LTM4691
Low VIN, High Efficiency, Dual 2A
Step-Down DC/DC µModule Regulator
FEATURES
DESCRIPTION
Tiny Surface Mount, Low Profile 3mm × 4mm ×
1.18mm LGA Package and 3mm × 4mm × 1.48mm
BGA Package
n Input Voltage Range: 2.25V to 3.6V
n Dual 2A DC Output Current
n ±1.5% Total Output Voltage Regulation
n Current Mode Control, Fast Transient Response
n External Frequency Synchronization
n 180° Out-of-Phase Operation
n Selectable Pulse-Skipping Mode/Burst Mode®
Operation/Forced Continuous Mode
n Power Good Indicator
n Internal Soft-Start
n Internal Compensation
n Overvoltage, Overcurrent and Overtemperature
Protection
The LTM®4691 is a complete dual 2A output switching mode DC/DC power supply in a tiny 3mm × 4mm
× 1.18mm LGA package and a 3mm × 4mm × 1.48mm
BGA package. Included in the package are the switching controller, power FETs, inductors and all supporting
components. Operating over an input voltage range of
2.25V to 3.6V, the LTM4691 supports two outputs with
programmable output voltage range from 0.5V to 2.5V set
by external resistors. Its high efficiency design delivers up
to 2A continuous current on each output. Only bulk input
and output capacitors are needed.
n
APPLICATIONS
The LTM4691 operates in forced continuous mode for low
noise pulse-skipping mode or Burst Mode operation for
high efficiency at lights loads. The typical buck switching
frequency is 2MHz and can be synchronized from 1MHz to
3MHz. Its high switching frequency and a current mode
architecture enables a very fast transient response to line
and load changes without sacrificing stability.
Other features include precision run thresholds, a PGOOD
signal, output overvoltage protection, thermal shutdown
and output short-circuit protection. The LTM4691 is
Pb-free and RoHS compliant.
Telecom, Networking and Industrial Equipment
Point-of-Load Regulation
n FPGA, ASIC Core Supplies
n
n
All registered trademarks and trademarks are the property of their respective owners.
TYPICAL APPLICATION
Dual 2A DC/DC μModule Regulator
VIN
VOUT1
1.2V, 2A
VOUT1
10µF
140k
10µF
VOUT2
1.8V, 2A
VOUT2
261k
RUN2
MODE/SYNC
GND
fSW = 2MHz
FB2
PGOOD
1.2pF
22µF
0.5
80
22µF
100k
LTM4691
0.6
EFFICIENCY
70
60
50
0.4
Burst Mode OPERATION
VIN = 3.3V, VOUT = 1.8V
fSW = 2MHz
CH1 OFF
0.3
40
0.2
30
20
100k
4691 TA01a
10
0
0.001
POWER LOSS (W)
FB1
RUN1
VIN
2.7pF
90
EFFICIENCY (%)
VIN
2.25V TO 3.6V
Efficiency vs Load Current
100
0.1
POWER LOSS
0.01
0.1
1
LOAD CURRENT (A)
10
0
4691 TA01b
Rev. A
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1
LTM4691
TABLE OF CONTENTS
Features............................................................................................................................. 1
Applications........................................................................................................................ 1
Typical Application ................................................................................................................ 1
Description......................................................................................................................... 1
Absolute Maximum Ratings...................................................................................................... 3
Order Information.................................................................................................................. 3
Pin Configuration.................................................................................................................. 3
Electrical Characteristics......................................................................................................... 4
Typical Performance Characteristics........................................................................................... 6
Pin Functions....................................................................................................................... 8
Block Diagram...................................................................................................................... 9
Decoupling Requirements........................................................................................................ 9
Operation..........................................................................................................................10
Applications Information........................................................................................................11
VIN to VOUT Step-Down Ratios............................................................................................................................... 11
Output Voltage Programming................................................................................................................................ 11
Input Decoupling Capacitors.................................................................................................................................. 11
Output Decoupling Capacitors............................................................................................................................... 11
Mode Selection ..................................................................................................................................................... 11
Operating Frequency and External Synchronization .............................................................................................. 12
Power GOOD ......................................................................................................................................................... 12
Output Overvoltage Protection............................................................................................................................... 12
Output Voltage Soft-Start....................................................................................................................................... 13
Dropout Operation ................................................................................................................................................ 13
Output Short-Circuit Protection and Recovery....................................................................................................... 13
Load Sharing......................................................................................................................................................... 13
Using the Precision RUN Threshold ...................................................................................................................... 13
Thermal Considerations and Output Current Derating........................................................................................... 14
Safety Considerations............................................................................................................................................ 17
Layout Checklist/Example...................................................................................................................................... 17
Applications Information........................................................................................................18
Typical Applications..............................................................................................................19
Pin Configuration Table..........................................................................................................20
LTM4691 Component LGA and BGA Pinout.......................................................................................................... 20
Package Description.............................................................................................................21
Revision History..................................................................................................................23
Package Photo....................................................................................................................24
Related Parts......................................................................................................................24
Rev. A
2
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LTM4691
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Note 1)
(See Pin Functions, Pin Configuration Table)
Operating Junction Temperature
(Note 2).............................................. –40°C to 125°C
Storage Temperature Range................... –55°C to 125°C
Peak Solder Reflow Body Temperature.................. 260°C
VIN................................................................ –0.3V to 4V
VOUT1, VOUT2.............................................. –0.3V to 2.5V
PGOOD, RUN1, RUN2, MODE/SYNC,
FB1, FB2.................................................... –0.3V to 4V
TOP VIEW
A
B
C
SGND2
FB2
PGOOD RUN2
TOP VIEW
FB1
SGND1
RUN1
MODE/
SYNC
A
B
VIN
VIN
C
SGND2
FB2
PGOOD RUN2
SGND1
RUN1
MODE/
SYNC
VIN
VIN
GND
GND
D
D
E
F
FB1
E
VOUT2
VOUT1
F
1
2
3
4
LGA PACKAGE
24-LEAD (3mm × 4mm × 1.18mm) LGA PACKAGE
TJMAX = 125°C, θJA = 40.4°C/W,
θJCtop = 47.9°C/W, θJCbot = 8.5°C/W
WEIGHT = 0.042gram
VOUT2
VOUT1
1
2
3
4
BGA PACKAGE
24-LEAD (3mm × 4mm × 1.48mm) BGA PACKAGE
TJMAX = 125°C, θJA = 40°C/W,
θJCtop = 50°C/W, θJCbot = 8.5°C/W
WEIGHT = 0.048gram
NOTES:
1. θ VALUES ARE DETERMINED BY SIMULATION PER JESD-51 CONDITIONS.
2. θJA VALUE IS OBTAINED WITH DEMO BOARD.
3. REFER TO PAGE 17 FOR LAB MEASUREMENT AND DE-RATING INFORMATION.
NOTES:
1. θ VALUES ARE DETERMINED BY SIMULATION PER JESD-51 CONDITIONS.
2. θJA VALUE IS OBTAINED WITH DEMO BOARD.
3. REFER TO PAGE 17 FOR LAB MEASUREMENT AND DE-RATING INFORMATION.
ORDER INFORMATION
PART MARKING
PART NUMBER
LTM4691EV#PBF
LTM4691IV#PBF
LTM4691EY#PBF
LTM4691IY#PBF
PAD OR BALL FINISH
DEVICE
Au (RoHS)
4691V
FINISH CODE
JDEC
FINISH CODE
PACKAGE
TYPE
e4
LGA
v
SAC305 (RoHS)
4691Y
• Contact the factory for parts specified with wider operating
temperature ranges. *Pad or ball finish code is per IPC/JEDEC
J-STD-609.
MSL
RATING
3
e1
TEMPERATURE RANGE
–40°C to 125°C
BGA
• Recommended LGA and BGA PCB Assembly and Manufacturing Procedures
• LGA and BGA Package and Tray Drawings
Rev. A
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3
LTM4691
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C (Note 2), VIN = 3.3V, per the typical application.
SYMBOL
PARAMETER
VIN
Input DC Voltage
VOUT1,2(RANGE)
Output Voltage Range
VOUT1,2(DC)
Output Voltage, Total Variation with
Line and Load
VIN_UVLO
VIN Undervoltage Lockout
CONDITIONS
MIN
l
VIN_UVLO_HYS
VIN Undervoltage Lockout Hysteresis
VRUN1,2
RUN Pin On-Threshold
VRUN1HYS/VRUN2HYS
RUN Pin Hysteresis
IRUN1,2
RUN Pin Leakage Current
TYP
2.25
MAX
3.6
V
2.5
V
1.523
V
VIN = 2.25V to 3.6V
l
0.5
MODE/SYNC = Float
VIN = 2.5V to 3.6V
IOUT = 0A to 2A, VIN = 2.5V
l
1.477
1.50
VIN Rising
2.05
2.15
2.25
V
VRUN Rising
0.375
150
0.4
mV
0.425
50
RUN = 3.6V
VIN Quiescent
Current in Shutdown
UNITS
V
mV
±100
nA
VIN = 3.6V, RUN = 0V
1.5
μA
85
2.6
32
μA
mA
mA
IQ(VIN) with Both
Bucks Enabled
Input Supply Bias Current
VOUT = 1.5V, MODE/SYNC = VIN
MODE/SYNC = GND
MODE/SYNC = FLOAT
IOUT1,2(DC)
Output Continuous Current Range
VOUT = 1.5V (Note 3)
∆VOUT1(LINE)/VOUT1
∆VOUT2(LINE)/VOUT2
Line Regulation Accuracy
∆VOUT1(LOAD)/VOUT1
∆VOUT2(LOAD)/VOUT2
0
2
A
VOUT = 1.5V, VIN = 2.25V to 3.6V, IOUT = 0A
l
0.001
0.5
%/V
Load Regulation Accuracy
VOUT = 1.5V, IOUT = 0A to 2A
VIN = 2.5V
l
0.2
1.5
%
VOUT1,2(AC)
Output Ripple Voltage
IOUT = 0A, COUT = 22μF Ceramic
VIN = 3.3V, VOUT = 1.5V
5.5
mV
∆VOUT(START)
(Each Channel)
Turn-On Overshoot
IOUT = 0A, COUT = 22μF Ceramic
VIN = 3.3V, VOUT = 1.5V
12
mV
tSTART
(Each Channel)
Turn-On Time
COUT = 22μF Ceramic,
No Load, VIN = 3.3V, VOUT = 1.5V
(Note 4)
1
ms
∆VOUTLS
(Each Channel)
Peak Deviation for Dynamic Load
Load: 0% to 50% to 0% of Full Load
COUT = 100μF Ceramic, VIN = 3.3V, VOUT = 1.5V
55
mV
tSETTLE
(Each Channel)
Settling Time for Dynamic Load Step
Load: 0% to 50% to 0% of Full Load
COUT = 100μF Ceramic, VIN = 3.3V, VOUT = 1.5V
25
μs
IOUT1PK, IOUT2PK
Output Current Limit
VIN = 3.3V, VOUT = 1.5V
VFB1,2
Voltage at FB Pin
IOUT = 0A, VOUT = 1.5V
IFB1,2
Current at FB Pin
PGOOD
Threshold/HYS
PGOOD Rising Threshold
PGOOD Hysteresis
Overvoltage Rising Threshold
Overvoltage Hysteresis
As a Percentage of the Regulated VFB
VPGOOD = 3.6V
2.8
l
Internal PGOOD Leakage
Oscillator Frequency
MODE/SYNC
Threshold
Programming Pulse-Skipping Mode
l
Programming Burst Mode Operation
l
SYNC Frequency Range
Clock Level High on SYNC
Clock Level Low on SYNC
A
0.505
V
±20
nA
–3.5
%
%
%
%
14
±100
IPGOOD
SYNC_RANGE
0.50
–2.5
1.1
10
2
fOSC
SYNC_LEVEL
0.495
2
0.1
VIN
– 0.1
1
1.2
nA
MHz
V
V
3
0.4
MHz
V
V
Rev. A
4
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LTM4691
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 LTM4691 is tested under pulsed load conditions such that
TJ ≈ TA. The LTM4691E 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 LTM4691I is guaranteed to meet specifications over the
full –40°C to 125°C internal operating 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 resistance and other environmental
factors.
Note 3: See output current derating curves for different VIN, VOUT and TA.
Note 4: Guaranteed by design.
Rev. A
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5
LTM4691
TYPICAL PERFORMANCE CHARACTERISTICS
Efficiency vs Load Current
at Different Modes of Operation
VIN = 3.3V, VOUT = 1.2V
Efficiency vs Load at Different
Modes of Operation
VIN = 3.3V, VOUT = 1.8V
100
100
Burst Mode OPERATION
90
80
PULSE-SKIPPING
70
EFFICIENCY (%)
EFFICIENCY (%)
80
60
50
40
30
FORCED CONTINUOUS
60
50
40
FORCED CONTINUOUS
30
20
10
10
0.010
0.100
1.000
LOAD CURRENT (A)
PULSE-SKIPPING
70
20
0
0.001
Burst Mode OPERATION
90
0
0.001
10.0
0.010
0.100
1.000
LOAD CURRENT (A)
4691 G01
4691 G02
Efficiency vs Load Current
at 2.25VIN, Channel 2 off
Efficiency vs Load Current
at 3.3VIN, Channel 2 off
100
FORCED CONTINUOUS MODE
95
95
90
90
EFFICIENCY (%)
EFFICIENCY (%)
100
85
80
0.8VOUT
1.0VOUT
1.2VOUT
1.5VOUT
1.8VOUT
75
70
0
0.5
FORCED CONTINUOUS MODE
85
0.8VOUT
1.0VOUT
1.2VOUT
1.5VOUT
1.8VOUT
2.5VOUT
80
75
1
1.5
LOAD CURRENT (A)
70
2
0
0.5
1
1.5
LOAD CURRENT (A)
2
4691 G04
4691 G05
Efficiency vs Load Current
at 2.25VIN, Both Channels On
100
FORCED CONTINUOUS MODE
95
95
90
90
EFFICIENCY (%)
EFFICIENCY (%)
100
85
80
0.8VOUT
1.0VOUT
1.2VOUT
1.5VOUT
1.8VOUT
75
70
0
0.5
Efficiency vs Load Current
at 3.3VIN, Both Channels On
FORCED CONTINUOUS MODE
85
80
0.8VOUT
1.0VOUT
1.2VOUT
75
1
1.5
LOAD CURRENT (A)
10.0
2
70
0
0.5
4691 G07
1
1.5
LOAD CURRENT (A)
1.5VOUT
1.8VOUT
2.5VOUT
2
4691 G08
Rev. A
6
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LTM4691
TYPICAL PERFORMANCE CHARACTERISTICS
Transient Response, PulseSkipping Mode
Transient Response, Forced
Continuous Mode
Transient Response, Burst Mode
Operation
VOUT
100mV/DIV
AC-COUPLED
VOUT
100mV/DIV
AC-COUPLED
VOUT
100mV/DIV
AC-COUPLED
LOAD STEP
CURRENT
1A/DIV
LOAD STEP
CURRENT
1A/DIV
20µs/DIV
LOAD STEP
CURRENT
1A/DIV
4691 G07
4691 G08
20µs/DIV
20µs/DIV
4691 G09
LOAD STEP: 0.1A TO 1.5A
VIN = 3.3V
VOUT = 1.2V
LOAD STEP: 0.1A TO 1.5A
VIN = 3.3V
VOUT = 1.2V
LOAD STEP: 0.1A TO 1.5A
VIN = 3.3V
VOUT = 1.2V
Start-Up Transient, No Load
Start-Up Transient, Full Load
Start-Up with Prebiased Output
VOUT
1V/DIV
VOUT
1V/DIV
RUN
5V/DIV
PGOOD
5V/DIV
RUN
2V/DIV
RUN
2V/DIV
VOUT
1V/DIV
IIN
200mA/DIV
IIN
200mA/DIV
1ms/DIV
IIN
100mA/DIV
4691 G10
VIN = 3.3V
VOUT = 1.2V
4691 G11
1ms/DIV
500μs/DIV
VIN = 3.3V
VOUT = 1.2V
RLOAD = 0.6Ω
4691 G12
VIN = 3.3V
VOUT = 1.2V
Short-Circuit, No Load
Short-Circuit, Full Load
VOUT
1V/DIV
VOUT
1V/DIV
IIN
1A/DIV
IIN
200mA/DIV
50μs/DIV
VIN = 3.3V
VOUT = 1.2V
4691 G13
50µs/DIV
4691 G14
VIN = 3.3V
VOUT = 1.2V
Rev. A
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7
LTM4691
PIN FUNCTIONS
PACKAGE ROW AND COLUMN LABELING MAY VARY
AMONG µModule PRODUCTS. REVIEW EACH PACKAGE
LAYOUT CAREFULLY.
VIN (C4, C1): Power Input Pins. Both VIN pins are internally connected and must be connected with a short.
Each VIN should have its own input bypass capacitors.
Recommend placing input decoupling capacitors as close
as possible to the pins.
VOUT1 (E4, F3, F4), VOUT2 (E1, F1, F2): Power Output
Pins of Each Switching Mode Regulator. Apply output load
between these pins and GND pins. Recommend placing
output decoupling capacitance directly between these
pins and GND pins.
GND (C2, C3, D1, D2, D3, D4, E2, E3): Power Ground
Pins for Both Input and Output Returns.
SGND1 (A4), SGND2 (A1): Signal Ground Connection
PGOOD (B1): Power Good Output. Open-drain output.
When the regulated output voltage of either switching
regulator falls below its PGOOD threshold or rises above
its overvoltage threshold, this pin is driven low.
RUN1 (B3), RUN2 (B2): Run Control Input of Each
Switching Mode Regulator Channel. It has a precision
threshold and an optional external resistor divider from
VIN or another supply programs when each channel is
enabled. If the precision threshold is not required, drive
RUN1, RUN2 to VIN to enable. Do Not Float.
FB1 (A3), FB2 (A2): The Negative Input of the Error
Amplifier for the switching Mode Regulator Channel. The
LTM4691 regulates the voltage between FB and SGND
to 500mV. A resistor divider connecting to VOUT sets the
output voltage.
MODE/SYNC (B4): Mode Selection and External Clock
Synchronization Input. Ground this pin to enable pulseskipping mode. For higher efficiency at light loads, tie
this pin to VIN to enable Burst Mode. For fast transient
response and constant frequency operation over a wide
load range, float this pin to enable forced continuous
mode. Drive MODE/SYNC with an external clock to synchronize both buck converters to the applied frequency.
When syncing, the operating mode is forced continuous.
The slope compensation is automatically adapted to the
external clock frequency. In the absence of an external
clock both buck converters will switch at the default
switching frequency.
Rev. A
8
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LTM4691
BLOCK DIAGRAM
VIN
BUCK1
B3
RUN1
0.4V
B4
+
–
ENBUCK1
OT
MODE/SYNC
SWITCH
LOGIC
AND
ANTISHOOT
THROUGH
BUCK
CONTROL
0°
OSCILLATOR
VC
PULSE SKIP
MODE
DETECTION
FC
+
–
GM
0.47μH
0.5V
FB1
0.55V
0.4V
+
–
0.55V
VIN
BUCK2
0.5V
A3
C1
0.49V
180°
0.4V
B2
VOUT1
E4, F3, F4
BURST
INTERNAL
REFERENCE
RUN2
C4
OVER
TEMPERATURE
DETECT
ENBUCK2
OT
SWITCH
LOGIC
AND
ANTISHOOT
THROUGH
BUCK
CONTROL
VC
+
–
+
–
GM
0.47μH
VOUT2
E1, F1, F2
0.5V
FB2
A2
FB1
0.49V
0.55V
+
–
+
–
PGOOD
B1
ENBUCK1
ENBUCK2
FB2
0.49V
+
–
GND: C2, C3, D1, D2, D3, D4, E2, E3
4691 BD
DECOUPLING REQUIREMENTS
SYMBOL
PARAMETER
CONDITIONS
MIN
CIN
COUT1,2
TYP
MAX
UNITS
External Input Capacitor Requirement
(VIN = 2.25V to 3.6V, VOUT = 1.5V)
IOUT = 2A
(Each Channel)
10
(For Each Channel)
µF
External Output Capacitor Requirement
(VIN = 2.25V to 3.6V, VOUT = 1.5V)
IOUT = 2A
22
µF
Rev. A
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9
LTM4691
OPERATION
The LTM4691 is a dual standalone non-isolated switching
mode DC/DC power supply. Each channel can deliver up to
2A of DC output current with few external input and output capacitors. This module provides precisely regulated
output voltage programmable via external resistor divider
from 0.5V to 3.6V over 2.5V to 3.6V input voltage range.
The typical application schematic is shown on page 1.
The LTM4691 integrates two constant frequency peak
current mode regulators, power MOSFETs, inductors,
and other supporting discrete components. The typical
switching frequency of the LTM4691 is 2MHz, it can be
externally synchronized to a clock from 1MHz to 3MHz.
See the Applications Information section.
With current mode control and internal feedback loop
compensation, the LTM4691 module has sufficient stability margins and good transient performance with minimum output capacitors. Current mode control provides
cycle-by-cycle fast current limiting. Peak current limiting is provided in an over-current condition. Each buck
switching regulator has its own internal PGOOD signal.
If either enabled buck’s internal PGOOD signal stays low
for greater than 120µs, then the PGOOD pin is pulled
low indicating to a microprocessor that a power fault has
occurred.
The RUN pins have precision 400mV threshold with 50mV
hysteresis. It can be used to provide event-based power
up sequencing by connecting the RUN pin to the output
of another buck through a resistor divider. If the RUN pin
of a buck is low, that buck is shut down and in a low quiescent current state. If both RUN pins are low, both bucks
are in shutdown, the SW pins are high impedance, and
the quiescent current of the LTM4691 is less than 1μA.
If either pin is above the enable threshold of 400mV, its
respective buck is enabled.
All buck regulators have forward and reverse-current limiting, soft-start to limit inrush current during start-up, and
short-circuit protection. When both bucks are disabled
and either back is enabled, there is a 400μs (typical) delay
while internal circuitry powers up followed by a 100μs
(typical) no start-time before switching commences and
the soft-start ramp begins. If a second buck is enabled, it
will also have a 100μs (typical) no start-time. If the second
buck is enabled within 400μs of the first buck, it will wait
until the expiry of the 400μs to begin its no start-time.
The buck switching regulators are 180° out of phase with
respect to each other. The phase determines the fixed
edge of the switching sequence, which is when the internal top PMOS turns on. The PMOS off (NMOS on) phase
is subject to the duty cycle demanded by the regulator.
Rev. A
10
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LTM4691
APPLICATIONS INFORMATION
The typical LTM4691 application circuit is shown on
page 1. External component selection is primarily determined by the input voltage, the output voltage and the
maximum load current. Refer to Table 4 for specific external capacitor requirements for a particular application.
VOUT
BUCK
SWITCHING FB
REGULATOR
RTOP
CFF
+
COUT
RBOT
4691 F01
VIN to VOUT Step-Down Ratios
There are restrictions in the minimum VOUT step-down
ratio that can be achieved for a given input voltage due to
the minimum on-time limits of the regulator.
The minimum on-time limit imposes a minimum duty
cycle of the converter which can be calculated using
Equation 1.
(1)
D
=t
•f
MIN ON(MIN) SW
where tON(MIN) is the minimum on-time, 35ns typical for
LTM4691. In rare cases where the minimum duty cycle
is surpassed, the output voltage will remain in regulation, but the switching frequency will decrease from its
programmed value.
Figure 1. Feedback Components
Input Decoupling Capacitors
The LTM4691 module should be connected to a low
AC-impedance DC source. For the regulator, one-piece
10µF input ceramic capacitor near each VIN pin is recommended for RMS ripple current decoupling. Bulk input
capacitor is only needed when the input source impedance is compromised by long inductive leads, traces or
not enough source capacitance. The bulk capacitor can be
an electrolytic aluminum capacitor and polymer capacitor.
Without considering the inductor current ripple, the RMS
current of the input capacitor can be estimated as shown
in Equation 3.
IOUT(MAX)
There is no maximum VOUT step-down ratio limitation for
the LTM4691. Operating at 100% duty-cycle low dropout,
the output voltage of the LTM4691 could be as high as
2.5V.
Output Voltage Programming
Output Decoupling Capacitors
The PWM controller has an internal 0.5V reference voltage. Adding a resistor divider from VOUT remote sensing
point to FB pin and from FB pin to SGND pin programs
the output voltage as shown in Equation 2.
With an optimized high frequency, high bandwidth
design, only one 22μF low ESR output ceramic capacitor
is required for LTM4691 to achieve low output voltage
ripple and very good transient response. Additional output
filtering may be required by the system designer, if further
reduction of output ripples 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 500mA (25%) load step transient.
R
+ RBOT
VOUT = 0.5V • TOP
RBOT
(2)
1% resistors are recommended to maintain output voltage accuracy. The buck regulator transient response may
improve with an optional phase lead capacitor CFF that
helps cancel the pole created by the feedback resistors
and the input capacitance of the FB pin (Figure 1).
ICIN(RMS) =
η%
• D • (1– D)
(3)
where η% is the estimated efficiency of the power module.
Mode Selection
The buck switching regulators can operate in three different modes by setting the MODE/SYNC pin: pulse-skipping
mode (when the MODE/SYNC pin is set low), forced continuous PWM mode (when the MODE/SYNC pin is floating), and Burst Mode operation (when the MODE/SYNC
Rev. A
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11
LTM4691
APPLICATIONS INFORMATION
pin is set high). The MODE/SYNC pin sets the operating
mode for both buck switching regulators.
In pulse-skipping mode, the oscillator operates continuously and positive SW transitions are aligned to the clock.
Negative inductor current is not allowed and during light
loads switch pulses are skipped to regulate the output.
In forced continuous mode, the oscillator runs continuously. To maintain regulation, the inductor current is
allowed to reverse under light load conditions. This mode
allows the buck to run at a fixed frequency with minimal
output ripple.
In Burst Mode operation, at light loads, the output capacitor is charged to a voltage slightly higher than its regulation point. The regulator then goes into a sleep state,
during which time the output capacitor provides the load
current. In sleep, most of the regulator’s circuitry is powered down, helping to conserve input power. When the
output voltage drops below its programmed value, the
circuitry is powered on and another burst cycle begins.
The sleep time decreases as load current increases. In
Burst Mode operation, the regulator will burst at light
loads whereas at higher loads it will operate in constant
frequency PWM mode.
Operating Frequency and External Synchronization
The operating frequency of the LTM4691 is optimized
to achieve the compact package size and the minimum
output ripple voltage while still keeping high efficiency.
The default frequency is internally set to 2MHz. If any
operating frequency other than 2MHz is required, it can
be synchronized to an external clock from 1MHz to 3MHz.
The LTM4691’s internal oscillator is synchronized through
an internal PLL circuit to an external frequency by applying a square wave clock signal to the MODE/SYNC pin.
After detecting an external clock on the SYNC pin, the
internal PLL starts up at default frequency, then gradually
adjusts its operating frequency to match the frequency
of the SYNC signal. During synchronization, the buck 1
PMOS turns on is locked to the rising edge of the external
frequency source. Buck 2 will be 180° out of the phase
with respect to buck 1. While syncing, the buck switching
regulators operate in forced continuous mode.
When the external clock is removed, the LTM4691 will
detect the absence of the external clock within approximately 10µs. During this time, it will continue to provide
clock cycles. Once the external clock removal has been
detected, the oscillator will gradually adjust to its operating frequency back to the default.
Power GOOD
Power failure conditions are reported back via the PGOOD
pin. Both buck switching regulators have an internal power
good (PGOOD) signal and if a buck is enabled, its internal
PGOOD signal must be high for PGOOD pin to be high.
When the regulated output voltage of an enabled buck
rises above 98% of its programmed value the PGOOD
signal transitions high. If the regulated output voltage
subsequently falls below 97% of the programmed value
the PGOOD signal is pulled low. If either enabled buck’s
internal PGOOD signal stays low for greater than 120μs,
then the PGOOD pin is pulled low, indicating to a microprocessor that a power failure fault has occurred. The
120μs filter time prevents the pin from being pulled low
during a load transient. In addition, whenever PGOOD
transitions high there will be a 120μs assertion delay.
The LTM4691 also reports overvoltage conditions at the
PGOOD pin. If either enabled buck regulators output voltages rises above 110% of the programmed value, the
PGOOD pin is pulled low after 120μs. Similarly, if both
enabled outputs that are overvoltage subsequently fall
below 107.8% of the programmed value, the PGOOD pin
transitions high again after 120μs.
PGOOD is also low in the following scenarios: if neither buck switching regulator is enabled, if VIN is
below the UVLO threshold, or if the LTM4691 is in
overtemperature condition.
Output Overvoltage Protection
During an output overvoltage event, when the FB pin
voltage is greater than 110% of its regulated value, the
LTM4691 PMOS will be turned off immediately.
An output overvoltage event should not happen under
normal operating conditions.
Rev. A
12
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LTM4691
APPLICATIONS INFORMATION
Output Voltage Soft-Start
Using the Precision RUN Threshold
Soft-starting the output is needed to prevent current surge
on the input supply and output voltage overshoot.
The LTM4691 has precision threshold RUN pins for each
buck regulator to enable or disable each buck. When both
are forced low, the device enters into a low current shutdown mode.
The LTM4691 has internal soft-start, during soft-start,
the output voltage will proportionally track an internal
voltage ramp. An active pull-down circuit discharges that
internal voltage in the case of fault conditions. The ramp
will restart when the fault is cleared. Fault conditions that
clear the soft-start ramp are the RUN pin goes low, VIN
voltage falling too low or thermal shutdown.
Dropout Operation
As the input supply voltage approaches the output voltage, the duty cycle increase toward 100%. Further reduction of the supply voltage forces the PMOS to remain on
for more than one cycle, eventually reaching 100% duty
cycle. The output voltage will then be determined by the
input voltage minus the DC voltage drop across the internal PMOS and the inductor.
Output Short-Circuit Protection and Recovery
The peak inductor current level at which the current comparator shuts off the PMOS is controlled by the error
amplifier. When the output current increase, the error
amplifier raised the internal VC voltage until the average
inductor current matches the load current. The LTM4691
clamps the maximum internal VC voltage, thereby limiting
the peak inductor current. The LTM4691 can not be paralleled due to the VC node being internal and not accessible.
When the output is shorted to ground, the inductor current decays very slowly because the voltage across the
inductor current is low during the downslope. To keep the
inductor current in control a secondary limit is imposed
on the valley of the inductor current. If the inductor current measured through the NMOS remains greater than
IVALLEY at the end of the cycle, the PMOS will be held
off. Subsequent switching cycles will be skipped until the
inductor current falls below IVALLEY.
Load Sharing
The LTM4691 is not designed to load share.
The rising threshold of both RUN comparators is 400mV,
with 50mV of hysteresis. The RUN pins can be tied to
VIN if the shutdown feature is not used. Adding a resistor
divider from VIN to a RUN pin to ground programs the
LTM4691 to regulate that output only when VIN is above
a desired voltage.
Typically, this threshold (VIN(RUN)) is used in situations
where the input supply is current limited or has a relatively high source resistance. A switching regulator draws
near constant power from its input source, so source current increases as source voltage drops. This looks like
a negative resistance load to the source and can cause
the source to current limit or latch low under low source
voltage conditions. The VIN(RUN) threshold prevents the
regulator from operating at source voltages where problems may occur. As illustrated in Figure 2, this threshold
can be adjusted by setting the values of R1 and R2 such
that they satisfy Equation 4.
⎛ R2 ⎞
VIN(RUN) = 400mV • ⎜1+ ⎟
⎝ R1 ⎠
(4)
VIN
BUCK
SWITCHING RUN
REGULATOR
R2
R1
4691 F02
Figure 2. RUN Divider
The buck regulator will remain off until VIN is above
VIN(RUN). The buck regulator will remain enabled until VIN
falls to 0.875 • VIN(RUN) and RUN is 350mV.
Alternatively, a resistor divider from the output of one
buck to the RUN pin of the second buck to ground provides event-based power-up sequencing as the first buck
reaching regulation enables the second buck. Replace
VIN(RUN) in Equation 4 with the desired output voltage of
the first buck (e.g., 90% of the regulated value) at which
the second buck is enabled.
Rev. A
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13
LTM4691
APPLICATIONS INFORMATION
Thermal Considerations and Output Current Derating
To prevent thermal damage, the LTM4691 incorporates an
overtemperature (OT) function. If the junction temperature reaches approximately 165°C, both power switches
will be turned off resulting in thermal shutdown until the
temperature falls to 160°C.
The thermal resistances reported in the Pin Configuration
section of the data sheet are consistent with those parameters defined by JESD51-12 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.
The motivation for providing these thermal coefficients is
found in JESD51-12 (“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.
µModule DEVICE
The Pin Configuration section typically gives four thermal
coefficients explicitly defined in JESD51-12; 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.
2. θJCbot, the thermal resistance from junction to the bottom of the product case, is determined with all of the
components power dissipation flowing through the
bottom of the package. In the typical μModule regulator, 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 maybe 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 θJCbot, this value may be useful
for comparing packages but the test conditions don’t
generally match the user’s application.
θJA JUNCTION-TO-AMBIENT RESISTANCE
θJCtop JUNCTION-TO-CASE
(TOP) RESISTANCE
CASE (TOP)-TO-AMBIENT
RESISTANCE
JUNCTION
AMBIENT
θJCbot JUNCTION-TO-CASE
(BOTTOM) RESISTANCE
CASE (BOTTOM)-TO-BOARD
RESISTANCE
BOARD-TO-AMBIENT
RESISTANCE
4691 F03
Figure 3. Graphical Representation of JESD51-12 Thermal Coefficients
Rev. A
14
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LTM4691
APPLICATIONS INFORMATION
A graphical representation of the aforementioned thermal resistances is given in Figure 3; 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 JESD51-12 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 the LTM4691 module, be aware there are multiple
power devices and components dissipating power, with
a consequence that the thermal resistances 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
JSED51-12 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 θJA is shown to correlate
quite well with the µModule model with no airflow or heat
sinking in a properly defined chamber. This θJA 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 power loss curves in Figure 4 and Figure 5 can be
used in coordination with the load current derating curves
in Figure 6 and Figure 7 for calculating an approximate
θJA thermal resistance for the LTM4691 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 junction temperature.
This approximate factor is: 1.15 for 125°C at junction
temperature. Maximum load current is achievable while
increasing ambient temperature as long as the junction
temperature is less than 125°C. When the ambient temperature reaches a point where the junction temperature
is 125°C, then the load current is lowered to maintain
the junction at 125°C. The derating curves are plotted
with the output current starting at 2A per channel and
the ambient temperature at 30°C. The output voltages
are 1.0V, 1.5V and 2.5V. 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 125°C maximum while lowering output
current or power with increasing ambient temperature.
The decreased output current will decrease the internal
module loss as ambient temperature is increased. The
monitored junction temperature of 125°C minus the ambient operating temperature specifies how much module
temperature rise can be allowed.
Rev. A
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15
LTM4691
APPLICATIONS INFORMATION
0.7
0.5
0.4
0.3
0.2
0.4
0.3
0.2
0.1
0.1
0
0.8VOUT
1.0VOUT
1.2VOUT
1.5VOUT
1.8VOUT
0.5
POWER LOSS (W)
0.6
POWER LOSS (W)
0.6
0.8VOUT
1.0VOUT
1.2VOUT
1.5VOUT
1.8VOUT
0
0.4
1.2
0.8
LOAD CURRENT (A)
1.6
0
2
0
0.4
1.2
0.8
LOAD CURRENT (A)
1.6
4691 F04
4691 F05
Figure 5. Power Loss at 3.3VIN,
Per Channel
2.5
2.5
2.0
2.0
IO1 = IO2 MAX (A)
IO1 = IO2 MAX (A)
Figure 4. Power Loss at 2.25VIN,
Per Channel
1.5
1.0
0.5
0
60
1.5
1.0
0.5
0LFM
200LFM
400LFM
80
100
AMBIENT TEMPERATURE (°C)
120
0
0LFM
200LFM
400LFM
60
80
100
AMBIENT TEMPERATURE (°C)
120
4691 F07
4691 F06
Figure 6. 3.3VIN to 1VOUT
Derating Curve, No Heat Sink
2
Figure 7. 3.3VIN to 1.5VOUT
Derating Curve, No Heat Sink
2.5
IO1 = IO2 MAX (A)
2
1.5
1
0.5
0
OLFM
200LFM
400LFM
60
100
80
AMBIENT TEMPERATURE (°C)
120
4691 F08
Figure 8. 3.3VIN to 2.5VOUT
Derating Curve, No Heat Sink
Rev. A
16
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LTM4691
APPLICATIONS INFORMATION
As an example, in Figure 6 the ambient temperature is
derated to 84.7°C when each channel is running at maximum of 2A of load current with no forced air or heat
sink to prevent the junction temperature from exceeding 125°C. For the 3.3VIN to 1VOUT at 4A the total power
loss for both channels is 0.914W, considering the 1.15
multiplying factor the total power loss to be 1.05W. If
the 84.7°C ambient temperature is subtracted from the
125°C junction temperature, then the difference of 40.3°C
divided by 1.05W equals a 38.4°C/W for θJA the system
equivalent thermal resistance. Table 1 specifies a 40°C/W
value which is very close. Table 2 and Table 3 provide
equivalent thermal resistances for 1.5V and 2.5V outputs
with and without airflow. The derived thermal resistances
in Table 1 to Table 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 temperature multiplicative
factors. The referenced 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.
Safety Considerations
Layout Checklist/Example
The high integration of LTM4691 makes the PCB board
layout very simple and easy. However, to optimize its
electrical and thermal performance, some layout considerations are still necessary.
• 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.
• Place high frequency ceramic input and output capacitors next to the VIN, GND and VOUT pins to minimize
high frequency noise.
• 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 via directly on the pad, unless they are
capped or plated over.
• Use a separated SGND ground copper area for components connected to signal pins. Connect the SGND
to GND underneath the unit.
• Bring out test points on the signal pins for monitoring.
Figure 9 gives a good example of the recommended layout.
The LTM4691 modules do not provide galvanic 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 thermal
shutdown and over current protection.
Rev. A
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17
LTM4691
APPLICATIONS INFORMATION
GND
VOUT1
VIN
VOUT2
GND
4691 F09
Figure 9. Recommended PCB Layout
Table 1. 1.0V Output
DERATING CURVE
AIRFLOW (LFM)
HEAT SINK
θJA (°C/W)
Figure 5
0
None
40°C
Figure 5
200
None
35°C
3.3
Figure 5
400
None
34°C
VIN (V)
POWER LOSS CURVE
Figure 6
3.3
Figure 6
3.3
Figure 6
Table 2. 1.5V Output
VIN (V)
POWER LOSS CURVE
AIRFLOW (LFM)
HEAT SINK
θJA (°C/W)
Figure 7
3.3
Figure 5
0
None
39°C
Figure 7
3.3
Figure 5
200
None
34°C
Figure 7
3.3
Figure 5
400
None
33°C
DERATING CURVE
Table 3. 2.5V Output
VIN (V)
POWER LOSS CURVE
AIRFLOW (LFM)
HEAT SINK
θJA (°C/W)
Figure 8
3.3
Figure 5
0
None
40°C
Figure 8
3.3
Figure 5
200
None
35°C
Figure 8
3.3
Figure 5
400
None
34°C
DERATING CURVE
Table 4. Output Voltage Response vs Component Matrix (Refer to Front Page Application) 1A to 1.5A Load Step Typical Measured Values
CIN
BULK
PART
NUMBER
VENDORS
220µF, 6.3V PANASONIC
CIN
CERAMIC
6TPE220MI 10µF, 6.3V
VENDORS
PART NUMBER
COUT
CERAMIC
VENDORS
PART NUMBER
KEMET
C0402C106M9PACTU
22µF, 6.3V
Murata
GRM188C80J226ME15D
VOUT
(V)
CIN
(CERAMIC)
(µF)
CIN
(BULK)
(µF)
COUT1
(CERAMIC)
(µF)
COUT2
(CERAMIC)
(µF)
CFF
(pF)
VIN
(V)
1.0
10 ×2
220
22
22
2.7
2.25, 3.3
20
1.5
10 ×2
220
22
22
1.2
2.25, 3.3
25
1.8
10 ×2
220
22
22
1.2
2.25, 3.3
2.5
10 ×2
220
22
22
1
3.3
P-P
DROOP DERIVATION
(mV)
(mV)
RECOVERY
TIME (μs)
LOAD
STEP
(A)
LOAD STEP
SLEW RATE
(A/μs)
45
25
0.5
0.5
50
25
0.5
0.5
30
60
25
0.5
0.5
42
84
30
0.5
0.5
Rev. A
18
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LTM4691
TYPICAL APPLICATIONS
Dual 1.5V and 1.8V 2MHz, 2A Buck Regulators, VIN = 2.5V
VIN
2.5V
VIN
VOUT1
1.5V, 2A
VOUT1
10µF
200k
RUN1
1.2pF
22µF
FB1
LTM4691
100k
VIN
VOUT2
1.8V, 2A
VOUT2
10µF
261k
RUN2
1.2pF
22µF
FB2
100k
MODE/SYNC
PGOOD
GND
1M
VIN
4691 TA02
fSW = 2MHz
Dual 1.2V and 0.8V 2MHz, 2A Buck Regulators, VIN = 3.3V
VIN
3.3V
VIN
VOUT1
1.2V, 2A
VOUT1
10µF
140k
RUN1
LTM4691
VIN
2.7pF
FB1
100k
VOUT2
0.8V, 2A
VOUT2
10µF
60.4k
RUN2
22µF
6.8pF
47µF
FB2
100k
MODE/SYNC
PGOOD
GND
fSW = 2MHz
1M
VIN
4691 TA03
Rev. A
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19
LTM4691
TYPICAL APPLICATIONS
Dual 1.2V and 0.8V 1MHz, 2A Buck Regulators, VIN = 3.3V
VIN
3.3V
VOUT1
1.2V, 2A
VOUT1
VIN
22µF
140k
22µF
FB1
LTM4691
RUN1
2.7pF
100k
VIN
VOUT2
0.8V, 2A
VOUT2
22µF
60.4k
RUN2
6.8pF
47µF
FB2
100k
1MHz
MODE/SYNC
PGOOD
1M
GND
VIN
4691 TA04
fSW = 1MHz
Dual 1.2V and 0.8V 3MHz, 2A Buck Regulators, VIN = 3.3V
VIN
3.3V
VOUT1
1.2V, 2A
VOUT1
VIN
10µF
140k
22µF
FB1
LTM4691
RUN1
2.7pF
100k
VIN
VOUT2
0.8V, 2A
VOUT2
10µF
60.4k
RUN2
6.8pF
47µF
FB2
100k
3MHz
MODE/SYNC
PGOOD
1M
GND
VIN
4691 TA05
fSW = 3MHz
PIN CONFIGURATION TABLE
LTM4691 Component LGA and BGA Pinout
PIN ID
FUNCTION
PIN ID
FUNCTION
PIN ID
FUNCTION
PIN ID
FUNCTION
A1
SGND2
A2
FB2
A3
FB1
A4
SGND1
B1
PGOOD
B2
RUN2
B3
RUN1
B4
MODE/SYNC
C1
VIN
C2
GND
C3
GND
C4
VIN
D1
GND
D2
GND
D3
GND
D4
GND
E1
VOUT2
E2
GND
E3
GND
E4
VOUT1
F1
VOUT2
F2
VOUT2
F3
VOUT1
F4
VOUT1
Rev. A
20
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LTM4691
PACKAGE DESCRIPTION
LGA Package
24-Lead (3mm × 4mm × 1.18mm)
(Reference LTC DWG# 05-08-1657 Rev A)
SEE NOTES
2×
aaa Z
Z
A
Z
DETAIL A
ccc Z
SEE NOTES
A1
4
3
2
6
1
3
PIN 1
A
PIN 1
CORNER
b
b
4
MOLD
CAP
D
C
F
SUBSTRATE
D
H1
H2
// bbb Z
B
E
e
DETAIL B
F
X
Y
e
Øb (24 PLACES)
b
DETAIL B
PACKAGE SIDE VIEW
ddd M Z X Y
eee M Z
PACKAGE TOP VIEW
2×
aaa Z
E
G
PACKAGE BOTTOM VIEW
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M-1994
2. ALL DIMENSIONS ARE IN MILLIMETERS
DETAIL A
3
PAD DESIGNATION PER JEP95
4
DETAILS OF PIN 1 IDENTIFIER ARE OPTIONAL,
BUT MUST BE LOCATED WITHIN THE ZONE INDICATED.
THE PIN 1 IDENTIFIER MAY BE EITHER A MOLD OR
MARKED FEATURE
0.975
0.325
0.000
0.325
0.975
DIMENSIONS
1.625
0.35 REF Ø 24x
0.975
0.325
0.000
0.325
0.975
1.625
SUGGESTED PCB LAYOUT
TOP VIEW
SYMBOL
A
A1
b
D
E
e
F
G
H1
H2
aaa
bbb
ccc
ddd
eee
MIN
1.08
NOM
1.18
0.32
0.35
4.00
3.00
0.65
3.25
1.95
0.18 REF
1.00 REF
MAX
1.28
0.03
0.38
NOTES
5. PRIMARY DATUM -Z- IS SEATING PLANE
6
PAD DIMENSION
SUBSTRATE THK
MOLD CAP HT
0.15
0.10
0.10
0.15
0.08
TOTAL NUMBER OF PADS: 24
!
PACKAGE ROW AND COLUMN LABELING MAY VARY
AMONG µModule PRODUCTS. REVIEW EACH PACKAGE
LAYOUT CAREFULLY
LTXXXXXX
COMPONENT
PIN 1
TRAY PIN 1
BEVEL
PACKAGE IN TRAY LOADING ORIENTATION
LGA 24 0319 REV A
Rev. A
Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog
Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications
subject to change without notice. No license For
is granted
implication or
otherwise under any patent or patent rights of Analog Devices.
more by
information
www.analog.com
21
LTM4691
BGA Package
24-Lead (4mm × 3mm × 1.48mm)
Z
A
A1
2×
aaa Z
Z
(Reference LTC DWG# 05-08-1658 Rev Ø)
ccc Z
SEE NOTES
DETAIL A
SEE NOTES
A2
4
3
2
6
1
3
PIN 1
A
PIN 1
CORNER
b
b1
4
MOLD
CAP
D
C
F
SUBSTRATE
D
H1
H2
// bbb Z
B
E
e
DETAIL B
F
X
Y
aaa Z
E
e
Øb (24 PLACES)
b
DETAIL B
PACKAGE SIDE VIEW
ddd M Z X Y
eee M Z
2×
PACKAGE TOP VIEW
G
PACKAGE BOTTOM VIEW
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M-1994
2. ALL DIMENSIONS ARE IN MILLIMETERS
DETAIL A
3
BALL DESIGNATION PER JEP95
4
DETAILS OF PIN 1 IDENTIFIER ARE OPTIONAL,
BUT MUST BE LOCATED WITHIN THE ZONE INDICATED.
THE PIN 1 IDENTIFIER MAY BE EITHER A MOLD OR
MARKED FEATURE
0.975
0.325
0.000
0.325
0.975
DIMENSIONS
0.35 ±0.025 Ø 24x
1.625
0.975
0.325
0.000
0.325
0.975
SUGGESTED PCB LAYOUT
TOP VIEW
MIN
1.32
0.23
1.09
0.35
0.32
NOM
1.48
0.30
1.18
0.40
0.35
4.00
3.00
0.65
3.25
1.95
0.18 REF
1.00 REF
MAX
1.64
0.37
1.27
0.45
0.38
NOTES
BALL HT
BALL DIMENSION
PAD DIMENSION
5. PRIMARY DATUM -Z- IS SEATING PLANE
6
!
SUBSTRATE THK
MOLD CAP HT
0.15
0.10
0.10
0.15
0.08
TOTAL NUMBER OF BALLS: 24
COMPONENT
PIN 1
TRAY PIN 1
BEVEL
PACKAGE ROW AND COLUMN LABELING MAY VARY
AMONG µModule PRODUCTS. REVIEW EACH PACKAGE
LAYOUT CAREFULLY
LTMXXXXXX
µModule
1.625
SYMBOL
A
A1
A2
b
b1
D
E
e
F
G
H1
H2
aaa
bbb
ccc
ddd
eee
PACKAGE IN TRAY LOADING ORIENTATION
BGA 24 0718 REV Ø
Rev. A
22
For more information www.analog.com
LTM4691
REVISION HISTORY
REV
DATE
DESCRIPTION
A
10/20
Add LTM4691IY#PBF order information
PAGE NUMBER
1, 2, 3, 21, 23, 24
Rev. A
Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog
Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications
subject to change without notice. No license For
is granted
implication or
otherwise under any patent or patent rights of Analog Devices.
more by
information
www.analog.com
23
LTM4691
PACKAGE PHOTO
1.18mm
1.48mm
4mm
4mm
3mm
3mm
DESIGN RESOURCES
SUBJECT
DESCRIPTION
µModule Design and Manufacturing Resources
Design:
• Selector Guides
• Demo Boards and Gerber Files
• Free Simulation Tools
µModule Regulator Products Search
1. Sort table of products by parameters and download the result as a spread sheet.
Manufacturing:
• Quick Start Guide
• PCB Design, Assembly and Manufacturing Guidelines
• Package and Board Level Reliability
2. Search using the Quick Power Search parametric table.
Digital Power System Management
Analog Devices’ family of digital power supply management ICs are highly integrated solutions that
offer essential functions, including power supply monitoring, supervision, margining and sequencing,
and feature EEPROM for storing user configurations and fault logging.
RELATED PARTS
PART NUMBER
LTM4622
LTM4622A
LTM4623
LTM4624
LTM4625
LTM4632
LTM4668/
LTM4668A
LTM4643
LTM4644
DESCRIPTION
Ultrathin, Dual 2.5A or Single 5A StepDown uModule Regulator
Ultrathin, Dual 2A or Single 4A StepDown uModule Regulator
Ultrathin, Single 3A Step-Down µModule
Regulator
Single 4A Step-Down µModule
Regulator
Single 5A Step-Down µModule
Regulator
Ultrathin, Triple Output, ±3A Step-Down
µModule Regulator for DDR Memory
Quad 1.2A Step-Down µModule
Regulator
Ultrathin, Quad 3A Step-Down µModule
Regulator
Quad 4A Step-Down µModule Regulator
COMMENTS
3.6V ≤ VIN ≤ 20V, 0.6V ≤ VOUT ≤ 5.5V, 6.25mm x 6.25mm x 1.82mm LGA,
6.25mm x 6.25mm x 2.42mm BGA.
3.6V ≤ VIN ≤ 20V, 1.5V ≤ VOUT ≤ 12V, 6.25mm x 6.25mm x 1.82mm LGA,
6.25mm x 6.25mm x 2.42mm BGA.
4V ≤ VIN ≤ 20V, 0.6V ≤ VOUT ≤ 5.5V, 6.25mm x 6.25mm x 1.82mm LGA,
6.25mm x 6.25mm x 2.42mm BGA.
4V ≤ VIN ≤ 14V, 0.6V ≤ VOUT ≤ 5.5V, 6.25mm x 6.25mm x 5.01mm BGA.
4V ≤ VIN ≤ 20V, 0.6V ≤ VOUT ≤ 5.5V, 6.25mm x 6.25mm x 5.01mm BGA.
3.6V ≤ VIN ≤ 15V, 0.6V ≤ VOUT ≤ 2.5V, 6.25mm x 6.25mm x 1.82mm LGA,
6.25mm x 6.25mm x 2.42mm BGA.
2.7V ≤ VIN ≤ 17V, 0.6V ≤ VOUT ≤ 1.8V (LTM4668A: 0.6V ≤ VOUT ≤ 5.5V, 2.25MHz)
6.25mm x 6.25mm x 2.1mm BGA.
4V ≤ VIN ≤ 20V, 0.6V ≤ VOUT ≤ 3.3V, 9mm x 15mm x 1.82mm LGA,
9mm x 15mm x 2.42mm BGA.
4V ≤ VIN ≤ 14V, 0.6V ≤ VOUT ≤ 5.5V, 9mm x 15mm x 5.01mm BGA.
Rev. A
24
10/20
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For more information www.analog.com
ANALOG DEVICES, INC. 2020