FAIRCHILD AN-400A

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AN-400A
Low-Power Green-Mode PWM Flyback Power Controller
without Secondary Feedback
Abstract
This highly integrated PWM controller, FAN400A, offers
several features to enhance the performance of a flyback
converter for low-power applications. Using the controller
reduces the costs of battery chargers and AC adapters. The
no-load power consumption can be less than 200mW for
universal AC input voltage range to meet the power
conservation requirements.
GND
GATE
FB
VDD
NC
SENSE
Features
ƒ Linearly Decreasing PWM Frequency
ƒ Green Mode Under Light-load and Zero-load Conditions
ƒ Constant Voltage (CV) and Constant Current (CC)
ƒ No Secondary Feedback
ƒ Low Startup Current: 8μA
ƒ Low Operating Current: 3.6mA
ƒ Leading-edge Blanking
ƒ Constant Power Limit
ƒ Universal AC Input Range
ƒ Synchronized Slope Compensation
ƒ 140°C OTP Sensor with Hysteresis
ƒ VDD Over-Voltage Clamping
ƒ Cycle-by-cycle Current Limiting
ƒ Under voltage lockout (UVLO)
ƒ Fixed PWM Frequency with Hopping
ƒ Gate Output Maximum Voltage Clamped at 17V
ƒ Small SOT-26 Package
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
Figure 1. SOT-26 Pin Configuration
GATE
GND
VDD
FB
NC
NC
SENSE
NC
Figure 2. DIP-8 Pin Configuration
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AN-400A
APPLICATION NOTE
Application Diagram
V IN
DO
R IN
D1
CO
W AUX
VDD
GATE
C IN
VO
Q1
SENSE
GND
RS
Figure 3. Typical Application
Internal Block Diagram
Figure 4. Functional Block Diagram
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
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AN-400A
APPLICATION NOTE
Start-up Circuitry
When the power is turned on, the input rectified voltage
VDC charges the hold-up capacitor C1 via a startup resistor
RIN. As the voltage of the VDD pin reaches the start
threshold voltage VDD-ON, the FAN400A activates and
drives the entire power supply.
Figure 6. Voltage Regulated by VDD Feedback
VO
Without Secondary Feedback Circuitry
With Secondary Feedback Circuitry
Figure 5. Circuit Providing Power to FAN400A
The maximum power-on delay time is determined as:
VDD - ON
t D_ON
⎡
⎤
−
R IN ⋅C1
⎥
= (VDC − I DD −ST ⋅ R IN ) ⎢1 − e
⎢⎣
⎥⎦
(1)
IO
where IDD_ST is the startup current of FAN400A and tD_ON is
the power-on delay time of the power supply.
Figure 7. Output Characteristics with and without
Secondary Feedback Circuitry
Due to the low startup current, a large RIN, such as 1.5MΩ,
can be used. With a hold-up capacitor of 10μF/50V, the
power-on delay tD_ON is less than 2.8s for 90VAC input.
A typical secondary feedback circuit mainly consisting of a
shunt regulator and an opto-coupler is shown in Figure 8.
R1 and R2 form a voltage divider for the output voltage
regulation. R3 and C1 are adjusted for control-loop
compensation. A small-value RC filter (e.g. RFB= 47Ω,
CFB=1nF) placed from FB pin to GND can increase
stability. The maximum sourcing current of the FB pin is
1.4mA. The phototransistor must be capable of sinking this
current to pull FB level down at no load. The value of
biasing resistor RB is determined as follows:
Constant Voltage (CV) Operation
The FAN400A can regulate the output voltage without
secondary-side feedback signal. As shown in Figure 6, an
internal VDD feedback comparator (VDD-comp) is used to
modulate the PWM output pulses when the FB pin is
floating. The primary VDD voltage is maintained at 22.7V
due to internal feedback compensation circuit. The output
voltage is proportional to VDD according to the ratio
between transformer auxiliary winding and secondary
winding. A typical output characteristic using FAN400A is
shown in Figure 7. If more precise output voltage regulation
is required, secondary feedback circuitry should be used.
VO − VD − VZ
⋅ K ≥ 1.4mA
RB
(2)
where:
VD is the drop voltage of photodiode, about 1.2V;
VZ is the minimum operating voltage of the shunt regulator
(typically 2.5V), and;
K is the current transfer rate (CTR) of the opto-coupler.
For an output voltage VO=5V, with CTR=100%, the
maximum value of RB is around 910Ω.
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
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AN-400A
FB
APPLICATION NOTE
RFB
RB
Oscillator & Green Mode Operation
VO
The proprietary green-mode function provides off-time
modulation to reduce the PWM frequency at light-load and
in no-load conditions. The feedback voltage of the FB pin is
taken as a reference. When the feedback voltage is lower
than about 2.6V, the PWM frequency decreases. Because
most losses in a switching-mode power supply are
proportional to the PWM frequency, the off-time
modulation reduces the power consumption of the power
supply at light-load and no-load conditions. The PWM
frequency is 65KHz at nominal load and decreases to
17KHz at light load. The power supply enters “adaptive offtime modulation” in zero-load conditions.
CFB
R3
R1
C1
R2
Figure 8. Feedback Circuit
Using secondary feedback circuitry, the primary VDD
voltage should be maintained lower than 20V. Otherwise,
the internal VDD feedback circuitry may activate with heavy
output loading. The transformer auxiliary turn number
should be reduced compared with primary feedback
application. When the secondary feedback circuitry is open
loop, the primary feedback circuitry acts as a back-up
protection to prevent the VDD exceeding 22.7V.
Figure 10. PWM Frequency vs. FB Voltage
Constant Current (CC) Operation
Built-in Slope Compensation
For a discontinuous-current mode flyback converter in
constant current operation, the output power is proportional
to the square of the peak primary current, and to the output
voltage. When the output voltage reduces to half, the
primary current drops to 0.707 times the original.
A flyback converter can be operated in either discontinuous
current mode (DCM) or continuous current mode (CCM).
There are many advantages to operating in CCM. With the
same output power, a converter in CCM exhibits smaller
peak inductor current than in DCM. Therefore, a smallsized transformer and a low-rating MOSFET can be
applied. On the secondary side of the transformer, the rms
output current of DCM can be up to twice that of CCM.
Larger wire gauge and output capacitors with larger ripple
current rating are required. DCM operation also results in a
higher output voltage spike. A large LC filter has to be
added. Therefore, a flyback converter in CCM achieves
better performance with lower component cost.
Inside the FAN400A, the VDD voltage is used to modulate
the level of the saw current limiting threshold voltage. As
shown in Figure 9, the valley voltage of the saw current
limiting curve reduces to 0.707 times of the original when
the VDD voltage reduces to half. With a good coupling of
the transformer, the ratio of the VDD voltage to the output
voltage is almost constant. A constant current operation is
therefore achieved.
Despite the above advantages of CCM operation, there is
one concern – stability. In CCM operation, the output power
is proportional to the average inductor current, while the
peak current is controlled. This causes the well-known subharmonic oscillation when the PWM duty cycle exceeds
50%. Adding slope compensation (reducing the currentloop gain) is an effective way to prevent oscillation.
FAN400A introduces a synchronized positive-going ramp
(VSLOPE) in every switching cycle to stabilize the current
loop. The sensed voltage, plus this slope compensation
signal (VSLOPE), is fed into the non-inverting input of the
PWM comparator. The resulting voltage is compared with
the FB signal to adjust the PWM duty cycle such that the
output voltage is regulated. Therefore, FAN400A allows
design of cost effective, highly efficient, and compact-sized
2VDD
VX
VDD
0.707 VX
Figure 9. Voltage Controlled SAW Current Limiting
Curves
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
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AN-400A
APPLICATION NOTE
flyback power supplies operating in CCM without adding
external components.
Actual Power
Limit Point
The positive ramp added is:
VSLOPE = VSL • D
High Line
(3)
Low Line
Sense Voltage
Sense Voltage
where VSL = 0.33V and D = duty cycle.
0
tD
tON1
tON2
Figure 12. Constant Power Limit Compensation
Leading-Edge Blanking (LEB)
A voltage signal proportional to the MOSFET current
develops on the current-sense resistor RS. Each time the
MOSFET turns on, a spike induced by the diode reverse
recovery and by the output capacitances of the MOSFET
and diode, appears on the sensed signal. A leading-edge
blanking time about 310ns is introduced to avoid premature
termination of MOSFET by the spike. Therefore, only a
small-value RC filter (e.g. 100Ω + 47pF) is required
between the SENSE pin and RS. A non-inductive resistor for
the RS is recommended.
Figure 11. Synchronized Slope Compensation
Over-Temperature Protection (OTP)
A built-in temperature sensing circuit shuts down PWM
output once the junction temperature exceeds 140°C. While
PWM output is shuts down, the VDD voltage gradually drops
to the UVLO voltage (around 8V). Then VDD is charged up
to the startup threshold voltage of 17V through the start up
resistor until PWM output is restarted. This “hiccup” mode
protection occurs repeatedly as long as the temperature
remains above 110°C. The temperature hysteresis window
for the OTP circuit is 30°C.
Constant Output Power Limit
The maximum output power of a flyback converter can be
generally designed by the current-sense resistor RS. When
the load increases, the peak inductor current increases
accordingly. When the output current arrives at the
protection value, the OCP comparator dominates the current
control loop. OCP occurs when the current-sense voltage
reaches the threshold value. The output GATE driver is
turned off after a small propagation delay, tD. The delay
time results in unequal power-limit level under universal
input. In FAN400A, a sawtooth power-limiter is designed to
solve the unequal power-limit problem. As shown in Figure
12, the power limiter is designed as a positive ramp signal
fed to the non-inverting input of OCP comparator. This
results in a lower current limit at high-line input than at lowline. However, with fixed propagation delay tD, the peak
primary current would be the same for various line input
voltage. Therefore, the maximum output power can almost
be limited to a constant value within a wide input voltage
range without adding external circuits.
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
Figure 13. Turn-on Spike
Gate Drive
FAN400A’s output stage is a fast totem-pole driver that can
directly drive MOSFET gate. It is equipped with a voltage
clamping Zener diode to protect MOSFET from damage
caused by undesirable over-drive voltage. The output
voltage is clamped at 17V. An internal pull-down resistor is
used to avoid floating state of gate before startup. A gate
drive resistor in the range of 47 to 100Ω is recommended to
limit the peak gate drive current and provide damping to
prevent oscillations at the MOSFET gate terminal.
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AN-400A
APPLICATION NOTE
Lab Note
Before rework or solder/desolder on the power supply,
discharge primary capacitors by external bleeding resistor.
Otherwise, the PWM IC may be destroyed by external high
voltage during solder/desolder.
This device is sensitive to ESD discharge. To improve
production yield, the production line should be ESD
protected according to ANSI ESD S1.1, ESD S1.4, ESD
S7.1, ESD STM 12.1, and EOS/ESD S6.1.
Figure 14. Gate Drive
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
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AN-400A
APPLICATION NOTE
Printed Circuit Board Layout
High-frequency switching current / voltage make printed
circuit board layout a very important design issue. Good
PCB layout minimizes excessive EMI helps the power
supply survive during surge/ESD tests.
Two suggestions with different pro and cons for ground
connections are recommended.
ƒ
GND3→2→4→1: This could avoid common impedance
interference for the sense signal.
Guidelines:
ƒ
GND3→2→1→4: This could be better for ESD tests where
the earth ground is not available on the power supply.
Regarding the ESD discharge path, the charges go from
secondary, through the transformer stray capacitance, to
GND2 first. Then the charges go from GND2 to GND1 and
back to mains. It should be noted that control circuits should
not be placed on the discharge path. Point discharge for
common choke can decrease high-frequency impedance and
increase ESD immunity.
ƒ
Should a Y-cap between primary and secondary be required,
connect this Y-cap to the positive terminal of C1 (VDC). If
this Y-cap is connected to primary GND, it should be
connected to the negative terminal of C1 (GND1) directly.
Point discharge of this Y-cap also helps for ESD. However,
the creepage between these two pointed ends should be at
least 5mm according to safety requirements.
To get better EMI performance and reduce line frequency
ripples, the output of the bridge rectifier should be
connected to capacitor C1 first, then to the switching
circuits.
ƒ
The high frequency current loop is in C1 – Transformer –
MOSFET – RS – C1. The area enclosed by this current loop
should be as small as possible. Keep the traces (especially
4→1) short, direct, and wide. High-voltage traces related the
drain of MOSFET and RCD snubber should be kept far way
from control circuits to prevent unnecessary interference. If
heatsink is used for MOSFET, connect this heatsink to ground.
ƒ
As indicated by 3, the ground of control circuits should be
connected first, then to other circuitry.
ƒ
As indicated by 2, the area enclosed by transformer auxiliary
winding, D1, and C2 should also be kept small. Place C2
close to FAN400A for good decoupling.
RIN
VDC
D1
C1
Common Mode
Choke
C2
1
VDD
2
FB
RFB
RG
Gate
FAN400A
RF
Sense
CFB
Cf
RS
GND
4
3
Y-cap
5
Figure 15. Layout Considerations
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
www.fairchildsemi.com
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AN-400A
APPLICATION NOTE
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS
HEREIN TO IMPROVE RELIABILITY, FUNCTION, OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE
APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS
PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS
WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION.
As used herein:
1.
2.
Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or
sustain life, or (c) whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be
reasonably expected to result in significant injury to the user.
A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause
the failure of the life support device or system, or to affect its safety or effectiveness
© 2008 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 5/29/08
www.fairchildsemi.com
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