LINER LT1103CT7

LT1103/LT1105
Offline Switching Regulator
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DESCRIPTION
FEATURES
■
■
■
■
■
■
■
■
■
■
■
±1% Line and Load Regulation with No Optocoupler
Switch Frequency Up to 200kHz
Internal 2A Switch and Current Sense (LT1103)
Internal 1A Totem-Pole Driver (LT1105)
Start-Up Mode Draws Only 200µA
Fully Protected Against Overloads
Overvoltage Lockout of Main Supply
Protected Against Underdrive or Overdrive to FET
Operates in Continuous or Discontinuous Mode
Ideal for Flyback and Forward Topologies
Isolated Flyback Mode Has Fully Floating Outputs
The LT®1103 Offline Switching Regulator is designed for
high input voltage applications using an external FET
switch whose source is driven by the open collector output
of the LT1103. The LT1103 is optimized for 15W to 100W
applications. For higher power applications or additional
switch current flexibility, the LT1105 is available and its
totem pole output drives the gate of an external FET.
Unique design of the LT1103/LT1105 eliminates the need
for an optocoupler while still providing ±1% load and line
regulation in a magnetic flux-sensed converter. This significantly simplifies the design of offline power supplies
and reduces the number of components which must cross
the isolation barrier to one, the transformer.
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APPLICATIONS
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The LT1103/LT1105 current mode switching techniques
are well suited to transformer isolated flyback and forward
topologies while providing ease of frequency compensation with a minimum of external components. Low external part count for a typical application combines with a
Up to 250W Isolated Mains Converter
Up to 50W Isolated Telecom Converter
Fully Isolated Multiple Outputs
Distributed Power Conversion Networks
, LTC and LT are registered trademarks of Linear Technology Corporation.
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TYPICAL APPLICATION
Fully Isolated Flyback 100kHz 50W Converter with Load Regulation Compensation
OPTIONAL OUTPUT FILTER
MBR2045
85VAC TO 270VAC
+
220k
1W
220µF
385V
499Ω
–
BRIDGE
RECTIFIER
+
LINE
FILTER
BAV21
BAV21
1N4148
39µF
35V
13k
1%
VSW
VIN
+
50V
470µF
*50V
3600µF
WINDINGS FOR
OPTIONAL
±12VDC OUTPUTS
BUK426-800A
5.20
5.15
10Ω
FB
GND
15V
VC
+
OSC
0.047µF
1µF
25V
TRANSFORMER DATA:
COILTRONICS CTX110228-3
L(PRI) = 1.6mH
NPRI:NSEC = 1:0.05
NBIAS:NSEC = 1:0.27
390pF
220VAC
5.05
5.00
4.95
85VAC
110VAC
270VAC
4.85
0.1µF
4.80
LT1103 TA13
Danger!! Lethal Voltages Present – See Text
5.10
4.90
330Ω
0.047µF
Load Regulation
5.25
LT1103
18.7k
4.75k
1%
5V
10A
+
*OUTPUT CAPACITOR IS THREE 1200µF,
50V CAPACITORS IN PARALLEL TO
ACHIEVE REQUIRED RIPPLE CURRENT
RATING AND LOW ESR.
1N4148
1000pF 100Ω
+
MUR150
10µH
VOUT (V)
+
!!
GER
!
DAN LTAGE!
O
V
HIGH
1.5KE300A
5W
4.75
0
1
2
3
4
5
6
7
8
9
10
IOUT (A)
LT1103 TA02
1
LT1103/LT1105
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DESCRIPTION
WAR I G!
200kHz maximum switching frequency to achieve high
power density. Performance at switching frequencies
above 100kHz may be degraded due to internal timing
constraints associated with fully isolated flyback mode.
Included are the oscillator, control, and protection circuitry such as current limit and overvoltage lockout.
Switch frequency and maximum duty cycle are adjustable.
Bootstrap circuitry draws 200µA for start-up of isolated
topologies. A 5V reference as well as a 15V gate bias are
available to power external primary-side circuitry. No
external current sense resistor is necessary with LT1103
because it is integrated with the high current switch. The
LT1105 brings out the input to the current limit amplifier
and requires the use of an external sense resistor.
The LT1103/LT1105 have unique features not found on
other offline switching regulators. Adaptive antisat switch
drive allows wide ranging load currents while maintaining
high efficiency. The external FET is protected from insufficient or excessive gate drive voltage with a drive detection circuit. An externally activated shutdown mode
reduces total supply current to less than 200µA, typical for
standby operation. Fully isolated and regulated outputs
can be generated in the optional isolated flyback mode
without the need for optocouplers or other isolated feedback paths.
DANGEROUS AND LETHAL POTENTIALS ARE
PRESENT IN OFFLINE CIRCUITS!
BEFORE PROCEEDING ANY FURTHER, THE
READER IS WARNED THAT CAUTION MUST
BE USED IN THE CONSTRUCTION, TESTING
AND USE OF OFFLINE CIRCUITS. HIGH
VOLTAGE, AC LINE-CONNECTED POTENTIALS
ARE PRESENT IN THESE CIRCUITS. EXTREME
CAUTION MUST BE USED IN WORKING WITH
AND MAKING CONNECTIONS TO THESE
CIRCUITS. REPEAT: OFFLINE CIRCUITS
CONTAIN DANGEROUS, AC LINE-CONNECTED
HIGH VOLTAGE POTENTIALS. USE CAUTION.
ALL TESTING PERFORMED ON AN OFFLINE
CIRCUIT MUST BE DONE WITH AN ISOLATION
TRANSFORMER CONNECTED BETWEEN THE
OFFLINE CIRCUIT'S INPUT AND THE AC LINE.
USERS AND CONSTRUCTORS OF OFFLINE
CIRCUITS MUST OBSERVE THIS PRECAUTION
WHEN CONNECTING TEST EQUIPMENT TO
THE CIRCUIT TO AVOID ELECTRIC SHOCK.
REPEAT: AN ISOLATION TRANSFORMER
MUST BE CONNECTED BETWEEN THE CIRCUIT
INPUT AND THE AC LINE IF ANY TEST
EQUIPMENT IS TO BE CONNECTED.
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ABSOLUTE MAXIMUM RATINGS (Note 1)
VIN .......................................................................... 30V
VSW Output Voltage (LT1103) ................................. 50V
VSW Output Current (200ns)(LT1105) ................. ±1.5A
VC, FB, OSC, SS ........................................................ 6V
ILIM (LT1105) ........................................................... 3V
0VLO Input Current ............................................... 1mA
Lead Temperature (Soldering, 10 sec.)................ 300°C
2
Maximum Operating Ambient Temperature Range
LT1103C .............................................. 0°C to 70°C
LT1105C .............................................. 0°C to 70°C
Maximum Operating Junction Temperature Range
LT1103C ............................................. 0°C to 100°C
LT1105C ............................................ 0°C to 100°C
LT1105I ......................................... – 40°C to 125°C
Storage Temperature Range ................ –65°C to 150°C
LT1103/LT1105
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PACKAGE/ORDER INFORMATION
TOP VIEW
ORDER PART
NUMBER
TOP VIEW
LT1105CN
LT1105IN
GND
1
8
ILIM
2
7
15V
FB
3
6
VIN
VC
4
5
OSC
VSW
PWRGND
1
14 VSW
OVLO
2
13 NC
FB
3
12 NC
N8 PACKAGE
8-LEAD PDIP
TJMAX = 100°C, θJA = 130°C/W
VC
4
11 15V
5V
5
10 VIN
SS
6
9
OSC
GND
7
8
ILIM
ORDER PART
NUMBER
LT1105CN8
LT1105IN8
FRONT VIEW
7
6
5
4
3
2
1
N PACKAGE
14-LEAD PDIP
PINS 1 AND 7 MUST BE TIED TOGETHER
TJMAX = 100°C, θJA = 100°C/W
ORDER PART
NUMBER
15V
VIN
OSC
GND
VC
FB
VSW
LT1103CT7
T7 PACKAGE
7-LEAD TO-220
CASE IS CONNECTED TO GROUND. LEADS ARE FORMED
TJMAX = 100°C, θJA = 50°C/W
Consult factory for Military grade parts.
ELECTRICAL CHARACTERISTICS
VIN = 20V, VC = 0.85V, OVLO = 0V, VSW Open, TA = 25°C, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
IQ
Supply Current
8V < VIN < 30V, After Device Has Started
●
ISTART
Start-Up Current
VIN < VIN Start Threshold
Industrial Grade
●
●
VIN Start Threshold
VIN Shutdown Threshold
VREF
VGATE
Note: Switching Stops When VSW < 10V (LT1103)
Note: Switching Stops When VGATE < 10V (LT1105)
5V Reference Voltage
TYP
MAX
10
20
30
UNITS
mA
200
400
450
µA
µA
●
14.5
16.0
17.5
V
●
5.0
7.0
8.0
V
●
4.80
4.95
5.20
V
VREF Line Regulation
10V < VIN < 30V
●
0.025
0.1
%/ V
VREF Load Regulation
0mA < IL < 20mA
●
0.025
0.05
%/mA
VREF Short-Circuit Current
Commercial Grade
Industrial Grade
●
●
25
20
60
110
120
mA
mA
15V Short-Circuit Current
Commercial Grade
Industrial Grade
●
●
30
25
130
140
mA
mA
15V Gate Bias Reference
17 < VIN < 30V, 0mA < IL < 30mA
●
13.8
15.0
16.2
V
15V Dropout Voltage
VIN = 15V, IL = 30mA
●
2.0
2.5
V
15V Short-Circuit Current
SF
MIN
Oscillator Scaling Factor
FB = 4V, VC = Open, Measured at VSW, ISW = 25mA,
OVLO = 5V, fOSC = SF/COSC, 40kHz < fOSC < 200kHz
●
30
70
130
mA
●
36
32
40
40
44
48
Hz • µF
Hz • µF
Oscillator Valley Voltage
2.0
V
Oscillator Peak Voltage
4.5
V
3
LT1103/LT1105
ELECTRICAL CHARACTERISTICS
VIN = 20V, VC = 0.85V, OVLO = 0V, VSW Open, TA = 25°C, unless otherwise noted.
SYMBOL
PARAMETER
CONDITONS
MIN
TYP
MAX
DC
Preset Max Switch Duty Cycle
(LT1103)
FB = 4V, VC = Open, fOSC = 40kHz, ISW = 25mA,
Note: Maximum Duty Cycle Can Be Altered at OSC Pin
●
58
65
72
%
Preset Max Switch Duty Cycle
(LT1105)
FB = 4V, VC = Open, fOSC = 40kHz, ISW = 25mA,
Note: Maximum Duty Cycle Can Be Altered at OSC Pin
Industrial Grade
●
56
63
70
%
●
55
75
%
OVLO Threshold
Overvoltage Lockout Threshold at Which Switching is Inhibited
Industrial Grade
●
●
2.3
2.2
2.5
2.7
2.8
V
V
OVLO Input Bias Current
OVLO = 2V, Measured Out of Pin (Note 2)
●
1.0
3.0
µA
FB Threshold Voltage
I(VC ) = 0mA
VFB
gm
AV
●
4.425
4.400
4.50
4.50
4.575
4.600
V
V
●
●
5
4
10
20
22
µA
µA
8
7
6
11
11
Industrial Grade
●
●
13
14
15
µA/V
µA/V
µA/V
FB Threshold Line Regulation
10V < VIN < 30V
●
0.025
0.10
Error Amp Transconductance
∆I(VC) = ±50µA
Industrial Grade
●
●
9000 12000 17500
6000 12000 20000
5000
24000
Error Amp Voltage Gain
1V < VC < 3V
Industrial Grade
●
●
500
450
1250
VC Switching Threshold
Switch Duty Cycle = 0%
●
0.85
1.25
1.4
V
●
●
50
50
150
Industrial Grade
250
300
mV
mV
●
150
275
●
●
1.5
0.7
3
Industrial Grade
4.5
4.5
mA
mA
Error Amp Clamp Voltage
FB = 4.75V
FB = 4.0V
●
●
0.3
4.2
0.7
4.4
0.9
4.6
V
V
Soft-Start Charging Current
SS = 0V
Industrial Grade
●
●
25
20
40
60
75
µA
µA
Soft-Start Reset Current
VIN = 6V, SS = 0.3V
●
1
2
Output Switch Leakage
(LT1103)
VSW = 45V
VSW = 15V
●
●
Switch Breakdown Voltage
(LT1103)
ISW = 5mA
●
50
VSW Current Limit (LT1103)
Duty Cycle = 25% (Note 4)
●
2.0
FB Input Bias Current
FB = VFB (Note 3)
Industrial Grade
Change in FB Input
Bias Current with Change in VC
FB = VFB, VC = 1V to 4V (Note 3)
Shutdown Threshold Voltage
Error Amp Source Current
Error Amp Sink Current
BV
Output Switch On Resistance
(LT1103)
∆IIN
∆ISW
4
UNIT
%/V
µmho
µmho
µmho
V/V
V/V
µA
mA
500
200
70
µA
µA
V
2.5
3.0
A
●
0.4
0.75
Ω
30
50
IQ Increase During Switch On Time
(LT1103)
ISW = 0.5A to 1.5A
●
Switch Output High Level
(LT1105)
Switch Output High Level
Industrial Grade
ISW = 200mA, VGATE = 15V
ISW = 750mA, VGATE = 15V
ISW = 200mA, VGATE = 15V
ISW = 750mA, VGATE = 15V
●
●
●
●
13.00
12.50
12.75
12.25
13.5
13.2
mA/A
V
V
V
V
LT1103/LT1105
ELECTRICAL CHARACTERISTICS
VIN = 20V, VC = 0.85V, OVLO = 0V, VSW Open, TA = 25°C, unless otherwise noted.
SYMBOL
PARAMETER
CONDITONS
MIN
Switch Output Low Level
(LT1105)
ISW = 200mA
ISW = 750mA
Rise Time (LT1105)
CL = 1000pF
50
ns
Fall Time (LT1105)
CL = 1000pF
20
ns
ILIM Threshold Voltage (LT1105)
Duty Cycle = 25% (Note 5)
●
300
375
450
mV
Low Switch Drive Lockout
Threshold
Measured at VSW (LT1103)
Measured at 15V Gate Bias Reference (LT1105)
●
9.0
9.5
10.5
V
High Switch Drive Lockout
Threshold
Measured at VSW (LT1103)
Measured at 15V Gate Bias Reference (LT1105)
●
17.0
18.5
20.0
V
●
●
The ● denotes specifications which apply over the full operating
temperature range.
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: The OVLO pin is clamped with a 5.5V Zener and can sink a
maximum input current of 1mA.
Note 3: FB input bias current changes as a function of the VC pin voltage.
Rate of change of FB input bias current is 11µA/V of change on VC. By
including a resistor in series with the FB pin, load regulation can be set
to zero.
TYP
MAX
UNIT
0.25
0.75
0.50
1.50
V
V
Note 4: Current limit on VSW is constant for DC < 35% and decreases for
DC > 35% due to internal slope compensation circuity. The LT1103 switch
current limit is given by ILIM = 1.76 (1.536 – DC) above 35% duty cycle.
Note 5: The current limit threshold voltage is constant for DC < 35% and
decreases for DC > 35% due to internal slope compensation circuitry. The
LT1105 switch current limit threshold voltage is given by VLIM = 0.225
(1.7 – DC) above 35% duty cycle.
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TYPICAL PERFORMANCE CHARACTERISTICS
Start-Up Supply Current vs
Input Voltage
Supply Current vs Input Voltage
15
10
5
I SHUT
0
5
10
15
20
INPUT VOLTAGE (V)
22
450
21
400
350
300
25°C
125°C
250
200
–55°C
150
100
50
I START
0
500
QUIESCENT SUPPLY CURRENT (mA)
25°C
20
SUPPLY CURRENT (mA)
START-UP SUPPLY CURRENT (µA)
25
Quiescent Supply Current vs
Input Voltage
25
30
LT1103 G01
0
20
125°C
19
25°C
18
17
16
–55°C
15
14
13
12
0
3
9
6
INPUT VOLTAGE (V)
12
15
LT1103 G02
0
5
10
15 20 25 30
INPUT VOLTAGE (V)
35
40
LT1103 G03
5
LT1103/LT1105
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TYPICAL PERFORMANCE CHARACTERISTICS
Shutdown Supply Current vs
Input Voltage
Shutdown Supply Current vs
VC Voltage
500
500
21
450
450
400
400
30V
20
19
18
17
8V
16
15
14
13
12
–75 –50 –25
SHUTDOWN CURRENT (µA)
22
SHUTDOWN SUPPLY CURRENT (µA)
QUIESCENT SUPPLY CURRENT (mA)
Quiescent Supply Current vs
Temperature
350
300
250
VC = 75mV
200
150
VC = 0
100
50
300
250
25°C
200
125°C
150
–55°C
100
50
0
0
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
350
5
20
15
10
25
INPUT VOLTAGE (V)
30
0
35
0
20 40 60 80 100 120 140 160 180 200
VC (mV)
LT1103 G05
LT1103 G04
VIN Start-Up Threshold vs
Temperature
LT1103 G06
VIN Shutdown Threshold vs
Temperature
17.5
Output Switch Frequency vs
Temperature
8.0
45
VIN SHUTDOWN THRESHOLD (V)
VIN START-UP THRESHOLD (V)
16.5
16.0
15.5
15.0
14.5
–75 –50 –25
OUTPUT SWITCH FREQUENCY (kHz)
COSC = 1000pF
17.0
7.7
7.4
7.1
6.8
LT1103 G07
3.0
OVERVOLTAGE LOCKOUT THRESHOLD (V)
SWITCH FREQUENCY (kHz)
PRESET SWITCH DUTY CYCLE (%)
60
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G10
6
LT1103 G09
1000
63
100
10
100
0 25 50 75 100 125 150
TEMPERATURE (°C)
Overvoltage Lockout Threshold vs
Temperature
COSC = 1000pF
66
37
Switch Oscillator Frequency vs
Capacitance
75
69
39
LT1103 G08
Preset Switch Maximum Duty
Cycle vs Temperature
72
41
35
–75 –50 –25
6.5
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
43
1000
CAPACITANCE (pF)
10000
LT1103 G11
2.8
2.6
2.4
2.2
2.0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G12
LT1103/LT1105
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TYPICAL PERFORMANCE CHARACTERISTICS
0
60
–0.5
–1.0
–1.5
–2.0
–2.5
–3.0
–75 –50 –25
5
SOFT-START RESET CURRENT (mA)
SOFT-START CHARGING CURRENT (µA)
OVLO = 2V
OVLO INPUT BIAS CURRENT (µA)
Soft-Start Reset Current vs
Temperature
Soft-Start Charging Current vs
Temperature
OVLO Input Bias Current vs
Temperature
50
40
30
20
10
0
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
3
2
1
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G13
4
LT1103 G14
5V Reference Voltage vs
Temperature
LT1103 G15
5V Load Regulation vs
Temperature
5.20
5V Line Regulation vs
Temperature
0.025
0.05
0.020
0.04
5.10
5.05
5.00
4.95
4.90
5V LINE REGULATION (%/V)
5V LOAD REGULATION (%/mA)
5V REFERENCE VOLTAGE (V)
5.15
0.015
0.010
0.005
0.03
0.02
0.01
4.85
4.80
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G16
LT1103 G18
LT1103 G17
15V Gate Bias Reference vs
Temperature
5V Reference Short-Circuit
Current vs Temperature
15V Gate Bias Dropout Voltage vs
Temperature
16.2
100
90
80
70
60
50
40
30
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G19
2.5
15V GATE BIAS DROPOUT VOLTAGE (V)
110
15V GATE BIAS REFERENCE (V)
5V REFERENCE SHORT-CIRCUIT CURRENT (mA)
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
15.8
15.4
15.0
14.6
14.2
13.8
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G20
2.0
1.5
1.0
0.5
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G21
7
LT1103/LT1105
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TYPICAL PERFORMANCE CHARACTERISTICS
130
110
90
70
50
30
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
High Switch Drive Lockout
Threshold vs Temperature
10.5
10.2
9.9
9.6
9.3
9.0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
HIGH SWITCH DRIVE LOCKOUT THRESHOLD (V)
Low Switch Drive Lockout
Threshold vs Temperature
LOW SWITCH DRIVE LOCKOUT THRESHOLD (V)
15V GATE BIAS SHORT-CIRCUIT CURRENT (mA)
15V Gate Bias Short-Circuit
Current vs Temperature
20.0
19.5
19.0
18.5
18.0
17.5
17.0
–75 –50 –25
LT1103 G24
LT1103 G23
LT1103 G22
Feedback Threshold vs
Temperature
Change in FB Input Bias Current
with Change in VC vs Temperature
(VC = 1V to 4V)
FB Input Bias Current vs
Temperature (VC = 1V)
20
14
CHANGE IN FB INPUT BIAS CURRENT
WITH CHANGE IN VC (µA/ V)
4.60
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
FB INPUT BIAS CURRENT (µA)
4.52
4.48
4.44
16
12
12
11
10
8
4
10000
5000
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G28
8
0.020
0.018
Error Amplifier Voltage Gain vs
Temperature
200
PHASE
0.016
160
gm
0.014
140
0.012
120
0.010
100
0.008
80
0.006
60
0.004
gm
0.002
0
0.1
10
100
FREQUENCY (kHz)
40
20
PHASE
1
2500
180
0
1000
LT1103 G29
ERROR AMPLIFIER VOLTAGE GAIN (V/V)
15000
LT1103 G27
Error Amplifier Transconductance
and Phase vs Frequency
ERROR AMPLIFIER TRANSCONDUCTANCE (mho)
ERROR AMPLIFIER TRANSCONDUCTANCE (µmho)
Error Amplifier Transconductance
vs Temperature
20000
8
LT1103 G26
LT1103 G25
25000
9
7
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
4.40
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
PHASE (DEGREES)
FEEDBACK THRESHOLD (V)
13
4.56
2000
1500
1000
500
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G30
LT1103/LT1105
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TYPICAL PERFOR A CE CHARACTERISTICS
Error Amplifier Source Current vs
Temperature
ERROR AMPLIFIER SINK CURRENT (mA)
300
275
250
225
200
175
4.0
3.5
3.0
2.5
2.0
1.5
–75 –50 –25
150
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
4.3
4.2
4.1
4.0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G33
LT1103 Output Switch Leakage
Current vs Temperature
1.5
0.8
0.7
0.6
0.5
0.4
1.3
1.1
0.9
0.7
0.5
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G34
LT1103 OUTPUT SWITCH LEAKAGE CURRENT (µA)
0.9
LT1103 VSW CURRENT LIMIT (A)
0.4
ISW = 0.5A
0.2
80
VSW = 15V
40
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 VSW Current Limit vs
Temperature
3.0
–55°C
0.6
VSW = 45V
120
LT1103 G36
3.0
ISW = 1.5A
160
LT1103 VSW Current Limit vs
Duty Cycle
1.2
1.0
200
LT1103 G35
LT1103 Switch Saturation Voltage
vs Temperature
0.8
4.4
VC Switching Threshold Voltage
vs Temperature
VC SWITCHING THRESHOLD (V)
ERROR AMPLIFIER LOW CLAMP VOLTAGE (V)
Error Amplifier Low Clamp
Voltage vs Temperature
(FB = 4.75V)
0.3
–75 –50 –25
4.5
LT1103 G32
LT1103 G31
2.5
25°C
2.0
125°C
2.9
LT1103 VSW CURRENT LIMIT (A)
ERROR AMPLIFIER SOURCE CURRENT (µA)
325
ERROR AMPLIFIER HIGH CLAMP VOLTAGE (V)
4.5
350
LT1103 SWITCH SATURATION VOLTAGE (V)
Error Amplifier High Clamp
Voltage vs Temperature
(FB = 4V)
Error Amplifier Sink Current vs
Temperature
1.5
1.0
0.5
DC = 25%
2.8
2.7
2.6
2.5
2.4
2.3
2.2
2.1
0
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G38
0
0
10
20
30 40 50 60
DUTY CYCLE (%)
70
80
LT1103 G39
2.0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G40
9
LT1103/LT1105
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TYPICAL PERFOR A CE CHARACTERISTICS
LT1103 Driver Current vs
Temperature
30
20
10
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
3.0
2.5
2.0
1.5
ISW = 750mA
1.0
0.5
ISW = 200mA
0
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
3.0
2.5
ISW = 750mA
2.0
1.5
ISW = 200mA
1.0
0.5
0
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G43
LT1103 G42
LT1103 G41
LT1105 Current Limit Threshold
Voltage vs Temperature
LT1105 VSW Rise Time vs
Temperature
450
LT1105 VSW Fall Time vs
Temperature
100
100
80
80
DC = 25°C
425
LT1105 VSW RISE TIME (ns)
LT1105 CURRENT LIMIT THRESHOLD VOLTAGE (mV)
LT1105 VSW HIGH SATURATION VOLTAGE (V)
40
LT1105 VSW High Saturation
Voltage vs Temperature
400
375
350
325
60
40
LT1105 VSW FALL TIME (ns)
LT1103 DRIVER CURRENT (mA /A)
50
LT1105 VSW LOW SATURATION VOLTAGE (V)
LT1105 VSW Low Saturation
Voltage vs Temperature
CLOAD = 4700pF
CLOAD = 1000pF
20
60
CLOAD = 4700pF
40
20
CLOAD = 1000pF
300
–75 –50 –25
0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G46
10
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G44
0
–75 –50 –25 0 25 50 75 100 125 150 175
TEMPERATURE (°C)
LT1103 G45
LT1103/LT1105
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PIN FUNCTIONS
LT1103
FB: The Feedback pin is the inverting input to the sampling
error amplifier. The noninverting input is tied to a 4.5V
reference. The FB pin is used for output voltage sensing.
The input bias current is a function of the control pin VC
voltage and can be used for load regulation compensation
by including a resistor in series with the FB pin. The
sampling error amplifier has a typical gm of 0.012 mhos
and the output of the sampling error amplifier has asymmetrical slew rate to reduce overshoot during start-up
conditions or following the release of an output overload.
VC: The VC control pin is used for frequency compensation, current limiting and shutdown. It is the high impedance output of the sampling error amplifier and the input
of the current limit comparator.
GND: The Ground pin acts as both the negative sense
point for the internal sampling error amplifier feedback
signal and as the high current path for the 2A switch.
Also, the case of the 7-lead TO-220 is connected to
ground. Proper connections to ground for signal paths
and high current paths must be made in order to insure
good load regulation.
OSC: The Oscillator pin sets the operating frequency of the
regulator with one external capacitor to ground. Maximum
duty cycle can also be adjusted by using an external
resistor to alter the charge/discharge ratio.
VIN: The Input Supply pin is designed to operate with
voltages of 12V to 30V. The supply current is typically
200µA up to the start-up threshold of 16V. Normal operating supply current is fairly flat at 18mA down to the
shutdown threshold of 7V. Switching is inhibited for VIN
less than 12V due to the gate drive detection circuit.
15V: A 15V reference is used to bias the gate of an external
power FET. The voltage temperature coefficient is typically
3mV/°C and the output can source 30mA. Typical dropout
voltage is 1.5V for VIN less than 17V and 30mA of load
current.
VSW: The Switch Output pin is the collector of the internal
NPN power switch. This pin has a typical ON resistance of
0.4Ω and a minimum breakdown voltage of 50V. This pin
also ties to the FET gate drive detection circuit.
LT1105
All functions on the LT1105 are equivalent to the LT1103
with the exception of the VSW pin and the ILIM pin and the
availability of the OVLO, 5V, and SS functions.
OVLO: The Overvoltage Lockout pin inhibits switching
when the pin is pulled above its threshold voltage of 2.5V.
OVLO is implemented with a resistor divider network from
the rectified DC line and is used to protect the external FET
from an overvoltage condition in the off state. This function is only available on the 14-lead PDIP.
5V: A 5V reference is available to power primary-side
circuitry. The temperature coefficient is typically
50ppm/°C and the output can source 25mA. This function is only available on the 14-lead PDIP.
SS: The Soft-Start pin is used to either program start-up
time with a capacitor to ground or to set external current
limit with a resistor divider. The SS pin has a 40µA pull-up
current and is reset to 0V by a 1mA pull-down current
during start-up and shutdown. This function is only available on the 14-lead PDIP.
VSW: The Switch Output pin is the output of a 1A NPN
totem-pole stage. The VSW pin turns the external FET on by
pulling its gate high. Break-Before-Make action of 200ns
on each switch edge is built in to eliminate cross conduction currents.
ILIM: The ILIM pin is the input to the current limit amplifier
and requires the use of a noninductive, power sense
resistor from ILIM to ground to set current limit. The typical
current limit threshold voltage is 350mV. The typical input
bias current is 100µA out of the pin.
11
LT1103/LT1105
W
BLOCK DIAGRA S
LT1103
VSW
OSC
GATE
BIAS
DETECT
15V
GATE
BIAS
15V
OSCILLATOR
START-UP
16V
VIN
LOGIC
DRIVER
7V
SPIKE
BLANK
ANTISAT
COMP
4.5V
CURRENT
LIMIT
AMP
–
AV = 10
0.15Ω
–
SAMPLING
ERROR AMP
gm = 0.012
FB
+
5V
VREF
+
5V
6V
40µA
0VLO
SHUT
DOWN
2.5V
OVERVOLTAGE
LOCKOUT
RESET
0.15V
LT1103 BD
VC
12
SS
GND
LT1103/LT1105
W
BLOCK DIAGRA S
LT1105
OSC
GATE
BIAS
DETECT
15V
GATE
BIAS
15V
OSCILLATOR
START-UP
DRIVER
16V
VIN
LOGIC
VSW
7V
DRIVER
SPIKE
BLANK
ANTISAT
COMP
4.5V
+
CURRENT
LIMIT
AMP
ILIM
–
AV = 10
–
SAMPLING
ERROR AMP
gm = 0.012
FB
+
5V
5V
VREF
6V
40µA
0VLO
SHUT
DOWN
RESET
2.5V
OVERVOLTAGE
LOCKOUT
0.15V
LT1105 BD
VC
SS
GND
13
LT1103/LT1105
U
OPERATIO
LT1103
The LT1103 is a current mode switcher. Switch duty cycle
is controlled by switch current rather than directly by the
output voltage. Referring to the block diagram, the switch
is turned on at the start of each oscillator cycle. It is turned
off when switch current reaches a predetermined level.
Control of output voltage is obtained by using the output
of a voltage sensing error amplifier to set current trip level.
This technique has several advantages. First, it has immediate response to input voltage variations, unlike ordinary
switchers which have notoriously poor line transient
response. Second, it reduces the 90° phase shift at mid
frequencies in the transformer. This greatly simplifies
closed-loop frequency compensation under widely varying input voltage or output load conditions. Finally, it
allows simple pulse-by-pulse current limiting to provide
maximum switch protection under output overload or
short-circuit conditions.
A start-up loop with hysteresis allows the IC supply
voltage to be bootstrapped from an extra primary side
winding on the power transformer. From 0V to 16V on VIN,
the LT1103 is in a prestart mode and total input current is
typically 200µA. Above 16V, up to 30V, the 6V regulator
that biases the internal circuitry and the externally available 15V regulator is turned on. The internal circuitry
remains biased on until VIN drops below 7V and the part
returns to the prestart mode. Output switching stops when
the VSW drive is less than 10V corresponding to VIN of
about 12V.
The oscillator provides the basic clock for all internal
timing. Frequency is adjustable to 200kHz with one external capacitor from OSC to ground. The oscillator turns on
the output switch via the logic and driver circuitry. Adaptive antisat circuitry detects the onset of saturation in the
power switch and adjusts driver current instantaneously
to limit switch saturation. This minimizes driver dissipation and provides very rapid turn-off of the switch.
The LT1103 is designed to drive the source of an external
power FET in common gate configuration. The 15V regulator biases the gate to guarantee the FET is on when the
switch is on. Special drive detection circuitry senses the
gate bias voltage and prevents the output switch from
14
turning on if the gate voltage is less than 10V or greater
than 20V, the industry standards for power MOSFET
operation.
The switch current is sensed internally and amplified to
trip the comparator and turn off the switch according to
the VC pin control voltage. A blanking circuit suppresses
the output of the current limit comparator for 500ns at the
beginning of each switch cycle. This prevents false tripping of the comparator due to current spikes caused by
external parasitic capacitance and diode stored charge.
The 4.5V Zener-based reference biases the positive input
of the sampling error amplifier. The negative input (FB) is
used for output voltage sensing. The sampling error
amplifier allows the LT1103 to operate in fully isolated
flyback mode by regulating from the flyback voltage of the
bootstrap winding. The leakage inductance spike at the
leading edge of the flyback waveform is ignored with a
blanking circuit. The flyback waveform is directly proportional to the output voltage in a transformer-coupled
flyback topology. Output voltages are fully floating up to
the breakdown voltage of the transformer windings. Multiple floating outputs are easily obtained with additional
windings.
The error signal developed at the comparator input is
brought out externally. This VC pin has three functions
including frequency compensation, current limit adjustment and total regulator shutdown. During normal operation, this pin sits at a voltage between 1.2V (low output
current) and 4.4V (high output current). The error amplifier is a current output (gm) type, so this voltage can be
externally clamped for adjusting current limit. Switch duty
cycle goes to zero if the VC pin is pulled to ground through
a diode, placing the LT1103 in an idle mode. Pulling the VC
pin below 0.15V causes total regulator shutdown and
places the LT1103 in a prestart mode.
LT1105
The LT1105 is a current mode switcher. Switch duty cycle
is controlled by switch current rather than directly by
output voltage. Referring to the block diagram, the switch
is turned on at the start of each oscillator cycle. It is turned
off when switch current reaches a predetermined level.
LT1103/LT1105
U
OPERATIO
Control of output voltage is obtained by using the output
of a voltage sensing error amplifier to set current trip level.
This technique has several advantages. First, it has immediate response to input voltage variations, unlike ordinary
switchers which have notoriously poor line transient response. Second, it reduces the 90° phase shift at
midfrequencies in the transformer. This greatly simplifies
closed-loop frequency compensation under widely varying input voltage or output load conditions. Finally, it
allows simple pulse-by-pulse current limiting to provide
maximum switch protection under output overload or
short-circuit conditions.
A start-up loop with hysteresis allows the IC supply
voltage to be bootstrapped from an extra primary side
winding on the power transformer. From 0V to 16V on VIN,
the LT1105 is in prestart mode and total input current is
typically 200µA. Above 16V, up to 30V, the 6V regulator
that biases the internal circuitry and the externally available 5V and 15V regulators are turned on. The internal
circuitry remains biased on until VIN drops below 7V and
the part returns to prestart mode. Output switching stops
when the 15V gate bias reference is less than 10V corresponding to VIN of about 12V.
The oscillator provides the basic clock for all internal
timing. Frequency is adjustable to 200kHz with one external capacitor from OSC to ground. The oscillator turns on
the output switch via the logic and driver circuitry.
The LT1105 is designed to drive the gate of an external
power FET in common source configuration. The drivers
and the 1A maximum totem-pole output stage are biased
from the 15V gate bias reference. Special drive detection
circuity senses the gate bias reference voltage and prevents the output switch from turning on if this voltage is
less than 10V or greater than 20V. Break-Before-Make
action of 200ns is built into each switch edge to eliminate
cross conduction currents.
Switch current is sensed externally through a precision,
power resistor. This allows for greater flexibility in switch
current and output power than allowed by the LT1103. The
voltage across the sense resistor is fed into the ILIM pin and
amplified to trip the comparator and turn off the switch
according to the VC pin control voltage. A blanking circuit
suppresses the output of the current limit comparator for
500ns at the beginning of each switch cycle. This prevents
false tripping of the comparator due to current spikes
caused by external parasitic capacitance and diode stored
charge.
A 4.5V Zener-based reference biases the positive input of
the sampling error amplifier. The negative input (FB) is
used for output voltage sensing. The sampling error
amplifier allows the LT1105 to operate in fully isolated
flyback mode by regulating the flyback voltage of the
bootstrap winding. The leakage inductance spike at the
leading edge of the flyback waveform is ignored with a
blanking circuit. The flyback waveform is directly proportional to the output voltage in the transformer coupled
flyback topology. Output voltages are fully floating up to
the breakdown voltage of the transformer windings. Multiple floating outputs are easily obtained with additional
windings.
The error signal developed at the comparator input is
brought out externally. The VC pin has three functions
including frequency compensation, current limit adjustment and total regulator shutdown. During normal operation, this pin sits at a voltage between 1.2V (low output
current) and 4.4V (high output current). The error amplifier is a current output (gm) type, so this voltage can be
externally clamped for adjusting current limit. Switch duty
cycle goes to zero if the VC pin is pulled to ground through
a diode, placing the LT1105 in an idle mode. Pulling the VC
pin below 0.15V causes total regulator shutdown and
places the LT1105 in prestart mode.
The SS pin implements soft-start with one external capacitor to ground. The internal pull-up current and clamp
transistor limit the voltage at VC to one diode drop above
the voltage at the SS pin, thereby controlling the rate of rise
of switch current in the regulator. The SS pin is reset to 0V
when the LT1105 is in prestart mode.
A final protection feature includes overvoltage lockout
monitoring of the main supply voltage on the OVLO pin. If
the OVLO pin is greater than 2.5V, the output switch is
prevented from turning on. This function can be disabled
by grounding the OVLO pin.
15
LT1103/LT1105
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APPLICATIONS INFORMATION
Bootstrap Start
It is inefficient as well as impractical to power a switching
regulator control IC from the rectified DC input as this
voltage is several hundred volts. Self-biased switching
regulator topologies take advantage of a lower voltage
auxiliary winding on the power transformer or inductor to
power the regulator, but require a start-up cycle to begin
regulation.
Start-up circuitry with hysteresis built into the LT1103/
LT1105 allows the input voltage to increase from 0V to
16V before the regulator tries to start. During this time the
start-up current of the switching regulator is typically
200µA and all internal voltage regulators are off. The low
quiescent current allows the input voltage to be trickled up
with only 500µA of current from the rectified DC line
voltage, thereby minimizing power dissipation in the startup resistor. At 16V, the internal voltage regulators are
turned on and switching begins. If enough power feeds
back through the auxiliary winding to keep the input
voltage to the switching regulator above 12V, then switching
continues and a bootstrap start is accomplished. If the
input voltage drops below 12V, then the FET drive detection
circuit locks out switching. The input voltage continues to
fall as the VIN bypass capacitor is discharged by the
normal quiescent current of the LT1103/LT1105. Once the
input voltage falls below 7V, the internal voltage regulators
are turned off and the switching regulator returns to the
low start-up current state. A continuous “burp start” mode
indicates a fault condition or an incomplete power loop.
The trickle current required to bootstrap the regulator
input voltage is typically generated with a resistor from the
rectified DC input voltage. When combined with the
regulator input bypass capacitor, the start-up resistor
creates a ramp whose slope governs the turn-on time of
the regulator as well as the period of the “burp start” mode.
The design trade-offs are power dissipated in the trickle
resistor, the turn-on time of the regulator, and the hold-up
time of the regulator input bypass capacitor. The value of
the start-up resistor is set by the minimum rectified DC
input voltage to guarantee sufficient start-up current. The
recommended minimum trickle current is 500µA. The
power rating of the start-up resistor is set by the maximum
rectified DC input voltage. A final consideration for the
16
start-up resistor is to insure that the maximum voltage
rating of the resistor is not exceeded. Typical carbon film
resistors have a voltage rating of 250V. The most reliable
and economical solution for the start-up resistor is generally
provided by placing several 0.25W resistors in series.
The LT1103/LT1105 is designed to operate with supply
pin voltages up to 30V. However, the auxiliary bias winding
should be designed for a typical output voltage of 17V to
minimize IC power dissipation and efficiency loss.
Allowances must also be made for cross regulation of the
bias voltage due to variations in the rectified DC line
voltage and output load current.
Soft-Start
Soft-start refers to the controlled increase of switch
current from a start-up or shutdown state. This allows the
power supply to come up to voltage in a controlled
manner and charge the output capacitor without activating
current limit. In general, soft-start is not required on the
LT1105 due to the design of the sampling error amplifier
gm stage which generates asymmetrical slew capability
on the VC pin.
This feature exhibits itself as a typical 3mA sink current
capability on the VC pin whereas source current is only
275µA. The low gm of the error amplifier allows smallvalued compensation capacitors to be used on VC. This
allows the sink current to slew the compensation capacitor
quickly. Therefore, overshoot of the output voltage on
start-up sequences and recovery from overload or shortcircuit conditions is prevented. However, if a longer startup period is required, the soft-start function can be used.
Soft-start is implemented with an internal 40µA pull-up
and a transistor clamp on the VC pin so that a single
external capacitor from SS ground can define the linear
ramp function. The voltage at VC is limited to one VBE
above the soft-start pin (SS). The time to maximum switch
current is defined as the capacitance on SS multiplied by
the active range in volts of the VC pin divided by the pullup current:
T=
C • (3.2V)
40µA
LT1103/LT1105
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APPLICATIONS INFORMATION
SS is reset to 0V whenever VIN is less than 7V (prestart
mode) or when shutdown is activated by pulling VC below
0.15V. The SS pin has a guaranteed reset sink current of
1mA when either the regulator supply voltage VIN falls
below 7V or the regulator is placed in shutdown.
Shutdown
The LT1103/LT1105 can be put in a low quiescent current
shutdown mode by pulling VC below 150mV. In the
shutdown mode the internal voltage regulators are turned
off, SS is reset to 0V and the part draws less than 200µA.
To initiate shutdown, about 400µA must be pulled out of
VC until the internal voltage regulators turn off. Then, less
than 50µA pull-down current is required to maintain
shutdown. The shutdown function has about 60mV of
hysteresis on the VC pin before the part returns to normal
operation. Soft-start, if used, controls the recovery from
shutdown.
5V Reference
A 5V reference output is available for the user’s convenience
to power primary-side circuitry or to generate a clamp
voltage for switch current limiting. The output will source
25mA and the voltage temperature coefficient is typically
50ppm/°C. If bypassing of the 5V reference is required, a
0.1µF is recommended. Values of capacitance greater
than 1µF may be susceptible to ringing due to decreased
phase margin. In such cases, the capacitive load can be
isolated from the reference output with a small series
resistor at the expense of load regulation performance.
Overvoltage Lockout
The switching supply and primarily the external power
MOSFET can be protected from an extreme surge of the
input line voltage with the overvoltage lockout feature
implemented on the OVLO pin. If the voltage on OVLO rises
above its typical threshold voltage of 2.5V, output switching
is inhibited. This feature can be implemented with a
resistive divider off of the rectified DC input voltage. This
feature is only available on the LT1105 in the 14-lead PDIP
and must be tied to ground if left unused.
Ground (LT1103)
The ground pin of the LT1103 is important because it acts
as the negative sense point for the internal error amplifier
feedback signal, the negative sense point for the current
limit amplifier, and as the high current path for the 2A
switch. The tab of the 7-lead TO-220 is internally connected
to GND (Pin 4).
To avoid degradation of load regulation, the feedback
resistor divider string and the reference side of the bias
winding should be directly connected to the ground pin on
the package. These ground connections should not be
mixed with high current carrying ground return paths. The
length of the switch current ground path should be as
short as possible to the input supply bypass capacitor and
low resistance for best performance. The case of the
LT1103 package is desirable to use as the high current
ground return path as this is a lower resistive and inductive
path than that of the actual package pin and will help
minimize voltage spikes associated with the high dI/dt
switch current.
Avoiding long wire runs to the ground pin minimizes load
regulation effects and inductive voltages created by the
high dI/dt switch current. Ground plane techniques should
also be used and will help keep EMI to a minimum.
Grounding techniques are illustrated in the Typical
Applications section.
Ground (LT1105)
The ground pin of the LT1105 is important because it acts
as the negative sense point for the internal error amplifier
feedback signal and as the negative sense point for the
current limit amplifier. The LT1105 8-pin PDIP has Pin 1
as its ground. The LT1105 14-pin PDIP has Pin 1 and
Pin 7 as grounds and must be tied together for proper
operation.
To avoid degradation of load regulation, the feedback
resistor divider should be directly connected to the package
ground pin. These ground connections should not be
mixed with high current carrying ground return paths. The
length of the switch current ground path should be as
short as possible to the input supply bypass capacitor and
17
LT1103/LT1105
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APPLICATIONS INFORMATION
low resistance for best performance. This will help minimize
voltage spikes associated with the high dI/dt switch current.
Avoiding long wire runs to the ground pin minimizes load
regulation effects and inductive voltages created by the
high dI/dt switch current. Ground plane techniques should
also be used and will help keep EMI to a minimum.
Grounding techniques are illustrated in the Typical
Applications section.
Oscillator
The oscillator of the LT1103/LT1105 is a linear ramp type
powered from the internal 6V bias line. The charging
currents and voltage thresholds are generated internally
so that only one external capacitor is required to set the
frequency. The 150µA pull-up current, which is on all the
time, sets the preset maximum on-time of the switch and
the 450µA pull-down current which is turned on and off,
sets the dead time. The threshold voltages are typically 2V
and 4.5V, so for a 400pF capacitor the ramp-up time of the
voltage on the OSC pin is 6.67µs and the ramp-down time
is 3.3µs, resulting in an operating frequency of 100kHz.
Although the oscillator, as well as the rest of the switching
regulator, will function at higher frequencies, 200kHz is
the practical upper limit that will allow control range for
line and load regulation. The lowest operating frequency is
limited by the sampling error amplifier to about 10kHz.
The frequency temperature coefficient is typically –80ppm/
°C with a good low T.C. capacitor. This means that with a
low temperature coefficient capacitor, the temperature
coefficient of the currents and the temperature coefficient
of the thresholds sum to –80ppm/°C over the commercial
temperature range. Bowing in the temperature coefficient
of the currents affects the frequency about ±3% at the
extremes of the military temperature range. The capacitor
type chosen will have a direct effect on the frequency
tempco.
Maximum duty cycle is set internally by the pull-up and
pull-down currents, independent of frequency. It can be
adjusted externally by modifying the fixed pull-up current
with an additional resistor. In practice, one resistor from
the OSC pin to the 5V reference or to ground does the job.
18
Note that the capacitor value must change to maintain the
same frequency. For example, a 24k resistor from 5V to
OSC and a 440pF capacitor from OSC to ground will yield
100kHz with 50% maximum duty cycle. A 56k resistor and
a 280pF capacitor from OSC to ground will yield 100 kHz
with 80% maximum duty cycle.
The oscillator can be synchronized to an external clock by
coupling a sync pulse into the OSC pin. The width of this
pulse should be a minimum of 500ns. The oscillator can
only be synchronized up in frequency and the synchronizing
frequency must be greater than the maximum possible
unsynchronized frequency (for the chosen oscillator
capacitor value). The amplitude of the sync pulse must be
chosen so that the sum of the oscillator voltage amplitude
plus the sync pulse amplitude does not exceed the 6V bias
reference. Otherwise, the oscillator pull-up current source
will saturate and erroneous operation will result. If the
LT1103/LT1105 is positioned on the primary side of the
transformer and the external clock on the isolated secondary
output side, the sync signal must be coupled into the OSC
pin using a pulse transformer. The pulse transformer must
meet all safety/isolation requirements as it also crosses
the isolation boundary. An example of externally
synchronizing the oscillator is shown in the Typical
Applications section.
Gate Biasing (LT1103)
The LT1103 is designed to drive an external power MOSFET
in the common gate or cascode connection with the VSW
pin. The advantage is that the switch current can be sensed
internally, eliminating a low value, power sense resistor.
The gate needs to be biased at a voltage high enough to
guarantee that the FET is saturated when the open-collector
source drive is on. This means 10V as specified in FET data
sheets, plus 1V for the typical switch saturation voltage,
plus a couple of volts for temperature variations and
processing tolerances. This leads to 15V for a practical
gate bias voltage.
Power MOSFETs are well suited to switching power supplies
because their high speed switching characteristics promote
high switching efficiency. To achieve high switching speed,
LT1103/LT1105
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A special circuit in the LT1103 senses the voltage at VSW
prior to turning on the switch. VSW is tied to the source of
the FET and should represent the bias voltage on the gate
when the switch is off. When the switch first turns off, the
drain flies back until it is clamped by a snubber network.
The source also flies high due to parasitic capacitive
coupling on the FET and parasitic inductance of the leads.
An extra diode from the source to the gate or VIN will
provide insurance against fault conditions that might
otherwise damage the FET. The diode clamps the source
to one diode drop above the gate or VIN, thereby limiting
the gate source reverse bias. Once the energy in the
leakage inductance spike is dissipated and the primary is
being regulated to its flyback voltage, the diode shuts off.
The source is then floating and its voltage will be close to
the gate voltage. If the sensed voltage on VSW is less than
10V or greater than 20V, the circuit prevents the switch
from turning on. This protects the FET from dissipating
high power in a nonsaturated state or from excessive gatesource voltage. The oscillator continues to run and the net
effect is to skip switching cycles until the gate bias voltage
is corrected. One consequence of the gate bias detection
circuit is that the start-up window is 6V if the gate is biased
from VIN and to 4V if the gate is biased from the 15V
output. This influences the size of the bypass capacitor on
VIN.
keep the switch just at the edge of saturation. Very low
switch current results in nearly zero driver current and
high switch currents automatically increase driver current
as necessary. The ratio of switch current to driver current
is approximately 30:1. This ratio is determined by the
sizing of the extra emitter and the value of the current
source feeding the driver circuitry. The quasisaturation
state of the switch permits rapid turn-off without the need
for reverse base emitter voltage drive.
VSW Output (LT1103)
Power MOSFETs are well suited to switching power supplies
because their high speed switching characteristics promote
high switching efficiency. To achieve high switching speed,
the gate capacitance must be charged and discharged
quickly with high peak currents. In particular, the turn-off
current can be as high as the peak switch current. The
switching speed is controlled by the impedance seen by
the gate capacitance. Practically speaking, zero impedance
is not desirable because of the high frequency noise spikes
introduced to the system. The gate bias supply which
drives the totem-pole output stage should be bypassed
with a 1µF low ESR capacitor to ground. This capacitor
supplies the energy to charge the gate capacitance during
gate drive turn-on. The power MOSFET should have a 5Ω
resistor or larger in series with its gate from the VSW pin
to define the source impedance.
The VSW pin of the LT1103 is the collector of an internal
NPN power switch. This NPN has a typical on resistance of
0.4Ω and a typical breakdown voltage (BVCBO) of 75V. Fast
switching times and high efficiency are obtained by using
a special driver loop which automatically adapts base drive
current to the minimum required to keep the switch in a
quasisaturated state. The key element in the loop is an
extra emitter on the output power transistor as seen in the
block diagram. This emitter carries no current when the
NPN output transistor collector is high (unsaturated). In
this condition, the driver circuit can deliver very high base
drive to the switch for fast turn-on. When the switch
saturates, the extra emitter acts as a collector of an NPN
operating in inverted mode and pulls base current away
from the driver. This linear feedback loop serves itself to
Gate Biasing (LT1105)
The LT1105 is designed to drive an external power MOSFET
in the common source configuration with the totem-pole
output VSW pin. The advantage is added switch current
flexibility (limited only by the choice of external power
FET) and higher output power applications than allowed by
LT1103. An external, noninductive, power sense resistor
must be used in series with the source of the FET to detect
switch current and must be tied to the input of the current
limit amplifier. The gate needs to be biased at a voltage
high enough to guarantee that the FET is saturated when
the totem-pole gate drive is on. This means 10V as
specified in FET data sheets, plus the totem-pole high side
saturation voltage plus a couple of volts for temperature
variations and processing tolerances. This leads to 15V for
a practical gate bias voltage.
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The LT1105 provides a 15V regulated output intended for
driving the totem-pole output stage. It will source 30mA
into a capacitive load with no stability problems. The
output voltage temperature coefficient is 3mV/°C. If VIN
drops below 17V, the 15V output follows about 2.0V below
VIN until the part shuts down. If the 15V output is pulled
above 17.5V, it will sink 5mA.
A special circuit in the LT1105 senses the voltage at the
15V regulated output prior to turning on the switch. The
15V regulator drives the totem-pole output stage and the
VSW pin will pull the gate of the FET very close to the value
of the 15V output when VSW turns on. Therefore, the 15V
output represents what the gate bias voltage on the FET
will be when the FET is turned on. If the sensed voltage on
the 15V output is less than 10V or greater than 20V, the
circuit prevents the switch from turning on. This protects
the FET from dissipating high power in a nonsaturated
state or from excessive gate-source voltage. The oscillator
continues to run and the net effect is to skip switching
cycles until the gate bias voltage is corrected. One
consequence of the gate bias detection circuit is that the
start-up window is 4V. This influences the size of the
bypass capacitor on VIN.
VSW Output (LT1105)
The VSW pin of the LT1105 is the output of a 1A totem-pole
driver stage. This output stage turns an external power
MOSFET on by pulling its gate high. Break-Before-Make
action of 200ns is built into each switch edge to eliminate
cross-conduction currents. Fast switching times and high
efficiency are obtained by using a low loss output stage
and a special driver loop which automatically adapts base
drive current to the totem-pole low side drive. The key
element in the loop is an extra emitter on the output pulldown transistor as seen in the block diagram. This emitter
carries no current when the low side transistor collector
is high (unsaturated). In this condition, the driver can
deliver very high base drive to the output transistor for fast
turn-off. When the low side transistor saturates, the extra
emitter acts as a collector of an NPN operating in inverted
mode and pulls base current away from the driver. This
linear feedback loop serves itself to keep the switch just at
20
the edge of saturation. This results in nearly zero driver
current. The quasisaturation state of the low side switch
permits rapid turn-on of the external FET when VSW pulls
high.
Fully Isolated Flyback Mode
A unique sampling error amplifier included in the control
loop of the LT1103/LT1105 eliminates the need for an
optoisolator while providing ±1% line and load regulation
in a magnetic flux-sensed flyback converter. In this mode,
the flyback voltage on the primary during “switch off” time
is sensed and regulated. It is difficult to derive a feedback
signal directly from the primary flyback voltage as this
voltage is typically several hundred volts. A dedicated
winding is not required because the bias winding for the
regulator lends itself to flux-sensing. Flux-sensing made
practical simplifies the design of off line power supplies by
minimizing the total number of external components and
reduces the components which must cross the isolation
barrier to one, the transformer. This inherently implies
greater safety and reliability. The transformer must be
optimized for coupling between the bias winding and the
secondary output winding(s) while maintaining the required
isolation and minimizing the parasitic leakage inductances.
Although magnetic flux-sensing has been used in the past,
the technique has exhibited poor output voltage regulation
due to the parasitics present in a transformer coupled
design. Transformers which provide the safety and isolation
as required by various international safety/regulatory
agencies also provide the poorest output voltage regulation.
Solutions to these parasitic elements have been achieved
with the novel sampling error amplifier of the LT1103/
LT1105. A brief review of flyback converter operation and
the problems which create a poorly regulated output will
provide insight on how the sampling error amplifier of the
LT1103/LT1105 addresses the regulation issue of magnetic
flux sensed converters.
The following figure shows a simplified diagram of a
flyback converter using magnetic flux sensing. The major
parasitic elements present in the transformer coupled
design are indicated. The relationships between the primary
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voltage, the secondary voltage, the bias voltage and the
winding currents are indicated in the figures found on the
following page for both continuous and discontinuous
modes of operation.
Simplified Flyback Converter
VIN
L(IkPRI)
1:N
L(lkSEC)
R
D1
VOUT
C1
COMMON
S1
VBIAS
1:N1
N = TURNS RATIO FROM SECONDARY TO PRIMARY.
N1 = TURNS RATIO FROM SECONDARY TO BIAS.
N2 = N/N1
L(lkPRI) = PRIMARY LEAKAGE INDUCTANCE.
L(lkSEC) = SECONDARY LEAKAGE INDUCTANCE.
R = PARASITIC WINDING, DIODE AND OUTPUT
CAPACITOR RESISTANCE.
LT1103 AI01
When the switch “turns on,” the primary winding sees the
input voltage and the secondary and bias windings go to
negative voltages as a function of the turns ratio. Current
builds in the primary winding as the transformer stores
energy. When the switch “turns off,” the voltage across
the switch flies back to a clamp level as defined by a
snubber network until the energy in the leakage inductance of the primary dissipates. Leakage inductance is one
of the main parasitic elements in a flux-sensed converter
and is modeled as an inductor in series with the primary
and secondary of the transformer. These parasitic inductances contribute to changes in the bias winding voltage
and thus the output voltage with increasing load current.
The energy stored in the transformer transfers through the
secondary and bias windings during “switch off” time.
Ideally, the voltage across the bias winding is set by the DC
output voltage, the forward voltage of the output diode,
and the turns ratio of the transformer after the energy in
the leakage inductance spike of the primary is dissipated.
This relationship holds until the energy in the transformer
drops to zero (discontinuous mode) or the switch turns on
again (continuous mode). Either case results in the voltage across the secondary and bias windings decreasing
to zero or changing polarity. Therefore, the voltage on the
bias winding is only valid as a representation of the output
voltage while the secondary is delivering current.
Although the bias winding flyback voltage is a representation of the output voltage, its voltage is not constant. For
a brief period following the leakage inductance spike, the
bias winding flyback voltage decreases due to nonlinearities
and parasitics present in the transformer. Following this
nonlinear behavior is a period where the bias winding
flyback voltage decreases linearly. This behavior is easily
explained. Current flow in the secondary decreases linearly at a rate determined by the voltage across the
secondary and the inductance of the secondary. The
parasitic secondary leakage inductance appears as an
impedance in series with the secondary winding. In addition, parasitic resistances exist in the secondary winding,
the output diode and the output capacitor. These impedances can be combined to form a lumped sum equivalent
and which cause a voltage drop as secondary current
flows. This voltage drop is coupled from the secondary to
the bias winding flyback voltage and becomes more significant as the output is loaded more heavily. This voltage
drop is largest at the beginning of “switch off” time and
smallest just prior to either all transformer energy being
depleted or the switch turning on again.
The best representation of the output voltage is just prior
to either all transformer energy being used up and the bias
winding voltage collapsing to zero or just prior to the
switch turning on again and the bias winding going
negative. This point in time also represents the smallest
forward voltage for the output diode. It is possible to
redefine the relationship between the secondary winding
voltage and the bias winding voltage as:
VBIAS =
(VOUT + Vf + I • RP)
N1
where Vf is the forward voltage of the output diode, I is the
current flowing in the secondary, RP is the lumped sum
equivalent secondary parasitic impedance and N1 is the
transformer turns ratio from the secondary to the bias
winding. It is apparent that even though the above point in
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Flyback Waveform for Discontinuous Mode Operation
Flyback Waveform for Continuous Mode Operation
VZENER
VZENER
PRIMARY SWITCH VOLTAGE
PRIMARY SWITCH VOLTAGE
[VOUT + Vf + (ISEC • RP)]/N
a
[VOUT + Vf + (ISEC • RP)]/ N
a
VIN
VIN
AREA “a” = AREA “b” TO MAINTAIN
ZERO VOLTS ACROSS PRIMARY
0V
b
AREA “a” = AREA “b” TO MAINTAIN
ZERO VOLTS ACROSS PRIMARY
b
0V
SECONDARY WINDING VOLTAGE
SECONDARY WINDING VOLTAGE
[VOUT + Vf + (ISEC • RP)]
c
0V
AREA “c” = AREA “d” TO MAINTAIN
ZERO VOLTS ACROSS SECONDARY
N • VIN
d
[VOUT + Vf + (ISEC • RP)]
c
0V
AREA “c” = AREA “d” TO MAINTAIN
ZERO VOLTS ACROSS SECONDARY
N • VIN
d
BIAS WINDING VOLTAGE
BIAS WINDING VOLTAGE
[VOUT + Vf + (ISEC • RP)]/N1
e
f
[VOUT + Vf + (ISEC • RP)]/ N1
e
0V
0V
AREA “e” = AREA “f” TO MAINTAIN
ZERO VOLTS ACROSS BIAS WINDING
N2 • VIN
AREA “e” = AREA “f” TO MAINTAIN
ZERO VOLTS ACROSS BIAS WINDING
N2 • VIN
f
IPRI
IPRI
∆I
PRIMARY CURRENT
∆I
PRIMARY CURRENT
0A
0A
ISEC = IPRI/N
ISEC = IPRI/N
SECONDARY CURRENT
SECONDARY CURRENT
0A
0A
IPRI
IPRI
∆I
SWITCH CURRENT
∆I
SWITCH CURRENT
0A
0A
IPRI
IPRI
SNUBBER DIODE CURRENT
SNUBBER DIODE CURRENT
0A
0A
∆t = (IPRI)[L(lkPRI)]/VSNUB
∆t = (IPRI)[L(lkPRI)]/VSNUB
LT1103 WF01
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time is the most accurate representation of the output
voltage, the answer given by the bias winding voltage is
still off from the “true” answer by the amount I•RP/N1.
The sampling error amplifier of the LT1103/LT1105 provides solutions to the errors associated with the bias
winding flyback voltage. The error amplifier is comprised
of a leakage inductance spike blanking circuit, a slew rate
limited tracking amplifier, a level detector, a sample-andhold, an output gm stage and load regulation compensation circuitry. This all seems complicated at first glance,
but its operation is straightforward and transparent to the
user of the IC. When viewed from a system or block level,
the sampling error amplifier behaves like a simple transconductance amplifier. Here’s how it works.
The sampling error amplifier takes advantage of the fact
that the voltage across the bias winding during at least a
portion of switch off time is proportional to the DC output
voltage of the secondary winding. The feedback network
used to sense the bias winding voltage is no longer
comprised of a traditional peak detector in conjunction
with a resistor divider network. The feedback network
consists of a diode in series with the bias winding feeding
the resistor divider network directly. The resultant error
signal is then fed into the input of the error amplifier. The
purpose of the diode in series with the bias winding is now
not to peak detect, but to prevent the FB pin (input of the
error amplifier) from being pulled negative and forward
biasing the substrate of the IC when the bias winding
changes polarity with “switch turn-on.”
The primary winding leakage inductance spike effects are
first eliminated with an internal blanking circuit in the
LT1103/LT1105 which suppresses the input of the FB pin
for 1.5µs at the start of “switch off” time. This prevents the
primary leakage inductance spike from being propagated
through the error amplifier and affecting the regulated
output voltage.
With the effects of the leakage inductance spike eliminated, the effects of decreasing bias winding flyback
voltage can be addressed. With the traditional diode/
capacitor peak detector circuitry eliminated from the feedback network, the tracking amplifier of the LT1103/LT1105
follows the flyback waveform as it changes with time and
amplifies the difference between the flyback signal and the
internal 4.5V reference. Tracking is maintained until the
point in time where the bias winding voltage collapses as
a result of all transformer energy being depleted (discontinuous mode) or the switch turning on again (continuous
mode). The level detector circuit senses the fact that the
bias winding flyback voltage is no longer a representation
of the output voltage and activates an internal peak detector. This effectively saves the most accurate representation of the output voltage which is then buffered to the
second stage of the error amplifier.
The second stage of the error amplifier consists of a
sample-and-hold. When the switch turns on, the sampleand-hold samples the buffered error voltage for 1µs and
then holds for the remainder of the switch cycle. This held
voltage is then processed by the output gm stage and
converted into a control signal at the output of the error
amplifier, the VC pin.
The final adjustment in regulation is provided by the load
regulation compensation circuitry. As stated earlier, output regulation degrades with increasing load current (output power). The effect is traced to secondary leakage
inductance and parasitic secondary winding, diode and
output capacitor resistances. Even though the tracking
amplifier has obtained the most accurate representation of
the output voltage, its answer is still flawed by the amount
of the voltage drop across the secondary parasitic lumped
sum equivalent impedance which is coupled to the bias
winding voltage. This error increases with increasing load
current. Therefore, a technique for sensing load current
conditions has been added to the LT1103/LT1105. The
switch current is proportional to the load current by the
turns ratio of the transformer. A small current proportional
to switch current is generated in the LT1103/LT1105 and
fed back to the FB pin. This allows the input bias current of
the sampling error amplifier to be a function of load
current. A resistor in series with the FB pin generates a
linear increase in the effective reference voltage with
increasing load current. This translates to a linear increase
in output voltage with increasing load current. By adjusting the value of the series resistor, the slope of the load
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compensation can be set to cancel the effects of these
parasitic voltage drops. The feature can be ignored by
eliminating the series resistor and lowering the equivalent
divider impedance to swamp out the effects of the input
bias current.
Frequency Compensation
In order to prevent a regulator loop using the LT1103/
LT1105 from oscillating, frequency compensation is
required. Although the architecture of the LT1103/LT1105
is simple enough to lend itself to a mathematical approach
to frequency compensation, the added complication of
input/or output filters, unknown capacitor ESR, and gross
operating point changes with input voltage and load current
variations all suggest a more practical empirical approach.
Many hours spent on breadboards have shown that the
simplest way to optimize the frequency compensation of
the LT1103/LT1105 is to use transient response techniques
and an “RC” box to quickly iterate toward the final
compensation network. Additional information on this
technique of frequency compensation can be found in
Linear Technology’s Application Note 19.
In general, frequency compensation is accomplished with
an RC series network on the VC pin. The error amplifier has
a gm (voltage “in” to current “out”) of ≈ 12000 µmhos.
Voltage gain is determined by multiplying gm times the
total equivalent error amplifier output loading, consisting
of the error amplifier output impedance in parallel with the
series RC external frequency compensation network. At
DC, the external RC can be ignored. The output impedance
of the error amplifier is typically 100kΩ resulting in a
voltage gain of ≈ 1200V/V. At frequencies just above DC,
the voltage gain is determined by the external
compensation, RC and CC. The gain at mid frequencies is
given by:
AV =
gm
2π • f • CC
The gain at high frequencies is given by:
AV = gm • RC
Phase shift from the FB pin to the VC pin is 90° at mid
frequencies where the external CC is controlling gain, then
24
drops back to 0° (actually 180° since FB is an inverting
input) when the reactance of CC is small compared to RC.
Thus, this RC series network forms a pole-zero pair. The
pole is set by the high impedance output of the error
amplifier and the value of CC on the VC pin. The zero is
formed by the value of CC and the value of RC in series with
CC on the VC pin. The RC series network will have capacitor
values in the range of 0.1µF to 1.0µF and series resistor
values in the range of 100Ω to 1000Ω.
It is noted that the RC network on the VC pin forms the main
compensation network for the regulator loop. However, if
the load regulation compensation feature is used as explained in the section on fully-isolated flyback mode,
additional frequency compensation components are required. The load regulation compensation feature involves
the use of local positive feedback from the VC pin to the FB
pin. Thus, it is possible to add enough load regulation
compensation to make the loop oscillate. In order to
prevent oscillation, it is necessary to roll off this local
positive feedback at high frequencies. This is accomplished by placing a capacitor in parallel with the compensation resistor which is in series with the FB pin. A value
for this capacitor in the range of 0.01µF to 0.1µF is
recommended. The time constant associated with this RC
combination will be longer than that associated with the
loop bandwidth. Thus, transient response will be affected
in that settling time will be increased. However, this is
typically not as important as controlling the absolute
under or overshoot amplitude of the system in response to
load current changes which could cause deleterious system operation.
Switching Regulator Topologies
Two basic switching regulator topologies are pertinent to
the LT1103/LT1105, the flyback and forward converter.
The flyback converter employs a transformer to convert
one voltage to either a higher or lower output voltage. VOUT
in continuous mode is defined as:
VOUT = VIN • N •
DC
(1– DC)
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where N is the transformer turns ratio of secondary to
primary and DC is the duty cycle. This formula can be
rewritten in terms of duty cycle as:
DC =
(
VOUT
VOUT + N • VIN
)
It is important to define the full range of input voltage, the
range of output loading conditions and the regulation
requirements for a design. Duty cycle should be calculated
for both minimum and maximum input voltage.
In many applications, N can vary over a wide range without
degrading performance. If maximum output power is
desired, N can be optimized:
N(OPT ) =
(V
VOUT + Vf
(
)
M – VIN MAX – VSNUB
)
where
Vf = Forward voltage of the output diode
VM = Maximum switch voltage
VSNUB = Snubber clamp level – primary flyback
voltage.
In the isolated flyback mode, the LT1103/LT1105 sense
and regulate the transformer primary voltage VPRI during
“switch off” time. The secondary output voltage will be
regulated if VPRI is regulated. VPRI is related to VOUT by:
VPRI =
(VOUT + Vf)
N
This allows duty cycle for an isolated flyback converter to
be rewritten as:
DC = Duty Cycle =
(
VPRI
VPRI + VIN
)
An important transformer parameter to be determined is
the primary inductance LPRI. The value of this inductance
is a trade-off between core size, regulation requirements,
leakage inductance effects and magnetizing current ∆I.
Magnetizing current is the difference between the primary
current at the start of “switch on” time and the current at
the end of “switch on” time. If maximum output power is
needed, a reasonable starting value is found by assigning
∆I a value of 20% of the peak switch current (2A for the
LT1103 and set by the external FET rating used with the
LT1105). With this design approach, LPRI is defined as:
L PRI =
VIN

V 
( ∆I)(f)1 + IN 
 VPRI 
If maximum output power is not required, then ∆I can be
increased which results in lower primary inductance and
smaller magnetics. Maximum output power with an isolated
flyback converter is defined by the primary flyback voltage
and the peak allowed switch current and is limited to:
POUT(MAX) =
(
(VPRI )
 
2 
∆I
 VIN  IP –  – Ip R E
2
VPRI + VIN  

)
( )
where
R = Total “switch” on resistance
IP = Maximum switch current
E = Overall efficiency ≈ 75%
Peak primary current is used to determine core size for the
transformer and is found from:
IPRI =
(VOUT )(IOUT )(VPRI + VIN ) + ∆I
2
E( VPRI )( VIN )
A second consideration on primary inductance is the
transition point from continuous mode to discontinuous
mode. At light loads, the flyback pulse across the primary
will drop to zero before the end of “switch off” time. The
load current at which this starts to occur can be calculated
from:
2
VPRI • VIN )
(
IOUT(TRANSITION) =
(VPRI + VIN )2 (2VOUT )(f)(LPRI )
The forward converter as shown below is another
transformer-based topology that converts one voltage to
either a higher or a lower voltage.
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VOUT in continuous mode is defined as:
VOUT = VIN • N • DC
The secondary voltage charges up L1 through D1 when S1
is on. When S1 is off, energy in L1 is transferred through
free-wheeling diode D2 to C1. The extra transformer
winding and diode D3 are needed in a single switch
The isolated feedback path can take several forms. A
second transformer in a modulator/demodulator scheme
provides the isolation, but with significant complexity. An
optoisolator can be substituted for the transformer with a
savings in volume to be traded off with component
variations and possible aging problems with the
optoisolator transfer function. Finally, an extra winding
closely coupled to the output inductor L1 can sense the
flux in this element and give a representation of the output
voltage when S1 is off.
Simplified Forward Converter
L1
VIN
1:N
VOUT
D1
C1
D2
COMMON
D3
forward converter to define the switch voltage when S1 is
off. This “reset” winding limits the maximum duty cycle
allowed for the switch. This topology trades off reduced
transformer size for increased complexity and parts count.
A separate isolated feedback path is required for full
isolation from input to output because voltages on the
primary are no longer related to the DC output voltage
during switch off time.
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LT1103 FET Connection
15V
LT1103
VSW
LT1103 TA03
LT1105 FET Connection
15V
LT1105
VSW
ILIM
LT1103 TA04
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Setting Oscillator Frequency
Setting Overvoltage Lockout
OVLOTH
R2
LT1103/LT1105
LT1105
OVLO
R1
OSC
LT1103 TA09
COSC
LT1103 TA05
CHOOSE OVLOTH
CHOOSE 20kHz ≤ fOSC ≤ 200kHz
LET R1 = 5k
100µA
I
=
COSC = SF =
fOSC
∆V fOSC
2.5V fOSC
( )(
) (
)(
)
R2 =
(
)
OVLOTH
–1 R1
2.5V
DC ≅ 0.66 ⇒ 66%
Increasing Oscillator
Maximum Duty Cycle
Decreasing Oscillator
Maximum Duty Cycle
Synchronizing Oscillator Frequency
to an External Clock
5V
LT1105
LT1103/LT1105
LT1103/LT1105
500ns
OSC
COSC
5V
OSC
R
I1
OSC
1µF
0V
COSC
R
1:0.5
COSC
I1
LT1103 TA07
LT1103 TA08
LT1103 TA06
CHOOSE 0 ≤ DC ≤ 0.66
(6 – 9DC)
SOLVE FOR X ⇒ X =
2
0 ≤X≤3
CHOOSE 0.66 ≤ DC ≤ 1.0
(9DC – 6)
SOLVE FOR X ⇒ X =
2
0 ≤ X ≤ 1.5
⇒ I1 = X • I = X • 100µA
⇒ R = 1.75V
I1
COSC =
100µA
(2.5V)(fOSC )
⇒ I1 = X • I = X • 100µA
(3X – 2X )
⇒R=
2
• 1+
ISOLATION
BOUNDARY
9
COSC =
3.25V
I1
(
(
3X + 2X
100µA
• 1–
9
2.5V fOSC
)(
)
2
)
27
LT1103/LT1105
U
TYPICAL APPLICATIONS
LT1103 Ground Connections
15V
VIN
OSC
GND
VC
FB
VSW
SWITCH CURRENT PATH
KEEP RESISTANCE LOW
LT1103 TA11a
TO BIAS
WINDING OUTPUT
GND
SEPARATE
GROUND PATH
SWITCH CURRENT PATH
KEEP RESISTANCE LOW
15V
VIN
OSC
GND
VC
FB
VSW
LT1103 TA11b
TO BIAS
WINDING OUTPUT
LT1105 Ground Connections
HIGH CURRENT
GROUND PATH
GND
VSW
ILIM
FB
VIN
VC
TO BIAS
WINDING
OUTPUT
28
LT1103 TA12a
GND
LT1103/LT1105
U
PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
N8 Package
8-Lead PDIP (Narrow 0.300)
(LTC DWG # 05-08-1510)
0.400*
(10.160)
MAX
8
7
6
5
1
2
3
4
0.255 ± 0.015*
(6.477 ± 0.381)
0.300 – 0.325
(7.620 – 8.255)
0.009 – 0.015
(0.229 – 0.381)
(
+0.035
0.325 –0.015
8.255
+0.889
–0.381
)
0.045 – 0.065
(1.143 – 1.651)
0.130 ± 0.005
(3.302 ± 0.127)
0.065
(1.651)
TYP
0.100 ± 0.010
(2.540 ± 0.254)
0.125
(3.175) 0.020
MIN (0.508)
MIN
0.018 ± 0.003
(0.457 ± 0.076)
N8 1197
*THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm)
29
LT1103/LT1105
U
PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
N Package
14-Lead PDIP (Narrow 0.300)
(LTC DWG # 05-08-1510)
0.770*
(19.558)
MAX
14
13
12
11
10
9
8
1
2
3
4
5
6
7
0.255 ± 0.015*
(6.477 ± 0.381)
0.130 ± 0.005
(3.302 ± 0.127)
0.300 – 0.325
(7.620 – 8.255)
0.045 – 0.065
(1.143 – 1.651)
0.020
(0.508)
MIN
0.065
(1.651)
TYP
0.009 – 0.015
(0.229 – 0.381)
+0.035
0.325 –0.015
(
+0.889
8.255
–0.381
)
0.125
(3.175)
MIN
0.005
(0.125)
MIN
0.100 ± 0.010
(2.540 ± 0.254)
*THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm)
30
0.018 ± 0.003
(0.457 ± 0.076)
N14 1197
LT1103/LT1105
U
PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
T7 Package
7-Lead Plastic TO-220 (Standard)
(LTC DWG # 05-08-1422)
0.390 – 0.415
(9.906 – 10.541)
0.165 – 0.180
(4.191 – 4.572)
0.147 – 0.155
(3.734 – 3.937)
DIA
0.045 – 0.055
(1.143 – 1.397)
0.230 – 0.270
(5.842 – 6.858)
0.460 – 0.500
(11.684 – 12.700)
0.570 – 0.620
(14.478 – 15.748)
0.330 – 0.370
(8.382 – 9.398)
0.620
(15.75)
TYP
0.700 – 0.728
(17.780 – 18.491)
0.152 – 0.202
0.260 – 0.320 (3.860 – 5.130)
(6.604 – 8.128)
0.040 – 0.060
(1.016 – 1.524)
0.095 – 0.115
(2.413 – 2.921)
0.013 – 0.023
(0.330 – 0.584)
0.026 – 0.036
(0.660 – 0.914)
0.135 – 0.165
(3.429 – 4.191)
0.155 – 0.195
(3.937 – 4.953)
T7 (TO-220) (FORMED) 1197
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
31
LT1103/LT1105
U
TYPICAL APPLICATION
Minimum Parts Count Fully-Isolated Flyback 100kHz 50W Converter
OPTIONAL OUTPUT FILTER
MBR2045
85VAC TO 270VAC
+
+
!!
GER E!!
N
A
D
TAG
VOL
H
G
I
H
220k
1W
220µF
385V
499Ω
1.5KE300A
5W
+
MUR150
BRIDGE
RECTIFIER
+
LINE
FILTER
1N4148
16.2k
1%
VIN
39µF
25V
BUK426-800A
VSW
+
+
50V
470µF
WINDINGS FOR
OPTIONAL
±12VDC OUTPUTS
BAV21
BAV21
35V
3600µF
5V
10A
*OUTPUT CAPACITOR IS THREE 1200µF,
50V CAPACITORS IN PARALLEL TO
ACHIEVE REQUIRED RIPPLE CURRENT
RATING AND LOW ESR.
–
1000pF
100Ω
10µH
LT1103
10Ω
GND
5.36k
1%
TRANSFORMER DATA:
COILTRONICS - CTX110228-3
L(PRI) = 1.6mH
NPRI:NSEC = 1:0.05
NBIAS:NSEC = 1:0.27
15V
FB
+
OSC
VC
1µF
25V
390pF
330Ω
0.1µF
0.047µF
LT1103 TA01
Danger!! Lethal Voltages Present – See Text
Load Regulation
5.25
5.20
5.15
VOUT (V)
5.10
270VAC
5.05
220VAC
5.00
4.95
110VAC
4.90
85VAC
4.85
4.80
4.75
0
1
2
3
4
5
6
7
9
8
10
IOUT (A)
LT1103 TA14
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1241
High Speed Current Mode Pulse Width Modulators
Up to 500kHz Operation
LT1246
Off-Line Current Mode PWM
1MHz Operation
LT1248
Power Factor Controller
Programmable Frequency, 16-Pin SO
LT1249
Power Factor Controller
100kHz, SO-8
LT1508
Power Factor and PWM Controller
Voltage Mode
LT1509
Power Factor and PWM Controller
Current Mode
32
Linear Technology Corporation
11035fd LT/TP 0998 REV D 2K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 1992