External-Sync Power Supply with Universal Input Voltage Range for Monitors

AN1080/D
External−Sync Power
Supply with Universal Input
Voltage Range for Monitors
Prepared by: S.K. Tong and K.T. Cheng
http://onsemi.com
APPLICATION NOTE
ABSTRACT
This paper describes the design of a low−cost 90 W
flyback switching power supply for a multi−sync color
monitor. In order to minimize the screen interference from
the switching noise, the power supply can be automatically
synchronized at the fixed frequency of the horizontal
scanning frequency (15 to 32 kHz) of the color monitor. The
line and load regulations of the power supply are excellent.
Also, a new universal input−voltage adaptor enables the
power supply to operate at two input voltage ranges, 90−130
Vac or 180−260 Vac. It can minimize the ripple current
requirement of the input bulk capacitors and the stresses on
the power switch. The design demonstrates how to use
recently introduced components in a low−cost power
supply. The state−of−the−art perforated emitter
epi−collector bipolar power transistor MJE18004 and
opto−isolator MOC8102 are utilized.
due to high efficiency and light weight. However, the
EMI/RFI generated by switching power supplies has
adverse effects on the resolution of high−definition color
monitors (e.g. 800 x 600 or higher). Asynchronous
switching noise beat with the horizontal scanning frequency
of the color monitor, creating undesirable interferences and
jitter on the screen. It affects the horizontal resolution of the
high−definition color monitor because the random pulses
generated by the asynchronous switching operation and also
deflect the electron beams and blur their precisely controlled
positions. Thus, the switching power supply for the
high−definition monitors or TVs must be synchronous with
the horizontal frequency.
Recently, multi−sync color monitors became popular
because they can adapt to several modes of computer
displays. For example, CGA, EGA and VGA display modes
are used in IBM PCs. The three display modes have different
horizontal resolutions and scanning frequencies, ranging
from 15.7 kHz to 31.5 kHz. Hence, the switching power
supply developed in this note can be synchronized to the
horizontal scanning frequencies of the multi−sync color
monitor, as shown in Figure 1. It provides three DC outputs.
The specifications are:
1. INTRODUCTION
As the resolution of modern color display increases, the
power supply for these high−definition monitors become
critical in its features and performance. Nowadays,
switching power supplies replace the linear regulators
MULTI−SYNC SIGNALS FROM COMPUTER (H & V SYNC, RGB SIGNALS)
AC LINE
+5 V
(FOR LOGIC ICs)
POWER SUPPLY
DEVELOPED IN
THIS NOTE.
+12 V
(AUX. POWER)
MULTI−SYNC
VIDEO
PROCESSOR,
RGB DRIVERS
& HV CIRCUIT
R
G
B
HV
HIGH RESOLUTION
MULTI−SYNC
COLOR DISPLAY
FOCUS
−110 V
HV
(MAIN POWER)
EXT.
SYNC
H. SYNC
DC ISOLATION
Figure 1. Block Diagram of Modern Multi−Sync Color Monitor
This document may contain references to devices which are
no longer offered. Please contact your ON Semiconductor
representative for information on possible replacement devices.
 Semiconductor Components Industries, LLC, 2004
April, 2004 − Rev. 1
1
Publication Order Number:
AN1080/D
AN1080/D
Outputs
+110 V 0.7 A
+12 V 0.3 A
+5 V
0.2 A
Others
for HV, RGB drivers and deflection
for auxiliary use
for logic ICs
External synchronization with DC isolation (15 kHz to
32 kHz) which are regarded power supply standards for
modern color monitors. The two low−voltage outputs are
obtained by post−regulators of the +15 V and +8 V inputs.
In Figure 2, the block diagram of the switching power
supply, according to the specifications, is shown. Besides
the input filter, it mainly consists of three parts − the
rectification circuit, the universal input−voltage adaptor and
the 90 W flyback converter.
Inputs
90−130 Vac or 180−260 Vac 50/60 Hz
Power
90 W with overload protection
Conversion Efficiency
Minimum 70% at full load
BRIDGE RECTIFIERS
+VCC
L
90−130 VAC
OR 180−260 VAC
−
+110 V
(0.7 A)
+
INPUT
FILTER
+
Cin
N
−
−
90 W
FLYBACK
CONVERTER
−
TRIAC
+
Cin
−
+15 V
(0.3 A)
+8 V
(0.2 A)
0V
E
UNIVERSAL
INPUT−VOLTAGE
ADAPTOR
(VOLTAGE DOUBLER)
EXT. SYNC
Figure 2. Block Diagram of Switched−Mode Power Supply for Multi−Sync Monitor
2. DESIGN OF THE FLYBACK POWER SUPPLY
The universal input−voltage adaptor can automatically
select the input−voltage range and controls the triac in order
to provide the rectified DC voltage VCC in between 200 to
370 V. In 90−130 V range, the triac is continuously fired and
the whole rectification circuit forms a voltage doubler. In
180−260 V range, the triac turns off and the rectification
circuit works as normal. This design can significantly reduce
the current ripples of the two smoothing capacitors, Cin, and
the switching stresses on the power transistor(s) due to wide
range of VCC. Some previous designs without the universal
adaptor handle the full input−voltage range only by simple
bridge rectification. The current ripple of the smoothing
capacitors are usually several amperes for 90 W power
converters. Furthermore, the output voltage ripple (at VCC)
is generally higher for the same value of smoothing
capacitors at low line.
In section 2, the design of the flyback converter is
reviewed, whereas the design of the universal input−voltage
adaptor is given in section 3. Then, in section 4, the
performance and further improvements of the power supply
are discussed. In the last section, the conclusions include a
summary of the design of the power supply and the future
developments of switching power converters suitable for
multi−sync monitors.
2.1 TOPOLOGY SELECTION
The single−ended discontinuous−mode flyback topology
is selected to perform the major power transfer from the
rectified output (VCC) to the load. Advantages and
disadvantages of this topology are:
Advantages
1. It has smaller transformer size and output choke.
The power density and cost of the power supply
are lowered.
2. Current mode operation is excellent because the
current waveform fed to the current mode
controller is strictly triangular. It can improve the
noise immunity of the current sensing circuit.
3. Single−pole roll−off characteristic of the power
converter simplifies the design of feedback
circuits. [1]
4. Simplified in design if single−ended configuration
is used.
5. Good cross regulation. [1]
http://onsemi.com
2
AN1080/D
Current mode control is employed in this power supply
because:
1. Inherent line ripple rejection ( VO/ VCC = 0).
2. Eliminate the possible double−pole characteristics
in continuous mode. This would cause instability
of the power supply under some critical conditions.
3. Discontinuous mode flyback topology has
excellent current mode operation due to large
current amplitude.
4. Synchronization is easier to implement without
greatly affecting the converter performances and
circuit configuration.
5. Simple and low cost as commercial current mode
controller IC is available.
UC3842A/3843A, current mode control IC, is used in the
power supply to perform the current mode operation. The
feedback from secondary side to primary is through
MOC8102 opto−isolator.
6. The working duty cycle can be greater than 50%.
This is particularly important for multi−sync
monitor power supply.
7. Lower cost than other topologies.
Disadvantages
1. High RMS and peak transformer currents result in
high losses in power switch. windings and voltage
clamp.
2. The large air gap in the flyback transformer causes
higher EMI/RFI and flux fringe.
3. Higher ripple current appearing in output
capacitors produces greater output ripple voltage
which may cause screen interference. The
switching frequency of the power supply is
designed in synchronization with the horizontal
frequency. The adverse effect due to this point
becomes less significant.
4. Transformer and snubber capacitor ring after the
magnetic energy stored in the magnetic core is
completely released. This phenomenon can be
often found in the previous designs.
With the considerations of cost−effectiveness, size, and
cross regulations, flyback topology is selected. It is
particularly suitable for 90 W switching power converter
application. Disadvantages are minimized through careful
design (see later).
2.2 DESIGN OF FLYBACK TRANSFORMER
The lowest value of VCC is assumed to be 200 V, i.e. 50 V
below the rectified low−line peak voltage (180 x 1.414 =
255 V), and the highest value is about 370 V. Therefore, the
flyback converter shown in Figure 3 should operate within
200−370 Vdc. The total power is 90 W, slightly higher than
the sum of all three outputs. The switching frequency is from
15 kHz to 32 kHz with external synchronization.
VCC
FLYBACK TRANSFORMER
VOLTAGE
CLAMP
(Vo)
+110 V
D110
n:1
R2
C2
Lp
Np
Ls (110)
Ns (110)
+
R110
Co 110
0V
D2
R1
D1
RC TURN−OFF
SNUBBER
D15
+15 V
C1
Ls (15)
R15
Co 15
0V
TO CONTROLLER
D8
LA
Ls (8)
+8 V
R8
Is
0V
M1
MTP4N90
+
RA
VDS
−
TO CURRENT
SENSE OF CM
CONTROLLER
(1 V PEAK)
Co 8
Rs
Figure 3. Flyback Converter
(Discontinuous Inductor−Current Mode)
http://onsemi.com
3
AN1080/D
Lp 1.66 mH
If the efficiency is taken into account and it is assumed that
the typical conversion efficiency is about 70%, the total
input power Pin is,
The duty cycle at VCC = 370 V is 0.216 under full−load
condition. It becomes smaller as the load decreases. Also
from (1), at same power level,
Pin 900.7 128.6 W
Then, the following problem is how to determine suitable
primary inductance Lp and maximum working duty cycle D
of the power transistor. Assuming that the primary
inductance and input power are constant,
where
Pin Lp Ipk2 fs2 (Energy law)
(1)
VCC Lp Ipktc (Faradays law)
(2)
Ipk at 32 kHz
Ipk at 15 kHz
Ipk at 32 kHz (0.6847) (3.215) 2.2 A
and Dmax at 32 kHz = 0.4/0.6847 = 0.584
For the flyback converter operating in discontinuous mode
at 32 kHz, the duty cycle with respect to secondary side of
transformer D′ = td/T is set to 0.4, which is slightly less than
(1−0.584) = 0.416, because the remaining switching time is
used to compensate other non−idealities such as leakage
inductances, stray capacitances, finite switching fall and rise
times, etc. To calculate the secondary inductances, the
power relation is used again. If the output power (90 W) was
lumped to +110 V output, from (3), at fs = 32 kHz and
VCC = 200 V,
tc = conduction time of the switch = DT
T = 1/fs = switching period
Hence,
Pin (VCC tc) Ipk fs2 VCC Ipk D2
15
0.6847
32
(3)
If we set D = 0.4 at VCC = 200 V, fs = 15 kHz and
Pin = 128.6 W, we have, from (3), Ipk = 3.215 A.
The current waveform is shown in Figure 4. Put Ipk into
(1) or (2), then the primary inductance is calculated to be,
VDS
A
Vspk
VCC + nVo
C
B
VCC
D
0
td
Is
Rs
ti
tc
t
tspk
Ipk Rs
0
t
Figure 4. Switching Waveforms of Flyback Converter
Po = 90 W = Vo Ipk′ D′/2
where Po = net output power
Vo = output voltage of +110 V
Ipk′ = peak inductor current of +110 V
windings
D′ = td/T = 0.4 (referred to Figure 3)
Hence, Ipk′ = 4.1 A and td = 12.5 s.
Then, substitute Ipk′ into (1) or (2), we have,
Ls(110) = inductance of +110 V winding
= 0.334 mH
And, the inductance of other two windings are,
Ls(15) = Ls(110) (16/111)2 = 6.9 H
Ls(8) = Ls(110) (9/111)2 = 2.2 H
The diode drops of the output rectifiers are taken into
consideration for the two low voltage outputs. The turn ratio
n is equal to,
n NpNs(110) [LpLs(110)]12 2.22
where
http://onsemi.com
4
(4)
Np = number of turns of Lp (primary inductance)
Ns(110) = number of turns of Ls(110)
AN1080/D
Ns(15)
Ns(8)
NA
NA
Two magnetic cores are found to be suitable for the
implementation of the flyback transformer. They are EE40
core and ETD39 core. The spacing factors are just around
0.4 for both. The maximum working flux density Bmax is set
to 0.25T. For EE40 core, the effective cross−sectional area
Ae is 130.65 mm2.
Np
= (VCC tc)/(Bmax Ae) = (200 x 0.4 x 66.67)/
(0.25 x 130.65) = 163
Ns(110) = 163/2.22 = 73
Ns(15) = 11
Ns(8)
= 6
where Ns(15) = number of turns of Ls(15), and
Ns(8) = number of turns of Ls(8)
For ETD39 core, Ae is 124.15 mm2. The required wire
gauges of each winding are also listed in the following. Irms
value is equal to (D/3)1/2 Ipk. At fs = 15 kHz, Ipk′ = 6.0 A and
td = 18.2 s, hence,
D′
= 18.2/66.67 = 0.273
Np
= (200 x 0.4 x 66.67)/(0.25 x 124.15)
= 172 Irms = (0.4/3)1/2 x 3.215
= 1.17 A (AWG #23)
Ns(110) = 77 Irms = (0.273/3)1/2 x 2 x 0.7/0.273
= 1.55 A (AWG #22)
=
=
=
=
11 Irms = 0.66 A (AMG #26)
7
Irms = 0.44 A (AWG #26)
18 for MTP4N90 and
13 for MJE18004 (see later)
The ETD39 core will be used in the power supply due to its
round bobbin shape and efficient AP product [1]. The
temperature rise of the transformer core is about 30°C. To
obtain an approximate length of air gap Ig, the calculation is
based on:
1. The reluctance of the magnetic core is negligible.
2. The air gap is in the middle of the three limbs, all
equal to Ig.
3. The relative permeability r is constant and equals
2000 for TDK H7C4 material.
Hence, Lp o Np2 Ae(2Ig)
or Ig 1.4 mm
(5)
But, a 4 mm air gap is used practically to obtain the required
inductance due to flux fringe and other non−idealities. The
transformer construction diagram is shown in Figure 10.
To meet with the world safety regulations (e.g. VDE, UL,
CSA, etc.) for the transformer, readers should refer to
corresponding regulation books and (4).
+20 V (START−UP)
7
VCC
1N4148
I1
1 nF
SYNC
Vp
VSYNC
0.1 F
VCT
4 RT/CT
Vo
IC
Rc
3−5 V
1N4747A
UC3842A
10
Q2
2N3906
1k
8 V
ref
Qop
MOC8102
0
Ve
CT
1k
CS 3
12
2
COMP
1
5
RopE
Rs
0.28
470 pF
INV
10 k
M1
MTP4N90
10
6
GND
10 k
(Vo)
+110
1
+8 V
RopD
1
Rx
IF
−
Cf
+
RB1
RE
I1
Q3
2N3906
Dop
MOC8102
RB2
Ry
1′
TL431CLP
0.1 F
1′
CONSTANT CURRENT SOURCE
0V
Figure 5. Current Mode Controller and Sync Circuit for MTP4N90 (MOSFET)
http://onsemi.com
5
AN1080/D
Since the maximum inductor current Ipk(110) at 110 V rail
is 5.13 A, and the output ripple voltage is maximum at
fs = 15 kHz,
+10 V
1N4740A
7
VCC
td 0.273 66.67 s 18.2 s
ti idle time (as shown in Figure 4)
T tc td 21.8 s
IC
If the output ripple voltage is set to 1% of Vo, i.e. 1.0 V,
Vo
6
+
Vo 1 0.5 5.13 18.2Co(110)
Q1
MJE18004
CB
IB
Co(110) 46.68 F
−
However, the output ripple current (1.55 A) is so large that
two or more capacitors are needed to be connected in parallel
in order to lower their individual ripple currents and the
additional output ripple caused by ESR and ESL of the
output capacitors. As a result, two of 22 F to 33 F
capacitors each with maximum ripple current of 0.8 A are
used in the power supply. Their maximum working voltage
is 160 Vdc.
The dummy resistors R110, R15 and R8 are used to
maintain minimum load currents of the three outputs. R110
is set to 5.6 k and dissipates 2.0 W.
LC filter is cascaded with each output to lower the output
ripple voltage. They are shown in Figure 14. The corner
frequency for that at +110 V output is about 6.2 kHz and the
approximate output ripple voltage is,
UC3843A
CS
1k
3
RS
0.28
470 pF
OTHERS ARE SAME AS IN FIGURE 5
Figure 6. Current Mode Controller and Sync Circuit
for MJE18004 (Bipolar Junction Transistor)
2.3 DESIGN OF OUTPUT CIRCUITS
The following paragraphs describe how to determine the
values of output capacitors and to select output rectifiers as
shown in Figure 3. The ultrafast recovery rectifier MUR140
is chosen for D110 due to its fast recovery time (75 ns),
reliability and low cost. The maximum reverse voltage of
this diode is 110 + 370/n = 277 V, so 400 V device is
selected. The average current of D110 is 0.7 A maximum.
D15 and D8 are schottky diodes, MBR160 and 1N5819
respectively, because Schottky rectifiers are more suitable
for low voltage outputs.
During td, the output voltage rises from its minimum value
to its peak.
Vo 1
Co(110)
1[1 (156.2)4]12 0.1684 V (peak to peak)
2.4 SELECTION OF SWITCHING TRANSISTOR,
SNUBBERS AND VOLTAGE CLAMP
Two types of power switches are considered for the
flyback power supply. They are TMOS power FETs, and the
state−of−the−art perforated emitter bipolar transistors
introduced in 1988. The series TMOS FETs simplifies the
design of driving circuits and provides extremely fast
switching transitions. These MOSFETs can operate in the
MHz range. In this power supply, although the switching
frequency is relatively low, it still provides several
advantages such as simple drive circuit, less supply current
for the MOS driver, fast switching times which result in less
energy loss at switching transitions, and hence a smaller
value of snubber capacitor C1 (1000 pF) is required. Since
the maximum drain voltage of M1 is near 850 V (see later),
and the peak drain current is 3.2 A, MTP4N90 is selected for
M1, with 4.0 rDS(on) [5]. Thus, the approximate
conduction loss in M1 is [(0.4/3)1/2 x 3.2]2 x 4 = 5.5 W at
fs = 15 kHz, VCC = 200 V and full load. The power
dissipation is well below the maximum power that can be
dissipated by the device.
To demonstrate the switching improvement of the newly
introduced perforated−emitter BJT family, the design of the
flyback power supply also provides an alternative for a new
device. MJE18004 is chosen for M1 because its breakdown
voltage V(BR)CES is above 1000 V, the continuous collector
current is 5.0 A and its switching times are excellent
for switchers below 70 kHz (tfi = 70 ns and tsi = 0.6 s at
IC = 2.0 A, Ib1 = 250 mA and VBE(off) = −5.0 V) [6]. Another
ot Ipk(110) Ipk(110)
t dt Vo(min)
td
Vo(min)
Ipk(110)
1
I
t
t2
2 td
Co(110) pk(110)
It consists of a linearly increasing term and a convex
parabolic curve. Thus,
Vo(max) Ipk(110)
1
I
t
t2
2 td
Co(110) pk(110)
Ipk(110) td
t td Vo(min) 1
Vo(min)
2 Co(110)
and output ripple voltage is,
Ipk(110) td
Vo Vo(max) Vo(min) 1
2 Co(110)
http://onsemi.com
6
AN1080/D
Thus,
two important features are its lower cost and power loss than
the MOSFET. Its performance is quite different from the
previous bipolar transistors. For the tripple diffused power
transistors, which are still widely used in Japan (e.g.
BU508), these devices face three major problems: long
switching times, dispersion of device characteristics, and
hFE degradations after several thousand operating hours.
The epicollector technologies which MJE18004 uses,
improve the switching speed and control of device
characteristics. Since the emitter of BJT affects the device
performance very much, various emitter structures have
evolved. With SWITCHMODE III, with hollow emitter
structure, the speed and RBSOA improvements are
accompanied by the increased die size (about 125% of
standard technology). For the perforated emitter structure,
the emitter is interleaved by the base, thus, this increases the
emitter perimeter to area ratio. That means higher speed
switching transistor can be fabricated in a smaller die size.
It improves the operating frequencies and lowers the cost.
In Figure 3, a dissipated RC turn−off snubber is shown. Its
function is to reduce the power loss of the transistor M1 at
turn−off by limiting the rising slope of VDS. It is also called
the dV/dt limiter. When M1 turns off, the inductor current
begins to commutate from the power switch to the snubber
capacitor C1 through the diode D1 within tfi. The snubber
capacitor slows down the increasing rate of VDS, so the VDS
Is product area (during cross−over time) can be limited to
certain acceptable value. This snubber is particularly
important for the old and slow bipolar transistors. With the
advents of TMOS FETs and perforated emitter bipolar
power transistors, the snubber capacitance can be chosen to
be as low as 1000 pF. As the current fall−time of power
transistor given in data sheets includes the effect of transistor
output capacitance (Coss), it is difficult to calculate an
optimum value of C1 which requires the fall−time
information without the effect of Coss [2],[3].
Theoretically, the charge stored in C1 at turn−off should
be completely dissipated in R1 when the switch M1 turns on.
However, in the discontinuous−mode flyback power supply,
it cannot always have that because severe stray oscillation
which is caused by Lp and C1 occurs when the energy stored
in the magnetic core is completely discharged to the loads.
This phenomenon is often seen in previous designs.
Therefore, the resistor R1 has another function that it acts as
a damper for the Lp−C1 resonant circuit. Then, a
compromise between the two opposing operations should be
considered. For a series LCR resonant circuit, the damping
ratio can be used to control the envelope of the damped
sinusoidal oscillation. From any standard text on linear
control systems,
Damping ratio R1
2
CLp1
1 0.5 R1 (1000p1.66m)12 or R1 2.58 k
In practice, a smaller value of R1 will increase the discharge
rate of C1 at turn−on. So, a standard value of 2.4 k is
used. The maximum power dissipation of R1 is equal to
C1 VCC(max)2 fs(max)/2 = 2.2 W, for complete discharge of
C1 during the conduction time of M1. But, due to the stray
oscillation caused by C1, Lp and R1, the resistor R1 should
have a power dissipation of 3.0 W.
Another RC snubber of 180 and 470 pF used in the
power supply is to damp the stray oscillation caused by the
junction capacitance of D110 and the leakage inductance [2].
In Figure 4, a high voltage spike (point A) in VDS is
caused by the discharge of leakage magnetic energy in the
transformer. The time between A and B represents this
period. Since the discontinuous−mode flyback converter has
greater peak inductor current, the effect of leakage
inductance can be the dominant source of power loss. As
shown in Figure 3, a voltage clamp for the leakage
inductance limits the spike voltage to a designated value,
Vspk. In [3], it points out that voltage clamp is more effective
than shunt snubber in limiting the spike voltage. It is actually
a boost converter with an input voltage of approximately
nVo and the leakage inductance as switching inductor. From
power relation, neglecting the minor effect of the shunt RC
snubber,
L3 Ipk2 fs2 nVo tspk fs Ipk2
(Vspk VCC)2R2 for C2R2 1fs
and from Faraday’s law,
Ipk L3(Vspk VCC nVo) tspk
where L3 = leakage inductance in primary side. On
substitution,
nVo
1 L I 2f 1
2 3 pk s
Vspk VCC nVo
(Vspk VCC)2
(8)
R2
Note that although the above result is similar to that shown
in [3], the leakage inductance which stores energy to be
dissipated is merely L3, and the leakage inductances in the
secondary side only come into effect between point A and B
in Figure 4. The power loss due to L3 is essentially the same
for all switching frequencies because Ipk2 fs is constant for
same power level and VCC. At 15 kHz, the primary
inductance was measured to be 0.15 mH with major
secondary winding (110 V output) short−circuited at zero
bias current. It is about one−tenth of Lp. So, L3 is equal to
0.15 mH/2 = 75 H. If the peak voltage of M1 is limited to
850 V for MTP4N90, then,
(7)
0.5 75 3.22 15 k [1 244(850 370 244)]
(850 370)2R2
If the damping ratio is set to 1, no undershoot below VCC will
result.
R2 19.67 k (11.7 W)
http://onsemi.com
7
AN1080/D
gate−source short−circuited. The regulated output current is
actually its saturation current IDSS at pinch−off.
The external synchronization is achieved by the one−shot
triggering circuit built around Q2. It is active once when the
falling edge of sync pulse appears. Then, a single high pulse
of 2.0 to 3.0 s charges the timing capacitor CT through the
charging resistor RC at a very fast rate (about 50−100 times
the normal rate). The value of RC can be calculated by,
For MJE18004, Vspk is limited to 950 V and R2 = 33.8 k
(9.95 W). Practical values of 20 k (10 W) and 33 k
(10 W) are used for MTP4N90 and MJE18004, respectively.
2.5 CONTROL, BASE DRIVE AND EXTERNAL SYNC
CIRCUITS
The current mode control IC selected is the UC3842A or
UC3843A. For MOSFET, MTP4N90, UC3842A is used to
provide sufficient gate voltage because it is operated at 20 V.
The circuit configuration is shown in Figure 6. The
maximum current sense (CS) voltage on pin 3 of UC3842A
is 0.9 V (minimum) [9]. Hence, the current sensing resistor
Rs is 0.9/3.2 = 0.28 with power dissipation less than
0.5 W. Three 1.0 (1/4 W) and one 2.2 (1/4 W) are
connected in parallel to obtain the required resistance. An
RC filter (1.0 k and 470 pF) is added to “kill’’ the voltage
spikes. The corner frequency of the filter is 339 kHz.
To be able to synchronize externally, the power supply
must have a free−running frequency below 15 kHz. For the
simplification of the design and operation of the oscillation
in UC3842A, a constant current source I1 is used instead of
a resistor RT. Since the internal current source I2 in
UC3842A provides a discharging current of 8.4 mA, the
dead time t2 and switching frequency can be determined as
follows.
I1 CT 1.6 and I2 I1 CT 1.6
t1
t2
t1
I2 I1
t2
I1
T t1 t2 1fs
(5 2.8 0.5) (100 0.756) 47 The minimum voltage drop on RC is approximately
5 − 2.8 − 0.5 = 1.7 V because VCT swings between 1.2 to
2.8 V, with respect to ground [9], and the saturation voltage
of Q2 is about 0.5 V. The choices of the input capacitance
and BE resistance can vary the pulse period. The
anti−parallel BE diode, 1N4148 is to prevent the BE junction
from possible avalanche breakdown if the amplitude of
Vsync is above 5.0 V.
It is also possible to combine the sync circuit into the
constant current source by injecting the sync signal into the
base of the current source transistor.
The feedback scheme is selected as follows. A voltage
reference with comparator (linear error amplifier) TL431
detects and amplifies the error signal, and drives the LED
of the optocoupler MOC8102. The gain of the error
amplifier (EA) in UC3842A is set to unity for better noise
immunity and stability. Since the output voltage of the error
amplifier is from 1.4 (two diode drops) to 4.1 V (1.4 + 0.3
x 3) typically [9], and Ve is equal to (5 − output voltage of
EA), the voltage Ve across RopE is from 0.9 to 3.6 V.
In the past optocouplers have suffered from current
transfer ratio (CTR) degradation. The main cause for CTR
degradation is the reduction in efficiency of the LED within
the optocoupler due to the increase in space−charge
recombination within the diode. Past industry LED burn−in
data under accelerated conditions indicated that a 15% to
20% degradation after 1000 hours was not unusual. Of even
more concern was the fact that the population also contained
“fliers’’ units through infant mortality mechanisms
eventually exhibited degradations approximately 50%. A
typical percentage degradation is 40% after 105 hours
normal operation at If = 25 mA. In 1987, Motorola’s
Optoelectronics Operation decided to resolve the
industry−wide problem of LED light output degradation.
They concentrated their efforts to improve and control
certain critical LED wafer processing steps and eventually,
5000 hours of accelerated stress burn−in testing shows zero
degradation. This means that low degradation
characteristics are now achievable not only on an average
(mean) basis, but also that “fliers’’ can be eliminated.
Therefore, the opto−isolator can be regarded as a low−cost,
reliable, simple but high performance component to be used
in future power supplies. Besides the zero degradation of
CTR, the new MOC810X series optocoupler that are
specifically designed for switching power supplies provides
two additional features. Their specifications include tightly
controlled window values of CTR. Also, each device’s
(I2 I1)
(9)
The hysteresis voltage of the oscillator is 1.6 V. The time
periods t1 and t2 are the rise and fall times of the triangular
waveforms (VCT). Due to the effect of leakage inductance,
other parasitics and snubber circuits at fs = 32 kHz, the dead
time t2 is set to 6−8 s. Then, if the free−running frequency
is assumed to be 12.5 kHz, t1/T = 0.91,
or
I2 I1
0.91
1 0.91
I1
I1 0.756 mA and CT 0.036 F
The constant current source I1 is implemented using a single
PNP transistor Q3. The current gain of 2N3906 is about 200.
The current through RB1 and RB2 is assumed to be 20 x IB3,
and the emitter voltage is set to 4.0 V since the peak voltage
of VCT is 3.0 V. Then, we have,
RE 1I1 1.32 k
and IB3 0.756 mA200 4 A.
Since VB3 5 1 0.7 3.3 V,
5 RB2(RB1 RB2) 3.3
RB1RB2 0.515
RB1 20 k and RB2 39 k
The practical values for RE and CT are 1.2 k and 39 nF, and
the free−running switching frequency is around 13 kHz. The
constant current source I1 can be directly replaced by current
regulating diode (1N5294), which is a JFET with
http://onsemi.com
8
AN1080/D
transformer winding NA through DA and RA. A zener diode
of appropriate voltage rating is used to regulate the supply
voltage for IC1. For UC3842A and MTP4N90, the supply
voltage is 20 V and the total supply current is about 20 to
50 mA. Thus, NA is chosen to be 18 turns to provide an extra
5.0 V for regulation. RA is set to 47 . The smoothing
capacitor CA is for filtering, but an unobvious effect of its
capacitance is on the start−up transients of the primary
control circuitry. Since the current mode controller
UC3842A/3843A has a voltage hysteresis in undervolt
lockout, the capacitance of CA must be large enough to
maintain the initial switching operations, i.e. the supply
voltage must be kept above the lower threshold point, before
the power can be fed from the transformer. The practical
values of CA are 3.3 F for UC3842A and 2200 F for
UC3843A. The much larger capacitance used in the latter
case is due to the small hysteresis of the supply voltage of
UC3843A and the relatively large base current. NA and RA
for MJE18004 are 13 turns and 10 (1.0 W) respectively.
It is also possible to minimize the value of CA to several
F and to avoid long start time using a “kick’’ starter
described in previous Application Notes. The “kick’’ starter
is actually an NPN high voltage, small power transistor
connected as a simple voltage regulator for the control
circuit. The reference voltage is derived from a zener diode
biased by a resistor connected across +VCC and the base of
the “kick’’ transistor. Its emitter is regarded as output of the
regulator and its collector can be tied to +VCC. When the
power supply is connected to AC mains, the “kick’’ starter
charges CA above the start−up threshold of
UC3842A/3843A quickly. Then, the power for the control
circuitry is fed from the auxiliary windings (NA), which
raises the DC voltage at the emitter of the “kick’’ transistor,
and the transistor will be turned off. Thus, the “kick’’
transistor conducts for a very short time and dissipates very
small power.
internal base connection has been eliminated, effectively
minimizing the noise susceptibility problem. Noise is
further minimized by coplanar die placement, which puts
the LED and phototransistor end−to−end, rather than one
above the other. The result is a mere 0.2 pF coupled
capacitance, which minimizes the amount of capacitively
coupled noise that is injected by the optoisolator.
MOC8102 is selected due to its moderate CTR (from 0.73
to 1.17 at IF = 10 mA) [11]. Then, two extreme cases are
considered. For the lowest If delivered by TL431, it should
provide sufficient coupled current to develop a minimum
voltage of 0.9 V on RopE. The operating current range
of If is chosen to be 0.5 to 20 mA. For the highest limit
of the selected If range, i.e. 20 mA, the value of RopE is
3.6 V/0.5 x 20 mA) = 360 , if CTR is at the lowest value,
i.e. 0.5 approximately. Then, nearly whole ranges of CTR
and If are covered by the design with RopE equal to 360 .
The practical value for RopE is selected to be 390 For the
determination of RopD, the maximum LED current is
considered. Thus, the value of RopD is (8−1) V/20 mA =
350 . A 330 resistor is used in practice.
The feedback point is directly taken from the positive
terminal of the output capacitors Co(110). This point must be
placed before the output LC filter because the filter forms an
additional double−pole in the feedback loop. Since the
internal reference voltage of TL431 is 2.5 V, the values of Rx
and Ry (the voltage divider) are chosen to be Rx = 142 k
and Ry = 3.3 k because, 110 Ry/(Rx + Ry) = 2.5 or
Rx/Ry = 43.
The gate drive circuit consists of a series 10 resistor to
minimize the “gate ring’’ problem. But for MJE18004, the
base drive circuit is not as simple as that for MOSFET. It is
shown in Figure 6. The supply voltage of the current mode
controller is lowered to 10 V in order to minimize the power
loss in base drive circuit, and meanwhile, UC3843A is used
instead of UC3842A, which has a lower ON threshold of
supply voltage. Other functions are identical to UC3842A.
The typical hFE value for MJE18004 is 14 [6], and thus, it is
assumed that the minimum hFE value is 10 partly because of
the tight control in manufacture. Then, the minimum base
current IB is 3.2/10 = 0.32 A to maintain transistor saturation
at full load. A slightly larger base current of 0.35 A is used
practically. From [9], the voltage drop on the source output
transistor of UC3843A is about 2.0 V at an output current of
0.35 A. And the value of VBE(sat) of MJE18004 is 0.95 V [6].
Therefore, the value of base resistor RB is,
RB (10 0.95 2)0.35 20 2.6 CLOSING THE FEEDBACK LOOP
After determination of almost all the component values
and configurations for the flyback power supply, the last but
not the least piece to design is the feedback loop. Figure 7
shows the gain−block diagram of the flyback power supply.
The input of the system is the internal reference voltage in
the TL431, which is 2.5 V 1%, and is compared to the
feedback signal. The H−block is purely a voltage divider
formed by Rx and Ry, thus the gain value in this block is
3.3/(142 + 3.3) = 0.0227 = Ho. The difference or error signal
is then amplified by the error amplifier in TL431, which is
compensated externally. The compensation network is
chosen to consist of an integrating capacitor Cf and a resistor
Rf. Thus, we have,
(1.2 W)
The base drive capacitor CB can be determined by
1/(2CBRB) fs(min)/2, i.e. CB 1.0 F. Note that the BE
junction of MJE18004 will not have avalanche breakdown
because the breakdown voltage of BE junction is about
9.0 V. Other optimum base drive circuits can be found in [7]
(e.g., how to use base inductor to improve the turn−off
operation of power transistor).
As shown in Figures 3 and 5, the primary control circuitry
is self−supplied. The required power is delivered from the
A 1
sCfRf
where
http://onsemi.com
9
(10)
s = Laplace transform operator (jw for sinusoidal
analysis)
Rf = RxRy/(Rx + Ry) = 3.23 k
AN1080/D
FORWARD GAIN BLOCK (G)
ERROR AMP.
IN TL431
Vref
+
+2.5 V
A 1
s Cf Rf
OPTOCOUPLER
+
CTR
= 1 (APPROX)
+
+
−
If
1/RopD
= 3.03 mS
+
UC3842A/3843A
INTERNAL
DIVIDER
9
111 Ho
B = −3.7 V
(DC OFFSET)
Ic
Vs
−1.3
Vc
1/RS
= 3.6
RopE
= 390 FLYBACK POWER XFORMER
Ipk
Lp fs RL
2
= 163/
(1 + s/wp)
1 swp
fs = 32 kHz
RL = 1 k wp = 13.8 rad/s
VOLTAGE DIVIDER (Rx & Ry)
Vo
Ho = 0.0227
Figure 7. Approximate DC and Low Frequency AC Model of the Flyback Power Supply
The capacitance value of Cf can be determined for overall
stability of the power supply once when the forward gain G
is known under the worst condition.
The low frequency AC model for the discontinuous mode
current−injected flyback converter consists of a DC gain
block cascaded with a single−pole roll−off network which
has a pole frequency at 1/(CoRL), where Co is the total
output capacitance and RL is the total load resistance at Vo
[1]. The equivalent maximum load resistance RL(max) is
approximated by experimental measurements at no load,
fs = 32 kHz and VCC = 200 V (for MTP4N90). The input
current was measured to be 0.06 A and thus,
The forward gain block G is subdivided into its individual
elemental blocks in Figure 7. They are the resistor RopD
which converts the output voltage of TL431 into the diode
current for the LED of MOC8102, the non−linear CTR (0.65
to 4.5 from data sheet), the resistor RopE which generates a
voltage Ve from the coupled current IC, the internal
one−third divider of UC3842A/3843A (the minus sign is
due to the inverting configuration of the op amp), the current
sensing resistor Rs which relates VC to Ipk, and finally, the
gain of the power stage which includes the signal pole. The
DC gain of the power stage can be directly derived from the
power relation.
RL(max) 1102(200 0.06) 1 k
Vo2
1 Lp Ipk2 fs
2
RL
For the equivalent total output capacitance (for
MTP4N90), the capacitances at three output circuits are
lumped to +110 V output, and by charge relation,
or
Vo
Ipk
Co [(110 V) (66 F) (15 V) (330 F) (8 V)
(470 )]110 V 145 F
Thus,
Go Hence, the lowest corner frequency fp of the flyback power
supply is approximately 2.2 Hz. If the ESR and ESL of the
output capacitors are neglected, the G−block has a transfer
function [1] as,
G Go(1 sWp)
Lp R2L fs
(RopERopD)
3 Rs
(CTR)
RL Lp2 fs
(12)
The value of DC gain Go can be determined analytically by
substituting parameters under worst case, i.e. fs = 32 kHz
and RL = 1.0 k (including +8.0 V and +15 V rails), when
the value of Go is highest. On substituting the known
parameters,
(11)
where Wp = 2fp = 13.8 rad/s.
http://onsemi.com
10
AN1080/D
RopE 390 RopD 330 CTR 1 (for MOC8102)
Rs 0.28 that can be varied, i.e. Cf, and only one optimum condition
(either gain or phase) can be satisfied, we set the minimum
phase of the loop gain to −120° to guarantee the relative
stability. That means Wf should be placed 30/45 = 0.667
decade beyond Wp or,
Lp 1.66 mH
we have,
|Go| 229 or 47.2 dB
It is observed that a local feedback occurs in the TL431
output circuit and the LED of the optocoupler. Its end effects
are:
1. Loop−gain enhancement by the additional
block connected in parallel with A−block, i.e.
9/(111 Ho) = 3.57.
2. A proportional−integral (PI) controller resulted,
instead of a pure integrator.
The overall gain (transconductance) of the feedback error
amplifier can be derived as follows.
iF Vo (9111) Vo Ho A
[9(111 Ho) A] Ho Vo
or
Wf 100.667 Wp
4.64 Wp 64 rads
because the down slope of the phase of the flyback converter
gain is −45°/decade and the PI controller has an initial phase
shift of −90°. Then,
Cf 1[(3.23 k) (3.57) (64)] 1.355 F
A practical value of 1.5 F is used. Plots for the overall loop
gain of the power supply at fs = 32 kHz and minimum load
is shown in Figure 8 with the following equations.
9
1 206.4 3.57
jw
sCfRf 111 Ho
where Go 229
Go
G
Wp 13.8
1 sWp
A (f) (13)
iF(Ho Vo) 9(111 Ho) A
where
vo = AC component of Vo
iF = AC component of IF (LED current)
To simulate the equation (13), an additional block consisting
of 9/(111 Ho) only is placed in Figure 7. The zero frequency
of the error amplifier is,
wf 1(3.57 CfRf)
Ho 0.0227
Gain (f) = 0.2 log10 |A′ (f) x G x Ho|
Phase (f) = Arg[A′ (f) x G x I Ho]
The unity gain bandwidth is about 40 Hz (at fT) and the
phase margin is about 80°. But, the dominant value in the
phase plot is its lowest value of −128° at wf, where the gain
is greater than 0 dB. It determines nearly all transient load
responses.
(14)
when |A| = 9/(111 Ho).
After knowing all equivalent AC gains of the converter
circuit, we can determine the value of Cf for optimum circuit
dynamic performance. Since there is merely one parameter
100
−90
fp = 2.2 Hz
ff = 10 Hz
fT = 40 Hz
80
PHASE (f) (DEG.)
GAIN (f) (dB)
60
40
20
0
−105
−120
−20
−40
−135
0.01
0.1
1
10
100
1000
0.01
f (k)
0.1
1
10
f (k)
Figure 8. Bode Plot of the Flyback Converter at fs = 32 kHz and No Load
http://onsemi.com
11
100
1000
AN1080/D
2.7 OTHER OPTIONS
in secondary output(s). Shutdown or foldback signal(s) can
be fed to the UC3842A/3843A by an optocoupler.
To improve and control the start−up transients, a soft−start
circuit may be added to the current mode controller. Typical
example can be found in [9].
Under normal circumstances, the output voltage should
not exceed 150 V. But, as protection for the monitor circuits
(it would generate X−ray if extremely high anode voltage
appears), an optional high voltage zener diode 1N5953A
(1.0 W) is connected across the 110 V output rail. If
abnormally high voltage (150 V) continuously appears on
this rail, the zener diode will be zapped to form a permanent
short−circuit. Other better OVP circuits such as SCR
crowbar circuit and 0 V shutdown circuit can be used with
higher unit cost.
Another option which may be required in the power
supply is short−circuit (not just overload) protection. Since
the flyback power converter is operated with current mode
control, it is inherently over−power protected. But, if the
outputs are short−circuited, maximum power will be
delivered to the low voltages with high output currents.
Then, the output rectifiers and windings are likely to be
damaged. Short−circuit protection is generally best installed
3. UNIVERSAL INPUT VOLTAGE ADAPTOR
The universal input voltage adaptor is used with bridge
rectification circuit to provide a rather narrow range of
rectified DC output voltage at either low or high range of
input voltage, i.e. 90−130 Vac or 180−260 Vac. A simplified
circuit block diagram has been shown in Figure 2, and the
detailed circuits are shown in Figures 9 and 10. The voltage
range selection is performed by an overvoltage detector and
the adaptor is supplied from a charge pump circuit. At low
range, the triac is fired continuously by the adaptor, and a
voltage doubler is formed, while simple bridge rectification
is retained at high range. The rectified output voltage (VCC)
range is from 200 to 370 Vdc.
+VCC
4 x 1N5398
Cin
+
−
47 k
1W
1N5956A
39 k
1W
1N5956A
L
5011
Cin
90−130 VAC
OR 180−260 VAC
1N4001
MT1
− G
CG
−
N
C
10 k
1k
T2
MCR102
1
1k
4K7
2M2
5%
MC3423P
3
100 p
30 k
1%
MT2
IG
8
1N4735A
+
−
T1
MAC229A8
10
100
F
25 V
+
+
6.2 V
−
4
2
5
7
50 nF
1N4148
1N4001
560 k
Figure 9. Negative Gate (Triac) Current − Preferred
http://onsemi.com
12
START−UP
AN1080/D
+VCC
4 x 1N5398
Cin
+
−
47 k
1W
1N5956A
39 k
1W
1N5956A
L
5011
Cin
90−130 VAC
OR 180−260 VAC
+
−
10
N
1N4001
START−UP
C
1
1k
8
1N4735A
100
F
25 V
10 k
T2
MCR102
+
4K7
2M2
5%
MC3423P
3
100 p
−
+
6.2 V
−
4
2
30 k
1%
CG
5
+
7
50 nF
1N4148
1N4001
IG
−
560 k 1 k
T1
MAC229A8
Figure 10. Positive Gate (Triac) Current
Pin 12 (Cin2) [VCC(pk)2 VCC(min)2] (2fin)
3.1 ADVANTAGES OF USING UNIVERSAL
INPUT VOLTAGE ADAPTOR
or
Three advantages are gained by using the universal input
voltage adaptor. They are:
1. Smaller ripple current in the smoothing bulk
capacitors for fixed output power.
2. Less output ripple voltage at the rectified DC
output (VCC) at constant output power.
3. Greatly reducing the stresses (voltage and current)
on the power switch of the flyback converter for
constant output voltage (Vo).
Cin 2 Pin
1
2
VCC(pk) VCC(min)2 fin
(16)
and VCC = VCC(pk) − VCC(min)
where VCC(pk) = peak voltage at VCC = 1.414 x input
voltage (rms)
VCC(min) = lowest voltage at VCC
fin
= frequency of input voltage
For the worst case, VCC(pk) = 180 x 1.414 = 255 V,
VCC(min) = 200 V, Pin = 128.6 W and fin = 50 Hz since the
lowest working voltage of the flyback power supply is
200 V, and the frequency of input voltage is from 50 Hz to
60 Hz. Therefore,
3.2 DETAILS OF CIRCUIT DESIGN
To select a suitable capacitance for the input bulk
capacitors Cin, the ripple voltage at VCC is considered.
Sketches of voltage and current ripples are shown in
Figures 11 and 12 for the following analysis. Figure 11 is for
normal bridge rectification, while Figure 12 is for voltage
doubler.
For simple bridge rectification, the ripple voltage VCC is
related to the capacitance of Cin as follows, from the power
relation. It applies provided that ta is much less T/2,
Cin 205.6 F
The time period ta, the conduction time of the bridge
rectifiers, is given by,
http://onsemi.com
13
AN1080/D
C dVCC
Icap(pk) in
2
dt
VCC(pk)
fin Cin VCC(pk)2 VCC(min)2
VCC(min)
CAPACITOR
VOLTAGE
VCC
0
(18)
5.5 A for the practical value of Cin equal to
220 F
ta
Thus,
Icap(rms) Icap(pk)
ta
D3 Icap(pk) 3T2
(19)
1.47 A
T
assuming that the AC component contributed by the
switching operation of the flyback converter is negligible.
This assumption holds because the high−frequency
(switching frequency) ripple current is filtered by the
additional small−valued capacitor (0.1 F) connected
across VCC.
With reference to Figure 12, for the voltage doubler, the
two capacitors are alternatively charged to peak line voltage.
Note that whenever the rectified voltage VCC is at
instantaneous minimum VCC(min), the voltage of one
capacitance is at its minimum, but the voltage on the other
capacitor is at halfway between peak and minimum
voltages, VC(pk) and VC(min) respectively. The value of
VC(min) can be determined as follows:
Icap(pk)
Icap
0
(AC ONLY)
Figure 11. Waveforms of Bridge Rectification
VCC(min) VC(min) [VC(min) VC(pk)]2
Vin
(20)
or VC(min) [2VCC(min) VC(pk)]3
91 V for VC(pk) 90 1.414 127 V
and VCC(min) 200 V
VCC(pk)
VCC
T
From energy law,
VCC(min)
Pin2 12 Cin [VC(pk)2 VC(min)2] fin
VC(pk)
or
Cin VC1
VC(min)
VC2
VC1
VC2
Pin
1
2
VC(pk) VC(min)2 fin
(21)
327.5 F at fin 50 Hz and full load.
0
The time ta, ripple currents Icap(pk) and Icap(rms) are given by,
ta C(pk)
2 fin
2.46 ms
Icap(pk) 2 fin Cin VC(pk)2 VC(min)2
0
Icap
(A.C. ONLY)
(22)
(23)
9.18 A for Cin 330 F (practical value)
Icap(rms) Icap(pk)
Figure 12. Waveforms of Voltage Doubler
cos 1 VCC(min)
CC(pk)
2fin
2.13 ms
3Tta 1.86 A
(24)
As the power supply is designed to operate at both input
ranges, the latter case defines the relevant maximum ripple
current. In order to demonstrate the effectiveness of the
universal input voltage adaptor, the ripple current and
voltage assuming no doubler are calculated to be, with
Cin = 330 F, Vin = 90 Vac and Pin = 128.6 W at 50 Hz,
V
ta cos 1 VC(min)
V
Icap(pk)
(17)
In order to evaluate the rms ripple current Icap(rms) of the
smoothing capacitors Cin, a triangular approximation is used
to simplify the derivation. The AC peak current Icap(pk) of
Cin is,
http://onsemi.com
14
AN1080/D
the adaptor. The practical values of the capacitor and resistor
connected at pin 4 to ground are 50 nF and 560 k,
respectively, which has a time delay of approximate 650 s.
The output is connected, through a resistive divider, to a
small−power SCR (MCR102 with IK(max) = 0.8 A). When
the input voltage is detected to be above the trip point, the
SCR is fired to shunt all the incoming current from the
charge pump, and the triac will remain off.
The MC3423 can operate from 4.5 V to 40 V of supply
voltage [15]. Hence, a 6.2 V zener diode is used to clamp the
supply voltage of the crowbar sensor to 6.2 + 0.7 7.0 V
for stable operation. A 100 pF filtering capacitor for the
sensing divider and a small signal diode 1N4148 for
clamping the input of MC3423 are also added in the circuit.
To calculate a suitable value for the charge−pump
capacitor C, the working principle of the charge pump is first
considered. It consists of two diodes (1N4001), a coupling
capacitor C, and a smoothing capacitor (100 F). C is
charged during the rise time of input voltage and is
discharged during fall time. Assuming that the voltage drop
on the charge pump circuit is much less than the peak of
input voltage (VP), from charge balance principle,
VCC(min) [1272 128.6(60 165 )]12 23.3 V
VCC 127 23.3 103.7 V (compared with 55 V
for high range)
ta 4.4 ms
Icap(pk) 6.5 A
Icap(rms) 3 A (nearly double of the value with
voltage doubler)
Such a large ripple voltage at VCC will greatly stress the
switching transistor and will degrade the overall
performance, especially the conversion efficiency and
regulation.
The bridge rectifiers are selected to be 1N5398, a 1.5 A
device because the highest average line input current is
0.9 x 128.6/90 1.3 A. The two 1.0 W resistors, in parallel
with Cin, are used to discharge the input capacitor after
powered off. Note that one of them is connected to
“start−up’’ at one end instead of the ground (the inverted
triangular sign). It provides the starting current for the
current mode controller and drive circuit at initial power−on,
when the control circuitry is still not self−supplied. The
start−up current is limited to approximately 2.0 to 4.6 mA.
The inrush input current is limited to an acceptable level
by the thermistor which has a resistance of 5.0 at room
temperature and 1.0 after heated up.
MAC229A8 has been found suitable for the triac in the
universal input voltage adaptor because of the following
points:
1. It is a sensitive gate device with IGT of 10 mA
maximum for operation quadrants I, II and III
[13]. The small gate current requirement will
minimize the power dissipation in the adaptor and
will lower the capacitance of the charge−pump
capacitor C.
2. Its breakdown voltage is 600 V, which exceeds all
input voltage limits.
3. Guaranteed 25 V/s, rate of rise of off−state
voltage ensures the accurate operation of
MAC229A8 [13].
4. Low power loss in the device due to its low
voltage drop across MT1 and MT2 at operation.
MC3423 is originally designed for overvolt “crowbar’’
sensing circuit, but it is also applicable in the universal input
voltage adaptor because of the similar working condition
[14]. It has a temperature−compensated internal reference
voltage of 2.6 V which is connected to one terminal of the
input comparator. Thus, if the trip point at which the triac is
turned off is set to 135 Vac or 191 Vdc, the divider ratio in
Figure 9 is,
or
C (IT)(2VP)
where I average DC current supplied to the line adaptor
The boundary case is at low line, low range, where
VP = 127 V and I = 10 mA for gate current plus 6.0 mA for
bias current. Thus,
C [(10 6) (150)](2 127) 1.2 F
At high line, high range, VP 370 V and the maximum
value of I is 53 mA at 60 Hz. The maximum power
consumption of the line adaptor is 7 x 0.053 = 0.37 W. The
10 resistor in series with C is used to limit the inrush
current when starting.
So far in the design of the universal input voltage adaptor,
an important point which has not yet been considered is the
hazard of severe overvoltage at VCC during start−up. If the
power supply is started at high line, high range,
Vin = 260 Vac, during the falling edge of input voltage, and
the supply voltage of MC3423 is charged to about 7.0 V, the
triac will be turned on for the doubler operation in the
remaining negative cycle of input voltage, without the gate
capacitor CG, since MC3423 had not yet and would not be
tripped until the next positive cycle. Then, the lower bulk
capacitor will be stressed to nearly double of its normal
voltage rating. This harmful effect not only damages the
bulk capacitor, but also produces abnormally high input
voltage (VCC) for the flyback converter, in a small instant.
Therefore, CG is connected to the gate and MT1 terminal of
the triac to serve two purposes:
1. To delay the turn−on of triac for nearly a quarter of
one cycle.
2. To increase the dV/dt blocking capability of the
triac ( 200 V/s) and hence, the overall system
reliability [13].
2.6 191 R2(R1 R2)
or
Q (2VP) C IT
R1R2 72.5
R1 2.2 M and R2 30 k
The internal constant current source (pin 4) can provide a
time delay before tripping the “crowbar’’ SCR. It results in
better noise immunity and controlled start−up transients of
http://onsemi.com
15
AN1080/D
C Discharges
400
TL Delay Time
(BY 100 & CG)
367 V
Vin (V)
200
MC3423
Begins to Work
0
DZ (1N4735A)
Begins to Conduct
−200
tx
ty
Hazardous Range
for Voltage Doubler
−367 V
−400
0
3T
4
T
2
T
4
T = 16.67 ms
Figure 13. Worst Case Consideration for the Universal Input Voltage Adaptor (Negative Gate Current)
A practical value of 100 F is used in Figure 14. Note that
the discharging current of C at zero−crossing of input
voltage is greater than the average value I. The time constant
of the gate capacitance and gate resistor (1.0 k) is 0.1s,
which is sufficient for resetting the triac between
consecutive power−off and on. The 10 k resistor is for
discharge of the 100 F capacitor, and the corresponding
time constant is 1 second. Time constants too long in the
above design may result in failure of the universal input
voltage adaptor if the power supply which was previously
socketed in 110 V line is quickly plugged in 220 V line.
It should be noted that two optional power zener diodes
(1N5956A) are connected across each bulk capacitor Cin
because:
1. They can absorb short transient voltages
(200 V) on Cin.
2. They can prevent any failure of the universal input
voltage adaptor from damaging the flyback
converter and the two bulk capacitors.
Although such failures are rare the consequences are to be
avoided since failure of the line adaptor poses a safety
hazard to the human beings (especially the eyes radiated by
X−ray).
Common mode and differential mode EMI/RFI filters are
generally required for all switching power supplies. They
are included in Figure 14, but are excluded in the DEMO
board.
The determination of the capacitance of CG is determined
as follows, with reference to Figure 13. At high line, high
range, and 60 Hz, the average current I is maximum
(53 mA). All discussions below are referred to a falling edge
and the consecutive rising edge of less than 1/4 cycle of input
voltage, because the charge−pump capacitor C is
discharging to the adaptor circuit during fall time and the
crowbar sensor cannot be tripped if Vin falls beyond +200 V.
If the supply voltage for MC3423 is just about 4.5 V, the
crowbar sensing IC functions, and meanwhile, the
instantaneous input voltage is at the trip point (200 V) and
is going to the negative cycle, the gate capacitor CG must be
large enough to delay the conduction of the triac before the
input voltage rises again, i.e. at the negative peak. Assume
that, for simplicity, the supply voltage of MC3423 rises to
about 6.2 V (zener voltage) when the input voltage falls to
−200 V. Then,
tx = charging time of the capacitor across the supply
voltage of MC3423
= 2 x sin−1 (200/367)/(2 x 60) = 3 ms
(6.2−4.5) V x (Capacitance value)/(53−6) mA
or capacitance value 100 F (connected across supply
voltage of MC3423)
But this capacitance is necessary to meet the ripple voltage
requirement of the adaptor circuit. Afterwards, the zener
diode (1N4735A) conducts, and the two capacitors
connected in parallel are needed to delay the remaining time
ty before the input voltage rises from its negative peak again,
within the same negative cycle. Therefore,
4. PERFORMANCE OF THE FLYBACK POWER
SUPPLY
ty (16.674 32) ms
0.7 V (CG 100) F47 mA
4.1 COMPLETE CIRCUITRY
Figure 14 shows the complete circuit schematic of the
90 W flyback power supply. The triac in the universal
adaptor is negatively driven by the charge pump, since it is
least sensitive to noise in this mode. Drive circuits for
MTP4N90 and MJE18004 are also shown.
since the threshold gate voltage of MAC229A8 is 0.7 V
typically.
CG 79 F
http://onsemi.com
16
AN1080/D
4 x 1N5398
0.2 F
400 V
2A
L
90−130 VAC
OR 180−260 VAC
50/60 Hz
0.1 F
400 V
330 F
200 V
KMG
0.1 F
400 V
5D−11
330 F
200 V
KMG
270 k
1W
+
−
+
−
47 k
1W
+VCC
(200−370 Vdc)
39 k
1W
1N5956A
1N5956A
N
4700p(Y)
4700p(Y)
NOT INCLUDED
IN THE DEMO
BOARD
E
4700p(Y)
T1
MAC229A8
START−UP
1N4001
100 F
6V
1k
T2
MCR102
10
100 F
25 V
+
10 k
1.2 F
400 V
1k
1
1N4735A
MC3423P
3
1N4001
100 p
−
30 k
1%
−
8
4K7
2M2
5%
+
UNIVERSAL
INPUT VOLTAGE
ADAPTOR
4
2
5
1N4148
7
50 nF
560 k
Figure 14. Complete Circuit Schematics of 90 W Off−the−Line Power Supply (continued on next page)
http://onsemi.com
17
AN1080/D
VCC
180
470p
1
MUR140
0.1 400 V
20 k
Lp
172T
1K2
1
Ls (110)
5K6
77T
2W
33 20 H 160 V
0.1 250 V
+
−
+
−
+110 V
(0.7 A)
1N5953A
(Optional)
0V
MUR180
2N3906
I1
R2
2x33 160 V
39 k
MUR180
2K4
3W
1000p
1kV
0.1 1′
Ls (15)
560
11T
0.5 W
+15 V
(0.3 A)
20 H
MBR160
+
+
330 − 25 V
220 − 25 V
0V
START−UP
MBR160
1N4148
+
CA
−
8
1k
SYNC
DZ
7
0.1 I1
2N3906
4
47
MTP
10
1 nF
6
IC1
390
2
10 k
0.28
0.5 W
MJE18004
6
20 1 W
IC1
TO CS OF IC1
0.28
330 − V
330
MOC8102 *
5
15
− +
3K3
1%
1 F
16 V
+
−
+
0V
142 k
1%
START−UP
7
470 − V
RA
470 pF
1
+
220
0.5 W
1k
3
MOC8102
Ls (8)
7T
4N90
10
39n
10 k
LA
+8 V
(0.2 A)
20 H
1N5819
MOSFET
Bipolar
FOR
MTP4N90
MJE18004
IC1
RA
CA
DZ
NA
Start−up
R2
UC3842A
47
33 25 V
1N4747A
18T
20 V
20 k
UC3843A
10
2200 16 V
1N4740A
13T
10 V
33 k (10W)
TL431CLP
HEATSINK
Figure 14. Complete Circuit Schematics of 90 W Off−the−Line Power Supply (continued from previous page)
http://onsemi.com
18
AN1080/D
TOP VIEW
TOP VIEW
Figure 15a. Universal Input Voltage Adaptor (+IG)
Figure 15b. Universal Input Voltage Adaptor (−IG)
TOP VIEW
Figure 15c. Main Board (for MTP4N90 and MJE18004)
Figure 15. P.C.B. and Component Layouts
http://onsemi.com
19
AN1080/D
TRANSFORMER CONSTRUCTION DIAGRAM
BOTTOM VIEW
Ls(110)
Ns(110) = 77
AWG #22
Lp = 1.5 to 1.75 mH
Np = 172
AWG #23
Ls(8)
Ns(8) = 7
AWG #26
LA
NA = 18 AWG #26 (for MTP4N90)
= 13 AWG #26 (for MJE18004)
WINDING AREA
Ls(15)
Ns(15) = 11
AWG #26
Ig
AIR GAP: Ig = 4 mm APPROX.
Ns(8)
Ns(15)
Ns(110)
PRIMARY−TO−
SECONDARY
INSULATION
NA
Np
CENTER LIMB OF FERRITE CORE
FERRITE CORE: TDK ETD−39 H7C4
BOBBIN: TDK PST−39
Figure 16. Flyback Transformer Construction
Sometimes, it is unnecessary to have the universal input
voltage adaptor because the power supply may be used only
at one range. Then, a modular approach for the adaptor can
lower the system cost and can increase the flexibility of
manufacture. The universal input voltage adaptor board can
be simply removed or unplugged from the power supply
board without affecting the normal operation of the power
supply, if the adaptor is not needed. Therefore, using this
approach, the adaptor becomes optional. The printed circuit
board and component layouts of the universal input voltage
adaptor(s) and the main board of power supply are shown in
Figure 15. The construction diagram of the power
transformer is shown in Figure 16. Table 1 lists all
semiconductor components used in this power supply.
Table 1. List of Semiconductor Components
Part Numbers
IC
UC3842A (for MTP4N90)
UC3843A (for MJE18004)
MC3423P
TL431CLP
1
1
1
1
Opto
MOC8102
1
MOSFET
MTP4N90
1
SCR
MCR102
1
TRIAC
MAC229A8
1
BJT
MJE18004
2N3906
1
2
Rectifier
1N4001
1N5819
1N5398
MUR140
MUR180
MBR160
2
1
4
1
2
2
Zener
1N4735A
1N4740A
1N4747A
1N5953A
1N5956A
http://onsemi.com
20
Qty.
6.2 V
10 V (for MJE18004)
20 V (for MTP4N90)
150 V (optional)
200 V
1
1
1
1
2
AN1080/D
4.2 EXPERIMENTAL MEASUREMENTS AND RESULTS
Also in Figure 18, the transient responses of the power
supply are introduced for very large−signal disturbances −
from no load to full−load. The overshoot is about 20 V and
the undershoot is over 30 V, which is quite satisfactory. The
overshoot can be further reduced by increasing the
integrating capacitance Cf in the feedback loop. But, this
will result in slower transient responses.
Typical experimental switching waveforms are shown in
Figure 17, at different load currents, input voltages and
switching frequencies. Also, Figure 19 shows the photo of
the 90 W off−the−line power supply.
DC measurements are summarized in Table 2. Line and
load regulation are excellent (better than 0.5%) for the
+110 V output. Regulation for other two rails is within 10%,
if the transformer is properly manufactured. Conversion
efficiency, is close to the expected figure (70%), and the best
one is 73.7% at Io(110) = 0.7 A, fs = 15.7 kHz and VCC = 360 V
for MTP4N90; whereas for the bipolar power transistor
MJE18004, the best efficiency is 74.2% at Io(110) = 0.7 A,
fs = 15.7 kHz and VCC = 360 V. Although MJE18004 has
lower conduction loss than MTP4N90, it has higher power
losses in the base drive circuit and in the switching transitions.
This is why MOSFETs can compete with advanced BJT even
with higher conduction loss at relatively low switching
frequency.
The maximum ripple voltage at 110 V output is
approximately 150 mV (peak−to−peak) which is less than
0.2% of the output voltage, as predicted in section 2.3. The
power supply is observed to be stable over the entire range
of load currents. The dynamic response is also satisfactory,
with an overshoot of less than 8.0 V at fs = 15.7 kHz and
VCC = 200 V, from half−load to full−load (see Figure 1).
5. CONCLUSION
A low−cost 90 W flyback power supply with external
synchronization and universal input voltage adaptor for
multi−sync color monitor has been discussed in detail. The
power supply has excellent line and load regulation and is
found to be suitable in the application of low−cost
multi−sync color monitors or TVs. Also, it can operate at
both AC mains, i.e. 90−130 V or 180−260 V, without greatly
affecting the system cost and performance.
MTP4N90 (MOSFET)
Io (110 V)
Vo (110 V)
(15 V)
(8.0 V)
fs
Iin
VCC
Efficiency
0.2
0.5
0.7
110.1
110.0
109.9
16.01
16.23
16.31
8.88
9.05
9.10
15.7
15.7
15.7
0.12
0.26
0.35
300
300
300
61.2
70.5
73.3
0.7
0.7
109.9
109.9
16.32
16.30
9.10
9.10
15.7
15.7
0.55
0.29
200
360
69.9
73.7
0.2
0.5
0.7
110.1
110.0
110.0
15.99
16.19
16.25
8.88
9.03
9.08
25.0
25.0
25.0
0.13
0.26
0.35
300
300
300
56.5
70.5
73.3
0.7
0.7
110.0
109.9
16.26
16.25
9.07
9.08
25.0
25.0
0.53
0.29
200
360
72.6
73.7
0.2
0.5
0.7
110.1
110.0
110.0
15.98
16.17
16.23
8.88
9.03
9.07
32.0
32.0
32.0
0.13
0.26
0.35
300
300
300
56.5
70.5
73.3
0.7
0.7
110.0
110.0
16.24
16.23
9.07
9.07
32.0
32.0
0.53
0.30
200
360
72.6
71.3
A
V
V
V
kHz
A
V
%
http://onsemi.com
21
AN1080/D
MJE18004 (Bipolar)
Io (110 V)
Vo (110 V)
(15 V)
(8.0 V)
fs
Iin
VCC
Efficiency
0.2
0.5
0.7
110.8
110.7
110.6
14.41
14.65
14.82
8.82
9.00
9.11
15.7
15.7
15.7
0.12
0.26
0.35
300
300
300
61.6
71.0
73.7
0.7
0.7
110.6
110.6
14.73
14.83
9.06
9.11
15.7
15.7
0.54
0.29
200
360
71.7
74.2
0.2
0.5
0.7
110.8
110.8
110.7
14.44
14.70
14.78
8.83
9.02
9.09
25.0
25.0
25.0
0.13
0.27
0.36
300
300
300
56.8
68.4
71.8
0.7
0.7
110.7
110.7
14.77
14.78
9.08
9.09
25.0
25.0
0.53
0.30
200
360
73.1
71.8
0.2
0.5
0.7
110.8
110.8
110.7
14.43
14.68
14.75
8.83
9.01
9.07
32.0
32.0
32.0
0.13
0.27
0.36
300
300
300
56.5
68.4
71.8
0.7
0.7
110.7
110.7
14.75
14.75
9.07
9.08
32.0
32.0
0.54
0.30
200
360
71.8
71.8
A
V
V
V
kHz
A
V
%
CH1
CH2
RF1
RF2gnd
20 V
A 10 s 9.38 V VERT
500 mV 10 s 40.000 s
200 V
5 V 10 s
2 V 10 s
RF3gnd
RF4gnd
2 V 10 s
CH1
CH2
5V
100 V
A 10 s 1.36 V VERT
MTP4N90 VSYNC
fs = 25 kHz
VCC = 300 V
IO = 0.5 A VP
VCT
CH2gnd
IS/RS
CH1gnd
VGS
fs = 25 kHz
VCC = 300 V
IO = 0.5 A
MJE18004
CH2gnd
VDS
CH1gnd
RF1gnd
CH2 FREQ = 25.126 kHz
Figure 17a. Key Waveforms at fs = 25 kHz and
VCC = 300 V (for MTP4N90)
Figure 17b. VCE and VBE at fs = 25 kHz and
VCC = 300 V (for MJE18004)
Figure 17. Experimental Oscillograms
http://onsemi.com
22
AN1080/D
CH1
CH2
20 V
200 V
CH1
CH2
A 10 s 8.89 V VERT
20 V
100 V
A 10 s
8.91 V VERT
fs = 15.7 kHz
VCC = 200 V
IO = 0.7 A
MTP4N90
fs = 15.7 kHz
VCC = 360 V
IO = 0.7 A
MTP4N90
CH2gnd
CH2gnd
CH1gnd
CH1gnd
CH2 FREQ = 15.674 kHz
CH2 FREQ = 15.823 kHz
Figure 17c. VDS and VGS at fs = 15.7 kHz and
VCC = 360 V (for MTP4N90)
Figure 17d. VDS and VGS at fs = 15.7 kHz and
VCC = 200 V (for MTP4N90)
CH1
CH2
20 V
200 V
A 10 s
fs = 25 kHz
VCC = 360 V
CH1
CH2
8.98 V VERT
20 V
100 V
A 10 s 8.98 V VERT
IO = 0.7 A
MTP4N90
fs = 25 kHz
VCC = 200 V
IO = 0.7 A
MTP4N90
CH2gnd
CH2gnd
CH1gnd
CH1gnd
CH2 FREQ = 25.000 kHz
CH2 FREQ = 25.000 kHz
Figure 17e. VDS and VGS at fs = 25 kHz and
VCC = 360 V (for MTP4N90)
Figure 17f. VDS and VGS at fs = 25 kHz and
VCC = 200 V (for MTP4N90)
CH1
CH2
20 V
200 V
CH1
CH2
A 10 s 9.69 V VERT
20 V
100 V
A 10 s 9.22 V VERT
fs = 32 kHz
VCC = 200 V
IO = 0.7 A
MTP4N90
fs = 32 kHz
VCC = 360 V
IO = 0.7 A
MTP4N90
CH2gnd
CH2gnd
CH1gnd
CH1gnd
CH2 FREQ = 31.646 kHz
CH2 FREQ = 32.051 kHz
Figure 17g. VDS and VGS at fs = 32 kHz and
VCC = 360 V (for MTP4N90)
Figure 17h. VDS and VGS at fs = 32 kHz and
VCC = 200 V (for MTP4N90)
Figure 17. Experimental Oscillograms (continued)
http://onsemi.com
23
AN1080/D
CH1
CH2
10 V
20 V
CH1
CH2
A 100 ms 703 mV VERT
10 V
5V
A 100 ms 703 mV VERT
No Load to Full−Load
Half−Load to Full−Load
CH2gnd
fs = 15.7 kHz
VCC = 200 V
MTP4N90
fs = 15.7 kHz
VCC = 200 V
MTP4N90
CH1gnd
CH1gnd
CH2gnd
CH2 FREQ = 1.9841 Hz
CH2 FREQ = 2.0151 Hz
Figure 18a. For MTP4N90, From No Load to
Full−Load at fs = 15.7 kHz
Figure 18b. For MTP4N90, From Half−Load to
Full−Load at fs = 15.7 kHz
CH1
CH2
10 V
20 V
CH1
CH2
A 100 ms 4.14 V VERT
No Load to
Full−Load
10 V
5V
A 100 ms 4.14 V VERT
fs = 15.7 kHz
VCC = 200 V
MJE18004
CH2gnd
Half−Load to
Full−Load
CH2gnd
fs = 15.7 kHz
VCC = 200 V
MJE18004
CH1gnd
CH1gnd
Figure 18c. For MJE18004, From No Load to
Full−Load at fs = 15.7 kHz
CH1
CH2
10 V
20 V
Figure 18d. For MJE18004, From Half−Load to
Full−Load at fs = 15.7 kHz
CH1
CH2
A 100 ms 703 mV VERT
10 V
5V
A 100 ms 703 mV VERT
No Load to Full−Load
Half−Load to Full−Load
CH2gnd
fs = 32 kHz
VCC = 200 V
MTP4N90
fs = 32 kHz
VCC = 200 V
MTP4N90
CH1gnd
CH1gnd
CH2gnd
CH2 FREQ = 1.9920 Hz
CH2 FREQ = 2.0000 Hz
Figure 18e. For MTP4N90, From No Load to
Full−Load at fs = 32 kHz
Figure 18f. For MTP4N90, From Half−Load to
Full−Load at fs = 32 kHz
Figure 18. Large−Signal Transient Load Responses
http://onsemi.com
24
AN1080/D
ACKNOWLEDGEMENTS
In the course of preparing of the manuscript, several
persons gave their contributions to aid the completion of this
application note. Mr. T.S. Au, a summer student from H.K.
Polytechnic helped to draft all P.C.B. and component layouts
and to prepare demo boards. Mr. Cedric Lai, a cooperative
student from H.K. University, reviewed the script with great
care. Also, continual support from Power Group of Discrete
Business, Motorola Semiconductors H.K. Ltd. was proved
to be essential to the success of our works. We, Cheng and
Tong, must express our thanks to these helpful people at the
end of our article.
5. Data sheets for MTP4N90 (Motorola Power
MOSFET Transistor Data − DL135 R3).
6. Advanced data sheets for MJE18004 (Motorola
Semiconductors Ltd.).
7. W. Hetterscheid, “Base Circuit Design for
High−Voltage Switching Transistors in Power
Converters,’’ Mullard Technical Note 6, p. 1−14,
1974.
8. Al Pshaenich, “The Effect of Emitter−Base
Avalanching on High−Voltage Power Switching
Transistors,’’ Motorola Application Note AN803,
p. 1−16, 1979.
9. Data sheets for UC3842A (Motorola Linear and
Interface ICs − DL128 R2).
10. Advanced data sheets for MC44602 (Motorola
Semiconductors Ltd.).
11. Advanced data sheets for MOC810X (Motorola
Semiconductors Ltd.).
12. “Guide to Thyristor Applications,’’ Motorola
Application Note AN849, p. 1−7, 1982.
13. Data sheets for MAC229A8 (Motorola Thyristor
Device Data − DL137 R1).
14. Data sheets for MC3423P (Motorola Linear and
Interface ICs − DL128 R2).
REFERENCES
1. SEM−500, Unitrode Power Supply Design
Seminar. Unitrode Corporation: Lexington, MA.
1986.
2. K. Harada, T. Ninomiya & M. Kohmo, “Optimum
Design of RC Snubbers for Switching
Regulators,’’ IEEE Trans. on Aerospace and
Electronic Systems, Vol. AES−15, No. 2,
p. 209−218, Mar. 1979.
3. W. McMurray, “Selection of Snubbers and Clamps
to Optimize the Design of Transistor Switching
Converters,’’ PESC ’79, p. 62−74, 1979.
4. G. Chryssis, “High−Frequency Switching Power
Supplies: Theory and Design.’’ (2nd edition)
McGraw−Hill Publishing Company, 1988.
Figure 19. Photo of 90 W Off−the−Line Power Supply
http://onsemi.com
25
AN1080/D
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,
and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal
Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
PUBLICATION ORDERING INFORMATION
LITERATURE FULFILLMENT:
Literature Distribution Center for ON Semiconductor
P.O. Box 5163, Denver, Colorado 80217 USA
Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada
Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada
Email: [email protected]
N. American Technical Support: 800−282−9855 Toll Free
USA/Canada
ON Semiconductor Website: http://onsemi.com
Order Literature: http://www.onsemi.com/litorder
Japan: ON Semiconductor, Japan Customer Focus Center
2−9−1 Kamimeguro, Meguro−ku, Tokyo, Japan 153−0051
Phone: 81−3−5773−3850
http://onsemi.com
26
For additional information, please contact your
local Sales Representative.
AN1080/D