LINER LT1509IN

LT1509
Power Factor and
PWM Controller
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DESCRIPTION
FEATURES
The LT ® 1509 is a complete solution for universal off-line
switching power supplies utilizing active power factor
correction. The PFC section is identical to the LT1248 PFC
controller except the EN/SYNC pin is removed because
PFC and PWM are synchronized internally.
PFC and PWM Single Chip Solution
Synchronized Operation up to 300kHz
99% Power Factor over 20:1 Load Current Range
Current Mode PWM
Instantaneous Overvoltage Protection
Dedicated Overvoltage Protection (OVP Pin)
Minimal Line Current Dead Zone
Typical 250µA Start-Up Supply Current
Line Switching Noise Filter
Low Quiescent Current: 13mA
Fast 2A Peak Current Gate Drivers
Separate Soft Start Controls
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The current mode PWM section (the LT1508 is the voltage-mode counterpart) contains all the primary side functions to convert the PFC preregulated high voltage output
to an isolated low voltage output. The PWM duty cycle is
internally limited to 47% (maximum 50%) to prevent
transformer saturation. PWM soft start begins when PFC
output reaches the preset voltage. In the event of brief line
loss, the PWM will be shut off when the PFC output voltage
drops below 73% of the preset value.
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APPLICATIONS
Universal Power Factor Corrected Power Supplies
and Preregulators
■
, LTC and LT are registered trademarks of Linear Technology Corporation.
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BLOCK DIAGRAM
VREF
VAOUT
7.5V
VREF
10
VCC
+
16V TO 10V
–
MOUT ISENSE
8
7
12
CAOUT
GND1
6
3
PKLIM VCC
5
17
RUN
7µA
+
2.2V
–
M1
–
VSENSE
–
14
EA
IAC
7.5V
+
IB
9
IM
IM =
25k
+
–
IA
CA
+
IA2IB
–
R
RUN
+
7.9V
Q
GTDR1
S
1
+
+
0.7V
OVP
–
–
11
SS1
R
200µA2
OSC
16V
GND2
14µA
2
16
–
+
CL
1V
–
–
+
14µA
SS2
PWM0K
–
1.2V
+
+
R
S
13
NOTE: PWM PULSE IS DELAYED BY 55% DUTY CYCLE AFTER PFC PULSE
15
RSET
55%
DELAY
+
7V to
4.7V
4
CSET
–
19
18
RAMP
VC
50µA
Q
GTDR2
20
R
200ns
BLANKING
16V
1500 • BD01
1
LT1509
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DESCRIPTION
By using fixed high frequency PWM current averaging
without the need for slope compensation, the LT1509
achieves far lower line current distortion with a smaller
magnetic element than systems that use either peak
current detection, or zero current switching approach, in
both continuous and discontinuous modes of operation.
the multiplier. Line current dead zone is minimized with
low bias voltage at the current input to the multiplier.
The LT1509 provides many protection features including
peak current limiting and overvoltage protection. Implemented with a very high speed process, the LT1509 can be
operated at frequencies as high as 300kHz.
The LT1509 also provides filtering capability to reject line
switching noise which can cause instability when fed into
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ABSOLUTE MAXIMUM RATINGS
PACKAGE/ORDER INFORMATION
Supply Voltage ........................................................ 27V
GTDR Current Continuous ...................................... 0.5A
GTDR Output Energy ................................................ 5µJ
IAC, RSET, PKLIM Input Current .............................. 20mA
VSENSE, OVP Input Voltage .................................... VMAX
RAMP, VC Input Voltage ............................................ 8V
ISENSE, MOUT Input Current ................................... ±5mA
Operating Junction Temperature Range
Commercial ........................................... 0°C to 100°C
Industrial .......................................... – 40°C to 125°C
Thermal Resistance (Junction-to-Ambient)
N Package ................................................... 100°C/W
SW Package ................................................ 120°C/W
ORDER PART
NUMBER
TOP VIEW
GTDR1 1
20 GTDR2
GND2 2
19 RAMP
GND1 3
18 VC
CSET 4
17 VCC
PKLIM 5
16 SS1
CAOUT 6
15 RSET
ISENSE 7
14 VSENSE
MOUT 8
13 SS2
IAC 9
12 VREF
VAOUT 10
11 OVP
N PACKAGE
20-LEAD PDIP
LT1509CN
LT1509CSW
LT1509IN
LT1509ISW
SW PACKAGE
20-LEAD PLASTIC SO WIDE
TJMAX = 125°C, θJA = 100°C/ W (N)
TJMAX = 125°C, θJA = 120°C/ W (SW)
Consult factory for Military grade parts.
ELECTRICAL CHARACTERISTICS
Maximum operating voltage (VMAX) = 25V, VCC = 18V, RSET = 15k to GND, CSET = 1nF to GND, IAC = 100µA, ISENSE = 0V, CAOUT = 3.5V,
VAOUT = 5V, OVP = VREF. No load on any outputs unless otherwise noted.
PARAMETER
Overall
Supply Current (VCC in Undervoltage Lockout)
Supply Current On
VCC Turn-On Threshold (Undervoltage Lockout)
VCC Turn-Off Threshold
Voltage Amplifier (PFC Section)
Voltage Amp Offset
Input Bias Current
Voltage Gain
Voltage Amp Unity-Gain Bandwidth
Voltage Amp Output High (Internally Clamped)
Voltage Amp Output Low
Voltage Amp Short-Circuit Current
2
CONDITIONS
VCC = Lockout Voltage – 0.2V
11.5V ≤ VCC ≤ VMAX
MIN
TYP
MAX
UNITS
●
15.5
9.5
0.25
13
16.5
10.5
0.45
19
17.5
11.5
mA
mA
V
V
●
– 10
10
– 250
mV
nA
dB
MHz
V
V
mA
●
●
●
VAOUT = 3.5V
VSENSE = 0V to 7V
●
70
●
11.3
●
VAOUT = 0V
●
3
– 25
100
3
13.3
1.1
8
2
17
LT1509
ELECTRICAL CHARACTERISTICS
Maximum operating voltage (VMAX) = 25V, VCC = 18V, RSET = 15k to GND, CSET = 1nF to GND, IAC = 100µA, ISENSE = 0V, CAOUT = 3.5V,
VAOUT = 5V, OVP = VREF. No load on any outputs unless otherwise noted.
PARAMETER
Current Amplifier (PFC Section)
Current Amp Offset Voltage
ISENSE Bias Current
Current Amp Voltage Gain
Current Amp Unity-Gain Bandwidth
Current Amp Output High
Current Amp Output Low
Current Amp Short-Circuit Current
Input Range, ISENSE, MOUT (Linear Operation)
Reference
Reference Output Voltage
VREF Load Regulation
VREF Line Regulation
VREF Short-Circuit Current
VREF Worst Case
Current Limit
PKLIM Offset Voltage
PKLIM Input Current
PKLIM to GTDR Propagation Delay
Multiplier
Multiplier Output Current
Multiplier Output Current Offset
Multiplier Maximum Output Current
Multiplier Gain Constant (Note 1)
IAC Input Resistance
Oscillator
Oscillator Frequency
CSET Ramp Peak-to-Peak Amplitude
CSET Ramp Valley Voltage
Overvoltage Comparator (PFC Section)
Comparator Trip Voltage Ratio (VTRIP / VREF)
Hysteresis
OVP Bias Current
OVP Propagation Delay
Gate Drivers (GTDR1 and GTDR2)
Max Output Voltage
Output High
Output Low (Device Unpowered)
Output Low (Device Active)
Peak Output Current
Rise and Fall Time
Max Duty Cycle (PFC)
Max Duty Cycle (PWM) (Note 2)
CONDITIONS
MIN
●
●
80
●
7.2
●
CAOUT = 0V
●
●
IREF = 0mA, TA = 25°C
– 5mA < IREF < 0mA
11.5V < VCC < VMAX
VREF = 0V
Load, Line, Temperature
PKLIM = – 0.1V
PKLIM Falling from 50mV to – 50mV
IAC = 100µA, RSET = 15k
RAC = 1M from IAC to GND
IAC = 450µA, RSET = 15k, VAOUT = 7V, MOUT = 0V
7.39
●
– 20
12
7.32
●
– 25
●
●
MAX
UNITS
±1
– 25
110
3
8.5
1.1
8
±4
– 250
mV
nA
dB
MHz
V
V
mA
V
7.50
5
5
28
7.5
7.60
– 50
400
●
kHz
kHz
V
V
1.05
0.35
0.2
100
1.06
15
17.5
0.9
0.5
0.2
2
25
96
1.5
1.0
0.4
●
1.04
OVP = 7.5V
●
0mA Load, 18V < VCC
– 200mA Load, 11.5V ≤ VCC ≤ 15V
VCC = 0V, 50mA Load (Sinking)
200mA Load (Sinking)
10mA Load
10nF from GTDR to GND
1nF from GTDR to GND
●
●
12
VCC – 3.0
●
●
●
90
44
mV
µA
ns
115
78
5.0
1.55
85
58
4.35
1.15
– 286
25
– 100
100
68
4.7
1.3
●
●
●
20
50
7.68
V
mV
mV
mA
V
35
15
●
2
17
1
µA
µA
µA
V –2
kΩ
35
– 0.05
– 260
0.035
25
IAC from 50µA to 1mA
RSET = 15k, CSET = 1000pF
RSET = 15k, CSET = 1500pF
3
– 0.3
TYP
– 0.5
– 235
1
50
V
µA
ns
V
V
V
V
V
A
ns
%
%
3
LT1509
ELECTRICAL CHARACTERISTICS
VCC = 18V, RSET = 15k to GND, CSET = 1nF to GND, IAC = 100µA, ISENSE = 0V, CAOUT = 3.5V, VAOUT = 5V, OVP = VREF. No load on any
outputs, unless otherwise noted.
PARAMETER
Soft Start Current
SS1 Current (PFC)
SS2 Current (PWM)
Comparators in PWM Section
RAMP Input Current
Current Limit Comparator (CL) Threshold
GTDR2 Switching Off Threshold at VC or at SS2
VC Input Current
PWMOK Comparator Low Threshold (in Terms of VREF)
VC Pin High Voltage (LT1509)
GTDR2 Turn-On Blanking Time
CONDITIONS
SS1 = 2.5V
SS2 = 1V
●
RAMP = 0V, VC = 1.6V
VC > 2.6V
RAMP = 0V
VC = 0V
●
●
●
●
●
The ● denotes specifications which apply over the full operating
temperature range.
IM
Note 1: Multiplier Gain Constant: K =
IAC (VAOUT – 2)2
TYP
MAX
5
5
12
12
30
30
µA
µA
– 0.3
1.1
–2
1.2
µA
V
V
µA
0.95
1
– 20
0.57
2.6
●
1mA into VC Pin
MIN
●
0.63
3.2
180
UNITS
– 80
0.70
3.8
V
ns
Note 2: GTDR2 (PWM) pulse is delayed by 53% duty cycle after GTDR1
(PFC) is set. See PFC/PWM Synchronization graph in the Typical
Performance Characteristics section.
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TYPICAL PERFORMANCE CHARACTERISTICS
PFC Voltage Amplifier Open-Loop
Gain and Phase
100
PFC Current Amplifier Open-Loop
Gain and Phase
0
80
100
–20
80
–20
GAIN
GAIN
–60
GAIN (dB)
GAIN (dB)
40
60
40
–80
20
–100
0
–120
10M
–20
PHASE
–40
–60
PHASE (DEG)
–40
PHASE (DEG)
60
20
PFC/PWM Synchronization
0
PFC (GTDR1)
53%
–80
PHASE
PWM (GTDR2)
0
–20
10
100
1k
10k 100k
FREQUENCY (Hz)
1M
LT1509 • TPC01
4
–100
10
100
1k
10k 100k
FREQUENCY (Hz)
1M
–120
10M
LT1509 • TPC02
TIME
LT1509 TPC03
LT1509
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TYPICAL PERFORMANCE CHARACTERISTICS
Reference Voltage vs
Temperature
Multiplier Current
300
7.536
VAOUT = 5.5V
VAOUT = 7V
7.512
VAOUT = 6.5V
7.500
VAOUT = 6V
IM (µA)
REFERENCE VOLTAGE (V)
7.524
7.488
7.476
VAOUT = 5V
150
VAOUT = 4.5V
7.464
VAOUT = 4V
7.452
VAOUT = 3.5V
7.440
7.428
–75 –50 –25 0 25 50 75 100 125 150
JUNCTION TEMPERATURE (°C)
0
0
VAOUT = 3V
VAOUT = 2.5V
500
250
IAC (µA)
LT1509 • TPC05
LT1509 • TPC04
Supply Current vs Supply Voltage
Start-Up Supply Current vs
Supply Voltage
GTDR Rise and Fall Time
400
16
550
15
500
TJ = –55°C
450
12
TJ = 125°C
TJ = 25°C
11
10
FALL TIME
200
9
RISE TIME
8
100
7
32
21
SUPPLY VOLTAGE (V)
0
10
20
30
40
LOAD CAPACITANCE (nF)
FREQUENCY (kHz)
350
300
250
200
150
MAXIMUM DUTY CYCLE
500
RSET = 10k
RSET = 15k
RSET = 20k
RSET = 30k
0
50
2200
LT1509 • TPC09
2
4
6 8 10 12 14 16 18 20
SUPPLY VOLTAGE (V)
MOUT Pin Characteristics
1.0
0.98
0.5
0.97
0.96
0.95
0.94
0.93
0.91
1800
1400
CSET CAPACITANCE (pF)
0
LT1509 • TPC08
0.99
50
1000
125°C
150
1.5
0.92
600
200
1.00
100
0
200
–55°C
25°C
250
GTDR1 Maximum Duty Cycle vs
RSET and CSET
Frequency vs RSET and CSET
400
300
LT1509 • TPC07
LT1509 • TPC06
450
350
50
MOUT CURRENT (mA)
10
0
400
100
NOTE: GTDR SLEWS
BETWEEN 1V AND 16V
6
5
SUPPLY CURRENT (µA)
300
13
TIME (ns)
SUPPLY CURRENT (mA)
14
0.90
200
RSET = 10k
RSET = 15k
RSET = 20k
RSET = 30k
600
1000
1800
1400
CSET CAPACITANCE (pF)
TJ = 125°C
TJ = 25°C
TJ = –55°C
0
–0.5
–1.0
–1.5
–2.0
–2.5
–3.0
–3.5
2200
LT1509 • TPC10
–4.0
–2.4
–1.2
1.2
0
MOUT VOLTAGE (V)
2.4
LT1509 • TPC11
5
LT1509
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TYPICAL PERFORMANCE CHARACTERISTICS
RSET Voltage vs Current
PKLIM Pin Characteristics
120
–360
TJ = 125°C
TJ = 25°C
TJ = –55°C
100
–240
60
PKLIM CURRENT (µA)
VRSET – VREF (mV)
80
40
20
0
–20
–40
–180
–120
–60
0
60
120
–60
180
–80
240
–100
0
–0.2
–0.4
–0.8
–0.6
RSET CURRENT (mA)
–1.0
LT1509 • TPC12
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PIN FUNCTIONS
TJ = 125°C
TJ = 25°C
TJ = –55°C
–300
300
–0.8
–0.4
0.4
0
PKLIM VOLTAGE (V)
0.8
LT1509 • TPC13
(For application help with the PFC portion of this chip, see the LT1248 data sheet)
PFC SECTION
GTDR1 (Pin 1): The PFC MOSFET gate driver is a fast
totem pole output which is clamped at 15V. Capacitive
loads like the MOSFET gates may cause overshoot. A gate
series resistor of at least 5Ω will prevent the overshoot.
GND2 (Pin 2): Power Ground. High current spikes occur
in this line when either GTDR1 or GTDR2 switches low.
GND1 (Pin 3): Analog Ground.
CSET (Pin 4): The capacitor from this pin to GND and RSET
determines oscillator frequency. The oscillator ramp is 5V
and the frequency = 1.5/(RSET CSET).
PKLIM (Pin 5): The threshold of the peak current limit
comparator is GND. To set current limit, a resistor divider
can be connected from VREF to current sense resistor.
IAC (Pin 9): This is the AC line voltage sensing input to the
multiplier. It is a current input that is biased at 2V to
minimize the crossover dead zone caused by low line
voltage. At the pin, a 25k resistor is in series with the
current input, so that a lowpass RC can be used to filter out
the switching noise coming down from the line with a high
line impedance environment.
VAOUT (Pin 10): This is the output of the voltage error
amplifier. The output is clamped at 13.5V. When the
output goes below 2.5V, the multiplier output current is
zero.
CAOUT (Pin 6): This is the output of the current amplifier
that senses and forces the line current to follow the
reference signal that comes from the multiplier by commanding the pulse width modulator. When CAOUT is low,
the modulator has zero duty cycle.
OVP (Pin 11): This is the input to the overvoltage comparator. The threshold is 1.05 times the reference voltage.
When the comparator trips, the multiplier, which is quickly
inhibited, blanks PFC switching to prevent further overshoot. This pin is also the input to the PWMOK comparator
that releases the PWM soft start (SS2) after the PFC output
gets close to the final voltage and has a hysteresis of
approximately 150V for 382V PFC output.
ISENSE (Pin 7): This is the inverting input of the current
amplifier. This pin is clamped at – 0.6V by an ESD protection diode.
VREF (Pin 12): This is the 7.5V reference. When VCC goes
low, VREF will stay at 0V. VREF biases most of the internal
circuitry and can source up to 5mA externally.
MOUT (Pin 8): This is the multiplier high impedance
current output and the noninverting input of the current
amplifier. This pin is clamped at – 0.6V and 3V.
VSENSE (Pin 14): This is the inverting input to the voltage
amplifier.
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LT1509
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PIN FUNCTIONS
(For application help with the PFC portion of this chip, see the LT1248 data sheet)
RSET (Pin 15): A resistor from RSET to GND sets the
oscillator charging current and the maximum multiplier
output current which is used to limit the maximum line
current.
IM(MAX) = 3.75V/RSET
SS1 (Pin 16): Soft Start. SS1 is reset to zero for low VCC.
When VCC rises above lockout threshold, SS1 is released
to ramp up at a rate set by the internal 12µA current source
and an external capacitor. During this ramp up, PFC
reference voltage is equal to SS1 voltage. After SS1 rises
past 7.5V, reference voltage remains at 7.5V.
VCC (Pin 17): This is the supply for the chip. The LT1509
has two fast gate drivers required to fast charge high
power MOSFET gate capacitances. Good supply bypassing is required consisting of a 0.1µF ceramic capacitor in
parallel with a low ESR electrolytic capacitor (56µF or
higher) in close proximity to IC GND.
PWM SECTION
SS2 (Pin 13): PWM Soft Start. The comparator PWMOK
monitors the OVP pin and releases the SS2 after the PFC
output gets close to the final voltage.
VC (Pin 18): PWM current mode control voltage. Normally
connects to the optocoupler amplifier output. A pull-up
current of 50µA flows out of the pin.
RAMP (Pin 19): PWM current mode current sense input
with current limit set to 1V.
GTDR2 (Pin 20): The PWM MOSFET gate driver is a 1.5A
fast totem pole output. It is clamped at 15V. Capacitive
loads like the MOSFET gates may cause overshoot. A gate
series resistor of at least 5Ω will prevent the overshoot.
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APPLICATIONS INFORMATION
Voltage Error Amplifier (PFC Section)
C2
0.047µF
The voltage error amplifier has a 100dB DC gain and 3MHz
unity-gain frequency. The output is internally clamped at
13.3V with VCC = 18V. Maximum error amp output voltage
decreases to VCC – 1.5V for VCC less than 12V. The
noninverting input is tied to the 7.5VREF through a diode
and can be pulled down with the SS1 pin. Referring to
Figure 1, VOUT = VREF [(R1 + R2)/R2]. With R1 = 1M and
R2 = 20k, VOUT = 382V. R1 through R4, C1 and C2 form the
compensation for the voltage loop. Gain of the voltage
error amp with the values shown is given by:
VAOUT
= –
VOUT
1+j
R1
1M
R3
20k
VSENSE
R4
330k
–
+
VAOUT
ERROR AMP
VREF = 7.5V
R2
20k
LT1509
OVP
–
+
1.05VREF
f
1
OVERVOLTAGE
COMPARATOR
LT1509 • F01
) )
Figure 1
(j)(f)(6.6) 1 + j f
11
The small-signal gain for the remaining portion of the
voltage loop for frequencies below the current loop bandwidth is (see Figure 2):
VOUT
VIN
=
VAOUT (5π)(j)(f)(COUT)(VOUT)
C1
0.47µF
REGULATOR OUTPUT
VOUT = 382V
(RREF)(PIN)
RS(RIAC + 25k)
With VIN = 120VAC, PIN = 150W, RS = 0.15Ω, RREF = 4k,
RIAC = 1M, VOUT = 382V and COUT = 470µF, VOUT/VAOUT =
85/(j)(f). At very low frequencies, the loop has a – 40dB/
decade slope. Additional zero-pole compensation is added
at 1Hz and 11Hz. The resulting loop gain and phase margin
is shown in Figure 3. The unity-gain bandwidth is low
compared to 120Hz, which results in low distortion and a
high power factor.
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LT1509
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APPLICATIONS INFORMATION
VIN
L
IIN
RS
0.15Ω
+
VIN
–
D1
RREF
4k
VOUT
COUT
470µF
C4
300pF
R5
4k
VCA(OUT) (VOSC)(L)(fSW)
≤
VRS
(VOUT)(RS)
C3
0.001µF
R6
20k
To avoid subharmonic oscillations, the amplified downslope
of the inductor current must be less than the slope of the
oscillator ramp.
=
VIN
ISENSE
MOUT
RIAC
1M
IM
CAOUT
–
+
(5V)(500µH)(100k)
= 4.4
(382V)(0.15Ω)
CA
LT1509
IAC
If the current amplifier gain at 100kHz is less than 4.4,
there will be no subharmonic oscillation. The open-loop
gain of the current loop is given by:
1509 • F02
VRS
Figure 2
VCA(OUT)
60
80
60
45
40
30
20
15
0
0
–20
–15
–40
–30
1
10
100
Figure 3
Current Amplifier (PFC Section)
The current amplifier has a 110dB DC gain, 3MHz unitygain frequency and a 2V/µs slew rate. It is internally
clamped at 8.5V. Note that in the current averaging operation, high gain at twice the line frequency is necessary to
minimize line current distortion. Because CAOUT may need
to swing 5V over one line cycle at high line condition,
20mV AC will be needed at the inputs of the current
amplifier for a gain of 260 at 120Hz. Especially at light load
when the current loop reference signal is small, lower gain
will distort the reference signal and line current. But, if
signal gain at switching frequency is too high, the system
behaves more like a current mode system and can cause
subharmonic oscillation.
80
60
60
45
40
30
20
15
0
0
–20
–40
100
PHASE MARGIN (DEG)
LT1509 • F03
8
The current error amp, with R5 = 4k, R6 = 20k, C3 =
0.001µF and C4 = 300pF, provides zero pole compensation resulting in 16kHz loop crossover frequency. The
current amp gain at 100kHz is 1.7. The resulting current
loop gain and phase margin is shown in Figure 4.
1k
FREQUENCY (Hz)
(VOUT)(RS)
(j)(2πf)(L)(VOSC)
(382V)(0.15Ω)
3648
=
(j)(2πf)(500µH)(5V) (j)(f)
CURRENT LOOP GAIN (dB)
0.1
PHASE MARGIN (DEG)
LOOP GAIN (dB)
=
=
–15
1k
10k
100k
–30
1M
FREQUENCY (Hz)
LT1509 • F04
Figure 4
Multiplier
The multiplier has high noise immunity and superior
linearity over its full operating range. The current gain is
IM = (IACIEA2)/(200µA2) with IEA = (VAOUT – 2V)/ 25k. The
error amplifier output voltage required at the input to the
multiplier is:
LT1509
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APPLICATIONS INFORMATION
VAOUT = 2 +
(PIN)(RS)(25)(RIAC + 25k)
(VIN2)(RREF)
See Figure 2 for RREF.
VAOUT is squared in the multiplier, resulting in excellent
performance over a wide range of output power and input
voltage without the addition of feedforward line frequency
ripple. Care must be taken to avoid feeding switching
frequency noise into the multiplier from the IAC pin. An
internal 25k is provided in series with the low impedance
multiplier input so that only a capacitor from the IAC pin to
GND1 is required to filter noise. The maximum multiplier
output current, which ultimately limits the input line current, is set by a resistor from the RSET pin to GND1
according to the formula: IM(MAX) = 3.75V/RSET. Figure 5
shows IM versus IAC for various values of VAOUT. Note that
Figure 5 data was taken with RSET = 15k.
300
VAOUT = 5.5V
VAOUT = 7V
VAOUT = 6.5V
IM (µA)
VAOUT = 6V
VAOUT = 5V
150
VAOUT = 4.5V
VAOUT = 4V
VAOUT = 3.5V
0
0
250
IAC (µA)
VAOUT = 3V
VAOUT = 2.5V
500
LT1509 • F05
Figure 5. Multiplier Current IM vs IAC and VAOUT
Oscillator Frequency and Maximum
Line Current Setting
The oscillator frequency is set by RSET and CSET. RSET is
the resistor from the RSET pin to GND1 and CSET is the
capacitor from the CSET pin to GND1. RSET should be
determined first. The oscillator frequency, which is equal
to the switching frequency for both the PFC and PWM
section, is determined by:
1.5
fOSC =
(RSET)(CSET)
The multiplier output acts as the command signal to the
current loop error amplifier. During steady-state operation
the voltage across RREF = (IM)(RREF) = (IIN)(RS). Based on
this the value for RS is determined by:
RS ≤
(IM(MAX))(RREF)(VIN)(eff)
POUT √2
with RSET = 15k, IM(MAX) = 3.75/15k = 250µA. For a 300W
converter with an efficiency (eff) of 0.8 at low line (90VRMS)
and RREF set to 4k, RS should be less than:
(250µA)(4k)(90VAC)(0.8)
300W√2
= 0.169Ω
A 0.15Ω resistor will yield a maximum peak input current
of (IM(MAX))(RREF/RS) = (250µA)(4k)/0.15Ω = 6.67A. For
a 100kHz switching frequency with RSET = 15k, CSET = 1.5/
(100kHz)(15k) = 1nF. For added protection the LT1509
provides a second independent current limit comparator.
When the input voltage to the comparator (PKLIM pin) dips
below 0V, GTDR1 pin quickly goes low turning off the PFC
power switch. A resistor divider from VREF to RS (Figure 6)
senses the voltage across the line current sense resistor
(RS) and limits the peak input line current to [(7.5V/R1) +
50µA] (R2/RS). The 50µA represents the PKLIM input
current which flows out of the PKLIM pin. With R1 = 10k
and R2 = 1.8k, IIN = 9.6A peak above the 6.67A peak
average plus the input inductor peak ripple current.
Always use RSET to set the primary line current limit. The
PKLIM comparator is only for secondary protection. When
the line current reaches the primary limit, VOUT can no
longer be supported with the given input current and
begins to fall. System stability is maintained by the current
loop which is controlled by the current amplifier. When the
R2
1.8k
R1
10k
7.5V
LT1509
VREF
+
–
RS
0.15Ω
IPKLIM
PKLIM
C1
1nF
ILINE
C1 IS TO REJECT NOISE, CURRENT
LIMIT DELAY IS ABOUT 2µs
–
+
LT1509 • F06
Figure 6
9
LT1509
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APPLICATIONS INFORMATION
0.047µF
line current reaches the secondary limit, the comparator
takes over control and hysteresis may occur causing
audible noise.
0.47µF
R1
1M
Overvoltage Protection (PFC Section)
Because of the slow loop response necessary for power
factor correction, output overshoot can occur following a
sudden load reduction or removal. To protect downstream
components, the LT1509 provides an overvoltage comparator which senses the output voltage and quickly
reduces the line current demand. Referring back to Figure
1, VOUT is 382V and during normal operation, since no
current flows in R3, 7.5V appears at both the VSENSE and
OVP pins. When VOUT overshoots its preset value, the
overcurrent from R1 will flow through R2 as well as R3.
The voltage amplifier feedback will keep VSENSE at 7.5V.
Therefore, the equivalent AC resistance seen by the OVP
pin is R2 in parallel with R3 or 10k. With these values and
the overvoltage comparator trip level internally set at
1.05VREF, the comparator trips when VOUT overshoots
10%. Overvoltage trip level is given by:
(%)VOUT = 5%
(
R2 + R3
R3
)
For additional protection, the OVP pin can be connected
to VOUT through an independent resistor divider (see
Figure 7). This ensures overvoltage protection during
safety agency abnormal testing conditions, such as
opening R1 or shorting R2.
The output of the multiplier looks like a high impedance
current source. In the current loop, offset line current is
determined by multiplier offset current and input offset
voltage of the current error amplifier. A – 4mV current
amplifier VOS translates to 27mA line current and 6.7W
input power for 250VAC line if a 0.15Ω sense resistor is
used. Under a no-load condition or when the load power
is less than the offset output power, the offset line current
could slowly charge the output to an overvoltage level.
This is because the best the overvoltage comparator can
do is to reduce the multiplier output current to zero.
Unfortunately, this does not guarantee zero output current
if the current amplifier has offset. To regulate VOUT under
10
330k
VOUT
R4
1.05M
VSENSE
–
VAOUT
R2
20k
+
ERROR
AMP
OVP
R5
20k
–
LT1509
+
OVERVOLTAGE
COMPARATOR
1.05VREF
VOUT = 382V
OVERVOLTAGE = 420V
1509 • F07
Figure 7
this condition, the amplifier M1 (see Block Diagram)
becomes active. When VAOUT reduces to 2.2V, M1 supplies up to 7µA of current to the resistor at the ISENSE pin
in order to cancel a negative VOS and keep VOUT error to
within 2V.
Undervoltage Lockouts and Soft Start
The LT1509 turns on when VCC reaches 16V and remains
on until VCC falls below 10V, whereupon the chip enters the
lockout state. In the lockout state, the oscillator is off and
the VREF and gate driver pins remain low. A capacitor from
SS1 to GND1 determines the ramp-up time of the PFC
section. SS1 is released from a zero when VCC rises above
the lockout threshold. Once released, an internal 14µA
current source ramps the voltage error amplifier’s reference voltage to 7.5V. SS1 voltage then continues beyond
7.5V. A second capacitor from SS2 to GND1 determines
the start-up time from the PWM section. A PWMOK
comparator (see Block Diagram) holds SS2 low until the
OVP pin reaches 7V. This corresponds to the PFC output
voltage reaching approximately 93% of its preset voltage.
SS2 is diode coupled to the PMW comparator which is
connected to the VC pin by a second diode. Holding SS2
low at any time will disable PWM output. Once released,
the 14µA current source ramps the PWM comparator
LT1509
U
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APPLICATIONS INFORMATION
input up to VC and then the SS2 voltage continues beyond
VC. The PWMOK comparator contains hysteresis and will
pull SS2 low disabling the PWM section if the PFC output
voltage falls below approximately 62% of its preset value
(240V with nominal 382V output).
Output Capacitor (PFC Section)
Start Up and Supply Voltage
The peak-to-peak 120Hz PFC output ripple is determined by:
The LT1509 draws only 250µA before the chip starts at
16V on VCC. To trickle start, a 91k resistor from the power
line to VCC supplies trickle current, and C4 holds VCC up
while switching starts (see Figure 8); then the auxiliary
winding takes over and supplies the operating current.
Note that D3 and the larger values of C3 are only necessary
for systems that have sudden large load variations down
to minimum load and/or very light load conditions. Under
these conditions the loop may exhibit a start/restart mode
because switching remains off long enough for C4 to
discharge below 10V. Large values for C3 will hold VCC up
until switching resumes. For less severe load variations D3
is replaced with a short and C3 is omitted. The turns ratio
between the primary winding determines VCC
according to :
for 382V VOUT and 18V VCC, Np/Ns ≈ 19.
R1
91k
1W
D1
D3
+
D2
+
VCC
C1
2µF
C2
2µF
+
C3
390µF
+
C4
100µF
LT1509 • F08
Figure 8
where ILOAD(DC) is the DC load current of the PWM stage
and Z is the capacitor impedance at 120Hz.
For 470µF, impedance is 2.8Ω at 120Hz. At 335W load,
ILOAD(DC) = 335V/382V = 0.88A, VP-P = (2)(0.88)(2.8Ω) =
5V. If less ripple is desired higher capacitance should be
used. The selection of the output capacitor is based on
voltage ripple, hold-up time and ripple current. Assuming
the DC converter (PWM section) is designed to operate
with 240V to 382VIN , the minimum hold-up time is a
function of the energy storage capacity of the capacitor:
tHOLD =
(0.5)COUT
(382V – 0.5VP–P)2 – 240V2
POUT
I120HZ ≈ ILOAD(DC) √2
MAIN INDUCTOR
NP
NS
VP-P = 2ILOAD(DC)(Z)
with COUT = 470µF, VP-P = 11.5V, and POUT = 335W,
tHOLD = 60ms which is 3.6 line cycles at 60Hz. The ripple
current can be divided into two major components. The
first is the 120Hz component which is related to the DC
load current as follows:
VOUT
N
= P
VCC – 2V NS
LINE
GTDR2 (PWM) pulse is synchronized to GTDR1 (PFC) pulse
with 53% duty cycle delay to reduce RMS ripple current in the
output capacitor. See PFC/PWM Synchronization graph in
the Typical Performance Characteristics section.
The second component is made up of switching frequency
components due to the PFC stage charging the capacitor
and the PWM stage discharging the capacitor. For a 300W
output PFC forward converter running from an input
voltage of 100VRMS, the total high frequency ripple current
was measured to be 1.79ARMS.
For the United Chemicon KMH 450V capacitor series,
ripple current at 100kHz is specified 1.43 times higher
than the 120Hz limit.
11
LT1509
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APPLICATIONS INFORMATION
The total equivalent 120Hz ripple in the output capacitor
can be calculated by:
( )
I
I120HZ2 + HF
1.43
IRMS =
∆TO = ∆TK
2
For ILOAD(DC) = 0.88A, 1120Hz = 0.62A and the equivalent
120Hz ripple current is:
0.622 +
( )
1.79 2
= 1.4ARMS
1.43
(105°C + ∆TK) – (TA + ∆TO)
10
L = (LO)2
where
L = Expected life time
LO = Hours of load life at rated ripple current and rated
ambient temperature
∆TK = Capacitor internal temperature rise at rated
condition. ∆TK = (I2R)/(KA), where I is the rated current, R is capacitor ESR and KA is a volume constant.
TA = Operating ambient temperature
∆TO = Capacitor internal temperature rise at operating
condition
Table 1. PFC Capacitor RMS Ripple Current
200W
300W
VINRMS
I120HZ
IHF
I120HZ
IHF
I120HZ
IHF
100
0.2
0.6
0.41
1.18
0.62
1.79
120
0.2
0.5
0.41
0.97
0.62
1.45
230
0.2
0.53
0.41
0.87
0.62
1.26
12
2
L = (2000)(2)
(105°C + 5°C) – (60 + 3.3°C)
10
= 50,870 Hours
Table 1 lists the ripple current components from lab
measurements for various output powers and line voltages. The 120Hz ripple current rating at 105°C ambient is
1.72A for the 470µF KMH 35mm × 50mm capacitor. The
expected life of the output capacitor may be calculated
from thermal stress analysis:
100W
( ) ( )
2
IRMS
1.4A
= 5°C
= 3.3°C
1.72A
1.72A
Assuming the operating ambient temperature is 60°C, the
approximate lifetime is:
IHF = 100kHz Ripple Current.
IRMS =
In our example, LO = 2000 hours assuming ∆TK = 5°C at
rated 1.72A. ∆TO can then be calculated from:
For longer life a capacitor with a higher ripple current rating
or parallel capacitors should be used.
PWM Comparators
The LT1509 includes two comparators in the PWM section
which implement peak current mode control. The primary
current sense voltage is fed into the RAMP pin. The VC or
Control Voltage pin sets the primary peak current level. An
additional current limit comparator turns GTDR2 off in the
event the RAMP pin voltage exceeds 1V. Referring to the
Block Diagram, there is a 1.2V offset between the RAMP
and VC pin. This feature simplifies the connection to an
optocoupler because the VC pin no longer has to be pulled
all the way to ground to inhibit switching. On-chip blanking
avoids reset due to leading edge noise.
Typical Application
Figure 9 shows a 24VDC, 300W power factor corrected,
universal input supply. The 2-transistor forward converter
offers many benefits including low peak currents,
nondissipative snubber, 500VDC switches and automatic
core reset guaranteed by the LT1509’s 50% maximum
duty cycle.
20k
1%
20k
1%
9
11
GND1
3
GND2
2
IAC
OVP
4700pF
"Y"
0.1
"X"
0.047µF
14 VSENSE
0.47µF
0.0047µF
0.1
"X"
0.1
"X"
0.001µF
1µF
FILM
15k
15
RSET
15V
+
16
SS1
200µF
20
VREF
2k
VC
18
RAMP 19
17
1µF
FILM
–
+
1.2V
GTDR2
+
330µF
35V
LT1431
1k
2N2222A
220Ω
GND-F COMP
6
2
1
COLL
2.2k
2.2k
470Ω
220Ω
100pF
+
C1
1µF
400V
Figure 9. 24V, 300W Off-Line PFC Supply
0.01µF
CNY17-3
2N2222A
100pF
1N5819
IRFP450
MURH860CT
(DUAL)
330Ω
FUJI
ERA82-004
0.6A/40VR
20k
15V
1N5819
20Ω
2.2µF
50V
2.2µF
50V
6
1
CAOUT GTDR1
+
+
VCC
20k
0.047µF
7
ISENSE
0.001µF
300pF
4.02k
1%
ERA82-004
ERA82-004
T1
RT1 = KETEMA S65T SURGE GARD
T1 = COILTRONICS CTX02-12378-2, (407) 241-7876
T3 = BI TECHNOLOGY HM41-11510, (714) 447-2345
C1 = ELECTRONIC CONCEPTS 5MP12J105K
R1 = JW MILLER/FUKUSHIMA MPC71
BR1= GENERAL INSTRUMENTS KBU6J
13
SS2
LT1509
5 8
PKLIM MOUT
4.02k
1%
R1
0.15Ω
5W
Danger!! Lethal Voltages Present
NOTE: UNLESS OTHERWISE SPECIFIED
1. ALL RESISTORS 1/4W, 5%
2. ALL CAPACITANCE VALUES IN MICROFARADS
4
CSET
1.8k
10k
12
VREF
0.1µF
VREF
0.001µF
10
RT1
VAOUT
330k
Danger!! Lethal Voltages Present
In This Section
499k
1%
499k
1%
499k
1%
382VBUS
499k
1%
VIN
90VAC TO 1M
264VAC 1/2W
BR1
91k
2W
GND-S
5
–
+
0.1µF
3
V+
20k
20Ω
10:15
TURNS
RTOP
7
REF 8
RMID
4
100Ω
OUTPUT COM
3.4k
1%
1µF
63V
FILM
+
+
IRF840
MUR150
2000pF
10Ω,
2W
0.51Ω, 2W
RG ALLEN
RPS2
(× 2)
67µH
39T 12AWG
T150-52
4700pF
"Y"
MUR150
IRF840
470µF, 50V
NICHICON
PL12,5X25
(× 3)
+
20k
2200pF
"Y"
20k
15V
1N965
(× 2)
30.1k
1%
10k
1%
24.9k
1%
VREF
10Ω
0.0022µF
2N2907
10Ω
1µF FILM
T3
470µF
450V
382VBUS
T2
T2 7 TURNS
0.9" × 0.005" Cu
ETD44-P
LPRI = 3.1mH
G1
FEP
30DP
(DUAL)
1000pF
10Ω
1W
24VOUT
12.5A
17 TURNS
26AWG
TRI-FILAR
17 TURNS
26AWG
TRI-FILAR
U
U
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T1
APPLICATIONS INFORMATION
U
4700pF
"Y"
+
–
6A
FAST
+
–
VIN
LT1509
13
LT1509
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APPLICATIONS INFORMATION
An LT1431 reference/amplifier coupled to a low cost
optoisolator closes the loop from secondary side to primary side. Unity loop frequency is a conservative 3kHz.
Figure 10 shows the output voltage’s response with a 2A
to almost 10A current step. Output voltage is maintained
to within 0.5V during the load step. Efficiency versus
power and line voltage is shown in Figure 11. The PFC
preregulator alone has efficiency numbers between 90%
and 97% over line and load.
voltage, and changes as necessary, in order to maintain
constant bank voltage. The forward converter sees a
voltage input of 382VDC unless the line voltage drops out,
in which case the 470µF main capacitor discharges to
240VDC before the PWM stage is shut down. Compared to
a typical off-line converter, the effective input voltage
range of the forward converter is much smaller, simplifying the design. Additionally, the higher bus voltage provides greater hold-up times for given capacitor size.
A 3-turn secondary added to the 70-turn primary of T1
bootstraps VCC to about 15V supplying the chip’s 13mA
requirement as well as about 39mA to cover the gate
current of the three FETs and high side transformer. A
0.15Ω sense resistor is used to sense input current and
servo to the command created by the outer voltage and
multiplier. Thus the input current follows the input line
Because the high side transformer effectively delays the
turn-on reverse recovery spike past the end of the built-in
blanking time, an external blanking transistor is needed.
Controlling the output current during an output short
circuit depends on the duty cycle reducing to a small
fraction of steady state. An additional transistor disables
blanking during turn-on and output short circuit.
5A/DIV
0.5V/DIV
Figure 10
90
200W/300W
EFFICIENCY (%)
85
100W
80
75
30W
70
90
132
180
250
VRMS
LT1509 • F11
Figure 11
14
LT1509
U
PACKAGE DESCRIPTION
Dimension in inches (millimeters) unless otherwise noted.
N Package
20-Lead PDIP (Narrow 0.300)
(LTC DWG # 05-08-1510)
1.040*
(26.416)
MAX
20
19
18
17
16
15
14
13
12
11
1
2
3
4
5
6
7
8
9
10
0.255 ± 0.015*
(6.477 ± 0.381)
0.130 ± 0.005
(3.302 ± 0.127)
0.300 – 0.325
(7.620 – 8.255)
0.009 – 0.015
(0.229 – 0.381)
0.045 – 0.065
(1.143 – 1.651)
0.015
(0.381)
MIN
+0.025
0.325 –0.015
0.065
(1.651)
TYP
0.005
(0.127)
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)
(
+0.635
8.255
–0.381
)
0.018 ± 0.003
(0.457 ± 0.076)
0.125
(3.175)
MIN
N20 0695
SW Package
20-Lead Plastic Small Outline (Wide 0.300)
(LTC DWG # 05-08-1620)
0.496 – 0.512*
(12.598 – 13.005)
20
19
18
17
16
15
14
13
12
11
0.394 – 0.419
(10.007 – 10.643)
NOTE 1
1
2
3
4
5
6
7
8
9
10
0.291 – 0.299**
(7.391 – 7.595)
0.010 – 0.029 × 45°
(0.254 – 0.737)
0.093 – 0.104
(2.362 – 2.642)
0.037 – 0.045
(0.940 – 1.143)
0° – 8° TYP
0.009 – 0.013
(0.229 – 0.330)
NOTE 1
0.016 – 0.050
(0.406 – 1.270)
0.050
(1.270)
TYP
0.014 – 0.019
(0.356 – 0.482)
TYP
0.004 – 0.012
(0.102 – 0.305)
SOL20 0695
NOTE:
1. PIN 1 IDENT, NOTCH ON TOP AND CAVITIES ON THE BOTTOM OF PACKAGES ARE THE MANUFACTURING OPTIONS
THE PART MAY BE SUPPLIED WITH OR WITHOUT ANY OF THE OPTIONS.
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
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.
15
LT1509
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1084
5A Low Dropout Linear Regulator
Good for Post Regulation of Switching Power Supplies
LT1105
Simplified Off-Line Controller
Solution for Universal Off-Line Inputs with Output to 100W
LT1241-5
High Frequency Current Mode PWM Controller
Operates at Oscillator Frequencies up to 500kHz
LT1247
High Frequency Current Mode PWM Controller
Operates at Oscillator Frequencies up to 1MHz
LT1248
Full-Feature Average Current Mode Power Factor Controller
Provides All Features in 16-Lead Package
LT1249
Minimal Parts Count Power Factor Controller
Simplified PFC Design
LT1508
Power Factor and PWM Controller
Voltage Mode PWM
16
Linear Technology Corporation
LT/GP 1295 10K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507 ● TELEX: 499-3977
 LINEAR TECHNOLOGY CORPORATION 1995