ETC NCP1651/D

NCP1651
Single Stage Power Factor
Controller
The NCP1651 is an active, power factor correction controller that
can operate over a wide range of input voltages. It is designed for
50/60 Hz power systems. It is a fixed frequency controller that can
operate in continuous or discontinuous conduction modes.
The NCP1651 provides a low cost, low component count solution
for isolated ac−dc converters with mid−high output voltage
requirements. The NCP1651 eases the task of meeting the
IEC1000−3−2 harmonic requirements for converters in the range of
50 W − 250 W.
The NCP1651 drives a flyback converter topology to operate in
continuous/discontinuous mode and programs the average input
current to follow the line voltage in order to provide unity power
factor. By using average current mode control CCM algorithm, the
NCP1651 can help provide excellent power factor while limiting the
peak primary current. Also, the fixed frequency operation eases the
input filter design.
The NCP1651 uses a proprietary multiplier design that allows for
much more accurate operation than with conventional analog
multipliers.
Features
•
•
•
•
•
•
•
•
•
•
Fixed Frequency Operation
Average Current Mode PWM
Internal High Voltage Start−Up Circuit
Continuous or Discontinuous Mode Operation
High Accuracy Multiplier
Overtemperature Shutdown
External Shutdown
Undervoltage Lockout
Low Cost/Parts Count Solution
Ramp Compensation Does Not Affect Oscillator Accuracy
Typical Applications
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MARKING
DIAGRAM
SO−16
D SUFFIX
CASE 751B
16
1
A
WL, L
YY, Y
WW, W
= Assembly Location
= Wafer Lot
= Year
= Work Week
PIN CONNECTIONS
OUT 1
16 STARTUP
GND 2
15 NC
CT 3
14 NC
RAMP COMP 4
13 VCC
IS+ 5
12 Vref
Iavg−fltr 6
11 AC COMP
Iavg 7
10 AC REF
FB/SD 8
9 AC INPUT
(Top View)
ORDERING INFORMATION
Package
Shipping†
NCP1651D
SO−16
48 Units/Rail
NCP1651DR2
SO−16
2500/Tape & Reel
Device
• High Current Battery Chargers
• Front Ends for Distributed Power Systems
TBD
†For information on tape and reel specifications,
including part orientation and tape sizes, please
refer to our Tape and Reel Packaging Specifications
Brochure, BRD8011/D.
 Semiconductor Components Industries, LLC, 2003
October, 2003 − Rev. 5
1
Publication Order Number:
NCP1651/D
NCP1651
PIN FUNCTION DESCRIPTION
Pin No.
Function
Description
1
Output
Drive output for power FET or IGBT. Capable of driving small devices, or can be connected to an
external driver for larger transistors.
2
Ground
Ground reference for the circuit.
3
CT
4
Ramp
Compensation
Timing capacitor for the internal oscillator. This capacitor adjusts the oscillator frequency.
5
IS+
6
Iavg−fltr
A capacitor connected to this pin filters the high frequency component from the instantaneous current
waveform, to create a waveform that resembles the average line current.
7
Iavg
An external resistor with a low temperature coefficient is connected from this terminal to ground, to set
and stabilize the gain of the Current Sense Amplifier output that drives the ac error amplifier.
8
Feedback/
Shutdown
The error signal from the error amplifier circuit is fed via an optocoupler or other isolation circuit, to this
pin. A shutdown circuit is also connected to this pin which will put the unit into a low power shutdown
mode if this voltage is reduced to less than 0.6 volts.
9
AC Input
10
AC Reference
A capacitor is connected to this pin to filter the modulated output of the reference multiplier.
11
AC
Compensation
Provides pole for the ac Reference Amplifier. This amplifier compares the sum of the ac input voltage
and the low frequency component of the input current to the reference signal. The response must be
slow enough to filter out most of the high frequency content of the current signal that is injected from
the current sense amplifier, but fast enough to cause minimal distortion to the line frequency
information.
12
Vref
6.5 volt regulated reference output.
13
VCC
Provides power to the device. This pin is monitored for undervoltage and the unit will not operate if the
VCC voltage is not within the UVLO range. Initial power is supplied to this pin via the high voltage
start−up network.
14
No Connection
This pin is not available due to spacing considerations of the start−up pin.
15
No Connection
This pin is not available due to spacing considerations of the start−up pin.
16
Start−up
This pin biases the ramp compensation circuit, to adjust the amount of compensation that is added to
the current signal for stability purposes.
Positive current sense input. Designed to connect to the positive side of the current shunt.
The fullwave rectified sinewave input is connected to this pin. This information is used for the
reference comparator and the average current compensation circuit.
This pin connects to the rectified input signal and provides current to the internal bias circuitry for the
start−up period of operation.
NOTE: Pins 14 and 15 have not been used for clearance considerations due to the potential voltages present on pin 16. In order to
maintain proper spacing between the high voltage and low voltage pins, traces should not be placed on the circuit board between
pins 16 and 13.
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NCP1651
MAXIMUM RATINGS (Maximum ratings are those that, if exceeded, may cause damage to the device. Electrical Characteristics are
not guaranteed over this range.)
Rating
Symbol
Value
Unit
VCC
−0.3 to 18
V
Current Sense Amplifier Input (Pin 5)
V(IS+)
−0.3 to 1.0
V
FB/SD Input (Pin 8)
VFB/SD
−0.3 to 11
V
VCT
−0.3 to 4.5
V
Vstartup
−0.3 to 500
V
−0.3 to 6.5
V
Power Supply Voltage (Operating)
Output (Pin 1)
CT Input (Pin 3)
Line Voltage
All Other Pins
°C/W
Thermal Resistance, Junction−to−Air
0.1 in2 Copper
0.5 in2 Copper
JA
Thermal Resistance, Junction−to−Lead
JL
50
°C/W
Pmax
0.77
W
Operating Temperature Range
Tj
−40 to 125
°C
Non−operating Temperature Range
Tj
−55 to 150
°C
130
110
Maximum Power Dissipation @ TA = 25°C
1. Maximum Ratings are those values beyond which damage to the device may occur. Exposure to these conditions or conditions beyond those
indicated may adversely affect device reliability. Functional operation under absolute maximum−rated conditions is not implied. Functional
operation should be restricted to the Recommended Operating Conditions.
A. This device series contains ESD protection and exceeds the following tests:
Pins 1−6: Human Body Model 2000 V per MIL−STD−883, Method 3015.
Pins 1−6: Machine Model Method 200 V.
Pin 8 is the HV start−up to the device and is rated to the maximum rating of the part, or 500 V.
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NCP1651
ELECTRICAL CHARACTERISTICS (Unless otherwise noted: VCC = 14 volts, CT = 470 pF, C12 = 0.1 F, Tj = 25°C for typical
values. For min/max values Tj is the applicable junction temperature.)
Characteristic
Symbol
Min
Typ
Max
Unit
Fosc
90
100
110
kHz
OSCILLATOR
Frequency
Tj = −40°C to +125°C
Frequency Range (Note 2)
−
25
−
250
kHz
Max Duty Cycle
dmax
0.95
−
−
−
Ramp Peak (Note 2)
VRpeak
−
4.0
−
V
Ramp Valley (Note 2)
VRvalley
−
0.100
−
V
Ramp Compensation Peak Voltage (Pin 4) (Note 2)
−
−
4.0
−
V
Ramp Compensation Current (Pin 4) (Note 2)
−
−
150
−
A
Input Offset Voltage
VIO
−
20
−
mV
Transconductance
gm
75
100
150
umho
IOsource
25
70
−
A
IOsink
−25
−70
−
A
Input Bias Current (Pin 5)
Ibias
40
60
80
A
Input Offset Voltage (Vcomp = 2.0) Tj = −40°C to +85°C
Tj = −40°C to +125°C
VIO
0
0
3.0
3.0
10
20
mV
ILIMthr
0.715
−
0.79
V
Output Gain (150 A/0.150 V) (Voltage Loop Outputs)
−
−
1000
−
umho
Output Gain (150 A/0.150 V) (AC E/A Output) (R10 = 15 k)
−
−
1000
−
umho
tLEB
−
200
−
ns
Bandwidth (Note 2)
−
−
1.5
−
MHz
PWM Output Voltage Gain (k = VPWM+ / (Vsense+ − Vsense−))
(Vpin 3 = Vpin 13 = 0)
Av
4.0
5.0
6.0
V/V
Current Limit Voltage Gain
(k = Vace/a− / (Vsense+ − Vsense−)) (Vpin59 = 0) (R7 = 15 k)
Av
8.0
10
12
V/V
Av
−
0.75
−
V/V
−
−
3.50
1.0
−
−
−
7.5
−
−
0.01
−
AC ERROR AMPLIFIER (Vcomp = 2.0 V)
Output Source
Output Sink
CURRENT AMPLIFIER
Current Limit Threshold
Leading Edge Blanking Pulse (Note 2)
AVERAGE CURRENT COMPENSATION AMPLIFIER
Voltage Gain
REFERENCE MULTIPLIER
Dynamic Input Voltage Range
Ac Input (p−input) (Note 2)
Offset Voltage (a−input)
Vmax
Multiplier Gain
V
k
k
Vmult out
(VACVramp pk) (VLOOPcomp Voffset)
−
(Note 2)
AC INPUT (Pin 5)
Input Bias Current (Total bias current for reference multiplier and current
compensation amplifier) (Note 2)
2. Verified by design.
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IINbias
A
NCP1651
ELECTRICAL CHARACTERISTICS (continued) (Unless otherwise noted: VCC = 14 volts, CT = 470 pF, C12 = 0.1 F, Tj = 25°C for
typical values. For min/max values Tj is the applicable junction temperature.)
Symbol
Min
Typ
Max
Unit
Rsource
−
8.0
15
Rsink
−
8.0
15
Rise Time (CL = 1.0 nF)
tr
−
50
−
ns
Fall Time (CL = 1.0 nF)
tf
−
50
−
ns
VO(UV)
−
1.0
10
mV
VrefOUT
6.24
6.50
6.76
V
DVrefOUT
0
−
40
mV
IOPTO
0.8
1.1
1.4
mA
Opto Current Source (Shutdown, VFB = 0.1 V)
−
15
20
25
A
Input Voltage for 0 Duty Cycle (Note 3)
−
1.5
−
−
−
Characteristic
DRIVE OUTPUT
Source Resistance (1.0 Volt Drop)
Sink Resistance (1.0 Volt Drop)
Output Voltage in UVLO Condition (Drive out = 100 A in, 1 nF load)
VOLTAGE REFERENCE
Buffered Output (Iload = 0 mA, VCC = 12 VDC, Temperature)
Load Regulation (Buffered Output, Io = 0 to 10 mA, VCC > 10 V)
FB/SD PIN
Opto Current Source (Unit Operational, VFB = 0.5 V)
Input Voltage for 95% Duty Cycle (Note 3)
−
−
−
4.0
V
Open Circuit Voltage (Device Operational) (Note 3)
VOC
−
−
12
V
Clamp Voltage (Device in Shutdown Mode) (Note 3)
VCL
0.9
1.5
1.6
V
Shutdown Start Up Threshold (Pin 8) (Vout Increasing)
VSD
0.40
0.60
0.70
V
Shutdown Hysteresis (Pin 8)
VH
30
75
130
mV
UVLO Startup Threshold (VCC Increasing)
VSU
10
10.75
11.5
V
UVLO Hysteresis (Shutdown Voltage = VSU – VH)
VH
0.8
1.0
1.2
V
Overtemperature Trip Point (Note 3)
TSD
140
160
180
°C
Overtemperature Hysteresis (Note 3)
−
−
30
−
°C
ISU
3.0
5.5
8.0
mA
5.0
8.5
12
mA
−
17
20
V
−
−
25
15
40
80
IBIAS
−
4.0
5.0
mA
IBshutdown
−
0.75
1.2
mA
STARTUP/UVLO
HIGH VOLTAGE START−UP (Pin 16 = 50 V)
Start−up Current (out of pin 13) (VCC = UVLO − 0.2 V)
Start−up Current (out of pin 13) (VCC = 0 V)
Min. Start−up Voltage (pin 16, pin 13 current = 1 mA)
VSU
Line Pin Leakage (pin 16, Start−up Circuit Inhibited)
(VDS = 400 V, TA = +25°C)
TA = +125°C
Ileak
A
TOTAL DEVICE
Operational Bias Current (CL(Driver) = 1.0 nF, fosc = 100 kHz)
Bias Current in Undervoltage Mode
3. Verified by design.
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NCP1651
16
STARTUP
13
VCC
6.5 V
4V
6.5 V
Vref
REFERENCE
REGULATOR
20 A
3.8 k
12
UVLO
FB/SD
+
−
8
0.50 V
V−I
CONVERTER
÷8 COUNTER
SHUTDOWN
R
Q
Clk
OVER−
TEMPERATURE
SENSOR
A
AC INPUT
9
REFERENCE
MULTIPLIER
AC REFERENCE
BUFFER
0.75 Vline + k ⋅ Iin = Vref
+
P
−
AC REF
4V
V−I
+
AC ERROR
AMP
16 k
S
PWM
Q
R
10
25 k
−
SET
4.5 V
DOMINANT
DRIVER
AC COMP
RAMP
COMPENSATION
11
LEB
1
20 k
+
+
−
OUT
IS+
5
OSCILLATOR
60 k
AVERAGE
CURRENT
COMPENSATION
CURRENT
SENSE
AMPLIFIER
−
GND
2
RAMP COMP
4
3
CT
Figure 1. Block Diagram
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Iavg 7 6 Iavg−fltr
NCP1651
DRIVE
LATCH Q
AC Error Amp + Ramp Comp + Inductor Current
PWM
4V
GND
FB/SD
0.5 V
GND
OSCILLATOR
RAMP
OSCILLATOR
BLANKING PULSE
Figure 2. Switching Timing Diagram
7
7
VCC
8
1
2
3
7
8
7
7
10.8 V
9.8 V
STARTUP OFF
ENABLE
ON
OUTPUT MAX
CURRENT
0
FB/SD
0.5 V
0
SHUTDOWN
START−UP
CURRENT LIMIT
Figure 3. Divide−by−Eight Counter Timing Diagram
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SHUTDOWN
7
8
NCP1651
Typical Performance Characteristics
(Test circuits are located in the document TND308/D)
5
12
10
4
PIN 7
8
Vpin 8 (V)
Vout (V)
PIN 6
3
2
6
4
1
2
0
0
0
100
200
300
400
500
0
400
600
800
1000 1200 1400 1600
Isink (A)
Figure 4. Current Sense Amplifier Gain
Figure 5. FB/SD V−I Characteristics
0.9
5.0
−40°C
0.8
VCC = 14 V
BIAS CURRENT (mA)
0°C
0.7
CURRENT (mA)
200
IS+ (mV)
25°C
80°C
0.6
0.5
125°C
0.4
0.3
0.2
4.5
4.0
3.5
3.0
0.1
0
0
2
4
6
8
10
2.5
−50
12
0
25
50
75
100
125
TEMPERATURE (°C)
Figure 6. Bias Current in Shutdown Mode
Figure 7. Bias Current in Operating Mode
9
150
39
25°C
8
−40°C
LEAKAGE CURRENT, PIN 16 (A)
STARTUP CURRENT, PIN 16 (mA)
−25
VCC (V)
0°C
7
6
125°C
5
80°C
4
3
2
1
0
1
10
100
34
29
24
19
14
9.0
−50
1000
−25
0
25
50
75
100
125
150
STARTUP PIN VOLTAGE (V)
TEMPERATURE (°C)
Figure 8. Startup Current versus High Voltage
Figure 9. Startup Leakage versus Temperature
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NCP1651
Typical Performance Characteristics
(Test circuits are located in the document TND308/D)
11.2
1.5
CLAMP VOLTAGE, PIN 8 (V)
TURN−ON
THRESHOLD (V)
10.8
10.5
10.2
TURN−OFF
9.8
9.5
−50
1.0
0.5
0
−25
0
25
50
75
100
125
0
2
4
6
8
10
12
TEMPERATURE (°C)
VCC (V)
Figure 10. UVLO versus Temperature
Figure 11. FB/SD Clamp Voltage versus VCC
5
1000
2.5 V
4.5
VCC, CAPACITANCE (F)
FB/SD = 3.0 V
4
2.0 V
AC REF (V)
3.5
3
2.5
1.8 V
2
1.5
1
100
10
1.6 V
0.5
0
1
0
1
2
4
3
5
1
10
100
1000
10,000
AC INPUT (V)
CHARGE TIME (ms)
Figure 12. Reference Multiplier Gain
Figure 13. VCC Cap Charge Time
100 k
4.40
NOTE: Ramp Valley
Voltage is Zero for
All Frequencies
4.35
4.30
CT (pF)
RAMP PEAK
10 k
1000
4.25
4.20
4.15
4.10
4.05
4.00
100
3.95
1
10
100
1000
0
50
100
150
200
250
FREQUENCY (kHz)
FREQUENCY (kHz)
Figure 14. CT versus Frequency
Figure 15. Ramp Peak versus Frequency
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300
NCP1651
Typical Performance Characteristics
(Test circuits are located in the document TND308/D)
10,000
99
RISE TIME
CAPACITANCE
98
97
96
95
1000
94
100
93
0
50
100
150
200
250
0
300
50
100
150
200
250
300
FREQUENCY (kHz)
10% TO 90% DRIVE RISE AND FALL TIMES
Figure 16. Maximum Duty Cycle versus
Frequency
Figure 17. Capacitance versus 10% to 90%
Drive Rise and Fall Times
350
110
Vref
50 mV/div
10 mA
Vref Load
0 mA
FREQUENCY (kHz)
MAXIMUM DUTY CYCLE
FALL TIME
105
100
95
90
−50
2.0 s/div
−25
0
25
50
75
100
125
TEMPERATURE (°C)
Figure 18. Transient Response for 6.5 Volt
Reference
Figure 19. Frequency versus Temperature
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10
150
NCP1651
Typical Performance Characteristics
(Test circuits are located in the document TND308/D)
6.52
NOTE: Valley
Voltage is Zero
25°C
4.10
Vref (V)
6.50
4.08
4.06
4.04
−50
−40°C
6.48
6.46
125°C
6.44
−25
0
25
50
75
100
125
2
0
4
6
8
TEMPERATURE (°C)
Vref LOAD (mA)
Figure 20. Peak Ramp Voltage versus
Temperature
Figure 21. Vref Load Regulation
1
0.8
NO LOAD
Vref (V)
PEAK RAMP VOLTAGE (V)
4.12
0.6
10 k
0.4
3.3 k
0.2
0
−50
−25
0
25
50
75
100
TEMPERATURE (°C)
Figure 22. Vref in Shutdown Condition
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125
10
NCP1651
6.5 V
3.8 k
FB/SD
9
SHUT
DOWN
680
V−I
CONVERTER
5
A
REFERENCE
MULTIPLIER
AC INPUT
(Allows external converters to be synchronized to the
switching frequency of this unit.)
Figure 23. External Shutdown Circuit
Vref
12
33 k
BAS16LT1
AC COMP
11
MMBT2907AL
R11
0.33 F
C11
Figure 24. Soft Start Circuit
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NCP1651
NCP1651
THEORY OF OPERATION
Introduction
Optimizing the power factor of units operating off of ac
lines is becoming more and more important. There are a
number of reasons for this.
There are a growing number of government regulations
requiring PFC (Power Factor Correction). Many of these are
originating in Europe. Regulations such as IEC1000−3−2
are forcing equipment to utilize input stages with topologies
other than a simple off−line front end which contains a
bridge rectifier and capacitor.
There are also system requirements that dictate the use of
PFC. In order to obtain the maximum power from an
existing circuit in a building, the power factor is very critical.
The real power available from such a circuit is:
reactive loads such as motors which are inductive, or
electroluminescent lighting which is highly capacitive. In
such a case the power factor is relatively simple to analyze,
and is determined by the phase shift.
PF cos Where is the phase angle between the voltage and the
current.
Reduced power factor due to distortion is more
complicated to analyze and is normally measured with ac
analyzers, although most circuit simulation programs can
also calculate power factor. One of the major causes of
distortion is rectification of the line into a capacitive filter.
This causes current spikes that do not follow the input
voltage waveform. An example of this type of waveform is
shown in the upper diagram in Figure 25.
A power converter with PFC forces the current to follow
the input waveform. This reduces the peak current, the rms
current and eliminates any phase shift.
In most modern PFC circuits, to lower the input current
harmonics, and improve the input power factor, designers
have historically used a boost topology. The boost topology
can operate in the Continuous (CCM), Discontinuous
(DCM), or Critical Conduction Mode.
Most PFC applications using the boost topology are
designed to use the universal input ac power 85−265 Vac, 50
or 60 Hz, and provide a regulated dc bus (typically 400 Vdc).
In most applications, the load can not operate off the high
voltage dc bus, so a dc−dc converter is used to provide
isolation between the ac source and load, and provide a low
voltage output. The advantages to this system configuration
are, low THD, a power factor close to unity, excellent
voltage regulation, and transient response on the isolated dc
output. The major disadvantage of the boost topology is that
two power stages are required which lowers the systems
efficiency, increases components count, cost, and increases
the size of the power supply.
ON Semiconductor’s NCP1651 offers a unique
alternative for Power Factor Correction designs, where the
NCP1651 has been designed to control a PFC circuit
operating in a flyback topology. There are several major
advantages to using the flyback topology. First, the user can
create a low voltage isolated secondary output, with a single
power stage, and still achieve a low input current distortion,
and a power factor close to unity. A second advantage,
compared to the boost topology with a dc−dc converter, is a
lower component count which reduces the size and the cost
of the power supply.
The NCP1651 can operate in either the Continuous or
Discontinuous mode of operation, the following analysis
will help to highlight the advantages of Continuous versus
Discontinuous mode of operation.
If we look at a single application and compare the results.
PO = 90 watts
Vin = 85−265 Vrms (analyzed at 85 Vrms input)
Preal Vrms Irms PF
A typical off−line converter will have a power factor of
0.5 to 0.6, which means that for a given circuit breaker rating
only 50% to 60% of the maximum power is available. If the
power factor is increased to unity, the maximum available
power can be obtained.
There is a similar situation in aircraft systems, where a
limited supply of power is available from the on−board
generators. Increasing the power factor will increase the
load on the aircraft without the need for a larger generator.
V
I
v, i
t
OFF−LINE CONVERTER
V
I
v, i
t
PFC CONVERTER
Figure 25. Voltage and Current Waveforms
Unity power factor is defined as the current waveform
being in phase with the voltage, and undistorted. Therefore,
there are two causes of power factor degradation – phase
shift and distortion. Phase shift is normally caused by
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NCP1651
Continuous Conduction Mode
A second result of running in DCM can be higher input
current distortion, EMI, and a lower Power Factor, in
comparison to CCM. While the higher peak current can be
filtered to produce the same performance result, it will
require a larger filter.
A simple Fast Fourier Transform (FFT) was run in Spice
to provide a comparison between the harmonic current
levels for CCM and DCM. The harmonic current levels will
affect the size of the input EMI filter which in some
applications are required to meet the levels of C.I.S.P.R. In
the SPICE FFT model we did not add any front end filtering
so the result of the analysis could be compared directly.
Efficiency = 80%
Pin = 108 W
VO = 48 Vdc
Freq = 100 kHz
Transformer turns ration N = 4
Continuous Mode (CCM)
To force the inductor current to be continuous over the
majority of the input voltage range (85−265 Vac), LP needs
to be at least 1 mH. Figure 26 shows the typical current
through the windings of the flyback transformer. During
switch on period, this current flows in the primary and
during the switch off time it flows in the secondary.
300
IPK
250
Iavg
(mA)
200
150
TIME
100
Figure 26.
The peak current is:
IPK = Iavg + ((1.414 ⋅ Vin sin ⋅ ton ⋅ 2)/LP)
where Iavg = 1.414 ⋅ Pin/Vin sin Ton = T/((NS/NP ⋅ 1.414 ⋅ Vin sin /VO) +1)
Ton = 6.19 s
IPK = (1.414 ⋅ 113)/85 sin + (1.414 ⋅ 85 ⋅ 6.15 s ⋅ 2) /1 mH
= 3.35 A
50
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8 2.0
FREQUENCY (MHz)
Figure 28. Continuous Conduction Mode
At the 100 kHz switching frequency, the rms value from
the FFT is 260 mA, and the 2nd harmonic (200 kHz) is
55 mA rms.
Discontinuous Mode (DCM)
In the discontinuous mode of operation, the inductor
current falls to zero prior to the end of the switching period
as shown in Figure 27.
2.8
2.4
2.0
IPK
(A)
1.6
Iavg
1.2
0.8
TIME
0.4
Figure 27.
0
To ensure DCM, LP needs to be reduced to approximately
100 H.
IPK = (Vin sin ⋅ 1.414 ⋅ ton)/LP
IPK = 1.414 ⋅ 85 sin 90 ⋅ 5.18 s/100 H = 6.23 A
The results show that the peak current for a flyback
converter operating in the Continuous Conduction Mode is
one half the peak current of a flyback converter operating in
the Discontinuous Conduction Mode.
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8 2.0
FREQUENCY (MHz)
Figure 29. Discontinuous Conduction Mode
At 100 kHz the rms value from the FFT are 2.8 A, and the
2nd harmonic (200 kHz) is 500 mA rms.
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NCP1651
Results
It is clear from the result of our analysis that a flyback PFC
converter operating in CCM has half the peak current and
one tenth the fundamental (100 kHz) harmonic current
compared to a flyback PFC converter operating in DCM.
The results are lower conduction losses in the MOSFET, and
secondary rectifying diode, and a smaller input EMI filter if
the designer needs to meet the requirements C.I.S.P.R.
conducted emission levels. On the down side to CCM
operation, the flyback transformer will be larger because of
the required higher primary inductance.
The advantages to operating in DCM include lower
switching losses because the current falls to zero prior to the
next switching cycle, and smaller transformer size.
It will ultimately be up to the designer to perform a
trade−off study to determine which topology, Boost versus
Flyback, Continuous versus Discontinuous Mode of
operation will meet all the system performance
requirements. But the recent introduction of the NCP1651
allows the system designer one additional option.
For an average current mode flyback topology based PFC
converter, determining the transformer parameters (primary
inductance and turns ratio) involves several trade−offs.
These include peak−to−average current ratio (higher
inductance or turns ratio result in lower peak current),
switching losses (higher turns ratio leads to higher peak
voltage and higher switching losses), CCM vs. DCM
operation (lower values of turns ratio or higher values of
inductance extend the CCM range) and range of duty cycles
over the operational line and load range. ON Semiconductor
has designed an Excel−based spreadsheet to help design
with the NCP1651 and balance these trade−offs. The design
aid is downloadable free−of−charge from our web−site
(www.onsemi.com).
The ideal solution depends on the specific application
requirements and the relative priority between factors such
as THD performance, cost, size and efficiency. The design
aid allows the designer to consider different scenarios and
settle on the best solution foe a given application. Following
guidelines will help in settling towards the most feasible
solution.
1. Turns Ratio Limitations: While higher turns ratio
can limit the reflected primary voltage and current,
it is constrained by the inherent limitations of the
flyback topology. A turns ratio of higher than 20:1
will result in very high leakage inductance and
lead to high leakage spikes on the primary switch.
Thus, practical application of this approach is
restricted to output voltages 12 V and above.
2. CCM Operation: The NCP1651 is designed to
operate in both CCM and DCM modes. However,
the CCM operation results in much better THD
than the DCM operation. Thus, it is recommended
that the circuit be designed to operate in CCM at
the specified test condition for harmonics
compliance (typically at 230 V, full load). Please
keep in mind that at or near zero crossing
(<10 deg angle), it is neither necessary nor feasible
to maintain CCM operation.
3. Following key governing equations have been
incorporated in the design aid:
PFC Operation
The basic PWM function of the NCP1651 is controlled by
a small block of circuitry, which comprises the DC
regulation loop and the PFC circuit. These components are
shown in Figure 30.
There are three inputs to this loop. They are the fullwave
rectified sinewave, the instantaneous input current and the
error signal at the FB/SD pin.
The input current is forced to maintain a near unity power
factor due to the control of the ac error amplifier. This
amplifier uses information from the ac input voltage and the
ac input current to control the power switch in a manner that
gives good DC regulation as well as excellent power factor.
The reference multiplier sets a reference level for the input
fullwave rectified sinewave. One of its inputs is connected
to a scaled down fullwave rectified sinewave, and the other
receives the error signal which has been converted to a
current. The error signal adjusts the level of the fullwave
rectified sinewave on the multiplier’s output without
distorting it. To accomplish this, it is necessary for the
bandwidth of the DC error amp to be less than twice the
lowest line frequency. Typically it is set at a factor of ten less
than the rectified frequency (e.g. for a 60 Hz input, the
bandwidth would be 12 Hz).
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15
Rectified Line
RDC1
6.5 V
Cout
20 A
4V
3.8 k
FB/SD
+
8
DRIVER
−
DRIVE
PWM
Logic
1
PWM
RDC2
Verror(ac)′
680
2
V−I
CONVERTER
AC INPUT
9
REFERENCE
MULTIPLIER
Vline
+
− .75
Vref
AC ERROR
AMP
+
−
.75 Vline +
k ⋅ Iin = Vref
Verror(ac)
+
V−I
AC REFERENCE
BUFFER
5
CURRENT
SENSE
AMPLIFIER
−
AVERAGE CURRENT
COMPENSATION
10
REF FILTER
IS+
NCP1651
16
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Figure 30. Simplified Block Diagram of Basic PFC Control Circuit
D5
NCP1651
The key to understanding how the input current is shaped
into a high quality sine wave is the operation of the ac error
amplifier. The inputs of an operational amplifier operating
in its linear range, must be equal. There are several
secondary effects, that create small differences between the
inverting and non−inverting inputs, but for the purpose of
this analysis they can be considered to be equal.
The fullwave rectified sinewave output of the reference
multiplier is fed into the non−inverting input of the ac error
amplifier. The inverting input to the ac error amplifier
receives a signal that is comprised of the input fullwave
rectified sinewave (which is not modified by the reference
multiplier), and summed with the filtered input current.
Since the two inputs to this amplifier will be at the same
potential, the complex signal at the non−inverting input will
have the same waveshape as the ac reference signal. The ac
reference signal (Vref) is a fullwave rectified sinewave, and
the ac input signal (Vline) is also a fullwave rectified
sinewave, therefore, the ac current signal (Iin), must also be
a fullwave rectified sinewave. This relationship gives the
formula:
AC Input
Vref
Vline
OSC
k ⋅ Iin
Vref
.75 ⋅ Vline + k ⋅ Iin
4 V ref
Verror(ac)
GND
Vref .75 Vref (k Iin)
4 V ref
Verror(ac)′
The Iin signal has a wide bandwidth, and its instantaneous
value will not follow the low frequency fullwave rectified
sinewave exactly, however, the output of the ac error
amplifier has a low frequency pole that allows the average
value of the .75 Vline + (k x Iin) to follow Vref. Since the ac
error amplifier is a transconductance amplifier, it is followed
by an inverting unity gain buffer stage with a low impedance
output so that the signal can be summed with the
instantaneous input switching current (Iin). The output of the
buffer is still Verror(ac).
Verror(ac)
GND
Figure 31. Typical Signals for PFC Circuit
The difference between Verror(ac) and the 4.0 volt
reference, sets the window that the instantaneous current
will modulate in, to determine when to turn the power switch
off.
The switch is turned on by the oscillator, which makes this
a fixed frequency controller. Under normal operation, the
switch will remain on until the instantaneous value of
Verror(ac)′ reaches the 4.0 volt reference level, at which time
the switch will turn off.
Since the input current has a fundamental frequency that
is twice that of the line, the output filter must have poles
lower than the input current to create a reasonable DC
waveform. The DC output voltage is compared to a
reference voltage by a secondary side error amplifier, and
the error signal out of the secondary side amplifier is fed
back into the Feedback input through an optocoupler.
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NCP1651
OPERATING DESCRIPTION
DC Reference and Buffer
The internal DC reference is a precision bandgap design
with a nominal output voltage of 4.0 volts. It is temperature
compensated, and trimmed for a 1% tolerance of its
nominal voltage, with an overall tolerance of 2%. To
assure maximum stability, this is only used as a reference so
there is minimal loading on this source.
The DC reference is fed into a buffer with a gain of 1.625
which creates a 6.5 volt supply. This is used as an internal
voltage to power many of the blocks inside of the NCP1651
and is also available for external use. The 6.5 volt reference
is designed to be terminated with at 0.1 F capacitor for
stability reasons.
There is no buffer between the internal and external 6.5
volt supply, so care should be used when connecting external
loads. A short or overload on this voltage output will inhibit
the operation of the chip.
INPUT A
V to I
CONVERTER
INPUT P
RAMP
+
−
Inverting Input
OUTPUT
NI Input
Undervoltage Lockout
An Undervoltage Lockout circuit (UVLO) is provided to
assure that the unit does not exhibit undesirable behavior at
low VCC levels. It also reduces power consumption to a level
that allows rapid charging of the VCC cap.
When the VCC cap is initially charging, the UVLO will
hold the unit off, and in a low bias current mode until the VCC
voltage reaches a nominal 10.8 volt level. At this point the
unit will begin operation, and the UVLO will no longer be
active. If the VCC voltage falls to a level that is 1.0 volts
below the turn−on point, the UVLO circuit will again
become active.
When in the active (shutdown) state, the UVLO circuit
removes power from all internal circuitry by shutting off the
6.5 volt supply. The 4.0 volt reference remains active, and
the UVLO and Shutdown comparators are also active.
Figure 32. Simplified Multiplier Schematic
The multiplier ramp is generated by the internal oscillator,
and is the same signal as is used in the PWM. It will therefore
have the same frequency as the power stage.
It is not necessary for Input P (into the PWM comparator)
to be a DC signal, low frequency ac signals (relative to the
ramp frequency) work well also.
The gain of the multiplier is determined by the
current−to−voltage ratio of the V−I converter, the load
resistor of the output filter and the peak and valley points of
the sawtooth ramp. When the P input signal is at the peak of
the ramp waveform, the comparator will allow the A input
signal to pass without chopping it at all. This gives an output
voltage of the A current multiplied by the output filter
resistance. When the P input signal is at the ramp valley
voltage, the comparator is held low and no current is passed
into the output filter. In between these two extremes, the duty
cycle (and therefore, the output signal) is proportional to the
level of the P input signal.
The output filter is a parallel RC network. The pole for this
network needs to be greater than twice the highest line
frequency (120 Hz for a 60 Hz line), and less than the
switching frequency. A recommended starting point is a
factor of 20 to 50 less than the switching frequency.
The pole is calculated by the formula:
Multiplier
The NCP1651 uses a new proprietary concept for its
Reference multiplier. This innovative design allows greatly
improved accuracy compared to a conventional linear
analog multiplier. The multiplier uses a PWM switching
circuit to create a scalable output signal, with a very well
defined gain.
One input (A) to the multiplier is a voltage−to−current
(V−I) converter. By converting the input voltage into a
current, an overall multiplier gain can be accomplished. In
addition, there will be no error in the output signal due to the
series rectifier.
The other signal (Input P) is input into the PWM
comparator. This selects a pulse width for the comparator
output. The current signal from the V−I converter is factored
by the duty cycle of the PWM comparator, and then filtered
by the RC network on the output. This network creates a low
pass filter, and removes the high frequency content from the
original waveform.
1
fo 2RC
So, for a 60 Hz line, and a 100 kHz switching frequency,
a 2.0 kHz pole is a good starting point. This would be a factor
of 50 below the switching frequency, and is still far enough
above the 120 Hz rectified line frequency that it won’t cause
undesirable distortion.
The reference multiplier contains an internal loading
resistor, with a nominal value of 25 ks. This is because the
resistor that converts the A input voltage into a current is
internal. Making both of these resistors internal, allows for
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NCP1651
Feedback/Shutdown
The FB/SD pin is a multiple function pin. Its primary
function is to port the error signal to the voltage−to−current
converter that feeds the reference multiplier. The operating
range for the feedback signal is from 1.0 to 4.0 volts. Below
an input level of 1.5 volts, the PWM duty cycle is reduced
to zero. At 4.0 volts the PWM is operating at its maximum
duty cycle.
The signal at this pin is also sensed by an internal
comparator that will shutdown the unit if the voltage falls
below 0.60 volts. Under normal operating conditions the
signal at this input will be 1.5 volts or greater, and the
shutdown circuit will be inactive. This circuit is designed
such that a 680 Ohm resistor in series with the optocoupler
will assure that the converter will go to zero duty cycle when
the opto is on full, but will not go low enough to put the unit
into its shutdown mode.
The shutdown function can be used for multiple purposes
including overvoltage, undervoltage or hot−swap control.
An external transistor, open collector or open drain gate,
connected to this pin can be used to pull it low, which will
inhibit the operation of the chip, and change the operating
state to a low power standby mode. An example of a
shutdown circuit is shown in Figure 23.
good accuracy and good temperature performance. Only a
capacitor needs to added externally to properly compensate
this multiplier. It is not recommended that an external
parallel resistor be used at the “Ref Gain” pin, due to
tolerance variations of the internal resistor.
There is an offset in the compensation (A−input) to the
reference multiplier. It is due to the V−I converter that feeds
the input.
The FB/SD signal is buffered by a voltage−to−current
converter for the appropriate signal into the multiplier. The
schematic for that converter follows.
CURRENT
MIRROR
i1
3.8 k
FB/SD
8
Vfb
6 X i1
imult
+
−
Reference Multiplier
20 k
1.5 V
Ramp Compensation
The Ramp Compensation pin allows the amount of ramp
compensation to be adjusted for optimum performance.
Ramp compensation is necessary in a current mode
converter to stabilize the units operation when the duty cycle
is greater than 50%.
The amount of compensation required is dependant on
several variables, including the boost inductor value, and the
desires of the designer. The value should be based on the
falling di/dt of the inductor current. For a boost inductor with
a variable input voltage, this will vary over the ac input
cycle, and with changes in the input line. A di/dt chart is
included in the design spreadsheet that is available for the
NCP1651.
For optimum load transient performance, the ramp
compensation should equal the falling di/dt at 100% duty
cycle. For optimum line transient response, it should equal
one half of the falling di/dt at 100% duty cycle.
This pin is a buffered output of the oscillator, which
provides a voltage equal to the ramp on the oscillator CT pin.
A resistor from this pin to ground, programs a current that
is transformed via a current mirror to the non−inverting
input of the PWM comparator.
The ramp voltage due to the inductor di/dt at the input to
the PWM comparator is the current shunt voltage at pin 5
multiplied by 10, which is the gain of the current amplifier
output that feeds the PWM.
Figure 33. Multiplier V−I Converter
The output current for this stage is:
imult 6 (Vfb 1.5 V)
20 k
Multiplier
1k
AC Ref
+
−
10
25 k
4.5 V
AC Error
Amplifier
Figure 34. Reference Multiplier Clamp Circuit
There is a 1 k resistor between the AC Ref pin and the AC
Error Amplifier for ESD protection. Due to this resistor, the
voltage on pin 10 (AC Ref) will exceed 4.5 volts under some
conditions, but the maximum voltage at the non−inverting
AC Error Amplifier input will be clamped at 4.5 volts.
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NCP1651
Current
Sense
Amp
i
AC Ref
Buffer
1.6i
+
−
16 k
Oscillator
Average Current Compensation
The input signal to this amplifier is the input fullwave
rectified sinewave. The amplifier is a unity gain amplifier,
with a voltage divider on the output that attenuates the signal
by a factor of 0.75. This scaled down fullwave rectified
sinewave is summed with the low frequency current signal
out of the current sense amplifier.
The sum of these signals must equal the signal at the
non−inverting input to the AC error amplifier, which is the
output of the reference multiplier. Since there is a hard limit
of 4.5 volts at the non−inverting input, the sum of the line
voltage plus the current cannot exceed this level.
A typical universal input design operates from 85 to 265
vac, which is a range of 3.1:1. The output of the Current
Compensation amplifier will change by this amount to allow
the maximum current to vary inversely to the line voltage.
PWM
Comparator
+
−
4
Ramp Compensation
RRC
Figure 35. Ramp Compensation Circuit
AC Error Amplifier
The ac error amplifier is a transconductance amplifier.
This amplifier forces a signal which is the sum of the current
and input voltage to equal the ac reference signal from the
reference multiplier.
Transconductance amplifiers differ from voltage
amplifiers in that the output is a high impedance with a
controlled voltage−to−current gain. This amplifier has a
nominal gain of 100 umhos (or 0.0001 amps/volt). This
means that an input voltage differential of 10 mv would
cause the output current to change by 1.0 A. Its maximum
output current is 30 A.
The current mirror is designed with a 1:1.6 current ratio.
The ramp signal injected can be calculated by the following
formula:
Vramp 1.6 Voscpk 16 k
RRC
102, 400
RRC
(eq. 1)
Where:
Vramp = Peak injected current signal (4 V)
RRC = Ramp compensation resistor (k)
Oscillator
The oscillator generates the sawtooth ramp signal that sets
the switching frequency, as well as sets the gain for the
multipliers. Both the frequency and the peak−to−peak
amplitude are important parameters.
The oscillator uses a current source for charging the
capacitor on the CT pin. The charge rate is approximately
200 A and is trimmed to maintain an accurate, repeatable
frequency. Discharge is accomplished by grounding the CT
pin with a saturated transistor. A hysteretic comparator
monitors that ramp signal and is used to switch between the
current source and discharge transistor. While the cap is
charging, the comparator has a reference voltage of 4.0
volts. When the ramp reaches that voltage, the comparator
switches from the charging circuit to the discharge circuit,
and its reference changes from 4.0 to 0.5 volts (overshoot
and delays will allow the valley voltage to reach 0 volts).
The relationship between the frequency and timing
capacitor is:
Current Sense Amplifier
The current sense amplifier is a wide bandwidth amplifier
with a differential input. It consists of a differential input
stage, a high frequency current mirror (PWM output) and a
low frequency current mirror (ac error amp output).
CURRENT
MIRROR
i1
3k
IS+
3k
i1
CURRENT
MIRROR
i1
30 k
6
LEB
i2
AC
Error
Amp
+
−
Iavg fltr
i2
PWM
7
Iavg
5
CT 47, 000f
Where CT is in pF and f is in kHz.
It is important not to load the capacitor on this pin, since
this could affect the accuracy of the frequency as well as that
of the multipliers which use the ramp signal. Any use of this
signal should incorporate a high impedance buffer.
Due to the required accuracy of the peak and valley ramp
voltages, the NCP1651 is not designed to be synchronized
to the frequency of another oscillator.
Figure 36. Current Sense Amplifier
The input to the current sense amplifier is a common base
configuration. The voltage developed across the current
shunt is sensed at the Is+ input. The amplifier input is
designed for positive going voltages only; the power stage
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NCP1651
PWM Logic
The PWM and logic circuits are comprised of a PWM
comparator, an RS flip−flop (latch) and an OR gate. The
latch is Set dominant which means that if both R and S are
high the S signal will dominate and Q will be high, which
will hold the power switch off.
The NCP1651 uses a voltage mode Pulse Width
Modulation scheme based on a fixed frequency oscillator.
The oscillator outputs a ramp waveform as well as a pulse
which is coincident with the falling edge of the ramp. The
pulse is fed into the PWM latch and OR gate that follows.
During the pulse, the latch is reset, and the output drive is in
its low state.
On the falling edge of the pulse, the output drive goes high
and the power switch begins conduction. The instantaneous
inductor current is summed with the ac error amplifier
voltage and the ramp compensation signal to create a
complex waveform that is compared to the 4.0 volt reference
signal on the inverting input to the PWM comparator. When
the signal at the non−inverting input to the PWM comparator
exceeds 4.0 volts, the output of the PWM comparator
changes to a high state which drives one of the Set inputs to
the latch and turns the power switch off until the next
oscillator cycle.
The OR gate that follows the PWM is used to inhibit the
drive signal to the power switch. In addition to the oscillator
pulse, this gate receives a signal from the shutdown OR gate,
which can inhibit operation due to an overtemperature
condition, shutdown signal, or insufficient VCC.
should resemble the configuration of the application circuit
in Figure 38.
Caution should be exercised when designing a filter
between the shunt resistor and this input, due to the low
impedance of this amplifier. Any series resistance due to a
filter, will create an offset of:
VOS 50 A Rexternal
which will add a positive offset to the current signal. The effect
of this is that the ac error amplifier will try to compensate for
the average output current which appears never to go to zero,
and cause additional zero crossing distortion.
The voltage across the current shunt resistor is converted
into a current (i1), which drives a current mirror. The output
of the i1 current mirror is a high frequency signal that is a
replica of the instantaneous current in the switch. The
conversion of the current sense signal to current i1 is:
i1 Vis3 k
The PWM output sends that information directly to the
PWM input where it is added to the ac error amp signal and
the ramp compensation signal.
The Leading Edge Blanking circuit (LEB) interrupts the
current signal to the PWM comparator for the first 200 ns of
the switching pulse. This blanks out any spike that might
occur at turn on, which could cause false triggering of the
PWM comparator.
The other output of the i1 mirror provides a voltage signal
to a buffer amplifier. This signal is the result of i1 dropped
across an internal 30 k resistor, and filtered by a capacitor
at pin 6. This signal, when properly filtered, will be the 2x
line frequency fullwave rectified sinewave. The filter pole
on pin 6 should be far enough below the switching frequency
to remove most of the high frequency component, but high
enough above the line frequency so as not to cause
significant distortion to the input fullwave rectified
sinewave waveform.
For a 100 kHz switching frequency and a 60 Hz line
frequency, a 10 kHz pole will normally work well. The
capacitor at pin 6 can be calculated knowing the desired pole
frequency by the equation:
C6 Driver
The output driver can be used to directly drive a FET, for
low and medium power applications, or a larger driver for
high power applications.
It is a complementary MOS, totem pole design, and is
capable of sourcing and sinking over 1.5 amps, with typical
rise and fall times of 50 ns with a 1.0 nF load. The totem pole
output has been optimized to minimize cross conduction
current during high speed operation.
Additional internal circuitry has been added to keep the
Driver in its low state whenever the Undervoltage Lockout
is active. This characteristic eliminates the need for an
external gate pull−down resistor.
1
2 f30k
Where:
C6 = Pin 6 capacitance (nF)
f = pole frequency (kHz)
Shutdown Modes and Logic
Overtemperature A temperature sensor and reference is
provided to monitor the junction temperature of the chip.
The chip will operate to a nominal temperature of 160°C at
which time the output of the temperature sensor will change
to a low state. This will set the output of the shutdown
NAND gate high, which in turn will set the output of the
PWM OR gate high, and force the driver into a low state.
There is a hysteresis of 30°C on this circuit, which will allow
the chip to cool down to 130°C before resuming operation.
or, for a 10 kHz pole, C6 would be 0.5 nF.
The gain of the low frequency current buffer is set by the
value of the resistor at pin 7. The value of R7 determines the
scale factor between the peak current and the average
current. The average current will be that of the primary
waveform only, since the secondary current will not conduct
across the shunt resistor.
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NCP1651
While in the overtemperature shutdown mode, the
start−up circuit will be operational and the VCC will cycle
between 10.8 and 9.8 volts.
Insufficient VCC If the level of the VCC voltage is not
sufficient to maintain operation, the drive of the chip will be
inhibited and the divide−by−eight timer will be invoked.
This will normally occur when the output is overloaded.
Under this condition, the divide−by−eight counter will count
for 8 VCC cycles. At the end of the eighth cycle the driver
will be enabled and the circuit will attempt to start. If the
failure has been corrected, the output will come up and the
circuit will resume normal operation. If not, another cycle
will begin. The waveforms for overload timeout are shown
in Figure 3.
Shutdown The NCP1651 has a shutdown circuit that
can be used to inhibit the operation of the chip by reducing
the FB/SD pin voltage to less than 0.6 volts. When a
shutdown signal is issued, the output of the shutdown
comparator goes low. This immediately ceases the operation
of the unit by OR’ing that signal to the output of the PWM
logic, and holding the driver in its low state.
The inverted output of the shutdown comparator is fed in
to the reset pin of the divide−by−eight counter. The counter
reset pin sets its count to seven. As long as the reset pin is
low, the counter will remain at seven. When the shutdown
signal is removed, the reset pin will go high, and the counter
will continue to count to eight. The counter is triggered on
the negative edge of the start−up enable signal. This means
that a shutdown signal that is removed on the upward VCC
slope will be in the 7 count for the remaining rise and fall of
that VCC cycle and will change to 8 on the next cycle.
This system assures that the unit will not be enabled until
the VCC voltage has a full discharge cycle available, and it
also insures that the unit will commence operation in less
than two VCC cycles. A timing diagram of this mode of
operation is shown in Figure 3. The count for the
divide−by–eight counter is shown as 7, 7, 7, 8 which
illustrates the operation of the reset function.
If the shutdown signal is terminated before the VCC voltage
reaches the lower UVLO limit (i.e. 9.8 volts), the unit will
resume operation on the following VCC down slope, and if the
shutdown signal is terminated on the VCC upward slope, the
unit will resume operation on the second VCC down slope.
CURRENT
MIRROR
2.9 V
AC
Comp
3
AC
ERROR
AMP
+
−
i1
i1
16 k
+
−
6.7 k
PWM,
Ramp
Comp
Current
Sense
Amp
Unity Gain Amplifier
Figure 37. AC Reference Buffer Schematic
The buffer’s transfer function is:
iout (2.9 V Vac(ea))6.7 k
The buffer amplifier, converts the input voltage to a
current by creating a current equal to the voltage difference
between the ac error amplifier output and the 2.9 volt
reference dropped across the 6.7 k resistor. The bipolar
transistor level shifts the voltage and maintains the proper
current into the current mirror. The current mirror has a 1:1
ratio and delivers its output current to the PWM input. This
current is summed with the currents of the ramp
compensation signal and the instantaneous current signal to
determine the turn−off point in the switching cycle.
Start−Up Circuit
The start−up circuit serves several functions. In addition
to providing the initial charge on the VCC capacitor, it serves
as a timer for the start−up, overcurrent, and shutdown modes
of operation. Due to the nature of this circuit, this chip must
be biased using the start−up circuit and an auxiliary winding
on the power transformer. Attempting to operate this chip
off of a fixed voltage supply will cause the chip to latch up
in some modes of operation.
A high voltage FET is biased as a current source to provide
current for start−up power. On the application of input voltage,
the high voltage start−up circuit is enabled and current is drawn
from the rectified ac line to charge the VCC cap.
When the voltage on the VCC cap reaches the turn on point
for the UVLO circuit (10.8 volts typical), the start−up circuit
is disabled, and the PWM circuit is enabled. With the
NCP1651 enabled, the bias current increases from its
standby level to the operational level. The divide−by−eight
counter is preset to the count of 7, so that on start−up the chip
will not be operational on the first cycle. The second VCC
cycle will be number 8, and the chip will be allowed to start
AC Reference Buffer
The ac reference buffer converts the voltage generated by
the ac error amplifier to be converted into a current to be
summed with the ramp compensation signal and the
instantaneous current signal.
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NCP1651
Soft−Start Circuit
The ac error amplifier has been configured such that a low
output level will cause the output duty cycle to go to zero.
This will have the effect of soft−starting the unit at turn−on,
since the output is coupled to ground through a capacitor.
There will be an initial offset of the output voltage due to
the output current and the resistor at pin 11. For example, if
the output is saturated in the high state at turn on, it will
source 50 A. If pin 11 is terminated with a 2.2 k resistor
and a 0.01 F capacitor, the initial step will be:
at this time. In the shutdown mode, the VCC cycle is held in
the 7 count state until the shutdown signal is removed. This
allows for a repeatable, fast restart. See Figure 3 for timing
diagram.
The unit will remain operational as long as the VCC
voltage remains above the UVLO undervoltage trip point. If
the VCC voltage is reduced to the undervoltage trip point,
operation of the unit will be disabled, the start−up circuit will
again be enabled, and will charge the VCC cap up to the turn
on voltage level. At this point the start−up circuit will turn
off and the unit will remain in the shutdown mode. This will
continue for the next seven cycles. On the eighth cycle, the
NPC1651 will again become operational. If the VCC voltage
remains above the undervoltage trip point the unit will
continue to operate, if not the unit will begin another
divide−by−eight cycle.
The purpose of the divide−by−eight counter is to reduce
the power dissipation of the chip under overload conditions
and allow it to recycle indefinitely without overheating the
chip.
It is critical that the output voltage reaches a level that allows
the auxiliary voltage to remain above the UVLO turn−off level
before the VCC cap has discharged to that level. If the bias
voltage generated by the inductor winding fails to exceed the
shutdown voltage before the capacitor reduces to the UVLO
undervoltage turn−off level, the unit will shut down and go into
a divide−by−eight cycle, and will never start. If this occurs, the
VCC capacitor value should be increased.
50 A 2.2 k 0.11 volts
and the rate of rise will be:
50 A0.01 F 5 mVs
or, 560 s until the output is at 2.8 volts, which corresponds
to full duty cycle.
There is also a clamp on pin 8 that will keep the
capacitance on that pin discharged to 1.5 volts so that the
FB/SD signal will also slew up from a low power level to a
high power level. When the unit is in standby mode, the
clamp will be enabled. At the same time as the unit is
enabled, the clamp will be disabled to allow the feedback
signal to control the loop.
An external soft−start circuit can be added, as shown in
Figure 24, if additional time is desired.
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Vin
680
24
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C4
Figure 38. Typical Application Schematic
2
GND
C3
R3
11
AC COMP
10
9
AC REF
AC INPUT
8
FB/SD
1 F
Rac1
Cin
20 A
25 k
20 k
4.5 V
60 k
AVERAGE CURRENT
COMPENSATION
+
−
p
a
REFERENCE
MULTIPLIER
V−I
CONVERTER
0.022 F
3.8 k
6.5 V
−
+
RAMP
COMP
4
−
+
R13
16 k
V−I
3
Ctiming
CT
OSCILLATOR
RAMP
COMPENSATION
0.75 Vline +
k ⋅ Iin = Vref
AC ERROR AMP
AC
REFERENCE
BUFFER
4V
−
+
LEB
PWM
R
S
4V
Q
R10
Iavg
7
6
CURRENT
SENSE
AMPLIFIER
SET
DOMINANT
÷ 8 COUNTER
UVLO
REFERENCE
REGULATOR
SHUTDOWN
VCC 13
OVERTEMPERATURE
SENSOR
0.6 V
STARTUP 16
C12
Iavg fltr
−
+
DRIVER
6.5 V
5
L1
Rshunt
IS+
1
OUT
Vref
12
Q1
Cref
Cout
0.47 F
2
5.23 k
422
453
9.31 k
4.7 k
MC3303
5.23 k
4.02 k
OVERVOLTAGE
COMPARATOR
−
+
ERROR
AMPLIFIER
−
+
UNDERVOLTAGE
COMPARATOR
+
−
0.01 F
TL431
7.5 k
NOTE: This is a theoretical design, and it is
not implied that a circuit designed by this
procedure will operate properly without
normal troubleshooting and adjustments as
are common with any power conversion
circuit. ON Semiconductor provides a
spread sheet that incorporates the relevant
equations, and will calculate the bias
components for a circuit using the
schematic shown.
Cac
Rac2
D4
D3
D2
D1
Rtn
12 V
NCP1651
DESIGN GUIDELINES
NCP1651
Basic Specifications
The design of any power converter begins with a basic set
of specifications. The following parameters should be
known before you begin:
Pomax
(Maximum rated output power)
Vrmsmin (Minimum operational line voltage)
Vrmsmax (Maximum operational line voltage)
fswitch
(Nominal switching frequency)
Vout
(Nominal regulated output voltage)
Most of these parameters will be dictated by system
requirements.
Using the available spreadsheet, with the following
parameters, a primary inductance of 330 H and a turns ratio
of 10:1 would be a good choice.
Limits
Pomax = 100 W
Vinmax = 265 Vrms
Vinmin = 85 Vrms
VO = 12 V
LP = 330 H
fswitch = 100 kHz
Np/Ns = 10
Transformer
For an average current mode, fixed frequency PFC
converter, there is no magic formula to determine the
optimum value of the transformer’s primary inductance.
There are several trade−offs that should be considered.
These include peak current vs. average current, switching
losses vs. core losses and range of duty cycles over the
operational line and load range. All of these are a function
of inductance, line and load. These parameters determine
when the converter is operating in the continuous
conduction mode and when it is operating in the
discontinuous conduction mode.
If you are designing your own transformer, the
ON Semiconductor spreadsheet (NCP1651_Design.xls)
that is available as a design aid for this part can be of help.
Enter various values of inductance as well as the turns ratio
and observe the variation in duty cycle and peak current vs.
average current.
The transformer’s duty cycle is an important parameter.
There are two main limitations for the duty cycle. The first
is the output voltage reflected back to the primary, which is
scaled by the turns ratio. This means that with a 10:1
(pri:sec) turns ratio, and a 12 volt output, the power switch
will see the input voltage plus 120 volts (10 x 12 volts) plus
leakage inductance spike. This reflected voltage determines
the maximum voltage rating of the power switch.
The second, there are practical limits to the turns ratio.
Given the flyback converter transfer function, continuous
conduction mode,
6
PEAK CURRENT
CURRENT (A)
5
4
PEDESTAL
CURRENT
3
2
1
0
0
45
90
PHASE ANGLE (°)
135
180
Figure 39. Switching Current versus Phase Angle
100
DUTY CYCLE (%)
100% = Discontinuous
50% = Continuous
75
50
MODE
25
VO Vin n (D1 D)
DUTY CYCLE
0
It is evident that there is a direct relationship between duty
cycle and the turns ratio. In general, 10:1 is about the
maximum, although some transformer manufacturers go as
high as 12:1 or even 15:1. Turns ratios of 20:1 and above are
not normally practical as they result in very high values of
leakage inductance, which creates large spikes on the power
switch. They also have a very large reflectovoltage
associated with them.
The other option is to contact a transformer manufacturer
such as Coiltronics (www.cooperet.com/) or Coilcraft
(www.coilcraft.com/). These companies will design and
manufacture transformers to your requirements.
0
45
90
DEGREES (°)
135
180
Figure 40. Continuous/Discontinuous and Duty Cycle
If an auxiliary winding is desired to provide a bias supply,
it should provide a minimum of 12.1 volts (to exceed the
UVLO spec) and a maximum of 18 volts. The auxiliary
winding should be connected such that it conducts when the
power switch is off. Near the zero crossings of the line
frequency, the voltage will have a peak voltage equal to the
regulated output voltage divided by the turns ratio. The filter
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NCP1651
cap on the VCC pin needs to be of sufficient size to hold the
voltage up over between the zero crossings.
12 V
9.31 k
Rout
Error Amplifier
The error amplifier resides on the secondary side of the
circuit, and therefore is not part of the chip. A minimal
solution would include either a discrete amplifier and
reference, or an integrated circuit that combines both, such
as the TL431 series of regulators.
453
+
−
Undervoltage
Capacitor
422
−
+
Error Amplifier
Cout
Vout
FB/SD
−
+
Ropto
5.23 k
Rdc1
Vref2
Cfb
Rdc2
−
+
7.5 k
Rbias
Overvoltage
Comparator
5.23 k
V′
Ropto
MC3303
4.02 k
Rfb
3.6 k
0.01 F
TL431
Rtn
Error
Amp
Figure 42. Error Amp with Over/Undershoot
Protection
Figure 41. Error Amplifier Circuit
The configuration shown in Figure 42, incorporates an
error amplifier with slow loop response, plus overvoltage
and undervoltage comparators. Under normal operation the
outputs of the Undervoltage and Overvoltage Comparators
are high. The Undervoltage Comparator provides drive for
the optocoupler, while the Overvoltage Comparator reverse
biases the diode on its output and is out of the loop.
This circuit is designed with 8% trip points both above and
below the regulation limit. If an overvoltage condition
exists, the Overvoltage comparator will respond very
quickly. When its output goes low, it will provide maximum
drive to the optocoupler, which will shut off the output of the
converter.
If the output voltage drops 8% or more below its regulated
level, the Undervoltage Comparator will go low. This will
remove the drive from the optocoupler, which will allow the
regulator to increase the duty cycle and return the output to
its regulation range much faster than the error amplifier
could.
This configuration will work over a range of 5 to 30 volts,
with the appropriate changes in Rout, Rbias and Ropto.
Rout (k) = (Vout − 4.753) / 0.7785
Rbias (k) = (Vout − 4.4)
Ropto (k) = (Vout − 3) / 2
The value for Ropto will allow a maximum of 2 mA to
drive the optocoupler. If additional current is needed, change
the 2 in the denominator of that equation to the current
(in mA) that is desired.
This configuration for the error amplifier will result in a
low cost regulator, however, due to the slow loop response
of a PFC regulator it will not protect against overvoltage
conditions (e.g. load removal) or droop when a transient
load is added.
The primary side circuit has been designed such that the
PFC controller will operate at maximum duty cycle with the
optocouple in a non−conducting state. This is necessary to
allow the unit to bring up the output when the system is
initially energized. At this time there is not output voltage
available to drive the LED in the optocoupler.
In the circuit of Figure 41, the amplifier and reference
need to be rated at the maximum voltage that the output will
experience, including transient conditions. Resistors Rdc1
and Rdc2 need to be chosen such that the voltage at V′ is
equal to Vref2 when Vout is at its regulated voltage. Ropto is
a current limiting resistor that protects the optocoupler from
current transients due to output surges.
This design also includes inherent compensation from
transients. Since the bandwidth of the error amplifier is very
low, its output can not respond rapidly to changes in the
output voltage. A transient change in the output voltage will
change the current through Ropto. Since the output of the
error amplifier does not change immediately, if the output
voltage increases, the voltage across Ropto will increase.
This drives more current through the optocoupler, which in
turn reduces the output of the converter.
An alternate regulator is recommended, which is only
slightly more expensive, and offers excellent protection
from positive transients, and quick recovery from negative
transients.
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NCP1651
Ac Voltage Divider
The voltage divider from the input rectifiers to ground is
a simple but important calculation. For this calculation it is
necessary to know the maximum line that the unit can
operate at. The peak input voltage will be:
Vinpeak = 1.414 x Vrmsmax
The maximum voltage at the ac input (pin 5) is 3.75 volts
(this is true for both multipliers).
If the maximum line voltage is 265 Vac, the peak input
voltage is:
Vinpeak = 1.414 x 265 Vrms = 375 Vpk
To keep the power dissipation reasonable for a 1/2 watt
resistor (Rac1), it should dissipate no more than 1/4 watt. The
power in this resistor is:
PRac1 = (375 V − 3.75 V)2 / Rac1 = 0.25 watts
so: Rac1 = 551 k
To minimize dissipation, use the next largest standard value,
or 560 k.
Typically, two 1/4 resistors are used in series to handle the
power.
Then, Rac2 = 3.75 V / ((375 V − 3.75 V) / 560 k) = 5.6 k
di/dt primary = di/dt secondary
Vin/LP ⋅ T/2 = VO/LP ⋅ NP/NS ⋅ T/2
Vin/LP = VO/LP ⋅ NP/NS
Equation 2)
For proper slope compensation, the relationship between
RS and RRC is:
di/dt (primary) ⋅ T ⋅ RS ⋅ High Frequency Current Gain =
VRcomp
VO/LP ⋅ T ⋅ NP/NS ⋅ RS ⋅ 16 k/3 k = 102.4 k/RRC
RS = (19,200/RRC ⋅ T) ⋅ (LP/VO) ⋅ (NS/NP)
Equation 3)
ton = T/(NS/NP ⋅ (√2 ⋅ VLL/VO)) + 1
For maximum output current, when the error amplifier is
saturated in a low state, the ramp compensation signal plus
the current signal must equal 4.0 volts (3.8 volts is used to
avoid over driving the amplifier), which is the reference
level for the PWM comparator. So:
Equation 4) VrefPWM = VinST + VRcomp
3.8 V = IPK ⋅ RS ⋅ 16 k/3 k + 102.4 k/RRC ⋅ ton/T
RRC Current Sense Resistor/Ramp Compensation
The combination of the voltage developed across the
current sense resistor and ramp compensation signal, will
determine the peak instantaneous current that the power
switch will be allowed to conduct before it is turned off.
The vector sum of the three signals that combine to create
the signal at the non−inverting input to the PWM comparator
must add up to 4.0 volts in order to terminate the switch
cycle. These signals are the error signal from the ac error
amp, the ramp compensation signal, and the instantaneous
current. For a worst case condition, the output of the ac error
amp could be zero (current), which would require that the
sum of the ramp compensation signal and current signal be
4.0 volts. This must be evaluated under full load and low line
conditions.
For proper ramp compensation, the ramp signal should
match the falling di/dt (which has been converted to a dv/dt)
of the inductor at 50% duty cycle. 50% duty cycle will occur
when the input voltage is 50% of the output voltage. Both the
falling di/dt and output voltage need to be reflected by the
transformer turns ratio to the primary side. Thus the
following equations for RS and RRC must be satisfied:
di/dt primary = Vin/LP ⋅ T/2
di/dt secondary = VO/LS ⋅ T/2
NS
LS NP
Combining equations 2 and 4 gives:
RS N
Where:
RS is the current shunt resistor (Ohms)
RRC is the ramp compensation resistor (Ohms)
ton is the on time for the conditions given (s)
T is the period for the switching frequency (s)
LP is the primary inductance of the transformer (H)
Vout is the output voltage (VDC)
Vrms is the rms line voltage at low line (Vrms)
Pout is the output power at full load (watts)
Iavg (T) is the average current for one switching cycle (A)
Ipk is the instantaneous peak primary side current (A)
V(t) is the peak line voltage (volts)
NP/NS is the transformer turns ratio (dimensionless)
Current Scaling Resistor & Filter Capacitor
R7 sets the gain of the averaged current signal out of the
current sense amplifier which is fed into the ac error
amplifier. R7 is used to scale the current to the appropriate
level for protection purposes in the ac error amplifier circuit.
R7 should be calculated to limit the maximum current
signal at the input to the ac error amplifier to less than
4.5 volts at low line and full load. 4.5 volts is the clamp
voltage at the output of the reference amplifier and limits the
maximum averaged current that the unit can process. The
equation for R7 is:
2
2
3.8
5.33 Ipk
P tonVO
NS 0.1875 LP
LP
di/dt reflected to the primary:
VLOP NNPS
102.4 k ton
(3.8 5.3 IPK RS)
N
T S
2 NP
R7 Simplifies to:
VO/LP ⋅ NP/NS ⋅ T/2
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212 k RS Pin
VinLL 4.5 (0.75 ACratio VinLL 2 )
NCP1651
To determine the values of R3 and C3, it is necessary to
look at the two signals that reach the PWM inputs. The
non−inverting input is a slow loop using the averaged
current signal. It’s gain is:
Where: Pin = rated input power (W)
Where: RS = Shunt resistance (W)
Where: VinLL = min. operating rms input voltage (W)
Where: ACratio = ac attenuation factor at pin 9
This equation does not allow for tolerances, and it would
be advisable to increase the input power to assure operation
at maximum power over production tolerance variations.
The current sense filter capacitor should be selected to set
its pole about a factor of 10 below the switching frequency.
AIf 30 k 15 k (gm R11) 2.3
3k
R7
Where the first two terms are the gains in the current sense
amplifier averaging circuit. The next term is the gain of the
transconductance amplifier and the constant is the gain of
the ac Reference Buffer.
The high frequency path is that of the instantaneous
current signal to the PWM non−inverting input. This gain is
16 k/3 k = 5.33, since the input signal is converted to a
current through a 3 k resistor in the current sense amplifier,
and then terminated by the 16 k resistor at the PWM input.
For stability, the gain of the low frequency path must be
less than the gain of the high frequency path. This can be
written as:
C6 5.3
f
Where: C6 = Pin 6 capacitance (nF)
Where: f = pole frequency (kHz)
so, for a 100 kHz switching frequency, a 10 kHz pole is
desirable, and C6 would be 0.5 nF.
Reference Multiplier
The output of the reference multiplier is a pulse width
modulated representation of the analog input. The multiplier
is internally loaded with a resistor to ground which will set
the DC gain. An external capacitor is required to filter the
signal back into one that resembles the input fullwave
rectified sinewave. The pole for this circuit should be greater
than the line frequency and lower than the switching
frequency.
1/15th of the switching frequency is a recommended
starting value for a 60 Hz line frequency. The filter capacitor
for pin 10 can be determined by the following equation:
C10 345, 000 gm R11
R7
5.3
The suggested resistor and capacitor values are:
R11 R7
130,000 gm
and for a zero at 1/10th of the switching frequency
C11 Where:
Where:
Where:
Where:
1
6.366E−6
fpole
2 3.14 25 k fpole
Where: C10 = Pin 10 capacitance (F)
Where: fpole = Ref gain pole freq (Hz)
AC Error Amplifier
The ac error amplifier is a transconductance amplifier that
is terminated with a series RC impedance. This creates a
pole−zero pair.
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1.59
fSW R11
R7 & R11 are in units of Ohms
gm is in units of mhos
C11 is in Farads
fsw is in Hz
NCP1651
Loop Compensation
Vline
Rdc1
Ropto
Np : Ns
Rac1
Vac
6.5 V
Vo
Rac2
3.8 k
Vfb FB/SD
8
Vref
REFERENCE
MULTIPLIER
C
AC
ERROR
AMP
−
+
Q1
4V
−
+
RL
OUT
LOGIC
1
PWM
25 k
5
C.S. Amp
Rfb
V′
Vref2
Vea
−
+
Rdc2
Iin
IS+
Cfb
C8
ERROR
AMP
DIVIDER
Rdc2
V
Rdc1 Rdc2
Vo
Ref Fltr
10
Iavg
7
RS
0.022 F
C10
ERROR AMP
fz 1
2 Cfb Rfb
R7
OPTO TRANSFER
REFERENCE SIGNAL
Vfb
3.8 k CTR
Vea
Ropto
Vref
2.66 Vac
Vfb
MODULATOR AND OUTPUT STAGE
Iin
R7
Vref RS 75, 000
Np
Vout
T ton
RL
ton
Ns
Iin
for f > fz:
Av RfbRdc1
Vac Vline Rac2
Rac1 Rac2
fp 1
2 RL C
for f < fz:
Av 1
2 f Cfb Rdc1
Figure 43. Voltage Regulation Loop
Loop Model
The model for the voltage loop has been broken down into
six sections. The voltage divider, error amplifier, and opto
Transfer are external to the chip, and the reference signal,
modulator and output stage are internal.
The modulator and output stage circuitry is greatly
simplified based on the assumption that that poles and zeros
in the current feedback loop are considerably greater than
the bandwidth of the overall loop. This should be a good
assumption, because a bandwidth in the kilohertz is
necessary for a good current waveform, and the voltage error
amplifier needs to have a bandwidth of less than the lowest
line frequency that will be used.
There are two poles in this circuit. The output filter has a
pole that varies with the load. The pole on the voltage error
amplifier will be determined by this analysis.
Voltage Error Amplifier
The voltage error amplifier is constrained by the two
equations. When this amplifier is compensated with a
pole−zero pair, there will be a unity gain pole which will be
cancelled by the zero at frequency fz. The corresponding
bode plot would be:
GAIN (dB)
20
Unity Gain
0
AV
fz
−20
Voltage Divider
The voltage divider is located on the secondary side
circuitry. It is a simple resistive divider that reduces the
output voltage to the level required by the internal reference
on the voltage error amplifier. If the amplifier circuit of
Figure 42 is used, there are four resistors instead of 2. To
determine the gain of this circuit, Rdc1 is the equivalent of
the upper two resistors, 9.31 k and 453 Ohms respectively,
and Rdc2 is the equivalent of the lower two resistors, 422 and
5.23 k respectively.
f, FREQUENCY
Figure 44. Pole−zero Bode Plot
The gain at frequencies greater than fz is determined by
Rfb. Once Rfb is determined, the value of Cfb can be easily
calculated using the formula for fz.
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NCP1651
Optocoupler Transfer
The optocoupler is used to allow for galvanic isolation for
the error signal from the secondary to primary side circuits.
The gain is based on the Current Transfer Ratio of the
device. This can change over temperature and time, but will
not result in a large change in dB.
The recommended capacitor at pin 8 is 0.022 F. If a larger
capacitor is used, the pole may become low enough that it
will have an effect on the gain phase plots near the unity gain
crossover frequency. In this case and additional zero will be
required in the error amplifier bias circuitry.
A(dB) = 20 Log10 (A)
For example, the voltage divider would be:
A
A(dB) = 20 Log10 0.0099 = −40 dB
The gain of the loop will vary as the input voltage changes.
It is recommended that the compensation for the error
amplifier be calculated under high line, full load conditions.
This should be the greatest bandwidth that the unit will see.
By necessity, the unity gain (0 dB) loop bandwidth for a
PFC unit, must be less than the line frequency. If the
bandwidth approaches or exceeds the line frequency, the
voltage error amplifier signal will have frequency
components in its output that are greater than the line
frequency. These components will cause distortion in the
output of the reference amplifier, which is used to shape the
current waveform. This in turn will cause distortion in the
current and reduce the power factor.
Typically the maximum bandwidth for a 60 Hz PFC
converter is 10 Hz, and slightly less for a 50 Hz system. This
can be adjusted to meet the particular requirements of a system.
The unity gain bandwidth is determined by the frequency at
which the loop gain passes through the 0 dB level.
For stability purposes, the gain should pass through 0 dB
with a slope of −20 dB for approximately on decade on either
side of the unity gain frequency. This assures a phase margin
of greater than 45°.
The gain can be calculated graphically using the equations
of Figure 18 as follows:
Divider: Calculate V′/Vo in dB, this value is constant so it
will not change with frequency.
Optocoupler Transfer: Calculate Vfb/Vea using the equation
provided. Convert this value into dB.
Reference Signal: Calculate Vref/Vfb using the peak level of
the ac input signal at high line that will be seen on pin 9.
Convert this to dB. This is also a constant value.
Modulator and Output Stage: Calculate the gain in dB for
DIo/DVref for the modulator, and also the gain in dB for the
output stage (DVout/DIin). Calculate the pole frequency. The
gain will be constant for all frequencies less than fp. Starting
at the pole frequency, this gain will drop off at a rate of
20 dB/decade.
Plot the sum of all of the calculated values. Be sure to
include the output pole. It should resemble the plot of
Figure 45. This plot shows a gain of 34 dB until the pole of
the output filter is reached at 3 Hz. After that, the gain is
reduced at a rate of 20 dB/decade.
Reference Signal
The error signal is transmitted to the primary side circuit
via. the optocoupler, is converted to a current by the V−I
converter and is then used as an input to the reference
multiplier. The gain of this block is dependent on the ac input
voltage, because of the multiplier which requires two inputs
for one output.
Modulator and Output Stage
The modulator receives an input from the reference
multiplier and forces the current to follow the shape and
amplitude. The is an internal loop within this section due to
the current sense amplifier. Based on the assumptions listed
in the introduction to this analysis, this is not analyzed
separately.
The equation for the gain is good for frequencies below
the pole. There is a single pole due to the output filter. Since
the NCP1651 is a current mode converter, the inductor is not
part of the output pole as can be seen in that equation.
The modulator and output stage transfer functions have
been split into two sets of equations. The first defines the
relationship between the input current and ac reference
signal, and the later, define the output stage gain and pole.
Due to the nature of a flyback transformer, the gain of the
output stage is dependant on the duty cycle (ton/T). For
continuous mode operation, the on−time is:
ton N
S
NP
T
2Vrms
Vout
5.6 k
0.0099
560 k 5.6 k
1
Calculating the Loop Gain
At this point in the design process, all of the parameters
involved in this calculation have been determined with the
exception of the pole−zero pair on the output of the voltage
error amplifier.
All equations give gains in absolute numbers. It is
necessary to convert these to the decibel format using the
following formula:
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30
NCP1651
cut in half or more and probably remain stable. This can be
tested in the circuit, or simulated with a model in SPICE or
a similar analysis program.
The gain and phase plots of the completed loop are shown
in Figures 46 and 47. These include the effects of all of the
stages shown.
40
35
30
GAIN (dB)
25
20
15
80
10
5
60
0
−5
40
0.01
0.1
10
1
FREQUENCY (Hz)
100
GAIN (dB)
−10
−15
1000
Figure 45. Forward Gain Plot
0
For a crossover frequency of 10 Hz, the error amplifier
needs a gain of −25 dB at 10 Hz, since the forward gain is
equal to 25 dB at this frequency. The high frequency gain of
the error amplifier is:
AVhf = Rfb / Rdc1
Where Rdc1 is the output voltage divider resistor that is
connected from the output of the converter to the input of the
error amplifier. If the output circuit of Figure 42 is used, Rdc1
would be 9.31 k + 453 , or 9.76 k. A gain of −25 dB is
equal to a divider ratio of:
AV = 10(−25/20) = 0.056
so, Rfb / Rdc1 = 0.056
or, Rfb = 0.056 x 9.76 k = 546 The closest standard value resistor is 560 .
To offset the 2 Hz pole of the output filter, the error
amplifier should have a zero of 2 Hz or slightly higher. For
a 2 Hz zero, the compensation capacitor, Cfb can be
calculated by:
Cfb 20
−20
−40
0.01
0.1
1
10
FREQUENCY (Hz)
100
1000
Figure 46. Loop Gain Plot
−75
−90
PHASE (°C)
−105
−120
−135
−150
−165
1
95 F
2 Rfb 3 Hz
−180
100 F is the closest standard value capacitor and would
be a good choice. This solution will provide a phase margin
of close to 90°. In practice the value of capacitance could be
0.01
0.1
10
1
FREQUENCY (Hz)
Figure 47. Loop Phase Plot
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31
100
1000
NCP1651
PACKAGE DIMENSIONS
SO−16
D SUFFIX
CASE 751B−05
ISSUE J
−A−
16
9
1
8
−B−
P
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSIONS A AND B DO NOT INCLUDE
MOLD PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)
PER SIDE.
5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.127 (0.005) TOTAL
IN EXCESS OF THE D DIMENSION AT
MAXIMUM MATERIAL CONDITION.
8 PL
0.25 (0.010)
B
M
S
G
R
K
DIM
A
B
C
D
F
G
J
K
M
P
R
F
X 45 C
−T−
SEATING
PLANE
J
M
D
16 PL
0.25 (0.010)
T B
M
S
A
S
FOOTPRINT FOR SOLDERING
0.275
7.0
0.024
0.6
INCHES
MIN
MAX
0.386
0.393
0.150
0.157
0.054
0.068
0.014
0.019
0.016
0.049
0.050 BSC
0.008
0.009
0.004
0.009
0
7
0.229
0.244
0.010
0.019
0.060
1.52
0.155
4.0
SO−16
MILLIMETERS
MIN
MAX
9.80
10.00
3.80
4.00
1.35
1.75
0.35
0.49
0.40
1.25
1.27 BSC
0.19
0.25
0.10
0.25
0
7
5.80
6.20
0.25
0.50
inches
mm
0.050
1.270
The product described herein (NCP1651), may be covered by U.S. patents including 6,373,734. Other patents may be pending.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
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NCP1651/D