LTC7851/LTC7851-1
Quad Output, Multiphase Step-Down Voltage Mode
DC/DC Controller with Accurate Current Sharing
FEATURES
DESCRIPTION
Operates with Power Blocks, DrMOS or External
Gate Drivers and MOSFETs
nn Voltage Mode Control with Accurate Current Sharing
nn ±0.75% 0.6V Voltage Reference
nn Quad Differential Output Voltage Sense Amplifiers
nn Multiphase Capability
nn Phase-Lockable Fixed Frequency 250kHz to 2.25MHz
nn Lossless Current Sensing Using Inductor DCR or
Precision Current Sensing with Sense Resistor or
DrMOS with Integrated Current Sensing
nn V
CC Range: 3V to 5.5V
nn V
OUT Range: 0.6V to VCC – 0.5V
nn Power Good Output Voltage Monitor
nn Output Voltage Tracking Capability with Soft-Start
nn Available in 58-Lead 5mm × 9mm QFN Package
The LTC®7851/LTC7851-1 are quad output multiphase synchronous step-down switching regulator controllers that
employ a constant frequency voltage mode architecture.
They maintain excellent current balance between channels
when paralleled with their internal current sharing loop.
Lossless DCR or a low value RSENSE is used for output
current sensing. Multiple LTC7851/LTC7851-1 devices can
be used for high phase count operation.
nn
APPLICATIONS
A very low offset, high bandwidth error amplifier, combined
with remote output voltage sensing, provides excellent
transient response and output regulation. The LTC7851/
LTC7851-1 operates with a VCC supply voltage from 3V to
5.5V and is designed for step-down conversion with VIN
from 3V to 27V* and produces an output voltage from
0.6V to VCC – 0.5V.
The LTC7851-1 is identical to the LTC7851 except it has
a lower current sense amplifier gain, making it ideal for
DrMOS devices with internal current sense.
High Current Distributed Power Systems
nn DSP, FPGA and ASIC Supplies
nn Datacom, Telecom and Computing Systems
nn
All registered trademarks and trademarks are the property of their respective owners. Protected
by U.S. Patents, including 6144194, 5055767.
*See Note 5.
TYPICAL APPLICATION
Dual-Output Converter: 1V/90A and 1.5V/30A with DrMOS
VIN
7V TO 14V
VINSNS
0.25µH
0.25µH
DrMOS
PWM3
3.57k
0.22µF
VOUT2
1.5V/30A
1µF
PINS NOT USED
IN THIS CIRCUIT:
CLKIN
CLKOUT
VSNSP2
VSNSP3
VSNSN2
VSNSN3
PGOOD2
PGOOD3
RUN4
IAVG4
TRACK/SS4
3.57k
0.22µF
ISNS2P
ISNS2N
FB2,3
100k
0.25µH
330µF
x3
+
100µF
x2
3.57k
0.22µF
3.3nF
332Ω
PGOOD1
PWM1
TRACK/SS1
TRACK/SS2
TRACK/SS3
0.25µH
DrMOS
3.57k
0.22µF
ISNS4P
ISNS1P
ISNS4N
ISNS1N
VSNSP4
VSNSP1
VSNSN4
VSNSN1
VSNSOUT4 VSNSOUT1,2,3
6.04k
10k
2.2nF
VCC
100k
PGOOD4
PWM4
RUN1
RUN2
RUN3
DrMOS
15k
10k
DrMOS
LTC7851
ISNS3P
ISNS3N
VCC
VCC
5V
PWM2
100pF
30.9k
42.2k
COMP4
FB4
FREQ
ILIM4
COMP1,2,3
FB1
IAVG1,2,3
ILIM1,2,3
SGND
100µF
x6
+
330µF
x9
VOUT1
1.0V/90A
10k
4.02k
10k
100pF
42.2k
2.2nF
3.3nF
15k
332Ω
100pF
7851 TA01
Rev A
Document Feedback
For more information www.analog.com
1
LTC7851/LTC7851-1
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
PGOOD1
PWM2
RUN2
PWM1
RUN1
CLKOUT
CLKIN
TOP VIEW
FREQ
TRACK/SS1
VCC Voltage ............................................... –0.3V to 6.5V
VINSNS Voltage ......................................... –0.3V to 30V
RUN1, RUN2, RUN3,
RUN4 Voltage .............................–0.3V to (VCC+0.3V)
ISNS1P, ISNS1N,
ISNS2P, ISNS2N........................ –0.3V to (VCC + 0.1V)
ISNS3P, ISNS3N,
ISNS4P, ISNS4N........................ –0.3V to (VCC + 0.1V)
All Other Pin Voltages....................–0.3V to (VCC + 0.3V)
Operating Junction Temperature Range.... –40° to 125°C
Storage Temperature Range................... –65°C to 150°C
FB1
(Note 1)
58 57 56 55 54 53 52 51 50 49
COMP1 1
48 ILIM1
VSNSP1 2
47 IAVG1
VSNSN1 3
46 ISNS1P
VSNSOUT1 4
45 ISNS1N
SGND 5
44 ISNS2N
VSNSOUT2 6
43 ISNS2P
VSNSN2 7
42 IAVG2
VSNSP2 8
41 ILIM2
COMP2 9
40 TRACK/SS2
59
SGND
FB2 10
39 VINSNS
VCC 11
38 PGOOD2
FB3 12
37 TRACK/SS3
COMP3 13
36 ILIM3
VSNSP3 14
35 IAVG3
VSNSN3 15
34 ISNS3P
VSNSOUT3 16
33 ISNS3N
VSNSOUT4 17
32 ISNS4N
VSNSN4 18
31 ISNS4P
30 IAVG4
VSNSP4 19
ILIM4
PGOOD3
RUN3
PWM3
PWM4
PGOOD4
RUN4
TRACK/SS4
FB4
COMP4
20 21 22 23 24 25 26 27 28 29
UHH PACKAGE
58-LEAD (5mm × 9mm) PLASTIC QFN
LEAD PITCH 0.4mm
θJA = 49°C/W, θJC = 15.5°C/W
EXPOSED PAD (PIN 59) IS SGND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC7851EUHH#PBF
LTC7851EUHH#TRPBF
7851
58-LEAD (5mm × 9mm) Plastic QFN
–40°C to 125°C
LTC7851IUHH#PBF
LTC7851IUHH#TRPBF
7851
58-LEAD (5mm × 9mm) Plastic QFN
–40°C to 125°C
LTC7851EUHH-1#PBF
LTC7851EUHH-1#TRPBF
78511
58-LEAD (5mm × 9mm) Plastic QFN
–40°C to 125°C
LTC7851IUHH-1#PBF
LTC7851IUHH-1#TRPBF
78511
58-LEAD (5mm × 9mm) Plastic QFN
–40°C to 125°C
Consult ADI Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Tape and reel specifications. Some packages are available in 500 unit reels through designated sales channels with #TRMPBF suffix.
2
Rev A
For more information www.analog.com
LTC7851/LTC7851-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C (Note 2). VCC = 5V, VRUN1,2,3,4 = 5V, VFREQ = VCLKIN = 0V,
VFB = 0.6V, fOSC = 600kHz, unless otherwise specified.
SYMBOL
PARAMETER
CONDITIONS
VINSNS
VIN Sense Range
VCC = 5V (Note 5)
VCC
VCC Voltage Range
VOUT
VOUT Voltage Range
IQ
Input Voltage Supply Current
Normal Operation
Shutdown Mode
UVLO
Limited by ISNSP/N Common Mode
Voltage Range (Note 3)
MIN
l
RUN Input Threshold
VRUN Rising
VRUN Hysteresis
IRUN
RUN Input Pull-Up Current
VRUN = 2.4V
VUVLO
Undervoltage Lockout Threshold
VCC Rising
VCC Hysteresis
ISS
Soft-Start Pin Output Current
VSS = 0V
tSS
Internal Soft-Start Time
VFB
Regulated Feedback Voltage
MAX
V
3
5.5
V
l
0.6
VCC – 0.5
V
60
16
1.95
2.25
250
110
100
mA
µA
mA
2.45
V
mV
1.5
l
100
1.5
2.5
µA
3
3.5
1.5
–20°C to 85°C
–40°C to 125°C
UNITS
27
l
VRUN1,2,3,4 = 5V
VRUN1,2,3,4 = 0V
VCC < VUVLO
VRUN
TYP
3
l
595.5
594
V
mV
µA
ms
600
600
604.5
606
mV
mV
0.05
0.2
%/V
�VFB/�VCC
Regulated Feedback Voltage Line Dependence 3.0V < VCC < 5.5V
ILIMIT
ILIM Pin Output Current
VILIM = 0.8V
18.5
20
21.5
µA
VFB(OV)
PGOOD/VFB Overvoltage Threshold
VFB Falling
VFB Rising
650
645
660
670
mV
mV
VFB(UV)
PGOOD/VFB Undervoltage Threshold
VFB Falling
VFB Rising
VPGOOD(ON)
PGOOD Pull-Down Resistance
IPGOOD(OFF)
PGOOD Leakage Current
VPGOOD = 5V
tPGOOD
PGOOD Delay
VPGOOD High to Low
IFB
FB Pin Input Current
VFB = 600mV
IOUT
COMP Pin Output Current
Sourcing
Sinking
AV(OL)
Open Loop Voltage Gain
SR
Slew Rate
f0dB
COMP Unity-Gain Bandwidth
Power Good
530
540
555
550
mV
mV
15
60
Ω
2
µA
30
µs
Error Amplifier
–100
100
nA
1
4
mA
mA
75
dB
(Note 4)
45
V/µs
(Note 4)
40
MHz
Differential Amplifier
VDA
VSNSP Accuracy
Measured in a Servo Loop with EA in Loop
0°C to 85°C
Measured in a Servo Loop with EA in Loop
–40°C to 125°C
l
594
600
606
mV
592
600
608
mV
IDIFF+
Input Bias Current
VSNSP = 600mV
fOdb
DA Unity-Gain Bandwidth
(Note 4)
–100
40
100
MHz
nA
IOUT(SINK)
Maximum Sinking Current
VSNSOUT = 600mV
100
µA
IOUT(SOURCE)
Maximum Sourcing Current
VSNSOUT = 600mV
500
µA
Rev A
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3
LTC7851/LTC7851-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C (Note 2). VCC = 5V, VRUN1,2,3,4 = 5V, VFREQ = VCLKIN = 0V,
VFB = 0.6V, fOSC = 600kHz, unless otherwise specified.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Current Sense Amplifier
VISENSE(MAX)
Maximum Differential Current Sense Voltage
(VISNSP – VISNSN)
LTC7851
50
mV
LTC7851-1
150
mV
AV(ISENSE)
Voltage Gain
LTC7851
VCM(ISENSE)
Input Common Mode Range
IISENSE
SENSE Pin Input Current
VCM = 1.5V
VIAVG
Zero Current IAVG Pin Voltage
VISNSP = VISNSN
VOS
Current Sense Input Referred Offset
LTC7851
l
–1
1
mV
LTC7851-1
l
–3
3
mV
l
l
520
0.85
680
1.15
kHz
MHz
20
LTC7851-1
V/V
4
–0.3
V/V
VCC – 0.5
100
V
nA
500
mV
Oscillator and Phase-Locked Loop
fOSC
Oscillator Frequency
VCLKIN = 0V
VFREQ = 0V
VFREQ = 5V
VCLKIN = 5V
RFREQ < 24.9k
RFREQ = 30.9k
RFREQ = 36.5k
RFREQ = 48.7k
RFREQ = 64.9k
RFREQ = 82.5k
RFREQ = 88.7k
600
1
180
370
570
970
1.4
1.9
2.1
Maximum Frequency
kHz
kHz
kHz
kHz
MHz
MHz
MHz
3
MHz
Minimum Frequency
MHz
21.5
µA
IFREQ
FREQ Pin Output Current
VFREQ = 0.8V
18.5
tCLKIN(HI)
CLKIN Pulse Width High
VCLKIN = 0V to 5V
100
ns
tCLKIN(LO)
CLKIN Pulse Width Low
VCLKIN = 0V to 5V
100
ns
RCLKIN
CLKIN Pull Up Resistance
20
kΩ
VCLKIN
CLKIN Input Threshold
VCLKIN Falling
VCLKIN Rising
0.8
2
V
V
VFREQ
FREQ Input Threshold
VCLKIN = 0V
VFREQ Falling
VFREQ Rising
1.5
2.5
V
V
VOL(CLKOUT)
CLKOUT Low Output Voltage
ILOAD = –500µA
0.2
V
VOH(CLKOUT)
CLKOUT High Output Voltage
ILOAD = 500µA
VCC – 0.2
θ2 – θ1
θ3 – θ1
θ4 – θ1
θCLKOUT – θ1
20
0.25
V
Channel 2 to Channel 1 Phase Relationship
180
Deg
Channel 3 to Channel 1 Phase Relationship
90
Deg
Channel 4 to Channel 1 Phase Relationship
270
Deg
CLKOUT to Channel 1 Phase Relationship
45
Deg
PWM Output
PWM
PWM Output High Voltage
ILOAD = 500µA
l
PWM Output Low Voltage
ILOAD = –500µA
l
VCC – 0.5
V
PWM Output Current in Hi-Z State
PWM Maximum Duty Cycle
4
91.5
0.5
V
±5
µA
%
Rev A
For more information www.analog.com
LTC7851/LTC7851-1
ELECTRICAL CHARACTERISTICS
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: The LTC7851/LTC7851-1 are tested under pulsed load conditions
such that TJ ≈ TA. The LTC7851E/LTC7851E-1 are guaranteed to meet
performance specifications from 0°C to 85°C. Specifications over the
–40°C to 125°C operating junction temperature range are assured by
design, characterization and correlation with statistical process controls.
The LTC7851I/LTC7851I-1 are guaranteed over the –40°C to 125°C
operating junction temperature range. Note that the maximum ambient
temperature consistent with these specifications is determined by specific
operating conditions in conjunction with board layout, the rated package
thermal impedance and other environmental factors. TJ is calculated from
the ambient temperature TA and power dissipation PD according to the
following formula:
TJ = TA + (PD • 49˚C/W)
Note 3: The maximum VOUT range is limited by the current sense pins
(ISNSP/ISNSN) common mode voltage range. See the Current Sensing in
the Applications Information section.
Note 4: Guaranteed by design.
Note 5: The Absolute Maximum Voltage Rating for the VINSNS voltage
limits the Maximum VIN Voltage. For operation with a VIN range higher
than 27V, the VINSNS pin must be connected through a resistor divider
from VIN to limit the maximum VINSNS voltage to less than 27V.
TYPICAL PERFORMANCE CHARACTERISTICS
Load Step Transient Response
(Single Phase Using
FDMF5820DC DrMOS)
Load Step Transient Response
(2-Phase Using FDMF58200C
DrMOS)
ILOAD
25A/DIV
ILOAD
20A/DIV
0A TO 15A TO 0A
IL1
10A/DIV
IL
20A/DIV
VOUT
AC-COUPLED
50mV/DIV
IL2
10A/DIV
VIN = 12V
VOUT = 1.8V
fSW = 400kHz
VOUT
AC-COUPLED
50mV/DIV
7851 G01
50µs/DIV
7851 G02
20µs/DIV
VIN = 12V
VOUT = 1.2V
fSW = 400kHz
ILOAD = 10A TO 30A TO 10A
Load Step Transient Response
(4-Phase Using FDMF5820DC
DrMOS)
Load Step Transient Response
(3-Phase Using FDMF5820DC
DrMOS)
ILOAD
50A/DIV
0A TO 50A TO 0A
IL1
20A/DIV
IL2
20A/DIV
VOUT
AC-COUPLED
20mV/DIV
IL3
20A/DIV
VIN = 12V
VOUT = 1.2V
fSW = 400kHz
VOUT
AC-COUPLED
50mV/DIV
40µs/DIV
VIN = 12V
VOUT = 1.2V
fSW = 400kHz
ILOAD = 0A TO 38A TO 0A
7851 G03
40µs/DIV
7851 G04
Rev A
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5
LTC7851/LTC7851-1
TYPICAL PERFORMANCE CHARACTERISTICS
Line Step Transient Response
(2-Phase Using FDMF5820DC
DrMOS)
EFFICIENCY (%)
IL1
10A/DIV
IL2
10A/DIV
VOUT
50mV/DIV
AC-COUPLED
VOUT = 1.2V
ILOAD = 15A
100
100
90
90
80
80
70
70
EFFICIENCY (%)
VIN
10V/DIV
7V TO 14V
60
50
40
30
20
7851 G05
20µs/DIV
Efficiency vs Load Current
(4-Phase Using D12S1R8130A
Power Block)
Efficiency vs Load Current
(2-Phase Using D12S1R8130A
Power Block)
fSW = 400kHz
VIN = 12V
VOUT = 1.2V
10
0
0
10
20
30
40
50
LOAD CURRENT (A)
60
70
60
50
40
30
10
0
3681 G06
Feedback Voltage VFB vs
Temperature
602
REGULATED VFB VOLTAGE (mV)
REGULATED VFB VOLTAGE (mV)
602
601
600
599
598
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
125
0
20
40
60
80 100
LOAD CURRENT (A)
120
140
3681 G07
Start-Up Response (2-Phase
Using FDMF5820DC DrMOS)
Regulated VFB vs Supply Voltage
RUN
5V/DIV
601
IL1
20A/DIV
IL2
20A/DIV
600
VOUT
1V/DIV
599
CSS = 0.1µF
5ms/DIV
598
3
3.5
4
4.5
SUPPLY VOLTAGE (V)
5
7851 G08
7851 G10
VIN = 12V
VOUT = 1.2V
RLOAD = 0.037Ω
fSW = 400kHz
5.5
7851 G09
Start-Up Response
(4-Phase Using D12S1R8130A
Power Block)
Start-Up Response (3-Phase
Using FDMF5820DC DrMOS)
RUN
5V/DIV
IL1
20A/DIV
IL2
20A/DIV
IL3
20A/DIV
ILOAD
50A/DIV
VOUT
1V/DIV
VOUT
1V/DIV
Coincident Tracking (Single Phase
Using FDMF5820DC DrMOS)
VIN = 12V
VOUT = 1.8V
RUN
4V/DIV
TRACK/SS
500mV/DIV
INTERNAL SOFT-START
RLOAD = 27mΩ
VIN = 12V
VOUT = 1.2V
6
fSW = 400kHz
VIN = 12V
VOUT = 1.2V
Airflow ≈ 400LFM
20
400µs/DIV
VOUT
1V/DIV
RLOAD = 0.01Ω
fSW = 400kHz
INTERNAL
SOFT–START
7851 G11
VIN = 12V
VOUT = 1.2V
RLOAD = 0.017Ω
fSW = 400kHz
500µs/DIV
7851 G12
2ms/DIV
7851 G13
Rev A
For more information www.analog.com
LTC7851/LTC7851-1
TYPICAL PERFORMANCE CHARACTERISTICS
Initial 7-Cycle Nonsynchronous
Start-Up (Single Phase Using
FDMF5820DC DrMOS)
Start-Up Response Into a 300mV
Prebiased Output (Single Phase
Using FDMF5820DC DrMOS)
IL
5A/DIV
Start-Up Into a Short (2-Phase
Using FDMF5820DC DrMOS)
TRACK/SS
1V/DIV
IL
10A/DIV
PWM
5V/DIV
IL1
50A/DIV
PWM
5V/DIV
VOUT
500mV/DIV
VIN = 12V
VOUT = 1.8V
10µs/DIV
IL2
50A/DIV
VOUT
1V/DIV
VIN = 12V
VOUT = 1.8V
7851 G14
IL1
20A/DIV
IL2
20A/DIV
VIN = 12V
VOUT = 1.2V
7851 G17
50µs/DIV
Oscillator Frequency vs RFREQ
Frequency < 1MHz
1050
1000
950
900
850
800
750
700
650
600
550
500
450
400
350
300
250
200
150
Oscillator Frequency vs RFREQ
Frequency ≥ 1MHz
OSCILLATOR FREQUENCY (kHz)
VOUT
1V/DIV
OSCILLATOR FREQUENCY (kHz)
TRACK/SS1
2V/DIV
24 27 30 33 36 39 42 45 48 51 54
RFREQ (kΩ)
2200
2100
2000
1900
1800
1700
1600
1500
1400
1300
1200
1100
1000
900
45
50
3681 G18
LTC7851-1 Overcurrent Threshold
vs Temperature
20.8
80
70
60
ILIM = 680mV
50
30
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
125
7851 G20
65 70 75
RFREQ (kΩ)
80
85
90
3681 G19
20.4
20.4
20.2
20
19.8
19.4
–50
60
FREQ Pin Current vs Temperature
20.2
20
19.8
19.6
19.4
19.6
40
55
20.6
20.6
ILIM = 860mV
90
ILIM Pin Current vs Temperature
FREQ PIN CURRENT (µA)
100
ILIM PIN CURRENT (µA)
CURRENT SENSE VOLTAGE (mV)
110
7851 G16
200µs/DIV
VIN = 12V
CTRACK/SS = 2200pF
7851 G15
200µs/DIV
128-Cycle Overcurrent Counter
(2-Phase Using FDMF5820DC DrMOS)
VOUT
50mV/DIV
–25
0
25
50
75
TEMPERATURE (°C)
100
125
7851 G21
19.2
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
125
7851 G22
Rev A
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7
LTC7851/LTC7851-1
TYPICAL PERFORMANCE CHARACTERISTICS
1MHz Preset Frequency vs
Temperature
1000
595
990
590
585
580
575
570
565
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
980
970
960
–25
0
25
50
75
TEMPERATURE (°C)
100
Shutdown Quiescent Current vs
Supply Voltage
60
–50
125
0
25
50
75
TEMPERATURE (°C)
100
125
RUN Threshold vs Temperature
2.5
65
2.4
40
30
20
2.3
RUN PIN VOLTAGE (V)
SHUTDOWN CURRENT (µA)
50
60
55
RISING
2.2
2.1
FALLING
2.0
1.9
1.8
1.7
10
1.6
0
1
2
3
4
SUPPLY VOLTAGE (V)
5
50
–50
6
7851 G26
–25
0
25
50
75
TEMPERATURE (°C)
100
1.5
–50
125
2.0
0
2.9
1.2
1.0
–50
TRACK/SS PIN CURRENT (µA)
3.0
TRACK/SS PIN CURRENT (µA)
0.5
1.4
–0.5
–1.0
–1.5
–2.0
–2.5
–25
0
25
50
75
TEMPERATURE (°C)
100
125
7851 G29
100
–3.0
125
TRACK/SS Pull-Up Current vs
Temperature
2.2
1.6
0
25
50
75
TEMPERATURE (°C)
7851 G28
TRACK/SS Current vs TRACK/SS
Voltage
1.8
–25
7851 G27
RUN Pull-Up Current vs
Temperature
8
–25
7851 G25
60
SHUTDOWN CURRENT (µA)
65
Shutdown Quiescent Current vs
Temperature
70
RUN PIN CURRENT (µA)
70
7851 G24
7851 G23
0
VIN = VCC = 5V
RUN1 = RUN2 = RUN3 = RUN4 = 5V
950
940
–50
125
Quiescent Current vs Temperature
75
QUIESCENT CURRENT (mA)
600
OSCILLATOR FREQUENCY (kHz)
OSCILLATOR FREQUENCY (kHz)
600kHz Preset Frequency vs
Temperature
2.8
2.7
2.6
2.5
2.4
2.3
0
1
2
3
4
TRACK/SS PIN VOLTAGE (V)
5
7851 G30
2.2
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
125
7851 G31
Rev A
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LTC7851/LTC7851-1
PIN FUNCTIONS
COMP1 (Pin 1), COMP2 (Pin 9), COMP3 (Pin 13), COMP4
(Pin 20): Error Amplifier Outputs. PWM duty cycle increases with this control voltage. The error amplifiers in
the LTC7851/LTC7851-1 are true operational amplifiers
with low output impedance. As a result, the outputs of
two active error amplifiers cannot be directly connected
together! For multiphase operation, connecting the FB pin
on an error amplifier to VCC will three-state the output of
that amplifier. Multiphase operation can then be achieved
by connecting all of the COMP pins together and using
one channel as the master and all others as slaves. When
the RUN pin is low, the respective COMP pin is actively
pulled down to ground.
VSNSP1 (Pin 2), VSNSP2 (Pin 8), VSNSP3 (Pin 14),
VSNSP4 (Pin 19): Differential Sense Amplifier Noninverting
Input. Connect this pin to the midpoint of the feedback
resistive divider between the positive and negative output
capacitor terminals.
VSNSN1 (Pin 3), VSNSN2 (Pin 7), VSNSN3 (Pin 15),
VSNSN4 (Pin 18): Differential Sense Amplifier Inverting
Input. Connect this pin to sense ground at the output load.
If the differential sense amplifier is not used, connect this
pin to local ground. Float this pin when the channel is a
slave channel.
VSNSOUT1 (Pin 4), VSNSOUT2 (Pin 6), VSNSOUT3
(Pin 16), VSNSOUT4 (Pin 17): Differential Amplifier Output.
Connect to the corresponding FB pin with a compensation
network for remote VOUT sensing. PolyPhase control is also
implemented in part by connecting all slave VSNSOUT pins
to the master VSNSOUT output. Only the master phase’s
differential amplifier contributes information to this output.
SGND (Pin 5, Exposed Pad Pin 59): Signal Ground. All
soft-start, small-signal and compensation components
should return to SGND. The exposed pad must be soldered
to PCB ground for rated thermal performance.
FB1 (Pin 58), FB2 (Pin 10), FB3 (Pin 12), FB4 (Pin 21):
Error Amplifier Inverting Input. Connect to the corresponding VSNSOUT pin with a compensation network for remote
VOUT sensing. Connecting the FB to VCC disables the differential and error amplifiers of the respective channel,
and will three-state the amplifier outputs.
VCC (Pin 11): Chip Supply Voltage. Bypass this pin to GND
with a capacitor (0.1μF to 1μF ceramic) in close proximity
to the chip.
TRACK/SS1 (Pin 57), TRACK/SS2 (Pin 40), TRACK/SS3
(Pin 37), TRACK/SS4 (Pin 22): Combined Soft-Start and
Tracking Inputs. For soft-start operation, connecting a
capacitor from this pin to ground will control the voltage
ramp at the output of the power supply. An internal 2.5μA
current source will charge the capacitor and thereby control
an extra input on the reference side of the error amplifier.
For coincident tracking of both outputs at start-up, a resistor divider with values equal to those connected to the
secondary VSNSP pin from the secondary output should
be used to connect the secondary track input from the
primary output. This pin is internally clamped to 2V, and
is used to communicate over current events in a masterslave configuration.
RUN1 (Pin 53), RUN2 (Pin 51), RUN3 (Pin 27), RUN4 (Pin
23): Run Control Inputs. A voltage above 2.25V on either
pin turns on the IC. However, forcing a RUN pin below 2V
causes the IC to shut down that particular channel. There
are 1.5μA pull-up currents for these pins.
PWM1 (Pin 52), PWM2 (Pin 50), PWM3 (Pin 26), PWM4
(Pin 24): (Top) Gate Signal Output. This signal goes to
the PWM or top gate input of the external gate driver or
integrated driver MOSFET. This is a three-state compatible output. In three-state, the voltage of this pin will be
determined by the external resistor divider.
PGOOD1 (Pin 49), PGOOD2 (Pin 38), PGOOD3 (Pin 28),
PGOOD4 (Pin 25): Power Good Indicator Output for Each
Channel. Open-drain logic out that is pulled to SGND when
either channel output exceeds a ±10% regulation window,
after the internal 30μs power bad mask timer expires.
ILIM1 (Pin 48), ILIM2 (Pin 41), ILIM3 (Pin 36), ILIM4 (Pin
29): Current Comparator Sense Voltage Limit Selection
Pin. Connect a resistor from this pin to SGND. This pin
sources 20μA when the channel is a master channel.
This pin does not source current when the channel is a
slave channel. The resultant voltage sets the threshold for
overcurrent protection. For multiphase operation, all ILIM
pins are tied together and only master channel's ILIM pin
sources 20μA.
Rev A
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9
LTC7851/LTC7851-1
PIN FUNCTIONS
IAVG1 (Pin 47), IAVG2 (Pin 42), IAVG3 (Pin 35), IAVG4 (Pin
30): Average Current Monitor Pin. A capacitor tied to
ground from the IAVG pin stores a voltage proportional to
the instantaneous average current of the master channel.
When the average current is zero, the IAVG pin voltage is
500mV. PolyPhase control is also implemented in part
by connecting all slave IAVG pins together to the master
IAVG output. The total capacitance on the IAVG bus should
range from 47pF to 220pF, inclusive, with the typical value
being 100pF. Only the master phase contributes information to this average through an internal resistor in current
sharing mode.
ISNS1P (Pin 46), ISNS2P (Pin 43), ISNS3P (Pin 34),
ISNS4P (Pin 31): Current Sense Amplifier(+) Input. The (+)
input to the current sense amplifier is normally connected
to the midpoint of the inductor’s parallel RC sense circuit
or to the node between the inductor and sense resistor if
using a discrete sense resistor.
ISNS1N (Pin 45), ISNS2N (Pin 44), ISNS3N (Pin 33),
ISNS4N (Pin 32): Current Sense Amplifier(–) Input. The
(–) input to the current amplifier is normally connected
to the respective VOUT at the inductor.
CLKOUT (Pin 54): Digital Output used for Daisychaining
Multiple LTC7851/LTC7851-1 ICs in Multiphase Systems.
When all RUN pins are driven low, the CLKOUT pin is actively pulled up to VCC. Signal swing is from VCC to ground.
CLKIN (Pin 55): External Clock Synchronization Input.
Applying an external clock between 250kHz to 2.25MHz
will cause the switching frequency to synchronize to the
clock. CLKIN is pulled high to VCC by a 20k internal resistor. The rising edge of the CLKIN input waveform will align
with the rising edge of PWM1 in closed-loop operation. If
CLKIN is high or floating, a resistor from the FREQ pin to
SGND sets the switching frequency. If CLKIN is low, the
FREQ pin logic state selects an internal 600kHz or 1MHz
preset frequency.
FREQ (Pin 56): Frequency Set/Select Pin. This pin sources
20μA current. If CLKIN is high or floating, then a resistor
between this pin and SGND sets the switching frequency. If
CLKIN is low, the logic state of this pin selects an internal
600kHz or 1MHz preset frequency.
VINSNS (Pin 39): VIN Sense Pin. Connects to the VIN
power supply to provide line feedforward compensation.
A change in VIN immediately modulates the input to the
PWM comparator and changes the pulse width in an inversely proportional manner, thus bypassing the feedback
loop and providing excellent transient line regulation. An
external lowpass filter can be added to this pin to prevent
noisy signals from affecting the loop gain.
10
Rev A
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LTC7851/LTC7851-1
BLOCK DIAGRAM
4
2
3
6
8
7
1
57
58
(Only CH1 and CH2 Are Shown)
VSNSOUT1
53
11
5
VCC
SGND
VCC
VSNSP1
1.5µA
100k
1.5µA
PGOOD2
VSNSOUT1 VSNSOUT2
VCC
VSNSP2
COMP1
38
PGOOD1
PGOOD
VCC
VSNSOUT2
VSNSN2
49
RUN2
100k
DA
VSNSN1
51
RUN1
DA
BG/BIAS
REF
TRACK/SS1
+
FB1
–
+
SD/UVLO
OC1 OC2
+
EA1
OV1 OV2
PWM1
52
NOC1
40
10
9
REF
TRACK/SS2
+
FB2
–
+
LOGIC
+
EA2
VFB1
ILIM1
VFB2
ILIM2
COMP2
MASTER/SLAVE/
INDEPENDENT
45
ISNS1P
ISNS1N
44
ISNS2P
ISNS2N
50
39
20µA
+
AV(ISENSE)
–
OC1
VCC
NOC1
20µA
S
43
VINSNS
RAMP/SLOPE/
FEEDFORWARD
VCC
S
46
PWM2
NOC2
+
VCC
AV(ISENSE)
20µA
–
OC2
PLL/VCO
NOC2
IAVG1
47
IAVG2
42
ILIM2
41
ILIM1
48
FREQ
56
CLKOUT CLKIN
54
55
7851BD
Rev A
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11
LTC7851/LTC7851-1
OPERATION (Refer to Block Diagram)
Main Control Architecture
The LTC7851/LTC7851-1 are quad-channel/quad-phase,
constant frequency, voltage mode controllers for DC/DC
step-down applications. They are designed to be used
in a synchronous switching architecture with external
integrated-driver MOSFETs (DrMOS), power blocks, or
external drivers and N-channel MOSFETs using single wire
three-state PWM interfaces. The LTC7851-1 is particularly
suited for applications using power stages with integrated
current sense signals. The controllers allow the use of
sense resistors or lossless inductor DCR current sensing to maintain current balance between phases and to
provide overcurrent protection. The operating frequency
is selectable from 250kHz to 2.25MHz. To multiply the
effective switching frequency, multiphase operation can
be extended to 2, 3, 4, 8, or higher phases by paralleling
additional controllers. In single phase operation, each
channel can be used as an independent output, i.e. one
single LTC7851/LTC7851-1 can provide four outputs.
Unlike a conventional differential amplifier, in which the
output is connected directly to the diffamp sensing pins,
the output voltage is resistively divided externally to create a feedback voltage for the controller (see Figure 3,
and Figure 4). Connect VSNSP of the unity-gain internal
differential amplifier, DA, to the center tap of the feedback
divider across the output load, and VSNSN to the load
ground. The output of the differential amplifier VSNSOUT
produces a signal equal to the differential voltage sensed
across VSNSP and VSNSN. This scheme overcomes any
ground offsets between local ground and remote output
ground and common mode voltage variations, resulting in
a more accurate output voltage.
In the main voltage mode control loop, the error amplifier output (COMP) directly controls the converter duty
cycle in order to drive the FB pin to 0.6V in steady state.
Dynamic changes in output load current can perturb the
output voltage. When the output is below regulation,
COMP rises, increasing the duty cycle. If the output rises
above regulation, COMP will decrease, decreasing the
duty cycle. As the output approaches regulation, COMP
will settle to the steady-state value representing the stepdown conversion ratio.
12
In normal operation, the PWM latch is set high at the beginning of the clock cycle (assuming COMP > 0.5V). When
the (line feedforward compensated) PWM ramp exceeds
the COMP voltage, the comparator trips and resets the
PWM latch. If COMP is less than 0.5V at the beginning
of the clock cycle, as in the case of an overvoltage at the
outputs, the PWM pin remains low throughout the entire
cycle. When the PWM pin goes high, it has a minimum
on-time of approximately 20ns and a minimum off-time
of approximately one-twelfth the switching period.
Current Sharing
In multiphase operation, the LTC7851/LTC7851-1 also
incorporate an auxiliary current sharing loop. Inductor
current is sampled each cycle. The master’s current sense
amplifier output is averaged at the IAVG pin. A small capacitor connected from IAVG to GND (typically 100pF) stores a
voltage corresponding to the instantaneous average current
of the master. Master phase's and slave phase's IAVG pins
must be connected together. Each slave phase integrates
the difference between its current and the master’s.
Within each phase the integrator output is proportionally
summed with the system error amplifier voltage (COMP),
adjusting that phase’s duty cycle to equalize the currents.
When multiple ICs are daisy chained, the IAVG pins must
be connected together. Figure 1 shows a transient load
step with current sharing in a 3-phase system.
IL1 (L= 0.47µH)
10A/DIV
IL2 (L= 0.25µH)
10A/DIV
IL3 (L= 0.47µH)
10A/DIV
VOUT
100mV/DIV
AC-COUPLED
7851 F01
VIN = 12V
VOUT = 1V
50µs/DIV
ILOAD STEP = 0A TO 30A TO 0A
fSW = 500kHz EXTERNAL CLOCK
Figure 1. Mismatched Inductor Load Step Transient Response
Overcurrent Protection
The current sense amplifier outputs also connect to overcurrent (OC) comparators that provide fault protection in
the case of an output short. When an OC fault is detected
Rev A
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LTC7851/LTC7851-1
OPERATION (Refer to Block Diagram)
for 128 consecutive clock cycles, the controller threestates the PWM output, resets the soft-start capacitor,
and waits for 32768 clock cycles before attempting to
start up again. The 128 consecutive clock cycle counter
has a 7-cycle hysteresis window, after which it will reset.
The LTC7851/LTC7851-1 also provide negative OC (NOC)
protection by preventing turn-on of the bottom MOSFET
during a negative OC fault condition. In this condition, the
bottom MOSFET will be turned on for 40ns every eight
cycles to allow the driver IC to recharge its topside gate
drive capacitor. The negative OC threshold is equal to –3/4
the positive OC threshold. See the Applications Information section for guidelines on setting these thresholds.
Excellent Transient Response
The LTC7851/LTC7851-1 error amplifiers are true
operational amplifiers, meaning that they have high
bandwidth, high DC gain, low offset and low output
impedance. Their bandwidth, when combined with high
switching frequencies and low-value inductors, allows
the compensation network to be optimized for very high
control loop crossover frequencies and excellent transient
response. The 600mV internal reference allows regulated
output voltages as low as 600mV without external levelshifting amplifiers.
Line Feedforward Compensation
The LTC7851/LTC7851-1 achieve outstanding line transient
response using a feedforward correction scheme which
instantaneously adjusts the duty cycle to compensate for
changes in input voltage, significantly reducing output
overshoot and undershoot. It has the added advantage
of making the DC loop gain independent of input voltage.
Figure 2 shows how large transient steps at the input have
little effect on the output voltage.
VIN
10V/DIV
7V TO 14V
IL1
10A/DIV
IL2
10A/DIV
VOUT
50mV/DIV
AC-COUPLED
VOUT = 1.2V
ILOAD = 15A
20µs/DIV
7851 F02
Figure 2. Line Step Transient Response
Remote Sense Differential Amplifier
The LTC7851/LTC7851-1 include four low offset, unity
gain, high bandwidth differential amplifiers for differential
output sensing. Output voltage accuracy is significantly
improved by removing board interconnection losses from
the total error budget.
The noninverting input of the differential amplifier is connected to the midpoint of the feedback resistive divider
between the positive and negative output capacitor terminals. The VSNSOUT is connected to the FB pin and the
amplifier will attempt to regulate this voltage to 0.6V. The
amplifier is configured for unity gain, meaning that the
differential voltage between VSNSP and VSNSN is translated
to VSNSOUT, relative to SGND.
Shutdown Control Using the RUN Pins
Each channel of the LTC7851/LTC7851-1 can be independently enabled using its own RUN pin. When all RUN pins
are driven low, all internal circuitry, including the internal
reference and oscillator, are completely shut down. When
the RUN pin is low, the respective COMP pin is actively
pulled down to ground. In a multiphase operation when
the COMP pins are tied together, the COMP pin is held
low until all the RUN pins are enabled. This ensures a
synchronized start-up of all the channels. A 1.5μA pull-up
current is provided for each RUN pin internally. The RUN
pins remain high impedance up to VCC.
Undervoltage Lockout
To prevent operation of the power supply below safe input
voltage levels, all channels are disabled when VCC is below
Rev A
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13
LTC7851/LTC7851-1
OPERATION (Refer to Block Diagram)
the undervoltage lockout (UVLO) threshold (2.9V falling, 3V
rising). If a RUN pin is driven high, the LTC7851/LTC7851-1
will start up the reference to detect when VCC rises above
the UVLO threshold, and enable the appropriate channel.
Overvoltage Protection
If the output voltage rises to more than 10% above the
set regulation value, which is reflected as a VSNSOUT
voltage of 0.66V or above, the LTC7851/LTC7851-1 will
force the PWM output low to turn on the bottom MOSFET
and discharge the output. Normal operation resumes
once the output is back within the regulation window.
However, if the reverse current flowing from VOUT back
through the bottom power MOSFET to PGND is greater
than 3/4 the positive OC threshold, the NOC comparator
trips and shuts off the bottom power MOSFET to protect
it from being destroyed. This scenario can happen when
the LTC7851/LTC7851-1 try to start into a precharged
load higher than the OV threshold. As a result, the bottom
switch turns on until the amount of reverse current trips
the NOC comparator threshold.
Nonsynchronous Start-Up and Prebiased Output
The LTC7851/LTC7851-1 will start up with seven cycles
of nonsynchronous operation before switching over to a
forced continuous mode of operation. The PWM output will
be in a three-state condition until start-up. The controller
will start the seven nonsynchronous cycles if it is not in
an overcurrent or prebiased condition, and if the COMP
pin voltage is higher than 500mV, or if the TRACK/SS
pin voltage is higher than 900mV. During the seven
nonsynchronous cycles the PWM latch is set high at the
beginning of the clock cycle, if COMP > 0.5V, causing the
PWM output to transition from three-state to VCC. The latch
is reset when the PWM ramp exceeds the COMP voltage,
causing the PWM output to transition from VCC to threestate followed immediately by a 20ns three-state to ground
pulse. The 7-cycle nonsynchronous mode of operation is
enabled at initial start-up and also during a restart from
a fault condition. In multiphase operation, where all the
TRACK/SS pins should be connected together, only an
overcurrent event on the master channel will discharge the
14
soft-start capacitor. After 32768 cycles, it will synchronize
the restart of all channels in to the nonsynchronous mode
of operation.
The LTC7851/LTC7851-1 can safely start-up into a prebiased output without discharging the output capacitors. A
prebias is detected when the FB pin voltage is higher than the
TRACK/SS or the internal soft-start voltage. A prebiased
condition will force the COMP pin to be held low, and
will three-state the PWM output. The prebiased condition
is cleared when the TRACK/SS or the internal soft-start
voltage is higher than the FB pin voltage or 900mV, whichever is lower. If the output prebias is higher than the OV
threshold then the PWM output will be low, which will pull
the output back in to the regulation window.
Internal Soft-Start
By default, the start-up of each channel’s output voltage
is normally controlled by an internal soft-start ramp. The
internal soft-start ramp represents a noninverting input to
the error amplifier. The FB pin is regulated to the lower of
the error amplifier’s three noninverting inputs (the internal
soft-start ramp for that channel, the TRACK/SS pin or the
internal 600mV reference). As the ramp voltage rises from
0V to 0.6V over approximately 2ms, the output voltage
rises smoothly from its prebiased value to its final set value.
Soft-Start and Tracking Using TRACK/SS Pin
The user can connect an external capacitor greater than
10nF to the TRACK/SS pin for the relevant channel to
increase the soft-start ramp time beyond the internally
set default. The TRACK/SS pin represents a noninverting
input to the error amplifier and behaves identically to the
internal ramp described in the previous section. An internal
2.5µA current source charges the capacitor, creating a
voltage ramp on the TRACK/SS pin. The TRACK/SS pin
is internally clamped to 2V. As the TRACK/SS pin voltage
rises from 0V to 0.6V, the output voltage rises smoothly
from 0V to its final value in:
CSS (µF ) • 0.6V
seconds
2.5µA
Rev A
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LTC7851/LTC7851-1
OPERATION (Refer to Block Diagram)
Alternatively, the TRACK/SS pin can be used to force the
start-up of VOUT to track the voltage of another supply.
Typically this requires connecting the TRACK/SS pin to
an external divider from the other supply to ground (see
the Applications Information section). It is only possible
to track another supply that is slower than the internal
soft-start ramp. The TRACK/SS pin also has an internal
open-drain NMOS pull-down transistor that turns on to
reset the TRACK/SS voltage when the channel is shut
down (RUN = 0V or VCC < UVLO threshold) or during an
OC fault condition.
No external PLL filter is required to synchronize the
LTC7851/LTC7851-1 to an external clock. Applying an
external clock signal to the CLKIN pin will automatically
enable the PLL with internal filter.
In multiphase operation, one master error amplifier is used
to control all of the PWM comparators. The FB pins for
the unused error amplifiers are connected to VCC in order
to three-state these amplifier outputs and the COMP pins
are connected together. When the FB pin is tied to VCC,
the internal 2.5µA current source on the TRACK/SS pin
is disabled for that channel. The TRACK/SS pins should
also be connected together so that the slave phases can
detect when soft-start is complete and to synchronize the
nonsynchronous mode of operation.
The LTC7851/LTC7851-1 feature a CLKOUT pin, which
allows multiple LTC7851/LTC7851-1 ICs to be daisy
chained together in multiphase applications. The clock
output signal on the CLKOUT pin can be used to synchronize
additional ICs in a multiphase power supply solution feeding
a single high current output, or even several outputs from
the same input supply.
Frequency Selection and the Phase-Locked Loop (PLL)
The selection of the switching frequency is a trade-off
between efficiency, transient response and component
size. High frequency operation reduces the size of the
inductor and output capacitor as well as increasing the
maximum practical control loop bandwidth. However,
efficiency is generally lower due to increased transition
and switching losses.
The LTC7851/LTC7851-1’s switching frequency can be
set in three ways: using an external resistor to linearly
program the frequency, synchronizing to an external clock,
or simply selecting one of two fixed frequencies (600kHz
and 1MHz). Table 1 highlights these modes.
Table 1. Frequency Selection
CLKIN PIN
FREQ PIN
FREQUENCY
Clocked
RFREQ to GND
250kHz to 2.25MHz
High or Float
RFREQ to GND
250kHz to 2.25MHz
Low
Low
600kHz
Low
High
1MHz
Constant-frequency operation brings with it a number of
benefits: inductor and capacitor values can be chosen
for a precise operating frequency and the feedback loop
can be similarly tightly specified. Noise generated by the
circuit will always be at known frequencies.
Using the CLKOUT Pin in Multiphase Applications
The phase relationship among each channel, as well as the
phase relationship between channel 1 and CLKOUT, are
summarized in Table 2. The phases are calculated relative to zero degrees, defined as the rising edge of PWM1.
Refer to Application Information for more details on how
to create multiphase applications.
Table 2. Phase Relationship
CH-1
0°
CH-2
180°
CH-3
90°
CH-4
270°
CLKOUT
45°
Using the LTC7851/LTC7851-1 Error Amplifiers in
Multiphase Applications
Due to the low output impedance of the error amplifiers,
multiphase applications using the LTC7851/LTC7851-1
use one error amplifier as the master with all of the slaves’
error amplifiers disabled. The channel 1 error amplifier
(phase = 0°) may be used as the master with phases 2
through n (up to 12) serving as slaves. To disable the
slave error amplifiers, connect the FB pins of the slaves
Rev A
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15
LTC7851/LTC7851-1
OPERATION (Refer to Block Diagram)
to VCC. This three-states the output stages of the amplifiers. All COMP pins should then be connected together
to create PWM outputs for all phases. As noted in the
section on soft-start, all TRACK/SS pins should also be
shorted together. Refer to the Multiphase Operation section in Applications Information for schematics of various
multiphase configurations.
Theory and Benefits of Multiphase Operation
Multiphase operation provides several benefits over traditional single phase power supplies:
Greater output current capability
n
Improved transient response
n
Reduction in component size
n
Increased real world operating efficiency
n
Because multiphase operation parallels power stages,
the amount of output current available is n times what it
would be with a single comparable output stage, where
n is equal to the number of phases.
The main advantages of PolyPhase operation are ripple
current cancellation in the input and output capacitors, a
faster load step response due to a smaller clock delay and
reduced thermal stress on the inductors and MOSFETs
due to current sharing between phases. These advantages
allow for the use of a smaller size or a smaller number
of components.
Power Good Indicator Pins (PGOOD)
Each PGOOD pin is connected to the open drain of an
internal pull-down device which pulls the PGOOD pin
low when the corresponding VSNSOUT pin voltage is
outside the PGOOD regulation window (±7.5% entering
regulation, ±10% leaving regulation). The PGOOD pins
16
are also pulled low when the corresponding RUN pin is
low, or during UVLO.
When the VSNSOUT pin voltage is within the ±10% regulation window, the internal PGOOD MOSFET is turned off
and the pin is normally pulled up by an external resistor.
When the VSNSOUT pin is exiting a fault condition (such
as during normal output voltage start-up, prior to regulation), the PGOOD pin will remain low for an additional
30μs. This allows the output voltage to reach steady-state
regulation and prevents the enabling of a heavy load from
retriggering a UVLO condition.
In multiphase application, only the master phase differential
and error amplifiers are used to control all phases. The
slave phase differential amplifiers are three-stated. The
slave phase VSNSOUT pins are connected to the master
phase VSNSOUT pin to obtain output voltage information. Only the PGOOD output for the master control error
amplifier should be connected to the fault monitor.
PWM Pins
The PWM pins are three-state compatible outputs, designed to drive MOSFET drivers, DrMOSs, power blocks,
etc., which do not represent a heavy capacitive load. An
external resistor divider may be used to set the voltage
to mid-rail while in the high impedance state.
Line Feedforward Gain
In a typical LTC7851/LTC7851-1 circuit, the feedback loop
consists of the line feedforward circuit, the modulator, the
external inductor, the output capacitor and the feedback
amplifier with its compensation network. All these components affect loop behavior and need to be accounted
for in the loop compensation. The modulator consists of
the PWM generator, the external output MOSFET drivers
and the external MOSFETs themselves. The modulator
gain varies linearly with the input voltage. The line feedforward circuit compensates for this change in gain, and
provides a constant gain from the error amplifier output
to the inductor input regardless of input voltage. From a
feedback loop point of view, the combination of the line
feedforward circuit and the modulator looks like a linear
voltage transfer function from COMP to the inductor input
and has a gain roughly equal to 12V/V.
Rev A
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LTC7851/LTC7851-1
APPLICATIONS INFORMATION
Output Voltage Programming and Differential Output
Sensing
More precisely, the VOUT value programmed in the previous
equation is with respect to the output’s ground reference,
and thus, is a differential quantity. The minimum differential
output voltage is limited to the internal reference, 0.6V,
and the maximum differential output voltage is VCC – 0.5V.
The LTC7851/LTC7851-1 integrate differential output sensing with output voltage programming, allowing for a simple
and seamless design. As shown in Figure 3, the output
voltage is programmed by an external resistor divider
from the regulated output point to its ground reference.
The resistive divider is tapped by the VSNSP pin, and the
ground reference is sensed by VSNSN. An optional feedforward capacitor, CFF, can be used to improve the transient
performance. The resulting output voltage is given according to the following equation:
The VSNSP pin is high impedance with no input bias
current. The VSNSN pin has about 7.5μA of current flowing out of the pin. Differential output sensing allows for
more accurate output regulation in high power distributed
systems having large line losses. Figure 4 illustrates the
potential variations in the power and ground lines due
to parasitic elements. These variations are exacerbated
in multi-application systems with shared ground planes.
Without differential output sensing, these variations directly
reflect as an error in the regulated output voltage.
⎛ R ⎞
VOUT = 0.6 V • ⎜ 1 + FB2 ⎟
⎝
RFB1 ⎠
The LTC7851/LTC7851-1’s differential output sensing
scheme is distinct from conventional schemes. In conventional schemes, the regulated output and its ground
reference are directly sensed with a difference amplifier
whose output is then divided down with an external resistive divider and fed into the error amplifier input. This
conventional scheme is limited by the common mode
input range of the difference amplifier and typically limits
differential sensing to the lower range of output voltages.
VOUT
LTC7851/
LTC7851-1
CFF
(OPT)
RFB2
COUT
VSNSP
RFB1
VSNSN
7851 F03
The LTC7851/LTC7851-1 allow for seamless differential
output sensing by sensing the resistively divided feedback
voltage differentially. This allows for differential sensing
in the full output range from 0.6V to VCC – 0.5V. The dif-
Figure 3. Setting Output Voltage
CIN
MT
LTC7851/
LTC7851-1
VSNSP
RFB2
VSNSN
RFB1
+
–
VIN
POWER TRACE
PARASITICS
L
±VDROP(PWR)
MB
COUT1
ILOAD
COUT2 I
LOAD
GROUND TRACE
PARASITICS
±VDROP(GND)
OTHER CURRENTS FLOWING IN
SHARED GROUNDPLANE
7851 F04
Figure 4. Differential Output Sensing Used to Correct Line Loss Variations
in a High Power Distributed System with a Shared Ground Plane
Rev A
For more information www.analog.com
17
LTC7851/LTC7851-1
APPLICATIONS INFORMATION
ference amplifier of the LTC7851/LTC7851-1 has a gain
bandwidth of 40MHz, high enough not to affect main
loop compensation and transient behavior. To avoid noise
coupling into VSNSP, the resistor divider should be placed
near the VSNSP and VSNSN pins and physically close to
the LTC7851/LTC7851-1. The remote output and ground
traces should be routed parallel to each other as a differential pair to the remote output. These traces should be
terminated as close as physically possible to the remote
output point that is to be accurately regulated through
remote differential sensing. In addition, avoid routing
these sensitive traces near any high speed switching
nodes in the circuit. Ideally, they should be shielded by a
low impedance ground plane to maintain signal integrity.
Programming the Operating Frequency
The LTC7851/LTC7851-1 can be hard wired to one of two
fixed frequencies, linearly programmed to any frequency
between 250kHz and 2.25MHz or synchronized to an
external clock.
Table 1 in the Operation section shows how to connect the
CLKIN and FREQ pins to choose the mode of frequency
programming. The frequency of operation is given by the
following equation:
Frequency = (RFREQ – 19.8kΩ) • 33.5Hz/Ω,
when Frequency is