tD-VDDOVP
Parameter
Continuously Operating Voltage Start-up Current Operating Current Start Threshold Voltage Minimum Operating Voltage VDD OVP Threshold Debounce Time of VDD OVP
Test Conditions
0V < VDD < VDD-ON VDD=15V; OPFC, OPWM open; RI=24K
Min.
Typ.
10 6
Max.
20 25 10 13 11 25.5 25
Unit
V A mA V V V s
11 9 23.5 8
12 10 24.5
Oscillator Section
Symbol
FOSC RI RIOPEN RISHORT
Parameter
PWM Frequency RI Pin Resistance Range RI Pin Open Protection If RI > RIopen , SG6901A Turns Off RI Pin Short Protection If RI < RIshort , SG6901A Turns Off
Test Conditions
RI=24K
Min.
62 15.6
Typ.
65
Max.
68 47.0
Unit
KHz K K K
200 2
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Product Specification PFC / Flyback PWM Controller SG6901A
VRMS for UVP and RANGE
Symbol
VRMS-UVP-1 VRMS-UVP-2 tD-PWM tUVP VRMS-H VRMS-L tRANGE VOL IOH
Parameter
RMS AC Voltage Under-Voltage Protection Threshold (with tUVP delay) Recovery Level on VRMS When UVP Occurs, Interval from PFC Off to PWM Off Under-Voltage Protection Delay Time* High VRMS Threshold for RANGE Comparator Low VRMS Threshold for RANGE Comparator Range-Enable Delay Time Output Low Voltage of RANGE Pin Output High Leakage Current of RANGE Pin
Test Conditions
Min.
0.75 VRMS-UVP-1 + 0.16V tUVP-Min+9 150 1.90 1.55 140
Typ.
0.8 VRMS-UVP-1 + 0.18V
Max.
0.85 VRMS-UVP-1 + 0.2V tUVP-Min+1 4
Unit
V V ms ms V V ms V nA
195 1.95 1.60 170
240 2.00 1.65 200 0.5 50
Io=1mA RANGE=5V
* No delay for start-up.
PFC Stage Voltage Error Amplifier
Symbol
VREF Av Zo OVPPFC OVPPFC tOVP-PFC VFBPFC-H GFBPFC-H VFBPFC-L GFBPFC-L IFBPFC-L IFBPFC-H UVPFBPFC tUVP-FBPFC
Parameter
Reference Voltage Open-Loop Gain Output Impedance PFC Over-Voltage Protection (OVP Pin) PFC Feedback Voltage Protection Hysteresis Debounce Time of PFC OVP Clamp-High Feedback Voltage Clamp-High Gain Clamp-Low Feedback Voltage Clamp-Low Gain Maximum Source Current Maximum Sink Current PFC Feedback Under-Voltage Protection Debounce Time of PFC UVP
Test Conditions
Min.
2.95
Typ.
3.00 60 110
Max.
3.05
Unit
V dB K
3.20 60 40 3.10 2.75 1.5 70 0.35 40
3.25 90 70 3.15 0.5 2.85 6.5 2.0 110 0.40 70
3.30 120 120 3.20 2.90
V mV s V A/mV V mA/mV mA A
0.45 120
V s
Current Error Amplifier
Symbol
VOFFSET AI BW CMRR VOUT-HIGH VOUT-LOW IMR1, IMR2 IL IH
Parameter
Input Offset Voltage ((-) > (+)) Open-Loop Gain Unit Gain Bandwidth Common Mode Rejection Ratio Output High Voltage Output Low Voltage Reference Current Source Maximum Source Current Maximum Sink Current
Test Conditions
Min.
Typ.
8 60 1.5
Max.
Unit
mV dB MHz dB V
VCM=0 to +1.5V 3.2
70 0.2
V A mA mA
RI=24K (IMR=20+IRI*0.8)
50 3 0.25
70
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Product Specification PFC / Flyback PWM Controller SG6901A
Peak Current Limit
Symbol
IP VPK tPD-PFC tLEB-PFC
Parameter
Constant Current Output Peak Current Limit Threshold Voltage Cycle-by-Cycle Limit (VSENSE < VPK) Propagation Delay Leading-Edge Blanking Time
Test Conditions
RI=24K VRMS=1.05V VRMS=3V
Min.
90 0.15 0.35 270
Typ.
100 0.20 0.40 350
Max.
110 0.25 0.45 200 450
Unit
A V V ns ns
Multiplier
Symbol
IAC IMO-max IMO-1 IMO-2 VIMP
Parameter
Input AC Current Maximum Multiplier Current Output Multiplier Current Output (Low-line, High-power) Multiplier Current Output (High-line, High-power) Voltage of IMP Open
Test Conditions
Multiplier Linear Range RI=24K VRMS=1.05V; IAC=90A; VEA=7.5V; RI=24K VRMS=3V; IAC=264A; VEA=7.5V; RI=24K
Min.
0
Typ.
250
Max.
360
Unit
A A
200 65 3.4
250 85 3.9
280
A A
4.4
V
PFC Output Driver
Symbol
VZ VOL-PFC tPFC VOH-PFC tR-PFC tF-PFC DCYMAX
Parameter
Output Voltage Maximum (Clamp) Output Voltage Low Interval OPFC Lags Behind OPWM at Start-up Output Voltage High Rising Time Falling Time Maximum Duty Cycle
Test Conditions
VDD=20V VDD=15V; IO=100mA
Min.
Typ.
16
Max.
18 1.5
Unit
V V ms V
9.0 VDD=13V; IO=100mA VDD=15V; CL=5nF; O/P=2V to 9V VDD=15V; CL=5nF; O/P=9V to 2V 8 40 40 93
11.5
14.0
70 60
120 110 98
ns ns %
PWM Stage FBPWM
Symbol
Av-PWM ZFB IFB FBOPEN-LOOP tOPEN-PWM tOPEN-PWM-Hiccup
Parameter
FB to Current Comparator Attenuation Input Impedance Maximum Source Current PWM Open-Loop Protection voltage PWM Open-Loop Protection Delay Time Interval of PWM Open-Loop Protection Reset
Test Conditions
Min.
2.5 4 0.8 4.2 45 450
Typ.
3.1 5 1.2 4.5 56 600
Max.
3.5 7 1.5 4.8 70 750
Unit
V/V K mA V ms ms
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Product Specification PFC / Flyback PWM Controller SG6901A
PWM-Current Sense
Symbol
tPD-PWM VLIMIT-1 VLIMIT-2 tLEB-PWM VSLOPE
Parameter
Propagation Delay to Output Peak Current Limit Threshold Voltage1 Peak Current Limit Threshold Voltage2 Leading-Edge Blanking Time Slope Compensation
Test Conditions
VDD=15V,OPWM<=9V RANGE=Open RANGE=Ground VS=VSLOPE x (Ton/T) VS: Compensation Voltage Added to Current Sense
Min.
60 0.65 0.60 270 0.45
Typ.
0.70 0.65 350 0.50
Max.
120 0.75 0.70 450 0.55
Unit
ns V V ns V
PWM Output Driver
Symbol
VZ-PWM VOL-PWM VOH-PWM tR-PWM tF-PWM DCYMAXPWM
Parameter
Output Voltage Maximum (Clamp) Output Voltage Low Output Voltage High Rising Time Falling Time Maximum Duty Cycle
Test Conditions
VDD=20V VDD=15V; IO=100mA VDD=13V; IO=100mA VDD=15V; CL=5nF; O/P=2V to 9V VDD=15V; CL=5nF; O/P=9V to 2V
Min.
Typ.
16
Max.
18 1.5
Unit
V V V
8 30 30 73 60 50 78 120 110 83
ns ns %
OTP Section
Symbol
IOTP VOTP-ON VOTP-OFF tOTP
Parameter
OTP Pin Output Current Recovery Level on OTP OTP Threshold Voltage OTP Debounce Time
Test Conditions
RI=24K
Min.
90 1.35 1.15 8
Typ.
100 1.40 1.20
Max.
110 1.45 1.25 25
Unit
A V V s
Soft-Start Section
Symbol
ISS RD
Parameter
Constant Current Output for Soft-Start Discharge RDSON
Test Conditions
RT=24K
Min.
44
Typ.
50 470
Max.
56
Unit
A
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Product Specification PFC / Flyback PWM Controller SG6901A
TYPICAL CHARACTERISTICS
S tart-Up C urrent (ID D -S T ) vs Temperature
25 20
11.0 10.6
Minimum Operating Voltage (V D D -O F F ) vs Temperature
ID D -S T (uA)
V D D -O F F (V)
-40 -25 -10 5 20 35 50 65 80 95 110 125
15 10 5 0
10.2 9.8 9.4 9.0 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ()
Temperature ( )
Operating C urrent (ID D -O P ) vs Temperature
10.0 8.8
68 67 66 64 63 62
PWM Frequency (F OS C ) vs Temperature
ID D -O P (mA)
7.6 6.4 5.2 4.0 -40 -25 -10 5 20 35 50 65 80 95 110 125
F OS C (KHz)
-40
-25
-10
5
20
35
50
65
80
95
110
125
Temperature ()
Temperature ( )
S tart Threshold Voltage (V D D -O N ) vs Temperature
13.0 12.6
V DD Over Voltage Protection (V D D -O VP ) vs
25.5 25.1
Temperature
V D D -O N (V )
12.2 11.8 11.4 11.0 -40 -25 -10 5 20 35 50 65 80 95 110 125
V D D -O VP (V)
24.7 24.3 23.9 23.5 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ()
Temperature ( )
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Product Specification PFC / Flyback PWM Controller
Hig h VR MS Th resho ld fo r R ANGE C om p arator (V R M S - H ) v s Tem p eratur e
SG6901A
Reference V oltage (V R E F ) vs Temperature
3.05 3.03
2.00 1.98
VR M S - H (V )
V R E F (V)
1.96 1.94 1.92 1.90 -40 -25 -10 5 20 35 50 65 80 95 110 125
3.01 2.99 2.97 2.95 -40 -25 -10 5 20 35 50 65 80 95 110 125
Tem perature ()
Temperature ()
Low V RMS Thres hold for RANG E C omparator
1.65 1.63
Ris ing Time (tR -P F C ) vs Temperature
120 104
(V R M S -L ) vs Temperature
tR -P F C (ns )
V R M S -L (V)
1.61 1.59 1.57 1.55 -40 -25 -10 5
88 72 56 40
Temperature ( )
20
35
50
65
80
95
110
125
-40
-25
-10
5
20
35
50
65
80
95
110
125
Temperature ()
P F C Over V oltage P rotection (OVP P F C ) vs Temperature
3.30 3.28
96 110
F alling Time (tF -P F C ) vs Temperature
OVP PF C (V)
tF -P F C (ns)
-40 -25 -10 5 20 35 50 65 80 95 110 125
3.26 3.24 3.22 3.20
82 68 54 40 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ( )
Temperature ()
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Product Specification PFC / Flyback PWM Controller
Maximum Duty C ycle (DC Y M AX ) vs Temperature
98 97
0.75 0.73
SG6901A
P eak Current Limit Threshold V oltage 1 (V L IMIT -1) vs Temperature
DC Y M AX (% )
96 95 94 93 -40 -25 -10 5 20 35 50 65 80 95 110 125
V LIM IT -1 (V )
0.71 0.69 0.67 0.65 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ( )
Temperature ()
P WM Open Loop P rotection Voltage (F B O P E N -L O O P ) vs Temperature
4.80 0.70 0.68
Peak C urrent Limit Threshold Voltage 2 (V LIM IT -2) vs Temperature
F B O P E N -L O OP (V)
4.68
V LIM IT -2 (V)
-40 -25 -10 5 20 35 50 65 80 95 110 125
4.56 4.44 4.32 4.20
0.66 0.64 0.62 0.60 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ()
Temperature ( )
PW M Open Loop Protection Delay Tim e (t O P E N - P W M ) vs
70 65
Ris ing Time (tR -P WM ) vs Temperature
120 102
Tem perature
tOP EN - P W M (m s )
tR -P WM (ns )
60 55 50 45 -40 -25 -10 5 20 35 50 65 80 95 110 125
84 66 48 30 -40 -25 -10 5 20 35 50 65 80 95 110 125
Tem perature ()
Temperature ()
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Product Specification PFC / Flyback PWM Controller
F alling Time (tF -P WM ) vs Temperature
110 94 78 62 46 30 -40 -25 -10 5 20 35 50 65 80 95 110 125
SG6901A
PWM Maximum Duty C ycle (DC Y M AXPW M ) vs
83 81 79 77 75 73 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature
Temperature ()
DC Y M AXP WM (% )
tF -P W M (ns )
Temperature ( )
PWM Maximum Duty C ycle (DC Y M AXP WM ) vs
83 81 79 77 75 73 -40 -25 -10 5 20 35 50 65 80 95 110 125
OTP Thres hold Voltage (V O T P -O F F ) vs Temperature
1.25 1.23
Temperature
DC Y M AXPW M (% )
V OT P-O F F (V)
1.21 1.19 1.17 1.15 -40 -25 -10 5 20 35 50 65 80 95 110 125
Temperature ( )
Temperature ( )
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Product Specification PFC / Flyback PWM Controller SG6901A
OPERATION DESCRIPTION
SG6901A is a highly integrated PFC/PWM combination controller. Many functions and protections are built in to provide a compact design. The following sections describe the operation and function.
PFC Output Voltage Control (RANGE)
For an universal input (90 ~ 264VAC) power supply applying active boost PFC and flyback as a second stage, the output voltage of PFC is usually designed around 250V at low line and 390V at high line. This can improve the efficiency at low-line input. The RANGE pin (open-drain structure) is used for the two-level output voltage setting. Figure 2 shows the RANGE output that programs the PFC output voltage. The RANGE output is shorted to ground when the VRMS voltage exceeds VRMS-H (1.95V) while it is of high impedance (open) whenever the VRMS voltage drops below VRMS-L (1.6V). The output voltages can be designed using equations:
Range = Open VO = Range = Ground VO R A + RB x 3V RB
Switching Frequency and Current Sources
The switching frequency of SG6901A can be programmed by the resistor RI connected between RI pin and GND. The relationship is:
FOSC =
1560 (kHz) ----------RI (k )
(1)
For example, a 24K resistor RI results in a 65KHz switching frequency. Accordingly, a constant current, IT, flows through RI:
IT =
1.2V (mA) ---------------RI (k )
(2)
R + (R B // R C ) =A x 3V (R B // R C )
----
(3)
IT is used to generate internal current reference.
Line Voltage Detection (VRMS)
Figure 1 shows a resistive divider with low-pass filtering for line-voltage detection on the VRMS pin. The VRMS voltage is used for the PFC multiplier, brownout protection, and range control. For brownout protection, the SG6901A is disabled with 195ms delay time if the voltage VRMS drops below 0.8V. For PFC multiplier and range control, refer to section below for more details. FIG.2 Range Control Two-Level Output Voltage
FIG.1 Line Voltage Detection Circuit (c) System General Corp. Version 1.0.1 (IAO33.0062.B0) - 13 www.sg.com.tw * www.fairchildsemi.com September 26, 2007
Product Specification PFC / Flyback PWM Controller SG6901A Through the differential amplification of the signal across RS, better noise immunity is achieved. The output of IEA is compared with an internal sawtooth and the pulse width for PFC is determined. Through the average current-mode control loop, the input current IS is proportional to IMO:
Interleave Switching
The SG6901A uses interleaved switching to synchronize the PFC and flyback stages, which reduces switching noise and spreads the EMI emissions. Figure 3 shows off-time, TOFF, inserted between the turn-off of the PFC gate drive and the turn-on of the PWM.
IMO x R 2 = IS x R S --------------------
(5)
According to Equation 5, the minimum value of R2 and maximum of RS can be determined since IMO should not exceed the specified maximum value. There are different concerns in determining the value of the sense resistor RS. The value of RS should be small enough to reduce power consumption, but large enough to maintain the resolution. A current transformer (CT) may be used to improve efficiency of high-power converters. To achieve good power factor, the voltage for VRMS and VEA should be kept as constant as possible, according to Equation 4. Good RC filtering for VRMS and narrow bandwidth (lower than the line frequency) for voltage loop are suggested for better input current shaping. The transconductance error amplifier has output impedance ZO and a capacitor CEA (1F ~ 10F) should be connected to ground. This establishes a dominant pole f1 for the voltage loop:
FIG.3 Interleaved Switching Pattern
PFC Operation
The purpose of a boost active power factor corrector (PFC) is to shape the input current of a power supply. The input current waveform and phase follow that of the input voltage. Average-current-mode control is utilized for continuous-current-mode operation for the PFC booster. With the innovative multi-vector control for voltage loop and switching charge multiplier-divider for current reference, excellent input power factor is achieved with good noise immunity and transient response. Figure 4 shows the total control loop for the average-current-mode control circuit of SG6901A. The current source output from the switching charge multiplier-divider can be expressed as:
f1 =
1 2 x Z O x CEA
----------------------
(6)
The average total input power can be expressed as:
Pin = VIN (rms) x IIN (rms) VRMS x IMO I AC x VEA VRMS
2
IMO = K x
IAC x VEA (A) -----------VRMS 2
(4)
VRMS x
----------------
(7)
As shown in Figure 4, the current output from IMP pin, IMP, is the summation of IMO and IMR1. IMR1 and IMR2 are identical fixed-current sources used to pull high the operating point of the IMP and IPFC pins since the voltage across RS goes negative with respect to ground. Constant current sources IMR1 and IMR2 are typically 60A.
VRMS x
Vin x VEA R AC VRMS
2
V = 2 x EA R AC
From Equation 7, VEA, the output of the voltage error amplifier, controls the total input power and the power delivered to the load.
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Product Specification PFC / Flyback PWM Controller SG6901A
FIG.4 Average-Current-Mode Control Loop
Multi-Vector Error Amplifier
Although the PFC stage has a low bandwidth voltage loop for better input power factor, the innovative multi-vector error amplifier provides a fast transient response to clamp the overshoot and undershoot of the PFC output voltage. Figure 5 shows the block diagram of the multi-vector error amplifier. When the variation of the feedback voltage exceeds 5% of the reference voltage, the transconductance error amplifier adjusts its output impedance to increase the loop response.
PFC Over-Voltage Protection
Using a voltage divider from the output of PFC to the OVP pin, the PFC output voltage can be safely protected. Once the voltage on the OVP pin is over OVPPFC, the OPFC is disabled. THE OPFC is not enabled again until the OVP voltage falls below OVPPFC.
Cycle-by-Cycle Current Limiting
SG6901A provides cycle-by-cycle current limiting for both PFC and PWM stages. Figure 6 shows the peak current limit for the PFC stage. The PFC gate drive is terminated once the voltage on the ISENSE pin goes below VPK. The voltage of VRMS determines the voltage of VPK. The relationship between VPK and VRMS is shown in Figure 6. The amplitude of the constant current, IP, is determined by the internal current reference according to the equation:
IP = 2 x
FIG. 5 Multi-Vector Error Amplifier (c) System General Corp. Version 1.0.1 (IAO33.0062.B0) - 15 -
1.2V --------------------RI
(8)
www.sg.com.tw * www.fairchildsemi.com September 26, 2007
Product Specification PFC / Flyback PWM Controller SG6901A
Limited Power Control
Every time the output of power supply is shorted or overloaded, the FBPWM voltage increases. If the FBPWM voltage is higher than a designed threshold, FBOPEN-LOOP (4.5V) for longer than tOPEN-PWM (56ms), the OPWM is turned off. As long as the voltage on the VDD pin is larger than VDD-OFF (minimum operating voltage), the OPWM is not enabled. This protection is reset every tOPEN-PWM-Hiccup interval. A low-frequency hiccup mode protection prevents the power supply from being overheated under overloading conditions.
FIG. 6 VRMS Controlled Current Limiting
The peak current of the ISENSE is given by (VRMS<1.05V):
ISENSE_peak =
(IP x RP ) - 0.2V RS
------------------
(9)
Over-Temperature Protection
SG6901A provides an OTP pin for over-temperature protection. A constant current is output from this pin. If RI is equal to 24K, the magnitude of the constant current is 100A. An external NTC thermistor must be connected from this pin to ground, as shown as Figure 8. When the OTP voltage drops below VOTP-OFF (1.2V), SG6901A is disabled and does not recover until OTP voltage exceeds VOTP-ON (1.4V).
Flyback PWM and Slope Compensation
As shown in Figure 7, peak-current-mode control is utilized for flyback PWM. The SG6901A inserts a synchronized 0.5V ramp at the beginning of each switching cycle. This built-in slope compensation ensures stable operation for continuous current-mode operation.
FIG. 8 OTP Function FIG. 7 Peak Current Control Loop When the IPWM voltage, across the sense resistor, reaches the threshold voltage (0.9V), the OPWM is turned off after a small propagation delay tPD-PWM. To improve stability or prevent sub-harmonic oscillation, a synchronized positive-going ramp is inserted at every switching cycle.
Soft-Start
During start-up of PWM stage, the SS pin charges an external capacitor with a constant current source. The voltage on FBPWM is clamped by the SS voltage during start-up. In the event of a protected condition and/or PWM disabled, the SS pin quickly discharges.
Gate Drivers
SG6901A output stage is a fast totem-pole gate driver. The output driver is clamped by an internal 18V Zener diode to protect the external power MOSFET.
(c) System General Corp. Version 1.0.1 (IAO33.0062.B0)
- 16 -
www.sg.com.tw * www.fairchildsemi.com September 26, 2007
Product Specification PFC / Flyback PWM Controller SG6901A
PACKAGE INFORMATION 20 PINS - PLASTIC SOP (S)
E
H
Detail A
1
b
10 e
F
c
A D
y
A2 A1
L Detail A
Dimensions:
Millimeter Min. 2.362 0.101 2.260 Inch Min. 0.093 0.004 0.089
Symbol A A1 A2 b c D E e H L F y
Typ.
Max. 2.642 0.305 2.337
Typ.
Max. 0.104 0.012 0.092
0.406 0.203 12.598 7.391 1.270 10.007 0.406 0.508X45 0 0.101 8 0 10.643 1.270 0.394 0.016 12.903 7.595 0.496 0.291
0.016 0.008 0.508 0.299 0.050 0.419 0.050 0.020X45 0.004 8
(c) System General Corp. Version 1.0.1 (IAO33.0062.B0)
- 17 -
www.sg.com.tw * www.fairchildsemi.com September 26, 2007
Product Specification PFC / Flyback PWM Controller SG6901A
(c) System General Corp. Version 1.0.1 (IAO33.0062.B0)
- 18 -
www.sg.com.tw * www.fairchildsemi.com September 26, 2007

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