FAIRCHILD AN4146

www.fairchildsemi.com
Application Note AN4146
Design Guidelines for Quasi-Resonant Converters
Using FSCQ-series Fairchild Power Switch (FPSTM)
Abstract
In general, a Quasi-Resonant Converter (QRC) shows lower
EMI and higher power conversion efficiency compared to
the conventional hard switched converter with a fixed
switching frequency. Therefore, it is well suited for color TV
applications that are noise sensitive. This application note
presents practical design considerations of Quasi-Resonant
Converters for color TV applications employing FSCQseries FPSTM (Fairchild Power Switch). It includes
designing the transformer, output filter and sync network,
selecting the components and closing the feedback loop. The
step-by-step design procedure described in this application
note will help engineers design Quasi-Resonant Converter
easily. To make the design process more efficient, a software
design tool, FPS design assistant which contains all the
equations described in this application note, is also provided.
The design procedure is verified through an experimental
prototype converter.
DR(n)
LP(n)
VO(n)
NS(n)
CO(n)
Np
DR1
CP(n)
LP1
VO1 (B+)
NS1
AC
IN
CO1
FSCQ-series
Sync
CP1
Drain
PWM
LP2
DR2
Cr
VO2 (Sound)
GND
NS2
VFB
Vcc
CB
Rcc
Ca1
Dzc
Vco
Ca2
Da
DSY
CP2
CO2
Linear
regulator
Rd
RSY1
Rstr
MCU
Na
R3
Rbias
H11A817A
R1
Dz
CSY
RSY2
KA431
RF
CF
R2
R1
Q
Picture ON
Figure 1. Basic Quasi-Resonant Converter (QRC) Using FPS (Color TV Application)
1. Introduction
The FSCQ-series FPSTM (Fairchild Power Switch) is an
integrated Pulse Width Modulation (PWM) controller and
Sense FET specifically designed for Quasi-resonant off-line
Switch Mode Power Supplies (SMPS) with minimal external
components. Compared with discrete MOSFET and PWM
controller solution, it can reduce total cost, component count,
size and weight, while simultaneously increasing efficiency,
productivity, and system reliability.
Figure 1 shows the basic schematic of an FPS based QuasiResonant Converter for the color TV application, which also
serves as the reference circuit for the design process
described in this application note. An experimental converter
from the design example has been built and tested to show
the validity of the design procedure.
Rev. 1.0.1
©2005 Fairchild Semiconductor Corporation
AN4146
APPLICATION NOTE
2. Step-by-step Design Procedure
1. Define the system specifications
(Vlinemin, Vlinemax, fL , Po , Eff )
In this section, a design procedure is presented using the
schematic of Figure 1 as a reference. Figure 2 illustrates the
design flow chart. The detailed design procedures are as
follows:
[STEP-1] Define the system specifications
2. Determine DC link capacitor (CDC)
and DC link voltage range
- Line voltage range (Vlinemin and Vlinemax).
- Line frequency (fL).
3. Determine the reflected output voltage
(VRO)
- Maximum output power (Po).
- Estimated efficiency (Eff) : The power conversion
efficiency must be estimated to calculate the maximum input
power. If no reference data is available, set Eff = 0.7~0.75 for
low voltage output applications and Eff = 0.8~0.85 for high
voltage output applications. In the case of Color TV
applications, the typical efficiency is 80~83%.
4. Determine the transformer primary side
inductance (Lm)
5. Choose proper FPS considering input
power and Idspeak
6. Determine the proper core and the
minimum primary turns (Npmin)
With the estimated efficiency, the maximum input power is
given by
P
P in = ------oE ff
7. Determine the number of turns for each
output and Vcc auxiliary circuit
For multiple output SMPS, the load occupying factor for
each output is defined as
8. Determine the startup resistor
Po ( n )
K L ( n ) = -----------Po
9. Determine the wire diameter for each
winding
Is the winding window
area (Aw) enough ?
(1)
Y
(2)
where Po(n) is the maximum output power for the n-th
output. For single output SMPS, KL(1)=1. It is assumed that
Vo1 is the reference output that is regulated by the feedback
control in normal operation.
N
Y
Is it possible to change the core ?
[STEP-2] Determine DC link capacitor (CDC) and the
DC link voltage range.
N
10. Choose the secondary side rectifier diodes
Typically, the DC link capacitor is selected as 2-3uF per watt
of input power for universal input range (85-265Vrms) and
1uF per watt of input power for European input range (195V265Vrms). With the DC link capacitor selected, the
minimum DC link voltage is obtained as
11. Determine the output capacitors
V DC
min
=
2 ⋅ ( V line
12. Design the synchronization network
13. Design the voltage drop circuit for burst
operation
P in ⋅ ( 1 – D ch )
) – -----------------------------------C DC ⋅ f L
min 2
(3)
where CDC is the DC link capacitor and Dch is the duty cycle
ratio for CDC to be charged as defined in Figure 3, which is
typically about 0.2. Pin, Vlinemin and fL are specified in
STEP-1.
14. Design the feedback control circuit
The maximum DC link voltage is given as
Design finished
Figure 2. Flow Chart of Design Procedure
2
V DC
max
=
2V line
max
(4)
where Vlinemax is specified in STEP-1.
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
[STEP-4] Determine the transformer primary side
inductance (Lm)
Figure 5 shows the typical waveforms of MOSFET drain
current, secondary diode current and the MOSFET drain
voltage of a Quasi-Resonant Converter. During TOFF, the
current flows through the secondary side rectifier diode and
the MOSFET drain voltage is clamped at (VDC+VRO). When
the secondary side current reduces to zero, the drain voltage
begins to drop because of the resonance between the
effective output capacitor of the MOSFET and the primary
side inductance (Lm). To minimize the switching loss, the
FSCQ-series is designed to turn on the MOSFET when the
drain voltage reaches its minimum voltage (VDC -VRO).
Minimum DC link voltage
DC link voltage
T1
Dch = T1 / T2
= 0.2
T2
Figure 3. DC Link Voltage Waveform
[STEP-3] Determine the reflected output voltage (VRO)
Figure 4 shows the typical waveforms of the drain voltage of
Quasi-resonant flyback converter. When the MOSFET is
turned off, the DC link voltage (VDC) together with the
output voltage reflected to the primary (VRO) is imposed on
the MOSFET and the maximum nominal voltage across the
MOSFET (Vdsnom) is
V ds
nom
= V DC
max
+ V RO
Ids
ID
(5)
where VDCmax is as specified in equation (4). By increasing
VRO, the capacitive switching loss and conduction loss of the
MOSFET are reduced. However, this increases the voltage
stress on the MOSFET as shown in Figure 4. Therefore, VRO
should be determined by a trade-off between the voltage
margin of the MOSFET and the efficiency. It is typical to set
VRO as 120~180V so that Vdsnorm is 490~550V (75~85% of
MOSFET rated voltage).
V ds
V DC +V RO
V RO
V RO
V DC
V DC -V RO
T ON
+
+
VDC
Lm
Figure 5. Typical Waveforms of Quasi-Resonant
Converter
VO
VRO
-
FPS
Drain
GND
+
Cr
To determine the primary side inductance (Lm), the
following variables should be determined beforehand.
+
Vds
-
VRO
VRO
Vdsnom
VDC max
VRO
Vdsnom
VRO
0V
Figure 4. The Typical Waveform of MOSFET Drain
Voltage for Quasi Resonant Converter
©2005 Fairchild Semiconductor Corporation
TF
TS
-
-
T OFF
• The minimum switching frequency (fsmin) : The
minimum switching frequency occurs at the minimum
input voltage and full load condition, which should be
higher than the minimum switching frequency of FPS
(20kHz). By increasing fsmin, the transformer size can be
reduced. However, this results in increased switching
losses. Therefore determine fsmin by a trade-off between
switching losses and transformer size. Typically, fsmin is
set to be around 25kHz.
• The falling time of the MOSFET drain voltage (TF) :
As shown in Figure 5, the MOSFET drain voltage fall
time is half of the resonant period of the MOSFET’s
effective output capacitance and primary side inductance.
By increasing TF, EMI can be reduced. Meanwhile, this
forces an increase of the resonant capacitor (Cr) resulting
in increased switching losses. The typical value for TF is
2-2.5us.
3
AN4146
APPLICATION NOTE
After determining fsmin and TF, the maximum duty cycle is
calculated as
V RO
min
D max = ------------------------------------⋅ ( 1 – fs
× TF )
min
V RO + V DC
(6)
where VDCmin is specified in equation (3) and VRO is
determined in STEP-3.
Then, the primary side inductance is obtained as
2
min
Lm
( V DC
⋅ D max )
= --------------------------------------------min
2 ⋅ fs
⋅ P in
(7)
where Pin, VDCmin and Dmax are specified in equations (1),
(3), and (6), respectively and fsmin is the minimum switching
frequency.
Once Lm is determined, the maximum peak current and RMS
current of the MOSFET in normal operation are obtained as
min
I ds
peak
I ds
rms
V DC
D max
= ----------------------------------min
Lm fs
=
(8)
D max
peak
-------------- ⋅ I ds
3
(9)
where VDCmin, Dmax and Lm are specified in equations (3),
(6) and (7), respectively and fsmin is the minimum switching
frequency.
[STEP-5] Choose the proper FPS considering input
power and peak drain current.
Maximum Output Power
230VAC
85-265Vac
±15%
Table 2 shows the commonly used cores for C-TV
application for different output powers. When designing the
transformer, consider the maximum flux density swing in
normal operation (∆B) as well as the maximum flux density
in transient (Bmax). The the maximum flux density swing in
normal operation is related to the hysteresis loss in the core
while the maximum flux density in transient is related to the
core saturation.
With the chosen core, the minimum number of turns for the
transformer primary side to avoid the over temperature in the
core is given by
peak
NP
min
ILIM (A)
Min
Typ
Max
FSCQ0565RT
70 W
60 W
3.08
3.5
3.92
FSCQ0765RT
100 W
85 W
4.4
5
5.6
FSCQ0965RT
130 W
110 W
5.28
6
7.84
FSCQ1265RT
170 W
140 W
6.16
7
7.84
FSCQ1465RT
190 W
160 W
7.04
8
8.96
FSCQ1565RT
210 W
170 W
7.04
8
8.96
FSCQ1565RP
250 W
210 W
10.12
11.5
12.88
Table 1. FPS Lineups with Rated Output Power
L m I ds
6
= -------------------------- × 10
∆ BA e
(10)
where Lm is specified in equation (7), Idspeak is the peak
drain current specified in equation (8), Ae is the crosssectional area of the transformer core in mm2 as shown in
Figure 6 and ∆B is the maximum flux density swing in tesla.
If there is no reference data, use ∆B =0.25~0.30 T.
Since the MOSFET drain current exceeds Idspeak and reaches
ILIM in a transient or fault condition, the transformer should
be designed not to be saturated when the MOSFET drain
current reaches ILIM . Therefore, the maximum flux density
(Bmax) when drain current reaches ILIM should be also
considered as
NP
With the resulting maximum peak drain current of the
MOSFET (Idspeak) from equation (8), choose the proper FPS
whose the pulse-by-pulse current limit level (ILIM) is higher
than Idspeak. Since FPS has ± 12% tolerance of ILIM, there
should be some margin for ILIM when choosing the proper
FPS device. Table 1 shows the lineups of FSCQ-series with
rated output power and pulse-by-pulse current limit.
PRODUCT
[STEP-6] Determine the proper core and the minimum
primary turns.
min
L m I LIM
6
= -------------------- × 10
B max A e
(11)
where Lm is specified in equation (7), ILM is the pulse-bypulse current limit, Ae is the cross-sectional area of the core
in mm2 as shown in Figure 6 and Bmax is the maximum flux
density in tesla. Figure 7 shows the typical characteristics of
ferrite core from TDK (PC40). Since the core is saturated at
low flux density as the temperature goes high, consider the
high temperature characteristics. If there is no reference data,
use Bmax =0.35~0.4 T.
The primary turns should be determined as less than Npmin
values obtained from equation (10) and (11).
Aw
(mm2)
Ae
(mm2)
Figure 6. Window Area and Cross Sectional Area
4
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
N p = n ⋅ N s1 > N p
M agnetization Curves (typical)
M aterial :PC40
(13)
where n is obtained in equation (12) and Np and Ns1 are the
number of turns for the primary side and the reference
output, respectively.
25 ℃
500
60 ℃
100 ℃
400
Flux density B (mT)
min
The number of turns for the other output (n-th output) is
determined as
Vo ( n ) + VF ( n )
N s ( n ) = --------------------------------⋅ N s1
V o1 + V F1
300
( 14 )
where Vo(n) is the output voltage and VF(n) is the diode
(DR(n)) forward voltage drop of the n-th output, respectively.
200
100
NS(n)
0
800
M agnetic field H (A/m)
0
1600
+ VF(n) DR(n)
+
VO(n)
Figure 7. Typical B-H Characteristics of Ferrite Core
(TDK/PC40)
Np
NS2
-
Output Power
Core
70-100W
EER35
100-150W
EER40
EER42
150-200W
EER49
+ VF2 DR2 VO2
+
VRO
-
+
Rcc
Table 2. Commonly Used Cores for C-TV Applications
Vcc
+
-
- VFa + N
a
Va D
a
+
18V
Linear
Regulator
NS1
+ VF1 DR1
+
VO1
-
[STEP-7] Determine the number of turns for each output
and Vcc auxiliary circuit
Figure 8 shows the simplified diagram of the transformer. It
is assumed that Vo1 is the reference output that is regulated
by the feedback control in normal operation. It is also
assumed that linear regulator is connected to Vo2 to supply a
stable voltage for MCU.
First, calculate the turns ratio (n) between the primary
winding and reference output (Vo1) winding as a reference as
in
V R0
n = ------------------------V o1 + V F1
(12)
where VRO is determined in STEP-3 and Vo1 is the reference
output voltage and VF1 is the forward voltage drop of diode
(DR1).
Then, determine the appropriate integer for Ns1 so that the
resulting Np is larger than Npmin as
©2005 Fairchild Semiconductor Corporation
Figure 8. Simplified Diagram of the Transformer
- Vcc winding design : As shown in Figure 9, FSCQ-series
drops all the outputs including the Vcc auxiliary voltage (Va)
in standby mode to minimize the power consumption.
Because the Vcc auxiliary voltage (Va) changes a over wide
range, a regulation circuit using zener diode is typically used
to provide a stable supply voltage (Vcc) for FPS in normal
operation, as shown in Figure 8. It is typical to design the
regulation circuit so that the Vcc voltage is regulated as 18V
in normal operation and is above Vcc stop voltage (9V) by
2~3V in standby operation as shown in Figure 9. After
FSCQ-series enters into standby mode, the current
consumed by FPS drops below 500uA and the voltage drop
across Rcc is negligible.
5
AN4146
APPLICATION NOTE
- Vcc drop resistor (Rcc) : The current consumed by FPS in
normal operation is given by
Vo2
Vo2normal
( 18 )
I cc = I op + I drv
where Iop and Idrv are the currents required for IC operation
and MOSFET gate drive, respectively. Iop is given in the
data sheet and Idrv is obtained as
Vo2stby
I drv = V cc ⋅ C iss ⋅ f s
Vcc
18V
Vastby
9V
where Ciss is the input capacitance of the MOSFET and fs is
the switching frequency. When considering Idrv, it is typical
to assume that Vcc is Vz (18V) and fs is 90kHz.
Va
Vanormal
( 19 )
The condition for the Vcc drop resistor (Rcc) is given by
normal
V co
– Vz
R cc < ------------------------------------I cc
2-3 V
Normal mode
Standby mode
( 20 )
The heat dissipation of Rcc in normal operation is given by
Figure 9. Output Voltage Drop in Standby Mode
normal
2
( v co
– Vz )
P a = --------------------------------------------R cc
( 21 )
where Vz is the zener breakdown voltage (typically 18V).
In standby mode, Vo2 is regulated by the feedback control
and the voltage drop ratio of the Vo2 winding is defined in
stby
V 02
+ V F2
K drop = -----------------------------------------normal
V 02
+ V F2
(15)
where VF2 is the diode forward voltage drop of the DR2, and
Vo2normaland Vo2stby are the output voltages of Vo2 in normal
mode and standby mode, respectively, as shown in Figure 9.
Assuming that the Vcc auxiliary voltage (Va) is reduced with
the ratio of Kdrop, Va in normal mode is obtained as
normal
Va
+ V Fa
= -------------------------------- – V F2
K drop
After determining Vanormal, the number of turns for the Vcc
auxiliary winding (Na) is obtained as
normal
( 17 )
where VFa is the forward voltage drop of Da as defined in
Figure 8.
6
3-5 Ω
FSCQ-series
Ca1
10kΩ
Ca2
( 16 )
where Vastby is the minimum voltage of Va in standby mode,
which should be larger than Vcc stop voltage of FPS
(typically 9V). Notice that the operating current is reduced in
standby mode and therefore the voltage drop across Rcc is
negligible. It is typical to have a voltage margin of 2-3V
when determining Vastby.
Va
+ V Fa
N a = -------------------------------------- ⋅ N s1
V o1 + V F1
Da
Vcc
Vz
(18V)
stby
Va
When a large voltage drop of more than 20V is required,
application circuit shown in Figure 11 is preferred to
minimize the power dissipation in the voltage drop circuit.
Figure. 10 Vcc Auxiliary Circuit for a Large Voltage Drop
[STEP-8] Determine the startup resistor
Figure 10 shows the typical circuit of Vcc winding for
FSCQ-series. Initially, FPS consumes only startup current
(max 50uA) before it begins switching. Therefore, the
current supplied through the startup resistor (Rstr) can charge
the capacitors Ca1 and Ca2 while supplying startup current to
FPS. When Vcc reaches start voltage of 15V (VSTART), FPS
begins switching and the current consumed by FPS
increases. Then, the current required by FPS is supplied from
the transformer’s auxiliary winding.
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
[STEP-9] Determine the wire diameter for each
winding based on the RMS current of each output.
The RMS current of the n-th secondary winding is obtained
as
C DC
I sec ( n )
AC line
= I ds
rms
I sup
Rstr
Vcc
R CC
Da
Vco
FSCQ-series
Vz
(18V)
C a1
C a2
Figure. 11 Startup and Vcc Auxiliary Circuit
- Startup resistor (Rstr) : The average of the minimum
current supplied through the startup resistor is given by
I sup
rms
avg
min
⎛ 2⋅V
⎞
V
line
start
1
⎜
------------------------------------=
– -----------------⎟ ⋅ -----------⎜
π
2 ⎟ R
str
⎝
⎠
( 22 )
The maximum startup time is determined as
max
V start
= C e ⋅ -------------------------------------------------avg
max
( I sup
– I start
)
( 23 )
( 25 )
where Dmax and Idsrms are specified in equations (6) and (9),
Vo(n) is the output voltage of the n-th output, VF(n) is the
diode (DR(n)) forward voltage drop, VRO is specified in
STEP-3 and KL(n) is the load occupying factor for n-th
output defined in equation (2).
The current density is typically 5A/mm2 when the wire is
long (>1m). When the wire is short with a small number of
turns, a current density of 6-10 A/mm2 is also acceptable.
Avoid using wire with a diameter larger than 1 mm to avoid
severe eddy current losses as well as to make winding easier.
For high current output, it is recommended using parallel
windings with multiple strands of thinner wire to minimize
skin effect.
Check if the winding window area of the core, Aw (refer to
Figure 6) is enough to accommodate the wires. The required
winding window area (Awr) is given by
Aw r = Ac ⁄ KF
where Vlinemin is the minimum input voltage, Vstart is the
start voltage (15V) of FPS and Rstr is the startup resistor. The
startup resistor should be chosen so that Isupavg is larger than
the maximum startup current (50uA). If not, Vcc can not be
charged up to the start voltage and FPS will fail to start up.
T str
V RO ⋅ K L ( n )
1 – D max
----------------------- ⋅ -------------------------------------( Vo ( n ) + VF ( n ) )
D max
(26)
where Ac is the actual conductor area and KF is the fill factor.
Typically the fill factor is 0.2~0.25 for single output
applications and 0.15~0.2 for multiple outputs applications.
If the required window (Awr) is larger than the actual window
area (Aw), go back to the STEP-6 and change the core to a
bigger one. Sometimes it is impossible to change the core
due to cost or size constraints. In that case, reduce VRO in
STEP-3 or increase fsmin, which reduces the primary side
inductance (Lm) and the minimum number of turns for the
primary (Npmin) shown in equation (7) and (10).
Where Ce is the effective Vcc capacitor (Ca1+Ca2) and
Istartmax is the maximum startup current (50uA) of FPS.
Once the startup resistor (Rstr) is determined, the maximum
approximate power dissipation in Rstr is obtained as
max⎞ 2
2
max⎞
⎛⎛V
+V
⋅V
2 2⋅V
⎜ ⎝ line
⎟
⎠
start
1
start line
P
= ------------ ⋅ ⎜ ---------------------------------------------------------------- – -----------------------------------------------------------------⎟
str R str ⎜
π
2
⎟
⎝
⎠
[STEP-10] Choose the proper rectifier diodes in the
secondary side based on the voltage and current ratings.
The maximum reverse voltage and the rms current of the
rectifier diode (DR(n)) of the n-th output are obtained as
( 24 )
where Vlinemax is the maximum input voltage, which is
specified in STEP-1. The startup resistor should have a
proper dissipation rating based on the value of Pstr.
max
V DC
⋅ ( Vo (n ) + VF ( n ) )
V D ( n ) = V o ( n ) + --------------------------------------------------------------V RO
( 27 )
V RO K L ( n )
1 – D max
----------------------- ⋅ -------------------------------------( Vo ( n ) + VF ( n ) )
D max
( 28 )
ID ( n )
rms
= I ds
rms
where KL(n), VDCmax, Dmax and Idsrms are specified in
equations (2), (4), (6) and (9), respectively, VRO is specified
in STEP-3, Vo(n) is the output voltage of the n-th output and
VF(n) is the diode (DR(n)) forward voltage drop. The typical
©2005 Fairchild Semiconductor Corporation
7
AN4146
APPLICATION NOTE
voltage and current margins for the rectifier diode are as
follows
V RRM > 1.3 ⋅ V D ( n )
I F > 1.5 ⋅ I D ( n )
(29)
rms
[STEP-11] Determine the output capacitors considering
the voltage and current ripple.
The ripple current of the n-th output capacitor (Co(n)) is
obtained as
(30)
where VRRM is the maximum reverse voltage and IF is the
average forward current of the diode.
A quick selection guide for the Fairchild Semiconductor
rectifier diodes is given in Table 3. In this table, trr is the
maximum reverse recovery time.
I cap ( n )
rms
=
( ID ( n )
rms 2
) – Io ( n)
2
(31)
where Io(n) is the load current of the n-th output and ID(n)rms
is specified in equation (28). The ripple current should be
smaller than the maximum ripple current specification of the
capacitor. The voltage ripple on the n-th output is given by
I
D
I
peak
V R
K
( Vo ( n ) + VF ( n ) )
o ( n ) max
ds
RO C ( n ) L ( n )
∆ V o ( n ) = -------------------------+ ---------------------------------------------------------- (32)
Ultra Fast Recovery Diode
Products
VRRM
IF
trr
Package
EGP10B
100 V
1A
50 ns
DO-41
UF4002
100 V
1A
50 ns
DO-41
EGP20B
100 V
2A
50 ns
DO-15
EGP30B
100 V
3A
50 ns
DO-210AD
FES16BT
100 V
16 A
35 ns
TO-220AC
EGP10C
150 V
1A
50 ns
DO-41
EGP20C
150 V
2A
50 ns
DO-15
EGP30C
150 V
3A
50 ns
DO-210AD
FES16CT
150 V
16 A
35 ns
TO-220AC
EGP10D
200 V
1A
50 ns
DO-41
UF4003
200 V
1A
50 ns
DO-41
EGP20D
200 V
2A
50 ns
DO-15
EGP30D
200 V
3A
50 ns
DO-210AD
FES16DT
200 V
16 A
35 ns
TO-220AC
EGP10F
300 V
1A
50 ns
DO-41
EGP20F
300 V
2A
50 ns
DO-15
EGP30F
300 V
3A
50 ns
DO-210AD
EGP10G
400 V
1A
50 ns
DO-41
UF4004
400 V
1A
50 ns
DO-41
EGP20G
400 V
2A
50 ns
DO-15
EGP30G
400 V
3A
50 ns
DO-210AD
UF4005
600 V
1A
75 ns
DO-41
EGP10J
600 V
1A
75 ns
DO-41
EGP20J
600 V
2A
75ns
DO-15
EGP30J
600 V
3A
75 ns
DO-210AD
UF4006
800 V
1A
75 ns
TO-41
UF4007
1000 V
1A
75 ns
TO-41
Table 3. Fairchild Diode Quick Selection Table
Co ( n ) fs
min
where Co(n) is the capacitance, Rc(n) is the effective series
resistance (ESR) of the n-th output capacitor, KL(n), Dmax and
Idspeak are specified in equations (2), (6) and (8) respectively,
VRO is specified in STEP-3, Io(n) and Vo(n) are the load
current and output voltage of the n-th output, respectively
and VF(n) is the diode (DR(n)) forward voltage drop.
Sometimes it is impossible to meet the ripple specification
with a single output capacitor due to the high ESR of the
electrolytic capacitor. In those cases, use additional LC filter
stages (post filter) to reduce the ripple on the output.
[STEP-12] Design the synchronization network.
The FSCQ-series employs a quasi-resonant switching
technique to minimize the switching noise and loss. In this
technique, a capacitor (Cr) is added between the MOSFET
drain and source as shown in Figure 12. The basic
waveforms of a Quasi-Resonant Converter are shown in
Figure 13. The external capacitor lowers the rising slope of
drain voltage, which reduces the EMI caused by the
MOSFET turn-off. To minimize the MOSFET switching
loss, the MOSFET should be turned on when the drain
voltage reaches its minimum value as shown in Figure 13.
The optimum MOSFET turn-on time is indirectly detected
by monitoring the Vcc winding voltage as shown in Figure
12 and 13. The output of the sync detect comparator (CO)
becomes high when the sync voltage (Vsync) exceeds 4.6V
and low when the Vsync reduces below 2.6V. The MOSFET is
turned on at the falling edge of the sync detect comparator
output (CO).
©2005 Fairchild Semiconductor Corporation
8
APPLICATION NOTE
AN4146
Np
Vds
N s1
FSCQ-series
+
VRO
Drain
CO
Cr
Ids
4.6/2.6V
Sync
V o1
Lm
Sync comparator
+
V ds
-
VRO
VDC
GND
Vcc
R cc
TF
Vsync
Na
Vco
Vovp (12V)
Da
Vsyncpk
18V
C a1
C a2
D SY
4.6V
V sync
2.6V
R SY1
TQ
CO
C SY
R SY2
MOSFET Gate
Figure. 12 Synchronization Circuit
ON
The peak value of the sync signal is determined by the
voltage divider network RSY1 and RSY2 as
V sync
pk
R SY2
normal
= ---------------------------------- ⋅ V a
R SY1 + R SY2
ON
Figure. 13 Synchronization Waveforms
( 33 )
where Vanormal is the Vcc auxiliary voltage in normal mode.
Choose the voltage divider RSY1 and RSY2 so that the peak
value of sync voltage (Vsyncpk) is lower than the OVP
threshold voltage (12V) to avoid triggering OVP in normal
operation. It is typical to set Vsyncpk to be 8~10V.
To synchronize the Vsync with the MOSFET drain voltage,
the sync capacitor (CSY) should be chosen so that TF is same
as TQ as shown in Figure 13. TF and TQ are given as
[STEP-13] Design voltage drop circuit for the burst
operation.
VO2
RD
(34)
CF
C
normal
TQ
R SY2
⎛ Va
⎞
= R SY2 ⋅ C SY ⋅ ln ⎜ -------------------- ⋅ ----------------------------------⎟
2.6
R
+
R
⎝
SY1
SY2⎠
(35)
where Lm is the primary side inductance of the transformer,
Ns and Na are the number of turns for the output winding and
Vcc winding, respectively, Vanormal is the Vcc auxiliary
voltage in normal mode and Ceo is the effective MOSFET
output capacitance (Coss+Cr).
KA431
A
M icom
Dz (VZB )
Rbias
R1
T F = π ⋅ L m ⋅ C eo
Linear
Regulator
VO1 (B+)
RF
D1
R3
Q1
Picture ON
R
R2
Figure 14. Typical Feedback Circuit to Drop Output
Voltage in Standby Mode
To minimize the power consumption in the standby mode,
FSCQ-series employs burst operation. Once FPS enters into
burst mode, all output voltages and effective switching
frequencies are reduced. Figure 14 shows the typical output
voltage drop circuit for C-TV applications. Under normal
©2005 Fairchild Semiconductor Corporation
9
AN4146
APPLICATION NOTE
operation, the picture on signal is applied and the transistor
Q1 is turned on, which de-couples R3, Dz and D1 from the
feedback network. Thus, only Vo1 is regulated by the
feedback circuit in normal operation and is determined as
R1 + R2
V o1 = 2.5 ⋅ ⎛ --------------------⎞
⎝ R2 ⎠
in Figure 16, the feedback loop can be easily implemented
with a one-pole and one-zero compensation circuit. The
current control factor of FPS, K is defined as
I pk
I LIM
K = --------- = ----------------V FB
V FBsat
(36)
Figure 15 shows the standby mode operation waveforms. In
standby mode, the picture on signal is disabled and the
transistor Q1 is turned off, which couples R3, Dz and D1 to
the reference pin of KA431. If R3 is much smaller than R1,
Vo2 is dominant in the feedback loop. Before Vo2 drops to
Vo2stby, the voltage on the reference pin of KA431 is higher
than 2.5V, which increases the current through the opto LED.
This pulls down the feedback voltage (VFB) of FPS and
forces to stop switching. Once FPS stops switching, Vo2
decrease, and when Vo2 reaches Vo2stby, the current through
the opto LED decreases allowing the feedback voltage to
rise. When the feedback voltage reaches 0.4V, FPS resumes
switching with a predetermined peak drain current.
Assuming that the forward voltage drop of D1 is 0.5V, the
approximate output voltage for Vo2 in standby mode is given
by
where Ipk is the peak drain current and VFB is the feedback
voltage for a given operating condition, ILIM is the current
limit of the FPS and VFBsat is the internal feedback saturation
voltage, which is typically 2.5V.
In order to express the small signal AC transfer functions,
the small signal variations of feedback voltage (vFB) and
controlled output voltage (vo1) are introduced as vˆFB and vˆo1.
vo1
stby
= V ZB + 0.5 + 2.5
vbias
FPS
vFB
RB
V 02
(38)
CB
(37)
RD
ibias
Rbias
iD
CTR :1
where VZB is the zener breakdown voltage of Dz.
CF
RF
R1
KA431
R2
Vo2
Ipk
MOSFET
current
Vo2stby
Figure 16. Control Block Diagram
VFB
For quasi-resonant flyback converter, the control-to-output
transfer function using current mode control is given by
0.4V
vˆ o1
G vc = -------vˆ
FB
K ⋅ R L V DC ( N p ⁄ N s1 ) ( 1 + s ⁄ w z ) ( 1 – s ⁄ w rz )
= ----------------------------------------------------- ⋅ ---------------------------------------------------------1 + s ⁄ wp
2 ( 2V RO + v DC )
Ids
Normal mode
Standby mode
Figure 15. Burst Operation Waveforms
( 39 )
where VDC is the DC input voltage, RL is the effective total
load resistance of the controlled output, which is defined as
Vo12/Po , Np and Ns1 are specified in STEP-7, VRO is
specified in STEP-3, Vo1 is the reference output voltage, Po
is specified in STEP-1 and K is specified in equation (38).
The pole and zeros of equation (39) are defined as
2
[STEP-14] Design the feedback control circuit.
Since FSCQ-series employs current mode control as shown
10
RL ( 1 – D )
1
(1 + D)
w z = -------------------- , w rz = ---------------------------------------- and w p = ------------------2
R c1 C o1
R L C o1
DL m ( N s1 ⁄ N p )
where Lm is specified in equation (7), D is the duty cycle of
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
the FPS, Co1 is the output capacitor of Vo1 and RC1 is the
ESR of Co1.
When the converter has more than one output, the low
frequency control-to-output transfer function is proportional
to the parallel combination of all load resistance, adjusted by
the square of the turns ratio. Therefore, the effective load
resistance is used in equation (39) instead of the actual load
resistance of Vo1. Notice that there is a right half plane
(RHP) zero (wrz) in the control-to-output transfer function of
equation (39). Because the RHP zero reduces the phase by
90 degrees, the crossover frequency should be placed below
the RHP zero.
Figure 17 shows the variation of a quasi-resonant flyback
converter control-to-output transfer function for different
input voltages. This figure shows the system poles and zeros
together with the DC gain change for different input
voltages. The gain is highest at the high input voltage
condition and the RHP zero is lowest at the low input voltage
condition.
Figure 18 shows the variation of a quasi-resonant flyback
converter control-to-output transfer function for different
loads. This figure shows that the gain between fp and fz does
not change for different loads and the RHP zero is lowest at
the full load condition.
The feedback compensation network transfer function of
Figure 16 is obtained as
ˆ
w i 1 + s ⁄ w zc
v FB
----- --------------------------------ˆ - = - s ⋅ 1 + s ⁄ w pc
v o1
( 40 )
40 dB
fp
Light load
20 dB
fp
0dB
Heavy load
-20 dB
frz
frz
fz
-40 dB
1Hz
10Hz
100Hz
1kHz
10kHz
100kHz
Figure 18. QR Flyback Converter Contro to Output
Transfer Function Variation for Different Loads
When the input voltage and the load current vary over a wide
range, determining the worst case for the feedback loop
design is difficult. The gain together with zeros and poles
varies according to the operating conditions.
One simple and practical solution to this problem is
designing the feedback loop for low input voltage and full
load condition with enough phase and gain margin. The RHP
zero is lowest at low input voltage and full load condition.
The gain increases only about 6dB as the operating condition
is changed from the lowest input voltage to the highest input
voltage condition under universal input condition.
The procedure to design the feedback loop is as follows
(a) Set the crossover frequency (fc) below 1/3 of RHP zero to
minimize the effect of the RHP zero. Set the crossover
frequency below half of the minimum switching frequency
(fsmin).
R B ⋅ CTR
1
1
where w i = ------------------------ , w zc = --------------- , w pc = --------------R1 RD CF
RF CF
RB CB
and RB is the internal feedback bias resistor of FPS, which is
typically 2.8kΩ, CTR is the current transfer ratio of opto
coupler and R1, RD, RF, CF and CB are shown in Figure 16.
(b) Determine the DC gain of the compensator (wi/wzc) to
cancel the control-to-output gain at fc.
(c) Place a compensator zero (fzc) around fc/3.
(d) Place a compensator pole (fpc) around 3fc.
40 dB
fp
Loop gain T
20 dB
40 dB
fp
High input voltage
0dB
Low input voltage
0 dB
frz
fz
Control to output
frz
-40 dB
Compensator
fpc
fp
-20 dB
1Hz
fzc
20 dB
fz
fc
frz
-20 dB
10Hz
100Hz
1kHz
10kHz
100kHz
Figure 17. QR Flyback Converter Control to Output
Transfer Function Variation for Different Input Voltages
fz
-40 dB
1Hz
10Hz
100Hz
1kHz
10kHz
100kHz
Figure 19. Compensator Design
©2005 Fairchild Semiconductor Corporation
11
AN4146
APPLICATION NOTE
When determining the feedback circuit component, there are
some restrictions as described below:
(a) Design the voltage divider network of R1 and R2 to
provide 2.5V to the reference pin of the KA431. The
relationship between R1 and R2 is given as
2.5 ⋅ R 1
R 2 = -----------------------V o1 – 2.5
(41)
where Vo1 is the reference output voltage.
(b) The capacitor connected to feedback pin (CB) is related
to the shutdown delay time in an overload condition by
T delay = ( V SD – 2.5 ) ⋅ C B ⁄ I delay
(42)
where VSD is the shutdown feedback voltage and Idelay is the
shutdown delay current. Typical values for VSD and Idelay
are 7.5V and 5uA, respectively. In general, a 20 ~ 50 ms
delay is typical for most applications. Because CB also
determines the high frequency pole (wpc) of the compensator
transfer function as shown in equation (40), too large a CB
can limit the control bandwidth by placing wpc at too low a
frequency. Typical value for CB is 10-50nF.
(c) The resistors Rbias and RD used together with the optocoupler H11A817A and the shunt regulator KA431 should
be designed to provide proper operating current for the
KA431 and to guarantee the full swing of the feedback voltage for the FPS device chosen. In general, the minimum
cathode voltage and current for the KA431 are 2.5V and
1mA, respectively. Therefore, Rbias and RD should be
designed to satisfy the following conditions.
V bias – V OP – 2.5
--------------------------------------------- > I FB
RD
V OP
------------- > 1mA
R bias
( 43 )
(44)
where Vbias is the KA431 bias voltage as shown in Figure 16
and VOP is opto-diode forward voltage drop, which is
typically 1V. IFB is the feedback current of FPS, which is
typically 1mA.
12
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
3. Design Example Using FPS Design Assistant
Application
Device
Input Voltage
Output Power
Output Voltage
(Rated Current)
Ripple Spec
Color TV
FSCQ0765RT
85-265Vac
83W
125V (0.4A)
±5%
24V (0.5A)
±5%
18V (0.5A)
±5%
12V (1.0A)
±5%
(60Hz)
FPS Design Assistant for AN4146
Ver 1.00
by H.S. Choi
Blue cells are the input parameters
Red cells are the output parameters
1. Define the system specifications
Minimum Line voltage (V linemin)
Maximum Line voltage (V line
Line frequency (fL)
max
85 V.rms
)
265 V.rms
60 Hz
V o(n)
1st output (Vo1) ; regulated by feedback
2nd output (Vo2)
3rd output (Vo3)
4th output (Vo4)
5th output (Vo5)
125
24
18
12
V
V
V
V
V
Maximum output power (P o) =
83.0 W
Estimated efficiency (E ff)
Maximum input power (P in) =
82 %
101.2 W
Io(n)
0.40
0.50
0.50
1.00
A
A
A
A
A
P o(n)
50
12
9
12
0
W
W
W
W
W
K L(n)
60
14
11
14
0
%
%
%
%
%
- It is assumed that the efficiency is 83% at the minimum input voltage and full load condition.
2. Determine DC link capacitor and DC link voltage range
220 uF
DC link capacitor (CDC)
Minimum DC link voltage (VDC
min
Maximum DC link voltage (VDC
)=
max
91 V
)=
375 V
- Since the maximum input power is 101.2W, the DC link capacitor is set to be 220uF by 2uF/Watt.
3. Determine the reflected output (V RO)
Output voltage reflected to primary (V RO)
Maximum nominal Drain voltage (V ds
nom
)=
126 V
501 V
- VRO is set to be 126V so that Vdsnom should be about 77% of BVdss
©2005 Fairchild Semiconductor Corporation
13
AN4146
APPLICATION NOTE
4. Determine transformer primary side inductance (Lm)
2.3 us
Drain voltage falling time (T F)
Minimum Switching frequency of FPS (f s_min)
24 kHz
Maximum duty cycle (D max) =
Primary side inductance (L m) =
Maximum peak drain current (Ids
RMS drain current (Ids
rms
0.55
514 uH
peak
)=
4.05 A
)=
1.73 A
5. Choose the proper FPS considering the input power and current limit
5.00 A
Typical current limit of FPS (ILIM)
Minimum ILIM considering tolerance
4.40 A
->O.K.
>
4.05 A
- Considering the tolerance of 12%, FSCQ0765RT is chosen, whose pulse-by-pulse current limit is 5A (typical).
6. Determine the proper core and the minimum primary turns
0.30 T
Maximum flux density swing in normal mode (∆
Maximum flux density in transient (Bsat)
0.38 T
Cross sectional area of core (A e)
Minimum primary turns (N p
min
109 mm
)=
-->
Np> 63.69 T
-->
Np> 62.07 T
2
63.7 T
2
- EER3540 core is chosen, whose cross sectional area is 109mm .
7. Determine the number of turns for each output and Vcc drop circuit
Vo2 in standby mode (Vo2stby)
8.0 V
Vo2= 24 V in normal mode
Vcc auxiliary voltage drop ratio (Kdrop) =
Minimum Va in standby mode
Va in normal mode
(Vanormal)
0.37
stby
(Va )
13.0 V
=
37.7 V
# of turns
1.2 V
19.7 =>
20 T
1.2 V
64 =>
64 T
13 T
1.2 V
12.8 =>
10 T
1.2 V
9.7 =>
1.2 V
6.7 =>
7T
0T
V
0.0 =>
64 T > 63.7 T
--->enough turns
3130 nH/T2
1.04337 mm
VF(n)
Winding for Va (37.7V)
Winding for Vo1 (125V)
Winding for Vo2 (24V)
Winding for Vo3 (18V)
Winding for Vo4 (12V)
Winding for Vo5 (V)
Number of turns for primary winding (Np)=
Ungapped AL value (AL)
Gap length (G) ; center pole gap =
14
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
Maximum operating current of FPS (Iop)
MOSFET input capacitance (Ciss)
Breakdown voltage of Vcc zener diode
Current consummed by FPS (Icc) =
Vcc drop resistor (Rcc)
Power dissipation of Rcc =
AN4146
6 mA
1840
18
9.0
1.5
0.3
pF
V
mA
kΩ
W
at
90 kHz
2 kΩ
<
- In standby mode, Vo2 is reduced from 24V to 8V. In order to prevent Vcc under voltage lockout in standby mode, Va in
standby mode is designed as 13V. Then, Va would be 37.7V in normal mode.
-Assuming that the maximum switching frequency is 90kHz, the maximum current consumed by FPS is 9mA. Vcc resistor is
determined as 1.5kΩ.
8. Determine the startup resistor
Maximum Startup current of FPS (Istart)
Startup resistor
Effective Vcc capacitor (Ce)
Maximum dissipation in startup resistor =
Maximum startup time (Tstrmax) =
50
240
20
0.13
3.83
uA
kΩ
uF
W
s
<
616 kΩ
at
at
265 Vac
85 Vac
9. Determine the wire diameter for each winding
Primary winding
Winding for Vcc (37.7V)
Winding for Vo1 (125V / 0.4A)
Winding for Vo2 (24V / 0.5A)
Winding for Vo3 (18V / 0.5A)
Winding for Vo4 (12V / 1A)
Winding for Vo5 (V / A)
Copper area (Ac) =
Fill factor (KF)
Required window area (Awr)
Diameter
0.6
0.3
0.5
0.4
0.4
0.5
Parallel
mm
×
mm
×
mm
×
mm
×
mm
×
mm
×
mm
×
1
1
1
2
2
2
ID(n)rms
1.7
0.1
0.9
1.1
1.1
2.2
#####
A
A
A
A
A
A
A
(A/mm2)
6.1
1.4
4.8
4.5
4.5
5.5
####
40.56 mm2
0.2
202.78 mm2
- For each winding, the diameter of wire is determined so that the current density should be about 5A/mm2
- For EER3540 core, the winding window area is 223mm2. Assuming a fill factor of 0.2, this core is enough to accommodate
the wires.
©2005 Fairchild Semiconductor Corporation
15
AN4146
APPLICATION NOTE
10. Choose the rectifier diode in the secondary side
ID(n)rms
0.10
0.95
1.14
1.12
2.17
#####
VD(n)
Rectifier
Rectifier
Rectifier
Rectifier
Rectifier
Rectifier
diode
diode
diode
diode
diode
diode
for
for
for
for
for
for
Vcc
Vo1
Vo2
Vo3
Vo1
Vo5
(125V / 0.4A)
(24V / 0.5A)
(18V /0.5A)
(12V /1A)
(V /A)
153
500
99
75
51
0
V
V
V
V
V
V
Vcc winding
1N4937
Ultra fast recovery
Vo1 (125V)
EGP20J (600V/2A)
Ultra fast recovery
Vo2 (24V)
EGP20D (200V/2A)
Ultra fast recovery
Vo3 (18V)
EGP20D (200V/2A)
Ultra fast recovery
Vo4 (12V)
EGP20D (200V/2A)
Ultra fast recovery
A
A
A
A
A
A
11. Determine the output capacitor
Output
Output
Output
Output
Output
capacitor
capacitor
capacitor
capacitor
capacitor
for
for
for
for
for
Vo1
Vo2
Vo3
Vo4
Vo5
(125V / 0.4A)
(24V / 0.5A)
(18V / 0.5A)
(12V / 1A)
(V / A)
Co(n)
100
1000
1000
1000
uF
uF
uF
uF
uF
RC(n)
100
100
100
100
Icap(n)
mΩ
0.9
mΩ
1.0
mΩ
1.0
mΩ
1.9
mΩ #####
12. Design the synchronization network
Peak value of Sync voltage (Vsyncpk)
9.0 V
Sync voltage divider resistor (Rsy1)
1500 Ω
Sync voltage divider resistor (Rsy2)
Effective output capacitance of MOSFET
Sync capacitor (Csy)
470 Ω
1.0 nF ( Coss + Cr )
3.9 nF
A
A
A
A
A
ΔVo(n)
0.3
0.3
0.3
0.6
####
V
V
V
V
V
4.6 < Vsyncpk < 12V (VOVP)
- Since the output capacitance of MOSFET is 100pF (typical), external capacitor (Cr) of 1nF is used.
13. Design voltage drop circuit for the burst operation
Vo2 in standby mode (Vo2stby)
8.0 V
Breakdown voltage of zener diode, Dz
5.0 V
- Zener diode with a breakdown voltage of 5.1V is chosen.
16
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
14. Design the feedback control circuit
Control-to-output DC gain =
Control-to-output zero (wz) =
50
100.0 krad/s => fz=
15,924 Hz
Control-to-output RHP zero (wrz)=
136.0 krad/s => frz=
21,650 Hz
Control-to-output pole (wp)=
82 rad/s =>
Voltage divider resistor (R1)
100 ㏀
Voltage divider resistor (R2)=
2.0 ㏀
fp=
FPS
Opto coupler diode resistor (RD)
1㏀
KA431 Bias resistor (Rbias)
47 nF
Feedback Capacitor (CF) =
22 nF
Feedback resistor (RF) =
Current transfer ratio of opto coupler (CTR)
vo1
vo2
vFB
RD
ibias
Rbias
iD
CB
CTR:1
1.2 ㏀
Feeback pin capacitor (CB) =
13 Hz
CF
RF
R1
KA431
R2
39 ㏀
100 %
Feedback integrator gain (wi) =
1273 rad/s =>
f i=
203 Hz
Compensator zero (wzc)=
1166 rad/s =>
fzc=
186 Hz
Compensator pole (wpc)=
7599 rad/s =>
fpc=
1,210 Hz
100
80
60
Gain (dB)
40
20
0
1
-20
-40
10
control-to-output
100
1000
10000
Compens ator
Clos ed loop gain (T)
-60
frequency (Hz)
©2005 Fairchild Semiconductor Corporation
17
AN4146
APPLICATION NOTE
0
1
10
100
1000
10000
-30
Phase (degree)
-60
-90
-120
Control-to-output
-150
Compens ator
Clos ed loop gain (T)
-180
frequency (Hz)
- The control bandwidth (crossover frequency) is about 600Hz with a phase margin of 50 degrees.
18
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
Design Summary
•
•
•
•
•
•
High efficiency (>80% at 85Vac input)
Wider load range through the extended quasi-resonant operation
Low standby mode power consumption (<1W)
Low component count
Enhanced system reliability through various protection functions
Internal soft-start (20ms)
Key Design Notes
• 24V output is designed to drop to around 8V in standby mode
• Zener diode ZD102 is used for a safety test such as UL. When the drain pin and feedback pin are shorted, the zener diode
fails and remains short, which causes the fuse (F1) to pop and prevents explosion of the opto-coupler (IC301). This zener
diode also increases the immunity against line surge.
1. Schematic
T1
EER3540
RT101
5D-9
C102
220uF
400V
R101
120kΩ
0.25W
BD101
BEAD101
R102
120kΩ
0.25W
1
ZD101
18V
1W
Drain
SYNC
3 Vcc IC101
5
FSCQ0765RT
GND
2
C104
10uF
50V
FB
4
C103
47nF
50V
R106 C106
1.5kΩ 10uF
1W 50V
D106
1N4148
R105
470Ω
0.25W
D105
1N4937
1
10
3
11
18V, 0.5A
C210
470pF
1kV
4
12V, 1A
13
D103
1N4937
12
C209
470pF
1kV
R103 6
5.1Ω
0.25W
14
15
16
C105
3.9nF
50V
C207
470pF
1kV
L202
C201 BEAD
100uF
160V
125V, 0.4A
C202
47uF
160V
D203
EGP20D
24V, 0.5A
17
LF101
18
OPT101
817A
C208
470pF
1kV
C203
1000uF
35V
VR201
30kΩ
R201
1kΩ
0.25W
R202
1kΩ R203
0.25W 39kΩ
0.25W
C101
330nF
275VAC
ZD102
12V
1W
C205
1000uF
35V
D202
EGP20J
7
FUSE
250V
3.0A
C204
1000uF
35V
D204
EGP20D
C107
1nF
1kV
R104
1.5kΩ
0.25W
D205
EGP20D
C301
2.2nF
Q201
KA431LZ
C206
22nF
50V
R205
100kΩ
0.25W D201
1N4148
R204
2.0kΩ
0.25W
ZD201
5.1V
0.5W
R208
1kΩ
0.25W
Q202
KSC945
SW201
R207
5.1kΩ
0.25W
R206
10kΩ
0.25W
Figure 20. Schematic of Design Example
©2005 Fairchild Semiconductor Corporation
19
AN4146
APPLICATION NOTE
2. Transformer Specifications
EER3540
N p1
1
18
2
17
Na
3
16
N18V
4
15
5
14
N 24 V
N p2
N 125V/2
N125V/2
Np2
N 125V/2
N12V
13
6
N24V
N 12V
Na
7
12
N125V/2
8
11
Np1
9
10
N 18V
Figure 21. Transformer Schematic Diagram
Winding Specification
No
Pin (s→f)
Wire
φ
0.6 × 1
Turns
Winding Method
32
Center Winding
Np1
1-3
N125V/2
16 - 15
0.5 × 1
32
Center Winding
N24V
18 - 17
0.4φ
×2
13
Center Winding
N12V
12 - 13
0.5 × 2
7
Center Winding
Np2
3-4
0.6 × 1
32
Center Winding
N125V/2
15 - 14
0.5φ
×1
32
Center Winding
N18V
11 - 10
0.4 × 2
10
Center Winding
Na
7-6
20
Center Winding
φ
φ
φ
φ
φ
0.3 × 1
Electrical Characteristics
Inductance
Leakage Inductance
Pin
Specification
1-3
514uH ± 5%
1-3
10uH Max
Remarks
1kHz, 1V
2
nd
all short
Core & Bobbin
Core : EER 3540
Bobbin : EER3540
Ae : 109 mm2
20
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
Experimental Verification
To show the validity of the design procedure presented in
this application note, we have built and tested the converter
in the design example. All the circuit components are used as
designed in the design example. The schematic and
transformer specifications are shown in Figure 20 and 21,
respectively.
The Figure 22 shows the FPS drain current and the DC link
voltage waveforms at the minimum input voltage and full
load condition. As shown, the minimum DC link voltage
(VDCmin) is about 90V, which is the same as the designed
value in STEP-2 of page 13.
Figure 23 shows the FPS drain current and voltage
waveforms at the minimum input voltage and full load
condition. As can be seen, the maximum peak drain current
(Idspeak) is about 3.9A and the minimum switching
frequency (fsmin) is 26kHz. The values in the design are
4.05A for Idspeak and 24kHz for fsmin as can be seen in
STEP-4 of page 14.
Figure 22. Waveforms of Drain Current and DC Link
Voltage at 85Vac and Full load Condition (Time:2ms/div)
Figure 24 shows the FPS drain current and voltage
waveforms at the maximum input voltage and full load
condition. As calculated in STEP-3 of page 13, the nominal
drain voltage is about 500V.
Figures 25 and 26 show the waveforms of Vsync, drain
voltage and drain current at the maximum input voltage and
full load condition. As designed, the MOSFET drain fall
time is 2.3us and the MOSFET is turned on when the drain
voltage reaches its minimum value.
Figure 27 shows the waveforms of Vcc, drain voltage and
drain current. The measured startup time is 2.45s, which is
smaller than the calculated maximum startup time of 3.83s in
STEP-8 of page 15. When the typical value for the startup
current (25us) is used for the equation (19), the typical
startup time is calculated as
T str
max
Figure 23. Waveforms of Drain Current and Voltage
at 85Vac and Full Load Condition (Time : 10us/div)
V start
- = 2.91s
= C e ⋅ -------------------------------------------------avg
max
( I sup
– I start
)
Figure 28 shows the output voltage drop in standby mode.
As designed, the 24V output drops down to 8V. Figure 29
shows the detailed burst mode operation waveforms. Burst
mode operation alternately enables and disables switching of
the MOSFET thereby reducing switching loss in standby
mode.
The Table 4 shows the line regulation of each output.
The Figure 30 shows the measured efficiency at the full load
condition for different input voltages. The minimum
efficiency is about 81% at the minimum input voltage
condition.
Figure 24. Waveforms of Drain Current and Voltage
at 265Vac and Full Load Condition (Time : 5us/div)
©2005 Fairchild Semiconductor Corporation
21
AN4146
Figure 25. Vsync, Vds and Ids Waveforms at 265Vac and
Full Load Condition (Time : 5us/div)
APPLICATION NOTE
Figure 28. Output Voltage Drop in the Standby Mode
Figure 29. Burst Mode Operation
Figure 26. Vsync, Vds and Ids Waveforms at 265Vac and
Full Load Condition (Time : 2us/div)
Input
voltage
Vo1(125V)
Vo2 (24)
Vo3 (18V)
Vo4 (12V)
85Vac
125.3 V
24.25 V
18.88 V
12.85 V
110Vac
125.3 V
24.23 V
18.87 V
12.84V
160Vac
125.3 V
24.20 V
18.87 V
12.82 V
220Vac
125.3V
24.19 V
18.85 V
12.81 V
265Vac
125.3 V
24.18 V
18.85 V
12.79 V
Table 4. Line Regulation of Each Output at Full Load
Condition
Figure 27. Vcc, Vds and Ids Waveforms at 265Vac and
Full Load Condition (Time : 2/div)
22
©2005 Fairchild Semiconductor Corporation
APPLICATION NOTE
AN4146
Efficiency (%)
90
85
80
75
85
115
145
175
205
235
265
Input Voltage (Vac)
Figure 30. Measured Efficiency
©2005 Fairchild Semiconductor Corporation
23
AN4146
APPLICATION NOTE
by Hang-Seok Choi / Ph. D
Power Conversion Team / Fairchild Semiconductor
Phone : +82-32-680-1383 Facsimile : +82-32-680-1317
E-mail : [email protected]
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
CORPROATION. As used herein:
1. 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.
2. 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.
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© 2005 Fairchild Semiconductor Corporation