LINER LT3579IFE-1-PBF

LT3579/LT3579-1
6A Boost/Inverting
DC/DC Converter with Fault Protection
FEATURES
DESCRIPTION
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The LT®3579 is a PWM DC/DC converter with built-in fault
protection features to aid in protecting against output shorts,
input/output overvoltage, and overtemperature conditions.
The part consists of a 42V master switch, and a 42V slave switch
that can be tied together for a total current limit of 6A.
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6A, 42V Combined Power Switch
Output Short Circuit Protection
Wide Input Range: 2.5V to 16V Operating,
40V Maximum Transient
LT3579-1: Dual-Phase Capable
Master/Slave (3.4A/2.6A) Switch Design
User Configurable Undervoltage Lockout
Easily Configurable as a Boost, SEPIC, Inverting, or
Flyback Converter
Low VCESAT Switch: 250mV at 5.5A (Typical)
Can be Synchronized to External Clock
Can Synchronize other Switching Regulators
High Gain SHDN Pin Accepts Slowly Varying Input
Signals
20-Lead TSSOP and 20-Pin 4mm × 5mm QFN
Packages
The LT3579 is ideal for many local power supply designs. It
can be easily configured in Boost, SEPIC, Inverting, or Flyback
configurations, and is capable of generating 12V at 1.7A, or
–12V at 1.2A from a 5V input. In addition, the LT3579’s slave
switch allows the part to be configured in high voltage, high
power charge pump topologies that are very efficient and
require fewer components than traditional circuits.
The LT3579’s switching frequency range can be set between
200kHz and 2.5MHz. The part may be clocked internally at
a frequency set by the resistor from the RT pin to ground,
or it may be synchronized to an external clock. A buffered
version of the clock signal is driven out of the CLKOUT
pin, and may be used to synchronize other compatible
switching regulator ICs to the LT3579.
APPLICATIONS
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Local Power Supply
Vacuum Flourescent Display (VFD) Bias Supplies
TFT-LCD Bias Supplies
Automotive Engine Control Unit (ECU) Power
The LT3579 also features innovative SHDN pin circuitry that
allows for slowly varying input signals and an adjustable
undervoltage lockout function. Additional features such
as frequency foldback and soft-start are integrated. The
LT3579 is available in 20-lead TSSOP and 20-pin 4mm ×
5mm QFN packages.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Protected by U.S. Patents, including 7579816.
TYPICAL APPLICATION
Efficiency and Power Loss
1MHz, 5V to 12V Boost Converter with Output Short Circuit Protection
2.2μH
100k
200k
130k
FAULT
CLKOUT
VC
RT
SYNC GND
86.6k
10μF
GATE
LT3579
SHDN
6.3k
FB
VIN
VIN
TEMPERATURE
MONITOR
8k
SS
0.1μF
47pF
2.2nF
3.2
90
2.8
80
2.4
70
2.0
60
1.6
50
1.2
40
0.8
30
0.4
0
20
0
3579 TA01
POWER LOSS (W)
10μF
SW1 SW2
22μF
VOUT
12V
1.7A
EFFICIENCY (%)
VIN
5V
100
0.25 0.5 0.75 1 1.25 1.5 1.75
LOAD CURRENT (A)
2
35791 TA02
35791f
1
LT3579/LT3579-1
ABSOLUTE MAXIMUM RATINGS
(Note 1)
VIN Voltage ................................................. –0.3V to 40V
SW1/SW2 Voltage ..................................... –0.4V to 42V
RT Voltage .................................................... –0.3V to 5V
SS, FB Voltage ......................................... –0.3V to 2.5V
VC Voltage ................................................... –0.3V to 2V
SHDN Voltage ............................................ –0.3V to 40V
SYNC Voltage ............................................ –0.3V to 5.5V
GATE Voltage ............................................. –0.3V to 80V
FAULT ......................................................... –0.3V to 40V
FAULT Current .....................................................±0.5mA
CLKOUT ....................................................... –0.3V to 3V
CLKOUT Current ....................................................±1mA
Operating Junction Temperature Range
LT3579E (Notes 2, 4) .........................–40°C to 125°C
LT3579I (Notes 2, 4) ..........................–40°C to 125°C
Storage Temperature Range...................–65°C to 150°C
PIN CONFIGURATION
20 SYNC
2
19 SS
20 19 18 17
GATE
3
18 RT
FAULT
4
17 SHDN
VIN
5
SW1
6
SW1
7
GATE 1
16 RT
15 SHDN
FAULT 2
16 CLKOUT
VIN 3
14 CLKOUT
21
GND
13 SW2
14 SW2
SW1 5
12 SW2
SW1 6
11 SW2
8
13 SW2
SW1
9
12 SW2
SW1 10
11 SW2
FE PACKAGE
20-LEAD PLASTIC TSSOP
7
8
9 10
SW2
SW1
GND
SW1 4
GND
15 SW2
SW1
21
GND
SS
1
VC
VC
FB
FB
SYNC
TOP VIEW
TOP VIEW
UFD PACKAGE
20-LEAD (4mm s 5mm) PLASTIC QFN
TJMAX = 125°C, θJA = 38°C/W, θJC = 10°C/W
EXPOSED PAD (PIN 21) IS GND, MUST BE SOLDERED TO PCB
TJMAX = 125°C, θJA = 34°C/W, θJC = 2.7°C/W
EXPOSED PAD (PIN 21) IS GND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LT3579EFE#PBF
LT3579EFE#TRPBF
LT3579FE
20-Lead Plastic TSSOP
–40°C to 125°C
LT3579IFE#PBF
LT3579IFE#TRPBF
LT3579FE
20-Lead Plastic TSSOP
–40°C to 125°C
LT3579EUFD#PBF
LT3579EUFD#TRPBF
3579
20-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
LT3579IUFD#PBF
LT3579IUFD#TRPBF
3579
20-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
LT3579EFE-1#PBF
LT3579EFE-1#TRPBF
LT3579FE-1
20-Lead Plastic TSSOP
–40°C to 125°C
LT3579IFE-1#PBF
LT3579IFE-1#TRPBF
LT3579FE-1
20-Lead Plastic TSSOP
–40°C to 125°C
LT3579EUFD-1#PBF
LT3579EUFD-1#TRPBF
35791
20-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
LT3579IUFD-1#PBF
LT3579IUFD-1#TRPBF
35791
20-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
35791f
2
LT3579/LT3579-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 5V, VSHDN = VIN, VFAULT = VIN unless otherwise noted. (Note 2).
PARAMETER
CONDITIONS
MIN
TYP
2.3
2.5
V
16.2
18.7
21.2
V
V
l
Minimum Input Voltage
VIN Overvoltage Lockout
MAX
UNITS
Positive Feedback Voltage
l
1.195
1.215
1.230
Negative Feedback Voltage
l
3
9
16
mV
VFB=Positive Feedback Voltage, Current into Pin
l
80.5
83.3
85
μA
Negative FB Pin Bias Current
VFB=Negative Feedback Voltage, Current out of Pin
l
81
83.3
85.5
Error Amp Transconductance
ΔI=10μA
Positive FB Pin Bias Current
Error Amp Voltage Gain
Quiescent Current
Not Switching
Quiescent Current in Shutdown
VSHDN = 0V
μA
250
μmhos
70
V/V
1.9
2.4
mA
0
1
μA
Reference Line Regulation
2.5V ≤ VIN ≤ 15V
0.01
0.05
%/V
Switching Frequency, fOSC
RT = 34kΩ
l
2.2
2.5
2.8
MHz
RT = 432kΩ
l
175
200
225
kHz
Switching Frequency in Foldback
Compared to Normal fOSC
Switching Frequency Range
Free-Running or Synchronizing
1/6
l
200
SYNC High Level for Sync
l
1.3
SYNC Low Level for Sync
l
SYNC Clock Pulse Duty Cycle
VSYNC = 0V to 2V
ratio
2500
kHz
V
20
0.4
V
80
%
Recommended Minimum SYNC Ratio
fSYNC/fOSC
3/4
Minimum Off-Time
45
nS
Minimum On-Time
55
nS
SW1 Current Limit
At All Duty Cycles (Note 3)
SW Current Sharing, ISW2/ISW1
SW1 and SW2 Tied Together
SW1 + SW2 Current Limit
ISW2/ISW1 = 0.78, At All Duty Cycles (Note 3)
Switch VCESAT
l
3.4
4.2
5.1
0.78
l
6
A
A/A
7.5
9.4
A
SW1 and SW2 Tied Together, ISW1 + ISW2 = 5.5A
250
350
mV
SW1 Leakage Current
VSW1 = 5V
0.01
1
μA
SW2 Leakage Current
VSW2 = 5V
0.01
1
μA
35791f
3
LT3579/LT3579-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 5V, VSHDN = VIN, VFAULT = VIN unless otherwise noted. (Note 2).
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Soft-Start Charge Current
VSS = 30mV, Current Flows Out of SS pin
l
5.7
8.7
11.3
μA
Soft-Start Discharge Current
Part in FAULT
VSS = 2.1V,
Current Flows into SS Pin
l
5.7
8.7
11.3
μA
Soft-Start High Detection Voltage
Part in FAULT
l
1.65
1.8
1.95
V
Soft-Start Low Detection Voltage
Part Exiting FAULT
l
30
50
85
SHDN Minimum Input Voltage High
Active Mode, SHDN Rising
Active Mode, SHDN Falling
l
l
1.27
1.24
1.33
1.3
1.41
1.38
SHDN Input Voltage Low
Shutdown Mode
l
.3
V
SHDN Pin Bias Current
VSHDN = 3V
VSHDN = 1.3V
VSHDN = 0V
9.5
40
11.4
0
60
13.4
0.1
μA
μA
μA
CCLKOUT = 50pF
1.9
2.1
2.3
V
200
mV
CLKOUT Output Voltage High
mV
V
V
CLKOUT Output Voltage Low
CCLKOUT = 50pF
100
CLKOUT Duty Cycle
LT3579, TJ = 25°C
42
LT3579-1, All TJ
50
%
CLKOUT Rise Time
CCLKOUT = 50pF
12
ns
CLKOUT Fall Time
CCLKOUT = 50pF
8
ns
GATE Pull Down Current
VGATE = 3V
VGATE = 80V
GATE Leakage Current
VGATE = 50V, GATE Off
FAULT Output Voltage Low
100μA into FAULT Pin
FAULT Leakage Current
VFAULT = 40V, FAULT Off
l
l
800
800
l
933
933
%
1100
1100
μA
μA
0.01
1
μA
150
300
mV
0.01
1
μA
FAULT Input Voltage Low Threshold
l
700
750
800
mV
FAULT Input Voltage High Threshold
l
950
1000
1050
mV
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: The LT3579E is guaranteed to meet performance specifications
from 0°C to 125°C junction temperature. Specifications over the –40°C
to 125°C operating junction temperature range are assured by design,
characterization and correlation with statistical process controls. The
LT3579I is guaranteed over the full –40°C to 125°C operating junction
temperature range.
Note 3: Current limit guaranteed by design and/or correlation to static test.
Note 4: This IC includes overtemperature protection that is intended
to protect the device during momentary overload conditions. Junction
temperature will exceed 125°C when overtemperature protection is active.
Continuous operation over the specified maximum operating junction
temperature may impair device reliability.
35791f
4
LT3579/LT3579-1
TYPICAL PERFORMANCE CHARACTERISTICS
Switch Current Limit
Switch Saturation Voltage
10
Switch Current Sharing
1.0
350
0.9
9
300
7
6
5
4
3
2
VSW1 = VSW2
0.8
250
0.7
ISW2/ISW1 (A/A)
8
SATURATION VOLTAGE (mV)
SW1 + SW2 CURRENT (A)
TA = 25°C, unless otherwise noted.
200
150
0
50
40
60
DUTY CYCLE (%)
30
70
0.1
0.0
0
80
1
3
2
4
5
6
SW1 + SW2 CURRENT (A)
7
35791 G01
9
9
8
8
6
5
4
3
6
5
4
2
1
0
0.2
0.4
0.6
0.8
SS VOLTAGE (V)
1
35791 G04
RT = 432k
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G07
1.22
1.215
1.21
1.2
–50 –25
1.2
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G05
35791 G06
Oscillator Frequency During
Soft-Start
CLKOUT Duty Cycle
1
80
70
CLKOUT DUTY CYCLE (%)
NORMALIZED OSCILLATOR FREQUENCY (FSW/FNOM)
FREQUENCY (MHz)
RT = 34k
4
1.205
0
25 50 75 100 125 150
TEMPERATURE (°C)
3.5
Positive Feedback Voltage
3
1
Oscillator Frequency
1.5 2 2.5 3
SW1 CURRENT (A)
1.225
7
2
0
1
1.23
FB VOLTAGE (V)
SW1 + SW2 CURRENT (A)
SW1 + SW2 CURRENT (A)
10
7
0.5
35791 G03
Commanded Switch Current vs SS
10
3.0
2.8
2.6
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
–50 –25
0
8
35791 G02
Switch Current Limit
vs Temperature
0
–50 –25
0.4
0.2
0
20
0.5
0.3
100
50
1
0.6
1/2
1/3
1/4
1/5
1/6
INVERTING
CONFIGURATIONS
0
0
0.2
BOOSTING
CONFIGURATIONS
0.4
0.6
0.8
FB VOLTAGE (V)
1
1.2
35791 G08
60
50
40
30
20
0
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G09
35791f
5
LT3579/LT3579-1
TYPICAL PERFORMANCE CHARACTERISTICS
Gate Pin Current (VSS = 2.1V)
Gate Pin Current (VGATE = 5V)
50
1000
1000
45
900
900
40
GATE PIN CURRENT (μA)
CLKOUT RISE TIME
35
30
25
20
15
CLKOUT FALL TIME
10
800
TA = –40°C
TA = 25°C
TA = 125°C
GATE PIN CURRENT (μA)
CLKOUT RISE OR FALL TIME (ns)
CLKOUT Rise Time at 1MHz
TA = 25°C, unless otherwise noted.
700
600
550
400
300
800
700
600
500
400
300
200
200
5
100
100
0
0
0
50
100
150
200
CLKOUT CAPACITIVE LOAD (pF)
250
0
0
10
20 30 40 50 60
GATE PIN VOLTAGE (V)
70
0
80
0.5
0.75
1
SS VOLTAGE (V)
0.25
1.25
1.5
35791 G10
35791 G11
35791 G12
SHDN Pin Current
Active/Lockout Threshold
1.4
SHDN Pin Current
30
250
TA = –40°C
1.38
SHDN PIN CURRENT (μA)
SHDN VOLTAGE (V)
SHDN RISING
1.34
1.32
1.3
SHDN FALLING
1.28
1.26
1.24
SHDN PIN CURRENT (μA)
25
1.36
20
15
10
TA = 25°C
TA = 125°C
25 50 75 100 125 150
TEMPERATURE (°C)
0
0.25 0.5 0.75 1 1.25 1.5 1.75
SHDN VOLTAGE (V)
35791 G13
0
2
0
Internal UVLO
2.45
21
FAULT RISING
19
18
17
16
14
2.15
40
1
15
2.2
35
Fault Input Threshold
FAULT VOLTAGE (V)
VIN VOLTAGE (V)
VIN VOLTAGE (V)
2.4
2.25
15 20 25 30
SHDN VOLTAGE (V)
1.25
20
2.3
10
35791 G15
VIN OVLO
22
2.35
5
35791 G14
2.5
2.1
–50 –25
100
TA = –40°C
0
0
TA = 125°C
150
50
5
1.22
1.2
–50 –25
TA = 25°C
200
0.75
FAULT FALLING
0.5
0.25
13
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G16
12
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G17
0
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
35791 G18
35791f
6
LT3579/LT3579-1
PIN FUNCTIONS
(QFN/TSSOP)
GATE (Pin 1/Pin 3): PMOS Gate Drive Pin. The GATE pin
is a pull-down current source, and can be used to drive
the gate of an external PMOS transistor for output short
circuit protection or output disconnect. The GATE pin
current increases linearly with the SS pin’s voltage, with
a maximum pull-down current of 933μA at SS voltages
exceeding 500mV. Note that if the SS voltage is greater
than 500mV, and the GATE pin voltage is less than 2V, the
GATE pin looks like a 2kΩ impedance to ground. See the
Appendix for more information.
FAULT (Pin 2/Pin 4): Fault Indication Pin. This active
low, bidirectional pin can either be pulled low (below
750mV) by an external source, or internally by the chip
to indicate a fault. When pulled low, this pin causes the
power switches to turn off, the GATE pin to become high
impedance, the CLKOUT pin to become disabled, and the
SS pin to go through a charge/discharge sequence. The
end/absence of a fault is indicated when the voltage on this
pin exceeds 1V. A pull-up resistor or some other form of
pull-up network needs to exist on this pin to pull it above
1V in the absence of a fault.
VIN (Pin 3/Pin 5): Input Supply Pin. Must be locally
bypassed.
SW1 (Pins 4 - 7/Pins 6 - 10): Master Switch Pin. This is the
collector of the internal master NPN power switch. SW1
is designed to handle a peak collector current of 3.4A
(minimum). Minimize the metal trace area connected to
this pin to minimize EMI.
GND (Pins 8, 9, Exposed Pad Pin 21/Exposed Pad Pin 21):
Ground. Must be soldered directly to local ground
plane.
SW2 (Pins 10-13/Pins 11-15): Slave Switch Pin. This is
the collector of the internal slave NPN power switch. SW2
is designed to handle a peak collector current of 2.6A
(minimum). Minimize the metal trace area connected to
this pin to minimize EMI.
CLKOUT (Pin 14/Pin 16): Clock Output Pin. Use this pin to
synchronize one or more other ICs to the LT3579. This pin
oscillates at the same frequency as the internal oscillator of
the part or as the SYNC pin. CLKOUT may also be used as
a temperature monitor since the CLKOUT pin’s duty cycle
varies linearly with the part’s junction temperature. The
CLKOUT pin signal of the LT3579-1 is 180° out of phase
with the internal oscillator or SYNC pin, and the duty cycle
is fixed at ~50%. The LT3579-1 is useful for multiphase
switching regulators.
SHDN (Pin 15/Pin 17): Shutdown Pin. In conjunction
with the UVLO (undervoltage lockout) circuit, this pin is
used to enable/disable the chip and restart the soft-start
sequence. Drive below 0.3V to disable the chip with very
low quiescent current. Drive above 1.33V (typical) to
activate the chip and restart the soft-start sequence. Do
not float this pin.
RT (Pin 16/Pin 18): Timing Resistor Pin. Adjusts the
LT3579’s switching frequency. Place a resistor from this
pin to ground to set the frequency to a fixed free running
level. Do not float this pin.
SYNC (Pin 17/Pin 20): To synchronize the switching
frequency to an outside clock, simply drive this pin with
a clock. The high voltage level of the clock must exceed
1.3V, and the low level must be less than 0.4V. Drive this
pin to less than 0.4V to revert to the internal free running
clock. See the Applications Information section for more
information.
SS (Pin 18/Pin 19): Soft-Start Pin. Place a soft-start
capacitor here. Upon start-up, the SS pin will be charged
by a (nominally) 250kΩ resistor to ~2.1V. During a fault,
the SS pin will be slowly charged up and discharged as
part of a timeout sequence.
VC (Pin 19/Pin 2): Error Amplifier Output Pin. Tie external
compensation network to this pin.
FB (Pin 20/Pin 1): Positive and Negative Feedback Pin.
For a Boost or Inverting Converter, tie a resistor from the
FB pin to VOUT according to the following equations:
⎛V
– 1.215V ⎞
RFB = ⎜ OUT
⎟ ; Boost or SEPIC Converter
83.3µA
⎝
⎠
⎛ | V | +9mV ⎞
RFB = ⎜ OUT
⎟ ; Inverting Converter
⎝ 83.3µA ⎠
35791f
7
LT3579/LT3579-1
BLOCK DIAGRAM
OPTIONAL
D1
L1
M1
VIN
VOUT
COUT1
CIN
COUT
RFAULT
RGATE
FAULT
GATE
933μA
+
–
SW1
+
–
SW2
+
–
ISW1
**
50mV
+
–
+
–
1.8V
250k
**
STARTUP
& FAULT
LOGIC
SS
42V (MIN)
1.33V
SW2
TD ~ 30ns
+
–
SHDN
45mV
3.4A (MIN)
DRIVER
DISABLE
CSS
1.17V
FB
42V (MIN)
–
+
+
–
750mV
+
–
2.1V
–
+
DIE TEMP
16.2V
VIN
165°C
VC
–
+
SOFTSTART
+
–
VBE • 0.9
Q2
SW1
COMPARATOR
SR1
VIN
R
A3
1.215V
REFERENCE
S
Q1
Q
+
+
+
14.6k
∑
A1
RS
12m
RFB
GND
RAMP
GENERATOR
+
14.6k
A4
–
–
FB
15.4m
DRIVER
–
UVLO
FREQUENCY
FOLDBACK
A2
÷N ADJUSTABLE
OSCILLATOR
SS
–
SYNC
BLOCK
VC
SYNC
RT
CLKOUT
RC
CC
RT
3579 BD
** SW OVERVOLTAGE PROTECTION IS NOT GUARANTEED TO PROTECT THE LT3579/LT3579-1 DURING SW OVERVOLTAGE EVENTS.
Figure 1. Block Diagram
35791f
8
LT3579/LT3579-1
STATE DIAGRAM
SHDN < 1.33V
OR
VIN < 2.3V
CHIP OFF
• ALL SWITCHES DISABLED
• IGATE OFF
• FAULTS CLEARED
SHDN > 1.33V
AND
VIN > 2.3V
INITIALIZE
• SS PULLED LOW
FAULT1
SS < 50mV
FAULT2
FAULT DETECTED
SOFT START
• IGATE ENABLED
• SS CHARGES UP
• SWITCHER ENABLED
FAULT1
• SS CHARGES UP
• IGATE OFF
• FAULT PULLED LOW INTERNALLY BY LT3579
• SWITCHER DISABLED
• CLKOUT DISABLED
SS > 1.8V
AND NO FAULT1
CONDITIONS STILL DETECTED
POST FAULT DELAY
• SS SLOWLY DISCHARGES
SAMPLE MODE
• Q1 & Q2 SWITCHES
FORCED ON EVERY CYCLE
FOR AT LEAST MINIMUM
ON-TIME
• IGATE FULLY ACTIVATED
WHEN SS > 500mV
FAULT1
FAULT1
SS < 50mV
LOCAL FAULT OVER
IF |VOUT| DROPS CAUSING:
FB < 1.17V (BOOST)
OR
FB > 45mV (INVERTING)
FAULT1 =
• INTERNAL FAULT PULLDOWN
RELEASED BY LT3579
• SS CONTINUES DISCHARGING
TO GND
NORMAL MODE
• NORMAL OPERATION
• CLKOUT ENABLED WHEN
SS > 1.8V
OVER VOLTAGE PROTECTION ON VIN (VIN > 16.2V (MIN))
OVER TEMPERATURE (TJUNCTION > 165°C (TYP))
OVER CURRENT ON SW1 (ISW1 > 3.4A (MIN))
OVER VOLTAGE PROTECTION ON SW1 (VSW1 > 42V (MIN))
OVER VOLTAGE PROTECTION ON SW1 (VSW2 > 42V (MIN))
FAULT1
FAULT > 1.0V
FAULT1
FAULT2 = FAULT PULLED LOW EXTERNALLY (FAULT < 0.75V)
3759 SD
Figure 2. State Diagram
35791f
9
LT3579/LT3579-1
OPERATION
OPERATION – OVERVIEW
The LT3579 uses a constant-frequency, current mode
control scheme to provide excellent line and load regulation.
The part’s undervoltage lockout (UVLO) function, together
with soft-start and frequency foldback, offers a controlled
means of starting up. Fault features are incorporated in
the LT3579 to aid in the detection of output shorts, overvoltage, and overtemperature conditions. Refer to the Block
Diagram (Figure 1) and the State Diagram (Figure 2) for
the following description of the part’s operation.
OPERATION – START-UP
Several functions are provided to enable a very clean
start-up for the LT3579.
Precise Turn-On Voltage
The SHDN pin compares to an internal voltage reference to
give a precise turn on voltage level. Taking the SHDN pin
above 1.33V (typical) enables the part. Taking the SHDN pin
below 0.3V shuts down the chip, resulting in extremely low
quiescent current. The SHDN pin has 30mV of hysteresis
to protect against glitches and slow ramping.
Undervoltage-Lockout (UVLO)
The SHDN pin can also be used to create a configurable
UVLO. The UVLO function sets the turn on/off of the LT3579
at a desired input voltage (VINUVLO). Figure 3 shows how
a resistor divider (or single resistor) from VIN to the SHDN
pin can be used to set VINUVLO. RUVLO2 is optional. It may
be left out, in which case set it to infinite in the equation
below. For increased accuracy, set RUVLO2 ≤ 10kΩ. Pick
RUVLO1 as follows:
RUVLO1 =
VINUVLO – 1.33V
⎛ 1.33V
⎜
⎜R
⎝ UVLO2
⎞
⎟ + 11.66µA
⎟
⎠
VIN
VIN
1.33V
RUVLO1
SHDN
–
ACTIVE/
LOCKOUT
+
11.6μA
AT 1.33V
RUVLO2
(OPTIONAL)
GND
3579 F03
Figure 3. Configurable UVLO
The LT3579 also has internal UVLO circuitry that disables
the chip when VIN < 2.3V (typical).
Soft-Start of Switch Current
The soft-start circuitry provides for a gradual ramp-up of
the switch current (refer to Commanded Switch Current vs.
SS in Typical Performance Characteristics). When the part
is brought out of shutdown, the external SS capacitor is
first discharged which resets the states of the logic circuits
in the chip. Then an integrated 250k resistor pulls the SS
pin to ~1.8V at a ramp rate set by the external capacitor
connected to the pin. Once SS gets to 1.8V, the CLKOUT
pin is enabled, and an internal regulator pulls the pin up
quickly to ~2.1V. Typical values for the external soft-start
capacitor range from 100nF to 1μF.
Soft-Start of External PMOS (if used)
The soft-start circuitry also gradually ramps up the GATE
pin pull-down current which allows an external PMOS
to slowly turn on (M1 in Block Diagram). The GATE pin
current increases linearly with SS voltage, with a maximum
current of 933μA when the SS voltage gets above 500mV.
Note that if the GATE pin voltage is less than 2V for SS
voltages exceeding 500mV, then the GATE pin impedance
to ground is 2kΩ. The soft turn on of the external PMOS
helps limit inrush current at start-up, making hot plugs
of the LT3579 feasible and safe.
35791f
10
LT3579/LT3579-1
OPERATION
Sample Mode
Sample Mode is the mechanism used by the LT3579 to
aid in the detection of output shorts. It refers to a state of
the LT3579 where the master and slave power switches
(Q1 and Q2) are turned on for a minimum period of time
every clock cycle (or every few clock cycles in frequency
foldback) in order to “sample” the inductor current. If the
sampled current through Q1 exceeds the master switch
current limit of 3.4A (minimum), the LT3579 triggers an
overcurrent fault internally (see Operation-Fault section for
details). Sample Mode exists when FB is out of regulation
by more than 3.7% or 45mV < FB < 1.17V (typical). The
LT3579’s power switches are designed to handle a total
peak current of 6A (minimum).
Frequency Foldback
The frequency foldback circuit reduces the switching
frequency when 350mV < FB < 900mV (typical). This
feature lowers the minimum duty cycle that the part can
achieve, thus allowing better control of the inductor current
during start-up. When the FB voltage is pulled outside of
this range, the switching frequency returns to normal.
Note that the peak inductor current at start-up is a
function of many variables including load profile, output
capacitance, target VOUT, VIN, switching frequency, etc. Test
the application’s performance at start-up to ensure that
the peak inductor current does not exceed the minimum
current limit.
OPERATION – REGULATION
The following description of the LT3579’s operation
assumes the FB voltage is close enough to its regulation
target so that the part is not in Sample Mode. Use the
Block Diagram as a reference when stepping through
the following description of the LT3579 operating in
regulation. At the start of each oscillator cycle, the SR
latch (SR1) is set, which turns on the power switches Q1
and Q2. The collector current through the master switch,
Q1, is ~1.3 times the collector current through the slave
switch, Q2, when the collectors of the two switches are
tied together. Q1’s emitter current flows through a current
sense resistor (RS) generating a voltage proportional to
the total switch current. This voltage (amplified by A4) is
added to a stabilizing ramp and the resulting sum is fed
into the positive terminal of the PWM comparator A3.
When the voltage on the positive input of A3 exceeds
the voltage on the negative input, the SR latch is reset,
turning off the master and slave power switches. The
voltage on the negative input of A3 (VC pin) is set by A1
(or A2), which is simply an amplified difference between
the FB pin voltage and the reference voltage (1.215V if
the LT3579 is configured as a boost converter, or 9mV
if configured as an inverting converter). In this manner,
the error amplifer sets the correct peak current level to
maintain output regulation.
As long as the part is not in fault (see Operation – FAULT
section) and the SS pin exceeds 1.8V, the LT3579 drives its
CLKOUT pin at the frequency set by the RT pin or the SYNC
pin. The CLKOUT pin can synchronize other compatible
switching regulator ICs (including additional LT3579s) with
the LT3579. Additionally, the duty cycle of CLKOUT varies
linearly with the part’s junction temperature and may be
used as a temperature monitor. The CLKOUT signal on the
LT3579-1 is ~180° out of phase with the internal oscillator
and has a fixed duty cycle of ~50%.
OPERATION – FAULT
The LT3579’s FAULT pin is an active low, bidirectional
pin (refer to Block Diagram) that pulls low to indicate a
fault. Each of the following events can trigger a fault in
the LT3579:
A. FAULT1 Events:
1. SW Overcurrent
a. ISW1 > 3.4A (minimum)
b. (ISW1 + ISW2) > 6A (minimum)
2. VIN Voltage > 16.2V (minimum)
3. SW1 Voltage and/or SW2 Voltage > 42V
(minimum)
4. Die Temperature > 165°C
B. FAULT2 Events:
1. Pulling the FAULT pin low externally
35791f
11
LT3579/LT3579-1
OPERATION
When a fault is detected, in addition to the FAULT pin
being pulled low internally, the LT3579 also disables
its CLKOUT pin, turns off its power switches, and the
GATE pin becomes high impedance (refer to the State
Diagram). The external PMOS, M1, turns off when the
gate of M1 is pulled up to its source by the external
RGATE resistor (see Block Diagram) With the external
PMOS turned off, the power path from VIN to VOUT is
cut off, protecting power components downstream.
At the same time, a timeout sequence commences where
the SS pin is charged up to 1.8V (the SS pin will continue
charging up to ~2.1V and be held there in the case of
a FAULT1 event still existing), and then discharged to
50mV. This timeout period relieves the part, the PMOS,
and other downstream power components from electrical
and thermal stress for a minimum amount of time as set
by the voltage ramp rate on the SS pin.
In the absence of faults, the FAULT pin is pulled high by
the external RFAULT resistor (typically 100k). Figures 4
and 5 show the events that accompany the detection of
an output short on the LT3579.
VOUT
10V/DIV
CLKOUT
2V/DIV
IL
5A/DIV
FAULT
5V/DIV
10μs/DIV
35791 F04
Figure 4. Output Short Circuit Protection of the LT3579
SS
2V/DIV
GATE
5V/DIV
IL
5A/DIV
FAULT
5V/DIV
50ms/DIV
35791 F05
Figure 5. Continuous Output Short Showing FAULT Timeout Cycle
35791f
12
LT3579/LT3579-1
APPLICATIONS INFORMATION
BOOST CONVERTER COMPONENT SELECTION
VIN
5V
VIN
OPTIONAL
M1
COUT1
10μF
RFB
130k
SW1 SW2
100k
PARAMETERS/EQUATIONS
D1
30V, 4A
L1
2.2μH
Table 1. Boost Design Equations
VOUT
12V
1.7A
RGATE
6.3k
COUT
10μF
FB
FAULT
Step 1:
Inputs
Step 2:
DC
VIN
GATE
CIN
22μF
SHDN
CLKOUT
RT
VC
SYNC GND
SS
RT
86.6k
DC ≅
L TYP =
LT3579
200k
Pick VIN, VOUT, and fOSC to calculate equations below.
CSS
0.1μF
CF
47pF
VOUT – VIN + 0.5V
VOUT + 0.5V – 0.27 V
( VIN – 0.27V ) • DC
(1)
fOSC • 1.8 A
( VIN – 0.27V ) • (2 • DC – 1)
4A • fOSC • (1 – DC)
( V – 0.27V ) • DC
= IN
LMIN =
RC
8k
CC
2.2nF
Step 3:
L1
LMAX
• Solve equations 1, 2, and 3.
Figure 6. Boost Converter – The Component Values Given Are
Typical Values for a 1MHz, 5V to 12V Boost
Table 1 is a step-by-step set of equations to calculate
component values for the LT3579 when operating as a
Boost converter. Input parameters are input and output
voltage, and switching frequency (VIN , VOUT and fOSC
respectively). Refer to the Appendix for further information
on the design equations presented in Table 1.
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Output Current
IRIPPLE = Inductor Ripple Current
RDSON_PMOS = RDSON of External PMOS (set to 0 if not
using PMOS)
(3)
fOSC • 0.5A
37591 F06
The LT3579 can be configured as a Boost converter as in
Figure 6. This topology allows for positive output voltages
that are higher than the input voltage. An external PMOS
(optional) driven by the GATE pin of the LT3579 can achieve
input or output disconnect during a FAULT event. A single
feedback resistor sets the output voltage. For output
voltages higher than 40V, see the Charge Pump topology
in the Charge Pump Aided Regulators section.
(2)
• Choose the higher value between LTYP and LMIN for L1.
L1 should never exceed LMAX.
Step 4:
IRIPPLE
IRIPPLE =
( VIN – 0.27V ) • DC
fOSC • L1
Step 5:
IOUT
⎞
⎛
I
IOUT = ⎜6 A – RIPPLE ⎟ • (1 – DC)
2 ⎠
⎝
Step 6:
D1
VR > VOUT ; IAVG > IOUT
Step 7:
COUT,
COUT1
Step 8:
CIN
COUT =COUT1 =
(
fOSC • 0.01• VOUT – 0.5•IOUT • RDSON_PMOS
)
CIN = CPWR + C VIN
CIN =
IRIPPLE
6 A • DC
+
8 • fOSC • 0.005 • VIN 40 • fOSC • 0.005 • VIN
Step 9:
RFB
Step 10:
RT
IOUT • DC
RFB =
RT =
VOUT – 1.215V
83.3μA
87.6
– 1; fOSC in MHz and R T in kΩ
fOSC
Only needed for input or output disconnect. See PMOS
Step 11:
Selection in the Appendix for information on sizing the PMOS
PMOS
and the biasing resistor, RGATE.
Note: The maximum design target for peak switch current is 6A and
is used in this table. The final values for COUT and CIN may deviate
from the above equations in order to obtain desired load transient
performance for a particular application.
35791f
13
LT3579/LT3579-1
APPLICATIONS INFORMATION
SEPIC CONVERTER COMPONENT SELECTION
– COUPLED OR UN-COUPLED INDUCTORS
VPWR
9V TO 16V
C1
4.7μF
L1
6.8μH
CPWR
4.7μF
D1
60V, 3A
L2
6.8μH
RFB
130k
VIN
FB
SHDN
FAULT
DC ≅
L TYP =
GATE
SYNC
VC
GND
VOUT + 0.5V
VIN + VOUT + 0.5V – 0.27 V
( VIN – 0.27V ) • DC
(1)
fOSC • 1.8 A
( VIN – 0.27V ) • (2 • DC – 1)
4A • fOSC • (1 – DC)
( V – 0.27V ) • DC
= IN
LMIN =
CLKOUT
RT
RT
86.6k
Step 2: DC
Pick VIN, VOUT, and fOSC to calculate equations below.
LT3579
100k
CVIN
4.7μF
PARAMETERS/EQUATIONS
Step 1:
Inputs
COUT
10μF
s3
SW1 SW2
VIN
3.3V
TO 5V
VOUT
12V
1.6A (VPWR >9V)
1.9A (VPWR >12V)
Table 2. SEPIC Design Equations
CF
47pF
SS
CSS
0.22μF
RC
9.53k
Step 3: L
CC
2.2nF
• Choose the higher value between LTYP and LMIN for L.
L should never exceed LMAX.
• L = L1 = L2 for coupled inductors.
Figure 7. SEPIC Converter – The Component Values Given Are
Typical Values for a 1MHz, 9V–16V to 12V SEPIC Topology Using
Coupled Inductors
Table 2 is a step-by-step set of equations to calculate
component values for the LT3579 when operating as a
SEPIC converter using coupled inductors. Input parameters
are input and output voltage, and switching frequency
(VIN , VOUT and fOSC respectively). Refer to the Appendix
for further information on the design equations presented
in Table 2.
• L = L1⏐⏐L2 for un-coupled inductors.
Step 4:
IRIPPLE
IRIPPLE =
( VIN – 0.27V ) • DC
fOSC • L
Step 5: IOUT
⎞
⎛
I
IOUT = ⎜6 A – RIPPLE ⎟ • (1 – DC)
2 ⎠
⎝
Step 6: D1
VR > VIN + VOUT ; IAVG > IOUT
Step 7: C1
4.7μF ( typical) ; VRATING > VIN
Step 8: COUT
COUT =
Step 9: CPWR
CPWR =
Step 10: CVIN
C VIN =
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Output Current
IRIPPLE = Inductor Ripple Current
(3)
fOSC • 0.5A
• Solve equations 1, 2, and 3.
3759 F07
The LT3579 can also be configured as a SEPIC as in
Figure 7. This topology allows for positive output voltages
that are lower, equal, or higher than the input voltage. Output
disconnect is inherently built into the SEPIC topology,
meaning no DC path exists between the input and output
due to capacitor C1. This implies that a PMOS controlled
by the GATE pin is not required in the power path.
LMAX
(2)
fOSC • 0.005 • VOUT
IRIPPLE
8 • fOSC • 0.005 • VIN
6 A • DC
40 • fOSC • 0.005 • VIN
RFB =
Step 11: RFB
Step 12: RT
IOUT • DC
RT =
VOUT – 1.215V
83.3μA
87.6
– 1; fOSC in MHz and R T in kΩ
fOSC
Note: The maximum design target for peak switch current is 6A and
is used in this table. The final values for COUT, CPWR, and CVIN may
deviate from the above equations in order to obtain desired load
transient performance for a particular application.
35791f
14
LT3579/LT3579-1
APPLICATIONS INFORMATION
DUAL INDUCTOR INVERTING CONVERTER COMPONENT
SELECTION – COUPLED OR UN-COUPLED INDUCTORS
C1
4.7μF
L1
3.3μH
VIN
5V
PARAMETERS/EQUATIONS
Step 1: Inputs
L2
3.3μH
D1
30V, 2A
Table 3. Dual Inductor Inverting Design Equations
RFB
144k
VOUT
–12V
1.2A
Pick VIN, VOUT, and fOSC to calculate equations below.
DC ≅
Step 2: DC
SW1 SW2
VIN
FB
SHDN
CIN
22μF
GATE
LT3579
100k
FAULT
RT
SYNC
RT
72k
( VIN – 0.27V ) • DC
(1)
fOSC • 1.8 A
( VIN – 0.27V ) • (2 • DC – 1)
4A • fOSC • (1 – DC)
( V – 0.27V ) • DC
= IN
LMIN =
CLKOUT
VC
GND
L TYP =
COUT
10μF
s2
| VOUT | + 0.5V
VIN + | VOUT | +0.5V – 0.27 V
SS
CSS
0.22μF
CF
27pF
RC
20k
CC
1nF
Step 3: L
LMAX
(2)
(3)
fOSC • 0.5A
• Solve equations 1, 2, and 3.
3759 F08
• Choose the higher value between LTYP and LMIN for L.
L should never exceed LMAX.
Figure 8. Dual Inductor Inverting Converter – The Component
Values Given Are Typical Values for a 1.2MHz, 5V to –12V Inverting
Topology Using Coupled Inductors
Due to its unique FB pin, the LT3579 can work in a Dual
Inductor Inverting configuration as in Figure 8. Changing
the connections of L2 and the Schottky diode in the
SEPIC topology, results in generating negative output
voltages. This solution results in very low output voltage
ripple due to inductor L2 in series with the output. Output
disconnect is inherently built into this topology due to the
capacitor C1.
Table 3 is a step-by-step set of equations to calculate
component values for the LT3579 when operating as a Dual
Inductor Inverting converter using coupled inductors. Input
parameters are input and output voltage, and switching
frequency (VIN , VOUT and fOSC respectively). Refer to the
Appendix for further information on the design equations
presented in Table 3.
• L = L1 = L2 for coupled inductors.
• L = L1⏐⏐L2 for un-coupled inductors.
IRIPPLE =
Step 4: IRIPPLE
fOSC • L
Step 5: IOUT
⎞
⎛
I
IOUT = ⎜6 A – RIPPLE ⎟ • (1 – DC)
2 ⎠
⎝
Step 6: D1
VR > VIN +| VOUT | ; IAVG > IOUT
Step 7: C1
4.7μF ( typical) ; VRATING > VIN + | VOUT |
COUT =
Step 8: COUT
IRIPPLE
8 • fOSC • 0.005 • | VOUT |
CIN = CPWR + C VIN
Step 9: CIN
CIN =
IRIPPLE
6 A • DC
+
8 • fOSC • 0.005 • VIN 40 • fOSC • 0.005 • VIN
RFB =
Step 10: RFB
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Output Current
IRIPPLE = Inductor Ripple Current
( VIN – 0.27V ) • DC
Step 11: RT
RT =
| VOUT | + 9mV
83.3μA
87.6
– 1; fOSC in MHz and R T in kΩ
fOSC
Note: The maximum design target for peak switch current is 6A and
is used in this table. The final values for COUT and CIN may deviate
from the above equations in order to obtain desired load transient
performance for a particular application.
35791f
15
LT3579/LT3579-1
APPLICATIONS INFORMATION
LAYOUT GUIDELINES FOR BOOST, SEPIC, AND DUAL
INDUCTOR INVERTING TOPOLOGIES
General Layout Guidelines
• To optimize thermal performance, solder the exposed
ground pad of the LT3579 to the ground plane with
multiple vias around the pad connecting to additional
ground planes.
• A ground plane should be used under the switcher circuitry
to prevent interplane coupling and overall noise.
• High speed switching path (see specific topology below for
more information) must be kept as short as possible.
• The VC , FB, and RT components should be placed as
close to the LT3579 as possible, while being as far
away as practically possible from the switch node. The
ground for these components should be separated from
the switch current path.
• Place the bypass capacitor for the VIN pin (CVIN) as
close as possible to the LT3579.
• Place the bypass capacitor for the inductor (CPWR) as
close as possible to the inductor.
• Bypass capacitors, CPWR and CVIN, may be combined
into a single bypass capacitor, CIN, if the input side of the
inductor can be close to the VIN pin of the LT3579.
• The load should connect directly to the positive and
negative terminals of the output capacitor for best load
regulation.
Boost Topology Specific Layout Guidelines
• Keep length of loop (high speed switching path)
governing switch, diode D1, output capacitor COUT, and
ground return as short as possible to minimize parasitic
inductive spikes at the switch node during switching.
SEPIC Topology Specific Layout Guidelines
• Keep length of loop (high speed switching path) governing
switch, flying capacitor C1, diode D1, output capacitor COUT,
and ground return as short as possible to minimize parasitic
inductive spikes at the switch node during switching.
VIAS TO GROUND PLANE REQUIRED TO IMPROVE
THERMAL PERFORMANCE
GND
1
CIN
–
A
21
20
SYNC
2
19
3
18
4
17
SHDN
5
16
CLKOUT
6
15
7
14
8
13
9
12
10
11
B
–
VIN
+
COUT1
COUT
VOUT
D1
L1
M1
+
D2
RGATE
3579 F08
A– RETURN CIN GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE CIN GROUND
WITH GND EXCEPT AT THE EXPOSED PAD.
B– RETURN COUT AND COUT1 GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE
COUT AND COUT1 GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
Figure 9. Suggested Component Placement for Boost Topology in FE20 Package
35791f
16
LT3579/LT3579-1
APPLICATIONS INFORMATION
the heat generated within the package. This can be
accomplished by taking advantage of the thermal pad on
the underside of the IC. It is recommended that multiple
vias in the printed circuit board be used to conduct heat
away from the IC and into a copper plane with as much
area as possible.
Inverting Topology Specific Layout Guidelines
• Keep ground return path from the cathode of D1 (to
chip) separated from output capacitor COUT’s ground
return path (to chip) in order to minimize switching
noise coupling into the output. Notice the separate
ground return for D1’s cathode in Figure 11.
• Keep length of loop (high speed switching path)
governing switch, flying capacitor C1, diode D1, and
ground return as short as possible to minimize parasitic
inductive spikes at the switch node during switching.
Power & Thermal Calculations
Power dissipation in the LT3579 chip comes from four
primary sources: switch I2R loss, NPN base drive loss
(AC), NPN base drive loss (DC), and additional VIN pin
current. These formulas assume continuous mode
operation, so they should not be used for calculating
thermal losses or efficiency in discontinuous mode or at
light load currents.
THERMAL CONSIDERATIONS
For the LT3579 to deliver its full output power, it is imperative that a good thermal path be provided to dissipate
VIAS TO GROUND PLANE REQUIRED TO IMPROVE
THERMAL PERFORMANCE
GND
21
1
CIN
–
A
VIN
20
SYNC
2
19
3
18
4
17
SHDN
5
16
CLKOUT
6
15
7
14
8
13
9
12
10
11
B
–
COUT
+
VOUT
C1
D1
L1
L2
+
3579 F10
A– RETURN CIN AND L2 GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE CIN AND L2 GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
B– RETURN COUT GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE COUT GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
L1, L2 –MOST COUPLED INDUCTOR MANUFACTURERS USE CROSS PINOUT FOR IMPROVED PERFORMANCE.
Figure 10. Suggested Component Placement for SEPIC Topology in FE20 Package
35791f
17
LT3579/LT3579-1
APPLICATIONS INFORMATION
VIAS TO GROUND PLANE REQUIRED TO IMPROVE
THERMAL PERFORMANCE
GND
21
1
CIN
–
A
VIN
+
20
SYNC
2
19
3
18
4
17
SHDN
5
16
CLKOUT
6
15
7
14
8
13
9
12
10
11
B
GND
C
COUT
C1
D1
–VOUT
L1
L2
3579 F11
A– RETURN CIN GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE CIN GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
B– RETURN COUT GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE COUT GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
C– RETURN D1 GROUND DIRECTLY TO LT3579 EXPOSED PAD PIN 21. IT IS ADVISED TO NOT COMBINE D1 GROUND WITH GND EXCEPT AT THE EXPOSED PAD.
L1, L2 – MOST COUPLED INDUCTOR MANUFACTURERS USE CROSS PINOUT FOR IMPROVED PERFORMANCE.
Figure 11. Suggested Component Placement for Inverting Topology in FE20 Package.
Note Separate Ground Path for D1’s Cathode
35791f
18
LT3579/LT3579-1
APPLICATIONS INFORMATION
The following example calculates the power dissipation
in the LT3579 for a particular boost application:
(VIN = 5V, VOUT = 12V, IOUT = 1.5A, fOSC = 1MHz,
VD = 0.5V, VCESAT = 0.185V).
where T J =Die Junction Temperature, TA =Ambient
Temperature, PTOTAL is the final result from the calculations
shown in Table 4, and θJA is the thermal resistance from
the silicon junction to the ambient air.
To calculate die junction temperature, use the appropriate
thermal resistance number and add in worst-case ambient
temperature:
TJ = TA + θJA • PTOTAL
Table 4. Boost Power Calculations Example with VIN = 5V, VOUT = 12V, IOUT = 1.5A, fOSC = 1MHz, VD = 0.5V, VCESAT = 0.185V
DEFINITION OF VARIABLES
EQUATIONS
DC = Switch Duty Cycle
DC =
VOUT – VIN + VD
VOUT + VD – VCESAT
IIN = Average Input Current
η = Power Conversion Efficiency
(typically 90% at high currents)
PSW = Switch I2R Loss
RSW = Switch Resistance (typically
45mΩ combined SW1 and SW2)
PBAC = Base Drive Loss (AC)
IIN =
VIN • η
DC =
VALUE
12V – 5V + 0.5V
12V + 0.5V – .185V
DC = 60.9%
12V • 1.5A
5V • 0.9
IIN = 4A
IIN =
PSW = DC • IIN2 • RSW
PSW = 0.609 • (4A)2 • 45mΩ
PSW = 438mW
PBAC = 13ns • IIN • VOUT • fOSC
PBAC = 13ns • 4A • 12V • 1MHz
PBAC = 624mW
PBDC = Base Drive Loss (DC)
PBDC =
PINP = Input Power Loss
VOUT • IOUT
DESIGN EXAMPLE
VIN • IIN • DC
40
PINP = 14mA • VIN
PBDC =
5V • 4A • 0.609
40
PINP = 14mA • 5V
PBDC = 305mW
PINP = 70mW
PTOTAL = 1.437W
35791f
19
LT3579/LT3579-1
APPLICATIONS INFORMATION
The published (http://www.linear.com/designtools/
packaging/Linear_Technology_Thermal_Resistance_
Table.pdf) θJA value is 38°C/W for the TSSOP Exposed Pad
package and 34°C/W for the 4mm × 5mm QFN package. In
practice, lower θJA values are realizable if board layout is
performed with appropriate grounding (accounting for heat
sinking properties of the board) and other considerations
listed in the Layout Guidelines section. For instance, a θJA
value of ~22°C/W was consistently achieved for both TSSOP
and QFN packages of the LT3579 (at VIN = 5V, VOUT = 12V,
IOUT = 1.7A, fOSC = 1MHz) when board layout was optimized
as per the suggestions in the Layout Guidelines section.
Junction Temperature Measurement
The duty cycle of the CLKOUT signal on the LT3579 is linearly
proportional to die junction temperature, TJ (the CLKOUT
duty cycle on the LT3579-1 is fixed at ~50%). To get an
accurate reading, measure the duty cycle of the CLKOUT
signal and use the following equation to approximate the
junction temperature:
TJ =
DCCLKOUT – 35%
0.3%
where DCCLKOUT is the CLKOUT duty cycle in % and TJ is
the die junction temperature in °C. Although the absolute
die temperature can deviate from the above equation by
±15°C, the relationship between change in CLKOUT duty
cycle and change in die temperature is well defined. A
3% increase in CLKOUT duty cycle corresponds to ~10°C
increase in die temperature:
Note that the CLKOUT pin is only meant to drive capacitive
loads up to 50pF.
Thermal Lockout
SWITCHING FREQUENCY
There are several considerations in selecting the operating
frequency of the converter. The first is staying clear of
sensitive frequency bands, which cannot tolerate any
spectral noise. For example, in products incorporating RF
communications, the 455kHz IF frequency is sensitive to
any noise, therefore switching above 600kHz is desired.
Some communications have sensitivity to 1.1MHz and in
that case a 1.5MHz switching converter frequency may be
employed. The second consideration is the physical size
of the converter. As the operating frequency goes up, the
inductor and filter capacitors go down in value and size.
The tradeoff is efficiency, since the switching losses due to
NPN base charge (see Thermal Considerations), Schottky
diode charge, and other capacitive loss terms increase
proportionally with frequency.
Oscillator Timing Resistor (RT)
The operating frequency of the LT3579 can be set by the
internal free-running oscillator. When the SYNC pin is driven
low (< 0.4V), the frequency of operation is set by a resistor
from the RT pin to ground. An internally trimmed timing
capacitor resides inside the IC. The oscillator frequency
is calculated using the following formula:
fOSC =
87.6
RT + 1
where fOSC is in MHz and RT is in kΩ. Conversely, RT (in
kΩ) can be calculated from the desired frequency (in
MHz) using:
RT =
87.6
–1
fOSC
A fault condition occurs when the die temperature exceeds
~165°C (see Operation – FAULT Section), and the part goes
into thermal lockout. The fault condition ceases when the
die temperature drops by ~5°C (nominal).
35791f
20
LT3579/LT3579-1
APPLICATIONS INFORMATION
Clock Synchronization
An external source can set the operating frequency of the
LT3579 by providing a digital clock signal into the SYNC
pin (RT resistor still required). The LT3579 will operate at
the SYNC clock frequency. The LT3579 will revert to its
internal free-running oscillator clock when the SYNC pin is
driven below 0.4V for a few free-running clock periods.
Driving SYNC high for an extended period of time
effectively stops the operating clock and prevents latch
SR1 from becoming set (see Block Diagram). As a result,
the switching operation of the LT3579 will stop and the
CLKOUT pin will be held at ground.
10μF
VIN
200k
10μF
s2
CLKOUT
FB
LT3579
SLAVE
4.7μF
FAULT
SHDN
RT
SYNC
VC
68pF
SS
GND
86.6k
8k
0.1μF
3.3nF
VOUT
12V
1.7A
2.2μH
VIN
5V
10μF
The duty cycle of the SYNC signal must be between 20%
and 80% for proper operation. Also, the frequency of the
SYNC signal must meet the following two criteria:
SYNC may not toggle outside the frequency
range of 200kHz-2.5MHz unless it is stopped
below 0.4V to enable the free-running oscillator.
SW1 SW2
GATE
SW1 SW2
10k
1.
VOUT
18V
1A
3.3μH
100k
110k
4.7μF
130k
GATE
CLKOUT
LT3579
VIN
FB
MASTER
VC
FAULT
10μF
s3
47pF
SS
SHDN
RT
SYNC GND
8k
0.1μF
2.2nF
86.6k
3579 F12
2.
The SYNC frequency can always be higher than
the free-running oscillator frequency (as set by the
RT resistor), fOSC , but should not be less than 25%
below fOSC.
CLOCK SYNCHRONIZATION OF ADDITIONAL
REGULATORS
The CLKOUT pin of the LT3579 can synchronize additional
switching regulators and/or additional LT3579s as shown
in Figure 12.
The frequency of the master LT3579 is set by the external
RT resistor. The SYNC pin of the slave LT3579 is driven
by the CLKOUT pin of the master LT3579. Note that the
RT pin of the slave LT3579 must have a resistor tied to
ground. It takes a few clock cycles for the CLKOUT signal
to begin oscillating, and it’s preferable for all LT3579s to
have the same internal free-running frequency. Therefore,
in general, use the same value RT resistor for all of the
synchronized LT3579s.
Figure 12. Synchronize Multiple LT3579s. The External PMOS
Disconnects the Input from Both Power Paths During FAULT Events
Also, the FAULT pins can be tied together so that a fault
condition from one LT3579 causes all of the LT3579s to
enter fault, until the fault condition disappears.
2-Phase Converters using LT3579-1
The CLKOUT pin on the LT3579-1 is ~180° out of phase
with the internal oscillator, which allows two LT3579-1s to
operate in parallel for a high current, high power output.
The advantage of multiphase converters is that the ripple
current flowing into the output node is divided by the
number of phases or ICs used to generate the output
voltage. The VIN, SHDN, FAULT, FB, and VC pins of all the
LT3579-1s should be connected together. Figure 13 shows
a typical application of a 2-phase 12V to 24V boost with
output disconnect.
35791f
21
LT3579/LT3579-1
APPLICATIONS INFORMATION
Use the following equations to calculate the FB resistor
for 2-phase converters:
4.7μH
⎛V
– 1.215V ⎞
RFB = ⎜ OUT
⎟ ; Boost or SEPIC
⎝ 2 • 83.3μA ⎠ Multiphase Converter
4.7μF
⎛ | V | + 9mV ⎞
RFB = ⎜ OUT
⎟ ; Inverting Multiphase
⎝ 2 • 83.3μA ⎠ Converter
Note that the CLKOUT pin on the LT3579-1 runs at a fixed
duty cycle of ~50%. If monitoring the die temperature is
desired, the slave IC can be a LT3579.
It is possible to use the LT3579-1 in a multiphase converter
of more than 2 phases. Consult the LTC Applications
Engineering Department for more information.
• The master switch, immune from the capacitor current
spike, can sense the inductor current more accurately.
• Since the slave switch can sustain large current spikes,
the diodes that feed current into the flying capacitors
do not need current limiting resistors, leading to
efficiency and thermal improvements.
SS
0.22μF
86.6k
VOUT
24V
3.7A,
89W
VOUT1
VPWR
12V
VIN
5V
4.7μH
10μF
VOUT1
6.4k
4.7μF
s2
4.7μF
s2
100k
21.5k
CHARGE PUMP AIDED REGULATORS
• The slave switch, by not performing a current sense
operation like the master switch, can sustain fairly
large current spikes when the flying capacitors charge
up. Since this current spike flows through SW2, it
does not affect the operation of the current comparator
(A4 in Block Diagram).
SW1 SW2
VIN
CLKOUT
FB
FAULT
LT3579-1
SLAVE
GATE
SHDN
VC
RT
SYNC GND
500k
Designing charge pumps with the LT3579 can offer efficient
solutions with fewer components than traditional circuits
because of the master/slave switch configuration on the
IC. The current in the master switch (SW1) is sensed by
the current comparator (A4 in Block Diagram), but the
current in the slave switch (SW2) is not. Note that the slave
switch, SW2, operates in phase with SW1. This method
of operation by the master/slave switches can offer the
following benefits to charge pump designs:
4.7μF
s2
10μF
4.7μF
VIN
SW1 SW2
CLKOUT
FB
FAULT
LT3579-1
MASTER
GATE
SHDN
VC
RT
SYNC GND
5k
137k
86.6k
VPWR
47pF
SS
0.22μF
7k
2.2nF
3579 F13
Figure 13. 2-Phase Converters Using LT3579-1
High VOUT Charge Pump Topology
The LT3579 can be used in a charge-pump topology (refer
to Figure 16), multiplying the output of an inductive boost
converter. The master switch (SW1) can be used to drive
the inductive boost converter, while the slave switch (SW2)
can be used to drive one or more charge pump stages. This
topology is useful for high voltage applications including
VFD Bias Supplies.
Single Inductor Inverting Topology
If there is a need to use just 1 inductor to generate a
negative output voltage whose magnitude is greater than
VIN , the Single Inductor Inverting topology (shown in
Figure 15) can be used. Since the master and slave switches
are isolated by an external Schottky diode, the current spike
through C1 will flow through the slave switch, thereby
preventing the current comparator (A4 in Block Diagram)
from falsely tripping. Output disconnect is inherently built
into the single inductor topology.
35791f
22
LT3579/LT3579-1
APPLICATIONS INFORMATION
HOT PLUG
The high inrush current associated with hot-plugging VIN
can be largely rejected with the use of an external PMOS. A
simple hot-plug controller can be designed by connecting
an external PMOS in series with VIN, with the gate of the
PMOS being driven by the GATE pin of the LT3579. Since
the GATE pin pull-down current is linearly proportional to
the SS voltage, and the SS charge up time is relatively slow,
the GATE pin pull-down current will increase gradually,
thereby turning on the external PMOS slowly. Controlled
in this manner, the PMOS acts as an input current limiter
when VIN hot-plugs or ramps up sharply.
Likewise, when the PMOS is connected in series with the
output, inrush currents into the output capacitor can be
limited during a hot-plug event. To illustrate this, the circuit
in Figure 6 was re-configured by adding a large 1500μF
capacitor to the output. An 18Ω resistive load was used
and a 2.2μF capacitor was placed on SS. Figure 14 shows
the result of hot-plugging this re-configured circuit. The
inductor current is well behaved and VOUT comes up once
VIN settles out.
C1
D1
L1
D3
VIN
–VOUT
D2
SW1
RFB
SW2
VIN
FB
SHDN
COUT
GATE
LT3579
100k
FAULT
CIN
CLKOUT
VC
RT
SYNC GND
SS
RT
CF
RC
CC
CSS
3579 F15
Figure 15. Single Inductor Inverting Topology
4.7μF
VOUT2
100V
200mA
4.7μF
VOUT1
67V
100mA
4.7μF
4.7μF
10μH
VIN
12V
6.8μF
VIN
5V/DIV
383k
SW1 SW2
100k
VOUT
10V/DIV
VIN
6.5k
6.8μF
FB
FAULT
GATE
VIN
LT3579
536k
IL
5A/DIV
SHDN
RT
10μF
SYNC
SS
1V/DIV
86.6k
1s/DIV
3579 F14
Figure 14. VIN Hot-Plug Control. Inrush Current is Well Controlled
CLKOUT
VC
GND
SS
27pF
2.2μF
34k
470pF
3579 F16
Figure 16. High VOUT Charge Pump Topology
35791f
23
LT3579/LT3579-1
APPENDIX
SETTING THE OUTPUT VOLTAGE
The output voltage is set by connecting a resistor (RFB)
from VOUT to the FB pin. RFB is determined from the
following equation:
|V
– VFB |
RFB = OUT
83.3μA
where VFB is 1.215V (typical) for non-inverting topologies
(i.e. boost and SEPIC regulators) and 9mV (typical) for
inverting topologies (see Electrical Characteristics).
POWER SWITCH DUTY CYCLE
In order to maintain loop stability and deliver adequate
current to the load, the power NPNs (Q1 and Q2 in the
Block Diagram) cannot remain “on” for 100% of each clock
cycle. The maximum allowable duty cycle is given by:
DCMAX =
(TP – MinOffTime) • 100%
TP
where TP is the clock period and MinOffTime (found in the
Electrical Characteristics) is typically 45nS.
Conversely, the power NPNs (Q1 and Q2 in the Block
Diagram) cannot remain “off” for 100% of each clock
cycle, and will turn on for a minimum time (MinOnTime)
when in regulation. This MinOnTime governs the minimum
allowable duty cycle given by:
DCMIN =
(MinOnTime) •100%
TP
where TP is the clock period and MinOnTime (found in the
Electrical Characteristics) is typically 55nS.
The application should be designed such that the operating
duty cycle is between DCMIN and DCMAX.
Duty cycle equations for several common topologies are
given below where VD is the diode forward voltage drop
and VCESAT is typically 250mV at 5.5A for a combined
SW1 and SW2 current.
For the boost topology (see Figure 6):
DCBOOST ≅
VOUT – VIN + VD
VOUT + VD – VCESAT
For the SEPIC or Dual Inductor Inverting topology (see
Figures 7 and 8):
DCSEPIC _&_ INVERT ≅
VD + | VOUT |
VIN + | VD | + VOUT − VCESAT
For the Single Inductor Inverting topology (see Figure 14):
DCSI _ INVERT ≅
| VOUT | −VIN + VCESAT + 3 • VD
| VOUT | + 3 • VD
The LT3579 can be used in configurations where the duty
cycle is higher than DCMAX , but it must be operated in
the discontinuous conduction mode so that the effective
duty cycle is reduced.
INDUCTOR SELECTION
The high frequency operation of the LT3579 allows for
the use of small surface mount inductors. For high
efficiency, choose inductors with high frequency core
material, such as ferrite, to reduce core losses. Also to
improve efficiency, choose inductors with more volume
for a given inductance. The inductor should have low
DCR (copper-wire resistance) to reduce I2R losses, and
must be able to handle the peak inductor current without
saturating. Note that in some applications, the current
handling requirements of the inductor can be lower, such
as in the SEPIC topology where each inductor only carries
one half of the total switch current. Multilayer chokes or
chip inductors usually do not have enough core volume to
support peak inductor currents in the 4A to 7A range. To
minimize radiated noise, use a toroidal or shielded inductor.
See Table 5 for a list of inductor manufacturers.
35791f
24
LT3579/LT3579-1
APPENDIX
where:
Table 5. Inductor Manufacturers
Vishay
IHLP-2020BZ-01 and
IHLP-2525CZ-01 Series
www.vishay.com
Coilcraft
XLP, MLC and MSS Series
www.coilcraft.com
Cooper Bussmann DRQ125 and DRQ127
Series
www.cooperbussmann.
com
Sumida
CDRH series
www.sumida.com
TDK
RLF and SLF series
www.tdk.com
Würth
WE-PD, WE-PDF, WE-HC
and WE-DD Series
www.we-online.com
Minimum Inductance
Although there can be a tradeoff with efficiency, it is often
desirable to minimize board space by choosing smaller
inductors. When choosing an inductor, there are three
conditions that limit the minimum inductance; (1) providing
adequate load current, (2) avoidance of subharmonic
oscillation, and (3) supplying a minimum ripple current
to avoid false tripping of the current comparator.
Adequate Load Current
Small value inductors result in increased ripple currents and
thus, due to the limited peak switch current, decrease the
average current that can be provided to the load. In order
to provide adequate load current, L should be at least:
LBOOST >
(
DC • VIN − VCESAT
⎛
2 • fOSC • ⎜ IPK
⎝
)
Boost
VOUT • IOUT ⎞ Topology
−
⎟
VIN • η ⎠
or
LDUAL >
(
DC • VIN − VCESAT
)
⎛
|V |••I
2 • fOSC • ⎜ IPK − OUT OUT
VIN • η
⎝
SEPIC
or
⎞ Inverting
− IOUT ⎟ Topologies
⎠
LBOOST = L1 for Boost Topologies (see Figure 6)
LDUAL = L1 = L2 for Coupled Dual Inductor
Topologies (see Figures 7 and 8)
LDUAL = L1 || L2 for Uncoupled Dual Inductor
Topologies (see Figures 7 and 8)
DC
= Switch Duty Cycle (see Power Switch Duty
Cycle section in Appendix)
= Maximum Peak Switch Current; Should
IPK
Not Exceed 6A for a Combined SW1 +
SW2 Current or 3.4A of SW1 Current (see
Electrical Characteristics section.)
η
= Power Conversion Efficiency (typically 90%
for Boost and 85% for Dual Inductor
Topologies at high currents)
fOSC = Switching Frequency
IOUT = Maximum Output Current
Negative values of LBOOST or LDUAL indicate that the
output load current, IOUT, exceeds the switch current limit
capability of the LT3579.
Avoiding Sub-Harmonic Oscillations
The LT3579’s internal slope compensation circuit will
prevent sub-harmonic oscillations that can occur when
the duty cycle is greater than 50%, provided that the
inductance exceeds a minimum value. In applications that
operate with duty cycles greater than 50%, the inductance
must be at least:
LMIN =
( VIN − VCESAT ) • (2 • DC − 1)
4A • fOSC • (1− DC)
where:
LMIN
LMIN
LMIN
= L1 for Boost Topologies (see Figure 6)
= L1 = L2 for Coupled Dual Inductor
Topologies (see Figures 7 and 8)
= L1 || L2 for Uncoupled Dual Inductor
Topologies (see Figures 7 and 8)
35791f
25
LT3579/LT3579-1
APPENDIX
Maximum Inductance
DIODE SELECTION
Excessive inductance can reduce ripple current to levels
that are difficult for the current comparator (A4 in the Block
Diagram) to cleanly discriminate, thus causing duty cycle
jitter and/or poor regulation. The maximum inductance
can be calculated by:
Schottky diodes, with their low forward voltage drops and
fast switching speeds, are recommended for use with the
LT3579. Choose a Schottky with low parasitic capacitance
to reduce reverse current spikes through the power switch
of the LT3579. The Diodes Inc. MBRM360 is a very good
choice with a 60V reverse voltage rating and an average
forward current of 3A.
LMAX =
( VIN − VCESAT ) • DC
fOSC • 0.5A
where:
LMAX
LMAX
LMAX
OUTPUT CAPACITOR SELECTION
= L1 for Boost Topologies (see Figure 6)
= L1 = L2 for Coupled Dual Inductor
Topologies (see Figures 7 and 8)
= L1 || L2 for Uncoupled Dual Inductor
Topologies (see Figures 7 and 8)
Inductor Current Rating
The inductor(s) must have a rating greater than its (their)
peak operating current to prevent inductor saturation, which
would result in catastrophic failure and efficiency losses.
The maximum inductor current (considering start-up and
steady-state conditions) is given by:
V •T
IL _ PEAK = ILIM + IN MIN _ PROP
L
where:
= Peak Inductor Current in L1 for a Boost
Topology, or the sum of the Peak
Inductor Currents in L1 and L2 for Dual
Inductor Topologies.
= For Hard-Saturation Inductors, 9.4A with
ILIM
SW1 and SW2 Tied Together, or 5.1A
with just SW1 used. For Soft-Saturation
Inductors, 6A with SW1 and SW2 Tied
Together, or 3.4A with just SW1 used.
TMIN_PROP = 100ns (Propagation Delay through the
Current Feedback Loop).
Low ESR (equivalent series resistance) capacitors should
be used 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. X5R or X7R type are preferred, as these
materials retain their capacitance over wide voltage and
temperature ranges. A 22μF to 47μF output capacitor is
sufficient for most applications, but systems with low
output currents may need only 4.7μF to 22μF. Always
use a capacitor with a sufficient voltage rating. Many
ceramic capacitors, particularly 0805 or 0603 case sizes,
have greatly reduced capacitance at the desired output
voltage. Tantalum polymer or OS-CON capacitors can be
used, but it is likely that these capacitors will occupy more
board area than a ceramic, and will have higher ESR with
greater output ripple.
IL_PEAK
Note that these equations offer conservative results for
the required inductor current ratings. The current ratings
could be lower for applications with light loads, provided
the SS capacitor is sized appropriately to limit inductor
currents at start-up.
INPUT CAPACITOR SELECTION
Ceramic capacitors make a good choice for the input
decoupling capacitor, CVIN, which should be placed as
close as possible to the VIN pin of the LT3579. This ensures
that the voltage seen at the VIN pin of the LT3579 remains
a nearly flat DC voltage. A 1μF to 4.7μF input capacitor is
sufficient for most applications.
A ceramic bypass capacitor, CPWR, should also be placed
as close as possible to the input of the inductor. This
ensures that the inductor ripple current is supplied from
the bypass capacitor and provides a nearly flat DC voltage
to the input of the voltage converter. A 4.7μF to 10μF input
power capacitor is sufficient for most applications.
35791f
26
LT3579/LT3579-1
APPENDIX
Table 6 shows a list of several ceramic capacitor manufacturers. Consult the manufacturers for detailed information on their entire selection of ceramic parts.
Table 6. Ceramic Capacitor Manufacturers
TDK
www.tdk.com
Murata
www.murata.com
Taiyo Yuden
www.t-yuden.com
PMOS SELECTION
An external PMOS, controlled by the LT3579’s GATE pin,
can be used to facilitate input or output disconnect. The
GATE pin turns on the PMOS gradually during start-up
(see Soft-Start of External PMOS in the Operation section),
and turns the PMOS off when the LT3579 is in shutdown
or in fault.
The use of the external PMOS, controlled by the GATE pin,
is particularly beneficial when dealing with unintended
output shorts in a boost regulator. In a conventional boost
regulator, the inductor, Schottky diode, and power switches
are susceptible to damage in the event of an output short
to ground. Using an external PMOS in the boost regulator’s
power path (path from VIN to VOUT) controlled by the GATE
pin, will serve to disconnect the input from the output
when the output has a short to ground, thereby helping
save the IC, and the other components in the power path
from damage.
The PMOS chosen must be capable of handling the
maximum input or output current depending on whether
the PMOS is used at the input (see Figure 12) or the output
(see Figure 13).
Ensure that the PMOS is biased with enough source to gate
voltage (VSG) to enhance the device into the triode mode
of operation. The higher the VSG voltage that biases the
PMOS, the lower the RDSON of the PMOS, thereby lowering
power dissipation in the device during normal operation,
as well as improving the efficiency of the application in
which the PMOS is used. The following equations show
the relationship between RGATE (see Block Diagram) and
the desired VSG that the PMOS is biased with:
⎧
RGATE
< 2V
if V
⎪ VS
VSG = ⎨ RGATE + 2kΩ GATE
⎪
⎩ 933μA • RGATE if VGATE > 2V
When using a PMOS, it is advisable to configure the specific
application for undervoltage lockout (see the Operations
section). The goal is to have VIN get to a certain minimum
voltage where the PMOS has sufficient headroom to attain
a high enough VSG, which prevents it from entering the
saturation mode of operation during start-up.
Figure 6 shows the PMOS connected in series with the
output to act as an output disconnect during a fault
condition. The Schottky diode from the VIN pin to the GATE
pin is optional and helps turn off the PMOS quicker in the
event of hard shorts. The resistor from VIN to the SHDN
pin sets a UVLO of 4V for this application.
Connecting the PMOS in series with the output offers certain
advantages over connecting it in series with the input:
• Since the load current is always less than the input
current for a boost converter, the current rating of the
PMOS goes down when connected in series with the
output as opposed to the input.
• A PMOS in series with the output can be biased with
a higher overdrive voltage than a PMOS used in series
with the input, since VOUT > VIN. This higher overdrive
results in a lower RDSON for the PMOS, thereby improving
the efficiency of the regulator.
In contrast, an input connected PMOS works as a simple
hot-plug controller (covered in more detail in the Hot-Plug
section). The input connected PMOS also functions as an
inexpensive means of protecting against multiple output
shorts in boost applications that synchronize the LT3579
with other compatible ICs (see Figure 12).
35791f
27
LT3579/LT3579-1
APPENDIX
Table 7 shows a list of several discrete PMOS manufacturers. Consult the manufacturers for detailed information
on their entire selection of PMOS devices.
Table 7. Discrete PMOS Manufacturers
Vishay
www.vishay.com
Fairchild Semiconductor
www.fairchildsemi.com
Central Semiconductor
www.centralsemi.com
VOUT
500mV/DIV
AC COUPLED
IL
2A/DIV
ILOAD
1A/DIV
RC = 1k
COMPENSATION – ADJUSTMENT
To compensate the feedback loop of the LT3579, a series
resistor-capacitor network in parallel with an optional single
capacitor must be connected from the VC pin to GND. For
most applications, choose a series capacitor in the range
of 1nF to 10nF with 2.2nF being a good starting value.
The optional parallel capacitor should range in value from
22pF to 180pF with 47pF being a good starting value. The
compensation resistor, RC , is usually in the range of 5k to
50k. A good technique to compensate a new application is
to use a 100kΩ potentiometer in place of the series resistor
RC. With the series and parallel capacitors at 2.2nF and
47pF respectively, adjust the potentiometer while observing
the transient response and the optimum value for RC can
be found. Figures 17a to 17c illustrate this process for the
circuit of Figure 20 with a load current stepped between
0.7A and 1.5A. Figure 17a shows the transient response
with RC equal to 1k. The phase margin is poor as evidenced
by the excessive ringing in the output voltage and inductor
current. In Figure 17b, the value of RC is increased to 3.5k,
which results in a more damped response. Figure 17c
shows the results when RC is increased further to 8k. The
transient response is nicely damped and the compensation
procedure is complete.
100μs/DIV
3579 F17a
Figure 17a. Transient Response Shows Excessive Ringing
VOUT
500mV/DIV
AC COUPLED
IL
2A/DIV
ILOAD
1A/DIV
RC = 3.5k
100μs/DIV
3579 F17b
Figure 17b. Transient Response Is Better
VOUT
500mV/DIV
AC COUPLED
IL
2A/DIV
ILOAD
1A/DIV
RC = 8k
100μs/DIV
3579 F17c
Figure 17c. Transient Response Is Well Damped
COMPENSATION – THEORY
Like all other current mode switching regulators, the
LT3579 needs to be compensated for stable and efficient
operation. Two feedback loops are used in the LT3579: a
fast current loop which does not require compensation,
and a slower voltage loop which does. Standard Bode plot
analysis can be used to understand and adjust the voltage
35791f
28
LT3579/LT3579-1
APPENDIX
feedback loop.
As with any feedback loop, identifying the gain and phase
contribution of the various elements in the loop is critical.
Figure 18 shows the key equivalent elements of a boost
converter. Because of the fast current control loop, the
power stage of the IC, inductor and diode have been replaced
by a combination of the equivalent transconductance
amplifier gmp and the current controlled current source
(which converts IVIN to ηVIN I ). Gmp acts as a current
VOUT
gmp
IVIN
Output Pole : P1 =
VOUT
H• VIN
VOUT
• IVIN
RESR
1.215V
REFERENCE
CPL
RC
RO
CC
Error Amp Pole : P2 =
1
2• π • (RO + RC ) •CC
Error Amp Zero : Z1 =
1
2• π •RC •CC
R1
ESR Zero : Z2 =
+
gma
R2
FB
–
2
2• π •RL •COUT
RL
COUT
CF
From Figure 18, the DC gain, poles and zeros can be
calculated as follows:
DC Gain:
V
R
0.5R2
ADC = gma •RO • gmp • η• IN • L •
VOUT 2 R1 + 0.5R2
VIN
–
+
are finite. The output of the gmp stage is limited by the
minimum switch current limit (see Electrical Specifications)
and gma is nominally limited to about ±12μA.
RHP Zero : Z3 =
R2
3579 F18
CC: COMPENSATION CAPACITOR
COUT: OUTPUT CAPACITOR
CPL: PHASE LEAD CAPACITOR
CF: HIGH FREQUENCY FILTER CAPACITOR
gma: TRANSCONDUCTOR AMPLIFIER INSIDE IC
gmp: POWER STAGE TRANSCONDUCTANCE AMPLIFIER
RC: COMPENSATION RESISTOR
RL: OUTPUT RESISTANCE DEFINED AS VOUT/ILOADMAX
RO: OUTPUT RESISTANCE OF gma
R1, R2; FEEDBACK RESISTOR DIVIDER NETWORK
RESR: OUTPUT CAPACITOR ESR
H: CONVERTER EFFICIENCY (~90% AT HIGHER CURRENTS)
Figure 18. Boost Converter Equivalent Model
source where the peak input current, IVIN, is proportional
to the VC voltage.
Note that the maximum output currents of gmp and gma
1
2• π •RESR •COUT
VIN2 •RL
2• π • VOUT2 •L
High Frequency Pole : P3 >
Phase Lead Zero : Z 4 =
Phase Lead Pole : P4 =
fS
3
1
2• π •R1•CPL
1
R • 0.5R2
2• π • 1
•C
R1 + 0.5R2 PL
Error Amp Filter Pole :
1
P5 =
2• π •
RC •RO
C
RC + RO F
, CF <
CC
10
35791f
29
LT3579/LT3579-1
APPENDIX
140
0
–45
120
PHASE
80
–135
GAIN (dB)
–90
60
–180
40
Using the circuit in Figure 20 as an example, Table 8 shows
the parameters used to generate the Bode plot shown in
Figure 19.
46° AT
8kHz
GAIN
–225
20
–270
0
–315
–360
1M
–20
10
1k
100
Table 8. Bode Plot Parameters
PARAMETER
VALUE
UNITS
COMMENT
RL
7
Ω
Application Specific
COUT
30
μF
Application Specific
RESR
2
mΩ
Application Specific
R0
305
kΩ
Not Adjustable
CC
2200
pF
Adjustable
CF
47
pF
Optional/Adjustable
CPL
0
pF
8
kΩ
Adjustable
R1
130
kΩ
Adjustable
R2
14.6
kΩ
Not Adjustable
VOUT
12
V
Application Specific
VIN
5
V
Application Specific
gma
250
μmho
Not Adjustable
gmp
28
mho
Not Adjustable
L
2.2
μH
Application Specific
fOSC
1.0
MHz
Adjustable
10k
100k
FREQUENCY (Hz)
3060 TA02
Figure 19. Bode Plot for Example Boost Converter
L1
2.2μH
VIN
5V
D1
100k
CIN
22μF
FAULT
SHDN
FB
LT3579
COUT
10μF
s3
GATE
CLKOUT
RT
SYNC GND
86.6k
VOUT
12V
1.7A
130k
SW1 SW2
VIN
Optional/Adjustable
RC
PHASE (DEG)
The current mode zero (Z3) is a right half plane zero
which can be an issue in feedback control design, but is
manageable with proper external component selection.
100
VC
SS
47pF
8k
0.1μF
2.2nF
3579 F20
Figure 20. 5V to 12V Boost Converter
From Figure 19, the phase is –134° when the gain reaches
0dB giving a phase margin of 46°. The crossover frequency
35791f
30
LT3579/LT3579-1
TYPICAL APPLICATION
1MHz, 5V to 12V Boost Converter can Survive Output Shorts
L1
2.2μH
VIN
5V
D1
VOUT
12V
1.7A
M1
COUT1
10μF
130k
SW1 SW2
100k
200k
CIN
22μF
COUT
10μF
6.3k
FB
VIN
FAULT
D2
VIN
GATE
LT3579
SHDN
RT
SYNC
CLKOUT
VC
GND
86.6k
SS
47pF
8k
0.1μF
2.2nF
3579 TA03a
CIN: 22μF, 16V, X7R, 1210
COUT1, COUT: 10μF, 25V, X7R, 1210
D1: VISHAY SSB43L
D2: CENTRAL SEMI CMDSH-3TR
L1: WÜRTH WE-PD 744771002
M1: SILICONIX SI7123DN
100
3.2
90
2.8
80
2.4
70
2
60
1.6
50
1.2
40
0.8
30
0.4
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss
0
20
0
0.25 0.5 0.75 1 1.25 1.5 1.75
LOAD CURRENT (A)
2
3579 TA03
Output Short
Transient Response with 0.7A to 1.5A to 0.7A Output Load Step
VOUT
10V/DIV
VOUT
500mV/DIV
AC COUPLED
CLKOUT
2V/DIV
IL
2A/DIV
IL
2A/DIV
FAULT
5V/DIV
ILOAD
1A/DIV
10μs/DIV
3579 TA05
100μs/DIV
3579 TA06
35791f
31
LT3579/LT3579-1
TYPICAL APPLICATION
500kHz SEPIC Converter Generates 3.3V from a 3V to 33V Input
D3
VBAT
3V TO 33V (OPERATING)
6V TO 16V (START-UP)
•
C2
4.7μF
L1
3.3μH
CPWR
4.7μF
s2
VOUT
3.3V
1.8A (VBAT = 3V)
3.1A (VBAT = 9V)
3.4A (VBAT ≥ 12V)
D2
D4
L2
3.3μH
•
10k
200k
4.7nF
24.9k
M1
COUT
47μF
s6
SW1 SW2
C1
10nF
VIN
D1
15V
FB
SHDN
LT3579
100k
CVIN
10μF
174k
GATE
FAULT
VC
100pF
RT
CLKOUT
SYNC GND SS
8.25k
10k
Q1
0.22μF
4.7nF
3579 TA07a
C1: 10nF, 16V, X7R, 0603
CVIN: 10μF, 16V, X7R, 1206
CPWR, C2: 4.7μF, 50V, X7R, 1210
COUT: 47μF, 6.3V, X7R, 1210
D1: CENTRAL SEMI CMHZ5245B-LTZ
D2: VISHAY SS5P6
D3: CENTRAL SEMI CMMSH2-40
D4: CENTRAL SEMI CMMSH2-40
L1, L2: WÜRTH WE-DD 744870003
M1: 2N7002
Q1: MMBT3904
Transient Response with 9V to 33V to 9V VBAT Glitch (RLOAD = 1.5Ω)
90
4
80
3.5
70
3
2.5
60
VBAT = 3V
50
VBAT = 12V
2
40
1.5
30
1
20
0.5
VOUT
2V/DIV
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss
VBAT
10V/DIV
IL1 + IL2
1A/DIV
50ms/DIV
3579 TA08b
0
10
0
0.5
1
1.5 2 2.5 3
LOAD CURRENT (A)
3.5
4
3579 TA08a
35791f
32
LT3579/LT3579-1
TYPICAL APPLICATION
1.2MHz, 5V to -12V Inverting Converter
C1
4.7μF
L1
3.3μH
VIN
5V
L2
3.3μH
VOUT
–12V
1.2A
D1
143k
SW1 SW2
VIN
FB
SHDN
FAULT
CIN
22μF
GATE
COUT
10μF
s2
LT3579
100k
CLKOUT
RT
SYNC GND
71.5k
VC
SS
27pF
0.22μF
20k
1nF
3579 TA14
CIN: 22μF, 16V, X7R, 1210
C1: 4.7μF, 25V, X7R, 1206
COUT: 10μF, 25V, X7R, 1210
D1: DIODES INC B230A
L1, L2: COOPER BUSSMANN DRQ125-3R3-R
Transient Response with 0.5A to 1A to 0.5A Output Load Step
100
3.2
90
2.8
80
2.4
70
2
60
1.6
50
1.2
40
0.8
30
0.4
20
0
0.25
0.5
0.75
LOAD CURRENT (A)
1
VOUT
500mV/DIV
AC COUPLED
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss
IL1 + IL2
1A/DIV
ILOAD
1A/DIV
100μs/DIV
3579 TA16
0
1.25
3579 TA15
35791f
33
LT3579/LT3579-1
TYPICAL APPLICATION
VFD (Vacuum Flourescent Display) Power Supply Switches at 1MHz
Danger High Voltage! Operation by High Voltage Trained Personnel Only
D6
C6
2.2μF
s2
D5
C4
2.2μF
s2
D4
C5
2.2μF
s2
D3
VOUT2
100V
330mA*
VOUT1
67V
500mA*
C3
2.2μF
s2
D2
L1
10μH
VIN
9V TO 16V
D1
M1**
C1
2.2μF
s3
D9**
383k
SW1 SW2
VIN
100k
D8**
8.2V
6.5k**
FB
FAULT
D7**
VIN
GATE
LT3579
536k
SHDN
CIN
10μF
C2
2.2μF
s3
CLKOUT
VC
RT
SYNC
GND
SS
86.6k
27pF
2.2μF
34k
470pF
3579 TA17
CIN: 10μF, 25V, X7R, 1210
C1-C6: 2.2μF, 50V, X7R, 1210
D1-D6: DIODES INC SBR2A40P1
D7: CENTRAL SEMI CMDSH-3TR
D8: CENTRAL SEMI CMDZ5237B-LTZ
D9: DIODES INC MBRM360
L1: WÜRTH WE-PD 7447710
M1: SILICONIX SI7461DP
*MAX TOTAL
OUTPUT POWER
22W (VIN = 9V)
27W (VIN = 12V)
33W (VIN = 16V)
**OPTIONAL FOR OUTPUT
SHORT CIRCUIT PROTECTION
90
5
85
4
80
3
75
2
70
1
Cycle-to-Cycle
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss (VIN = 12V)
VOUT1
2V/DIV
AC COUPLED
VOUT2
2V/DIV
AC COUPLED
IL
1A/DIV
SW1
20V/DIV
1μs/DIV
65
0
5
15
10
20
25
TOTAL OUTPUT POWER (W)
3579 TA19
0
30
3579 TA18
35791f
34
LT3579/LT3579-1
TYPICAL APPLICATION
1MHz, 5V to ±12V Converter
C2
4.7μF
D5
D4
L1
4.7μH
VIN
5V
C1
4.7μF
D1
VOUT 2
–12V
COUT 2 0.8A*
10μF
s2
VOUT1
12V
0.8A*
R1**
1.2k
D3
D2
SW1
130k
SW2
VIN
COUT1
10μF
s2
FB
SHDN
GATE
LT3579
100k
FAULT
CIN
10μF
RT
SYNC
CLKOUT
VC
GND
SS
86.6k
27pF
0.1μF
34k
1nF
3579 TA20
CIN: 10μF, 16V, X7R, 1206
C1, C2: 4.7μF, 25V, X7R, 1206
COUT1, COUT2: 10μF, 25V, X7R, 1210
D1-D5: DIODES INC SBR2A40P1
L1: VISHAY IHLP-2525CZ-01-4R7
R1: 1.2k, 2W
*MAX TOTAL OUTPUT POWER = 9.6W
**IF DRIVING ASYMMETRICAL LOADS, PLACE A 1.2k, 2W
RESISTOR FROM THE +12V OUTPUT TO THE –12V OUTPUT FOR
IMPROVED LOAD REGULATION OF THE –12V OUTPUT.
Transient Response with 0.15A to 0.35A to 0.15A
Symmetrical Output Load Step
90
3
85
2.7
80
2.4
75
2.1
70
1.8
65
1.5
60
1.2
55
0.9
50
0.6
45
0.3
40
0
100
300
200
400
LOAD CURRENT (mA)
VOUT1
500mV/DIV
AC COUPLED
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss
VOUT2
500mV/DIV
AC COUPLED
IL
1A/DIV
100μs/DIV
3579 TA22
0
500
3579 TA21
35791f
35
LT3579/LT3579-1
TYPICAL APPLICATION
1MHz, 2-Phase Converter Generates a 24V Output from a 8V to 16V Input and Uses Small Components
L2
4.7μH
D2
COUT1S
4.7μF
s2
CPWR2
10μF
SW1 SW2
VIN
CLKOUT
FB
FAULT
LT3579-1
SLAVE
GATE
SHDN
VC
RT
CVIN2
4.7μF
SYNC GND
SS
0.22μF
86.6k
M1**
VOUT1
L1
4.7μH
VPWR
8V TO 16V
D1
6.4k**
VOUT1
500k
VIN
100k
SW1 SW2
CLKOUT
137k
FB
FAULT
LT3579-1
MASTER
GATE
SHDN
VC
RT
21.5k
CVIN1
4.7μF
SYNC GND
5k
86.6k
COUT
4.7μF
s2
COUT1M
4.7μF
s2
CPWR1
10μF
VIN
3.3V TO VPWR
VOUT
24V
5.1A*
D3**
VPWR
47pF
SS
0.22μF
7k
2.2nF
3579 F23
CPWR1, CPWR2: 10μF, 25V, X7R, 1210
CVIN1, CVIN2: 4.7μF, 25V, X7R, 1206
COUT1M, COUT1S, COUT: 4.7μF, 50V, X5R, 1210
D1, D2: CENTRAL SEMI CTLSH5-40M833
D3: CENTRAL SEMI CTLSH1-40M563
L1, L2: VISHAY IHLP-2525CZ-01-4R7
M1: SILICONIX SI7461DP
100
8
90
7
80
6
VIN = 12V
70
5
60
4
VIN = 3.3V
50
3
40
2
30
1
VPWR = 8V
VPWR = 12V
VPWR = 16V
VIN = 3.3V TO 5V
2.4A
3.7A
5.1A
VIN = VPWR
2.2A
3.1A
3.9A
**OPTIONAL FOR OUTPUT SHORT CIRCUIT PROTECTION
Transient Response with 1.5A to 3.25A to 1.5A
Output Load Step (VPWR = 12V and VIN = 3.3V)
VOUT
1V/DIV
AC COUPLED
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss (VPWR = 12V)
*MAX OUTPUT CURRENT
IL1 + IL2
5A/DIV
ILOAD
1A/DIV
100μs/DIV
20
0
0.5
1
1.5 2 2.5 3 3.5
LOAD CURRENT (A)
4
3579 TA25
0
4.5
3579 TA24
35791f
36
LT3579/LT3579-1
TYPICAL APPLICATION
2MHz, Boost Converter with Output Disconnect Generates a 5V Output from 2.8V to 4.2V Input
L1
0.47μH
VIN
2.8V TO 4.2V
D1
VOUT
5V
2A
M1
COUT1
22μF
43.5k
SW1 SW2
VIN
10k
FB
SHDN
GATE
LT3579
100k
COUT
22μF
CLKOUT
FAULT
VC
RT
SYNC GND
SS
CIN
10μF
43.2k
47pF
22nF
6.34k
2.2nF
3579 TA26
CIN: 10μF, 16V, X7R, 1206
COUT1, COUT: 22μF, 16V, X7R, 1210
D1: CENTRAL SEMI CTLSH3-30M833
L1: VISHAY IHLP-2020BZ-01-R47
M1: SILICONIX SI7123DN
Transient Response with 0.8A to 1.8A to 0.8A
Output Load Step (VIN = 3.3V)
2.4
90
2.1
80
1.8
70
1.5
60
1.2
VIN = 3.3V
50
0.9
40
0.6
30
0.3
20
0
0.5
1
1.5
LOAD CURRENT (A)
2
0
2.5
POWER LOSS (W)
EFFICIENCY (%)
Efficiency and Power Loss
100
VOUT
200mV/DIV
AC COUPLED
IL
1A/DIV
ILOAD
1A/DIV
100μs/DIV
3579 TA28
3579 TA27
35791f
37
LT3579/LT3579-1
PACKAGE DESCRIPTION
FE Package
20-Lead Plastic TSSOP (4.4mm)
(Reference LTC DWG # 05-08-1663)
Exposed Pad Variation CB
6.40 – 6.60*
(.252 – .260)
3.86
(.152)
3.86
(.152)
20 1918 17 16 15 14 13 12 11
6.60 ±0.10
2.74
(.108)
4.50 ±0.10
6.40
2.74 (.252)
(.108) BSC
SEE NOTE 4
0.45 ±0.05
1.05 ±0.10
0.65 BSC
1 2 3 4 5 6 7 8 9 10
RECOMMENDED SOLDER PAD LAYOUT
4.30 – 4.50*
(.169 – .177)
0.09 – 0.20
(.0035 – .0079)
0.25
REF
0.50 – 0.75
(.020 – .030)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
3. DRAWING NOT TO SCALE
1.20
(.047)
MAX
0° – 8°
0.65
(.0256)
BSC
0.195 – 0.30
(.0077 – .0118)
TYP
0.05 – 0.15
(.002 – .006)
FE20 (CB) 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
35791f
38
LT3579/LT3579-1
PACKAGE DESCRIPTION
UFD Package
20-Lead Plastic QFN (4mm × 5mm)
(Reference LTC DWG # 05-08-1711 Rev B)
0.70 ±0.05
4.50 ± 0.05
1.50 REF
3.10 ± 0.05
2.65 ± 0.05
3.65 ± 0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
2.50 REF
4.10 ± 0.05
5.50 ± 0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 ± 0.10
(2 SIDES)
0.75 ± 0.05
PIN 1 NOTCH
R = 0.20 OR
C = 0.35
1.50 REF
R = 0.05 TYP
19
20
0.40 ± 0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
5.00 ± 0.10
(2 SIDES)
2.50 REF
3.65 ± 0.10
2.65 ± 0.10
(UFD20) QFN 0506 REV B
0.200 REF
0.00 – 0.05
R = 0.115
TYP
0.25 ± 0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
35791f
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.
39
LT3579/LT3579-1
TYPICAL APPLICATION
Efficiency and Power Loss
VPWR
9V TO 16V
C1
4.7μF
L1
6.8μH
•
L2
6.8μH
SW1
VIN
COUT
10μF
s3
FB
SHDN
GATE
3.2
90
2.8
80
2.4
70
2
60
1.6
VPWR = 12V
VIN = 5V
50
1.2
40
0.8
30
0.4
LT3579
100k
CVIN
4.7μF
130k
•
SW2
VIN
3.3V TO VPWR
VOUT
12V
1.9A*
100
POWER LOSS (W)
CPWR
4.7μF
D1
EFFICIENCY (%)
1MHz SEPIC Converter Generates a 12V Output from
a 9V to 16V Input
CLKOUT
FAULT
RT
VC
SYNC GND SS
86.6k
20
47pF
0
0
9.53k
0.22μF
2.2nF
0.25 0.5 0.75 1 1.25 1.5 1.75
LOAD CURRENT (A)
2
3579 TA08
3579 TA29
*MAX OUTPUT CURRENT
CPWR: 4.7μF, 25V, X7R, 1206
CVIN: 4.7μF, 25V, X7R, 1206
VPWR = 9V VPWR = 12V
C1: 4.7μF, 25V, X7R, 1206
COUT: 10μF, 25V, X7R, 1210
1.6A
1.9A
VIN = 3.3V TO 5V
D1: DIODES INC MBRM360
=
V
1.4A
1.4A
V
L1, L2: COOPER BUSSMANN DRQ125-6R8-R IN PWR
LINE REGULATION (VIN = 5V, IOUT = 1A) = 0.017%/V
LOAD REGULATION (VPWR = 12V, VIN = 5V) = –0.23%/A
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT3581
3.3A (ISW), 42V, 2.5MHz, High Efficiency
Step-Up DC/DC Converter
VIN: 2.5V to 22V, VOUT(MAX) = 42V, IQ = 1.9mA, ISD = < 1μA, 4mm × 3mm DFN-14,
MSOP-16E
LT3580
2A (ISW), 42V, 2.5MHz, High Efficiency Step-Up
DC/DC Converter
VIN: 2.5V to 32V, VOUT(MAX) = 42V, IQ = 1mA, ISD = < 1μA, 3mm × 3mm DFN-8,
MSOP-8E
LT3479
3A (ISW), 40V, 3.5MHz, High Efficiency Step-Up
DC/DC Converter
VIN: 2.5V to 24V, VOUT(MAX) = 40V, IQ = 5mA, ISD = < 1μA, 4mm × 3mm DFN-14,
TSSOP-16E
35791f
40 Linear Technology Corporation
LT 0410 • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2010