ON FAN6757 Pwm controller Datasheet

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FAN6757— mWSaver® PWM Controller
Features
Description

Single-Ended Topologies, such as Flyback and
Forward Converters

mWSaver® Technology
The FAN6757 is a next-generation Green Mode PWM
controller with innovative mWSaver® technology, which
dramatically reduces standby and no-load power
consumption, enabling conformance to worldwide
Standby Mode efficiency guidelines.
- Achieves Low No-Load Power Consumption:
<50 mW at 230 VAC (EMI Filter Loss Included)
- Eliminates X ®Capacitor Discharge Resistor Loss
with AX-CAP Technology
- Linearly Decreases Switching Frequency
to 23 kHz
- Burst Mode Operation at Light-Load Condition
- 500 V High-Voltage JFET Startup Circuit to
Eliminate Startup Resistor Loss

Highly Integrated with Rich Features
- Proprietary Frequency Hopping to Reduce EMI
- High-Voltage Sampling to Detect Input Voltage
- Peak-Current-Mode Control with Slope
Compensation
- Cycle-by-Cycle Current Limiting with Line
Protections ensure safe operation of the power system
in various abnormal conditions. A proprietary frequencyhopping function decreases EMI emission. Built-in
synchronized slope compensation allows more stable
Peak-Current-Mode control over a wide range of input
voltage and load conditions. The proprietary internal line
compensation ensures constant output power limit over
the entire universal line voltage range.
Requiring a minimum number of external components,
FAN6757 provides a basic platform that is well suited for
cost-effective flyback converter designs that require
extremely low standby power consumption.
Applications
Compensation
- Leading-Edge Blanking (LEB)
- Built-In 7 ms Soft-Start

®
An innovative AX-CAP method minimizes losses in the
EMI filter stage by eliminating X-cap discharge resistors
while meeting IEC61010-1 safety requirements.
Flyback power supplies that demand extremely low
standby power consumption, such as:
Advanced Protections
- Brown-In/Brownout Recovery
- Internal Overload / Open-Loop Protection (OLP)
- VDD Under-Voltage Lockout (UVLO)
- VDD Over-Voltage Protection (VDD OVP)
- Over-Temperature Protection (OTP)
- Current-Sense Short-Circuit Protection (SSCP)


Adapters for Notebooks, Printers, Game Consoles
Open-Frame SMPS for LCD TV, LCD Monitors,
Printers
Ordering Information
Part Number
FAN6757MRMX
Protections
(1)
OLP
OVP
OTP
SSCP
Operating
Temperature Range
A/R
L
L
A/R
-40 to +105°C
Package
Packing
Method
8-Pin, Small-Outline
Package (SOP)
Tape &
Reel
Note:
1. A/R = Auto Recovery Mode protection, L = Latch Mode protection.
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
FAN6757— mWSaver® PWM Controller
November 2013
FAN6757— mWSaver® PWM Controller
Application Diagram
VAC
+
VO
-
FAN6757
1 GND
GATE 8
2 FB
VDD 7
3 NC
SENSE 6
4 HV
RT 5
Figure 1. Typical Application
Internal Block Diagram
NC
HV
3
4
VDDOVP
OTP
Line
Sensing
Latch
Protection
SSCP
Re-Start
Protection
OLP
Brownout Function
High/Low Line
Compensation
VDD
Internal
BIAS
7
Soft
Driver
VLimit
VPWM
S
OSC
GATE
6
SENSE
Q
SSCP
Comparator
R
UVLO
8
VRESET
SSCP
VSSCP-H/L
tD-SSCP
…
VDD-ON /
VRESTART
Soft-Start
Comparator
Pattern
Generator
Soft-Start
Current Limit
Comparator
VRESET
tD-VDDOVP
VDD
OVP
VLimit
Green
Mode
Blanking
Circuit
PWM
Comparator
VDD-OVP
Max.
Duty
Slope
Compensation
VPWM
VFB-OPEN
IRT
ZFB
RT
5
tD-OTP1
OTP
3R
OLP
2
tD-OLP
VRTTH1
R
OLP
Comparator
tD-OTP2
VRTTH2
FB
VFB-OLP
1
GND
Figure 2. Functional Block Diagram
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
2
FAN6757— mWSaver® PWM Controller
Marking Information
Z - Plant Code
X - 1-Digit Year Code
Y - 1-Digit Week Code
TT - 2-Digit Die Run Code
T - Package Type (M=SOP)
M - Manufacture Flow Code
ZXYTT
6757
TM
Figure 3. Top Mark
Pin Configuration
SOP-8
GND
1
8
GATE
FB
2
7
VDD
NC
3
6
SENSE
HV
4
5
RT
Figure 4. Pin Configuration (Top View)
Pin Definitions
Pin #
Name
1
GND
Description
Ground. This pin is used for the ground potential of all the pins. A 0.1 µF decoupling capacitor
placed between VDD and GND is recommended.
2
FB
Feedback. The output voltage feedback information from the external compensation circuit is fed
into this pin. The PWM duty cycle is determined from this pin and the current-sense signal from
Pin 6. The FAN6757 performs open-loop protection: if the FB voltage is higher than a threshold
voltage (around 4.6 V) for more than 57.5 ms, the controller latches off the PWM.
3
NC
No connection
HV
High-Voltage Startup. This pin is connected to the line input or bulk capacitor, via 200 kΩ
resistors, to achieve brownout and high/low line compensation. If the voltage of the HV pin is
lower than the brownout voltage (AC line peak voltage less than 100 V) and lasts for 65 ms,
PWM output turns off. High/low line compensation dominates the OCP level and cycle-by-cycle
current limit, to solve the unequal OCP level and power-limit problems under universal input.
5
RT
Over-Temperature Protection. An external NTC thermistor is connected from this pin to the
GND pin. The impedance of the NTC thermistor decreases at high temperatures. Once the
voltage of the RT pin drops below the threshold voltage, the controller latches off the PWM. If the
RT pin is not connected to an NTC resistor for over-temperature protection, it is recommended to
place one 100 kΩ resistor to ground to prevent from noise interference. This pin is limited by an
internal clamping circuit.
6
SENSE
7
VDD
Power Supply. The internal protection circuit disables PWM output as long as V DD exceeds the
OVP trigger point.
8
GATE
Gate Drive Output. The totem-pole output driver for the power MOSFET. It is internally clamped
below 14.5 V.
4
Current Sense. The sensed voltage is used for peak-current-mode control and cycle-by-cycle
current limiting.
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
3
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.
(1,2)
Max.
Units
30
V
VVDD
DC Supply Voltage
VFB
FB Pin Input Voltage
-0.3
7.0
V
VSENSE
SENSE Pin Input Voltage
-0.3
7.0
V
VRT
RT Pin Input Voltage
-0.3
7.0
V
VHV
HV Pin Input Voltage
500
V
PD
Power Dissipation (TA<50°C)
400
mW
ϴJA
Thermal Resistance (Junction-to-Air)
150
C/W
TJ
TSTG
TL
ESD
Operating Junction Temperature
-40
+125
C
Storage Temperature Range
-55
+150
C
+260
C
Lead Temperature (Wave Soldering or IR, 10 Seconds)
All Pins except HV Pin
(3)
6.5
Charged Device Model, JEDEC:JESD22-C101 All Pins except HV Pin
(3)
2.0
Human Body Model, JEDEC:JESD22-A114
kV
Notes:
1. All voltage values, except differential voltages, are given with respect to the network ground terminal.
2. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.
3. ESD level on the HV pin is CDM=1 kV and HBM=1 kV.
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. We does not
recommend exceeding them or designing to Absolute Maximum Ratings.
Symbol
RHV
Parameter
Min.
Typ.
Max.
Unit
150
200
250
kΩ
Resistance on HV Pin
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
4
FAN6757— mWSaver® PWM Controller
Absolute Maximum Ratings
VDD=15 V and TJ=TA=25C unless otherwise noted.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
VDD Section
VDD-ON
Threshold Voltage to Startup
VDD Rising
16
17
18
V
VUVLO
Threshold Voltage to Stop Switching in
Normal Mode
VDD Falling
5.5
6.5
7.5
V
VRESTART
Threshold Voltage to enable HV Startup
VDD Falling
to Charge VDD in Normal Mode
VDD-OFF
Threshold Voltage to Stop Operating in
Protection Mode
VDD Falling
10
11
12
V
VDD-OLP
Threshold Voltage to Enable HV Startup
VDD Falling
to Charge VDD in Protection Mode
6
7
8
V
VDD-LH
Threshold Voltage to Release Latch
Mode
3.5
4.0
4.5
V
VDD-AC
Minimum Voltage of VDD Pin for
Enabling Brown-in to Avoid Startup Fail
VUVLO
+2.5
VUVLO
+3.0
VUVLO
+3.5
V
IDD-ST
Startup Current
VDD=VDD-ON – 0.16 V
30
µA
IDD-OP1
Supply Current in PWM Operation
VDD=15 V, VFB=3 V,
Gate Open
1.8
mA
IDD-OP2
Supply Current when PWM Stops
VDD=15 V, VFB <1.4 V,
Gate Off
800
µA
IDD-OLP
Internal Sink Current when VDDOLP<VDD<VDD-OFF in Protection Mode
VDD = VDD-OLP + 0.1 V
90
190
µA
ILH
Internal Sink Current when VDD<VDD-OLP
in Latch-Protection Mode
VDD = 5 V
30
VDD-OVP
Threshold Voltage for VDD Over-Voltage
Protection
23.5
24.5
25.5
V
tD-VDDOVP
VDD Over-Voltage Protection Debounce
Time
110
205
300
µs
1.50
3.25
5.00
mA
VDD Falling
4.7
140
V
µA
HV Section
IHV
Inherent Current Limit of HV Pin
VAC=90 V (VDC=120 V),
VDD=0 V
VAC-OFF
Threshold Voltage for Brownout
DC Source Series,
R=200 kΩ to HV Pin
90
100
110
V
VAC-ON
Threshold Voltage for Brown-In
DC Source Series,
R=200 kΩ to HV Pin
100
110
120
V
△VAC
VAC-ON – VAC-OFF
DC Source Series,
R=200 kΩ to HV Pin
8
12
16
V
40
65
90
ms
tD-AC-OFF
Debounce Time for Brownout
tS-WORK
Work Period of HV-Sampling Circuit in
Standby Mode
VFB<VFB-ZDC
95
140
185
ms
tS-REST
Rest Period of HV-Sampling Circuit in
Standby Mode
VFB<VFB-ZDC
180
260
320
ms
VHV-DIS
HV Discharge Threshold
RHV=200 kΩ to HV Pin
VDC
×0.45
VDC
×0.51
VDC
×0.56
V
tD-HV-DIS
Debounce Time for HV Discharge
75
115
155
ms
HV Discharge Time
360
510
660
ms
tHV-DIS
Continued on the following page…
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
5
FAN6757— mWSaver® PWM Controller
Electrical Characteristics
VDD=15 V and TJ=TA=25C unless otherwise noted.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
62
65
68
Hopping Range (VFB>VFB-N)
±3.55
±4.25
±4.95
VFB>VFB-G
5.12
6.40
7.68
20
23
26
±1.25
±1.50
±1.75
Unit
Oscillator Section
fOSC
Frequency in Normal Mode
tHOP
Hopping Period
Center Frequency
Center Frequency
kHz
ms
Green-Mode Frequency
Hopping Range (Increase
VFB from VFB-G Until Hopping
Starts)
fDV
Frequency Variation vs. VDD Deviation
VDD=11 V to 22 V
5
%
fDT
Frequency Variation vs. Temperature
Deviation
TA=-40 to 105C
5
%
1/3.00
V/V
fOSC-G
kHz
Feedback Input Section
AV
Input Voltage to Current-Sense
Attenuation
ZFB
Pull High Impedance at Normal Mode
1/4.50 1/3.75
FB Pin Open
17
19
21
kΩ
5.2
5.4
5.6
V
VFB-OPEN
Output High Voltage
VFB-OLP
FB Open-Loop Trigger Level
4.3
4.6
4.9
V
tD-OLP
Delay of FB Pin Open-Loop Protection
45.0
57.5
70.0
ms
VFB-N
Green-Mode Entry FB Voltage
2.6
2.8
3.0
V
VFB-G
Green-Mode Ending FB Voltage
2.1
2.3
2.5
V
VFB-ZDCR
FB Threshold Voltage for Zero-Duty
Recovery at Normal Mode
1.9
2.1
2.3
V
VFB-ZDC
FB Threshold Voltage for Zero-Duty at
Normal Mode
1.8
2.0
2.2
V
100
250
ns
200
265
330
ns
Current-Sense Section
tPD
Delay to Output
tLEB
Leading-Edge Blanking Time
VLIMIT-L
Current Limit at Low Line
(VAC-RMS=86 V)
VDC=122 V,
Series R=200 kΩ to HV
0.43
0.46
0.49
V
VLIMIT-H
Current Limit at High Line
(VAC-RMS=259 V)
VDC=366 V,
Series R=200 kΩ to HV
0.36
0.39
0.42
V
VSSCP-L
Threshold Voltage for SENSE ShortCircuit Protection
VDC=122 V,
Series R=200 kΩ to HV
30
50
70
mV
VSSCP-H
Threshold Voltage for SENSE ShortCircuit Protection
VDC=366 V,
Series R=200 kΩ to HV
80
100
120
mV
tON-SSCP
On Time for VSSCP-(L/H) Checking
VSENSE<VSSCP-(L/H)
4.00
4.55
5.10
µs
tD-SSCP
Debounce Time for SENSE ShortCircuit Protection
VSENSE<VSSCP-(L/H)
110
170
230
µs
Soft-Startup Time
Startup Time
5
7
9
ms
tSS
Continued on the following page…
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
6
FAN6757— mWSaver® PWM Controller
Electrical Characteristics
VDD=15 V and TJ=TA=25C unless otherwise noted.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
75.0
82.5
90.0
%
1.5
V
GATE Section
DCYMAX
Maximum Duty Cycle
VGATE-L
Gate Low Voltage
VDD=15 V, IO=50 mA
VGATE-H
Gate High Voltage
VDD=12 V, IO=50 mA
8
tr
Gate Rising Time (10~90%)
VDD=15 V, CL=1 nF
85
110
135
ns
tf
Gate Falling Time (10~90%)
VDD=15 V, CL=1 nF
30
40
50
ns
11.0
14.5
18.0
V
VGATE-CLAMP Gate Output Clamping Voltage
VDD=22 V
V
RT Section
IRT
Output Current of RT Pin
100
µA
VRTTH1
Threshold Voltage, Latch Protection
(Generally Used for External OTP
Triggering)
VRTTH2< VRT <VRTTH1,
After 14.5 ms Latch Off
1.000
1.035
1.070
V
VRTTH2
Second Latch Protection Threshold
Voltage
VRTTH2 < 0.7 V,
After 185 µs Latch Off
0.65
0.70
0.75
V
9.66
10.50
11.34
kΩ
ROTP
Value of VRTTH1/IRT
tD-OTP1
Debounce Time, First Latch Protection
Triggering
VRTTH2 < VRT < VRTTH1
11.0
14.5
18.0
ms
tD-OTP2
Debounce Time, Second Latch
Protection Triggering
VRT< VRTTH2
110
185
260
µs
Over-Temperature Protection Section (OTP)
TOTP
TRESTART
Protection Junction Temperature
+135
°C
Restart Junction Temperature
TOTP25
°C
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
7
FAN6757— mWSaver® PWM Controller
Electrical Characteristics
6.0
11.4
11.2
11.0
10.8
10.6
10.4
10.2
10.0
9.8
9.6
5.0
VDD-OFF (V)
VRESTART (V)
5.5
4.5
4.0
3.5
3.0
-40
-30
-15
0
25
50
75
85
100 125
-40
-30
-15
0
Temperature (ºC)
9.0
8
8.5
7
8.0
6
7.5
7.0
6.5
1
5.0
0
25
50
75
85
-40
100 125
-30
-15
0
25
50
75
85
100 125
Temperature (ºC)
Temperature (ºC)
Figure 7. VDD-OLP vs. Temperature
Figure 8. VDD-LH vs. Temperature
70
100
90
80
70
60
50
40
30
20
10
0
65
ILH (µA)
60
tD_OLP (ms)
100 125
3
5.5
0
85
4
2
-15
75
5
6.0
-30
50
Figure 6. VDD-OFF vs. Temperature
VDD-LH (V)
VDD-OLP (V)
Figure 5. VRESTART vs. Temperature
-40
25
Temperature (ºC)
55
50
45
40
35
30
-40
-30
-15
0
25
50
75
85
100 125
-40
Temperature (ºC)
Figure 9. TD-OLP vs. Temperature
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
-30
-15
0
25
50
75
Temperature (ºC)
85
100 125
Figure 10. ILH vs. Temperature
www.fairchildsemi.com
8
FAN6757— mWSaver® PWM Controller
Typical Characteristics
115
110
VAC-OFF (V)
VAC-ON (V)
120
118
116
114
112
110
108
106
104
102
100
105
100
95
90
85
80
-40
-30
-15
0
25
50
75
85
100 125
-40
-30
-15
Temperature (ºC)
0
25
50
75
85
100 125
Temperature (ºC)
Figure 11. VAC-ON vs. Temperature
Figure 12. VAC-OFF vs. Temperature
80
6.0
5.5
75
1/AV (V/V)
fOSC (kHz)
5.0
70
65
60
55
4.0
3.5
3.0
2.5
2.0
50
-40
-30
-15
0
25
50
75
85
-40
100 125
-30
-15
0
25
50
75
85
Temperature (ºC)
Temperature (ºC)
Figure 13. fOSC vs. Temperature
Figure 14. 1/AV vs. Temperature
21.0
20.5
20.0
19.5
19.0
18.5
18.0
17.5
17.0
16.5
16.0
VFB-OPEN (V)
ZFB (kΩ)
4.5
-40
-30
-15
0
25
50
75
85
6.0
5.9
5.8
5.7
5.6
5.5
5.4
5.3
5.2
5.1
5.0
100 125
-40
Temperature (ºC)
-30
-15
0
25
50
75
85
100 125
Temperature (ºC)
Figure 15. ZFB vs. Temperature
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
100 125
Figure 16. VFB-OPEN vs. Temperature
www.fairchildsemi.com
9
FAN6757— mWSaver® PWM Controller
Typical Characteristics
90
0.55
80
0.50
VLIMIT-L (V)
0.60
DCYMAX (%)
100
70
60
50
0.45
0.40
0.35
40
0.30
30
-40
-30
-15
0
25
50
75
85
-40
100 125
-30
-15
Figure 17. DCYMAX vs. Temperature
0.55
tLEB (ns)
VLIMIT-H (V)
0.50
0.45
0.40
0.35
0.30
0.25
0.20
-30
-15
0
25
50
75
50
75
85
100 125
85
380
360
340
320
300
280
260
240
220
200
100 125
-40
Temperature (ºC)
-30
-15
0
25
50
75
85
100 125
Temperature (ºC)
Figure 19. VLIMIT-H vs. Temperature
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
25
Figure 18. VLIMIT-L vs. Temperature
0.60
-40
0
Temperature (ºC)
Temperature (ºC)
Figure 20. tLEB vs. Temperature
www.fairchildsemi.com
10
FAN6757— mWSaver® PWM Controller
Typical Characteristics
Current Mode Control
FAN6757 employs peak current-mode control, as shown
in Figure 21. An opto-coupler (such as the H11A817A)
and a shunt regulator (such as the KA431) are typically
used to implement the feedback network. Comparing
the feedback voltage with the voltage across the Rsense
resistor makes it possible to control the switching duty
cycle. The built-in slope compensation stabilizes the
current loop and prevents sub-harmonic oscillation.
5.4 V
2
GATE
8
SENSE
6
VO
VFB
VFB.ZDCR
VFB.ZDC
IDrain
VO
ZFB
PWM
Comparator
switching, reducing switching loss for lower power
consumption, as shown in Figure 23.
FB
Switching
Disabled
3R
Gate
driver
KA431
R
+
Primary side
+
Secondary
side
Slope
compensatin
Figure 21. Current Mode Control Circuit Diagram
Switching
Disabled
Figure 23. Burst Switching in Green Mode
Operating Current
In normal conditions, operating current is less than
1.8 mA (IDD-OP1). When VFB<1.4 V, operating current is
further reduced below 800 µA (IDD-OP2) by disabling
several blocks of the FAN6757. The low operating
current improves light-load efficiency and reduces the
requirement of VDD hold-up capacitance.
Green-Mode Operation
High-Voltage Startup and Line Sensing
The FAN6757 modulates the PWM frequency as a
function of the FB voltage to improve the medium- and
light-load efficiency, as shown in Figure 22. Since the
output power is proportional to the FB voltage in currentmode control, the switching frequency decreases as
load decreases. In heavy-load conditions, the switching
frequency is fixed at 65 kHz. Once VFB decreases below
VFB-N (2.8 V), the PWM frequency starts linearly
decreasing from 65 kHz to 23 kHz to reduce switching
losses. As VFB drops to VFB-G (2.3 V), where switching
frequency is decreased to 23 kHz, the switching
frequency is fixed to avoid acoustic noise.
The HV pin is typically connected to the AC line input
through two external diodes and one resistor (R HV), as
shown in Figure 24. When the AC line voltage is
applied, the VDD hold-up capacitor is charged by the line
voltage through the diodes and resistor. After VDD
reaches the turn-on threshold voltage (VDD-ON), the
startup circuit charging VDD capacitor is switched off and
VDD is supplied by the auxiliary winding of the
transformer. Once the FAN6757 starts up, it continues
operation until VDD drops below 6.5 V (VUVLO). The IC
startup time with a given AC line input voltage is:
fS
tSTARTUP  RHV  CDD  ln
fOSC
VAC IN 
VAC IN 
2 2

2 2

(1)
 VDD ON
RHV
4
fOSC-G
HV
7
VFB-N
VFB
CDD
VDD-ON/
VRESTART
Figure 22. VFB vs. PWM Frequency
CX
When VFB falls below VFB-ZDC (2.0 V) as load decreases
further, the FAN6757 enters Burst Mode operation,
where PWM switching is disabled. Then the output
voltage starts to drop, causing the feedback voltage to
rise. Once VFB rises above VFB-ZDCR (2.1 V), switching
resumes. Burst Mode alternately enables and disables
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
-
VFB-ZDC VFB-ZDCR VFB-G
VDD
+
VDD
Good
RLS
Sampling
Circuit
Brown-in/out
Function
AC Line
High/ Low Line
Compensation
VLIMIT
VOCP
Figure 24. Startup Circuit
www.fairchildsemi.com
11
FAN6757— mWSaver® PWM Controller
Functional Description
increases. The current-limit level is also proportional to
the RHV resistor value and the power-limit level can be
tuned using the RHV resistor.
OSC
GATE
8
DRV
Q S
V BROWN -OUT (RMS) 
R HV V AC ON
200k

2
R HV V AC OFF

2
200k
Current limit
comparator
HV
VLIMIT
+
+
Slope
compensation
SENSE
Power Limit Line
Compensation
6
VLIMIT (V)
0.5
Note that VDD must be larger than VDD-AC to start up,
even though sensed line voltage satisfies Equation 2.
0.45
RHV=240 kΩ
AX-CAP® Discharge
RHV=200 kΩ
0.4
RHV=160 kΩ
0.35
0.3
70
110
150
190
230
Line Voltage (VAC)
270
Figure 26. Current Limit vs. Line Voltage
Under-Voltage Lockout (UVLO)
As shown in Figure 27, as long as protection is not
triggered, the turn-off threshold of VDD is fixed internally
at VUVLO (6.5 V). When Protection Mode is triggered, the
VDD level to terminate PWM gate switching is changed
to VDD-OFF (11 V), as shown in Figure 28. When VDD
drops below VDD-OFF, switching is terminated and the
operating current from VDD is reduced to IDD-OLP to slow
down the discharge of VDD until VDD reaches VDD-OLP.
This delays re-startup after shutdown by protection to
minimize the input power and voltage/current stress of
switching devices during fault condition.
VDD
FAN6757 has pulse-by-pulse current limit, as shown in
Figure 25, to limit the maximum input power with a given
input voltage. If the output consumes beyond this
maximum power, the output voltage drops triggering the
overload protection.
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
R
Figure 25. Pulse-by-pulse Current Limit Circuit
Since the internal resistor (RLS=1.62 kΩ) of the voltage
divider is much smaller than RHV, the thresholds are
given as a function of RHV.
As shown in Figure 25, the high/low line compensation
block adjusts the current-limit level, VLIMIT, based on the
line voltage. Figure 26 shows how the pulse-by-pulse
current-limit level changes with the line voltage for
different RHV resistors. To maintain the constant output
power limit regardless of line voltage, the cycle-by-cycle
current-limit level, VLIMIT, decreases as line voltage
Line
Sensing
4
(3)
High/Low Line Compensation for Constant
Power Limit
SS
comparator
2
FB
VSS
(2)
The EMI filter in the front end of the Switched-Mode
Power Supply (SMPS) typically includes a capacitor
across the AC line connector. Most of the safety
regulations, such as UL 1950 and IEC61010-1, require
the capacitor be discharged to a safe level within a
given time when AC plug is removed from its receptacle.
Typically, discharge resistors across the capacitor are
used to ensure the capacitor is discharged naturally,
which introduces power loss as long as it is connected
to the receptacle.
®
The innovative AX-CAP
technology intelligently
discharges the filter capacitor only when the power
supply is unplugged from the power outlet. Since the
®
AX-CAP discharge circuit is disabled in normal
operation, the power loss in the EMI filter can be
virtually removed.
The discharge of the capacitor is achieved through the
HV pin. Once AC outlet detaching is detected, the
FAN6757 discharges the capacitor across the AC line
connector by the external resistor on the HV pin.
3R
Q R
Based on the detected line voltage, brown-in and
brownout thresholds are determined as:
V BROWN - IN (RMS) 
5.4 V
ZFB
PWM
Comparator
VDD-ON
17 V
VUVLO
VRESTART
6.5 V
4.7 V
GATE
t
Figure 27. VDD UVLO at Normal Mode
www.fairchildsemi.com
12
FAN6757— mWSaver® PWM Controller
The HV pin detects the AC line voltage using a switched
voltage divider consisting of an external resistor (RHV)
and an internal resistor (RLS), as shown in Figure 24.
The internal line-sensing circuit detects line voltage
using a sampling circuit and a peak-detection circuit.
Since the voltage divider causes power consumption
when it is switched on, the switching is driven by a
signal with a very narrow pulse width to minimize power
loss. The sampling frequency is also adaptively
changed according to the load condition to minimize
power consumption in light-load condition.
function. For OTP applications, an NTC thermistor,
RNTC, usually in series with a resistor RA, is connected
between the RT pin and ground. The internal current
source, IRT, (100 µA) introduces voltage on RT as:
17 V
VRT  I RT  (RNTC  R A )
11 V
VDD-OFF
VDD-OLP
At high ambient temperature, RNTC decreases reducing
VRT. When VRT is lower than VRTTH1 (1.035 V) for longer
than tD-OTP1 (14.5 ms), the protection is triggered and the
FAN6757 enters latch mode protection.
7V
GATE
t
Figure 28. VDD UVLO at Protection Mode
Leading-Edge Blanking (LEB)
Each time the power MOSFET is switched on, a turn-on
spike occurs on the sense resistor. To avoid premature
termination of the switching pulse, a leading-edge
blanking time, tLEB, is introduced. During this blanking
period, the current-limit comparator is disabled and
cannot switch off the gate driver.
Gate Output / Soft Driving
The BiCMOS output stage has a fast totem-pole gate
driver. The output driver is clamped by an internal
14.5 V Zener diode to protect power MOSFET gate from
over voltage. A soft driving is implemented to minimize
electromagnetic interference (EMI) by reducing the
switching noise.
VDD Over-Voltage Protection (OVP)
VDD over-voltage protection prevents IC damage from
over-voltage exceeding the IC voltage rating. When the
VDD voltage exceeds 24.5 V, the protection is triggered.
This protection is typically caused by open circuit of the
secondary-side feedback network.
The OTP can be also trigged by pulling down the RT pin
voltage using an opto-coupler or transistor. Once VRT is
less than VRTTH2 (0.7 V) for longer than tD-OTP2 (185 µs),
the protection is triggered and latch mode protection
begins.
When OTP is not used, it is recommended to place a
10 kΩ resistor between this pin and ground to prevent
noise interference.
Sense-Pin Short-Circuit Protection
FAN6757 provides safety protection for Limited Power
Source (LPS) test. When the current-sense resistor is
short circuited by a soldering defect during production,
the current-sensing information is not properly obtained,
which results in unstable operation of the power supply.
To protect the power supply against a short circuit
across the current-sense resistor, the FAN6757 shuts
down when the current-sense voltage is very low, even
with a relatively large duty cycle. As shown in Figure 29,
the current-sense voltage is sampled tON-SSCP (4.55 µs)
after the gate turn-on. If the sampled voltage (VS-CS) is
lower than VSSCP for 11 consecutive switching cycles
(170 µs), the FAN6757 shuts down immediately. VSSCP
varies linearly with the line voltage. At 122 V DC input, it
is typically 50 mV (VSSCP-L); while at 366 V DC, it is
typically100 mV (VSSCP-H).
Soft-Start
An internal soft-start circuit progressively increases the
pulse-by-pulse current-limit level of the MOSFET for
7 ms during startup to establish the correct working
conditions for the transformers and capacitors.
tD-SSCP
VS-CS
VSENSE
GATE
Over-Temperature Protection (OTP)
tON-SSCP
Figure 29. Timing Diagram of SSCP
The RT pin provides adjustable Over-Temperature
Protection (OTP) and an external latch triggering
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
(4)
www.fairchildsemi.com
13
FAN6757— mWSaver® PWM Controller
VDD
VDD-ON
Application
PWM Controller
Input Voltage Range
Output
65 W Notebook Adapter
FAN6757MRMX
85 VAC ~ 265 VAC
19 V, 3.42 A
X-cap
BD1
0.33F/275V
2A/600V
CDO
RDO
1nF/100V 23.5
LO
TF1
1.5H
510H
VAC
+
ZDSN
DO
P6KE150A
20A/150V
DSN
CIN
CO2
VO
470F/
25V
FR107
120F/
400V
1N4007
CO1
1000F/
25V
-
1N4007
Q1
FQPF7N65C
RG
20
RSENSE
RHV
0.176
200k
FAN6757
1 GND
RLPF
GATE 8
2 FB
100
RD
VDD 7
R1
1.2k
200k
3 NC
SENSE 6
4 HV
RT 5
CFB
CLPF
DDD
RA
1nF
PC817A
470pF
RF
CF
4.7k
2.2nF
1N4935
5.6k
RNTC
100k
CDD
KA431
R2
47F/ 50V
30k
Figure 30. Schematic of Typical Application Circuit
Transformer Schematic Diagram


Core: Ferrite Core RM-10
Bobbin: RM-10
RM-10
4
3-Layer Tape
S
N4
N1
3-Layer Tape
Shielding
1-Layer Tape
3-Layer Tape
N2
5
N3
N4
6
7
N3
F
N2
3-Layer Tape
Shielding
1-Layer Tape
N1
9
Bobbin
Figure 31. Transformer Specification
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
14
FAN6757— mWSaver® PWM Controller
Typical Application Circuit
Pin (Start → Finish)
Wire
Turns
Winding Method
Remark
4→5
0.5φ×1
19
Solenoid Winding
Enameled Copper Wire
N1
Insulation: Polyester Tape, t = 0.025 mm, 1 Layer
Shielding: Adhesive Tape of Copper Foil, t = 0.025×7 mm, 1.2 Layers, Open Loop, Connected to Pin 4
Insulation: Polyester Tape t = 0.025 mm, 3 Layers
S→F
N2
0.9φ×1
8
Solenoid Winding
Triple Insulated Wire
7
Solenoid Winding
Enameled Copper Wire
Insulation: Polyester Tape, t = 0.025mm, 3 Layers
9→7
N3
0.4φ×1
Insulation: Polyester Tape, t = 0.025 mm, 1 Layer
Shielding: Adhesive Tape of Copper Foil, t = 0.025×7 mm, 1.2 Layers, Open Loop, Connected to Pin 4
Insulation: Polyester Tape t = 0.025 mm, 3 Layers
5→6
N4
0.5φ×1
19
Solenoid Winding
Enameled Copper Wire
Insulation: Polyester Tape t = 0.025 mm, 3 Layers
Electrical Characteristics
Pin
Specification
Remark
Primary-Side Inductance
4-6
510 H ±5%
1 kHz, 1 V
Primary-Side Effective Leakage Inductance
4-6
20 H Maximum
Short All Other Pins
Typical Performance
Table 1. Power Consumption
Input Voltage
230 VAC
Output Power
Actual Output Power
Input Power
Specification
No Load
0W
0.045 W
Input Power < 0.05 W
0.25 W
0.255 W
0.360 W
Input Power < 0.5 W
0.5 W
0.521 W
0.711 W
Input Power < 1 W
Table 2. Efficiency
Output Power
16.25 W
32.5 W
48.75 W
65 W
Average
115 V 60 Hz
87.84%
87.42%
86.92%
86.23%
87.10%
230 V 50 Hz
87.88%
87.95%
87.82%
87.69%
87.83%
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
www.fairchildsemi.com
15
FAN6757— mWSaver® PWM Controller
Winding Specification
5.00
4.80
A
0.65
3.81
8
5
B
1.75
6.20
5.80
PIN ONE
INDICATOR
4.00
3.80
1
5.60
4
1.27
(0.33)
1.27
0.25
C B A
LAND PATTERN RECOMMENDATION
SEE DETAIL A
0.25
0.10
0.25
0.19
C
1.75 MAX
0.10
0.51
0.33
OPTION A - BEVEL EDGE
0.50 x 45°
0.25
R0.10
GAGE PLANE
R0.10
OPTION B - NO BEVEL EDGE
0.36
NOTES: UNLESS OTHERWISE SPECIFIED
8°
0°
0.90
0.40
A) THIS PACKAGE CONFORMS TO JEDEC
MS-012, VARIATION AA.
B) ALL DIMENSIONS ARE IN MILLIMETERS.
C) DIMENSIONS DO NOT INCLUDE MOLD
FLASH OR BURRS.
D) LANDPATTERN STANDARD: SOIC127P600X175-8M.
E) DRAWING FILENAME: M08Arev14
F) FAIRCHILD SEMICONDUCTOR.
SEATING PLANE
(1.04)
DETAIL A
SCALE: 2:1
Figure 32. 8-Pin, SOP-8 Package
Package drawings are provided as a service to customers considering our components. Drawings may change in any manner
without notice. Please note the revision and/or date on the drawing and contact our representative to verify or obtain the most recent
revision. Package specifications do not expand the terms of our worldwide terms and conditions, specifically the warranty therein,
which covers our products.
Always visit Fairchild Semiconductor’s online packaging area for the most recent package drawings:
http://www.fairchildsemi.com/dwg/M0/M08A.pdf.
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
16
FAN6757— mWSaver® PWM Controller
Physical Dimensions
FAN6757— mWSaver® PWM Controller
© 2013 Fairchild Semiconductor Corporation
FAN6757 • Rev. 1.0.1
17
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