LINER LT1943 High current quad output regulator for tft lcd panel Datasheet

LT1943
High Current Quad Output
Regulator for TFT LCD Panels
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FEATURES
DESCRIPTIO
■
The LT®1943 quad output adjustable switching regulator
provides power for large TFT LCD panels. The device,
housed in a low profile 28 pin thermally enhanced TSSOP
package, can generate a 3.3V or 5V logic supply along with
the triple output supply required for the TFT LCD panel.
Operating from an input range of 4.5V to 22V, a step-down
regulator provides a low voltage output VLOGIC with up to
2A current. A high-power step-up converter, a lowerpower step-up converter and an inverting converter provide the three independent output voltages AVDD, VON and
VOFF required by the LCD panel. A high-side PNP provides
delayed turn-on of the VON signal and can handle up to
30mA. Protection circuitry ensures that VON is disabled if
any of the four outputs are more than 10% below the
programmed voltage.
■
■
■
■
■
■
■
■
4 Integrated Switches: 2.4A Buck, 2.6A Boost,
0.35A Boost, 0.35A Inverter (Guaranteed Minimum
Current Limit)
Fixed Frequency, Low Noise Outputs
Soft-Start for all Outputs
Externally Programmable VON Delay
Integrated Schottky Diode for VON Output
PGOOD Pin for AVDD Output Disconnect
4.5V to 22V Input Voltage Range
PanelProtectTM Circuitry Disables VON Upon Fault
Available in Thermally Enhanced 28-Lead TSSOP
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APPLICATIO S
■
■
Large TFT-LCD Desktop Monitors
Flat Panel Televisions
All switchers are synchronized to an internal 1.2MHz
clock, allowing the use of low profile inductors and ceramic capacitors throughout. A current mode architecture
provides excellent transient response. For best flexibility,
all outputs are adjustable. Soft-start is included in all four
channels. A PGOOD pin can drive an optional PMOS pass
device to provide output disconnect for the AVDD output.
, LTC and LT are registered trademarks of Linear Technology Corporation.
PanelProtect is a trademark of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
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TYPICAL APPLICATIO
VIN, 8V TO 20V
VOFF
–5.5V
50mA
1µF
10µF
0.47µF
2.2µF
10µH
33µH
10µH
88.7k
44.2k
SW4
SW3
VIN
10.0k
10pF
SW2
0.015µF
RUN-SS
10µH
0.015µF
SS-234
FB4
LT1943
0.047µF
CT
PGOOD
BIAS
PGOOD
0.22µF
E3
FB3
16.2k
FB1
VC1
10.0k
VC2
VC3
10.0k
GND
SGND
VC4
RUN-SS
2V/DIV
VLOGIC
5V/DIV
AVDD
10V/DIV
VOFF
10V/DIV
VE3
20V/DIV
VON
50V/DIV
IIN(AVG)
1A/DIV
274k
SW1
4.7µH
VON
35V
30mA
VON
BOOST
Startup Waveforms
10µF
10.0k
FB2
NFB4
VLOGIC
3.3V
2A
AVDD
12.2V
500mA
2.2µF
22µF
5ms/DIV
18k
100pF
2.2nF
6.8k
100pF
2.2nF
27k
100pF
680pF
0.47µF
13k
100pF
2.2nF
Quad Output TFT-LCD Power Supply
1943 TA01
1943fa
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LT1943
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ABSOLUTE
AXI U RATI GS
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PACKAGE/ORDER I FOR ATIO
(Note 1)
VIN Voltage .............................................................. 25V
BOOST Voltage ........................................................ 36V
BOOST Voltage Above SW1 ..................................... 25V
BIAS Pin Voltage ..................................................... 18V
SW2, SW4 Pin Voltages .......................................... 40V
SW3 Voltage ............................................................ 40V
FB1, FB2, FB3, FB4 Voltages ...................................... 4V
NFB4 Voltage ................................................ +6V, –0.6V
VC1, VC2, VC3, VC4 Pin Voltages .............................. 6V
RUN-SS, SS-234 Pin Voltages ................................... 6V
PGOOD Pin Voltage ................................................. 36V
E3 Pin Voltage ......................................................... 38V
VON Voltage ............................................................. 38V
CT Pin Voltage ........................................................... 6V
Junction Temperature ........................................... 125°C
Operating Temperature Range (Note 2) ...–40°C to 85°C
Storage Temperature Range ..................–65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
ORDER PART
NUMBER
TOP VIEW
GND
1
28 SW2
VC1
2
27 SW2
VC2
3
26 VON
FB1
4
25 CT
FB2
5
24 E3
FB3
6
23 PGOOD
NFB4
7
FB4
8
21 SW3
VC3
9
20 GND
VC4 10
19 SW4
29
LT1943EFE
22 BIAS
SGND 11
18 RUN-SS
BOOST 12
17 SS-234
SW1 13
16 VIN
SW1 14
15 VIN
FE PART MARKING
1943E
FE PACKAGE
28-LEAD PLASTIC TSSOP
EXPOSED PAD (PIN 29) IS GROUND
(MUST BE SOLDERED TO PCB)
TJMAX = 125°C, θJA = 25°C/W, θJC = 7.5°C/W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, RUN-SS, SS-234 = 2.5V unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
●
Minimum Input Voltage
Maximum Input Voltage
Quiescent Current
Not Switching
RUN-SS = SS-234 = 0V
RUN-SS, SS-234 Pin Current
RUN-SS, SS-234 = 0.4V
10
35
RUN-SS, SS-234 Threshold
●
BIAS Pin Voltage to Begin SS-234 Charge
2.4
MAX
UNITS
4.5
V
22
V
14
45
mA
µA
1.7
µA
0.8
V
2.8
3.15
V
BIAS Pin Current
BIAS = 3.1V, All Switches Off
10.5
15
mA
FB Threshold Offset to Begin CT Charge
(Note 3)
90
125
160
mV
CT Pin Current Source
All FB Pins = 1.5V
16
20
25
µA
CT Threshold to Power VON
All FB Pins = 1.5V
1.0
VON Switch Drop
VON Current = 30mA
Maximum VON Current
VE3 = 30V
●
1.1
1.2
V
180
240
mV
30
60
PGOOD Threshold Offset
90
125
PGOOD Sink Current
200
PGOOD Pin Leakage
mA
160
µA
VPGOOD = 36V
1
Master Oscillator Frequency
●
1.1
1.0
mV
1.2
1.35
1.46
µA
MHz
MHz
Foldback Switching Frequency
All FB Pins = 0V
250
kHz
Frequency Shift Threshold on FB
∆200kHz
0.5
V
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LT1943
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, RUN-SS, SS-234 = 2.5V unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1.23
1.22
1.25
1.27
1.27
V
V
0.01
0.03
%/V
100
600
SWITCH 1 (2.4A BUCK)
FB1 Voltage
●
FB1 Voltage Line Regulation
4.5V < VIN < 22V
FB1 Pin Bias Current
(Note 4)
●
Error Amplifier 1 Voltage Gain
200
Error Amplifier 1 Transconductance
∆I = 5µA
Switch 1 Current Limit
Duty Cycle = 35% (Note 6)
Switch 1 VCESAT
µmhos
450
●
3.2
4.3
A
ISW = 2A
310
470
mV
Switch 1 Leakage Current
FB1 = 1.5V
0.1
10
µA
Minimum BOOST Voltage Above SW1 Pin
ISW = 1.5A (Note 7)
1.8
2.5
V
BOOST Pin Current
ISW = 1.5A
30
50
mA
Maximum Duty Cycle (SW1)
2.4
nA
V/V
●
82
92
1.23
1.22
1.25
●
1.27
1.27
V
V
0.01
0.03
%/V
220
1000
%
SWITCH 2 (2.6A BOOST)
FB2 Voltage
FB2 Voltage Line Regulation
4.5V < VIN < 22V
FB2 Pin Bias Current
(Note 4)
●
Error Amplifier 2 Voltage Gain
Error Amplifier 2 Transconductance
200
∆I = 5µA
µmhos
450
●
Switch 2 Current Limit
2.6
nA
V/V
3.8
4.9
A
mV
Switch 2 VCESAT
ISW2 = 2A
360
540
Switch 2 Leakage Current
FB2 = 1.5V
0.1
1
BIAS Pin Current
ISW2 = 2A
45
mA
%
Maximum Duty Cycle (SW2)
µA
●
85
92
1.23
1.22
1.25
●
1.27
1.27
V
V
0.01
0.03
%/V
100
600
nA
SWITCH 3 (350mA BOOST)
FB3 Voltage
FB3 Voltage Line Regulation
4.5V < VIN < 22V
FB3 Pin Bias Current
(Note 4)
●
Error Amplifier 3 Voltage Gain
Error Amplifier 3 Transconductance
∆I = 5µA
●
Switch 3 Current Limit
V/V
µmhos
0.5
0.7
A
Switch 3 VCESAT
ISW3 = 0.2A
180
280
mV
Switch 3 Leakage Current
FB3 = 1.5V
0.1
1
µA
BIAS Pin Current
ISW3 = 0.2A
Maximum Duty Cycle (SW3)
●
Schottky Diode Drop
I = 170mA
0.35
200
450
84
83
14
mA
88
%
%
700
mV
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LT1943
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. RUN-SS, SS-234 = 2.5V unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1.23
1.22
1.25
1.27
1.27
V
V
0.01
0.03
%/V
100
600
nA
1.245
1.275
1.275
V
V
SWITCH 4 (350mA INVERTER)
FB4 Voltage
●
FB4 Voltage Line Regulation
4.5V < VIN < 22V
FB4 Pin Bias Current
(Note 4)
●
NFB4 Voltage (VFB4-VNFB4)
●
1.215
1.205
NFB4 Voltage Line Regulation
4.5V < VIN < 22V
0.01
0.03
%/V
NFB4 Pin Bias Current
(Note 5)
100
600
nA
200
V/V
∆I = 5µA
450
µmhos
Error Amplifier 4 Voltage Gain
Error Amplifier 4 Transconductance
●
Switch 4 Current Limit
0.35
0.5
0.7
A
Switch 4 VCESAT
ISW4 = 0.3A
260
390
mV
Switch 4 Leakage Current
FB4 = 1.5V
0.1
1
µA
BIAS Pin Current due to SW4
ISW4 = 0.3A
15
mA
88
%
%
Maximum Duty Cycle (SW4)
84
83
●
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: The LT1943E is guaranteed to meet performance specifications
from 0°C to 70°C. Specifications over the –40°C to 85°C operating
temperature range are assured by design, characterization, and correlation
with statistical process controls.
Note 3: The CT pin is held low until FB1, FB2, FB3 and FB4 all ramp above
the FB threshold offset.
Note 4: Current flows into FB1, FB2, FB3 and FB4 pins.
Note 5: Current flows out of NFB4 pin.
Note 6: Current limit is guaranteed by design and/or correlation to static
test. Slope compensation reduces current limit at high duty cycle.
Note 7: This is the minimum voltage across the boost capacitor needed to
guarantee full saturation of the internal power switch.
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TYPICAL PERFOR A CE CHARACTERISTICS
Maximum Output Current
for VLOGIC = 3.3V
SW1 Current Limit vs Duty Cycle
4.5
TA = 25°C
TA = 25°C
2.6
4
4.0
2.4
2.2
L1 = 3.3µH
2.0
1.8
TYPICAL
SW1 CURRENT (A)
L1 = 4.7µH
SW1 CURRENT (A)
VLOGIC MAXIMUM OUTPUT CURRENT (A)
SW1 Current Limit
5
2.8
3
2
MINIMUM
3.5
3.0
1.6
1
1.4
1.2
0
0
5
10
15
20
INPUT VOLTAGE (V)
1943 G01
0
20
40
60
DUTY CYCLE (%)
80
100
1943 G02
2.5
–50
–25
50
25
0
75
TEMPERATURE (°C)
100
125
1943 G03
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LT1943
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TYPICAL PERFOR A CE CHARACTERISTICS
MINIMUM Input Voltage to Start,
VLOGIC = 3.3V
BOOST Pin Current
6.0
TA = 25°C
TA = 25°C
5.0
4.5
4.0
3.5
4.5
80
SW2 CURRENT (A)
BOOST PIN CURRENT (mA)
INPUT VOLTAGE (V)
5.5
3.0
SW2 Current Limit
5.0
100
60
40
20
0
100
40
60
80
LOAD CURRENT (mA)
3.5
3.0
20
2.5
–50
0
0
4.0
1.0
1.5
2.0
SW1 CURRENT (A)
0.5
2.5
3.0
50
25
0
75
TEMPERATURE (°C)
–25
100
1943 G05
1943 G04
SW3 Current Limit
125
1943 G06
SW4 Current Limit
SW1 VCESAT
0.8
0.8
600
0.7
0.7
500
0.6
0.5
0.4
0.3
SW1 VOLTAGE DROP (mV)
SW4 CURRENT (A)
SW3 CURRENT (A)
TA = 25°C
0.6
0.5
0.4
50
25
75
0
TEMPERATURE (°C)
100
50
25
75
0
TEMPERATURE (°C)
1943 G07
600
300
200
100
2.5
3.0
TA = 25°C
400
300
200
100
0
1.0
1.5
2.0
SW2 CURRENT (A)
0
0.1
0.2
0.3
400
300
200
100
0
0.4
0
0.1
0.2
0.3
0.4
SW4 CURRENT (A)
SW3 CURRENT (A)
1943 G10
3.0
SW4 VCESAT
SW4 VOLTAGE DROP (mV)
400
2.5
1.0
1.5
2.0
SW1 CURRENT (A)
0.5
500
TA = 25°C
SW3 VOLTAGE DROP (mV)
SW2 VOLTAGE DROP (mV)
0
1943 G09
500
TA = 25°C
0.5
125
SW3 VCESAT
SW2 VCESAT
0
100
1943 G08
500
0
200
0
0.2
–50 –25
125
300
100
0.3
0.2
–50 –25
400
1943 G11
1943 G12
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LT1943
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TYPICAL PERFOR A CE CHARACTERISTICS
VON Current Limit
Frequency Foldback
Oscillator Frequency
1.4
100
1.4
TA = 25°C
TA = 25°C
SWITCHING FREQUENCY (MHz)
1.3
80
FREQUENCY (MHz)
VON CURRENT (mA)
90
70
60
50
1.2
1.1
40
30
5
10
15
25
20
VON (V)
35
30
40
1.0
–50
1.0
0.8
0.6
0.4
0.2
0
–25
0
25
50
75
TEMPERATURE (°C)
100 125
1943 G13
0.2
0.4
0.6
0.8
1.0
FEEDBACK VOLTAGE (V)
1.2
1943 G15
Bias Pin Current
100
1.26
80
BIAS PIN CURRENT (mA)
1.27
1.25
1.24
1.23
60
ISW2 = 1.5A
ISW3 = 0.2A
ISW4 = 0.3A
40
20
1.22
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
ISW2 = ISW3 = ISW4 = 0A
0
50
25
75
–50 –25
0
TEMPERATURE (°C)
125
1943 G16
100
125
1943 G17
Efficiency, VLOGIC = 3.3V
Efficiency, AVDD = 13V
100
100
VIN = 5V
TA = 25°C
VIN = 5V
TA = 25°C
90
EFFICIENCY (%)
90
EFFICIENCY (%)
0
1943 G14
Reference Voltage
REFERENCE VOLTAGE (V)
1.2
80
70
80
70
60
60
50
50
0
0.1
0.3
0.4
0.2
LOAD CURRENT (A)
0.5
1943 G18
0
0.25
0.50 0.75 1.00
LOAD CURRENT (A)
1.25
1.50
1943 G19
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LT1943
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GND (Pins 1, 20, Exposed Pad Pin 29): Ground. Tie both
GND pins and the exposed pad directly to a local ground
plane. The ground metal to the exposed pad should be as
wide as possible for better heat dissipation. Multiple vias
(to ground plane under the ground backplane) placed
close to the exposed pad can further aid in reducing
thermal resistance.
VC1 (Pin 2): Switching Regulator 1 Error Amplifier Compensation. Connect a resistor/capacitor network in series
with this pin.
VC2 (Pin 3): Error Amplifier Compensation for Switcher 2.
Connect a resistor/capacitor network in series with this
pin.
FB1 (Pin 4): Switching Regulator 1 Feedback. Tie the
resistor divider tap to this pin and set VLOGIC according to
VLOGIC = 1.25 • (1 + R2/R1). Reference designators refer
to Figure 1.
FB2 (Pin 5): Feedback for Switch 2. Tie the resistor divider
tap to this pin and set AVDD according to AVDD = 1.25 •
(1 + R6/R5).
FB3 (Pin 6): Switching Regulator 3 Feedback. Tie the
resistor divider tap to this pin and set VON according to
VON = 1.25 • (1 + R9/R8) – 150mV.
NFB4 (Pin 7): Switching Regulator 4 Negative Feedback.
Switcher 4 can be used to generate a positive or negative
output. When regulating a negative output, tie the resistor
divider tap to this pin. Negative output voltage can be set
by the equation VOFF = –1.245 • (R3/R4) with R4 set to 10k.
Tie the NFB4 pin to FB4 for positive output voltages.
FB4 (Pin 8): Feedback for Switch 4. When generating a
positive voltage from switch 4, tie the resistor divider tap
to this pin. When generating a negative voltage, tie a 10k
resistor between FB4 and NFB4 (R4).
VC3 (Pin 9): Switching Regulator 3 Error Amplifier Compensation. Connect a resistor/capacitor network in series
with this pin.
VC4 (Pin 10): Switching Regulator 4 Error Amplifier
Compensation. Connect a resistor/capacitor network in
series with this pin.
SGND (Pin 11): Signal Ground. Return ground trace from
the FB resistor networks and VC pin compensation components directly to this pin and then tie to ground.
BOOST (Pin 12): The BOOST pin is used to provide a drive
voltage, higher than VIN, to the switch 1 drive circuit.
SW1 (Pins 13, 14): The SW1 pins are the emitter of the
internal NPN bipolar power transistor for switching regulator 1. These pins must be tied together for proper
operation. Connect these pins to the inductor, catch diode
and boost capacitor.
VIN (Pins 15, 16): The VIN pins supply current to the
LT1943’s internal regulator and to the internal power
transistor for switch 1. These pins must be tied together
and locally bypassed.
SS-234 (Pin 17): This is the soft-start pin for switching
regulators 2, 3 and 4. Place a soft-start capacitor here to
limit start-up inrush current and output voltage ramp rate.
When the BIAS pin reaches 2.8V, a 1.7µA current source
begins charging the capacitor. When the capacitor voltage
reaches 0.8V, switches 2, 3 and 4 turn on and begin
switching. For slower start-up, use a larger capacitor.
When this pin is pulled to ground, switches 2, 3 and 4 are
disabled. For complete shutdown, tie RUN-SS to ground.
RUN-SS (Pin 18): This is the soft-start pin for switching
regulator 1. Place a soft-start capacitor here to limit startup inrush current and output voltage ramp rate. When
power is applied to the VIN pin, a 1.7µA current source
charges the capacitor. When the voltage at this pin reaches
0.8V, switch 1 turns on and begins switching. For slower
start-up, use a larger capacitor. For complete shutdown,
tie RUN-SS to ground.
SW4 (Pin 19): This is the collector of the internal NPN
bipolar power transistor for switching regulator 4. Minimize metal trace area at this pin to keep EMI down.
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LT1943
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SW3 (Pin 21): This is the collector of the internal NPN
bipolar power transistor for switching regulator 3. Minimize metal trace area at this pin to keep EMI down.
BIAS (Pin 22): The BIAS pin is used to improve efficiency
when operating at higher input voltages. Connecting this
pin to the output of switching regulator 1 forces most of
the internal circuitry to draw its operating current from
VLOGIC rather than VIN. The drivers of switches 2, 3 and 4
are supplied by BIAS. Switches 2, 3 and 4 will not switch
until the BIAS pin reaches approximately 2.8V. BIAS must
be tied to VLOGIC.
PGOOD (Pin 23): Power Good Comparator Output. This is
the open collector output of the power good comparator
and can be used in conjunction with an external P-Channel
MOSFET to provide output disconnect for AVDD as shown
in the 5V Input, Quad Output TFT-LCD Power Supply on
the last page of the data sheet. When switcher 2’s output
reaches approximately 90% of its programmed voltage,
PGOOD will be pulled to ground. This will pull down on the
gate of the MOSFET, connecting AVDD. A 100k pull-up
resistor between the source and gate of the P-channel
MOSFET keeps it off when switcher 2’s output is low.
E3 (Pin 24): This is switching regulator 3’s output and the
emitter of the output disconnect PNP. Tie the output
capacitor and resistor divider here.
CT (Pin 25): Timing Capacitor Pin. This is the input to the
VON timer and programs the time delay from all four
feedback pins reaching 1.125V to VON turning on. The CT
capacitor value can be set using the equation C = (20µA •
tDELAY)/1.1V.
VON (Pin 26): This is the delayed output for switching
regulator 3. VON reaches its programmed voltage after the
internal CT timer times out. Protection circuitry ensures
VON is disabled if any of the four outputs are more than
10% below normal voltage.
SW2 (Pins 27, 28): The SW2 pins are the collector of the
internal NPN bipolar power transistor for switching regulator 2. These pins must be tied together. Minimize trace
area at these pins to keep EMI down.
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LT1943
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BLOCK DIAGRA
VIN
VIN
15
16
C1
MASTER
OSCILLATOR
1.2MHz
VLOGIC
R2
FOLDBACK
OSCILLATOR
SLOPE
COMPENSATION
BOOST
12
Σ
+
DRIVER
FB1
4
–
R1
2.4A
SWITCH
13
C3
–
R14
14
+
VC2
R5
C9
–
1.25V
BIAS
22
+
27
R
S Q
DRIVER
FOLDBACK
OSCILLATOR
+
C12
C21
+
CT
R11
3
gm
20µA
–
–
–
–
C11
C20
–
5
25
R10
2
1.25V
1.12V
FB2
C2
VC1
gm
R6
L1
D1
–
+
VLOGIC
SW1
R
S Q
PGOOD
23
AVDD
D2
2.6A
SWITCH
SW2
28
L2
VIN
D5
C16
L3
Σ
1.125V
SLOPE
COMPENSATION
AVDD
C8
FB4
8
1.7µA
RUN-SS
18
C5
VIN
–
INTERNAL
REGULATOR
AND
REFERENCE
+
7
17
C4
–
+
+
1.25V
R
S Q
DRIVER
FOLDBACK
OSCILLATOR
BIAS
VOFF
Σ
2.8V
VC3
gm
C22
C13
–
+
1.25V
VON
R12
9
–
26
VLOGIC
D6
C7
400mA
SWITCH
SLOPE
COMPENSATION
R8
VON
L4
D3 C6
6
VE3
SW4
19
+
FB3
R9
C14
C23
SW2
SW3
SW4
LOCKOUT
–
R13
10
gm
1.7µA
SS-234
R3
VC4
–
R4
C24
NFB4
+
–
SW3
21
R
S Q
DRIVER
L5
VIN
400mA
SWITCH
FOLDBACK
OSCILLATOR
C15
+
Σ
SLOPE
COMPENSATION
1.1V
1
GND
11
SGND
20
GND
29
E3
24
VE3
C10
GND
Figure 1. Block Diagram
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LT1943
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The LT1943 is a highly integrated power supply IC containing four separate switching regulators. All four switching regulators have their own oscillator with frequency
foldback and use current mode control. Switching regulator 1 consists of a step-down regulator with a switch
current limit of 2.4A. Switching regulator 2 can be configured as a step-up or SEPIC converter and has a 2.6A
switch. Switching regulator 3 consists of a step-up regulator with a 0.35A switch as well as an integrated Schottky
diode. Switching regulator 4 has two feedback pins (FB4
and NFB4) and can directly regulate positive or negative
output voltages. The four regulators share common circuitry including input source, voltage reference, and master oscillator. Operation can be best understood by referring to the Block Diagram as shown in Figure 1.
If the RUN/SS pin is pulled to ground, the LT1943 is shut
down and draws 35µA from the input source tied to VIN. An
internal 1.7µA current source charges the external softstart capacitor, generating a voltage ramp at this pin. If the
RUN/SS pin exceeds 0.6V, the internal bias circuits turn
on, including the internal regulator, reference, and 1.1MHz
master oscillator. The master oscillator generates four
clock signals, one for each of the switching regulators.
Switching regulator 1 will only begin to operate when the
RUN/SS pin reaches 0.8V. Switcher 1 generates VLOGIC,
which must be tied to the BIAS pin. When BIAS reaches
2.8V, the NPN pulling down on the SS-234 pin turns off,
allowing an internal 1.7µA current source to charge the
external capacitor tied to the SS-234 pin. When the voltage
on the SS-234 pin reaches 0.8V, switchers 2, 3 and 4 are
enabled. AVDD and VOFF will then begin rising at a ramp
rate determined by the capacitor tied to the SS-234 pin.
When all the outputs reach 90% of their programmed
voltages, the NPN pulling down on the CT pin will turn off,
and an internal 20µA current source will charge the external capacitor tied to the CT pin. When the CT pin reaches
1.1V, the output disconnect PNP turns on, connecting
VON. In the event of any of the four outputs dropping below
10% of their programmed voltage, PanelProtect circuitry
pulls the CT pin to GND, disabling VON.
A power good comparator monitors AVDD and turns on
when the FB2 pin is at or above 90% of its regulated value.
RUN-SS
2V/DIV
VLOGIC
5V/DIV
IL1
1A/DIV
SS-234
2V/DIV
AVDD
20V/DIV
IL2+L3
1A/DIV
PGOOD
20V/DIV
5ms/DIV
1943 F03a
(2a)
VOFF
10V/DIV
IL4
500mA/DIV
VE3
20V/DIV
IL5
500mA/DIV
VCT
2V/DIV
VON
50V/DIV
5ms/DIV
1943 F03b
(2b)
Figure 2. LT1943 Power-Up Sequence. (Traces From
Both Photos are Synchronized to the Same Trigger)
The output is an open collector transistor that is off when
the output is out of regulation, allowing an external resistor to pull the pin high. This pin can be used with a
P-channel MOSFET that functions as an output disconnect
for AVDD.
The four switchers are current mode regulators. Instead of
directly modulating the duty cycle of the power switch, the
feedback loop controls the peak current in the switch
during each cycle. Compared to voltage mode control,
current mode control improves loop dynamics and provides cycle-by-cycle current limit.
1943fa
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The control loop for the four switchers is similar. A pulse
from the slave oscillator sets the RS latch and turns on the
internal NPN bipolar power switch. Current in the switch
and the external inductor begins to increase. When this
current exceeds a level determined by the voltage at VC, the
current comparator resets the latch, turning off the switch.
The current in the inductor flows through the Schottky
diode and begins to decrease. The cycle begins again at the
next pulse from the oscillator. In this way, the voltage on
the VC pin controls the current through the inductor to the
output. The internal error amplifier regulates the output
voltage by continually adjusting the VC pin voltage. The
threshold for switching on the VC pin is 0.8V, and an active
clamp of 1.8V limits the output current. The RUN/SS and
SS-234 pins also clamp the VC pin voltage. As the internal
current source charges the external soft-start capacitor,
the current limit increases slowly.
Each switcher contains an extra, independent oscillator to
perform frequency foldback during overload conditions.
This slave oscillator is normally synchronized to the master oscillator. A comparator senses when VFB is less than
0.5V and switches the regulator from the master oscillator
to a slower slave oscillator. The VFB pin is less than 0.5V
during startup, short-circuit, and overload conditions.
Frequency foldback helps limit switch current and power
dissipation under these conditions.
The switch driver for SW1 operates either from VIN or from
the BOOST pin. An external capacitor and diode are used
to generate a voltage at the BOOST pin that is higher than
the input supply. This allows the driver to saturate the
internal bipolar NPN power switch for efficient operation.
STEP-DOWN CONSIDERATIONS
FB Resistor Network
The output voltage for switcher 1 is programmed with a
resistor divider (refer to the Block Diagram) between the
output and the FB pin. Choose the resistors according to:
R2 = R1(VOUT/1.25V – 1)
R1 should be 10kΩ or less to avoid bias current errors.
Input Voltage Range
The minimum operating voltage of switcher 1 is determined either by the LT1943’s undervoltage lockout of ~4V,
or by its maximum duty cycle. The duty cycle is the fraction
of time that the internal switch is on and is determined by
the input and output voltages:
DC = (VOUT + VF)/(VIN – VSW + VF)
where VF is the forward voltage drop of the catch diode
(~0.4V) and VSW is the voltage drop of the internal switch
(~0.3V at maximum load). This leads to a minimum input
voltage of
VIN(MIN) = (VOUT + VF)/DCMAX – VF + VSW
with DCMAX = 0.82.
Inductor Selection and Maximum Output Current
A good first choice for the inductor value is:
L = (VOUT + VF)/1.2
where VF is the voltage drop of the catch diode (~0.4V) and
L is in µH. The inductor’s RMS current rating must be
greater than the maximum load current and its saturation
current should be at least 30% higher. For highest efficiency, the series resistance (DCR) should be less than
0.1Ω. Table 1 lists several vendors and types that are
suitable.
The optimum inductor for a given application may differ
from the one indicated by this simple design guide. A
larger value inductor provides a higher maximum load
current, and reduces the output voltage ripple. If your load
is lower than the maximum load current, then you can
relax the value of the inductor and operate with higher
ripple current. This allows you to use a physically smaller
inductor, or one with a lower DCR resulting in higher
efficiency. Be aware that the maximum load current
depends on input voltage. A graph in the Typical Performance section of this data sheet shows the maximum load
current as a function of input voltage and inductor value
for VOUT = 3.3V. In addition, low inductance may result in
discontinuous mode operation, which further reduces
1943fa
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LT1943
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maximum load current. For details of maximum output
current and discontinuous mode operation, see Linear
Technology’s Application Note AN44. Finally, for duty
cycles greater than 50% (VOUT/VIN > 0.5), a minimum
inductance is required to avoid subharmonic oscillations.
See AN19.
these equations to check that the LT1943 will be able to
deliver the required output current. Note again that these
equations assume that the inductor current is continuous.
Discontinuous operation occurs when IOUT is less than
∆IL/2.
The current in the inductor is a triangle wave with an
average value equal to the load current. The peak switch
current is equal to the output current plus half the peak-topeak inductor ripple current. The LT1943 limits its switch
current in order to protect itself and the system from
overload faults. Therefore, the maximum output current
that the LT1943 will deliver depends on the switch current
limit, the inductor value, and the input and output voltages.
Part Number
When the switch is off, the potential across the inductor is
the output voltage plus the catch diode drop. This gives the
peak-to-peak ripple current in the inductor:
∆IL = (1 – DC)(VOUT + VF)/(L • f),
where f is the switching frequency of the LT1943 and L is
the value of the inductor. The peak inductor and switch
current is
ISWPK = ILPK = IOUT + ∆IL/2
To maintain output regulation, this peak current must be
less than the LT1943’s switch current limit of ILIM. For
SW1, ILIM is at least 2.4A at DC = 0.35 and decreases
linearly to 1.6A at DC = 0.8, as shown in the Typical
Performance Characteristics section. The maximum output current is a function of the chosen inductor value:
IOUT(MAX) = ILIM – ∆IL/2
= 3A • (1 – 0.57 • DC) – ∆IL/2
Choosing an inductor value so that the ripple current is
small will allow a maximum output current near the switch
current limit.
One approach to choosing the inductor is to start with the
simple rule given above, look at the available inductors,
and choose one to meet cost or space goals. Then use
Table 1. Inductors.
Value (µH)
IRMS (A)
DCR (Ω) Height (mm)
CR43-1R4
1.4
2.52
0.056
3.5
CR43-2R2
2.2
1.75
0.071
3.5
CR43-3R3
3.3
1.44
0.086
3.5
CR43-4R7
4.7
1.15
0.109
3.5
CDRH3D16-1R5
1.5
1.55
0.040
1.8
CDRH3D16-2R2
2.2
1.20
0.050
1.8
CDRH3D16-3R3
3.3
1.10
0.063
1.8
CDRH4D28-3R3
3.3
1.57
0.049
3.0
CDRH4D28-4R7
4.7
1.32
0.072
3.0
CDRH4D18-1R0
1.0
1.70
0.035
2.0
CDC5D23-2R2
2.2
2.50
0.03
2.5
CDRH5D28-2R6
2.6
2.60
0.013
3.0
DO1606T-152
1.5
2.10
0.060
2.0
DO1606T-222
2.2
1.70
0.070
2.0
DO1606T-332
3.3
1.30
0.100
2.0
DO1606T-472
4.7
1.10
0.120
2.0
DO1608C-152
1.5
2.60
0.050
2.9
DO1608C-222
2.2
2.30
0.070
2.9
DO1608C-332
3.3
2.00
0.080
2.9
DO1608C-472
4.7
1.50
0.090
2.9
MOS6020-222
2.2
2.15
0.035
2.0
MOS6020-332
3.3
1.8
0.046
2.0
MOS6020-472
4.7
1.5
0.050
2.0
D03314-222
2.2
1.6
0.200
1.4
1008PS-272
2.7
1.3
0.140
2.7
(D62F)847FY-2R4M
2.4
2.5
0.037
2.7
(D73LF)817FY-2R2M
2.2
2.7
0.03
3.0
Sumida
Coilcraft
Toko
1943fa
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LT1943
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OPERATIO
Output Capacitor Selection
For 5V and 3.3V outputs, a 10µF 6.3V ceramic capacitor
(X5R or X7R) at the output results in very low output
voltage ripple and good transient response. Other types
and values will also work; the following discussion explores tradeoffs in output ripple and transient performance.
The output capacitor filters the inductor current to generate an output with low voltage ripple. It also stores energy
in order satisfy transient loads and stabilizes the LT1943’s
control loop. Because the LT1943 operates at a high
frequency, minimal output capacitance is necessary. In
addition, the control loop operates well with or without the
presence of output capacitor series resistance (ESR).
Ceramic capacitors, which achieve very low output ripple
and small circuit size, are therefore an option.
Because loop stability and transient response depend on
the value of COUT, this loss may be unacceptable. Use X7R
and X5R types.
Electrolytic capacitors are also an option. The ESRs of
most aluminum electrolytic capacitors are too large to
deliver low output ripple. Tantalum and newer, lower ESR
organic electrolytic capacitors intended for power supply
use are suitable, and the manufacturers will specify the
ESR. Chose a capacitor with a low enough ESR for the
required output ripple. Because the volume of the capacitor determines its ESR, both the size and the value will be
larger than a ceramic capacitor that would give similar
ripple performance. One benefit is that the larger capacitance may give better transient response for large changes
in load current. Table 2 lists several capacitor vendors.
Table 2. Low ESR Surface Mount Capacitors
Type
Series
Taiyo Yuden
Ceramic
X5R, X7R
AVX
Ceramic
Tantalum
X5R, X7R
TPS
VRIPPLE = ∆IL • ESR for electrolytic capacitors (tantalum
and aluminum);
Kemet
Tantalum
Ta Organic
Al Organic
T491, T494, T495
T520
A700
where ∆IL is the peak-to-peak ripple current in the inductor. The RMS content of this ripple is very low so the RMS
current rating of the output capacitor is usually not of
concern. It can be estimated with the formula:
Sanyo
Ta or Al Organic
POSCAP
You can estimate output ripple with the following
equations:
VRIPPLE = ∆IL/(8 • f • COUT) for ceramic capacitors, and
IC(RMS)= ∆IL/√12
Another constraint on the output capacitor is that it must
have greater energy storage than the inductor; if the stored
energy in the inductor transfers to the output, the resulting
voltage step should be small compared to the regulation
voltage. For a 5% overshoot, this requirement indicates:
COUT > 10 • L • (ILIM/VOUT)2
The low ESR and small size of ceramic capacitors make
them the preferred type for LT1943 applications. Not all
ceramic capacitors are the same, however. Many of the
higher value capacitors use poor dielectrics with high
temperature and voltage coefficients. In particular, Y5V
and Z5U types lose a large fraction of their capacitance
with applied voltage and at temperature extremes.
Vendor
Panasonic
TDK
Al Organic
SP CAP
Ceramic
X5R, X7R
Diode Selection
The catch diode (D1 from Figure 1) conducts current only
during switch off time. Average forward current in normal
operation can be calculated from:
ID(AVG) = IOUT (VIN – VOUT)/VIN
The only reason to consider a diode with a larger current
rating than necessary for nominal operation is for the
worst-case condition of shorted output. The diode current
will then increase to the typical peak switch current.
Peak reverse voltage is equal to the regulator input voltage. Use a diode with a reverse voltage rating greater than
the input voltage. Table 3 lists several Schottky diodes and
their manufacturers.
1943fa
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LT1943
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Table 3. Schottky Diodes
Part Number
VR (V)
IAVE (A) VF at 1A (mV)
VF at 2A (mV)
On Semiconductor
MBRM120E
20
1
530
MBRM140
40
1
550
R4 should be 10kΩ or less to avoid bias current errors. If
switcher 4 is used to generate a positive output voltage,
NFB4 should be tied to FB4.
595
VOUT
Diodes Inc.
R3
FB4
B120
20
1
500
B130
30
1
500
B220
20
2
500
B230
30
2
500
B240
40
2
500
NFB4
R4
1943 A1
Regulating Negative Output Voltages
International Rectifier
10BQ030
30
1
20BQ030
30
2
420
470
470
Boost Pin Considerations
The minimum operating voltage of an LT1943 application
is limited by the undervoltage lockout ~4V and by the
maximum duty cycle. The boost circuit also limits the
minimum input voltage for proper start-up. If the input
voltage ramps slowly, or the LT1943 turns on when the
output is already in regulation, the boost capacitor may not
be fully charged. Because the boost capacitor charges
with the energy stored in the inductor, the circuit will rely
on some minimum load current to get the boost circuit
running properly. This minimum load will depend on input
and output voltages. The Typical Performance Characteristics section shows a plot of the minimum load current to
start as a function of input voltage for a 3.3V output. The
minimum load current generally goes to zero once the
circuit has started. Even without an output load current, in
many cases the discharged output capacitor will present
a load to the switcher that will allow it to start.
INVERTER/STEP-UP CONSIDERATIONS
The LT1943 contains an inverting op amp with its noninverting terminal tied to ground and its output connected
to the FB4 pin. Use this op amp to generate a voltage at FB4
that is proportional to VOUT4. Choose the resistors according to:
R6 =
–VOUT
R6
NFB4
C1
10pF
R3 = R4(VOUT/1.25 – 1)
R5
10k
FB4
1943 A2
Use 10k for R5. Tie 10pF in parallel with R5.
Duty Cycle Range
The maximum duty cycle (DC) of the LT1943 switching
regulator is 85% for SW2, and 83% for SW3 and SW4. The
duty cycle for a given application using the step-up or
charge pump topology is:
Regulating Positive Output Voltages
The output voltage is programmed with a resistor divider
between the output and the FB pin. Choose the resistors
according to:
R5 • | V0UT |
1.245V
DC =
| VOUT | – VIN
| VOUT |
The duty cycle for a given application using the inverter or
SEPIC topology is:
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LT1943
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OPERATIO
DC =
| VOUT |
VIN + | VOUT |
Output Capacitor Selection
The LT1943 can still be used in applications where the duty
cycle, as calculated above, is above the maximum. However, the part must be operated in discontinuous mode so
that the actual duty cycle is reduced.
Inductor Selection
Several inductors that work well with the LT1943 regulator
are listed in Table 4. Besides these, many other inductors
will work. Consult each manufacturer for detailed information and for their entire selection of related parts. Use
ferrite core inductors to obtain the best efficiency, as core
losses at frequencies above 1MHz are much lower for
ferrite cores than for powdered-iron units. A 10µH to 22µH
inductor will be the best choice for most LT1943 step-up
and charge pump designs. Choose an inductor that can
carry the entire switch current without saturating. For
inverting and SEPIC regulators, a coupled inductor, or two
separate inductors is an option. When using coupled
inductors, choose one that can handle at least the switch
current without saturating. If using uncoupled inductors,
each inductor need only handle approximately one-half of
the total switch current. A 4.7µH to 15µH coupled inductor
or two 10µH to 22µH uncoupled inductors will usually be
the best choice for most LT1943 inverting and SEPIC
designs.
Table 4. Inductors.
Part Number
Value (µH)
IRMS (A)
DCR (Ω)
Height (mm)
TP3-4R7
4.7
1.5
0.181
2.2
TP4-100
10
1.5
0.146
3.0
CD73-100
10
1.44
0.080
3.5
CDRH5D18-6R2
6.2
1.4
0.071
2.0
CDRH4D28-100
10
1.3
0.048
3.0
CDRH4D28-100
10
1.0
0.095
3.0
DO3314-103
10
0.8
0.520
1.4
1008PS-103
10
0.78
0.920
2.8
Use low ESR (equivalent series resistance) capacitors at
the output to minimize the output ripple voltage. Multilayer
ceramic capacitors are an excellent choice, as they have an
extremely low ESR and are available in very small packages. X7R dielectrics are preferred, followed by X5R, as
these materials retain their capacitance over wide voltage
and temperature ranges. A 10µF to 22µF output capacitor
is sufficient for most LT1943 applications. Even less
capacitance is required for outputs with |VOUT| > 20V or
|IOUT| < 100mA. Solid tantalum or OS-CON capacitors will
also work, but they will occupy more board area and will
have a higher ESR than a ceramic capacitor. Always use a
capacitor with a sufficient voltage rating.
Diode Selection
A Schottky diode is recommended for use with the LT1943
switcher 2 and switcher 4. The Schottky diode for switcher
3 is integrated inside the LT1943. Choose diodes for
switcher 2 and switcher 4 rated to handle an average
current greater than the load current and rated to handle
the maximum diode voltage. The average diode current in
the step-up, SEPIC, and inverting configurations is equal
to the load current. Each of the two diodes in the charge
pump configurations carries an average diode current
equal to the load current. The maximum diode voltage in
the step-up and charge pump configurations is equal to
|VOUT|. The maximum diode voltage in the SEPIC and
inverting configurations is VIN + |VOUT|.
Input Capacitor Selection
Coiltronics
Sumida
Coilcraft
Bypass the input of the LT1943 circuit with a 4.7µF or
higher ceramic capacitor of X7R or X5R type. A lower value
or a less expensive Y5V type will work if there is additional
bypassing provided by bulk electrolytic capacitors or if the
input source impedance is low. The following paragraphs
describe the input capacitor considerations in more detail.
Step-down regulators draw current from the input supply
in pulses with very fast rise and fall times. The input
capacitor is required to reduce the resulting voltage ripple
at the LT1943 input and to force this switching current into
a tight local loop, minimizing EMI. The input capacitor
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LT1943
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OPERATIO
must have low impedance at the switching frequency to do
this effectively and it must have an adequate ripple current
rating. The input capacitor RMS current can be calculated
from the step-down output voltage and current, and the
input voltage:
CINRMS = IOUT •
VOUT (VIN – V0UT ) IOUT
<
2
VIN
and is largest when VIN = 2 VOUT (50% duty cycle). The
ripple current contribution from the other channels will be
minimal. Considering that the maximum load current from
switcher 1 is ~2.8A, RMS ripple current will always be less
than 1.4A.
The high frequency of the LT1943 reduces the energy
storage requirements of the input capacitor, so that the
capacitance required is less than 10µF. The combination
of small size and low impedance (low equivalent series
resistance or ESR) of ceramic capacitors makes them the
preferred choice. The low ESR results in very low voltage
ripple. Ceramic capacitors can handle larger magnitudes
of ripple current than other capacitor types of the same
value. Use X5R and X7R types.
An alternative to a high value ceramic capacitor is a lower
value along with a larger electrolytic capacitor, for example a 1µF ceramic capacitor in parallel with a low ESR
tantalum capacitor. For the electrolytic capacitor, a value
larger than 10µF will be required to meet the ESR and
ripple current requirements. Because the input capacitor
is likely to see high surge currents when the input source
is applied, only consider a tantalum capacitor if it has the
appropriate surge current rating. The manufacturer may
also recommend operation below the rated voltage of the
capacitor. Be sure to place the 1µF ceramic as close as
possible to the VIN and GND pins on the IC for optimal
noise immunity.
A final caution is in order regarding the use of ceramic
capacitors at the input. A ceramic input capacitor can
combine with stray inductance to form a resonant tank
circuit. If power is applied quickly (for example by plugging the circuit into a live power source), this tank can ring,
doubling the input voltage and damaging the LT1943. The
solution is to either clamp the input voltage or dampen the
tank circuit by adding a lossy capacitor (an electrolytic) in
parallel with the ceramic capacitor. For details, see Application Note 88.
Soft-Start and Shutdown
The RUN/SS (Run/Soft-Start) pin is used to place the
switching regulators and the internal bias circuits in shutdown mode. It also provides a soft-start function, along
with SS-234. If the RUN/SS is pulled to ground, the
LT1943 enters its shutdown mode with all regulators off
and quiescent current reduced to ~35µA. An internal
1.7µA current source pulls up on the RUN/SS and SS-234
pins. If the RUN/SS pin reaches ~0.8V, the internal bias
circuits start and the quiescent currents increase to their
nominal levels.
If a capacitor is tied from the RUN/SS or SS-234 pins to
ground, then the internal pull-up current will generate a
voltage ramp on these pins. This voltage clamps the VC
pin, limiting the peak switch current and therefore input
current during start-up. The RUN/SS pin clamps VC1, and
the SS-234 pin clamps the VC2, VC3, and VC4 pins. A good
value for the soft-start capacitors is COUT/10,000, where
COUT is the value of the largest output capacitor.
To shut down SW2, SW3, and SW4, pull the SS-234 pin to
ground with an open drain or collector.
If the shutdown and soft-start features are not used, leave
the RUN/SS and SS-234 pins floating.
VON Pin Considerations
The VON pin is the delayed output for switching regulator
3. When the CT pin reaches 1.1V, the output disconnect
PNP turns on, connecting VON to E3. The VON pin is current
limited, and will protect the LT1943 and input source from
a shorted output. However, if the VON pin is charged to a
high output voltage, and then shorted to ground through
a long wire, unpredictable results can occur. The resonant
tank circuit created by the inductance of the long wire and
the capacitance at the VON pin can ring the VON pin several
volts below ground. This can lead to large and potentially
damaging currents internal to the LT1943. If the VON
output may be shorted after being fully charged, there
1943fa
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LT1943
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OPERATIO
and inverting regulators, the switched currents flow through
the power switch, the switching diode, and the tank
capacitor. The loop formed by the components in the
switched current path should be as small as possible.
Place these components, along with the inductor and
output capacitor, on the same side of the circuit board, and
connect them on that layer. Place a local, unbroken ground
plane below these components, and tie this ground plane
to system ground at one location, ideally at the ground
terminal of the output capacitor C2. Additionally, keep the
SW and BOOST nodes as small as possible.
should be 5Ω of resistance between the VON pin and its
connection to the load, as shown on Figure 3. The resistance will damp resonant tank circuit created by the output
short. As the transient on the VON pin during a short-circuit
condition will be highly dependent on the layout and the
type of short, be sure to test the short condition and
examine the voltage at the VON pin to check that it does not
swing below ground.
VON
R1
5Ω
TO LOAD
C1
0.47µF
Thermal Considerations
R1 IS ONLY NECESSARY
IF LOAD MAY HAVE TRANSIENT
SHORT CONDITION. OTHERWISE,
CONNECT VON PIN DIRECTLY TO LOAD
The PCB must provide heat sinking to keep the LT1943
cool. The exposed pad on the bottom of the package must
be soldered to a ground plane. This ground should be tied
to other copper layers below with thermal vias; these
layers will spread the heat dissipated by the LT1943. Place
additional vias near the catch diodes. Adding more copper
to the top and bottom layers and tying this copper to the
internal planes with vias can reduce thermal resistance
further. With these steps, the thermal resistance from die
(or junction) to ambient can be reduced to θJA = 25°C or
less. With 100LFPM airflow, this resistance can fall by
another 25%. Further increases in airflow will lead to lower
thermal resistance.
1943 F03
Figure 3. Transient Short Protection for VON Pin
Printed Circuit Board Layout
For proper operation and minimum EMI, care must be
taken during printed circuit board (PCB) layout. Figure 4
shows the high-current paths in the step down regulator
circuit. Note that in the step-down regulators, large,
switched currents flow in the power switch, the catch
diode, and the input capacitor. In the step-up regulators,
large, switched currents flow through the power switch,
the switching diode, and the output capacitor. In SEPIC
VIN
VIN
SW
GND
SW
GND
(a)
(b)
VSW
VIN
IC1
C1
L1
SW
D1
GND
C2
1943 F04
(c)
Figure 4. Subtracting the Current when the Switch is ON (a) From the Current when the Switch is OFF (b) Reveals the Path of
the High Frequency Switching Current (c) Keep this Loop Small. The Voltage on the SW and BOOST Nodes will also be
Switched; Keep these Nodes as Small as Possible. Finally, Make Sure the Circuit is Shielded with a Local Ground Plane
1943fa
17
LT1943
U
OPERATIO
GND
AVDD
VIN
PLACE VIAS UNDER
GROUND PAD TO
GROUND PLANE FOR
GOOD THERMAL
CONDUCTIVITY
VOFF
GND
VLOGIC
1943 F05
Figure 5. Top Side PCB Layout
U
TYPICAL APPLICATIO S
8V to 20V Input, Quad Output TFT-LCD Power Supply
VIN
8V TO 20V
ZHCS400
VOFF
–5.5V
50mA
44.2k
2.2µF
10V
X5R
ZHCS400
0.47µF
16V
X5R
10µH
10µF
25V
X5R
33µH
VIN
SW3
PGOOD
VON
VLOGIC
3.3V
2A
0.22µF
10V X5R
4.7µH
B230A
PGOOD
VON
35V
30mA
274k
FB3
22µF
6.3V
X5R
18k
0.047µF
E3
VC1
100pF
2.2nF
0.015µF
SW1
FB1
10.0k
10.0k
CT
BOOST
10µF
16V
X5R
0.015µF
SS-234
LT1943
BIAS
16.2k
SW2
RUN-SS
10µH
FB4
CMDSH-3
AVDD
12.2V
500mA
10µH
FB2
NFB4
10pF
B240A
88.7k
SW4
10.0k
1µF
25V
X5R
6.8k
100pF
2.2nF
VC2
VC3
10.0k
GND
SGND
VC4
27k
100pF
680pF
13k
100pF
2.2nF
2.2µF
50V
X5R
0.47µF
50V
X5R
1943 TA02
1943fa
18
LT1943
U
PACKAGE DESCRIPTIO
FE Package
28-Lead Plastic TSSOP (4.4mm)
(Reference LTC DWG # 05-08-1663)
Exposed Pad Variation EB
9.60 – 9.80*
(.378 – .386)
4.75
(.187)
4.75
(.187)
28 2726 25 24 23 22 21 20 19 18 1716 15
6.60 ±0.10
2.74
(.108)
4.50 ±0.10
SEE NOTE 4
0.45 ±0.05
EXPOSED
PAD HEAT SINK
ON BOTTOM OF
PACKAGE
6.40
2.74
(.252)
(.108)
BSC
1.05 ±0.10
0.65 BSC
RECOMMENDED SOLDER PAD LAYOUT
4.30 – 4.50*
(.169 – .177)
0.09 – 0.20
(.0035 – .0079)
0.50 – 0.75
(.020 – .030)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
2. DIMENSIONS ARE IN MILLIMETERS
(INCHES)
3. DRAWING NOT TO SCALE
1 2 3 4 5 6 7 8 9 10 11 12 13 14
0.25
REF
1.20
(.047)
MAX
0° – 8°
0.65
(.0256)
BSC
0.195 – 0.30
(.0077 – .0118)
TYP
0.05 – 0.15
(.002 – .006)
FE28 (EB) TSSOP 0204
4. RECOMMENDED MINIMUM PCB METAL SIZE
FOR EXPOSED PAD ATTACHMENT
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.150mm (.006") PER SIDE
1943fa
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.
19
LT1943
U
TYPICAL APPLICATIO
5V Input, Quad Output TFT-LCD Power Supply
ZHCS400
VOFF
–10V
50mA
0.47µF
16V
X5R
VIN
4.5V TO 8V
10µH
80.6k
2.2µF
10V
X5R
ZHCS400
4.7µH
10µF
10V
X5R
SW4
VIN
SW2
FB2
RUN-SS
FB4
VLOGIC
3.3V
1.5A
0.22µF
10V X5R
E3
232k
SW1
FB3
FB1
VC1
10.0k
22µF
10V
X5R
7.5k
100pF
2.7nF
AVDD
13V
500mA
VON
30V
20mA
0.047µF
PGOOD
VON
BOOST
4.7µH
B230A
Si2343DS
0.015µF
CT
BIAS
16.5k
10.0k
0.015µF
SS-234
LT1943
100k
95.3k
SW3
10pF
CMDSH-3
10µF
16V
X5R
68µH
NFB4
10.0k
B240A
VC2
4.7k
100pF
4700pF
VC3
10.0k
GND
SGND
VC4
30k
100pF
1500pF
13k
100pF
2.2nF
2.2µF
35V
X5R
0.47µF
35V
X5R
1943 TA03
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1615/LT1615-1
300mA/80mA (ISW), Constant Off-Time, High Efficiency
Step-Up DC/DC Converters
VIN: 1.2V to 15V, VOUT(MAX): 34V, IQ: 20µA, ISD: <1µA,
ThinSOTTM Package
LT1940
Dual Output 1.4A (IOUT), Constant 1.1MHz, High Efficiency
Step-Down DC/DC Converter
VIN: 3V to 25V, VOUT(MIN): 1.2V, IQ: 2.5mA, ISD: <1µA,
TSSOP-16E Package
LT1944/LT1944-1
Dual Output 350mA (ISW), Constant Off-Time, High Efficiency
Step-Up DC/DC Converter
VIN: 1.2V to 15V, VOUT(MAX): 34V, IQ: 20µA, ISD: <1µA,
MS Package
LT1945
Dual Output, Pos/Neg, 350mA (ISW), Constant Off-Time,
High Efficiency Step-Up DC/DC Converter
VIN: 1.2V to 15V, VOUT(MAX): ±34V, IQ: 20µA, ISD: <1µA,
MS Package
LT1946/LT1946A
1.5mA (ISW), 1.2MHz/2.7MHz, High Efficiency
Step-Up DC/DC Converter
VIN: 2.75V to 16V, VOUT(MAX): 34V, IQ: 20µA, ISD: <1µA,
MS Package
LT1947
1.1A, 3MHz, TFT-LCD Triple Output Switching Regulator
VIN: 2.7V to 8V, VOUT(MAX): 34V, IQ: 9.5mA, ISD: <1µA,
MS Package
LT3464
85mA (ISW), Constant Off-Time, High Efficiency Step-Up DC/DC VIN: 2.3V to 10V, VOUT(MAX): 34V, IQ: 25µA, ISD: <0.5µA,
Converter with Integrated Schottky and Output Disconnect PNP ThinSOT Package
ThinSOT is a trademark of Linear Technology Corporation.
1943fa
20
Linear Technology Corporation
LT/LT 0405 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900
●
FAX: (408) 434-0507 ● www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2003
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