LINER LTC3862HUH-PBF

LTC3862
Multi-Phase Current Mode
Step-Up DC/DC Controller
FEATURES
DESCRIPTION
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The LTC®3862 is a two phase constant frequency, current
mode boost and SEPIC controller that drives N-channel
power MOSFETs. Two phase operation reduces system
filtering capacitance and inductance requirements. The 5V
gate drive is optimized for most automotive and industrial
grade power MOSFETs.
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Wide VIN Range: 4V to 36V Operation
2-Phase Operation Reduces Input and Output
Capacitance
Fixed Frequency, Peak Current Mode Control
5V Gate Drive for Logic-Level MOSFETs
Adjustable Slope Compensation Gain
Adjustable Max Duty Cycle (Up to 96%)
Adjustable Leading Edge Blanking
±1% Internal Voltage Reference
Programmable Operating Frequency with One
External Resistor (75kHz to 500kHz)
Phase-Lockable Fixed Frequency 50kHz to 650kHz
SYNC Input and CLKOUT for 2-, 3-, 4-, 6- or
12-Phase Operation (PHASEMODE Programmable)
Internal 5V LDO Regulator
24-Lead Narrow SSOP Package
5mm × 5mm QFN with 0.65mm Lead Pitch and
24-Lead Thermally Enhanced TSSOP Packages
APPLICATIONS
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Automotive, Telecom and Industrial Power Supplies
Adjustable slope compensation gain allows the user to finetune the current loop gain, improving noise immunity.
The operating frequency can be set with an external resistor
over a 75kHz to 500kHz range and can be synchronized
to an external clock using the internal PLL. Multi-phase
operation is possible using the SYNC input, the CLKOUT
output and the PHASEMODE control pin allowing 2-, 3-,
4-, 6- or 12-phase operation.
Other features include an internal 5V LDO with undervoltage
lockout protection for the gate drivers, a precision RUN
pin threshold with programmable hysteresis, soft-start
and programmable leading edge blanking and maximum
duty cycle
L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners. Protected by U.S. Patents,
including 6144194, 6498466, 6611131.
TYPICAL APPLICATION
84.5k
19.4μH
RUN
GATE1
INTVCC
4.7μF
10nF
FB
10nF
ITH
475k
12.4k
68.1k
100pF
VIN = 12V
94
0.006Ω
3V8
VOUT = 48V
96
220μF
0.006Ω
50V
BLANK
SENSE1–
FREQ
GATE2
SYNC
SENSE2+
PLLFLTR
SS
1nF
98
SENSE1+
LTC3862
10k
Efficiency vs Output Current
EFFICIENCY (%)
10nF
VIN
5V TO 36V
VOUT
48V
5A (MAX)
VIN
24.9k
66.5k
19.4μH
22μF
50V
SENSE2–
PGND
CLKOUT
SLOPE
DMAX
PHASEMODE
SGND
92
90
88
VIN = 24V
VIN = 5V
86
84
82
80
100
1000
LOAD CURRENT (mA)
10000
3862 TA01b
3862 TA01
3862fb
1
LTC3862
ABSOLUTE MAXIMUM RATINGS
(Notes 1, 2)
Input Supply Voltage (VIN) ......................... –0.3V to 40V
INTVCC Voltage ............................................ –0.3V to 6V
INTVCC LDO RMS Output Current .........................50mA
RUN Voltage ................................................ –0.3V to 8V
SYNC Voltage ............................................... –0.3V to 6V
SLOPE, PHASEMODE, DMAX,
BLANK Voltage ........................................... –0.3V to 3V8
SENSE1+, SENSE1–, SENSE2+,
SENSE2– Voltage ....................................... –0.3V to 3V8
SS, PLLFLTR Voltage ................................. –0.3V to 3V8
ITH Voltage ............................................... –0.3V to 2.7V
FB Voltage .................................................. –0.3V to 3V8
FREQ Voltage ............................................ –0.3V to 1.5V
Operating Junction Temperature Range (Notes 3, 4)
LTC3862E............................................. –40°C to 85°C
LTC3862I............................................ –40°C to 125°C
LTC3862H .......................................... –40°C to 150°C
Storage Temperature Range................... –65°C to 150°C
Reflow Peak Body Temperature ........................... 260°C
PIN CONFIGURATION
5
20 VIN
SS
6
19 INTVCC
ITH
7
FB
8
17 PGND
SGND
9
16 GATE2
CLKOUT 10
18 GATE1
15 NC
SYNC 11
14 SENSE2–
PLLFLTR 12
13 SENSE2+
FE PACKAGE
24-LEAD PLASTIC TSSOP
TJMAX = 150°C, θJA = 38°C/W
EXPOSED PAD (PIN 25) IS PGND, MUST BE SOLDERED TO PCB
3
22 SENSE1–
PHASEMODE
FREQ
4
5
21 RUN
20 VIN
SS
6
19 INTVCC
ITH
7
18 GATE1
FB
8
SGND
9
CLKOUT 10
SYNC 11
PLLFLTR 12
17 PGND
16 GATE2
15 NC
14
SENSE2–
13 SENSE2+
GN PACKAGE
24-LEAD NARROW PLASTIC SSOP
TJMAX = 150°C, θJA = 85°C/W
RUN
FREQ
BLANK
SENSE1–
21 RUN
24 23 22 21 20 19
BLANK 1
18 VIN
17 INTVCC
PHASEMODE 2
FREQ 3
16 GATE1
25
SS 4
15 PGND
14 GATE2
ITH 5
FB 6
13 NC
7
8
9 10 11 12
SENSE2–
4
23 SENSE1+
SENSE2
PHASEMODE
SLOPE
SENSE1+
22 SENSE1–
24 3V8
2
+
3
1
3V8
BLANK
DMAX
DMAX
23 SENSE1+
SYNC
2
SLOPE
SLOPE
SGND
24 3V8
CLKOUT
1
25
TOP VIEW
TOP VIEW
DMAX
PLLFLTR
TOP VIEW
UH PACKAGE
24-LEAD (5mm s 5mm) PLASTIC QFN
TJMAX = 150°C, θJA = 34°C/W
EXPOSED PAD (PIN 25) IS PGND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC3862EFE#PBF
LTC3862EFE#TRPBF
3862FE
24-Lead Plastic TSSOP
–40°C to 85°C
LTC3862IFE#PBF
LTC3862IFE#TRPBF
3862FE
24-Lead Plastic TSSOP
–40°C to 125°C
LTC3862HFE#PBF
LTC3862HFE#TRPBF
3862FE
24-Lead Plastic TSSOP
–40°C to 150°C
LTC3862EGN#PBF
LTC3862EGN#TRPBF
LTC3862GN
24-Lead Plastic SSOP
–40°C to 85°C
LTC3862IGN#PBF
LTC3862IGN#TRPBF
LTC3862GN
24-Lead Plastic SSOP
–40°C to 125°C
LTC3862HGN#PBF
LTC3862HGN#TRPBF
LTC3862GN
24-Lead Plastic SSOP
–40°C to 150°C
LTC3862EUH#PBF
LTC3862EUH#TRPBF
3862
–40°C to 85°C
24-Lead (5mm × 5mm) Plastic QFN
LTC3862IUH#PBF
LTC3862IUH#TRPBF
3862
–40°C to 125°C
24-Lead (5mm × 5mm) Plastic QFN
LTC3862HUH#PBF
LTC3862HUH#TRPBF
3862
–40°C to 150°C
24-Lead (5mm × 5mm) Plastic QFN
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Consult LTC Marketing for information on non-standard lead based finish parts.
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/
2
3862fb
LTC3862
ELECTRICAL CHARACTERISTICS
(Notes 2, 3) The l denotes the specifications which apply over the full
operating junction temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, RUN = 2V and SS = open, unless
otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Supply Input and INTVCC Linear Regulator
VIN
VIN Supply Voltage Range
IVIN
VIN Supply Current
Normal Mode, No Switching
Shutdown
INTVCC
LDO Regulator Output Voltage
dVINTVCC(LINE)
Line Regulation
4
(Note 5)
VRUN = 0V
l
l
1.8
30
4.8
6V < VIN < 36V
dVINTVCC(LOAD) Load Regulation
Load = 0mA to 20mA
VUVLO
INTVCC UVLO Voltage
Rising INTVCC
Falling INTVCC
3V8
LDO Regulator Output Voltage
36
V
3.0
80
mA
μA
5.0
5.2
V
0.002
0.02
%/V
–2
%
3.3
2.9
V
V
3.8
V
Switcher Control Loop
VFB
Reference Voltage
VITH = 0.8V (Note 6)
E-Grade (Note 3)
I-Grade and H-Grade (Note 3)
dVFB/dVIN
Feedback Voltage VIN Line Regulation
VIN = 4V to 36V (Note 6)
l
l
1.210
1.199
1.223
1.223
1.235
1.248
V
V
±0.002
0.01
%/V
0.1
dVFB/dVITH
Feedback Voltage Load Regulation
VITH = 0.5V to 1.2V (Note 6)
0.01
gm
Transconductance Amplifier Gain
VITH = 0.8V (Note 6), ITH Pin Load = ±5μA
660
μMho
f0dB
Error Amplifier Unity-Gain Crossover
Frequency
(Note 7)
1.8
MHz
VITH
Error Amplifier Maximum Output Voltage
(Internally Clamped)
VFB = 1V, No Load
2.7
V
Error Amplifier Minimum Output Voltage
VFB = 1.5V, No Load
50
mV
IITH
%
Error Amplifier Output Source Current
–30
μA
Error Amplifier Output Sink Current
30
μA
IFB
Error Amplifier Input Bias Currents
(Note 6)
VITH(PSKIP)
Pulse Skip Mode Operation ITH Pin Voltage
Rising ITH Voltage (Note 6)
Hysteresis
ISENSE(ON)
SENSE Pin Current
VSENSE(MAX)
Maximum Current Sense Input Threshold
VSLOPE = Float, Low Duty Cycle
(Note 3)
VSENSE(MATCH)
CH1 to CH2 Maximum Current Sense
Threshold Matching
VSLOPE = Float, Low Duty Cycle (Note 3)
(VSENSE1 – VSENSE2)
IRUN
RUN Source Current
VRUN = 0V
VRUN = 1.5V
VRUN
High Level RUN Channel Enable Threshold
VRUNHYS
RUN Threshold Hysteresis
ISS
SS Pull-Up Current
VSS = 0V
–5
μA
RSS
SS Pull-Down Resistance
VRUN = 0V
10
kΩ
Oscillator Frequency
RFREQ = 45.6k
RFREQ = 45.6k
–50
–200
0.275
25
l
65
60
l
–10
nA
V
mV
0.01
2
μA
75
75
85
90
mV
mV
10
mV
RUN/Soft-Start
–0.5
–5
μA
μA
1.22
V
80
mV
Oscillator
fOSC
Oscillator Frequency Range
VFREQ
Nominal FREQ Pin Voltage
RFREQ = 45.6k
l
280
260
l
75
300
300
1.223
320
340
kHz
kHz
500
kHz
V
3862fb
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LTC3862
ELECTRICAL CHARACTERISTICS
(Notes 2, 3) The l denotes the specifications which apply over the full
operating junction temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, RUN = 2V and SS = open, unless
otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
SYNC Minimum Input Frequency
VSYNC = External Clock
l
SYNC Maximum Input Frequency
VSYNC = External Clock
l
VSYNC
SYNC Input Threshold
Rising Threshold
1.5
V
IPLLFLTR
Phase Detector Sourcing Output Current
fSYNC > fOSC
–15
μA
fSYNC
50
650
kHz
kHz
Phase Detector Sinking Output Current
fSYNC < fOSC
15
μA
CH1-CH2
Channel 1 to Channel 2 Phase Relationship
VPHASEMODE = 0V
VPHASEMODE = Float
VPHASEMODE = 3V8
180
180
120
Deg
Deg
Deg
CH1-CLKOUT
Channel 1 to CLKOUT Phase Relationship
VPHASEMODE = 0V
VPHASEMODE = Float
VPHASEMODE = 3V8
90
60
240
Deg
Deg
Deg
DMAX
Maximum Duty Cycle
VDMAX = 0V
VDMAX = Float
VDMAX = 3V8
96
84
75
%
%
%
tON(MIN)1
Minimum On-Time
VBLANK = 0V (Note 8)
180
ns
tON(MIN)2
Minimum On-Time
VBLANK = Float (Note 8)
260
ns
tON(MIN)3
Minimum On-Time
VBLANK = 3V8 (Note 8)
340
ns
Driver Pull-Up RDS(ON)
2.1
Ω
Driver Pull-Down RDS(ON)
0.7
Ω
Gate Driver
RDS(ON)
Overvoltage
VFB(OV)
VFB, Overvoltage Lockout Threshold
VFB(OV) – VFB(NOM) in Percent
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: All currents into device pins are positive; all currents out of device
pins are negative. All voltages are referenced to ground unless otherwise
specified.
Note 3: The LTC3862E is guaranted to meet performance specifications
from 0°C to 85°C. Specifications over the –40°C to 85°C operating
junction temperature range are assured by design, characterization and
correlation with statistical process controls. The LTC3862I is guaranteed
over the full –40°C to 125°C operating junction temperature range and
the LTC3862H is guaranteed over the full –40°C to 150°C operating
junction temperature range. High junction temperatures degrade operating
lifetimes. Operating lifetime is derated at junction temperatures greater
than 125°C.
8
10
12
%
Note 4: This IC includes overtemperature protection that is intended to
protect the device during momentary overload conditions. Continuous
operation above the specified maximum operating junction temperature
may impair device reliability.
Note 5: Supply current in normal operation is dominated by the current
needed to charge the external MOSFET gates. This current will vary with
supply voltage and the external MOSFETs used.
Note 6: The IC is tested in a feedback loop that adjusts VFB to achieve a
specified error amplifier output voltage.
Note 7: Guaranteed by design, not subject to test.
Note 8: The minimum on-time condition is specified for an inductor peakto-peak ripple current = 30% (see Minimum On-Time Considerations in the
Applications Information section).
3862fb
4
LTC3862
TYPICAL PERFORMANCE CHARACTERISTICS
Efficiency and Power Loss vs
Input Voltage
Efficiency vs Output Current
100
96
VOUT = 48V
95
95
90
85
75
EFFICIENCY (%)
VIN = 35V
80
VIN = 24V
70
65
3500
94
3000
93
2500
POWER LOSS
92
VIN = 12V
60
2000
91
VOUT = 48V
IOUT = 1A
55
90
50
10
100
1000
LOAD CURRENT (mA)
0
10000
10
1500
20
30
INPUT VOLTAGE (V)
40
3862 G01
Load Step
POWER LOSS (mW)
EFFICIENCY (%)
4000
EFFICIENCY
3862 G02
Quiescent Current vs Input
Voltage
Inductor Current at Light Load
3.00
ILOAD
5A/DIV
1A TO 5A
2.75
SW1
50V/DIV
QUIESCENT CURRENT (mA)
IL1
5A/DIV
2.50
SW2
50V/DIV
IL2
5A/DIV
IL1
2A/DIV
IL2
2A/DIV
VOUT
500mV/DIV
VIN = 24V
VOUT = 48V
500μs/DIV
3862 G03
VIN = 12V
VOUT = 48V
ILOAD = 100mA
1μs/DIV
2.25
2.00
1.75
1.50
1.25
1.00
0.75
0.50
3862 G04
0.25
0
4
8
12
16 20 24 28
INPUT VOLTAGE (V)
32
36
3862 G05
Shutdown Quiescent Current vs
Input Voltage
45
1.85
40
1.80
1.75
1.70
1.65
1.60
1.55
1.50
–50 –25
Shutdown Quiescent Current vs
Temperature
50
SHUTDOWN CURRENT (μA)
1.90
SHUTDOWN CURRENT (μA)
QUIESCENT CURRENT (mA)
Quiescent Current vs Temperature
35
30
25
20
15
10
VIN = 12V
40
30
20
10
5
0
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G06
0
4
8
12
16 20 24 28
INPUT VOLTAGE (V)
32
36
3862 G07
0
–50 –25
0
25 50
75 100 125 150
TEMPERATURE (°C)
3862 G08
3862fb
5
LTC3862
TYPICAL PERFORMANCE CHARACTERISTICS
INTVCC Line Regulation
INTVCC Load Regulation
INTVCC vs Temperature
5.00
5.00
5.25
4.99
4.98
5.00
INTVCC VOLTAGE (V)
INTVCC VOLTAGE (V)
INTVCC VOLTAGE (V)
4.95
4.90
4.97
4.96
4.95
4.94
4.93
4.85
4.92
4.91
4.75
5
0
10
15
4.80
25
20
10
30
40
20
INTVCC LOAD CURRENT (mA)
0
INPUT VOLTAGE (V)
INTVCC LDO Dropout vs Load
Current, Temperature
85°C
800
25°C
600
–40°C
400
3.5
1.233
1.231
1.229
3.3
3.2
3.1
3.0
2.9
10
0
20
30
INTVCC LOAD (mA)
40
50
1.225
1.223
1.221
1.219
1.215
2.7
1.213
2.6
–50 –25
1.211
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G12
Current Sense Threshold vs
Temperature
80
80
1.223
1.222
1.221
1.220
4
8
12
16 20 24 28
INPUT VOLTAGE (V)
32
36
3862 G15
70
CURRENT SENSE THRESHOLD (mV)
CURRENT SENSE THRESHOLD (mV)
1.226
1.224
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G14
Current Sense Threshold vs
ITH Voltage
1.225
0
3862 G13
Feedback Voltage Line
Regulation
FB VOLTAGE (V)
1.227
1.217
2.8
200
0
1.235
FB VOLTAGE (V)
1000
25 50 75 100 125 150
TEMPERATURE (°C)
Feedback Voltage vs Temperature
3.6
3.4
INTVCC VOLTAGE (V)
DROPOUT VOLTAGE (mV)
150°C
125°C
0
3862 G11
INTVCC UVLO Threshold vs
Temperature
1600
1200
50
3862 G10
3962 G09
1400
4.90
–50 –25
60
50
40
30
20
10
0
0
0.4
0.8
1.2
1.6
ITH VOLTAGE (V)
2.0
2.4
3862 G16
79
78
77
76
75
74
73
72
71
70
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G17
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6
LTC3862
TYPICAL PERFORMANCE CHARACTERISTICS
Maximum Current Sense
Threshold vs Duty Cycle
RUN Threshold vs Temperature
SLOPE = 0.625
70
SLOPE = 1
SLOPE = 1.66
65
60
1.4
ON
1.25
RUN PIN VOLTAGE (V)
75
1.20
OFF
1.15
50
1.10
–50 –25
10 20 30 40 50 60 70 80 90 100
DUTY CYCLE (%)
1.2
OFF
0
25 50 75 100 125 150
TEMPERATURE (°C)
RUN PIN CURRENT (μA)
–0.3
–0.5
–0.6
–0.7
15 20
25 30
INPUT VOLTAGE (V)
–0.8
0
0
–1
–1
–2
–3
–4
–5
–6
–8
–50 –25
25 50 75 100 125 150
TEMPERATURE (°C)
0
–2
–3
–4
–5
–7
25 50 75 100 125 150
TEMPERATURE (°C)
4
8
12
16
20
24
0
–5.1
–1
32
36
3862 G23
Soft-Start Current vs
Soft-Start Voltage
–5.0
28
INPUT VOLTAGE (V)
1344 G06
3862 G21vv
Soft-Start Current vs Temperature
40
–6
–7
–0.9
35
RUN Source Current vs
Input Voltage
RUN PIN CURRENT (μA)
0
–0.1
–0.4
10
3862 G20
RUN (On) Source Current vs
Temperature
–0.2
5
3862 G09
RUN (Off) Source Current vs
Temperature
0
ON
1.0
0
3862 G18
–1.0
–50 –25
1.3
1.1
55
0
RUN PIN CURRENT (μA)
RUN Threshold vs Input Voltage
1.5
1.30
RUN PIN VOLTAGE (V)
MAXIMUM CURRENT SENSE THRESHOLD (mV)
80
Oscillator Frequency vs
Temperature
307
–5.2
–5.3
–5.4
305
FREQUENCY (kHz)
SOFT-START CURRENT (μA)
SOFT-START CURRENT (μA)
306
–2
–3
–4
–5.5
–5
–5.6
–50 –25
–6
304
303
302
301
300
299
0
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G24
0
0.5
2.5 3
1 1.5 2
SOFT-START VOLTAGE (V)
3.5
4
3862 G25
298
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
3862 G26
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7
LTC3862
TYPICAL PERFORMANCE CHARACTERISTICS
Oscillator Frequency vs
Input Voltage
RFREQ vs Frequency
Frequency vs PLLFLTR Voltage
1000
320
1400
315
1200
300
295
FREQUENCY (kHz)
305
RFREQ (kΩ)
FREQUENCY (kHz)
310
100
1000
200
285
4
12 16 20 24 28
INPUT VOLTAGE (V)
8
32
10
36
0
0 100 200 300 400 500 600 700 800 900 1000
FREQUENCY (kHz)
1.235
1.233
400
1.231
350
MINIMUM ON-TIME (ns)
1.223
1.221
1.219
1.217
2.5
2
Minimum On-Time vs
Input Voltage
400
BLANK = 3V8
300
BLANK = FLOAT
250
200
BLANK = 3V8
350
BLANK = SGND
150
1.215
1.5
3862 G29
Minimum On-Time vs
Temperature
1.225
1
PLLFLTR VOLTAGE (V)
3862 G28
Frequency Voltage vs
Temperature
1.229
1.227
0.5
0
MINIMUM ON-TIME (ns)
0
3862 G27
FREQ VOLTAGE (V)
600
400
290
280
800
300
BLANK = FLOAT
250
200
BLANK = SGND
150
1.213
1.211
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
100
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
100
4
8
12
16 20 24 28
INPUT VOLTAGE (V)
3862 G31
3862 G30
Gate Turn-On Waveform Driving
Renesas HAT2266
32
36
3862 G32
Gate Turn-Off Waveform Driving
Renesas HAT2266
GATE
1V/DIV
GATE
1V/DIV
VIN = 12V
20ns/DIV
VOUT = 48V
IOUT = 1A
MOSFET RENESAS HAT2266
3862 G33
VIN = 12V
20ns/DIV
VOUT = 48V
IOUT = 1A
MOSFET RENESAS HAT2266
3862 G34
3862fb
8
LTC3862
PIN FUNCTIONS
3V8: Output of the Internal 3.8V LDO from INTVCC. Supply
pin for the low voltage analog and digital circuits. A low
ESR 1nF ceramic bypass capacitor should be connected
between 3V8 and SGND, as close as possible to the IC.
ITH: Error Amplifier Output. The current comparator trip
threshold increases with the ITH control voltage. The ITH
pin is also used for compensating the control loop of the
converter.
BLANK: Blanking Time. Floating this pin provides a nominal
minimum on-time of 260ns. Connecting this pin to 3V8
provides a minimum on-time of 340ns, while connecting
it to SGND provides a minimum on-time of 180ns.
PGND: Power Ground. Connect this pin close to the
sources of the power MOSFETs. PGND should also be
connected to the negative terminals of VIN and INTVCC
bypass capacitors. PGND is electrically isolated from the
SGND pin. The Exposed Pad of the FE and QFN packages
is connected to PGND.
CLKOUT: Digital Output Used for Daisy-Chaining Multiple
LTC3862 ICs in Multi-Phase Systems. The PHASEMODE
pin voltage controls the relationship between CH1 and
CH2 as well as between CH1 and CLKOUT.
DMAX: Maximum Duty Cycle.This pin programs the maximum duty cycle. Floating this pin provides 84% duty cycle.
Connecting this pin to 3V8 provides 75% duty cycle, while
connecting it to SGND provides 96% duty cycle.
FB: Error Amplifier Input. The FB pin should be connected
through a resistive divider network to VOUT to set the
output voltage.
FREQ: A resistor from FREQ to SGND sets the operating
frequency.
GATE1, GATE2: Gate Drive Output. The LTC3862 provides
a 5V gate drive referenced to PGND to drive a logic-level
threshold MOSFET.
INTVCC: Output of the Internal 5V Low Dropout Regulator
(LDO). A low ESR 4.7μF (X5R or better) ceramic bypass
capacitor should be connected between INTVCC and PGND,
as close as possible to the IC.
PHASEMODE: The PHASEMODE pin voltage programs
the phase relationship between CH1 and CH2 rising gate
signals, as well as the phase relationship between CH1
gate signal and CLKOUT. Floating this pin or connecting
it to either 3V8, or SGND changes the phase relationship
between CH1, CH2 and CLKOUT.
PLLFLTR: PLL Lowpass Filter Input. When synchronizing to an external clock, this pin serves as the lowpass
filter input for the PLL. A series resistor and capacitor
connected from PLLFLTR to SGND compensate the PLL
feedback loop.
RUN: Run Control Input. A voltage above 1.22V on the pin
turns on the IC. Forcing the pin below 1.22V causes the
IC to shut down. There is a 0.5μA pull-up current for this
pin. Once the RUN pin raises above 1.22V, an additional
4.5μA pull-up current is added to the pin for programmable hysteresis.
3862fb
9
LTC3862
PIN FUNCTIONS
SENSE1+, SENSE2+: Positive Inputs to the Current
Comparators. The ITH pin voltage programs the current
comparator offset in order to set the peak current trip
threshold. This pin is normally connected to a sense
resistor in the source of the power MOSFET.
SENSE1–, SENSE2–: Negative Inputs to the Current Comparators. This pin is normally connected to the bottom of
the sense resistor.
SGND: Signal Ground. All feedback and soft-start connections should return to SGND. For optimum load
regulation, the SGND pin should be kelvin connected to
the PCB location between the negative terminals of the
output capacitors.
SLOPE: This pin programs the gain of the internal slope
compensation. Floating this pin provides a normalized
slope compensation gain of 1.00. Connecting this pin
to 3V8 increases the normalized slope compensation by
66%, and connecting it to SGND decreases the normalized
slope compensation by 37.5%. See Applications Information for more details.
SS: Soft-Start Input. For soft-start operation, connecting
a capacitor from this pin to SGND will clamp the output of
the error amp. An internal 5μA current source will charge
the capacitor and set the rate of increase of the peak switch
current of the converter.
SYNC: PLL Synchronization Input. Applying an external
clock between 50kHz and 650kHz will cause the operating
frequency to synchronize to the clock. SYNC is pulled down
by a 50k internal resistor. The rising edge of the SYNC
input waveform will align with the rising edge of GATE1
in closed-loop operation.
VIN: Main Supply Input. A low ESR ceramic capacitor
should be connected between this pin and SGND.
3862fb
10
LTC3862
FUNCTIONAL DIAGRAM
CLKOUT
SYNC
SYNC
DETECT
PLLFLTR
VIN
VIN
RP
CIN
5V
LDO
CP
INTVCC
DMAX
PHASEMODE
UV
CLK1
VCO
FREQ
OT
CLK2
RFREQ
CVCC
3.8V
LDO
UVLO
L
3V8
C3V8
OVER
TEMP
BIAS
SLOPE
SLOPE
COMPENSATION
BLANK
BLANK
LOGIC
DMAX
S
OT
R1
UV
BLOGIC
D
GATE
Q
R2
SD
BLOGIC
M COUT
LOGIC
+
VOUT
PGND
PWM LATCH
SENSE+
OV
3V8
SS
ITRIP
PSKIP
+
–
ICMP
RLOOP
SENSE–
5μA
CSS
V TO I
OT
UV
SD
DUPLICATE FOR
SECOND CHANNEL
VFB
ITH
PSKIP
RC
RS
SD
OV
SGND
R2
R1
CC
PSKIP
– +
0.275V
EA
+ –
1.223V
OV
– +
1.345V
RUN
– +
4.5μA
0.5μA
3862 FD
RUN
1.22V
3862fb
11
LTC3862
OPERATION
The Control Loop
drive supply (INTVCC) and one for the low voltage analog
and digital control circuitry (3V8). A block diagram of this
power supply arrangement is shown in Figure 1.
The LTC3862 uses a constant frequency, peak current
mode step-up architecture with its two channels operating 180 degrees out of phase. During normal operation,
each external MOSFET is turned on when the clock for
that channel sets the PWM latch, and is turned off when
the main current comparator, ICMP, resets the latch. The
peak inductor current at which ICMP trips and resets the
latch is controlled by the voltage on the ITH pin, which is
the output of the error amplifier, EA. The error amplifier
compares the output feedback signal at the VFB pin to the
internal 1.223V reference and generates an error signal
at the ITH pin. When the load current increases it causes
a slight decrease in VFB relative to the reference voltage,
which causes the EA to increase the ITH voltage until the
average inductor current matches the new load current.
After the MOSFET is turned off, the inductor current flows
through the boost diode into the output capacitor and load,
until the beginning of the next clock cycle.
The Gate Driver Supply LDO (INTVCC)
The 5V output (INTVCC) of the first LDO is powered from
VIN and supplies power to the power MOSFET gate drivers. The INTVCC pin should be bypassed to PGND with a
minimum of 4.7μF of ceramic capacitance (X5R or better),
placed as close as possible to the IC pins. If two power
MOSFETs are connected in parallel for each channel in
order to increase the output power level, or if a single
MOSFET with a QG greater than 50nC is used, then it is
recommended that the bypass capacitance be increased
to a minimum of 10μF.
An undervoltage lockout (UVLO) circuit senses the INTVCC
regulator output in order to protect the power MOSFETs
from operating with inadequate gate drive. For the LTC3862
the rising UVLO threshold is typically 3.3V and the hysteresis is typically 400mV. The LTC3862 was optimized for
logic-level power MOSFETs and applications where the
output voltage is less than 50V to 60V. For applications
requiring standard threshold power MOSFETs, please refer
to the LTC3862-1 data sheet.
Cascaded LDOs Supply Power to the Gate Driver and
Control Circuitry
The LTC3862 contains two cascaded PMOS output stage
low dropout voltage regulators (LDOs), one for the gate
LTC3862
VIN
1.223V
CIN
–
P-CH
+
SGND
R2
R1
INTVCC
1.223V
INTVCC
–
CVCC
P-CH
GATE
+
PGND
SGND
R4
R3
3V8
ANALOG
CIRCUITS
3V8
LOGIC
C3V8
SGND
3862 F01
NOTE: PLACE CVCC AND C3V8 CAPACITORS AS CLOSE AS POSSIBLE TO DEVICE PINS
Figure 1. Cascaded LDOs Provide Gate Drive and Control Circuitry Power
3862fb
12
LTC3862
OPERATION
In multi-phase applications, all of the FB pins are connected
together and all of the error amplifier output pins (ITH) are
connected together. The INTVCC pins, however, should not
be connected together. The INTVCC regulator is capable of
sourcing current but is not capable of sinking current. As
a result, when two or more INTVCC regulator outputs are
connected together, the highest voltage regulator supplies
all of the gate drive and control circuit current, and the
other regulators are off. This would place a thermal burden
on the highest output voltage LDO and could cause the
maximum die temperature to be exceeded. In multi-phase
LTC3862 applications, each INTVCC regulator output should
be independently bypassed to its respective PGND pin as
close as possible to each IC.
The Low Voltage Analog and Digital Supply LDO (3V8)
The second LDO within the LTC3862 is powered off of
INTVCC and serves as the supply to the low voltage analog
and digital control circuitry, as shown in Figure 1. The
output voltage of this LDO (which also has a PMOS output device) is 3.8V. Most of the analog and digital control
circuitry is powered from the internal 3V8 LDO. The 3V8
pin should be bypassed to SGND with a 1nF ceramic capacitor (X5R or better), placed as close as possible to the
IC pins. This LDO is not intended to be used as a supply
for external circuitry.
Thermal Considerations and Package Options
The LTC3862 is offered in two package options. The 5mm
× 5mm QFN package (UH24) has a thermal resistance
RTH(JA) of 34°C/W, the 24-pin TSSOP (FE24) package has a
thermal resistance of 38°C/W, and the 24-pin SSOP (GN24)
package has a thermal resistance of 85°C/W. The QFN and
TSSOP package options have a lead pitch of 0.65mm, and
the GN24 option has a lead pitch of 0.025in.
The INTVCC regulator can supply up to 50mA of total
current. As a result, care must be taken to ensure that
the maximum junction temperature of the IC is never
exceeded. The junction temperature can be estimated
using the following equations:
IQ(TOT) = IQ + QG(TOT) • f
PDISS = VIN • (IQ + QG(TOT) • f)
TJ = TA + PDISS • RTH(JA)
The total quiescent current (IQ(TOT)) consists of the static
supply current (IQ) and the current required to charge
the gate capacitance of the power MOSFETs. The value
of QG(TOT) should come from the plot of VGS vs QG in the
Typical Performance Characteristics section of the MOSFET
data sheet. The value listed in the electrical specifications
may be measured at a higher VGS, such as 10V, whereas the
value of interest is at the 5V INTVCC gate drive voltage.
As an example of the required thermal analysis, consider
a 2-phase boost converter with a 9V to 24V input voltage
range and an output voltage of 48V at 2A. The switching
frequency is 150kHz and the maximum ambient temperature is 70°C. The power MOSFET used for this application
is the Vishay Si7478DP, which has a typical RDS(ON) of
8.8mΩ at VGS = 4.5V and 7.5mΩ at VGS = 10V. From the
plot of VGS vs QG, the total gate charge at VGS = 5V is
50nC (the temperature coefficient of the gate charge is
low). One power MOSFET is used for each phase. For the
QFN package option:
IQ(TOT) = 3mA + 2 • 50nC • 150kHz = 18mA
PDISS = 24V • 18mA = 432mW
TJ = 70°C + 432mW • 34°C/W = 84.7°C
In this example, the junction temperature rise is only 14.7°C.
These equations demonstrate how the gate charge current
typically dominates the quiescent current of the IC, and
how the choice of package option and board heat sinking
can have a significant effect on the thermal performance
of the solution.
3862fb
13
LTC3862
OPERATION
Thermal Shutdown Protection
In the event of an overtemperature condition (external
or internal), an internal thermal monitor will shut down
the gate drivers and reset the soft-start capacitor if the
die temperature exceeds 170°C. This thermal sensor
has a hysteresis of 10°C to prevent erratic behavior at
hot temperatures. The LTC3862’s internal thermal sensor is intended to protect the device during momentary
overtemperature conditions. Continuous operation above
the specified maximum operating junction temperature,
however, may result in device degradation.
Operation at Low Supply Voltage
The LTC3862 has a minimum input voltage of 4V, making
it a good choice for applications that experience low supply conditions. The gate driver for the LTC3862 consists
of PMOS pull-up and NMOS pull-down devices, allowing
the full INTVCC voltage to be applied to the gates during
power MOSFET switching. Nonetheless, care should be
taken to determine the minimum gate drive supply voltage
(INTVCC) in order to choose the optimum power MOSFETs.
Important parameters that can affect the minimum gate
drive voltage are the minimum input voltage (VIN(MIN)),
the LDO dropout voltage, the QG of the power MOSFETs,
and the operating frequency.
If the input voltage VIN is low enough for the INTVCC LDO
to be in dropout, then the minimum gate drive supply
voltage is:
VINTVCC = VIN(MIN) – VDROPOUT
The LDO dropout voltage is a function of the total gate
drive current and the quiescent current of the IC (typically
3mA). A curve of dropout voltage vs output current for the
LDO is shown in Figure 2. The temperature coefficient of
the LDO dropout voltage is approximately 6000ppm/°C.
The total Q-current (IQ(TOT)) flowing in the LDO is the sum
of the controller quiescent current (3mA) and the total gate
charge drive current.
IQ(TOT) = IQ + QG(TOT) • f
After the calculations have been completed, it is important to measure the gate drive waveforms and the gate
driver supply voltage (INTVCC to PGND) over all operating
conditions (low VIN, nominal VIN and high VIN, as well
as from light load to full load) to ensure adequate power
MOSFET enhancement. Consult the power MOSFET data
sheet to determine the actual RDS(ON) for the measured
VGS, and verify your thermal calculations by measuring
the component temperatures using an infrared camera
or thermal probe.
1600
1400
DROPOUT VOLTAGE (mV)
To prevent the maximum junction temperature from being exceeded, the input supply current to the IC should
be checked when operating in continuous mode (heavy
load) at maximum VIN. A tradeoff between the operating
frequency and the size of the power MOSFETs may need
to be made in order to maintain a reliable junction temperature. Finally, it is important to verify the calculations
by performing a thermal analysis of the final PCB using
an infrared camera or thermal probe. As an option, an
exernal regulator shown in Figure 3 can be used to reduce
the total power dissipation on the IC.
150°C
1200
125°C
1000
85°C
800
25°C
600
–40°C
400
200
0
0
10
20
30
INTVCC LOAD (mA)
40
50
3862 F02
Figure 2. INTVCC LDO Dropout Voltage vs Current
3862fb
14
LTC3862
OPERATION
Operation at High Supply Voltage
At high input voltages, the LTC3862’s internal LDO can
dissipate a significant amount of power, which could
cause the maximum junction temperature to be exceeded.
Conditions such as a high operating frequency, or the use
of more than one power MOSFET per channel, could push
the junction temperature rise to high levels. If the thermal
equations above indicate too high a rise in the junction
temperature, an external bias supply can always be used
to reduce the power dissipation on the IC, as shown in
Figure 3.
For example, a 5V or 12V system rail that is available
would be more suitable than the 24V main input power
rail to power the LTC3862. Also, the bias power can be
generated with a separate switching or LDO regulator. An
example of an LDO regulator is shown in Figure 3. The
output voltage of the LDO regulator can be set by selecting
an appropriate zener diode to be higher than 5V but low
enough to divide the power dissipation between LTC3862
and Q1 in Figure 3. The absolute maximum voltage rating
of the INTVCC pin is 6V.
R1
Q1
VIN
(OPT)
LTC3862
INTVCC
CVCC
If, however, the VIN supply to the IC comes up before the
INTVCC supply, the external INTVCC supply will act as a
load to the internal LDO in the LTC3862, and the LDO will
attempt to charge the INTVCC output with its short-circuit
current. This will result in excessive power dissipation and
possible thermal overload of the LTC3862.
If an independent 5V supply exists in the system, it may be
possible to short INTVCC and VIN together to 5V in order to
reduce gate drive power dissipation. With VIN and INTVCC
shorted together, the LDO output PMOS transistor is biased
at VDS = 0V, and the current demand of the internal analog
and digital control circuitry, as well as the gate drive current, will be supplied by the external 5V supply.
Programming the Output Voltage
The output voltage is set by a resistor divider according
to the following formula:
⎛ R2 ⎞
VOUT = 1.223V ⎜ 1+ ⎟
⎝ R1⎠
VIN
D1
flow from the external INTVCC supply, through the body
diode of the LDO PMOS device, to the input capacitor
and VIN pin. This high current flow could trigger a latchup
condition and cause catastrophic failure of the IC.
3862 F03
Figure 3. Using the LTC3862 with an External Bias Supply
The external resistor divider is connected to the output
as shown in Figure 4. Resistor R1 is normally chosen so
that the output voltage error caused by the current flowing
out of the VFB pin during normal operation is negligible
compared to the current in the divider. For an output voltage error due to the error amp input bias current of less
than 0.5%, this translates to a maximum value of R1 of
about 30k.
Power Supply Sequencing
As shown in Figure 1, there are body diodes in parallel
with the PMOS output transistors in the two LDO regulators in the LTC3862. As a result, it is not possible to bias
the INTVCC and VIN pins of the chip from separate power
supplies. Independently biasing the INTVCC pin from a
separate power supply can cause one of two possible
failure modes during supply sequencing. If the INTVCC
supply comes up before the VIN supply, high current will
VOUT
LTC3862
R2
FB
SGND
R1
3862 F04
Figure 4. Programming the Output Voltage
with a Resistor Divider
3862fb
15
LTC3862
OPERATION
Operation of the RUN Pin
VIN
The control circuitry in the LTC3862 is turned on and
off using the RUN pin. Pulling the RUN pin below 1.22V
forces shutdown mode and releasing it allows a 0.5μA
current source to pull this pin up, allowing a “normally
on” converter to be designed. Alternatively, the RUN pin
can be externally pulled up or driven directly by logic.
Care must be taken not to exceed the absolute maximum
rating of 8V for this pin.
The comparator on the RUN pin can also be used to sense
the input voltage, allowing an undervoltage detection
circuit to be designed. This is helpful in boost converter
applications where the input current can reach very high
levels at low input voltage:
LTC3862
INTERNAL 5V
0.5μA
4.5μA
RUN
+
10V
BIAS AND
START-UP
CONTROL
–
1.22V
RUN
COMPARATOR
SGND
3862 F05a
Figure 5a. Using the RUN Pin for a “Normally On” Converter
VIN
I
•V
IIN = OUT OUT
VIN • η
LTC3862
INTERNAL 5V
The 1.22V input threshold of the RUN comparator is derived
from a precise bandgap reference, in order to maximize
the accuracy of the undervoltage-sensing function. The
RUN comparator has 80mV built-in hysteresis. When
the voltage on the RUN pin exceeds 1.22V, the current
sourced into the RUN pin is switched from 0.5μA to 5μA
PTAT current. The user can therefore program both the
rising threshold and the amount of hysteresis using the
values of the resistors in the external divider, as shown in
the following equations:
EXTERNAL
LOGIC
CONTROL
10V
+
–
1.22V
BIAS AND
START-UP
CONTROL
RUN
COMPARATOR
SGND
3862 F05b
Figure 5b. On/Off Control Using External Logic
VIN
LTC3862
INTERNAL 5V
RA
0.5μA
B
Several of the possible RUN pin control techniques are
illustrated in Figure 5.
4.5μA
RUN
⎛ R ⎞
VIN(ON) = 1.22V ⎜ 1+ A ⎟ – 0.5μ • RA
⎝ RB ⎠
⎛ R ⎞
VIN(OFF ) = 1..22V ⎜ 1+ A ⎟ – 5μ • RA
⎝ R ⎠
0.5μA
4.5μA
RUN
RB
10V
+
1.22V
–
BIAS AND
START-UP
CONTROL
RUN
COMPARATOR
SGND
Frequency Selection and the Phase Lock Loop
3862 F05c
The selection of the switching frequency is a tradeoff
between efficiency and component size. Low frequency
operation increases efficiency by reducing MOSFET
switching losses, but requires a larger inductor and output
capacitor to maintain low output ripple.
Figure 5c. Programming the Input Voltage Turn-On and Turn-Off
Thresholds Using the RUN Pin
3862fb
16
LTC3862
OPERATION
The operating frequency of the LTC3862 can be approximated using the following formula:
1000
RFREQ (kΩ)
The LTC3862 uses a constant frequency architecture that
can be programmed over a 75kHz to 500kHz range using
a single resistor from the FREQ pin to ground. Figure 6
illustrates the relationship between the FREQ pin resistance
and the operating frequency.
100
RFREQ = 5.5096E9(fOSC)–0.9255
A phase-lock loop is available on the LTC3862 to synchronize the internal oscillator to an external clock source
connected to the SYNC pin. Connect a series RC network
from the PLLFLTR pin to SGND to compensate PLL’s
feedback loop. Typical compensation components are a
0.01μF capacitor in series with a 10k resistor. The PLLFLTR
pin is both the output of the phase detector and the input
to the voltage controlled oscillator (VCO). The LTC3862
phase detector adjusts the voltage on the PLLFLTR pin
to align the rising edge of GATE1 to the leading edge of
the external clock signal, as shown in Figure 7. The rising edge of GATE2 will depend upon the voltage on the
PHASEMODE pin. The capture range of the LTC3862’s PLL
is 50kHz to 650kHz.
Because the operating frequency of the LTC3862 can be
programmed using an external resistor, in synchronized
applications, it is recommended that the free-running frequency (as defined by the external resistor) be set to the
same value as the synchronized frequency. This results in
a start-up of the IC at approximately the same frequency
as the external clock, so that when the sync signal comes
alive, no discontinuity at the output will be observed. It also
ensures that the operating frequency remains essentially
constant in the event the sync signal is lost. The SYNC
pin has an internal 50k resistor to ground.
Using the CLKOUT and PHASEMODE Pins
in Multi-Phase Applications
The LTC3862 features two pins (CLKOUT and PHASEMODE)
that allow multiple ICs to be daisy-chained together for
higher current multi-phase applications. For a 3- or 4-phase
10
0 100 200 300 400 500 600 700 800 900 1000
FREQUENCY (kHz)
3862 F06
Figure 6. FREQ Pin Resistor Value vs Frequency
SYNC
10V/DIV
GATE1
10V/DIV
GATE2
10V/DIV
CLKOUT
10V/DIV
VIN = 12V
2μs/DIV
VOUT = 48V 1A
PHASEMODE = SGND
3862 F07
Figure 7. Synchronization of the LTC3862
to an External Clock Using the PLL
design, the CLKOUT signal of the master controller is connected to the SYNC input of the slave controller in order
to synchronize additional power stages for a single high
current output. The PHASEMODE pin is used to adjust the
phase relationship between channel 1 and channel 2, as well
as the phase relationship between channel 1 and CLKOUT,
as summarized in Table 1. The phases are calculated relative to the zero degrees, defined as the rising edge of the
GATE1 output. In a 6-phase application the CLKOUT pin
of the master controller connects to the SYNC input of the
2nd controller and the CLKOUT pin of the 2nd controller
connects to the SYNC pin of the 3rd controller.
3862fb
17
LTC3862
OPERATION
MASTER
Table 1
FREQ
PHASEMODE
CH-1 to CH-2
PHASE
CH-1 to CLKOUT
PHASE
APPLICATION
SGND
180°
90°
2-Phase, 4-Phase
Float
3V8
180°
120°
60°
240°
ON/OFF
CONTROL
RUN
LTC3862
FB
6-Phase
3-Phase
INTVCC
ITH
VOUT
SS
CLKOUT
INDIVIDUAL
INTVCC PINS
LOCALLY
DECOUPLED
SYNC
PLLFLTR
SGND
Using the LTC3862 Transconductance (gm) Error
Amplifier in Multi-Phase Applications
ALL RUN PINS
CONNNECTED
TOGETHER
SLAVE
The LTC3862 error amplifier is a transconductance, or gm
amplifier, meaning that it has high DC gain but high output
impedance (the output of the error amplifier is a current
proportional to the differential input voltage). This style
of error amplifier greatly eases the task of implementing
a multi-phase solution, because the amplifiers from two
or more chips can be connected in parallel. In this case
the FB pins of multiple LTC3862s can be connected together, as well as the ITH pins, as shown in Figure 8. The
gm of the composite error amplifier is simply n times the
transconductance of one amplifier, or gm(TOT) = n • 660μS,
where n is the number of amplifiers connected in parallel. The transfer function from the ITH pin to the current
comparator inputs was carefully designed to be accurate,
both from channel-to-channel and chip-to-chip. This way
the peak inductor current matching is kept accurate.
A buffered version of the output of the error amplifier
determines the threshold at the input of the current comparator. The ITH voltage that represents zero peak current
is 0.4V and the voltage that represents current limit is
1.2V (at low duty cycle). During an overload condition, the
output of the error amplifier is clamped to 2.6V at low duty
cycle, in order to reduce the latency when the overload
condition terminates. A patented circuit in the LTC3862 is
used to recover the slope compensation signal, so that the
maximum peak inductor current is not a strong function
of the duty cycle.
Soft-Start
The start-up of the LTC3862 is controlled by the voltage on
the SS pin. An internal PNP transistor clamps the current
comparator sense threshold during soft-start, thereby
limiting the peak switch current. The base of the PNP is
connected to the SS pin and the emitter to an internal,
INTVCC
FREQ
ALL ITH PINS
CONNECTED
TOGETHER
ITH
RUN
LTC3862
FB
SS
CLKOUT
ALL SS PINS
CONNNECTED
TOGETHER
SYNC
PLLFLTR
SGND
SLAVE
FREQ
INTVCC
RUN
ITH
ALL FB PINS
CONNECTED
TOGETHER
LTC3862
FB
SS
CLKOUT
SYNC
PLLFLTR
SGND
3862 F08
Figure 8. LTC3862 Error Amplifier Configuration
for Multi-Phase Operation
buffered ITH node (please note that the ITH pin voltage may
not track the soft-start voltage during this time period).
An internal 5μA current source charges the SS capacitor,
and clamps the peak sense threshold until the voltage on
the soft-start capacitor reaches approximately 0.6V. The
required amount of soft-start capacitance can be estimated
using the following equation:
⎛ t ⎞
CSS = 5μA ⎜ SS ⎟
⎝ 0.6 V ⎠
The SS pin has an internal open-drain NMOS pull-down
transistor that turns on when the RUN pin is pulled low,
when the voltage on the INTVCC pin is below its undervoltage
lockout threshold, or during an overtemperature condition. In multi-phase applications that use more than one
3862fb
18
LTC3862
OPERATION
LTC3862 chip, connect all of the SS pins together and use
one external capacitor to program the soft-start time. In
this case, the current into the soft-start capacitor will be
ISS = n • 5μA, where n is the number of SS pins connected
together. Figure 9 illustrates the start-up waveforms for a
2-phase LTC3862 application.
SW1
10V/DIV
SW2
10V/DIV
IL1
1A/DIV
IL2
1A/DIV
VIN = 17V
VOUT = 24V
LIGHT LOAD (10mA)
RUN
5V/DIV
IL1
5A/DIV
1μs/DIV
3862 F10
Figure 10. Light Load Switching Waveforms for
the LTC3862 at the Onset of Pulse Skipping
IL2
5A/DIV
VOUT
50V/DIV
VIN = 12V
VOUT = 48V
100Ω LOAD
1ms/DIV
3862 F09a
Figure 9. Typical Start-Up Waveforms for a
Boost Converter Using the LTC3862
Pulse Skip Operation at Light Load
As the load current is decreased, the controller enters
discontinuous mode (DCM). The peak inductor current can
be reduced until the minimum on-time of the controller
is reached. Any further decrease in the load current will
cause pulse skipping to occur, in order to maintain output
regulation, which is normal. The minimum on-time of
the controller in this mode is approximately 180ns (with
the blanking time set to its minimum value), the majority
of which is leading edge blanking. Figure 10 illustrates
the LTC3862 switching waveforms at the onset of pulse
skipping.
Programmable Slope Compensation
For a current mode boost regulator operating in CCM,
slope compensation must be added for duty cycles above
50%, in order to avoid sub-harmonic oscillation. For the
LTC3862, this ramp compensation is internal and user
adjustable. Having an internally fixed ramp compensation
waveform normally places some constraints on the value
of the inductor and the operating frequency. For example,
with a fixed amount of internal slope compensation, using
an excessively large inductor would result in too much
effective slope compensation, and the converter could
become unstable. Likewise, if too small an inductor were
used, the internal ramp compensation could be inadequate
to prevent sub-harmonic oscillation.
The LTC3862 contains a pin that allows the user to program
the slope compensation gain in order to optimize performance for a wider range of inductance. With the SLOPE
pin left floating, the normalized slope gain is 1.00. Connecting the SLOPE pin to ground reduces the normalized
gain to 0.625 and connecting this pin to the 3V8 supply
increases the normalized slope gain to 1.66.
With the normalized slope compensation gain set to 1.00,
the design equations assume an inductor ripple current of
20% to 40%, as with previous designs. Depending upon
the application circuit, however, a normalized gain of 1.00
may not be optimum for the inductor chosen. If the ripple
current in the inductor is greater than 40%, the normalized
slope gain can be increased to 1.66 (an increase of 66%)
by connecting the SLOPE pin to the 3V8 supply. If the
inductor ripple current is less than 20%, the normalized
slope gain can be reduced to 0.625 (a decrease of 37.5%)
by connecting the SLOPE pin to SGND.
To check the effectiveness of the slope compensation, apply
a load step to the output and monitor the cycle-by-cycle
behavior of the inductor current during the leading and
trailing edges of the load current. Vary the input voltage
over its full range and check for signs of cycle-by-cycle
SW node instability or sub-harmonic oscillation. When
3862fb
19
LTC3862
OPERATION
the slope compensation is too low the converter can
suffer from excessive jitter or, worst case, sub-harmonic
oscillation. When excess slope compensation is applied to
the internal current sense signal, the phase margin of the
control loop suffers. Figure 11 illustrates inductor current
waveforms for a properly compensated loop.
The LTC3862 contains a patented circuit whereby most
of the applied slope compensation is recovered, in order
to provide a SENSE+ to SENSE– threshold which is not
a strong function of the duty cycle. This sense threshold
is, however, a function of the programmed slope gain, as
shown in Figure 12. The data sheet typical specification of
75mV for SENSE+ minus SENSE– is measured at a normalized slope gain of 1.00 at low duty cycle. For applications
where the normalized slope gain is not 1.00, use Figure 12
to determine the correct value of the sense resistor.
ILOAD
2A/DIV
200mA-3A
IL1
2A/DIV
IL2
2A/DIV
VOUT
2V/DIV
VIN = 24V
VOUT = 48V
3862 F11
10μs/DIV
MAXIMUM CURRENT SENSE THRESHOLD (mV)
Figure 11. Inductor Current Waveforms for a
Properly Compensated Control Loop
80
SLOPE = 0.625
75
70
SLOPE = 1
SLOPE = 1.66
65
60
55
50
0
10 20 30 40 50 60 70 80 90 100
DUTY CYCLE (%)
3862 F12
Programmable Blanking and the Minimum On-Time
The BLANK pin on the LTC3862 allows the user to program
the amount of leading edge blanking at the SENSE pins.
Connecting the BLANK pin to SGND results in a minimum
on-time of 180ns, floating the pin increases this time to
260ns, and connecting the BLANK pin to the 3V8 supply
results in a minimum on-time of 340ns. The majority
of the minimum on-time consists of this leading edge
blanking, due to the inherently low propagation delay
of the current comparator (25ns typ) and logic circuitry
(10ns to 15ns).
The purpose of leading edge blanking is to filter out noise on
the SENSE pins at the leading edge of the power MOSFET
turn-on. During the turn-on of the power MOSFET the gate
drive current, the discharge of any parasitic capacitance
on the SW node, the recovery of the boost diode charge,
and parasitic series inductance in the high di/dt path all
contribute to overshoot and high frequency noise that
could cause false-tripping of the current comparator. Due
to the wide range of applications the LTC3862 is well-suited
to, fixing one value of the internal leading edge blanking
time would have required the longest delay time to have
been used. Providing a means to program the blank time
allows users to optimize the SENSE pin filtering for each
application. Figure 13 illustrates the effect of the programmable leading edge blank time on the minimum on-time
of a boost converter.
Programmable Maximum Duty Cycle
In order to maintain constant frequency and a low output
ripple voltage, a single-ended boost (or flyback or SEPIC)
converter is required to turn off the switch every cycle
for some minimum amount of time. This off-time allows
the transfer of energy from the inductor to the output
capacitor and load, and prevents excessive ripple current
and voltage. For inductor-based topologies like boost and
SEPIC converters, having a maximum duty cycle as close
as possible to 100% may be desirable, especially in low
VIN to high VOUT applications. However, for transformerbased solutions, having a maximum duty cycle near 100%
is undesirable, due to the need for V • sec reset during the
primary switch off-time.
Figure 12. Effect of Slope Gain on the Peak SENSE Threshold
3862fb
20
LTC3862
OPERATION
96% MAXIMUM DUTY CYCLE WITH DMAX = SGND
MINIMUM ON-TIME AT LIGHT LOAD WITH BLANK = SGND
INDUCTOR
CURRENT
1A/DIV
SW NODE
10V/DIV
GATE
2V/DIV
INDUCTOR
CURRENT
2A/DIV
SW NODE
20V/DIV
200ns/DIV
VIN = 30V
VOUT = 48V
MEASURED ON-TIME = 180ns
1μs/DIV
84% MAXIMUM DUTY CYCLE WITH DMAX = FLOAT
MINIMUM ON-TIME AT LIGHT LOAD WITH BLANK = FLOAT
INDUCTOR
CURRENT
1A/DIV
SW NODE
10V/DIV
GATE
2V/DIV
INDUCTOR
CURRENT
2A/DIV
SW NODE
20V/DIV
VIN = 30V
200ns/DIV
VOUT = 48V
MEASURED ON-TIME = 260ns
1μs/DIV
75% MAXIMUM DUTY CYCLE WITH DMAX = 3V8
MINIMUM ON-TIME AT LIGHT LOAD WITH BLANK = 3V8
INDUCTOR
CURRENT
1A/DIV
SW NODE
10V/DIV
GATE
2V/DIV
INDUCTOR
CURRENT
2A/DIV
SW NODE
20V/DIV
VIN = 30V
200ns/DIV
VOUT = 48V
MEASURED ON-TIME = 340ns
3862 F13
Figure 13. Leading Edge Blanking Effects
on the Minimum On-Time
In order to satisfy these different applications requirements, the LTC3862 has a simple way to program the
maximum duty cycle. Connecting the DMAX pin to SGND
limits the maximum duty cycle to 96%. Floating this pin
limits the duty cycle to 84% and connecting the DMAX pin
to the 3V8 supply limits it to 75%. Figure 14 illustrates
the effect of limiting the maximum duty cycle on the SW
node waveform of a boost converter.
1μs/DIV
3862 F14
Figure 14. SW Node Waveforms with Different Duty Cycle Limits
The LTC3862 contains an oscillator that runs at a multiple
of the switching frequency, in order to provide for 2-, 3-,
4-, 6- and 12-phase operation. A digital counter is used
to divide down the fundamental oscillator frequency in
order to obtain the operating frequency of the gate drivers.
Since the maximum duty cycle limit is obtained from this
digital counter, the percentage maximum duty cycle does
not vary with process tolerances or temperature.
3862fb
21
LTC3862
OPERATION
The SENSE+ and SENSE– Pins
The SENSE+ and SENSE– pins are high impedance inputs
to the CMOS current comparators for each channel.
Nominally, there is no DC current into or out of these
pins. There are ESD protection diodes connected from
these pins to SGND, although even at hot temperature the
leakage current into the SENSE+ and SENSE– pins should
be less than 1μA.
Since the LTC3862 contains leading edge blanking, an
external RC filter is not required for proper operation.
However, if an external filter is used, the filter components
should be placed close to the SENSE+ and SENSE– pins on
the IC, as shown in Figure 15. The positive and negative
sense node traces should then run parallel to each other
to a Kelvin connection underneath the sense resistor, as
shown in Figure 16. Sensing current elsewhere on the
board can add parasitic inductance and capacitance to
the current sense element, degrading the information
at the sense pins and making the programmed current
limit unpredictable. Avoid the temptation to connect the
SENSE– line to the ground plane using a PCB via; this
could result in unpredictable behavior.
The sense resistor should be connected to the source
of the power MOSFET and the ground node using short,
wide PCB traces, as shown in Figure 16. Ideally, the bottom terminal of the sense resistors will be immediately
VIN
adjacent to the negative terminal of the output capacitor,
since this path is a part of the high di/dt loop formed by
the switch, boost diode, output capacitor and sense resistor. Placement of the inductors is less critical, since the
current in the inductors is a triangle waveform.
Checking the Load Transient Response
The regulator loop response can be checked by looking at
the load current transient response. Switching regulators
take several cycles to respond to a step in DC (resistive)
load current. When a load step occurs, VOUT shifts by an
amount equal to ΔILOAD (ESR), where ESR is the effective
series resistance of COUT . ΔILOAD also begins to charge or
discharge COUT , generating the feedback error signal that
forces the regulator to adapt to the current change and
return VOUT to its steady-state value. During this recovery
time VOUT can be monitored for excessive overshoot or
ringing, which would indicate a stability problem.
The availability of the ITH pin not only allows optimization
of control loop behavior but also provides a DC-coupled
and AC-filtered closed-loop response test point. The DC
step, rise time and settling at this test point truly reflects the
closed-loop response. Assuming a predominantly second
order system, phase margin and/or damping factor can be
estimated using the percentage of overshoot seen at this
pin. The bandwidth can also be estimated by examining
the rise time at the pin.
VIN
MOSFET SOURCE
INTVCC
LTC3862
VOUT
GATE
SENSE+
RSENSE
RSENSE
SENSE–
PGND
3862 F15
FILTER COMPONENTS
PLACED NEAR
SENSE PINS
Figure 15. Proper Current Sense Filter Component Placement
TO SENSE
FILTER NEXT
TO CONTROLLER
3862 F16
GND
Figure 16. Connecting the SENSE+ and SENSE– Traces to the
Sense Resistor Using a Kelvin Connection
3862fb
22
LTC3862
OPERATION
The ITH series RC • CC filter sets the dominant pole-zero
loop compensation. The transfer function for boost and
flyback converters contains a right half plane zero that
normally requires the loop crossover frequency to be
reduced significantly in order to maintain good phase
margin. The RC • CC filter values can typically be modified
slightly (from 0.5 to 2 times their suggested values) to
optimize transient response once the final PC layout is done
and the particular output capacitor type(s) and value(s)
have been determined. The output capacitor configuration
needs to be selected in advance because the effective ESR
and bulk capacitance have a significant effect on the loop
gain and phase. An output current pulse of 20% to 80%
of full-load current having a rise time of 1μs to 10μs will
produce output voltage and ITH pin waveforms that will
give a sense of the overall loop stability without breaking
the feedback loop. Placing a power MOSFET and load
resistor directly across the output capacitor and driving
the gate with an appropriate signal generator is a practical way to produce a fast load step condition. The initial
output voltage step resulting from the step change in the
output current may not be within the bandwidth of the
feedback loop, so this signal cannot be used to determine
phase margin. This is why it is better to look at the ITH
pin signal which is in the feedback loop and is the filtered
and compensated control loop response. The gain of the
loop will be increased by increasing RC and the bandwidth
of the loop will be increased by decreasing CC. If RC is
increased by the same factor that CC is decreased, the
zero frequency will be kept the same, thereby keeping the
phase shift the same in the most critical frequency range
of the feedback loop. The output voltage settling behavior
is related to the stability of the closed-loop system and
will demonstrate the actual overall supply performance.
Figure 17 illustrates the load step response of a properly
compensated boost converter.
ILOAD
5A/DIV
1A TO 5A
IL1
5A/DIV
IL2
5A/DIV
VOUT
500mV/DIV
VIN = 24V
VOUT = 48V
500μs/DIV
3862 F17
Figure 17. Load Step Response of a Properly
Compensated Boost Converter
3862fb
23
LTC3862
APPLICATIONS INFORMATION
Typical Boost Applications Circuit
Minimum On-Time Limitations
A basic 2-phase, single output LTC3862 application circuit is
shown in Figure 18. External component selection is driven
by the characteristics of the load and the input supply.
In a single-ended boost converter, two steady-state conditions can result in operation at the minimum on-time of
the controller. The first condition is when the input voltage
is close to the output voltage. When VIN approaches VOUT
the voltage across the inductor approaches zero during
the switch off-time. Under this operating condition the
converter can become unstable and the output can experience high ripple voltage oscillation at audible frequencies.
For applications where the input voltage can approach
or exceed the output voltage, consider using a SEPIC or
buck-boost topology instead of a boost converter.
Duty Cycle Considerations
For a boost converter operating in a continuous conduction
mode (CCM), the duty cycle of the main switch is:
⎛V +V –V ⎞
D = ⎜ O F IN ⎟ = tON • f
⎝ VO + VF ⎠
where VF is the forward voltage of the boost diode. The
minimum on-time for a given application operating in
CCM is:
1⎛ VO + VF – VIN(MAX ) ⎞
tON(MIN) = ⎜
⎟
f⎝
VO + VF
⎠
For a given input voltage range and output voltage, it is
important to know how close the minimum on-time of the
application comes to the minimum on-time of the control
IC. The LTC3862 minimum on-time can be programmed
from 180ns to 340ns using the BLANK pin.
The second condition that can result in operation at the
minimum on-time of the controller is at light load, in deep
discontinuous mode. As the load current is decreased,
the on-time of the switch decreases, until the minimum
on-time limit of the controller is reached. Any further decrease in the output current will result in pulse skipping,
a typically benign condition where cycles are skipped in
order to maintain output regulation.
VIN
5V TO 36V
L1
19.4μH
PA2020-193
D1
PDS760
1nF
3V8
SENSE1+
SLOPE
BLANK
10nF
LTC3862
68.1k
ITH
FB
100pF
24.9k
84.5k
1μF
SS
12.4k
SGND
+
RUN
FREQ
10nF
0.006Ω
100μF
1W
63V
10nF
PHASEMODE SENSE1–
66.5k
Q1
HAT2266H
10Ω
6.8μF 50V
6.8μF 50V
6.8μF 50V
VIN
INTVCC
GATE1
PGND
10Ω
VOUT
48V
2A TO 5A
6.8μF 50V
6.8μF 50V
6.8μF 50V
10nF
SENSE2+
0.006Ω
1W
Q2
HAT2266H
GATE2
SENSE2–
CLKOUT
SYNC
PLLFLTR
100μF 6.8μF 50V
63V
4.7μF
475k
VOUT
+
DMAX
L2
19.4μH
PA2020-193
D2
PDS760
3862 F18
Figure 18. A Typical 2-Phase, Single Output Boost Converter Application Circuit
3862fb
24
LTC3862
APPLICATIONS INFORMATION
Maximum Duty Cycle Limitations
Another operating extreme occurs at high duty cycle,
when the input voltage is low and the output voltage is
high. In this case:
⎛ VO + VF – VIN(MIN) ⎞
DMAX = ⎜
⎟
VO + VF
⎝
⎠
A single-ended boost converter needs a minimum off-time
every cycle in order to allow energy transfer from the input
inductor to the output capacitor. This minimum off-time
translates to a maximum duty cycle for the converter. The
equation above can be rearranged to obtain the maximum
output voltage for a given minimum input or maximum
duty cycle.
VO(MAX ) =
VIN
– VF
1 – DMAX
The equation for DMAX above can be used as an initial
guideline for determining the maximum duty cycle of
the application circuit. However, losses in the inductor,
input and output capacitors, the power MOSFETs, the
sense resistors and the controller (gate drive losses) all
contribute to an increasing of the duty cycle. The effect
of these losses will be to decrease the maximum output
voltage for a given minimum input voltage.
After the initial calculations have been completed for an
application circuit, it is important to build a prototype of
the circuit and measure it over the entire input voltage
range, from light load to full load, and over temperature,
in order to verify proper operation of the circuit.
Peak and Average Input Currents
The control circuit in the LTC3862 measures the input
current (by means of resistors in the sources of the power
MOSFETs), so the output current needs to be reflected back
to the input in order to dimension the power MOSFETs
properly. Based on the fact that, ideally, the output power
is equal to the input power, the maximum average input
current is:
IIN(MAX ) =
IO(MAX )
1 – DMAX
The peak current in each inductor is:
IIN(PK ) =
1 ⎛ χ ⎞ IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠ 1 – DMAX
where n represents the number of phases and χ represents
the percentage peak-to-peak ripple current in the inductor.
For example, if the design goal is to have 30% ripple current in the inductor, then χ = 0.30, and the peak current
is 15% greater than the average.
Inductor Selection
Given an input voltage range, operating frequency and
ripple current, the inductor value can be determined using
the following equation:
L=
VIN(MIN)
ΔIL • f
• DMAX
where:
ΔIL =
χ IO(MAX )
•
n 1 – DMAX
Choosing a larger value of ΔIL allows the use of a lower
value inductor but results in higher output voltage ripple,
greater core losses, and higher ripple current ratings for
the input and output capacitors. A reasonable starting point
is 30% ripple current in the inductor (χ = 0.3), or:
ΔIL =
0.3 IO(MAX )
•
n 1 – DMAX
3862fb
25
LTC3862
APPLICATIONS INFORMATION
The inductor saturation current rating needs to be higher
than the worst-case peak inductor current during an
overload condition. If IO(MAX) is the maximum rated load
current, then the maximum current limit value (IO(CL))
would normally be chosen to be some factor (e.g., 30%)
greater than IO(MAX).
IO(CL) = 1.3 • IO(MAX)
Reflecting this back to the input, where the current is being
measured, and accounting for the ripple current, gives a
minimum saturation current rating for the inductor of:
IL(SAT) ≥
1 ⎛ χ ⎞ 1.3 • IO(MAX )
• 1+
•
1 – DMAX
n ⎜⎝ 2 ⎟⎠
The saturation current rating for the inductor should be
determined at the minimum input voltage (which results
in the highest duty cycle and maximum input current),
maximum output current and the maximum expected core
temperature. The saturation current ratings for most commercially available inductors drop at high temperature. To
verify safe operation, it is a good idea to characterize the
inductor’s core/winding temperature under the following
conditions: 1) worst-case operating conditions, 2) maximum allowable ambient temperature and 3) with the power
supply mounted in the final enclosure. Thermal characterization can be done by placing a thermocouple in intimate
contact with the winding/core structure, or by burying the
thermocouple within the windings themselves.
Remember that a single-ended boost converter is not
short-circuit protected, and that under a shorted output
condition, the output current is limited only by the input
supply capability. For applications requiring a step-up
converter that is short-circuit protected, consider using
a SEPIC or forward converter topology.
and thermal resistances RTH(JA) and RTH(JC)—both junction-to-ambient and junction-to-case.
The gate driver for the LTC3862 consists of PMOS pull-up
and NMOS pull-down devices, allowing the full INTVCC
voltage to be applied to the gates during power MOSFET
switching. Nonetheless, care must be taken to ensure
that the minimum gate drive voltage is still sufficient to
full enhance the power MOSFET. Check the MOSFET data
sheet carefully to verify that the RDS(ON) of the MOSFET
is specified for a voltage less than or equal to the nominal
INTVCC voltage of 5V. For applications that require a power
MOSFET rated at 6V or 10V, please refer to the LTC3862-1
data sheet.
Also pay close attention to the BVDSS specifications for
the MOSFETs relative to the maximum actual switch voltage in the application. Check the switching waveforms of
the MOSFET directly on the drain terminal using a single
probe and a high bandwidth oscilloscope. Ensure that the
drain voltage ringing does not approach the BVDSS of the
MOSFET. Excessive ringing at high frequency is normally
an indicator of too much series inductance in the high di/dt
current path that includes the MOSFET, the boost diode,
the output capacitor, the sense resistor and the PCB traces
connecting these components. In some challenging applications it may be necessary to use a snubber in order
to limit the switch node dV/dt.
Finally, check the MOSFET manufacturer’s data sheet for
an avalanche energy rating (EAS). Some MOSFETs are not
rated for body diode avalanche and will fail catastrophically if the VDS exceeds the device BVDSS, even if only by
a fraction of a volt. Avalanche-rated MOSFETs are better
able to sustain high frequency drain-to-source ringing near
the device BVDSS during the turn-off transition.
Power MOSFET Selection
Calculating Power MOSFET Switching and Conduction
Losses and Junction Temperatures
The peak-to-peak gate drive level is set by the INTVCC voltage is 5V for the LTC3862 under normal operating conditions. Selection criteria for the power MOSFETs include
the RDS(ON), gate charge QG, drain-to-source breakdown
voltage BVDSS, maximum continuous drain current ID(MAX),
In order to calculate the junction temperature of the power
MOSFET, the power dissipated by the device must be known.
This power dissipation is a function of the duty cycle, the
load current and the junction temperature itself (due to
the positive temperature coefficient of its RDS(ON)). As a
3862fb
26
LTC3862
APPLICATIONS INFORMATION
result, some iterative calculation is normally required to
determine a reasonably accurate value.
The power dissipated by the MOSFET in a multi-phase
boost converter with n phases is:
2
⎛ IO(MAX ) ⎞
PFET = ⎜
⎟ • RDS(ON) • DMAX • ρT
⎝ n • 1 – DMAX ⎠
(
)
+ k • VOUT2 •
IO(MAX )
(
n • 1 – DMAX
)
• CRSS • f
The first term in the equation above represents the I2R
losses in the device, and the second term, the switching
losses. The constant, k = 1.7, is an empirical factor inversely
related to the gate drive current and has the dimension
of 1/current.
The ρT term accounts for the temperature coefficient of
the RDS(ON) of the MOSFET, which is typically 0.4%/ºC.
Figure 19 illustrates the variation of normalized RDS(ON)
over temperature for a typical power MOSFET.
From a known power dissipated in the power MOSFET, its
junction temperature can be obtained using the following
formula:
TJ = TA + PFET • RTH(JA)
1.5
1.0
0.5
0
–50
It is tempting to choose a power MOSFET with a very low
RDS(ON) in order to reduce conduction losses. In doing
so, however, the gate charge QG is usually significantly
higher, which increases switching and gate drive losses.
Since the switching losses increase with the square of
the output voltage, applications with a low output voltage
generally have higher MOSFET conduction losses, and
high output voltage applications generally have higher
MOSFET switching losses. At high output voltages, the
highest efficiency is usually obtained by using a MOSFET
with a higher RDS(ON) and lower QG. The equation above
can easily be split into two components (conduction and
switching) and entered into a spreadsheet, in order to
compare the performance of different MOSFETs.
Programming the Current Limit
The peak sense voltage threshold for the LTC3862 is 75mV
at low duty cycle and with a normalized slope gain of
1.00, and is measured from SENSE+ to SENSE–. Figure 20
illustrates the change in the sense threshold with varying
duty cycle and slope gain.
MAXIMUM CURRENT SENSE THRESHOLD (mV)
RT NORMALIZED ON RESISTANCE
2.0
The RTH(JA) to be used in this equation normally includes
the RTH(JC) for the device plus the thermal resistance from
the case to the ambient temperature (RTH(CA)). This value
of TJ can then be compared to the original, assumed value
used in the iterative calculation process.
50
100
0
JUNCTION TEMPERATURE (°C)
150
3862 F19
Figure 19. Normalized Power MOSFET RDS(ON) vs Temperature
80
SLOPE = 0.625
75
70
SLOPE = 1
SLOPE = 1.66
65
60
55
50
0
10 20 30 40 50 60 70 80 90 100
DUTY CYCLE (%)
3862 F20
Figure 20. Maximum Sense Voltage Variation
with Duty Cycle and Slope Gain
3862fb
27
LTC3862
APPLICATIONS INFORMATION
For a boost converter where the current limit value is
chosen to be 30% higher than the maximum load current,
the peak current in the MOSFET and sense resistor is:
ISW(MAX ) = IR(SENSE) =
1 ⎛ χ ⎞ 1.3 • IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠
1 – DMAX
The sense resistor value is then:
RSENSE =
(
VSENSE(MAX ) • n • 1 – DMAX
⎛ χ⎞
1.3 • ⎜ 1+ ⎟ • IO(MAX )
⎝ 2⎠
)
Again, the factor n is the number of phases used, and χ
represents the percentage ripple current in the inductor.
The number 1.3 represents the factor by which the current limit exceeds the maximum load current, IO(MAX).
For example, if the current limit needs to exceed the
maximum load current by 50%, then the 1.3 factor should
be replaced with 1.5.
The average power dissipated in the sense resistor can
easily be calculated as:
2
⎛ 1.3 • IO(MAX ) ⎞
PR(SENSE) = ⎜
⎟ • RSENSE • DMAX
⎝ n • 1 – DMAX ⎠
(
)
This equation assumes no temperature coefficient for
the sense resistor. If the resistor chosen has a significant
temperature coefficient, then substitute the worst-case
high resistance value into the equation.
The resistor temperature can be calculated using the
equation:
TD = TA + PR(SENSE) • RTH(JA)
Selecting the Output Diodes
To maximize efficiency, a fast switching diode with low
forward drop and low reverse leakage is required. The
output diode in a boost converter conducts current during
the switch off-time. The peak reverse voltage that the diode
must withstand is equal to the regulator output voltage.
The average forward current in normal operation is equal
to the output current, and the peak current is equal to the
peak inductor current:
ID(PEAK ) =
1 ⎛ χ ⎞ IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠ 1 – DMAX
Although the average diode current is equal to the output
current, in very high duty cycle applications (low VIN to
high VOUT) the peak diode current can be several times
higher than the average, as shown in Figure 21. In this
case check the diode manufacturer’s data sheet to ensure
that its peak current rating exceeds the peak current in
the equation above. In addition, when calculating the
power dissipation in the diode, use the value of the
forward voltage (VF) measured at the peak current, not
the average output current. Excess power will be dissipated in the series resistance of the diode, which would
not be accounted for if the average output current and
forward voltage were used in the equations. Finally, this
SW NODE
10V/DIV
INDUCTOR
CURRENT
2A/DIV
DIODE
CURRENT
2A/DIV
VIN = 6V
VOUT = 24V
1μs/DIV
3862 F21
Figure 21. Diode Current Waveform for a
High Duty Cycle Application
3862fb
28
LTC3862
APPLICATIONS INFORMATION
additional power dissipation is important when deciding
on a diode current rating, package type, and method of
heat sinking.
To a close approximation, the power dissipated by the
diode is:
PD = ID(PEAK) • VF(PEAK) • (1 – DMAX)
The diode junction temperature is:
TJ = TA + PD • RTH(JA)
The RTH(JA) to be used in this equation normally includes
the RTH(JC) for the device plus the thermal resistance from
the board to the ambient temperature in the enclosure.
Once the proper diode has been selected and the circuit
performance has been verified, measure the temperature
of the power components using a thermal probe or infrared
camera over all operating conditions to ensure a good
thermal design.
Finally, remember to keep the diode lead lengths short
and to observe proper switch-node layout (see Board
Layout Checklist) to avoid excessive ringing and increased
dissipation.
ripple waveform are illustrated in Figure 22 for a typical
boost converter.
The choice of component(s) begins with the maximum
acceptable ripple voltage (expressed as a percentage of
the output voltage), and how this ripple should be divided
between the ESR step and the charging/discharging ΔV.
For the purpose of simplicity we will choose 2% for the
maximum output ripple, to be divided equally between the
ESR step and the charging/discharging ΔV. This percentage
ripple will change, depending on the requirements of the
application, and the equations provided below can easily
be modified.
One of the key benefits of multi-phase operation is a reduction in the peak current supplied to the output capacitor
by the boost diodes. As a result, the ESR requirement
of the capacitor is relaxed. For a 1% contribution to the
total ripple voltage, the ESR of the output capacitor can
be determined using the following equation:
ESRCOUT ≤
0.01 • VOUT
ID(PEAK )
where:
Output Capacitor Selection
Contributions of ESR (equivalent series resistance), ESL
(equivalent series inductance) and the bulk capacitance
must be considered when choosing the correct combination
of output capacitors for a boost converter application. The
effects of these three parameters on the output voltage
ID(PEAK ) =
1 ⎛ χ ⎞ IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠ 1 – DMAX
The factor n represents the number of phases and the factor
χ represents the percentage inductor ripple current.
SW1
50V/DIV
SW2
50V/DIV
IL1 2A/DIV
IL2 2A/DIV
VOUT
50mV/DIV
AC COUPLED
VIN = 10V
VOUT = 48V
500mA LOAD
1μs/DIV
3862 F22
Figure 22. Switching Waveforms for a Boost Converter
3862fb
29
LTC3862
APPLICATIONS INFORMATION
For the bulk capacitance, which we assume contributes
1% to the total output ripple, the minimum required capacitance is approximately:
COUT ≥
IO(MAX )
0.01 • n • VOUT • f
For many designs it will be necessary to use one type of
capacitor to obtain the required ESR, and another type
to satisfy the bulk capacitance. For example, using a
low ESR ceramic capacitor can minimize the ESR step,
while an electrolytic capacitor can be used to supply the
required bulk C.
The voltage rating of the output capacitor must be greater
than the maximum output voltage, with sufficient derating
to account for the maximum capacitor temperature.
IORIPPLE/IOUT
Because the ripple current in the output capacitor is a
square wave, the ripple current requirements for this
capacitor depend on the duty cycle, the number of phases
and the maximum output current. Figure 23 illustrates the
normalized output capacitor ripple current as a function of
duty cycle. In order to choose a ripple current rating for
the output capacitor, first establish the duty cycle range,
based on the output voltage and range of input voltage.
Referring to Figure 23, choose the worst-case high normalized ripple current, as a percentage of the maximum
load current.
3.25
3.00
2.75
2.50
2.25
2.00
1.75
1.50
1.25
1.00
0.75
0.50
0.25
0
0.1
The output ripple current is divided between the various
capacitors connected in parallel at the output voltage.
Although ceramic capacitors are generally known for low
ESR (especially X5R and X7R), these capacitors suffer
from a relatively high voltage coefficient. Therefore, it is
not safe to assume that the entire ripple current flows in
the ceramic capacitor. Aluminum electrolytic capacitors are
generally chosen because of their high bulk capacitance,
but they have a relatively high ESR. As a result, some
amount of ripple current will flow in this capacitor. If the
ripple current flowing into a capacitor exceeds its RMS
rating, the capacitor will heat up, reducing its effective
capacitance and adversely affecting its reliability. After
the output capacitor configuration has been determined
using the equations provided, measure the individual
capacitor case temperatures in order to verify good
thermal performance.
Input Capacitor Selection
The input capacitor voltage rating in a boost converter
should comfortably exceed the maximum input voltage.
Although ceramic capacitors can be relatively tolerant of
overvoltage conditions, aluminum electrolytic capacitors
are not. Be sure to characterize the input voltage for any
possible overvoltage transients that could apply excess
stress to the input capacitors.
1-PHASE
2-PHASE
0.2
0.3 0.4 0.5 0.6 0.7 0.8
DUTY CYCLE OR (1-VIN/VOUT)
0.9
3862 F23
Figure 23. Normalized Output Capacitor
Ripple Current (RMS) for a Boost Converter
3862fb
30
LTC3862
APPLICATIONS INFORMATION
The value of the input capacitor is a function of the
source impedance, and in general, the higher the source
impedance, the higher the required input capacitance.
The required amount of input capacitance is also greatly
affected by the duty cycle. High output current applications that also experience high duty cycles can place great
demands on the input supply, both in terms of DC current
and ripple current.
The input ripple current in a multi-phase boost converter
is relatively low (compared with the output ripple current),
because this current is continuous and is being divided
between two or more inductors. Nonetheless, significant
stress can be placed on the input capacitor, especially
in high duty cycle applications. Figure 24 illustrates the
normalized input ripple current, where:
INORM =
VIN
L•f
1. The duty cycle range (where 5A is available at the
output) is:
⎛V +V –V ⎞
DMAX = ⎜ O F IN ⎟
⎝ VO + VF ⎠
⎛ 48 V + 0.5V – 24V ⎞
= 50.5%
=⎜
⎝ 48 V + 0..5V ⎟⎠
2. The operating frequency is chosen to be 300kHz so
the period is 3.33μs. From Figure 6, the resistor from
the FREQ pin to ground is 45.3k.
0.90
0.80
0.70
$IIN/INORM
Consider the LTC3862 application circuit is shown in Figure 25a. The output voltage is 48V and the input voltage
range is 5V to 36V. The maximum output current is 5A
when the input voltage is 24V to 36V. Below 24V, current
limit will linearly reduce the maximum load to 1A at 5V
in (see Figure 25b).
⎛ 48 V + 0.5V – 36 V ⎞
= 25.8%
DMIN = ⎜
⎝ 48 V + 0.5V ⎟⎠
1.00
0.60
3. The minimum on-time for this application operating
in CCM is:
1-PHASE
0.50
0.40
1 ⎛ VO + VF – VIN(MAX ) ⎞
1
•
tON(MIN) = • ⎜
⎟=
f ⎝
VO + VF
⎠ 300kHz
2-PHASE
0.30
0.20
0.10
0
A Design Example
0
0.2
0.6
0.4
DUTY CYCLE
0.8
⎛ 48 V + 0.5V – 36 V ⎞
⎜⎝ 48 V + 0.5V ⎟⎠ = 859ns
1.0
3862 F24
Figure 24. Normalized Input Peak-to-Peak Ripple Current
The maximum DC input current is:
IIN(MAX ) =
IO(MAX )
1 – DMAX
=
5A
= 10.1A
1 – 0.505
3862fb
31
LTC3862
APPLICATIONS INFORMATION
VIN
5V TO 36V
L1
18.7μH
PB2020-223
D1
30BQ060
1nF
DMAX
3V8
SENSE1+
SLOPE
BLANK
LTC3862
ITH
FB
100pF
84.5k
1μF
SS
30.1k
24.9k
6.8μF 50V
6.8μF 50V
6.8μF 50V
VIN
100μF 10μF 50V
63V
4.7μF
INTVCC
12.4k
GATE1
PGND
SGND
0.008Ω
1W
10Ω
475k
VOUT
Q2
HAT2266H
GATE2
SENSE2–
CLKOUT
SYNC
PLLFLTR
VOUT
48V
5A (MAX)
+
10nF
+
RUN
FREQ
4.7nF
0.008Ω
100μF
1W
63V
10nF
PHASEMODE SENSE1–
45.3k
Q1
HAT2266H
10Ω
10μF 50V
10μF 50V
10μF 50V
10nF
SENSE2+
L2
18.7μH
PB2020-223
D2
30BQ060
3862 F25a
Figure 25a. A 5V to 36V Input, 48V/5A Output 2-Phase Boost Converter Application Circuit
5. The inductor ripple current is:
OUTPUT LOAD CURRENT (A)
6
5
ΔIL =
4
χ IO(MAX )
0.4
5A
•
=
•
= 2.02A
n 1 – DMAX
2 1 – 0.505
6. The inductor value is therefore:
3
2
L=
1
0
0
10
20
30
INPUT VOLTAGE (V)
40
3862 F25b
Figure 25b. Output Current vs Input Voltage
4. A ripple current of 40% is chosen so the peak current
in each inductor is:
IIN(PK ) =
=
1 ⎛ χ ⎞ IO(MAX )
• 1–
•
n ⎜⎝ 2 ⎟⎠ 1 – DMAX
1 ⎛ 0.4 ⎞
5A
•
= 6.06 A
• ⎜ 1+
⎟
2 ⎝
2 ⎠ 1 – 0.505
VIN(MIN)
ΔIL • f
• DMAX =
24V
• 0.505
2.02A • 300kHz
= 20μH
7. For a current limit value 30% higher than the maximum
load current:
IO(CL) = 1.3 • IO(MAX) = 1.3 • 5A = 6.5A
The saturation current rating of the inductors must
therefore exceed:
IL(SAT) ≥
=
1 ⎛ χ ⎞ 1.3 • IO(MAX )
• 1+
•
1 – DMAX
n ⎜⎝ 2 ⎟⎠
1 ⎛ 0.4 ⎞ 1.3 • 5A
•
= 7.9 A
• 1+
2 ⎜⎝
2 ⎟⎠ 1 – 0.505
3862fb
32
LTC3862
APPLICATIONS INFORMATION
The inductor value chosen was 18.7μH and the part
number is PB2020-223, manufactured by Pulse Engineering. This inductor has a saturation current rating
of 20A.
8. The power MOSFET chosen for this application is
a Renesas HAT2266H. This MOSFET has a typical
RDS(ON) of 11mΩ at VGS = 4.5V and 9.2mΩ at VGS
= 10V. The BVDSS is rated at a minimum of 60V and
the maximum continuous drain current is 30A. The
typical gate charge is 25nC for a VGS = 4.5V. Last but
not least, this MOSFET has an absolute maximum
avalanche energy rating EAS of 34mJ, indicating that it
is capable of avalanche without catastrophic failure.
9. The total IC quiescent current, IC power dissipation and
maximum junction temperature are approximately:
IQ(TOT) = IQ + 2 • QG(TOT) • f
= 3mA + 2 • 25nC • 300kHz = 18mA
PDISS = 24V • 18mA = 432mW
TJ = 70°C + 432mW • 34°C/W = 84.7°C
10. The inductor ripple current was chosen to be 40%
and the maximum load current is 5A. For a current
limit set at 30% above the maximum load current, the
maximum switch and sense resistor currents are:
ISW(MAX ) = IR(SENSE) =
=
1 ⎛ χ ⎞ 1.3 • IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠
1 – DMAX
1 ⎛ 0.4 ⎞ 1.3 • 5A
= 7.9 A
• 1+
•
2 ⎜⎝
2 ⎟⎠ 1 – 0.505
11. The maximum current sense threshold for the LTC3862
is 75mV at low duty cycle and a normalized slope gain
of 1.0. Using Figure 20, the maximum sense voltage
drops to 73mV at a duty cycle of 51% with a normalized slope gain of 1, so the sense resistor is calculated
to be:
RSENSE =
VSENSE(MAX )
ISW(MAX )
=
73mV
= 9.2mΩ
7.9 A
For this application a 8mΩ, 1W surface mount resistor
was used for each phase.
12. The power dissipated in the sense resistors in current
limit is:
2
⎛ 1.3 • IO(MAX ) ⎞
PR(SENSE) = ⎜
⎟ • RSENSE • DMAX
⎝ n • 1 – DMAX ⎠
(
)
2
⎛
⎞
1.3 • 5
=⎜
⎟ • 0.009 • 0.505
⎝ 2 • 1 – 0.505 ⎠
(
)
= 0.20 W
13. The average current in the boost diodes is half the
output current (5A/2 = 2.5A), but the peak current in
each diode is:
ID(PEAK ) =
=
1 ⎛ χ ⎞ IO(MAX )
• 1+
•
n ⎜⎝ 2 ⎟⎠ 1 – DMAX
1 ⎛ 0.4 ⎞
5A
= 6.06 A
• ⎜ 1+
•
⎟
2 ⎝
2 ⎠ 1 – 0.505
The diode chosen for this application is the 30BQ060,
manufactured by International Rectifier. This surface
mount diode has a maximum average forward current
of 3A at 125°C and a maximum reverse voltage of 60V.
The maximum forward voltage drop at 25°C is 0.65V
and is 0.42V at 125°C (the positive TC of the series
resistance is compensated by the negative TC of the
diode forward voltage).
The power dissipated by the diode is approximately:
PD = ID(PEAK) • VF(PEAK) • (1 – DMAX)
= 6.06A • 0.42V • (1 – 0.505) = 1.26W
14. Two types of output capacitors are connected in parallel for this application; a low ESR ceramic capacitor
and an aluminum electrolytic for bulk storage. For
a 1% contribution to the total ripple voltage, the
maximum ESR of the composite output capacitance
is approximately:
ESRCOUT ≤
0.01 • VOUT 0.01 • 48 V
=
= 0.109Ω
ID(PEAK )
4.4A
3862fb
33
LTC3862
APPLICATIONS INFORMATION
For the bulk capacitance, which we assume contributes
1% to the total output ripple, the minimum required
capacitance is approximately:
2. In order to help dissipate the power from the MOSFETs
and diodes, keep the ground plane on the layers closest
to the power components. Use power planes for the
MOSFETs and diodes in order to maximize the heat
IO(MAX )
5A
spreading from these components into the PCB.
COUT ≥
=
T
0.01 • n • VOUT • f 0.01 • 2 • 48 V • 300kHz
3. Place all power components in a tight area. This will
minimize the size of high current loops. The high di/dt
= 17.5μF
loops formed by the sense resistor, power MOSFET,
For this application, in order to obtain both low ESR
the boost diode and the output capacitor should be
and an adequate ripple current rating (see Figure 23),
kept as small as possible to avoid EMI.
two 100μF, 63V aluminum electrolytic capacitors were
4. Orient the input and output capacitors and current
connected in parallel with four 6.8μF, 50V ceramic
sense resistors in a way that minimizes the distance
capacitors. Figure 26 illustrates the switching wavebetween the pads connected to the ground plane.
forms for this application circuit.
Keep the capacitors for INTVCC, 3V8 and VIN as close
as possible to LTC3862.
SW1
50V/DIV
IL1
5A/DIV
5. Place the INTVCC decoupling capacitor as close as
possible to the INTVCC and PGND pins, on the same
layer as the IC. A low ESR (X5R or better) 4.7μF to
10μF ceramic capacitor should be used.
SW2
50V/DIV
IL2
5A/DIV
VOUT
100mV/DIV
AC COUPLED
6. Use a local via to ground plane for all pads that
connect to the ground. Use multiple vias for power
components.
VIN = 24V
VOUT = 48V, 1.5A
2.5μs/DIV
3862 F26
Figure 26. LTC3862 Switching Waveforms for Boost Converter
PC Board Layout Checklist
When laying out the printed circuit board, the following
checklist should be used to ensure proper operation of
the converter:
1. For lower power applications a 2-layer PC board is sufficient. However, for higher power levels, a multilayer
PC board is recommended. Using a solid ground plane
and proper component placement under the circuit is
the easiest way to ensure that switching noise does
not affect the operation.
7. Place the small-signal components away from high
frequency switching nodes on the board. The pinout
of the LTC3862 was carefully designed in order to
make component placement easy. All of the power
components can be placed on one side of the IC, away
from all of the small-signal components.
8. The exposed area on the bottom of the QFN package
is internally connected to PGND; however it should
not be used as the main path for high current flow.
9. The MOSFETs should also be placed on the same
layer of the board as the sense resistors. The MOSFET
source should connect to the sense resistor using a
short, wide PCB trace.
3862fb
34
LTC3862
APPLICATIONS INFORMATION
10. The output resistor divider should be located as
close as possible to the IC, with the bottom resistor
connected between FB and SGND. The PCB trace
connecting the top resistor to the upper terminal of
the output capacitor should avoid any high frequency
switching nodes.
14. Keep the MOSFET drain nodes (SW1, SW2) away
from sensitive small-signal nodes, especially from
the opposite channel’s current-sensing signals. The
SW nodes can have slew rates in excess of 1V/ns
relative to ground and should therefore be kept on
the “output side” of the LTC3862.
11. Since the inductor acts like a current source in a
peak current mode control topology, its placement
on the board is less critical than the high di/dt components.
15. Check the stress on the power MOSFETs by independently measuring the drain-to-source voltages directly
across the devices terminals. Beware of inductive
ringing that could exceed the maximum voltage rating
of the MOSFET. If this ringing cannot be avoided and
exceeds the maximum rating of the device, choose
a higher voltage rated MOSFET or consider using a
snubber.
12. The SENSE+ and SENSE– PCB traces should be routed
parallel to one another with minimum spacing in between all the way to the sense resistor. These traces
should avoid any high frequency switching nodes in
the layout. These PCB traces should also be Kelvinconnected to the interior of the sense resistor pads,
in order to avoid sensing errors due to parasitic PCB
resistance IR drops.
16. When synchronizing the LTC3862 to an external clock,
use a low impedance source such as a logic gate to
drive the SYNC pin and keep the lead as short as
possible.
13. If an external RC filter is used between the sense
resistor and the SENSE+ and SENSE– pins, these filter
components should be placed as close as possible to
the SENSE+ and SENSE– pins of the IC. Ensure that
the SENSE– line is connected to the ground only at the
point where the current sense resistor is grounded.
3862fb
35
LTC3862
TYPICAL APPLICATIONS
A 12V Input, 24V/5A Output 2-Phase Boost Converter Application Circuit
VIN
5V TO 24V
L1
4.2μH
CDEP145-4R2
D1
MBRD835L
1nF
DMAX
3V8
SENSE1+
SLOPE
BLANK
100k
22μF 25V
1μF
SS
ITH
FB
6.98k
SGND
22μF 25V
VIN
LTC3862
100pF
22μF 25V
+
10nF
26.7k
+
15k
RUN
FREQ
1nF
0.007Ω
100μF
1W
35V
10nF
PHASEMODE SENSE1–
45.3k
Q1
Si7386DP
10Ω
100μF 10μF 50V
35V
4.7μF
INTVCC
GATE1
PGND
130k
VOUT
10μF 50V
Q2
Si7386DP
GATE2
SENSE2–
CLKOUT
SYNC
PLLFLTR
10μF 50V
0.007Ω
1W
10Ω
VOUT
24V
5A (MAX)
10μF 50V
10nF
L2
4.2μH
CDEP145-4R2
SENSE2+
D2
MBRD835L
3862 TA02a
Start-Up
Load Step
ILOAD
5A/DIV
RUN
5V/DIV
IL1
5A/DIV
IL1
5A/DIV
IL2
5A/DIV
IL2
5A/DIV
VOUT
20V/DIV
VOUT
500mV/DIV
VIN = 12V
VOUT = 24V
ILOAD = 5A
3862 TA02b
1ms/DIV
VIN = 12V
VOUT = 24V
ILOAD = 2A TO 5A
500μs/DIV
3862 TA02c
Efficiency
100
10000
VIN = 12V
VOUT = 24V
95
EFFICIENCY (%)
1000
POWER LOSS
85
POWER LOSS (mW)
EFFICIENCY
90
80
75
100
1000
LOAD CURRENT (mA)
100
10000
3862 TA02d
3862fb
36
LTC3862
TYPICAL APPLICATIONS
A 4.5V to 5.5V Input, 12V/15A Output 4-Phase Boost Converter Application Circuit
VIN
4.5V TO 5.5V
L1
2.7μH
CDEP145-2R7
D1
MBRB2515LT41
1nF
3V8
BLANK
10nF
ON/OFF
CONTROL
FREQ
1μF
SS
10nF
33μF 10V
33μF 10V
RUN
10nF
LTC3862
3.83k
ITH
FB
330pF
0.005Ω
220μF
1W
16V
–
+
PHASEMODE SENSE1
45.3k
Q1
HAT2165H
10Ω
SENSE1+
SLOPE
33μF 10V
VIN
220μF 15μF 25V
16V
4.7μF
INTVCC
18.7k
GATE1
PGND
SGND
165k
VOUT
15μF 25V
0.005Ω
1W
10Ω
15μF 25V
Q3
HAT2165H
GATE2
15μF 25V
SENSE2–
CLKOUT
SYNC
PLLFLTR
VOUT
12V
15A
+
DMAX
10nF
L2
2.7μH
CDEP145-2R7
SENSE2+
L1
2.7μH
CDEP145-2R7
D2
MBRB2515LT41
D1
MBRB2515LT41
1nF
3V8
BLANK
–
+
RUN
FREQ
33μF 10V
33μF 10V
1μF
SS
330pF
0.005Ω
220μF
1W
16V
10nF
PHASEMODE SENSE1
45.3k
Q1
HAT2165H
10Ω
SENSE1+
SLOPE
LTC3862
ITH
FB
SGND
+
DMAX
33μF 10V
VIN
220μF 15μF 25V
16V
4.7μF
INTVCC
GATE1
PGND
15μF 25V
0.005Ω
1W
10Ω
15μF 25V
Q3
HAT2165H
GATE2
15μF 25V
SENSE2–
10nF
CLKOUT
SYNC
PLLFLTR
10k
10nF
L2
2.7μH
CDEP145-2R7
SENSE2+
D2
MBRB2515LT41
3862 TA03a
Start-Up
Efficiency
Load Step
100
VOUT
200mV/DIV
VIN = 5V
VOUT = 12V
RLOAD = 10Ω
1ms/DIV
3862 TA03b
100000
VIN = 5V
VOUT = 12V
90
EFFICIENCY (%)
VOUT
10V/DIV
VIN
5V/DIV
95
EFFICIENCY
10000
85
80
75
POWER LOSS
1000
POWER LOSS (mW)
IL1 MASTER
5A/DIV
IL2 MASTER
5A/DIV
IL1 SLAVE
5A/DIV
IL2 SLAVE
5A/DIV
ILOAD
2.5A-5A
5A DIV
IL1 MASTER
5A/DIV
IL2 MASTER
5A/DIV
IL1 SLAVE
5A/DIV
IL2 SLAVE
5A/DIV
70
65
VIN = 5V
VOUT = 12V
250μs/DIV
3862 TA03c
60
100
1000
10000
LOAD CURRENT (mA)
100
100000
3862 TA03d
3862fb
37
LTC3862
PACKAGE DESCRIPTION
FE Package
24-Lead Plastic TSSOP (4.4mm)
(Reference LTC DWG # 05-08-1663)
Exposed Pad Variation AA
7.70 – 7.90*
(.303 – .311)
3.25
(.128)
3.25
(.128)
24 23 22 21 20 19 18 17 16 15 14 13
6.60 p0.10
2.74
(.108)
4.50 p0.10
6.40
2.74 (.252)
(.108) BSC
SEE NOTE 4
0.45 p0.05
1.05 p0.10
0.65 BSC
1 2 3 4 5 6 7 8 9 10 11 12
RECOMMENDED SOLDER PAD LAYOUT
4.30 – 4.50*
(.169 – .177)
0.09 – 0.20
(.0035 – .0079)
0.25
REF
1.20
(.047)
MAX
0o – 8o
0.65
(.0256)
BSC
0.50 – 0.75
(.020 – .030)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
3. DRAWING NOT TO SCALE
0.05 – 0.15
(.002 – .006)
0.195 – 0.30
(.0077 – .0118)
TYP
FE24 (AA) TSSOP 0208 REV Ø
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
GN Package
24-Lead Plastic SSOP (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1641)
.337 – .344*
(8.560 – 8.738)
24 23 22 21 20 19 18 17 16 15 1413
.033
(0.838)
REF
.045 p.005
.229 – .244
(5.817 – 6.198)
.254 MIN
.150 – .157**
(3.810 – 3.988)
.150 – .165
1
.0165 p.0015
2 3
4
5 6
7
8
9 10 11 12
.0250 BSC
RECOMMENDED SOLDER PAD LAYOUT
.015 p .004
s 45o
(0.38 p 0.10)
.0075 – .0098
(0.19 – 0.25)
.0532 – .0688
(1.35 – 1.75)
.004 – .0098
(0.102 – 0.249)
0o – 8o TYP
.016 – .050
(0.406 – 1.270)
NOTE:
1. CONTROLLING DIMENSION: INCHES
INCHES
2. DIMENSIONS ARE IN
(MILLIMETERS)
3. DRAWING NOT TO SCALE
.008 – .012
(0.203 – 0.305)
TYP
.0250
(0.635)
BSC
GN24 (SSOP) 0204
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
3862fb
38
LTC3862
PACKAGE DESCRIPTION
UH Package
24-Lead Plastic QFN (5mm × 5mm)
(Reference LTC DWG # 05-08-1747 Rev A)
0.75 p0.05
5.40 p0.05
3.90 p0.05
3.20 p 0.05
3.25 REF
3.20 p 0.05
PACKAGE OUTLINE
0.30 p 0.05
0.65 BSC
RECOMMENDED SOLDER PAD LAYOUT
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
5.00 p 0.10
R = 0.05
TYP
0.75 p 0.05
BOTTOM VIEW—EXPOSED PAD
R = 0.150
TYP
23
0.00 – 0.05
PIN 1 NOTCH
R = 0.30 TYP
OR 0.35 s 45o
CHAMFER
24
0.55 p 0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
3.20 p 0.10
5.00 p 0.10
3.25 REF
3.20 p 0.10
(UH24) QFN 0708 REV A
0.200 REF
NOTE:
1. DRAWING IS NOT A JEDEC PACKAGE OUTLINE
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 0.20mm 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
0.30 p 0.05
0.65 BSC
3862fb
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
LTC3862
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1624
Current Mode DC/DC Controller
SO-8, 300kHz Operating Frequency, Buck, Boost, SEPIC Design,
VIN Up to 36V
LTC1700
No RSENSE™ Synchronous Step-Up Controller
Up to 95% Efficiency, Operating as Low as 0.9V Input
LTC1871/LTC1871-1 Wide Input Range, No RSENSE Current Mode Boost,
Flyback and SEPIC Controller
LTC1871-7
Programmable Frequency from 50kHz to 1MHz in MSOP-10 Package.
LT®1950
Wide Input Range Forward, Flyback, Boost or SEPIC Controller Suitable for
36V to 72V Inputs
Single Switch PWM Controller with Auxiliary Boost
Converter
LT1952/LT1952-1
Single Switch Synchronous Forward Controllers
Ideal for High Power 48V Input Applications
LTC3704
Positive-to-Negative DC/DC Controller
No RSENSE, Current Mode Control, 50kHz to 1MHz
LTC3706/LTC3705
Isolated Synchronous Forward Converter Chip Set
with PolyPhase® Capability
Ideal for High Power 48V Input Applications
LTC3726/LTC3725
Isolated Synchronous Forward Converter Chip Set
Ideal for High Power 48V Input Applications
LT3782A
2-Phase Step-Up DC/DC Controller
6V ≤ VIN ≤ 40V, 4A Gate Drive, 150kHz to 500kHz
LTC3803
LTC3803-3
LTC3803-5
Constant-Frequency Current Mode Flyback DC/DC
Controllers in ThinSOT™
Wide Input Range Flyback, Boost and SEPIC Controller. High Temperature
Grade Available
LTC3805
Adjustable Frequency Current Mode DC/DC Controller Wide Input Range Flyback, Boost and SEPIC Controller with Programmable
Frequency, Run and Soft-Start
LTC3806
Synchronous Flyback DC/DC Controller
Current Mode Flyback Controller with Synchronous Gate Drive
LTC3813
100V Current Mode Synchronous Step-Up Controller
Large 1Ω Gate Drivers, No Current Sense Resistor Required
LTC3814-5
60V Current Mode Synchronous Step-Up Controller
Large 1Ω Gate Drivers, No Current Sense Resistor Required
LT3825
Isolated No-OPTO Synchronous Flyback Controller
with Wide Input Supply Range
Input Voltage Limited Only by External Components, Ideal for 48V Input
Applications
LT3837
Isolated No-OPTO Synchronous Flyback Controller
Suitable for Industrial 9V to 36V Inputs
LTC3872
No RSENSE Current Mode Boost DC/DC Controller
550kHz Fixed Frequency, 2.75V ≤ VIN ≤ 9.8V, ThinSOT Package
LTC3873
LTC3873-5
No RSENSE Constant Frequency Current Mode
Flyback, Boost and SEPIC DC/DC Controllers
Programmable Soft-Start, Adjustable Current Limit, 2mm × 3mm DFN or
8-Lead TSOT-23 Packages
LTC3780
High Efficiency, Synchronous, 4-Switch Buck-Boost
Controller
VIN: 4V to 36V, VOUT : 0.8V to 30V, IQ = 1.5mA, ISD < 55μA, SSOP-24,
QFN-32 Packages
PolyPhase is a registrated treademark of Linear Technology Corporation. No RSENSE and ThinSOT are trademarks of Linear Technology Corporation.
3862fb
40 Linear Technology Corporation
LT 1208 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2008