LINER LTM4627IVPBF

LTM4627
15A DC/DC µModule
Regulator
FEATURES
DESCRIPTION
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The LTM®4627 is a complete 15A output high efficiency
switch mode DC/DC power supply. Included in the package are the switching controller, power FETs, inductor and
compensation components. Operating over an input voltage
range from 4.5V to 20V, the LTM4627 supports an output
voltage range of 0.6V to 5V, set by a single external resistor.
Only a few input and output capacitors are needed.
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Complete 15A Switch Mode Power Supply
Wide Input Voltage Range: 4.5V to 20V
0.6V to 5V Output Range
±1.5% Total DC Output Error (–40°C to 125°C)
Differential Remote Sense Amplifier for Precision
Regulation
Current Mode Control/ Fast Transient Response
Frequency Synchronization
Parallel Current Sharing (Up to 60A)
Selectable Pulse-Skipping or Burst Mode® Operation
Soft-Start/Voltage Tracking
Up to 93% Efficiency (12VIN, 3.3VOUT)
Overcurrent Foldback Protection
Output Overvoltage Protection
Small Surface Mount Footprint, Low Profile
15mm × 15mm × 4.32mm LGA Package
APPLICATIONS
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Current mode operation allows precision current sharing
of up to four LTM4627 regulators to obtain 60A output.
High switching frequency and a current mode architecture
enable a very fast transient response to line and load
changes without sacrificing stability. The device supports
frequency synchronization, multiphase/current sharing
operation, Burst Mode operation and output voltage tracking for supply rail sequencing.
The LTM4627 is offered in a thermally enhanced 15mm ×
15mm × 4.32mm LGA package. The LTM4627 is PB-free
and RoHS compliant.
L, LT, LTC, LTM, Linear Technology, the Linear logo, Burst Mode and μModule are registered
trademarks of Linear Technology Corporation. PolyPhase is a registered trademark of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Protected by U.S. Patents, including 5481178, 5847554, 6580258, 6304066, 6476589,
6774611, 6677210.
Telecom Servers and Networking Equipment
ATCA and Storage Cards
Industrial Equipment
Medical Systems
TYPICAL APPLICATION
1.2V, 15A DC/DC μModule® Regulator
95
22μF
16V
×3
90
150pF
10k
0.1μF
VIN
EXTVCC INTVCC PGOOD
COMP
VOUT
TRACK/SS
LTM4627
RUN
MODE_PLLIN
SGND
* SEE TABLE 4
** SEE TABLE 1
+
VOUT_LCL
DIFF_OUT
82pF
VOSNS+
VOSNS–
fSET
100k
85
GND
470μF
6.3V
VOUT
1.2V
15A
100μF*
6.3V
EFFICIENCY (%)
VIN
4.5V TO 16V
Efficiency vs Load Current
80
75
70
65
60
VFB
12VIN, 1.2VOUT
5VIN, 1.2VOUT
55
RFB**
60.4k
50
0
4627 TA01a
2
4
6
10 12
8
LOAD CURRENT (A)
14
16
4627 TA01b
4627f
1
LTM4627
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Note 1)
VIN ............................................................. –0.3V to 22V
INTVCC, VOUT (VOUT ≤ 3.3V with
DIFF AMP), VOUT_LCL, PGOOD, EXTVCC ....... –0.3V to 6V
MODE_PLLIN, fSET, TRACK/SS,
VOSNS –, VOSNS+, DIFF_OUT...................–0.3V to INTVCC
COMP, VFB ................................................ –0.3V to 2.7V
RUN (Note 5) ............................................... –0.3V to 5V
INTVCC Peak Output Current (Note 6) ..................100mA
Internal Operating Temperature Range
(Note 2).................................................. –40°C to 125°C
Storage Temperature Range .................. –55°C to 125°C
Reflow (Peak Body) Temperature .......................... 250°C
1
2
3
VIN
TOP VIEW
MODE_PLLIN
INTVCC
TRACK/SS
4
5
6
7
8
9
10
COMP
11
12
A
VIN
RUN
fSET
B
C
INTVCC
D
E
F
EXTVCC
PGOOD
VFB
G
PGOOD
GND
H
VOUT
SGND
J
VOSNS+
K
DIFF_OUT
L
VOUT_LCL
M
VOSNS–
VOUT
LGA PACKAGE
133-LEAD (15mm s 15mm s 4.32mm)
TJ(MAX) = 125°C, θJA = 13°C/W, θJCbottom = 2.3°C/W, θJCtop = 11°C/W to 13°C/W,
θJA DERIVED FROM 95mm × 76mm PCB WITH 4 LAYERS; WEIGHT = 2.6g
θ VALUES DETERMINED PER JESD51-12
ORDER INFORMATION
LEAD FREE FINISH
TRAY
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTM4627EV#PBF
LTM4627EV#PBF
LTM4627V
133-Lead (15mm × 15mm × 4.32mm) LGA
–40°C to 125°C
LTM4627IV#PBF
LTM4627IV#PBF
LTM4627V
133-Lead (15mm × 15mm × 4.32mm) LGA
–40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
This product is only offered in trays. For more information go to: http://www.linear.com/packaging/
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full internal operating
temperature range, otherwise specifications are at TA = 25°C (Note 2), VIN = 12V, per the typical application in Figure 18.
SYMBOL
PARAMETER
VIN
Input DC Voltage
VOUT(DC)
Output Voltage, Total
Variation with Line and Load
CONDITIONS
CIN = 22μF × 3
COUT = 100μF Ceramic, 470μF POSCAP
RFB = 40.2k, MODE_PLLIN = GND
VIN = 5V to 20V, IOUT = 0A to 15A (Note 4)
MIN
l
4.5
l
1.477
1.1
TYP
MAX
UNITS
20
V
1.50
1.523
V
1.25
1.4
V
Input Specifications
VRUN
RUN Pin On Threshold
VRUNHYS
RUN Pin On Hysteresis
VRUN Rising
130
mV
4627f
2
LTM4627
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full internal operating
temperature range, otherwise specifications are at TA = 25°C (Note 2), VIN = 12V, per the typical application in Figure 18.
SYMBOL
PARAMETER
CONDITIONS
IQ(VIN)
Input Supply Bias Current
VIN = 12V, VOUT = 1.5V, Burst Mode Operation, IOUT = 0.1A
VIN = 12V, VOUT = 1.5V, Pulse-Skipping Mode, IOUT = 0.1A
VIN = 12V, VOUT = 1.5V, Switching Continuous, IOUT = 0.1A
Shutdown, RUN = 0, VIN = 12V
IS(VIN)
Input Supply Current
VIN = 5V, VOUT = 1.5V, IOUT = 15A
VIN = 12V, VOUT = 1.5V, IOUT = 15A
MIN
TYP
MAX
17
25
54
40
UNITS
mA
mA
mA
μA
5.05
2.13
A
A
Output Specifications
IOUT(DC)
Output Continuous Current
Range
VIN = 12V, VOUT = 1.5V (Note 4)
0
15
A
ΔVOUT (Line)
VOUT
Line Regulation Accuracy
VOUT = 1.5V, VIN from 4.5V to 20V
IOUT = 0A
l
0.02
0.06
%/V
ΔVOUT (Load)
VOUT
Load Regulation Accuracy
VOUT = 1.5V, IOUT = 0A to 15A, VIN = 12V (Note 4)
l
0.2
0.45
%
VOUT(AC)
Output Ripple Voltage
IOUT = 0A, COUT = 100μF Ceramic, 470μF POSCAP
VIN = 12V, VOUT = 1.5V
15
mVP-P
ΔVOUT(START)
Turn-On Overshoot
COUT = 100μF Ceramic, 470μF POSCAP,
VOUT = 1.5V, IOUT = 0A, VIN = 12V
20
mV
tSTART
Turn-On Time
COUT = 100μF Ceramic, 470μF POSCAP,
No Load, TRACK/SS = 0.001μF, VIN = 12V
50
ms
ΔVOUTLS
Peak Deviation for Dynamic
Load
Load: 0% to 50% to 0% of Full Load
COUT = 100μF Ceramic, 470μF POSCAP,
VIN = 12V, VOUT = 1.5V
60
mV
tSETTLE
Settling Time for Dynamic
Load Step
Load: 0% to 50% to 0% of Full Load VIN = 5V,
COUT = 100μF Ceramic, 470μF POSCAP
20
μs
IOUTPK
Output Current Limit
VIN = 12V, VOUT = 1.5V
VIN = 5V, VOUT = 1.5V
25
25
A
A
VFB
Voltage at VFB Pin
IOUT = 0A, VOUT = 1.5V
IFB
Current at VFB Pin
(Note 7)
VOVL
Feedback Overvoltage
Lockout
ITRACK/SS
Track Pin Soft-Start Pull-Up
Current
TRACK/SS = 0V
tON(MIN)
Minimum On-Time
(Note 3)
RFBHI
Resistor Between VOUT_LCL
and VFB Pins
VOSNS+,
VOSNS– CM RANGE
Common Mode Input Range
VDIFF_OUT(MAX)
Maximum DIFF_OUT Voltage IDIFF_OUT = 300μA
Control Section
l
l
0.594
0.60
0.606
V
–12
–25
nA
0.65
0.67
0.69
V
1.0
1.2
1.4
μA
90
60.05
VIN = 12V, Run > 1.4V
60.40
0
ns
60.75
4
INTVCC – 1.4
kΩ
V
V
VOSNS+ = VDIFF_OUT = 1.5V, IDIFF_OUT = 100μA
VOS
Input Offset Voltage
2
AV
Differential Gain
1
SR
Slew Rate
2
V/μs
GBP
Gain Bandwidth Product
3
MHz
CMRR
Common Mode Rejection
(Note 7)
60
dB
IDIFF_OUT
DIFF_OUT Current
Sourcing
2
mV
V/V
mA
4627f
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LTM4627
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full internal operating
temperature range, otherwise specifications are at TA = 25°C (Note 2), VIN = 12V, per the typical application in Figure 18.
SYMBOL
PARAMETER
CONDITIONS
PSRR
Power Supply Rejection
Ratio
5V < VIN < 20V (Note 7)
MIN
TYP
100
MAX
UNITS
dB
RIN
Input Resistance
VOSNS+ to GND
80
kΩ
VPGOOD
PGOOD Trip Level
VFB With Respect to Set Output
VFB Ramping Negative
VFB Ramping Positive
–10
10
%
%
VPGL
PGOOD Voltage Low
IPGOOD = 2mA
0.1
0.3
V
5
5.2
V
INTVCC Linear Regulator
VINTVCC
Internal VCC Voltage
VINTVCC Load Reg INTVCC Load Regulation
6V < VIN < 20V
4.8
ICC = 0 to 50mA
VEXTVCC
External VCC Switchover
EXTVCC Ramping Positive
VLDO Ext
EXTVCC Voltage Drop
ICC = 25mA, VEXTVCC = 5V
l
4.5
0.5
%
4.7
V
50
100
mV
800
kHz
Oscillator and Phase-Locked Loop
fSYNC
SYNC Capture Range
250
Frequency
Nominal
Nominal Frequency
VfSET = 1.2V
450
500
550
kHz
Frequency Low
Lowest Frequency
VfSET = 1V
350
400
450
kHz
Frequency High
Highest Frequency
VfSET ≥ 2.4V
700
770
850
kHz
IFREQ
Frequency Set Current
9
10
11
μA
RMODE_PLLIN
Mode_PLLIN Input
Resistance
VIH_MODE_PLLIN
Clock Input Level High
VIL_MODE_PLLIN
Clock Input Level Low
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 LTM4627 is tested under pulsed load conditions such that
TJ ≈ TA. The LTM4627E is guaranteed to meet performance specifications
over the 0°C to 125°C internal operating temperature range. Specifications
over the full –40°C to 125°C internal operating temperature range are
assured by design, characterization and correlation with statistical process
controls. The LTM4627I is guaranteed to meet specifications over the
full –40°C to 125°C internal operating temperature range. Note that the
250
kΩ
2.0
V
0.8
V
maximum ambient temperature consistent with these specifications is
determined by specific operating conditions in conjunction with board
layout, the rated package thermal resistance and other environmental
factors.
Note 3: The minimum on-time condition is specified for a peak-to-peak
inductor ripple current of ~40% of IMAX Load. (See the Applications
Information section)
Note 4: See output current derating curves for different VIN, VOUT and TA.
Note 5: Limit current into the RUN pin to less than 2mA.
Note 6: Guaranteed by design.
Note 7: 100% tested at wafer level.
4627f
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LTM4627
TYPICAL PERFORMANCE CHARACTERISTICS
Efficiency vs Load Current
with 8VIN
100
95
95
90
90
90
85
85
85
80
75
70
1VOUT AT 400kHz
1.2VOUT AT 400kHz
1.5VOUT AT 400kHz
2.5VOUT AT 400kHz
3.3VOUT AT 650kHz
60
55
50
0
2
4
6
10 12
8
LOAD CURRENT (A)
14
80
75
70
1VOUT AT 400kHz
1.2VOUT AT 400kHz
1.5VOUT AT 400kHz
2.5VOUT AT 500kHz
3.3VOUT AT 600kHz
5VOUT AT 600kHz
65
60
55
50
16
0
2
4
6
10 12
8
LOAD CURRENT (A)
4627 G01
14
80
75
70
1VOUT AT 400kHz
1.2VOUT AT 400kHz
1.5VOUT AT 400kHz
2.5VOUT AT 650kHz
3.3VOUT AT 650kHz
5VOUT AT 700kHz
65
60
55
16
50
0
2
4
6
10 12
8
LOAD CURRENT (A)
4627 G02
Burst Mode Efficiency
14
16
4627 G03
Pulse-Skipping Mode Efficiency
1.0
1.0V Transient Response
1.0
5VIN, 2.5VOUT Burst Mode OPERATION
0.9
5VIN, 2.5VOUT
PULSE-SKIPPING MODE
0.9
EFFICIENCY (%)
0.8
12VIN, 2.5VOUT Burst Mode OPERATION
0.7
0.6
0.5
0.4
EFFICIENCY (%)
100
95
65
EFFICIENCY (%)
Efficiency vs Load Current
with 12VIN
100
EFFICIENCY (%)
EFFICIENCY (%)
Efficiency vs Load Current
with 5VIN
50mV/DIV
0.8
0.7
7.5A
LOAD STEP
0.6
12VIN, 2.5VOUT
PULSE-SKIPPING MODE
0.5
0.1
0.2
1
0.5
1.5
LOAD CURRENT (A)
2
0.4
100μs/DIV
VIN = 12V, VOUT = 1.0V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 5 s 100μF CERAMIC X5R
0.1
0.2
1
0.5
1.5
LOAD CURRENT (A)
4627 G04
2
4627 G05
1.2V Transient Response
1.5V Transient Response
1.8V Transient Response
50mV/DIV
50mV/DIV
50mV/DIV
7.5A
LOAD STEP
7.5A
LOAD STEP
7.5A
LOAD STEP
100μs/DIV
4627 G07
VIN = 12V, VOUT = 1.2V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 5 s 100μF CERAMIC X5R
4627 G06
100μs/DIV
4627 G08
VIN = 12V, VOUT = 1.5V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 5 s 100μF CERAMIC X5R
100μs/DIV
4627 G09
VIN = 12V, VOUT = 1.8V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 4 s 100μF CERAMIC X5R
4627f
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LTM4627
TYPICAL PERFORMANCE CHARACTERISTICS
2.5V Transient Response
3.3V Transient Response
5.0V Transient Response
50mV/DIV
50mV/DIV
50mV/DIV
7.5A
LOAD STEP
7.5A
LOAD STEP
7.5A
LOAD STEP
100μs/DIV
4627 G10
100μs/DIV
4627 G12
VIN = 12V, VOUT = 2.5V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 4 s 100μF CERAMIC X5R
VIN = 12V, VOUT = 3.3V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 2 s 100μF CERAMIC X5R
VIN = 12V, VOUT = 5V, CFF = 82pF, CCOMP = 33pF
OUTPUT CAPACITOR = 2 s 100μF CERAMIC X5R
Start-Up with Soft-Start
Short-Circuit Protection No Load
Short-Circuit Protection 15A Load
VOUT
VOUT
VOUT
100μs/DIV
4627 G11
500mV/DIV
500mV/DIV
500mV/DIV
IIN
IOUT
5A/DIV
1A/DIV
1A/DIV
IIN
100μs/DIV
4ms/DIV
4627 G13
VIN = 12V, VOUT = 1.5V, IOUT = 15A
INPUT CAP 150μF SANYO ELECTROLYTIC CAP
AND 22μF s 2 X5R CERAMIC CAP
OUTPUT CAP 1 s 100μF X5R CERAMIC AND 470μF
0.1μF CAP FROM TRACK/SS TO GND
VIN = 12V, VOUT = 1.5V, IOUT = 0A
4627 G14
4ms/DIV
4627 G15
VIN = 12V, VOUT = 1.5V, IOUT = 15A
PIN FUNCTIONS
VIN (A1-A6, B1-B6, C1-C6): Power Input Pins. Apply input
voltage between these pins and GND pins. Recommend
placing input decoupling capacitance directly between VIN
pins and GND pins.
PGOOD (F11, G12): Output Voltage Power Good Indicator.
Open-drain logic output that is pulled to ground when the
output voltage exceeds a ±10% regulation window. Both
pins are tied together internally.
VOUT (J1-J10, K1-K11, L1-L11, M1-M11): Power Output
Pins. Apply output load between these pins and GND
pins. Recommend placing output decoupling capacitance
directly between these pins and GND pins. Review Table 4.
SGND (G11, H11, H12): Signal Ground Pin. Return ground
path for all analog and low power circuitry. Tie a single
connection to the output capacitor GND in the application.
See layout guidelines in Figure 17.
GND (B7, B9, C7, C9, D1-D6, D8, E1-E7, E9, F1-F9, G1-G9,
H1-H9): Power Ground Pins for Both Input and Output
Returns.
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LTM4627
PIN FUNCTIONS
MODE_PLLIN (A8): Forced Continuous Mode, Burst Mode
Operation, or Pulse-Skipping Mode Selection Pin and
External Synchronization Input to Phase Detector Pin.
Connect this pin to INTVCC to enable pulse-skipping mode
of operation. Connect to ground to enable forced continuous
mode of operation. Floating this pin will enable Burst Mode
operation. A clock on this pin will enable synchronization
with forced continuous operation. See the Applications
Information section.
RUN: (A10) Run Control Pin. A voltage above 1.4V will turn
on the module. A 5.1V Zener diode to ground is internal
to the module for limiting the voltage on the RUN pin to
5V, and allowing a pull-up resistor to VIN for enabling the
device. Limit current into the RUN pin to ≤ 2mA.
fSET (B12): A resistor can be applied from this pin to
ground to set the operating frequency, or a DC voltage
can be applied to set the frequency. See the Applications
Information section.
EXTVCC (E12): External power input to an internal control
switch allows an external source greater than 4.7V, but less
than 6V to supply IC power and bypass the internal INTVCC
LDO. See the Applications Information section.
TRACK/SS (A9): Output Voltage Tracking Pin and SoftStart Inputs. The pin has a 1.2μA pull-up current source.
A capacitor from this pin to ground will set a soft-start
ramp rate. In tracking, the regulator output can be tracked
to a different voltage. The different voltage is applied to
a voltage divider then the slave output’s track pin. This
voltage divider is equal to the slave output’s feedback
divider for coincidental tracking. See the Applications
Information section.
VOUT_LCL: (L12) This pin connects to VOUT through a 1M
resistor, and to VFB with a 60.4k resistor. The remote sense
amplifier output DIFF_OUT is connected to VOUT_LCL, and
drives the 60.4k top feedback resistor in remote sensing
applications. When the remote sense amplifier is used,
DIFF_OUT effectively eliminates the 1MΩ from VOUT to
VOUT_LCL. When the remote sense amplifier is not used,
then connect VOUT_LCL to VOUT directly.
VFB (F12): The Negative Input of the Error Amplifier.
Internally, this pin is connected to VOUT_LCL with a
60.4k precision resistor. Different output voltages can
be programmed with an additional resistor between VFB
and ground pins. In PolyPhase® operation, tying the
VFB pins together allows for parallel operation. See the
Applications Information section for details.
COMP (A11): Current Control Threshold and Error Amplifier
Compensation Point. The current comparator threshold
increases with this control voltage. Tie all COMP pins
together for parallel operation. The device is internally
compensated.
INTVCC: (A7, D9) Internal 5V LDO for Driving the Control
Circuitry and the Power MOSFET Drivers. Both pins are
internally connected. The 5V LDO has a 100mA current
limit.
VOSNS+: (J12) (+) Input to the Remote Sense Amplifier.
This pin connects to the output remote sense point. The
remote sense amplifier is used for VOUT ≤ 3.3V.
VOSNS–: (M12) (–) Input to the Remote Sense Amplifier.
This pin connects to the ground remote sense point. The
remote sense amplifier is used for VOUT ≤ 3.3V.
DIFF_OUT: (K12) Output of the Remote Sense Amplifier.
This pin connects to the VOUT_LCL pin for remote sense
applications. Otherwise float when not used.
MTP1, MTP2, MTP3, MTP4, MTP5, MTP6, MTP7, MTP8
(A12, B11, C10, C11, C12, D10, D11, D12): Extra mounting pads used for increased solder integrity strength.
Leave floating.
4627f
7
LTM4627
BLOCK DIAGRAM
INTVCC
VOUT_LCL
1M
VIN
R1
VOUT
10k
PGOOD
> 1.4V = ON
< 1.1V = OFF
MAX = 5V
VIN
RUN
1.5μF
5.1V
R2
+
VIN
4.5V TO 20V
CIN
COMP
60.4k
M1
INTERNAL
COMP
0.4μH
10μF
VFB
VOUT
1V
15A
VOUT
POWER
CONTROL
SGND
M2
COUT
+
fSET
INTERNAL
LOOP
FILTER
INTVCC
TRACK/SS
MODE_PLLIN
+
250k
–
INTVCC
DIFF
AMP
VOSNS–
+
C SOFT-START
GND
RfSET
100k
–
90.9k
VOSNS+
C
DIFF_OUT
EXTVCC
4627 F01
Figure 1. Simplified LTM4627 Block Diagram
DECOUPLING REQUIREMENTS
TA = 25°C. Use Figure 1 configuration.
SYMBOL
PARAMETER
CONDITIONS
CIN
External Input Capacitor Requirement
(VIN = 4.5V to 20V, VOUT = 1.5V)
IOUT = 15A
COUT
External Output Capacitor Requirement
(VIN = 4.5V to 20V, VOUT = 1.5V)
IOUT = 15A
MIN
TYP
66
MAX
UNITS
μF
200
μF
4627f
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LTM4627
OPERATION
Power Module Description
The LTM4627 is a high performance single output standalone nonisolated switching mode DC/DC power supply.
It can provide a 15A output with few external input and
output capacitors. This module provides precisely regulated
output voltages programmable via external resistors from
0.6VDC to 5VDC over a 4.5V to 20V input range. The typical
application schematic is shown in Figure 18.
The LTM4627 has an integrated constant-frequency current
mode regulator, power MOSFETs, 0.4μH inductor, and other
supporting discrete components. The switching frequency
range is from 400kHz to 800kHz, and the typical operating
frequency is 500kHz. For switching noise-sensitive applications, it can be externally synchronized from 400kHz to
800kHz. A single resistor is used to program the frequency.
See the Applications Information section.
With current mode control and internal feedback loop
compensation, the LTM4627 module has sufficient stability margins and good transient performance with a wide
range of output capacitors, even with all ceramic output
capacitors.
Current mode control provides cycle-by-cycle fast current
limit in an overcurrent condition. An internal overvoltage
monitor protects the output voltage in the event of an
overvoltage >10%. The top MOSFET is turned off and the
bottom MOSFET is turned on until the output is cleared.
Pulling the RUN pin below 1.1V forces the regulator into a
shutdown state. The TRACK/SS pin is used for programming the output voltage ramp and voltage tracking during
start-up. See the Application Information section.
The LTM4627 is internally compensated to be stable over
all operating conditions. Table 4 provides a guideline for
input and output capacitances for several operating conditions. The Linear Technology μModule Power Design
Tool will be provided for transient and stability analysis.
The VFB pin is used to program the output voltage with a
single external resistor to ground.
A remote sense amplifier is provided for accurately sensing
output voltages ≤3.3V at the load point.
Multiphase operation can be easily employed with the
synchronization inputs using an external clock source.
See application examples.
High efficiency at light loads can be accomplished with
selectable Burst Mode operation using the MODE_PLLIN
pin. These light load features will accommodate battery
operation. Efficiency graphs are provided for light load
operation in the Typical Performance Characteristics
section.
4627f
9
LTM4627
APPLICATIONS INFORMATION
The typical LTM4627 application circuit is shown in Figure 18. External component selection is primarily determined by the maximum load current and output voltage.
Refer to Table 4 for specific external capacitor requirements
for particular applications.
VIN to VOUT Step-Down Ratios
There are restrictions in the VIN to VOUT step-down ratio
that can be achieved for a given input voltage. The VIN to
VOUT minimum dropout is a function of load current and
at very low input voltage and high duty cycle applications
output power may be limited as the internal top power
MOSFET is not rated for 15A operation at higher ambient
temperatures. At very low duty cycles the minimum 90ns
on-time must be maintained. See the Frequency Adjustment section and temperature derating curves.
Output Voltage Programming
The PWM controller has an internal 0.6V ±1% reference
voltage. As shown in the Block Diagram, a 60.4k internal
feedback resistor connects the VOUT_LCL and VFB pins
together. When the remote sense amplifier is used, then
DIFF_OUT is connected to the VOUT_LCL pin. If the remote
sense amplifier is not used, then VOUT_LCL connects to
VOUT. The output voltage will default to 0.6V with no feedback resistor. Adding a resistor RFB from VFB to ground
programs the output voltage:
VOUT = 0.6V •
60.4k + RFB
RFB
Table 1. VFB Resistor Table vs Various Output Voltages
VOUT (V)
RFB (k)
0.6
1.0
1.2
1.5
1.8
2.5
3.3
5.0
Open
90.9
60.4
40.2
30.1
19.1
13.3
8.25
For parallel operation of N LTM4627s, the following equation can be used to solve for RFB:
60.4 / N
RFB =
VOUT
–1
0.6
Tie the VFB pins together for each parallel output. The
COMP pins must be tied together also.
Input Capacitors
The LTM4627 module should be connected to a low
AC-impedance DC source. Additional input capacitors
are needed for the RMS input ripple current rating. The
ICIN(RMS) equation which follows can be used to calculate
the input capacitor requirement. Typically 22μF X7R ceramics are a good choice with RMS ripple current ratings
of ~ 2A each. A 47μF to 100μF surface mount aluminum
electrolytic bulk capacitor can be used for more input bulk
capacitance. This bulk input capacitor is only needed if
the input source impedance is compromised by long inductive leads, traces or not enough source capacitance.
If low impedance power planes are used, then this bulk
capacitor is not needed.
For a buck converter, the switching duty cycle can be
estimated as:
D=
VOUT
VIN
Without considering the inductor ripple current, for each
output, the RMS current of the input capacitor can be
estimated as:
IOUT(MAX)
I CIN(RMS)=
• D • (1– D)
η%
In the previous equation, η% is the estimated efficiency of the
power module. The bulk capacitor can be a switcher-rated
electrolytic aluminum capacitor or a Polymer capacitor.
4627f
10
LTM4627
APPLICATIONS INFORMATION
Output Capacitors
The LTM4627 is designed for low output voltage ripple
noise. The bulk output capacitors defined as COUT are
chosen with low enough effective series resistance (ESR)
to meet the output voltage ripple and transient requirements. COUT can be a low ESR tantalum capacitor, low ESR
Polymer capacitor or ceramic capacitors. The typical output
capacitance range is from 200μF to 800μF. Additional output
filtering may be required by the system designer if further
reduction of output ripple or dynamic transient spikes is
required. Table 4 shows a matrix of different output voltages
and output capacitors to minimize the voltage droop and
overshoot during a 7A/μs transient. The table optimizes
total equivalent ESR and total bulk capacitance to optimize
the transient performance. Stability criteria are considered
in the Table 4 matrix, and the Linear Technology μModule
Power Design Tool will be provided for stability analysis.
Multiphase operation will reduce effective output ripple
as a function of the number of phases. Application Note
77 discusses this noise reduction versus output ripple
current cancellation, but the output capacitance should be
considered carefully as a function of stability and transient
response. The Linear Technology μModule Power Design
Tool can calculate the output ripple reduction as the number
of implemented phase’s increases by N times.
Burst Mode Operation
The LTM4627 is capable of Burst Mode operation in which
the power MOSFETs operate intermittently based on load
demand, thus saving quiescent current. For applications
where maximizing the efficiency at very light loads is a
high priority, Burst Mode operation should be applied. To
enable Burst Mode operation, simply float the MODE_PLLIN
pin. During Burst Mode operation, the peak current of the
inductor is set to approximately 30% of the maximum peak
current value in normal operation even though the voltage
at the COMP pin indicates a lower value. The voltage at the
COMP pin drops when the inductor’s average current is
greater than the load requirement. As the COMP voltage
drops below 0.5V, the burst comparator trips, causing
the internal sleep line to go high and turn off both power
MOSFETs.
In sleep mode, the internal circuitry is partially turned
off, reducing the quiescent current. The load current is
now being supplied from the output capacitors. When the
output voltage drops, causing COMP to rise, the internal
sleep line goes low, and the LTM4627 resumes normal
operation. The next oscillator cycle will turn on the top
power MOSFET and the switching cycle repeats.
Pulse-Skipping Mode Operation
In applications where low output ripple and high efficiency at intermediate currents are desired, pulse-skipping
mode should be used. Pulse-skipping operation allows
the LTM4627 to skip cycles at low output loads, thus
increasing efficiency by reducing switching loss. Tying
the MODE_PLLIN pin to INTVCC enables pulse-skipping
operation. With pulse-skipping mode at light load, the
internal current comparator may remain tripped for several
cycles, thus skipping operation cycles. This mode has lower
ripple than Burst Mode operation and maintains a higher
frequency operation than Burst Mode operation.
Forced Continuous Operation
In applications where fixed frequency operation is more
critical than low current efficiency, and where the lowest
output ripple is desired, forced continuous operation
should be used. Forced continuous operation can be
enabled by tying the MODE_PLLIN pin to ground. In this
mode, inductor current is allowed to reverse during low
output loads, the COMP voltage is in control of the current
comparator threshold throughout, and the top MOSFET
always turns on with each oscillator pulse. During start-up,
forced continuous mode is disabled and inductor current
is prevented from reversing until the LTM4627’s output
voltage is in regulation.
4627f
11
LTM4627
APPLICATIONS INFORMATION
Multiphase Operation
For outputs that demand more than 15A of load current,
multiple LTM4627 devices can be paralleled to provide
more output current without increasing input and output
voltage ripple. The MODE_PLLIN pin allows the LTM4627
to be synchronized to an external clock (between 400kHz
to 800kHz) and the internal phase-locked loop allows the
LTM4627 to lock onto input clock phase as well. The fSET
resistor is selected for normal frequency, then the incoming
clock can synchronize the device over the specified range.
See Figure 20 for a synchronizing example circuit.
A multiphase power supply significantly reduces the
amount of ripple current in both the input and output capacitors. The RMS input ripple current is reduced by, and
the effective ripple frequency is multiplied by, the number
of phases used (assuming that the input voltage is greater
than the number of phases used times the output voltage).
The output ripple amplitude is also reduced by the number
of phases used. See Application Note 77.
The LTM4627 device is an inherently current mode controlled device, so parallel modules will have good current
sharing. This will balance the thermals in the design. Tie
the COMP and VFB pins of each LTM4627 together to
share the current evenly. Figure 20 shows a schematic of
the parallel design.
Input RMS Ripple Current Cancellation
Application Note 77 provides a detailed explanation of
multiphase operation. The input RMS ripple current cancellation mathematical derivations are presented, and a
graph is displayed representing the RMS ripple current
reduction as a function of the number of interleaved phases
(see Figure 2).
PLL, Frequency Adjustment and Synchronization
The LTM4627 switching frequency is set by a resistor (RfSET)
from the fSET pin to signal ground. A 10μA current (IFREQ)
flowing out of the fSET pin through RfSET develops a voltage
on fSET. RfSET can be calculated as:
RfSET (kΩ) =
The relationship of fSET voltage to switching frequency is
shown in Figure 3. For low output voltages from 0.8V to
1.5V, 400kHz operation is an optimal frequency for the best
power conversion efficiency while maintaining the inductor
current to about 30% to 40% of maximum load current.
For output voltages from 1.8V to 3.0V, 500kHz to 600kHz
is optimal. For output voltages from 3.0V to 5.0V, 750kHz
operation is optimal, but due to the higher ripple current
at 5V operation the output current is limited to 10A.
The LTM4627 can be synchronized from 400kHz to 800kHz
with an input clock that has a high level above 2V and
a low level below 0.8V. The 400kHz low end operation
limit is put in place to limit inductor ripple current. See the
Typical Applications section for synchronization examples.
The LTM4627 minimum on-time is limited to approximately
90ns. Guardband the on-time to 130ns. The on-time can
be calculated as:
t ON(MIN)=
1 ⎛ V OUT ⎞
•⎜
⎟
FREQ ⎝ VIN ⎠
Output Voltage Tracking
Output voltage tracking can be programmed externally
using the TRACK/SS pin. The output can be tracked up and
down with another regulator. The master regulator’s output
is divided down with an external resistor divider that is the
same as the slave regulator’s feedback divider to implement
coincident tracking. The LTM4627 uses an accurate 60.4k
resistor internally for the top feedback resistor. Figure 4
shows an example of coincident tracking.
⎛ 60.4k ⎞
VOUT(SLAVE) = ⎜ 1+
• V TRACK
R TA ⎟⎠
⎝
VTRACK is the track ramp applied to the slave’s track pin.
VTRACK has a control range of 0V to 0.6V, or the internal
reference voltage. When the master’s output is divided
down with the same resistor values used to set the slave’s
output, then the slave will coincident track with the master
until it reaches its final value. The master will continue to
FREQ(kHz)
+ 2kHz
4.5
4627f
12
LTM4627
APPLICATIONS INFORMATION
0.60
1 PHASE
2 PHASE
3 PHASE
4 PHASE
6 PHASE
0.55
0.50
RMS INPUT RIPPLE CURRENT
DC LOAD CURRENT
0.45
0.40
0.35
0.30
0.25
0.20
0.15
0.10
0.05
0
0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5 0.55 0.6 0.65 0.7 0.75 0.8 0.85 0.9
DUTY FACTOR (VOUT/VIN)
4627 F02
Figure 2. Normalized Input RMS Ripple Current vs Duty Factor for One to Six μModule Regulators (Phases)
900
SWITCHING FREQUENCY (kHz)
800
700
600
500
400
300
200
100
0
0
0.5
1
1.5
fSET PIN VOLTAGE (V)
2
2.5
4627 F03
Figure 3. Relationship Between Switching
Frequency and Voltage at the fSET Pin
4627f
13
LTM4627
APPLICATIONS INFORMATION
its final value from the slave’s regulation point. Voltage
tracking is disabled when VTRACK is more than 0.6V. RTA in
Figure 4 will be equal to the RFB for coincident tracking.
has a control range from 0V to 0.6V. The master’s TRACK/SS
pin slew rate is directly equal to the master’s output slew
rate in volts/time. The equation:
The TRACK/SS pin of the master can be controlled by an
external ramp or the soft-start function of that regulator
can be used to develop that master ramp. The LTM4627 can
be used as a master by setting the ramp rate on its track
pin using a soft-start capacitor. A 1.2μA current source
is used to charge the soft-start capacitor. The following
equation can be used:
MR
• 60.4k = R TB
SR
where MR is the master’s output slew rate and SR is the
slave’s output slew rate in volts/time. When coincident
tracking is desired, then MR and SR are equal, thus RTB
is equal to 60.4k. RTA is derived from equation:
⎛ C ⎞
t SOFT-START = 0.6 • ⎜ SS ⎟
⎝ 1.2µA ⎠
R TA =
Ratiometric tracking can be achieved by a few simple
calculations and the slew rate value applied to the master’s
TRACK/SS pin. As mentioned above, the TRACK/SS pin
VIN 6V
TO 16V
C7
22μF
16V
C9
22μF
16V
C10
22μF
16V
R2
10k
SOFT-START
CAPACITOR
CSS
150pF
where VFB is the feedback voltage reference of the regulator, and VTRACK is 0.6V. Since RTB is equal to the 60.4k
VIN
EXTVCC INTVCC PGOOD
COMP
VOUT
TRACK/SS
RUN
R4
100k
LTM4627
C3
22μF
16V
C1
22μF
16V
C2
22μF
16V
R1
10k
MASTER RAMP
OR OUTPUT
150pF
RTA
60.4k
RTB
60.4k
MODE_PLLIN
VOSNS–
COMP
VOUT
RUN
+
DIFF_OUT
VOSNS+
MODE_PLLIN
VOSNS–
GND
C11
100μF
6.3V
82pF
VOUT_LCL
fSET
SGND
C8
470μF
6.3V
RFB1
40.2k
EXTVCC INTVCC PGOOD
LTM4627
VOUT2
1.5V AT 15A
VFB
VIN
TRACK/SS
R3
100k
DIFF_OUT
VOSNS+
GND
+
VOUT_LCL
fSET
SGND
VIN 6V
TO 16V
0.6V
V
V FB
V
+ FB – TRACK
60.4k RFB
R TB
C4
470μF
6.3V
C6
100μF
6.3V
VOUT1
1.2V
15A
82pF
VFB
RFB
60.4k
4627 F04
Figure 4. Dual Outputs (1.5V and 1.2V) with Tracking
4627f
14
LTM4627
APPLICATIONS INFORMATION
top feedback resistor of the slave regulator in equal slew
rate or coincident tracking, then RTA is equal to RFB with
VFB = VTRACK. Therefore RTB = 60.4k, and RTA = 60.4k in
Figure 4.
In ratiometric tracking, a different slew rate maybe desired
for the slave regulator. RTB can be solved for when SR is
slower than MR. Make sure that the slave supply slew rate
is chosen to be fast enough so that the slave output voltage
will reach its final value before the master output.
For example, MR = 1.5V/ms, and SR = 1.2V/ms. Then RTB
= 75k. Solve for RTA to equal 51.1k.
For applications that do not require tracking or sequencing, simply tie the TRACK/SS pin to INTVCC to let RUN
control the turn on/off. When the RUN pin is below its
threshold or the VIN undervoltage lockout, then TRACK/SS
is pulled low.
MASTER OUTPUT
OUTPUT
VOLTAGE
SLAVE OUTPUT
electronic circuit breaker or fuse can be sized to be tripped
or cleared when the bottom MOSFET is turned on to protect against the overvoltage. Foldback current limiting is
disabled during soft-start or tracking start-up.
Run Enable
The RUN pin is used to enable the power module or
sequence the power module. The threshold is 1.25V, and
the pin has an internal 5.1V Zener to protect the pin. The
RUN pin can be used as an undervoltage lockout (UVLO)
function by connecting a resistor divider from the input
supply to the RUN pin:
VUVLO = ((R1+R2)/R2) • 1.25V.
See the Block Diagram for the example of use.
INTVCC Regulator
The LTM4627 has an internal low dropout regulator from
VIN called INTVCC. This regulator output has a 4.7μF
ceramic capacitor internal. This regulator powers the
internal controller and MOSFET drivers. The gate driver
current is ~20mA for 750kHz operation. The regulator loss
can be calculated as:
(VIN – 5V) • 20mA = PLOSS
TIME
4627 F05
Figure 5. Output Voltage Coincident Tracking
Overcurrent and Overvoltage Protection
The LTM4627 has overcurrent protection (OCP) in a short
circuit. The internal current comparator threshold folds
back during a short to reduce the output current. An
overvoltage condition (OVP) above 10% of the regulated
output voltage will force the top MOSFET off and the bottom MOSFET on until the condition is cleared. An input
EXTVCC external voltage source ≥ 4.7V can be applied to
this pin to eliminate the internal INTVCC LDO power loss
and increase regulator efficiency. A 5V supply can be
applied to run the internal circuitry and power MOSFET
driver. If unused, leave pin floating.
Stability Compensation
The module has already been internally compensated
for all output voltages. Table 4 is provided for most application requirements. The Linear Technology μModule
Power Design Tool will be provided for other control loop
optimization.
4627f
15
LTM4627
APPLICATIONS INFORMATION
Thermal Considerations and Output Current Derating
The thermal resistances reported in the Pin Configuration
section of the data sheet are consistent with those parameters defined by JESD51-9 and are intended for use with
finite element analysis (FEA) software modeling tools that
leverage the outcome of thermal modeling, simulation,
and correlation to hardware evaluation performed on a
μModule package mounted to a hardware test board—also
defined by JESD51-9 (“Test Boards for Area Array Surface
Mount Package Thermal Measurements”). The motivation
for providing these thermal coefficients in found in JESD
51-12 (“Guidelines for Reporting and Using Electronic
Package Thermal Information”).
Many designers may opt to use laboratory equipment
and a test vehicle such as the demo board to anticipate
the μModule regulator’s thermal performance in their application at various electrical and environmental operating
conditions to compliment any FEA activities. Without FEA
software, the thermal resistances reported in the Pin Configuration section are in-and-of themselves not relevant to
providing guidance of thermal performance; instead, the
derating curves provided in the data sheet can be used in
a manner that yields insight and guidance pertaining to
one’s application-usage, and can be adapted to correlate
thermal performance to one’s own application.
The Pin Configuration section typically gives four thermal
coefficients explicitly defined in JESD 51-12; these coefficients are quoted or paraphrased below:
1 θJA, the thermal resistance from junction to ambient, is
the natural convection junction-to-ambient air thermal
resistance measured in a one cubic foot sealed enclosure. This environment is sometimes referred to as
“still air” although natural convection causes the air to
move. This value is determined with the part mounted to
a JESD 51-9 defined test board, which does not reflect
an actual application or viable operating condition.
2 θJCbottom, the thermal resistance from junction to the
bottom of the product case, is the junction-to-board
thermal resistance with all of the component power
dissipation flowing through the bottom of the package.
In the typical μModule, the bulk of the heat flows out
the bottom of the package, but there is always heat
flow out into the ambient environment. As a result, this
thermal resistance value may be useful for comparing
packages but the test conditions don’t generally match
the user’s application.
3 θJCtop, the thermal resistance from junction to top of
the product case, is determined with nearly all of the
component power dissipation flowing through the top
of the package. As the electrical connections of the
typical μModule are on the bottom of the package, it
is rare for an application to operate such that most of
the heat flows from the junction to the top of the part.
As in the case of θJCbottom, this value may be useful
for comparing packages but the test conditions don’t
generally match the user’s application.
4 θJB, the thermal resistance from junction to the printed
circuit board, is the junction-to-board thermal resistance
where almost all of the heat flows through the bottom
of the μModule and into the board, and is really the
sum of the θJCbottom and the thermal resistance of the
bottom of the part through the solder joints and through
a portion of the board. The board temperature is measured a specified distance from the package, using a
two sided, two layer board. This board is described in
JESD 51-9.
A graphical representation of the aforementioned thermal
resistances is given in Figure 6; blue resistances are
contained within the μModule regulator, whereas green
resistances are external to the μModule.
As a practical matter, it should be clear to the reader that
no individual or sub-group of the four thermal resistance
parameters defined by JESD 51-12 or provided in the
Pin Configuration section replicates or conveys normal
operating conditions of a μModule. For example, in normal
board-mounted applications, never does 100% of the
device’s total power loss (heat) thermally conduct exclusively through the top or exclusively through bottom of the
μModule—as the standard defines for θJCtop and θJCbottom,
respectively. In practice, power loss is thermally dissipated
in both directions away from the package—granted, in the
absence of a heat sink and airflow, a majority of the heat
flow is into the board.
Within a SIP (system-in-package) module, be aware there
are multiple power devices and components dissipating
power, with a consequence that the thermal resistances
4627f
16
LTM4627
APPLICATIONS INFORMATION
JUNCTION-TO-AMBIENT RESISTANCE (JESD 51-9 DEFINED BOARD)
CASE (TOP)-TO-AMBIENT
RESISTANCE
JUNCTION-TO-CASE (TOP)
RESISTANCE
JUNCTION-TO-BOARD RESISTANCE
JUNCTION
JUNCTION-TO-CASE
CASE (BOTTOM)-TO-BOARD
(BOTTOM) RESISTANCE
RESISTANCE
At
BOARD-TO-AMBIENT
RESISTANCE
80421 F05
μMODULE DEVICE
Figure 6. Graphical Representation of JESD 51-12 Thermal Coefficients
relative to different junctions of components or die are not
exactly linear with respect to total package power loss. To
reconcile this complication without sacrificing modeling
simplicity—but also, not ignoring practical realities—an
approach has been taken using FEA software modeling
along with laboratory testing in a controlled-environment
chamber to reasonably define and correlate the thermal
resistance values supplied in this data sheet: (1) Initially,
FEA software is used to accurately build the mechanical
geometry of the μModule and the specified PCB with all
of the correct material coefficients along with accurate
power loss source definitions; (2) this model simulates
a software-defined JEDEC environment consistent with
JSED51-9 to predict power loss heat flow and temperature
readings at different interfaces that enable the calculation of
the JEDEC-defined thermal resistance values; (3) the model
and FEA software is used to evaluate the μModule with
heat sink and airflow; (4) having solved for and analyzed
these thermal resistance values and simulated various
operating conditions in the software model, a thorough
laboratory evaluation replicates the simulated conditions
with thermocouples within a controlled-environment
chamber while operating the device at the same power
loss as that which was simulated. An outcome of this
process and due-diligence yields a set of derating curves
provided in other sections of this data sheet. After these
laboratory test have been performed and correlated to the
μModule model, then the θJB and θBA are summed together
to correlate quite well with the μModule model with no
airflow or heat sinking in a properly define chamber. This
θJB + θBA value is shown in the Pin Configuration section
and should accurately equal the θJA value because approximately 100% of power loss flows from the junction
through the board into ambient with no airflow or top
mounted heat sink.
The 1.2V and 3.3V power loss curves in Figures 7 and 8
can be used in coordination with the load current derating
curves in Figures 9 to 16 for calculating an approximate
θJA thermal resistance for the LTM4627 with various heat
sinking and airflow conditions. The power loss curves
are taken at room temperature, and are increased with
multiplicative factors according to the ambient temperature. These approximate factors are: 1 for 40°C; 1.05 for
50°C; 1.1 for 60°C; 1.15 for 70°C; 1.2 for 80°C; 1.25 for
90°C; 1.3 for 100°C; 1.35 for 110°C and 1.4 for 120°C.
The derating curves are plotted with the output current
starting at 15A and the ambient temperature at 40°C. The
output voltages are 1.2V, and 3.3V. These are chosen to
include the lower and higher output voltage ranges for
correlating the thermal resistance. Thermal models are
derived from several temperature measurements in a controlled temperature chamber along with thermal modeling
analysis. The junction temperatures are monitored while
ambient temperature is increased with and without airflow.
The power loss increase with ambient temperature change
is factored into the derating curves. The junctions are
maintained at 120°C maximum while lowering output
current or power with increasing ambient temperature.
The decreased output current will decrease the inter4627f
17
LTM4627
APPLICATIONS INFORMATION
nal module loss as ambient temperature is increased.
The monitored junction temperature of 120°C minus
the ambient operating temperature specifies how much
module temperature rise can be allowed. As an example in
Figure 11 the load current is derated to ~12A at ~80°C with
no air or heat sink and the power loss for the 12V to 1.2V
at 12A output is about 2.8W. The 2.8W loss is calculated
with the ~2.35W room temperature loss from the 12V to
1.2V power loss curve at 12A, and the 1.2 multiplying
factor at 80°C ambient. If the 80°C ambient temperature
is subtracted from the 120°C junction temperature, then
the difference of 40°C divided by 2.8W equals a 14°C/W
θJA thermal resistance. Table 2 specifies a 13°C/W value
which is very close. Table 2 and Table 3 provide equivalent
3.0
6
5VIN TO 1.2VOUT POWER LOSS
12VIN TO 1.2VOUT POWER LOSS
2.0
1.5
1.0
4
3
2
1
0.5
0
5VIN TO 3.3VOUT POWER LOSS
12VIN TO 3.3VOUT POWER LOSS
5
POWER LOSS (W)
2.5
POWER LOSS (W)
thermal resistances for 1.2V and 3.3V outputs with and
without airflow and heat sinking. The derived thermal resistances in Tables 2 and 3 for the various conditions can
be multiplied by the calculated power loss as a function
of ambient temperature to derive temperature rise above
ambient, thus maximum junction temperature. Room
temperature power loss can be derived from the efficiency
curves in the Typical Performance Characteristics section
and adjusted with the above ambient temperature multiplicative factors. The printed circuit board is a 1.6mm thick
four layer board with two ounce copper for the two outer
layers and one ounce copper for the two inner layers. The
PCB dimensions are 95mm × 76mm. The BGA heat sinks
are listed in Table 4.
0
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
OUTPUT CURRENT (A)
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
OUTPUT CURRENT (A)
4627 F08
4627 F07
Figure 8. 3.3VOUT Power Loss
16
16
14
14
12
12
OUTPUT CURRENT (A)
OUTPUT CURRENT (A)
Figure 7. 1.2VOUT Power Loss
10
8
6
4
0 LFM
200 LFM
400 LFM
2
0
10
8
6
4
0
40
50
60
70
0 LFM
200 LFM
400 LFM
2
80
90 100 110 120 130
40
50
60
70
80
90 100 110 120 130
AMBIENT TEMPERATURE (°C)
AMBIENT TEMPERATURE (°C)
4627 F09
Figure 9. 5VIN to 1.2VOUT No Heat Sink
4627 F10
Figure 10. 5VIN to 1.2VOUT with Heat Sink
4627f
18
LTM4627
16
16
14
14
12
12
OUTPUT CURRENT (A)
OUTPUT CURRENT (A)
APPLICATIONS INFORMATION
10
8
6
4
10
8
6
4
0 LFM
200 LFM
400 LFM
2
0
40
50
60
70
0 LFM
200 LFM
400 LFM
2
80
0
90 100 110 120 130
40
50
60
70
80
90 100 110 120 130
AMBIENT TEMPERATURE (°C)
AMBIENT TEMPERATURE (°C)
4627 F12
4627 F10
Figure 12. 12VIN to 1.2VOUT with Heat Sink
14
14
12
12
OUTPUT CURRENT (A)
OUTPUT CURRENT (A)
Figure 11. 12VIN to 1.2VOUT No Heat Sink
10
8
6
4
0 LFM
200 LFM
400 LFM
2
0
40
50
60
70
10
8
6
4
0 LFM
200 LFM
400 LFM
2
80
0
90 100 110 120 130
40
50
AMBIENT TEMPERATURE (°C)
60
70
80
90 100 110 120 130
AMBIENT TEMPERATURE (°C)
4627 F14
Figure 13. 5VIN to 3.3VOUT No Heat Sink
Figure 14. 5VIN to 3.3VOUT with Heat Sink
16
16
14
14
12
12
OUTPUT CURRENT (A)
OUTPUT CURRENT (A)
4627 F13
10
8
6
4
0 LFM
200 LFM
400 LFM
2
0
40
50
60
70
10
8
6
4
0 LFM
200 LFM
400 LFM
2
80
90 100 110 120 130
AMBIENT TEMPERATURE (°C)
0
40
50
60
70
80
90 100 110 120 130
AMBIENT TEMPERATURE (°C)
4627 F15
Figure 15. 12VIN to 3.3VOUT No Heat Sink
4627 F16
Figure 16. 12VIN to 3.3VOUT with Heat Sink
4627f
19
LTM4627
APPLICATIONS INFORMATION
Table 2. 1.2V Output
DERATING
CURVE
VIN
POWER LOSS
CURVE
AIRFLOW
(LFM)
HEAT SINK
θJA (°C/W)
Figures 9, 11
5V, 12V
Figure 7
0
None
13
Figures 9, 11
5V, 12V
Figure 7
200
None
11
Figures 9, 11
5V, 12V
Figure 7
400
None
8
Figures 10, 12
5V, 12V
Figure 7
0
BGA Heat Sink
12
Figures 10, 12
5V, 12V
Figure 7
200
BGA Heat Sink
8
Figures 10, 12
5V, 12V
Figure 7
400
BGA Heat Sink
7
POWER LOSS
CURVE
AIRFLOW
(LFM)
HEAT SINK
θJA (°C/W)
Table 3. 3.3V Output
DERATING
CURVE
VIN
Figures 13, 15
5V, 12V
Figure 8
0
None
13
Figures 13, 15
5V, 12V
Figure 8
200
None
11
Figures 13, 15
5V, 12V
Figure 8
400
None
8
Figures 14, 16
5V, 12V
Figure 8
0
BGA Heat Sink
12
Figures 14, 16
5V, 12V
Figure 8
200
BGA Heat Sink
8
Figures 14, 16
5V, 12V
Figure 8
400
BGA Heat Sink
7
4627f
20
LTM4627
APPLICATIONS INFORMATION
Table 4. Output Voltage Response vs Component Matrix (Refer to Figure 18) 0A to 7.5A Load Step
VALUE
PART NUMBER
COUT1 AND COUT2
BULK VENDOR
VALUE
PART NUMBER
CIN
BULK VENDOR
VALUE
PART NUMBER
TDK
22μF 6.3V
C3216X7SOJ226M
Sanyo POSCAP
1000μF 2.5V
2R5TPD1000M5
Sanyo
56μF 25V
25SVP56M
Murata
22μF 16V
GRM31CR61C226KE15L
Sanyo POSCAP
470μF 2.5V
2R5TPD470M5
470μF 6.3V
6TPD470M
COUT1 AND COUT2
CERAMIC VENDOR
TDK
100μF 6.3V
C4532X5ROJ107MZ
Sanyo POSCAP
Murata
100μF 6.3V
GRM32ER60J107M
Sanyo POSCAP
VOUT
CIN
COUT1 (CERAMIC) AND
CIN
(V) (CERAMIC) (BULK)** COUT2 (CER AND BULK)
CFF
(pF)
VIN
(V)
CCOMP
(pF)
PEAK TO
PEAK
DROOP DEVIATION
(mV)
(mV)
RECOVERY
TIME(μs)
LOAD
STEP
(A/μs)
RFB
(kΩ)
FREQ.
(kHz)
1
22μF × 3
56μF
100μF × 2, 1000μF
68
150
5,12
50
100
30
7.5
90.9
400
1
22μF × 3
56μF
100μF × 2, 470μF × 2
82
150
5,12
50
100
20
7.5
90.9
400
1
22μF × 3
56μF
100μF × 4
82
33
5,12
52
108
18
7.5
90.9
400
1.2
22μF × 3
56μF
100μF × 2, 1000μF
82
150
5,12
40
80
20
7.5
60.4
400
1.2
22μF × 3
56μF
100μF, 470μF
82
150
5,12
60
120
20
7.5
60.4
400
1.2
22μF × 3
56μF
100μF × 2, 470μF × 2
82
150
5,12
40
80
25
7.5
60.4
400
1.2
22μF × 3
56μF
100μF × 4
82
33
5,12
50
114
20
7.5
60.4
400
1.5
22μF × 3
56μF
100μF × 2, 1000μF
82
150
5,12
60
120
23
7.5
40.2
400
1.5
22μF × 3
56μF
100μF, 470μF
82
47
5,12
67
130
20
7.5
40.2
400
1.5
22μF × 3
56μF
100μF × 2, 470μF × 2
82
150
5,12
60
120
25
7.5
40.2
400
1.5
22μF × 3
56μF
100μF × 3
82
33
5,12
65
130
20
7.5
40.2
400
1.8
22μF × 3
56μF
100μF × 2, 1000μF
68
150
5,12
64
130
25
7.5
30.1
400
1.8
22μF × 3
56μF
100μF, 470μF
82
150
5,12
76
135
22
7.5
30.1
400
1.8
22μF × 3
56μF
100μF × 2
82
none
5,12
66
132
20
7.5
30.1
400
2.5
22μF × 3
56μF
100μF × 2
82
none
5,12
88
164
30
7.5
19.1
500
2.5
22μF × 3
56μF
100μF, 470μF
82
150
5,12
100
200
25
7.5
19.1
500
3.3
22μF × 3
56μF
100μF × 2
82
none
5,12
100
200
30
7.5
13.3
600
3.3
22μF × 3
56μF
100μF, 470μF
82
150
5,12
100
200
30
7.5
13.3
600
5
22μF × 3
56μF
100μF × 2
68
none
12
125
250
20
7.5
8.25
700
5
22μF × 3
56μF
470μF
47
150
12
125
250
25
7.5
8.25
700
** Bulk capacitance is optional if VIN has very low input impedance.
HEAT SINK MANUFACTURER
PART NUMBER
WEBSITE
Wakefield Engineering
LTN20069
www.wakefield.com
AAVID Thermalloy
375424B00034G
www.aavidthermalloy.com
4627f
21
LTM4627
APPLICATIONS INFORMATION
Safety Considerations
The LTM4627 modules do not provide isolation from VIN
to VOUT. There is no internal fuse. If required, a slow blow
fuse with a rating twice the maximum input current needs
to be provided to protect each unit from catastrophic
failure. The device does support overvoltage protection
and overcurrent protection.
• Place a dedicated power ground layer underneath the
unit.
• To minimize the via conduction loss and reduce module
thermal stress, use multiple vias for interconnection
between top layer and other power layers.
• Do not put vias directly on the pad, unless they are
capped or plated over.
Layout Checklist/Example
• Place test points on signal pins for testing.
The high integration of the LTM4627 makes the PCB
board layout very simple and easy. However, to optimize
its electrical and thermal performance, some layout considerations are still necessary.
• Use a separated SGND ground copper area for components connected to signal pins. Connect the SGND
to GND underneath the unit.
• Use large PCB copper areas for high current paths,
including VIN, GND and VOUT. It helps to minimize the
PCB conduction loss and thermal stress.
• For parallel modules, tie the COMP and VFB pins together. Use an internal layer to closely connect these
pins together. Figure 17 gives a good example of the
recommended layout.
• Place high frequency ceramic input and output capacitors next to the VIN, GND and VOUT pins to minimize
high frequency noise.
VIN
CIN
CIN
CONTROL
CONTROL
GND
SIGNAL
GROUND
CONTROL
COUT
COUT
VOUT
VOUT
4627 F17
Figure 17. Recommended PCB Layout
4627f
22
LTM4627
TYPICAL APPLICATIONS
VIN
4.5V TO 20V
C3
22μF
25V
C1
22μF
25V
C2
22μF
25V
CCOMP
150pF
R1
10k
C7
0.1μF
VIN
EXTVCC INTVCC PGOOD
COMP
VOUT
TRACK/SS
RUN
R3
120k
CONTINUOUS
MODE
LTM4627
DIFF_OUT
fSET
VOSNS+
MODE_PLLIN
VOSNS–
SGND
GND
+
VOUT_LCL
CFF
82pF
COUT1
470μF
6.3V
s2
COUT2*
100μF
6.3V
VOUT
1.5V
15A
VFB
RFB
40.2k
*SEE TABLE 4
4627 TA02
Figure 18. 4.5V to 20VIN, 1.5V at 15A Design
4627f
23
24
R1
200k
C14
1μF
OUT1
SET
MOD
LTC6908-1
OUT2
GND
V+
INTVCC
R2
10k
VIN
7V TO 16V
C9
22μF
16V
C10
22μF
16V
C13
0.1μF
C1
22μF
16V
C2
22μF
16V
100k
SGND
GND
VOSNS–
MODE_PLLIN
VFB
VOSNS+
DIFF_OUT
fSET
RUN
LTM4627
VOUT_LCL
VOUT
TRACK/SS
EXTVCC INTVCC PGOOD
VFB
VIN
GND
VOSNS–
VOSNS+
DIFF_OUT
VOUT_LCL
COMP
SGND
MODE_PLLIN
fSET
RUN
LTM4627
VOUT
EXTVCC INTVCC PGOOD
TRACK/SS
270pF
100k
VIN
COMP
INTVCC
Figure 19. 1V at 30A, Two Parallel Outputs with 2-Phase Operation
CLOCK SYNC 180 PHASE
C3
22μF
16V
CLOCK SYNC 0 PHASE
C7
22μF
16V
INTVCC
4627 TA03
+
RFB1
45.3k
150pF
C4
470μF
6.3V
+
C6
100μF
6.3V
C8
470μF
6.3V
C11
100μF
6.3V
1V AT 30A
LTM4627
TYPICAL APPLICATIONS
4627f
LTM4627
TYPICAL APPLICATIONS
VIN
7V TO 16V
R1
10k
C20
22μF
16V
VIN
EXTVCC INTVCC PGOOD
VOUT
COMP
TRACK/SS
RUN
MODE_PLLIN
VOSNS–
SGND
V
C2
1μF
R2
100k
GND
+
DIFF_OUT
VOSNS+
INTVCC
+
LTM4627
VOUT_LCL
fSET
100k
4-PHASE CLOCK
VOUT
1.2V AT 60A
INTVCC
C22
22μF
16V C28
0.1μF
C21
470μF
6.3V
C24
100μF
6.3V
270pF
VFB
RFB2
15k
150pF
SET
LTC6902
MOD
DIV
PH
OUT1
OUT2
GND
OUT4
C14
22μF
16V
C18
22μF
16V
VIN
EXTVCC INTVCC PGOOD
VOUT
COMP
TRACK/SS
OUT3
RUN
VOSNS+
MODE_PLLIN
VOSNS–
SGND
C9
22μF
16V
GND
+
DIFF_OUT
fSET
100k
C7
22μF
16V
LTM4627
VOUT_LCL
C15
470μF
6.3V
C18
100μF
6.3V
INTVCC
VFB
VIN EXTVCC INTVCC PGOOD
VOUT
COMP
TRACK/SS
RUN
LTM4627
DIFF_OUT
fSET
VOSNS+
MODE_PLLIN
VOSNS–
100k
SGND
GND
+
VOUT_LCL
C8
470μF
6.3V
C11
100μF
6.3V
INTVCC
VFB
150pF
C3
22μF
16V
C1
22μF
16V
VIN EXTVCC INTVCC PGOOD
VOUT
COMP
TRACK/SS
RUN
LTM4627
DIFF_OUT
fSET
VOSNS+
MODE_PLLIN
VOSNS–
100k
SGND
GND
+
VOUT_LCL
C4
470μF
6.3V
C6
100μF
6.3V
INTVCC
VFB
4627 TA04
Figure 20. 1.2V, 60A, Current Sharing with 4-Phase Operation
4627f
25
LTM4627
PACKAGE DESCRIPTION
Pin Assignment Table
(Arranged by Pin Number)
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
PIN NAME
VIN
VIN
VIN
VIN
VIN
VIN
INTVCC
MODE_PLLIN
TRACK/SS
RUN
COMP
MTP1
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
B12
PIN NAME
VIN
VIN
VIN
VIN
VIN
VIN
GND
GND
MTP2
fSET
PIN NAME
C1 VIN
C2 VIN
C3 VIN
C4 VIN
C5 VIN
C6 VIN
C7 GND
C8 C9 GND
C10 MTP3
C11 MTP4
C12 MTP5
PIN NAME
D1 GND
D2 GND
D3 GND
D4 GND
D5 GND
D6 GND
D7 D8 GND
D9 INTVCC
D10 MTP6
D11 MTP7
D12 MTP8
PIN NAME
E1 GND
E2 GND
E3 GND
E4 GND
E5 GND
E6 GND
E7 GND
E8 E9 GND
E10 E11 E12 EXTVCC
PIN NAME
F1 GND
F2 GND
F3 GND
F4 GND
F5 GND
F6 GND
F7 GND
F8 GND
F9 GND
F10 F11 PGOOD
F12 VFB
G1
G2
G3
G4
G5
G6
G7
G8
G9
G10
G11
G12
PIN NAME
GND
GND
GND
GND
GND
GND
GND
GND
GND
SGND
PGOOD
H1
H2
H3
H4
H5
H6
H7
H8
H9
H10
H11
H12
PIN NAME
GND
GND
GND
GND
GND
GND
GND
GND
GND
SGND
SGND
PIN NAME
J1 VOUT
J2 VOUT
J3 VOUT
J4 VOUT
J5 VOUT
J6 VOUT
J7 VOUT
J8 VOUT
J9 VOUT
J10 VOUT
J11 J12 VOSNS+
PIN NAME
K1 VOUT
K2 VOUT
K3 VOUT
K4 VOUT
K5 VOUT
K6 VOUT
K7 VOUT
K8 VOUT
K9 VOUT
K10 VOUT
K11 VOUT
K12 DIFF_OUT
PIN NAME
L1 VOUT
L2 VOUT
L3 VOUT
L4 VOUT
L5 VOUT
L6 VOUT
L7 VOUT
L8 VOUT
L9 VOUT
L10 VOUT
L11 VOUT
L12 VOUT_LCL
PIN NAME
M1 VOUT
M2 VOUT
M3 VOUT
M4 VOUT
M5 VOUT
M6 VOUT
M7 VOUT
M8 VOUT
M9 VOUT
M10 VOUT
M11 VOUT
M12 VOSNS–
PACKAGE PHOTO
4627f
26
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.
6.9850
5.7150
4.4450
3.1750
1.9050
0.6350
0.0000
0.6350
1.9050
3.1750
4.4450
5.7150
6.9850
3.1750
0.630
SUGGESTED PCB LAYOUT
TOP VIEW
1.9050
PACKAGE TOP VIEW
0.6350
0.0000
0.6350
4
1.9050
PAD 1
CORNER
15
BSC
3.1750
aaa Z
6.9850
5.7150
4.4450
4.4450
5.7150
6.9850
15
BSC
Y
0.630
X
bbb Z
DETAIL B
4.22 – 4.42
DETAILS OF PAD #1 IDENTIFIER ARE OPTIONAL,
BUT MUST BE LOCATED WITHIN THE ZONE INDICATED.
THE PAD #1 IDENTIFIER MAY BE EITHER A MOLD OR
MARKED FEATURE
LAND DESIGNATION PER JESD MO-222, SPP-010
SYMBOL TOLERANCE
0.15
aaa
bbb
0.10
eee
0.05
6. THE TOTAL NUMBER OF PADS: 133
5. PRIMARY DATUM -Z- IS SEATING PLANE
4
3
2. ALL DIMENSIONS ARE IN MILLIMETERS
3
M
L
TRAY PIN 1
BEVEL
COMPONENT
PIN “A1”
PADS
SEE NOTES
1.27
BSC
13.97
BSC
0.12 – 0.28
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M-1994
DETAIL A
0.27 – 0.37
SUBSTRATE
eee S X Y
DETAIL B
0.630 ±0.025 SQ. 133x
aaa Z
3.95 – 4.05
MOLD
CAP
Z
(Reference LTC DWG # 05-08-1777 Rev Ø)
LGA Package
133-Lead (15mm × 15mm × 4.32mm)
K
G
F
E
LTMXXXXXX
μModule
PACKAGE BOTTOM VIEW
H
D
C
B
LGA 133 1008 REV Ø
A
DETAIL A
PACKAGE IN TRAY LOADING ORIENTATION
J
13.97
BSC
1
2
3
4
5
6
7
8
9
10
11
12
C(0.30)
PAD 1
LTM4627
PACKAGE DESCRIPTION
4627f
27
LTM4627
TYPICAL APPLICATION
3.3V at 10A Design
5V
C3
22μF
16V
C1
22μF
16V
C2
22μF
16V
C7
0.1μF
R1
10k
VIN
EXTVCC INTVCC PGOOD
COMP
VOUT
TRACK/SS
RUN
R3
174k
CONTINUOUS
MODE
LTM4627
DIFF_OUT
fSET
VOSNS+
MODE_PLLIN
VOSNS–
SGND
GND
C4
100μF
X5R
VOUT_LCL
82pF
C6
100μF
X5R
6.3V
VOUT
3.3V
10A
5V
VFB
RFB
13.3k
C5
47pF
4627 TA05
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTM4600
10A DC/DC μModule Regulator
Basic 10A DC/DC μModule
LTM4601A
12A DC/DC μModule Regulator with PLL,
Output Tracking/ Margining and Remote Sensing
Synchronizable, PolyPhase Operation to 48A, Pin Compatible with the
LTM4627
LTM4602
6A DC/DC μModule Regulator
Pin Compatible with the LTM4600
LTM4603
6A DC/DC μModule Regulator with PLL and
Output Tracking/Margining and Remote Sensing
Synchronizable, PolyPhase Operation, LTM4603-1 Version Has No
Remote Sensing, Pin Compatible with the LTM4601
LTM4604A
4A Low Voltage DC/DC μModule Regulator
2.375V ≤ VIN ≤ 5.5V; 0.8V ≤ VOUT ≤ 5V,
9mm × 15mm × 2.3mm (Ultrathin) LGA Package
LTM4605
Buck-Boost DC/DC μModule Family
All Pin Compatible; Up to 5A; Up to 36VIN, 34VOUT 15mm × 15mm × 2.8mm
LTM4606
Ultralow Noise 6A DC/DC μModule Regulator
4.5V ≤ VIN ≤ 28V, 0.6V ≤ VOUT ≤ 5V, 15mm × 15mm × 2.8mm Package
LTM4607
Buck-Boost DC/DC μModule Family
All Pin Compatible; Up to 5A; Up to 36VIN, 34VOUT 15mm × 15mm × 2.8mm
LTM4608A
8A Low Voltage DC/DC μModule Regulator
2.7V ≤ VIN ≤ 5.5V; 0.6V ≤ VOUT ≤ 5V; 9mm × 15mm × 2.8mm LGA Package
LTM4609
Buck-Boost DC/DC μModule Family
All Pin Compatible; Up to 5A; Up to 36VIN, 34VOUT 15mm × 15mm × 2.8mm
LTM4612
Ultralow Noise High VOUT DC/DC μModule Regulator
5A, 5V ≤ VIN ≤ 36V, 3.3V ≤ VOUT ≤ 15V, 15mm × 15mm × 2.8mm Package
LTM8023
36V, 2A DC/DC μModule Regulator
3.6V ≤ VIN ≤ 36V, 0.8V ≤ VOUT ≤ 10V, 9mm × 11.75mm × 2.8mm Package
LTM8032
Ultralow Noise 36V, 2A DC/DC μModule Regulator
EN55022 Class B Compliant; 0.8V ≤ VOUT ≤ 10V; 3.6V ≤ VIN ≤ 36V;
9mm × 15mm × 2.8mm
4627f
28 Linear Technology Corporation
LT 0810 • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900
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