STMICROELECTRONICS VIPER53DIP

VIPer53DIP
VIPer53SP
®
OFF LINE PRIMARY SWITCH
TYPICAL OUTPUT POWER CAPABILITY
European
(195 - 265 Vac)
US / Wide range
(85 - 265 Vac)
DIP-8
50W
30W
PowerSO-10™
65W
40W
TYPE
Note:
10
1
Above power capabilities are given under adequate
thermal conditions
PowerSO-10™
DIP-8
FEATURES
n SWITCHING FREQUENCY UP TO 300 kHz
n CURRENT LIMITATION
n CURRENT MODE CONTROL WITH
ADJUSTABLE LIMITATION
n SOFT START AND SHUT DOWN CONTROL
n AUTOMATIC BURST MODE IN STAND-BY
CONDITION (“BLUE ANGEL” COMPLIANT)
n UNDERVOLTAGE LOCKOUT WITH
HYSTERESIS
n HIGH VOLTAGE STARTUP CURRENT
SOURCE
n OVERTEMPERATURE PROTECTION
n OVERLOAD AND SHORT-CIRCUIT CONTROL
DESCRIPTION
The VIPer53 combines in the same package an
enhanced current mode PWM controller with a
high voltage MDMesh Power Mosfet. Typical
applications cover off line power supplies with a
secondary power capability ranging up to 30W in
wide range input voltage or 50W in single
European voltage range and DIP-8 package, with
the following benefits:
– Overload and short circuit controlled by
feedback monitoring and delayed device reset.
– Efficient standby mode by enhanced pulse
skipping.
– Primary regulation or secondary loop failure
protection through high gain error amplifier.
BLOCK DIAGRAM
OSC
DRAIN
ON/OFF
OSCILLATOR
PWM
LATCH
OVERTEMP.
DETECTOR
R1
S
FF
R2
R3
R4
BLANKING TIME
SELECTION
Q
1V
R5
H COMP
0.5V
UVLO
COMPARATOR
150/400ns
BLANKING
VDD
8.4/
11.5V
PWM
COMPARATOR
STANDBY
COMPARATOR
0.5V
4V
CURRENT
AMPLIFIER
8V
125k
15V
ERROR
AMPLIFIER
4.35V
OVERLOAD
COMPARATOR
OVERVOLTAGE
COMPARATOR
18V
4.5V
TOVL
June 2004
COMP
SOURCE
1/24
VIPer53DIP / VIPer53SP
PIN FUNCTION
Name
VDD
SOURCE
Function
Power supply of the control circuits. Also provides the charging current of the external capacitor during
start-up. The functions of this pin are managed by four threshold voltages:
- VDDon: Voltage value at which the device starts switching (Typically 11.5 V).
- VDDoff: Voltage value at which the device stops switching (Typically 8.4 V).
- VDDreg: Regulation voltage point when working in primary feedback (Trimmed to 15 V).
- VDDovp: Triggering voltage of the overvoltage protection (Trimmed to 18 V).
Power Mosfet source and circuit ground reference.
DRAIN
Power Mosfet drain. Also used by the internal high voltage current source during the start-up phase, for
charging the external VDD capacitor.
COMP
Input of the current mode structure, and output of the internal error amplifier. Allows the setting of the
dynamic characteristic of the converter through an external passive network. Useful voltage range
extends from 0.5 V to 4.5 V. The Power Mosfet is always off below 0.5 V, and the overload protection is
triggered if the voltage exceeds 4.35V. This action is delayed by the timing capacitor connected to the
TOVL pin.
TOVL
Allows the connection of an external capacitor for delaying the overload protection, which is triggered by
a voltage on the COMP pin higher than 4.35V.
OSC
Allows the setting of the switching frequency through an external Rt-Ct network.
CURRENT AND VOLTAGE CONVENTIONS
IDD
ID
VDD
DRAIN
I OSC
OSC
15V
TOVL
VDD
COMP
VDS
SOURCE
I TOVL
VOSC
ICOMP
VTOVL
VCOMP
CONNECTION DIAGRAM
1
8
TOVL
OSC 2
7
VDD
COMP
SOURCE
SOURCE
3
6
4
5
DRAIN
NC
NC
1
10
NC
2
9
NC
NC
3
8
NC
VDD
4
7
OSC
TOVL
5
6
COMP
SOURCE
DRAIN
PowerSO-10™
DIP-8
ORDER CODES
PACKAGE
DIP-8
PowerSO-10™
2/24
TUBE
TAPE and REEL
VIPer53DIP
-
VIPer53SP
VIPer53SP13TR
VIPer53DIP / VIPer53SP
ABSOLUTE MAXIMUM RATINGS
Symbol
VDS
ID
VDD
Parameter
Continuous Drain Source Voltage (Tj=25 ... 125°C)
(See note 1)
Continuous Drain Current
Supply Voltage
VOSC
OSC Input Voltage Range
ICOMP
ITOVL
COMP and TOVL Input Current Range
VESD
Electrostatic Discharge:
Machine Model (R=0Ω; C=200pF)
Charged Device Model
(See note 1)
Value
Unit
-0.3 ... 620
V
Internally limited
A
0 ... 19
V
0 ... VDD
V
-2 ... 2
mA
200
1.5
V
kV
Internally limited
°C
Tj
Junction Operating Temperature
Tc
Case Operating Temperature
-40 to 150
°C
Storage Temperature
-55 to 150
°C
Tstg
Note: 1. In order to improve the ruggedness of the device versus eventual drain overvoltages, a resistance of 1 kΩ should be inserted in
series with the TOVL pin.
THERMAL DATA
Symbol
Parameter
Rthj-case
DIP-8
Rthj-amb
DIP-8
Rthj-case
PowerSO-10™
Rthj-amb
PowerSO-10™
(See note 2)
(See note 3)
Max Value
Unit
20
°C/W
80
°C/W
2
°C/W
60
°C/W
Note: 2. When mounted on a standard single-sided FR4 board with 50mm² of Cu (at least 35 µm thick) connected to the DRAIN pin.
3. When mounted on a standard single-sided FR4 board with 50mm² of Cu (at least 35 µm thick) connected to the device tab.
3/24
VIPer53DIP / VIPer53SP
ELECTRICAL CHARACTERISTICS (Tj=25°C, VDD=13V, unless otherwise specified)
POWER SECTION
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
Drain-Source Voltage
ID=1mA; VCOMP=0V
Off State Drain Current
VDS=500V; VCOMP=0V; Tj=125°C
Static Drain-Source
On State Resistance
ID=1A; VCOMP=4.5V; VTOVL=0V
Tj=25°C
Tj=100°C
0.9
tfv
Fall Time
ID=0.2A; VIN=300V
(See figure 1 and note 4)
100
ns
trv
Rise Time
ID=1A; VIN=300V
(See figure 1 and note 4)
50
ns
Coss
Drain Capacitance
VDS=25V
170
pF
CEon
Effective Output
Capacitance
200V < VDSon < 400V
60
pF
BVDSS
IDSS
RDS(on)
620
(See note 5)
V
150
µA
1
1.7
Ω
Ω
Note 4. On clamped inductive load
5. This parameter can be used to compute the energy dissipated at turn on Eton according to the initial drain to source voltage VDSon
1.5
1
2 V DSon
and the following formula: E ton = --- ⋅ C Eon ⋅ 300 ⋅  ----------------
300
2
OSCILLATOR SECTION
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
(See figure 9)
95
100
105
kHz
(See figure 12)
RT=8kΩ; CT=2.2nF
VDD=VDDon ... VDDovp; Tj=0 ... 100°C
93
100
107
kHz
FOSC1
Oscillator Frequency
Initial Accuracy
RT=8kΩ; CT=2.2nF
FOSC2
Oscillator Frequency
Total Variation
VOSChi
Oscillator Peak Voltage
9
V
VOSClo
Oscillator Valley Voltage
4
V
4/24
VIPer53DIP / VIPer53SP
ELECTRICAL CHARACTERISTICS (Tj=25°C, VDD=13V, unless otherwise specified)
SUPPLY SECTION
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
50
V
Drain Voltage Starting
Threshold
VDD=5V; IDD=0mA
34
IDDch1
Startup Charging Current
VDD=0 ... 5V; VDS=100V (See figure 2)
-12
mA
IDDch2
Startup Charging Current
VDD=10V; VDS=100V
(See figure 2)
-2
mA
IDDchoff
Startup Charging Current
in Thermal Shutdown
VDD=5V; VDS=100V
Tj > TSD - THYST
(See figure 5)
VDSstart
0
mA
IDD0
Operating Supply Current
Fsw=0kHz; VCOMP=0V
Not Switching
8
IDD1
Operating Supply Current F =100kHz
sw
Switching
9
11
mA
mA
VDDoff
VDD Undervoltage
Shutdown Threshold
(See figure 2)
7.5
8.4
9.3
V
VDDon
VDD Startup Threshold
(See figure 2)
10.2
11.5
12.8
V
VDDhyst
VDD Threshold
Hysteresis
(See figure 2)
2.6
3.1
VDDovp
VDD Overvoltage
Shutdown Threshold
(See figure 7)
17
18
19
V
Min.
Typ.
Max.
Unit
14.5
15
15.5
V
V
ERROR AMPLIFIER SECTION
Symbol
Parameter
Test Conditions
VDDreg
VDD Regulation Point
ICOMP=0mA
∆VDDreg
VDD Regulation Point
Total Variation
ICOMP=0mA; Tj=0 ... 100°C
GBW
Unity Gain Bandwidth
From Input =VDD to Output = VCOMP
ICOMP=0mA
(See figure 10)
AVOL
Voltage Gain
ICOMP=0mA
(See figure 10)
DC Transconductance
VCOMP=2.5V
(See figure 3)
VCOMPlo
Output Low Level
ICOMP=-0.4mA; VDD=16V
VCOMPhi
Output High Level
ICOMP=0.4mA; VDD=14V
ICOMPlo
Output Sinking Current
ICOMPhi
Output Sourcing Current
Gm
(See figure 3)
2
%
700
kHz
40
45
dB
1
1.4
1.8
mS
0.2
V
(See note 6)
4.5
V
VCOMP=2.5V; VDD=16V
(See figure 3)
-0.6
mA
VCOMP=2.5V; VDD=14V
(See figure 3)
0.6
mA
Note 6. In order to insure a correct stability of the error amplifier, a capacitor of 10nF (minimum value: 8nF) should always be present on
the COMP pin.
5/24
VIPer53DIP / VIPer53SP
ELECTRICAL CHARACTERISTICS (Tj = 25 °C, VDD = 13 V, unless otherwise specified)
PWM COMPARATOR SECTION
Symbol
Parameter
HCOMP
∆VCOMP / ∆IDPEAK
VCOMP=1 ... 4 V
dID/dt=0
(See figure 8)
VCOMP Offset
dID/dt=0
(See figure 8)
IDlim
Peak Drain Current
Limitation
ICOMP=0mA; VTOVL=0V
dID/dt=0
(See figure 8)
IDmax
Drain Current Capability
VCOMP=VCOMPovl; VTOVL=0V
dID/dt=0
(See figure 8)
td
Current Sense Delay to
Turn-Off
ID=1A
VCOMP Blanking Time
Change Threshold
(See figure 11)
tb1
Blanking Time
VCOMP < VCOMPBL
(See figure 11)
300
400
500
ns
tb2
Blanking Time
VCOMP > VCOMPBL
(See figure 11)
100
150
200
ns
tONmin1
Minimum On Time
VCOMP < VCOMPBL
450
600
750
ns
tONmin2
Minimum On Time
VCOMP > VCOMPBL
250
350
450
ns
VCOMPoff
VCOMP Shutdown
Threshold
(See figure 6)
VCOMPos
VCOMPbl
Test Conditions
Min.
Typ.
Max.
Unit
1.7
2
2.3
V/A
0.5
V
1.7
2
2.3
A
1.6
1.9
2.3
A
250
ns
1
V
0.5
V
OVERLOAD PROTECTION SECTION
Symbol
Parameter
Test Conditions
VCOMP Overload
Threshold
ITOVL=0mA
VDIFFovl
VCOMPhi to VCOMPovl
Voltage Difference
VDD=VDDoff ... VDDreg; ITOVL=0mA
(See figure 4 and note 7)
VOVLth
VTOVL Overload
Threshold
(See figure 4)
tOVL
Overload Delay
COVL=100nF
VCOMPovl
Min.
(See figure 4 and note 7)
Typ.
Max.
4.35
50
(See figure 4)
150
Unit
V
250
mV
4
V
8
ms
Note 7. VCOMPovl is always lower than VCOMPhi.
OVERTEMPERATURE PROTECTION SECTION
Symbol
Parameter
Test Conditions
TSD
Thermal Shutdown
Temperature
(See fig. 5)
THYST
Thermal Shutdown
Hysteresis
(See fig. 5)
6/24
Min.
Typ.
Max.
Unit
140
160
°C
40
°C
VIPer53DIP / VIPer53SP
Figure 1: Rise and Fall Time
ID
C<<COSS
C
L
D
t
VDD
DRAIN
VDS
300V
OSC
15V
90%
trv
tfv
TOVL
COMP
SOURCE
t
10%
Figure 2: Start-up VDD Current
Figure 4: Overload event
VDD
IDD
Normal
operation
IDD0
Abnormal
operation
VDDon
VDDhyst
VDDoff
VDDoff
VDDon
VDD
IDDch2
t
VCOMP
VDIFFovl
VCOMPhi
VCOMPovl
VDS = 100 V
FSW = 0 kHz
IDDch1
t
VTOVL
Figure 3: Output Characteristics
VOVLth
ICOMP
tOVL
ICOMPhi
Slope = Gm
0
VDDreg
t
VDD
VDS
Not
switching
Switching
ICOMPlo
t
7/24
VIPer53DIP / VIPer53SP
Figure 5: Thermal Shutdown
Figure 7: Overvoltage Event
Tj
VDD
TSD
VDDovp
TSD-T HYST
t
VDD
VDDon
t
VCOMP
Abnormal
operation
Automatic
startup
Normal
operation
t
VCOMP
t
VDS
Not
switching
Switching
t
Figure 6: Shut Down Action
t
Figure 8: Comp Pin Gain and Offset
VOSC
IDpeak
VOSChi
IDlim
VOSClo
IDmax
t
Slope = 1 / HCOMP
VCOMP
VCOMP
VCOMPoff
t
ID
t
8/24
VCOMPos
VCOMPovl VCOMPhi
VIPer53DIP / VIPer53SP
Figure 9: Oscillator Schematic and Settings
Vcc
The switching frequency settings shown
on the graphic here below is valid within
the following boundaries:
VDD
Rt
OSC
R t > 2kΩ
PWM
section
F SW < 300 kHz
320 Ω
Ct
SOURCE
Frequency (kHz)
300
2.2nF
1nF
4.7nF
100
10nF
22nF
10
1
10
100
RT (KΩ)
9/24
VIPer53DIP / VIPer53SP
Figure 10: Error Amplifier Transfer Function
Vin
VDD
DRAIN
OSC
15V
TOVL
COMP
SOURCE
Vout
R
This configuration is for test purpose only. In
order to insure a correct stability of the error
amplifier, a capacitor of 10nF (minimum
value: 8nF) should be always connected
between COMP pin and ground. See figures 14,
15 and 18.
2.5 V
Gain (dB)
60
Open
40
R = 10 kΩ
20
R = 2.2 kΩ
R = 470 Ω
0
-20
-40
-60
1
10
100
1k
10k
100k
Frequency (Hz)
Figure 11: Blanking Time
tb
tb1
tb2
VCOMP
VCOMPbl
10/24
VCOMPhi
1M
10M
VIPer53DIP / VIPer53SP
Figure 12: Typical Frequency Variation vs. Junction Temperature
Normalised Frequency
1.04
1.02
1
0.98
0.96
-20
0
20
40
60
80
100
120
100
120
Temperature (°C)
Figure 13: Typical Current Limitation vs. Junction Temperature
Normalised IDlim
1.04
1.02
1
0.98
0.96
-20
0
20
40
60
80
Temperature (°C)
11/24
VIPer53DIP / VIPer53SP
Figure 14: Off Line Power Supply With Auxiliary Supply Feedback
F1
AC IN
C1
D1
T1
C2
R1
R2
C3
T2
D2
L1
D4
D3
R4
C8
C9
DC OUT
U1
VIPer73
R3
VDD
DRAIN
C10
OSC
15V
TOVL
C4
COMP
R6
1k
C5
SOURCE
R5
C11
10nF
C6
C7
PRIMARY REGULATION CONFIGURATION
EXAMPLE
The schematic on figure 14 delivers a fixed output
voltage by using the internal error amplifier of the
device in a primary feedback configuration. The
primary auxiliary winding provides a voltage to the
VDD pin, and is automatically regulated at 15 V
thanks to the internal error amplifier connected on
this pin. The secondary voltage has to be adjusted
through the turn ratio of the transformer between
auxiliary and secondary.
The error amplifier of the VIPer53 is a
transconductance one: its output is a current
proportional to the difference of voltage between
the VDD pin and the internal trimmed 15 V
reference, i.e. the error voltage. As the
transconductance value is set at a relatively low
value to control the overall loop gain and insure
stability, this current has to be integrated by a
capacitor (C7 in the above schematic). When the
steady state operation is reached, this capacitor
blocks any DC current from the COMP pin and
imposes a nil error voltage. Therefore, the VDD
voltage is accurately regulated to 15 V.
12/24
This results in a good load regulation, which
depends only on transformer coupling and output
diodes impedance. The current mode structure
takes care of all incoming voltage changes, thus
providing at the same time an excellent line
regulation.
The switching frequency can be set to any value
through the choice of R3 and C5. This allows to
optimize the efficiency of the converter by adopting
the best compromise between switching losses,
EMI (Lower with low switching frequencies) and
transformer size (Smaller with high switching
frequencies). For an output power of a few watts,
typical switching frequencies are comprised
between 20 kHz and 40 kHz because of the small
size of the transformer. For higher power, 70 kHz
to 130 kHz are generally chosen.
The value of the compensation resistor R5 sets the
dynamic behavior of the converter. It can be
adjusted to provide the best compromise between
stability and recovering time with fast load
changes.
VIPer53DIP / VIPer53SP
Figure 15: Off Line Power Supply With Optocoupler Feedback
F1
AC IN
C1
D1
T1
C2
R1
R2
C3
T2
D2
L1
D4
D3
R4
C8
C9
DC OUT
U1
VIPer73
R3
VDD
DRAIN
C10
OSC
15V
R8
TOVL
C4
COMP
SOURCE
U2
C5
R9
1k
C6
C11
10nF
R5
C12
C7
R7
U3
R6
SECONDARY FEEDBACK CONFIGURATION
EXAMPLE
When a more accurate output voltage is needed,
the definitive way is to monitor it directly on
secondary side, and to drive the PWM controller
through an optocoupler as shown on figure 15.
The optocoupler is connected in parallel with the
compensation network on the COMP pin. The
design of the auxiliary winding will be made in such
a way that the V DD voltage is always lower than the
internal 15 V reference. The internal error amplifier
will therefore be saturated in the high state, and
because of its transconductance nature, will
deliver a constant biasing current of 0.6 mA to the
optotransistor. This current doesn’t depend on the
compensation voltage, and so it doesn’t depend on
the output load either. The gain of the optocoupler
ensures consequently a constant biasing of the
TL431 device (U3) which is in charge of secondary
regulation. If the optocoupler gain is sufficiently
low, no additional components are required to
ensure a minimum current biasing of U3. Also, the
low biasing current value avoid any ageing of the
optocoupler.
The constant current biasing can be used to
simplify the secondary circuit: Instead of a TL431,
a simple zener and resistance network in series
with the optocoupler diode can insure a good
secondary regulation. As the current flowing in this
branch remains constant for the same reason as
above, typical load regulation of 1% can be
achieved from zero to full output current with this
simple configuration.
Since the dynamic characteristics of the converter
are set on the secondary side through components
associated to U3, the compensation network has
only a role of gain stabilization for the optocoupler,
and its value can be freely chosen. R5 can be set
to a fixed value of 1 kΩ, offering the possibility of
using C7 as a soft start capacitor: When starting up
the converter, the VIPer53 device delivers a
constant current of 0.6 mA on the COMP pin,
creating a constant voltage of 0.6 V in R5 and a
rising slope across C7. This voltage shape
together with the operating range of 0.5 V to 4.5 V
13/24
VIPer53DIP / VIPer53SP
provides a soft start-up of the converter. The rising
speed of the output voltage can be set through the
value of C7. C4 and C6 values must be adjusted
accordingly in order to ensure a correct start-up.
CURRENT MODE TOPOLOGY
The VIPer53 implements the conventional current
mode control method for regulating the output
voltage. This kind of feedback includes two nested
regulation loops:
The inner loop controls the peak primary current
cycle by cycle. When the Power MOSFET output
transistor is on, the inductor current (primary side
of the transformer) is monitored with a SenseFET
technique and converted into a voltage VS. When
VS reaches VCOMP, the power switch is turned off.
This structure is completely integrated as shown
on the Block Diagram of page 1, with the current
amplifier, the PWM comparator, the blanking time
function and the PWM latch. The following formula
gives the peak current in the Power MOSFET
according to the compensation voltage:
V C OMP – V COMPos
I Dpeak = ---------------------------------------------H COM P
The outer loop defines the level at which the inner
loop regulates peak current in the power switch.
For this purpose, VCOMP is driven by the output of
the error amplifier (Either the internal one in
primary feedback configuration or a TL431 through
an
optocoupler
in
secondary
feedback
configuration, see figures 14 and 15) and is set
accordingly the peak drain current for each
switching cycle.
As the inner loop regulates the peak primary
current in the primary side of the transformer, all
input voltage changes are compensated for before
impacting the output voltage. This results in an
improved line regulation, instantaneous correction
to line changes and better stability for the voltage
regulation loop.
Current mode topology also provides a good
converter start-up control. As the compensation
voltage can be controlled to increase slowly during
the start-up phase, the peak primary current will
follow this soft voltage slope to provide a smooth
output voltage rise, without any overshoot. The
simpler voltage mode structure which only controls
the duty cycle, leads generally to high currents at
start-up with the risk of transformer saturation. The
compensation pin can also be used to limit the
current capability of the device (See Current
Limitation section).
An integrated blanking filter inhibits the PWM
comparator output for a short time after the
integrated Power MOSFET is switched on. This
function prevents anomalous or premature
termination of the switching pulse in the case of
14/24
current spikes caused by primary side transformer
capacitance or secondary side rectifier reverse
recovery time when working in continuous mode.
STANDBY MODE
The device implements a special feature to
address the low load condition. The corresponding
function described hereafter consists of reducing
the switching frequency by going into burst mode,
with the following benefits:
– It reduces the switching losses, thus providing
low consumption on the mains lines. The device
is compliant with “Blue Angel” and other similar
standards, requiring less than 0.5 W of input
power when in standby.
– It allows the regulation of the output voltage,
even if the load corresponds to a duty cycle that
the device is not able to generate because of the
internal blanking time, and associated minimum
turn on.
For this purpose, a comparator monitores the
COMP pin voltage, and maintains the PWM latch
and the Power MOSFET in the off state as long as
VCOMP remains below 0.5 V (See Block Diagram
on page 1). If the output load requires a duty cycle
below the one defined by the minimum turn on of
the device, the error amplifier decreases its output
voltage until it reaches this 0.5 V threshold
(VCOMPoff). The Power MOSFET can be
completely off for some cycles, and resumes
normal operation as soon as VCOMP is higher than
0.5 V. The output voltage is regulated in burst
mode. The corresponding ripple is not higher than
the nominal one at full load.
In addition, the minimum turn on time which
defines the frontier between normal operation and
burst mode changes according to VCOMP value.
Below 1 V (VCOMPbl), the blanking time increases
to 400 ns, whereas it is 150 ns for higher voltages
(See figure 11). The minimum turn on times
resulting from these values are respectively 600 ns
and 350 ns, when taking into account internal
propagation time. This brutal change induces an
hysteresis between normal operation and burst
mode as shown on figure 16.
When the output power decreases, the system
reaches point 2 where VCOMP equals VCOMPbl.
The minimum turn on time passes immediately
from 350 ns to 600 ns, exceeding the effective turn
on time that should be needed at such output
power level. Therefore the regulation loop will
quickly drive VCOMP to VCOMPoff (Point 3) in order
to pass into burst mode and to control the output
voltage. The corresponding hysteresis can be
seen on the switching frequency which passes
from FSWnom which is the normal switching
frequency set by the components connected to the
OSC pin, to FSWstby. Note that this frequency is
VIPer53DIP / VIPer53SP
Figure 16: Standby Mode Implementation
ton
600ns
Minimum
turn on
3
1
2
350ns
VCOMP
VCOMPsd
VCOMPoff
VCOMPbl
PIN
1
PRST
3
2
PSTBY
FSW
FSWstby
FSWnom
actually an equivalent number of switching pulses
per second, rather than a fixed switching
frequency, as the device is working in burst mode.
As long as the power remains below P RST the
output of the regulation loop remains stuck at
VCOMPsd and the converter works in burst mode.
Its “density” increases (i.e. the number of missing
cycles decreases) as the power approaches PRST
and resumes finally normal operation at point 1.
The hysteresis cannot be seen on the switching
frequency, but the COMP pin voltage which
passes brutally at that power level from point 3 to
point 1.
The power points value PRST and PSTBY are
defined by the following formulas:
1
2
1
2
P RST = --- ⋅ F SWnom ⋅ ( tb 1 + td ) ⋅ V IN ⋅ -----2
Lp
1
2
P STBY = --- ⋅ F SW nom ⋅ Ip ( V COMPbl ) ⋅ Lp
2
Where Ip(VCOMPbl) is the peak Power MOSFET
current corresponding to a compensation voltage
of VCOMPbl (1V), that is to say about 250 mA. Note
that the power point P STBY where the converter is
going into burst mode doesn’t depend on the input
voltage.
The standby frequency FSWstb y is given by:
P STBY
F SWstby = -------------- ⋅ F SWnom
P RST
The ratio between the nominal switching frequency
and the standby one can be as high as 4,
depending on the Lp value and input voltage.
HIGH VOLTAGE START-UP CURRENT
SOURCE
An integrated high voltage current source provides
a bias current from the DRAIN pin during the startup phase. This current is partially absorbed by
internal control circuits in standby mode with
reduced consumption and also supplies the
external capacitor connected to the VDD pin. As
soon as the voltage on this pin reaches the high
voltage threshold VDDon of the UVLO logic, the
device turns into active mode and starts switching.
The start-up current generator is switched off, and
the converter should normally provide the needed
current on the VDD pin through the auxiliary
winding of the transformer, as shown on figure 14
or 15.
The external capacitor CVDD on the VDD pin must
be sized according to the time needed by the
converter to start-up, when the device starts
switching. This time tss depends on many
parameters, among which transformer design,
output capacitors, soft start feature and
compensation network implemented on the COMP
pin and possible secondary feedback circuit. The
following formula can be used for defining the
minimum capacitor needed:
I DD1 ⋅ tss
C VDD > ----------------------V DDhyst
Figure 17 shows a typical start-up event. VDD
starts from 0 V with a charging current I DDch1 at
about 9 mA. When about VDDoff is reached, the
Figure 17: Startup Waveforms
IDD
IDD1
t
IDDch2
IDDch1
VDD
tss
VDDreg
VDDst
VDDsd
tsu
t
15/24
VIPer53DIP / VIPer53SP
charging current is reduced down to IDDch2 which
is about 0.6 mA. This lower current leads to a slope
change on the VDD rise. The device starts
switching for a VDD equal to VDDon, and the
auxiliary winding delivers some energy to the VDD
capacitor after the start-up time tss.
The charging current change at VDDoff allows a fast
complete start-up time tsu, and maintains a low
restart duty cycle. This is especially useful for short
circuits and overloads conditions, as described in
the following section.
SHORT-CIRCUIT AND OVERLOAD
PROTECTION
A VCOMPovl threshold of about 4.35 V has been
implemented on the COMP pin. When VCOMP goes
above this level, the capacitor connected on the
TOVL pin begins to charge. When reaching
typically 4 V (VOVLth), the internal mosfet driver is
disabled and the device stops switching. This state
is latched thanks to the regulation loop which
maintains the COMP pin voltage above the
VCOMPovl threshold. Since the VDD pin doesn’t
receive any more energy from the auxiliary
winding, its voltage drops down until it reaches
VDDoff and the device is reset, recharging the
VDD capacitor for a new restart cycle. Note that if
VCOMP drops down below the V COMPovl threshold
for any reason during the VDD drop, the device
resumes switching immediately.
The device enters an endless restart sequence if
the overload or short circuit condition is
maintained. The restart duty cycle DRST is defined
as the time ratio for which the device tries to
restart, thus delivering its full power capability to
the output. In order to keep the whole converter in
a safe state during this event, D RST must be kept
as low as possible, without compromising the real
start up of the converter. A typical value of about
10 % is generally sufficient. For this purpose, both
VDD and TOVL capacitors can be used to satisfy
the following conditions:
–6
C OVL > 12.5 ⋅ 10 ⋅ tss
C OVL ⋅ I DDc h2
1
4
C VDD > 8 ⋅ 10 ⋅  ------------ – 1 ⋅ --------------------------------- D RST 
V DDhyst
Refer to the previous start-up section for the
definition of tss, and CVDD must also be checked
against the limit given in this section. The
maximum value of the two calculus will be
adopted.
All this behavior can be observed on figure 4. In
Figure 8 the value of the drain current Id for
VCOMP=VCOMPovl is shown. The corresponding
parameter I Dmax is the drain current to take into
account for design purpose. Since IDmax
represents the maximum value for which the
16/24
overload protection is not triggered, it defines the
power capability of the power supply.
TRANSCONDUCTANCE ERROR AMPLIFIER
The VIPer53 includes a transconductance error
amplifier. Transconductance Gm is the change in
output current ICOMP versus change in input
voltage VDD. Thus:
Gm =
∂I COMP
∂ V DD
The output impedance ZCOMP at the output of this
amplifier (COMP pin) can be defined as:
Z C OMP =
∂V COMP
1 ∂VCOM P
= --------- ⋅
Gm ∂ VDD
∂ I COMP
This last equation shows that the open loop gain
AVOL can be related to Gm and ZCOMP:
A VOL = Gm ⋅ Z COM P
where Gm value for VIPer53 is typically 1.4 mA/V.
Gm is well defined by specification, but ZCOMP and
therefore AVOL are subject to large tolerances. An
impedance Z must be connected between the
COMP pin and ground in order to define accurately
the transfer function F of the error amplifier,
according to the following equation, very similar to
the one above:
F(s) = Gm ⋅ Z(s)
The error amplifier frequency response is shown in
figure 10 for different values of a simple resistance
connected on the COMP pin. The unloaded
transconductance error amplifier shows an internal
ZCOMP of about 140 KΩ. More complex
impedances can be connected on the COMP pin to
achieve different compensation methods. A
capacitor provides an integrator function, thus
eliminating the DC static error, and a resistance in
series leads to a flat gain at higher frequency,
Figure 18: Typical Compensation Network
VDD
DRAIN
OSC
15V
TOVL
COMP
SOURCE
Rcomp
10nF
Ccomp
VIPer53DIP / VIPer53SP
introducing a zero and ensuring a correct phase
margin. This configuration is illustrated in figure 18
Figure 19: Typical Transfer Functions
for the schematic and figure 19 for the error
Gain (dB)
60
Rcomp=4.7k
Ccomp=470nF
50
40
30
20
10
0
-10
1
10
100
1k
10k
100k
1M
Frequency (Hz)
Phase (°)
0
Rcomp=4.7k
Ccomp=470nF
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
1
10
100
1k
10k
100k
1M
Frequency (Hz)
amplifier transfer function for a typical set of values
for CCOMP and RCOMP. Note that a capacitor of
10 nF (minimum value: 8 nF) should always be
connected to the COMP pin to insure a correct
stability of the internal error amplifier.
The complete converter open loop transfer
function can be built from both power cell and error
amplifier transfer functions. A theoretical example
can be seen in figure 20 for a discontinuous mode
flyback loaded by a simple resistor, regulated from
primary side (no optocoupler, the internal error
amplifier is fully used for regulation). A typical
schematic corresponding to this situation can be
seen on figure 14.
The transfer function of the power cell is
represented as G(s) in figure 20. It exhibits a pole
which depends on the output load and on the
output capacitor value. As the load of a converter
may change, two curves are shown for two
different values of output resistance value, RL1 and
RL2. A zero at higher frequency values then
appears, due to the output capacitor ESR. Note
that the overall transfer function doesn’t depend on
the input voltage, thanks to the current mode
control.
The error amplifier has a fixed behavior, similar to
the one shown in figure 19. Its bandwidth is limited,
in order to avoid injection of high frequency noise
17/24
VIPer53DIP / VIPer53SP
Figure 20: Complete Converter Transfer Function
G(S)
P
M AX
3.2 ⋅ -------------------P
O U T1
P
MAX
3.2 ⋅ -------------------P
OU T 2
1
---------------------------------------π⋅R
⋅C
L1
O UT
1
---------------------------------------π⋅R
⋅C
L2
O UT
F
1
1
-----------------------------------------------2 ⋅ π ⋅ ES R ⋅ C
O UT
F(S)
Gm ⋅ R
1
---------------------------------------------------------------2⋅π ⋅R
C
C O M P ⋅ CO M P
FC
COMP
F
1
F(S).G(S)
perfect first order decreasing slope until it reaches
the zero of the output capacitor ESR. The error
amplifier cut off then prevents definitely any further
spurious noise or resonance from disturbing the
regulation loop.
The point where the complete transfer function has
a unity gain is known as the regulation bandwidth
and has a double interest:
– The higher it is the faster will be the reaction to
an eventual load change, and the smaller will be
the output voltage change.
– The phase shift in the complete system at this
point has to be less than 135 ° to ensure a good
stability. Generally, a first order gives 90 ° of
phase shift, and 180 ° for a second order.
In figure 20, the unity gain is reached in a first order
slope, so the stability is ensured.
The dynamic load regulation is improved by
increasing the regulation bandwidth, but some
limitations have to be respected: As the transfer
function above the zero due the capacitor ESR is
not reliable (The ESR itself is not well specified,
and other parasitic effects may take place), the
bandwidth should always be lower than the
minimum of FC and ESR zero.
As the highest bandwidth is obtained with the
highest output power (Plain line with RL2 load in
figure 20), the above criteria will be checked for
this condition and allows to define the value of
RCOMP, as the error amplifier gain depends only
on this value for this frequency range. The
following formula can be derived:
R COMP =
With:
POUT2 F BW 2 ⋅ RL2 ⋅ C OUT
----------------- ⋅ -----------------------------------------------Gm
PM AX
2
VOUT
P OUT2 = -------------RL2
1
FBW 2
1
F
FBW 1
2
And: P M AX = --- ⋅ LP ⋅ ILIM ⋅ F SW :
2
The lowest load gives another condition for
stability: The frequency FBW1 must not encounter
the second order slope generated by the load pole
and the integrator part of the error amplifier. This
condition can be met by adjusting the CCOMP
value:
R L1 ⋅ COUT
C COMP > --------------------------------------------- ⋅
2
6.3 ⋅ Gm ⋅ R COMP
in the current mode section. A zero due to the
RCOMP-C COMP network is set at the same value as
the maximum load RL2 pole.
The total transfer function is shown as F(s).G(s) at
the bottom of figure 20. For maximum load (plain
line), the load pole is exactly compensated by the
zero of the error amplifier, and the result is a
18/24
2
V OUT
POUT1 = -------------R L1
POUT1
----------------PM AX
With:
The above formula gives a minimum value for
CCOMP. It can be then increased to provide a
natural soft start function as this capacitor is
charged by the error amplifier current capacity
ICOMPhi at start-up.
VIPer53DIP / VIPer53SP
SPECIAL RECOMMENDATIONS
As stated in the error amplifier section, a capacitor
of 10 nF (minimum value: 8 nF) should always be
connected to the COMP pin to insure a correct
stability of the internal error amplifier. This is
represented on figures 14, 15 and 18.
In order to improve the ruggedness of the device
versus eventual drain overvoltages, a resistance of
1 kΩ should be inserted in series with the TOVL
pin, as shown on figures 14 and 15. Note that this
resistance doesn’t impact the overload delay, as its
value is negligible in front of the internal pull up
resistance (about 125 kΩ).
SOFTWARE IMPLEMENTATION
All the above considerations and some others are
included in a design software which provides all
the needed components around the VIPer device
for a specified output configuration. This software
is available in download on the ST internet site.
19/24
VIPer53DIP / VIPer53SP
Plastic DIP-8 MECHANICAL DATA
DIM.
mm.
MIN.
TYP
MAX.
A
5.33
A1
0.38
A2
2.92
3.30
4.95
b
0.36
0.46
0.56
b2
1.14
1.52
1.78
c
0.20
0.25
0.36
D
9.02
9.27
10.16
E
7.62
7.87
8.26
E1
6.10
6.35
7.11
e
2.54
eA
7.62
eB
L
Package Weight
10.92
2.92
3.30
3.81
Gr. 470
P001
20/24
VIPer53DIP / VIPer53SP
PowerSO-10™ MECHANICAL DATA
mm.
DIM.
MIN.
A
A (*)
A1
B
B (*)
C
C (*)
D
D1
E
E2
E2 (*)
E4
E4 (*)
e
F
F (*)
H
H (*)
h
L
L (*)
α
α (*)
inch
TYP
3.35
3.4
0.00
0.40
0.37
0.35
0.23
9.40
7.40
9.30
7.20
7.30
5.90
5.90
MAX.
MIN.
3.65
3.6
0.10
0.60
0.53
0.55
0.32
9.60
7.60
9.50
7.60
7.50
6.10
6.30
0.132
0.134
0.000
0.016
0.014
0.013
0.009
0.370
0.291
0.366
0.283
0.287
0.232
0.232
1.35
1.40
14.40
14.35
0.049
0.047
0.543
0.545
1.80
1.10
8º
8º
0.047
0.031
0º
2º
TYP.
MAX.
0.144
0.142
0.004
0.024
0.021
0.022
0.0126
0.378
0.300
0.374
300
0.295
0.240
0.248
1.27
0.050
1.25
1.20
13.80
13.85
0.053
0.055
0.567
0.565
0.50
0.002
1.20
0.80
0º
2º
0.070
0.043
8º
8º
(*) Muar only POA P013P
B
0.10 A B
10
H
E
E2
E4
1
SEATING
PLANE
e
B
DETAIL "A"
h
A
C
0.25
D
= D1 =
=
=
SEATING
PLANE
A
F
A1
A1
L
DETAIL "A"
α
P095A
21/24
VIPer53DIP / VIPer53SP
PowerSO-10™ SUGGESTED PAD LAYOUT
TUBE SHIPMENT (no suffix)
14.6 - 14.9
CASABLANCA
B
10.8 - 11
MUAR
C
6.30
C
A
A
0.67 - 0.73
1
9.5
10
9
8
7
2
3
4
5
B
0.54 - 0.6
All dimensions are in mm.
1.27
Base Q.ty Bulk Q.ty Tube length (± 0.5)
6
Casablanca
Muar
50
50
1000
1000
532
532
A
B
C (± 0.1)
10.4 16.4
4.9 17.2
0.8
0.8
TAPE AND REEL SHIPMENT (suffix “13TR”)
REEL DIMENSIONS
Base Q.ty
Bulk Q.ty
A (max)
B (min)
C (± 0.2)
F
G (+ 2 / -0)
N (min)
T (max)
600
600
330
1.5
13
20.2
24.4
60
30.4
All dimensions are in mm.
TAPE DIMENSIONS
According to Electronic Industries Association
(EIA) Standard 481 rev. A, Feb. 1986
Tape width
Tape Hole Spacing
Component Spacing
Hole Diameter
Hole Diameter
Hole Position
Compartment Depth
Hole Spacing
W
P0 (± 0.1)
P
D (± 0.1/-0)
D1 (min)
F (± 0.05)
K (max)
P1 (± 0.1)
24
4
24
1.5
1.5
11.5
6.5
2
All dimensions are in mm.
End
Start
Top
No components
Components
No components
cover
tape
500mm min
Empty components pockets
saled with cover tape.
500mm min
User direction of feed
22/24
1
VIPer53DIP / VIPer53SP
DIP-8 TUBE SHIPMENT (no suffix)
A
C
B
Base Q.ty
Bulk Q.ty
Tube length (± 0.5)
A
B
C (± 0.1)
20
1000
532
8.4
11.2
0.8
All dimensions are in mm.
23/24
1
VIPer53DIP / VIPer53SP
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24/24