MAXIM MAX8655ETN+

19-3982; Rev 0; 10/07
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
Features
The MAX8655 synchronous-PWM buck regulator operates from a 4.5V to 25V input and generates an output
voltage adjustable from 0.7V to 5.5V at loads up to 25A.
Integrated power MOSFETs provide a small footprint,
ease of layout, and reduced EMI. Removing the board
trace inductances ensures the highest efficiency at
high frequency.
♦ 25A Output Current
The MAX8655 uses peak current-mode control architecture with an adjustable (200kHz to 1MHz), constantswitching frequency, which is externally synchronizable.
The MAX8655’s adjustable current limit uses the inductor’s DC resistance to improve efficiency or an external
sense resistor for higher accuracy. Foldback type current limit is available to reduce the power dissipation
under severe-overload or short-circuit conditions. A reference input is provided for use with a high-accuracy
external reference or for DDR and tracking applications.
Monotonic startup provides safe starting into a prebiased output, where traditional step-down regulators
discharge the output capacitor during soft-start, creating a negative voltage at the output and possibly damaging the load.
A 180° out-of-phase synchronization output is available
for synchronizing with another MAX8655.
An enable input is provided for on/off control and to
facilitate output sequencing. Output-voltage sensing for
programmable overvoltage protection is provided and
is independent of the feedback network to further
enhance the output overvoltage protection.
Overall, the MAX8655 provides enough flexibility for the
experienced user, as well as simplicity and ease of use
for non-power-supply engineers.
♦ Adjustable Switching Frequency and External
Synchronization from 200kHz to 1MHz
♦ Integrated Power MOSFETs
♦ Operates from 4.5V to 25V Supply
♦ 1% FB Voltage Accuracy Over Temperature
♦ Adjustable Output Voltage Down to 0.7V
♦ Multiphase Operation with Accurate Current
Sharing
♦ 180° Phase-Shifted Synchronization
♦ Adjustable Overcurrent Limit
♦ Adjustable Slope Compensation
♦ Selectable Current-Limit Mode: Latch-Off or
Automatic Recovery
♦ Monotonic Output Voltage Rise at Startup into
Prebias Output
♦ Output Sources and Sinks Current for DDR
Applications
♦ Enable Input
♦ Power-OK (POK) Output
♦ Adjustable Soft-Start
♦ Independently Adjustable Overvoltage Protection
Typical Operating Circuit
POK
FSYNC INPUT
FSYNC
SYNC OUTPUT
SYNCO
ILIM1
FB
OVP
SS
COMP
POWER-OK OUTPUT
ILIM2
SCOMP
Applications
Point-of-Load Power Supplies
Telecom Power
Networking
Nonisolated DC-DC Power Modules
Servers and Workstations
Notebook Computers
IBA Power Supplies
CS-
CS+
PVIN
OFF
ENABLE INPUT
Ordering Information
VL
IN
MAX8655
VL
ON
EN
VLGND
BST
LXB
+Denotes a lead-free package.
*EP = Exposed pad.
56 TQFN-EP*
(8mm x 8mm)
T5688M-4
INPUT 7V
TO 28V
OUTPUT
0.7V TO 12V
UP TO 25A
GND
PVIN
AVL
-40°C to +85°C
PKG
CODE
PGND
MAX8655ETN+
PINPACKAGE
MODE
TEMP
RANGE
REFIN
PART
LX
AVL
Pin Configuration appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
MAX8655
General Description
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
ABSOLUTE MAXIMUM RATINGS
PVIN, IN, EN to GND ..............................................-0.3V to +30V
BST to LXB ............................................................-0.3V to +7.5V
LX, LXB to GND............ (-2.5V for < 50ns transient) -1V to +30V
ILIM2, ILIM1, SYNCO, FSYNC, OVP,
SCOMP to GND .....................................-0.3V to (VAVL + 0.3V)
VL to PGND ...........................................................-0.3V to +7.5V
AVL, FB, POK, COMP, SS, MODE, REFIN to GND ..-0.3V to +6V
CS+, CS- to GND ....................................................-0.3V to +6V
PGND to GND to VLGND ......................................-0.3V to +0.3V
Operating Junction Temperature Range .......... -40°C to +125°C
Junction Temperature ......................................................+150°C
θJC (thermal resistance from
junction to exposed pad) (Note 1) ...............................3.5°C/W
θJT (thermal resistance from junction to the top) ............3.9°C/W
ILX (RMS) .................................................................................27A
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Note 1: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a 4-layer
board. For detailed information on package thermal considerations, see www.maxim-ic.com/thermal-tutorial.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = 12V, VBST - VLX = 6.5V, TA = -40°C to +85°C, circuit of Figure 4, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
PVIN Operating Voltage Range
TYP
3
IN Operating Voltage Range
VL = IN for VIN < 7V
IN Quiescent Supply Current
VFB = 0.75V, no switching
Shutdown Supply Current
MIN
4.5
2
MAX
UNITS
25
V
25.0
V
3
mA
EN = GND, VIN ≤ 28V
10
IIN + IVL + IAVL, EN = GND, VAVL = VVL = VIN = 5V
32
PVIN Shutdown Supply Current
VPVIN = VLX = VBST
AVL Undervoltage-Lockout
Threshold
VAVL rising, 3% typical hysteresis
3.90
Output-Voltage Adjust Range
Minimum output voltage is limited by minimum duty cycle
and external components
0.7
VL Regulation Voltage
7V < VIN < 28V
AVL Regulation Voltage
5.5V < VVL < 7V, 1mA < ILOAD < 10mA
AVL Output Current
1
4.15
µA
µA
4.40
V
5.5
V
V
6.0
6.5
7.0
4.900
4.975
5.050
10
V
mA
SOFT-START
SS Shutdown Resistance
From SS to GND, VEN = 0V
SS Soft-Start Current
VREF = 0.625V
20
100
Ω
23
28
µA
VAVL 1.0V
VAVL
V
-250
+250
nA
0
1.5
V
18
REFIN INPUT
REFIN Dual Mode™ Threshold
REFIN Input Bias Current
VREFIN = 0.7V to 1.5V
REFIN Input Voltage Range
Dual Mode is a trademark of Maxim Integrated Products, Inc.
2
_______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
(VIN = 12V, VBST - VLX = 6.5V, TA = -40°C to +85°C, circuit of Figure 4, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
0.693
0.7
0.707
VREFIN 0.00375
VREFIN
VREFIN +
0.00375
V
70
110
160
µS
20
100
Ω
50
nA
+1.5
V
ERROR AMPLIFIER
REFIN = AVL
FB Regulation Voltage
VREFIN = 0.7V to 1.5V
Transconductance
COMP Shutdown Resistance
From COMP to GND, VEN = 0V
FB Input Leakage Current
VFB = 0.7V
5
FB Input Common-Mode Range
-0.1
CURRENT-SENSE AMPLIFIER
Voltage Gain
VCS+ - VCS- = 30mV
VOUT = 0 to 5.5V
Part to part variation at TA = +85°C
V/V
12
-4
+4
%
CURRENT LIMIT
Peak Current-Limit
Threshold (VCS+ - VCS-)
RILIM1 = 24kΩ
27.2
32
36.8
ILIM1 = AVL
60
80
92
Negative Current Limit
% of valley current limit
-90
-120
-150
%
CS+, CS- Input Bias Current
VCS+ = VCS- = 0 or 5.5V
-25
+25
µA
0
5.5
V
CS+, CS- Input Common-Mode
Range
mV
SLOPE COMPENSATION
Slope Compensation at Maximum
Duty Cycle
VSCOMP = 2.5V
231.25
250.00
268.75
VSCOMP = 1.25V
113.77
123.00
132.23
SCOMP = AVL
SCOMP = GND
231.25
250.00
268.75
TA = 0°C to +85°C
113.77
123.00
132.23
TA = -40°C to +85°C
110.70
123.00
132.23
VAVL 0.5
SCOMP High Threshold
SCOMP Low Threshold
0.5
SCOMP Adjustment Range
1.25
SCOMP Input Leakage Current
VSCOMP = 1.25V to 2.5V
mV
V
V
5
2.50
V
200
nA
_______________________________________________________________________________________
3
MAX8655
ELECTRICAL CHARACTERISTICS (continued)
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
ELECTRICAL CHARACTERISTICS (continued)
(VIN = 12V, VBST - VLX = 6.5V, TA = -40°C to +85°C, circuit of Figure 4, typical values are at TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
CONDITIONS
MIN
TYP
MAX
RFSYNC = 21.0kΩ
800
1000
1200
RFSYNC = 143kΩ
160
200
240
UNITS
OSCILLATOR
Switching Frequency
Minimum Off-Time
Measured at LX
235
Minimum On-Time
Measured at LX
75
kHz
ns
100
ns
1200
kHz
FSYNC Synchronization Range
160
FSYNC Input High Pulse Width
100
ns
FSYNC Input Low Pulse Width
100
ns
FSYNC Rise/Fall Time
100
SYNCO Phase Shift
180
SYNCO Output Low Level
ISYNCO = 5mA
SYNCO Output High Level
ISYNCO = -5mA
0.4
VAVL - 1V
V
V
FSYNC Input Low
0.4
FSYNC Input High
ns
Degrees
2.5
V
V
THERMAL PROTECTION
Thermal Shutdown
Rising temperature
Thermal-Shutdown Hysteresis
+160
°C
15
°C
POK
POK Threshold
REFIN = AVL, VFB rising, typical hysteresis is 3%
629
650
671
mV
VREFIN = 0.75V to 1.5V, VFB rising, typical hysteresis is 3%
88.7
91.7
94.7
%
25
200
mV
1
µA
mV
POK Output Voltage, Low
VFB = 0.6V, IPOK = 2mA
POK Leakage Current, High
VPOK = 5.5V
OVP
OVP Threshold Voltage
OVP, Leakage Current, High
REFIN = AVL
770
800
840
VREFIN = 0.7V to 1.5V
110
115
120
%
500
nA
0.4
V
VOVP = 0.8V
MODE CONTROL
MODE Logic-Level Low
4.5V ≤ VAVL ≤ 5.5V
MODE Logic-Level High
4.5V ≤ VAVL ≤ 5.5V
1.8
MODE Input Current
VMODE = 0 to VAVL
-1
V
+1
µA
0.45
V
SHUTDOWN CONTROL
EN Logic-Level Low
4.5V ≤ VAVL ≤ 5.5V
EN Logic-Level High
4.5V ≤ VAVL ≤ 5.5V
2
VEN = 0V
-1
EN Input Current
VEN = 28V
V
+1
1.5
6.0
µA
Note 2: Specifications are 100% production tested at TA = +85°C. Limits over the operating temperature range are guaranteed by
design.
4
_______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
12A LOAD
3.33
3.30
3.29
0.710
FB VOLTAGE (V)
3.31
7.5A LOAD
0.715
3.32
OUTPUT VOLTAGE (V)
3.32
3.31
3.30
3.29
0.705
0.700
0.695
3.28
3.28
0.690
3.27
3.27
0.685
3.26
3.26
0
5
10
15
LOAD CURRENT (A)
20
25
0.680
5
10
15
INPUT VOLTAGE (V)
20
RFSYNC = 76.8kΩ
390
380
TA = +25°C
370
0
40
80
EXPOSED PAD TEMPERATURE (°C)
120
MAX8655 toc05
MAX8655 toc04
400
-40
STEP-LOAD RESPONSE
(CIRCUIT OF FIGURE 3)
OSCILLATOR FREQUENCY vs. INPUT VOLTAGE
(CIRCUIT OF FIGURE 4)
OSCILLATOR FREQUENCY (kHz)
OUTPUT VOLTAGE (V)
3.33
0.720
MAX8655 toc02
VIN = 12V
FB VOLTAGE vs. EXPOSED PAD TEMPERATURE
(CIRCUIT OF FIGURE 4)
3.34
MAX8655 toc01
3.34
LINE REGULATION
(CIRCUIT OF FIGURE 4)
MAX8655 toc03
LOAD REGULATION
(CIRCUIT OF FIGURE 4)
MAX8655
Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
VOUT = 1.2V
VOUT
50mV/div
(AC-COUPLED)
0A
TA = -40°C
360
350
340
TA = +85°C
330
IOUT
5A/div
320
310
300
8
13
18
23
INPUT VOLTAGE (V)
40μs/div
28
POWER-DOWN WAVEFORMS
(CIRCUIT OF FIGURE 4)
POWER-UP WAVEFORMS
(CIRCUIT OF FIGURE 4)
ENABLE WAVEFORMS
(CIRCUIT OF FIGURE 4)
MAX8655 toc07
MAX8655 toc06
MAX8655 toc08
VPOK
10V/div
VPOK
VIN
10V/div
5V/div
5V/div
VEN
5V/div
1V/div
VIN
VPOK
VOUT
VOUT
5V/div
2V/div
5A/div
ILX
ILX
2ms/div
2V/div
VOUT
10A/div
ILX
200μs/div
10A/div
2ms/div
_______________________________________________________________________________________
5
Typical Operating Characteristics (continued)
(TA = +25°C, unless otherwise noted.)
DUAL-PHASE SWITCHING
(CIRCUIT OF FIGURE 5)
FSYNC AND SYNCO
(CIRCUIT OF FIGURE 4)
MAX8655 toc10
MAX8655 toc09
VFSYNC
VLX
VSYNCO
INTERNAL 350kHz SYNCHRONIZED TO
OPERATION
EXTERNAL 500kHz CLOCK
5V/div
VLX
(SLAVE)
5V/div
5V/div
VLX
(MASTER)
5V/div
VSYNCO
(MASTER)
5V/div
5V/div
1μs/div
1μs/div
OVERVOLTAGE PROTECTION
(CIRCUIT OF FIGURE 3)
SHORT CIRCUIT AND RECOVERY
MAX8655 toc11
VIN
MAX8655 toc12
2V/div
VOUT
500mV/div
(AC-COUPLED)
VOUT
1V/div
VLX
5V/div
IIN
1A/div
40μs/div
1ms/div
CLOSED-LOOP BODE PLOT
(CIRCUIT OF FIGURE 3)
SAFE OPERATING AREA
40
180
144
20
72
10
36
0
0
GAIN
-20
-30
25
OUTPUT CURRENT (A)
108
PHASE MARGIN (DEGREES)
PHASE
30
-10
30
MAX8655 toc14
MAX8655toc13
50
GAIN (dB)
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
20
15
10
5
-40
500 1k 2k 4k
10k 20k 40k 100k 200k400k
FREQUENCY (Hz)
6
0
5
10
15
20
INPUT VOLTAGE (V)
25
30
_______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
(TA = +25°C, unless otherwise noted.)
MAXIMUM OUTPUT CURRENT
vs. EXPOSED PAD TEMPERATURE
(CIRCUIT OF FIGURE 4)
80
80
70
60
50
40
VO = 3.3V
10A LOAD
10
0
5
8
EFFICIENCY vs. LOAD CURRENT
12V INPUT, 3.3V OUTPUT
(CIRCUIT OF FIGURE 4)
1.0
20
200
90
80
180
160
40
60
50
40
30
30
20
20
10
10
0
0
1
10
LOAD CURRENT (A)
100
RVALLEY (kΩ)
EFFICIENCY (%)
50
80
20
0
300
400
500
600
FREQUENCY (kHz)
700
800
80
60
40
20
0
5
10
15
20
VALLEY CURRENT LIMIT (A)
25
OUTPUT-CURRENT CAPABILITY
vs. AMBIENT TEMPERATURE
30
300 LFM
OUTPUT-CURRENT CAPABILITY (A)
MAX8655 toc21
BOTTOM PCB TEMPERATURE (°C)
100
100
40
10A LOAD
BOTTOM LAYER PCB TEMPERATURE vs.
OUTPUT CURRENT
VIN = 12V, VCC = 1.2V
120
60
200
120
3.5
140
70
60
2.0
2.5
3.0
OUTPUT VOLTAGE (V)
RVALLEY vs. VALLEY CURRENT LIMIT
100
70
1.5
MAX8655 toc20
80
17
MAX8655 toc19
90
11
14
INPUT VOLTAGE (V)
EFFICIENCY vs. FREQUENCY
12.0V INPUT 3.3V OUTPUT
(CIRCUIT OF FIGURE 4)
MAX8655 toc18
100
12V INPUT
10A LOAD
10
0
-40 -20 0 20 40 60 80 100 120
EXPOSED PAD TEMPERATURE (°C)
40
20
20
0
50
30
30
5
60
100 LFM
25
MAX8655 toc22
10
90
EFFICIENCY (%)
EFFICIENCY (%)
15
MAX8655 toc17
90
70
20
100
MAX8655 toc16
25
OUTPUT CURRENT (A)
100
MAX8655 toc15
30
EFFICIENCY (%)
EFFICIENCY vs. OUTPUT VOLTAGE
(CIRCUIT OF FIGURE 4)
EFFICIENCY vs. INPUT VOLTAGE
(CIRCUIT OF FIGURE 4)
20
15
10
NO AIRFLOW
5
0
0
0
5
10
15
IOUT (A)
20
25
-40 -25 -10 5 20 35 50 65 80 95 110 125
AMBIENT TEMPERATURE (°C)
_______________________________________________________________________________________
7
MAX8655
Typical Operating Characteristics (continued)
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
MAX8655
Pin Description
PIN
NAME
FUNCTION
Power-Input Supply. PVIN connects to the drain of the internal high-side MOSFET. Connect inputdecoupling capacitors as close as possible between PVIN and PGND.
1–5, 51–56
PVIN
6, 16–21
LX
7–15
PGND
Power Ground Connection from Source of Internal Low-Side MOSFET. Connect input-decoupling
capacitors as close as possible between PVIN and PGND.
22
VLGND
Return for Low-Side MOSFET Gate-Driver Current
23, 28, 39,
48
GND
Analog Ground. Connect all pins to the analog ground plane, and connect the analog and power
ground planes together at the negative terminal of the output capacitor. Low-current signals return to
GND. Pin 28 must be connected externally to GND-EP, the analog ground plane.
24
VL
Internal 6.5V Linear-Regulator Output. Connect a 2.2µF to 10µF ceramic capacitor from VL to VLGND.
For VIN < 7V, connect VL directly to IN. VL supplies power for the internal gate drivers. VL is the input
to the AVL internal linear regulator.
25
IN
Input Supply Voltage. IN is the input to the VL linear regulator. Connect VL to IN for VIN < 7V.
Decouple to PGND with a 0.22µF ceramic capacitor.
26
EN
Enable. Apply logic-high to EN to enable the output, or logic-low to place the regulator in low-power
shutdown mode. Connect EN to IN for always-on operation.
27
AVL
Internal 5V Linear-Regulator Output. AVL powers the MAX8655’s internal circuits. Connect a 1µF
ceramic capacitor from AVL to GND.
29, 30, 42, 49
N.C.
No Connection. Not internally connected.
31
CS+
Positive Differential Current-Sense Input
32
CS-
Negative Differential Current-Sense Input
ILIM1
Analog Programmable Current-Limit Input for Inductor Current. Connect a resistor from ILIM1 to GND
to set the overcurrent threshold. ILIM1 sources 10µA through the resistor, and the voltage at ILIM1 is
attenuated 7.5:1 to set the final current limit. For example, a 60kΩ resistor results in 600mV at ILIM1.
This results in a current-limit threshold (VCS+ - VCS-) of 80mV. The ILIM1 resistor range is 24kΩ to
60kΩ. Connect ILIM1 to AVL to set the default threshold of 80mV.
34
OVP
Output-Voltage Sensing for Overvoltage Protection. Connect OVP to the center of a resistor-divider
connected between the output of the regulator and GND to set the FB independent output
overvoltage trip point. Connect OVP to FB if this independence is not desired. The OVP threshold is
1.15 times the nominal feedback regulation voltage.
35
FB
36
COMP
37
SS
Soft-Start. Connect a 0.01µF to 1µF ceramic capacitor from SS to GND. This capacitor sets the softstart period during startup. See the Startup and Soft-Start section for more details. SS is internally
pulled to GND through 20Ω during shutdown.
38
REFIN
External Reference Input. Connect REFIN to AVL to use the internal 0.7V reference for the feedback
threshold.
33
8
External Inductor Connection. Connect to the external power inductor. Leave pin 6 unconnected for
best routing.
Feedback Input. Connect FB to the center of a resistor voltage-divider connected between the output
and GND to set the output voltage. FB regulates to 0.7V or VREFIN.
Loop Compensation. Connect COMP to an external RC network to compensate the loop. COMP is
internally pulled to GND through 20Ω during shutdown.
_______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
PIN
NAME
FUNCTION
40
ILIM2
41
SCOMP
Programmable Slope-Compensation Input. Internal slope-compensation voltage rate is the voltage at
SCOMP times 0.1 divided by the oscillator period (T). Connect SCOMP to AVL or GND to set to the
default of 250mV/T or 125mV/T, respectively.
43
POK
Open-Drain Power-OK Output. POK goes high impedance when the output voltage rises above 91%
of the nominal regulation voltage. POK pulls low during shutdown or when the output drops below
88% of the nominal regulation voltage.
44
FSYNC
Frequency Set and Synchronization Input. Connect a resistor from FSYNC to GND to set the switching
frequency, or drive with a clock signal to synchronize between 160kHz and 1.2MHz. See the
Switching Frequency and Synchronization section.
45
MODE
Current-Limit Operating Mode Selection. Connect MODE to AVL for latch-off current limit or connect
MODE to GND for automatic recovery current limit.
46
SYNCO
Synchronization Output. Provides a clock output for synchronizing another MAX8655 with 180°
out-of-phase operation.
47
BST
Boost Capacitor Connection. Connect a 0.22µF ceramic capacitor from BST to LXB.
50
LXB
LX Boost Capacitor Connection. Connect a 0.22µF ceramic capacitor between LXB and BST.
—
GND-EP
Exposed Pad. Connect to GND externally. See the Pin Configuration.
—
PVIN-EP
Exposed Pad. Internally connected to PVIN. See the Pin Configuration.
—
LX-EP
Programmable Current-Limit Input. Connect a resistor from ILIM2 to GND to set the valley current
limit. See the Setting the Current Limit section.
Exposed Pad. Internally connected to LX. See the Pin Configuration.
_______________________________________________________________________________________
9
MAX8655
Pin Description (continued)
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
IN
MAX8655
PVIN
6.5V LDO
REGULATOR
EN
BST
UVLO
VL
LEVEL
SHIFT
THERMAL
SHDN
LX
SHOOT-THROUGH
PROTECTION
5V AVL
LDO
AVL
VL
VOLTAGE
REFERENCE
REF
SELECT
LOGIC
PWM
CONTROL
LOGIC
VREF
PGND
VLGND
SOFT-START
CIRCUITRY
REFIN
SYNCO
OVP
SS
1.15V REF
ERROR
AMPLIFIER
OSCILLATOR
FSYNC
SLOPE
COMP
SCOMP
COMP
CLAMP
GM
FB
PWM
COMPARATOR
COMP
OVP
CURRENT-SENSE
AMPLIFIER
CS+
VSUM
12
CURRENT-LIMIT
CONTROL LOGIC
LEVEL
SHIFT
MODE
CURRENT-LIMIT
COMPARATOR
X1
ILIM2
CS10μA
VL
POK
ILIM1
GND
÷7.5
0.9V REF
FB
Figure 1. Functional Diagram
10
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
DC-DC Converter Control Architecture
The MAX8655 step-down regulator uses a PWM, peak
current-mode control scheme. An internal transconductance amplifier establishes an integrated error voltage.
The heart of the PWM controller is a PWM comparator
that compares the integrated voltage-feedback signal
against the amplified current-sense signal plus an
adjustable slope-compensation ramp, which is
summed with the current signal to ensure stability. At
each rising edge of the internal clock, the internal highside MOSFET turns on until the PWM comparator trips
or the maximum duty cycle is reached. During this ontime, current ramps up through the inductor, storing
energy in the output inductor while sourcing current to
the output. The current-mode feedback system regulates the peak inductor current as a function of the output-voltage error signal. The circuit acts as a
switch-mode transconductance amplifier and pushes
the output LC filter pole normally found in a voltagemode PWM to a higher frequency. Figure 1 is the functional diagram.
During the second half of the cycle, the internal highside MOSFET turns off and the internal low-side MOSFET turns on. The output inductor releases the stored
energy as the current ramps down, providing current to
the load. The output capacitor stores charge when the
inductor current exceeds the required load current and
discharges when the inductor current is lower, smoothing the voltage across the load. Under soft-overload
conditions, when the peak inductor current exceeds the
selected current limit (see the Current-Limit Circuit section), the high-side MOSFET is turned off immediately
and the low-side MOSFET is turned on and remains on
to let the inductor current ramp down until the next
clock cycle. Under severe-overload or short-circuit conditions, the valley foldback current limit is enabled to
reduce power dissipation of external components.
The MAX8655 operates in a forced-PWM mode. As a
result, the regulator maintains a constant switching frequency, regardless of load, to allow for easier filtering
of the switching noise.
Internal Linear Regulators
The MAX8655 contains two internal LDO regulators.
The AVL regulator provides 5V for the IC’s internal circuitry, and the VL regulator provides 6.5V for the MOSFET gate drivers. Connect a 2.2µF ceramic capacitor
from VL to VLGND, and connect a 1µF ceramic capacitor from AVL to GND. The AVL regulator input is internally connected to the VL regulator output. For 5V input
applications, connect VL directly to IN and connect a
10Ω resistor from VL to AVL.
Undervoltage Lockout
When VAVL drops below 4.03V, the MAX8655 assumes
that the supply voltage is too low to make valid decisions, so the undervoltage-lockout (UVLO) circuitry
inhibits switching and turns off both internal power
MOSFETs. When VAVL rises above 4.15V, the regulator
enters the startup sequence and then resumes normal
operation.
Startup and Soft-Start
The internal soft-start circuitry gradually ramps up the
reference voltage to control the rate of rise of the output
voltage and reduce input surge currents during startup.
The soft-start period is determined by the value of the
capacitor from SS to GND. The soft-start time is
approximately (30.4ms/µF) x CSS. The MAX8655 also
features monotonic output-voltage rise; therefore, both
power MOSFETs are kept off if the voltage at FB is
higher than the voltage at SS. This allows the MAX8655
to start up into a prebiased output without pulling the
output voltage down.
Before the MAX8655 begins the soft-start and powerup sequence, the following conditions must be met:
• VAVL exceeds the 4.15V UVLO threshold.
• EN is at logic-high.
• The thermal limit is not exceeded.
Enable
The MAX8655 features a low-power shutdown mode. A
logic-low at EN shuts down the regulator. During shutdown, the output is high impedance. Shutdown
reduces the IN current to less than 10µA. A logic-high
at EN enables the regulator.
______________________________________________________________________________________
11
MAX8655
Detailed Description
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
VL
BST
MAX8655
LXB
Figure 2. High-Side Gate Boost Circuit
High-Side Gate-Drive Supply (BST)
A flying capacitor boost circuit (Figure 2) generates the
gate-drive voltage for the internal high-side n-channel
MOSFET. The capacitor between BST and LXB is
charged from VL to 6.5V minus the diode forward-voltage drop while the low-side MOSFET is on. When the
low-side MOSFET is switched off, the stored voltage of
the capacitor is stacked above LXB to provide the necessary turn-on voltage (VGS) for the high-side MOSFET.
An internal switch between BST and the internal highside MOSFET’s gate closes to turn the MOSFET on.
Current-Sense Amplifier
The current-sense circuit amplifies the differential current-sense voltage (VCS+ - VCS-). This amplified current-sense signal and the internal-slope-compensation
signal are summed (VSUM) together and fed into the
PWM comparator’s inverting input. The PWM comparator shuts off the high-side MOSFET when V SUM
exceeds the integrated feedback voltage (VCOMP).
The differential current sense is also used to provide
peak inductor current limiting. This current limit is more
accurate than the valley current limit, which is measured
across the internal low-side MOSFET.
Current-Limit Circuit
The MAX8655 uses both foldback and peak current limiting. The valley foldback current limit is used to reduce
power dissipation of external components—mainly the
inductor, internal power MOSFETs, and the upstream
power source, when the output is severely overloaded
or short circuited and when POK is low. Thus, the circuit
can withstand short-circuit conditions continuously without causing overheating of any component. The peak
constant current limit sets the current-limit point more
accurately since it does not have to suffer the wide variation of the low-side power MOSFET’s on-resistance
due to tolerance and temperature.
12
The valley current is sensed across the on-resistance of
the low-side MOSFET. The valley current limit trips when
the sensed current exceeds the valley current limit.
Set the minimum valley current limit when the output
voltage is at its nominal regulated value, higher than
the maximum peak current-limit setting. With this
method, the current-limit point accuracy is controlled
by the peak current limit and is not interfered with by
the wide variation of the MOSFET’s on-resistance. See
the Setting the Current Limit section for how to set
these limits.
The MAX8655 can be configured for either an
adjustable valley current-limit threshold with adjustable
foldback ratio or a fixed valley current limit that latches
the regulator off. To use foldback current limit with
autorecovery, connect MODE to GND. When the latch-off
mode is used, connect MODE to AVL and set the current-limit threshold with one resistor from ILIM2 to GND.
Cycle EN or input power to reset the current-limit latch.
The peak current limit is used to sense the inductor current, and is more accurate than the valley current limit
because it does not depend upon the on-resistance of
the low-side MOSFET. The peak current can be measured across the resistance of the inductor for the highest efficiency, or alternatively, a current-sense resistor
can be used for more accurate current sensing. A
resistor connected from ILIM1 to GND sets the peak
current-limit threshold.
For more information on the current limit, see the
Setting the Current Limit section.
Switching Frequency and Synchronization
The MAX8655 has an adjustable internal oscillator that
can be set to any frequency from 200kHz to 1MHz. To
set the switching frequency, connect a resistor from
FSYNC to GND.
The MAX8655 can also be synchronized to an external
clock by connecting the clock signal to FSYNC. A synchronization output (SYNCO) is provided to synchronize
a second MAX8655 180° out-of-phase with the first by
connecting SYNCO of the first MAX8655 to FSYNC of the
second. When the first MAX8655 is synchronized to an
external clock, the external clock is inverted to generate
SYNCO. Therefore, to get 180° out-of-phase operation
with an external clock, the clock input to the first
MAX8655 should have a 50% duty cycle. Figure 3 is the
single-phase, 600kHz switching, 10.8V to 13.2V input
and 1.2V/20A output. Figure 4 shows single-phase,
350kHz switching, 6V to 20V input, and 3.3V/20A output.
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
MAX8655
R3
2.87kΩ
R12
80.6kΩ
C8
0.47μF
C12
470pF
R7
40.2kΩ
CS-
ILIM1
OVP
FB
SS
COMP
REFIN
POK
GND
ILIM2
SCOMP
R13
100kΩ
POWER-OK OUTPUT
N.C.
C10
100pF
AVL
CS+
AVL
R2
357Ω
R9
56.2kΩ
R5
4.02kΩ
N.C.
C13
R10 0.022μF
51.1kΩ
GND
FSYNC INPUT
FOR INTERNAL
OSCILLATOR
OPERATION ONLY
R8
41.2kΩ
FSYNC
AVL
MODE
EN
SYNC OUTPUT
SYNCO
IN
BST
VL
C14
1μF
ENABLE
INPUT
OFF
C16
0.22μF
D1
GND
GND
MAX8655
N.C.
C18
2.2μF
C9
0.47μF
R1
681Ω
OUTPUT 1.2V
UP TO 20A
L1
0.56μH
1.8mΩ
C6–C20
4 x 100μF
CERAMIC
PGND
PGND
PGND
PVIN
PGND
LX
PGND
LX
PVIN
PGND
LX
PVIN
PGND
PVIN
LX
LX
PVIN
PVIN
PVIN
LX
PVIN
PVIN
PVIN
C1–C3
3 x 10μF
CERAMIC
LX
PVIN
INPUT
11.8V TO 13.2V
VLGND
LXB
PGND
C15
0.22μF
PGND
VL
ON
PVIN
Figure 3. Single-Phase, 600kHz Switching, 10.8V to 13.2V Input, and 1.2V/20A Output
REFIN
Power-Good Signal (POK)
The MAX8655 has a reference input (REFIN). When an
external reference up to 1.5V is connected to REFIN,
the feedback regulation voltage is equal to the voltage
applied to REFIN.
Connect REFIN to AVL to use the internal 0.7V reference.
POK is an open-drain output on the MAX8655 that monitors the output voltage. When the output is above 92%
of its nominal regulation voltage, POK is high impedance. When the output drops below 89% of its nominal
regulation voltage, POK is internally pulled low. POK is
also internally pulled low when the MAX8655 is shut
down or in a fault condition.
Overvoltage Protection
The MAX8655 provides output overvoltage protection
(OVP). The OVP threshold is set independent of the
output regulation voltage with a resistor voltage-divider.
When the voltage at OVP exceeds the OVP threshold,
the regulator stops switching and latches on the lowside power MOSFET. Cycle EN or the power applied to
AVL to clear the latch.
Thermal-Overload Protection
Thermal-overload protection limits total power dissipation in the MAX8655. When the junction temperature
exceeds +160°C, an internal thermal sensor shuts
down the device, allowing the IC to cool. The thermal
sensor turns the IC on again after the junction temperature cools by 15°C, resulting in a pulsed output during
continuous thermal-overload conditions.
______________________________________________________________________________________
13
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
R3
11.5kΩ
R4
11.5kΩ
C8
0.22μF
R2
3.57kΩ
R9
71.5kΩ
C10
100pF
CS-
ILIM1
OVP
FB
SS
COMP
POK
REFIN
POWER-OK OUTPUT
GND
SCOMP
R13
100kΩ
N.C.
R6
3.09kΩ
CS+
R5
3.09kΩ
R7
243kΩ
AVL
N.C.
R11
140kΩ
R14
13kΩ
ILIM2
AVL
C12
560pF
C13
0.022μF
R12
10kΩ
GND
C14
1μF
FSYNC INPUT
R8
76.8kΩ
FOR INTERNAL
OSCILLATOR
OPERATION ONLY
AVL
FSYNC
AVL
MODE
EN
SYNCO
IN
BST
VL
SYNC OUTPUT
ENABLE
INPUT
OFF
PVIN
C16
0.22μF
D1
VL
C15
0.22μF
GND
GND
MAX8655
N.C.
C18
2.2μF
VLGND
LXB
LX
PVIN
LX
PVIN
LX
PVIN
LX
PVIN
LX
PVIN
LX
PVIN
PGND
R1
1.74kΩ
L1
1μH
1.6mΩ
C6–C19
3 x 220μF
15μΩ ESR
PGND
PGND
PGND
PGND
PGND
PGND
PGND
PGND
LX
PVIN
PVIN
PVIN
PVIN
PVIN
C9
0.22μF
OUTPUT 3.3V
UP TO 20A
INPUT 6V TO 20V
C1–C5
5 x 10μF
CERAMIC
ON
Figure 4. Single-Phase, 350kHz Switching, 6V to 20V Input, and 3.3V/20A Output
Design Procedure
Setting the Output Voltage
To set the output voltage for the MAX8655, connect FB
to the center of an external resistor-divider from the output to GND (R3 and R5 of Figure 5). Select R5 between
5kΩ and 24kΩ, and then calculate R3 with the following
equation:
LX
R3
MAX8655
FB
⎛V
⎞
R3 = R5 × ⎜ OUT − 1⎟
⎝ VFB
⎠
where VFB = 0.7V or VREFIN . R3 and R5 should be
placed as close as possible to the IC.
14
R5
Figure 5. Setting the Output Voltage with a Resistor VoltageDivider
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
Setting the Switching Frequency
To set the switching frequency, connect a resistor from
FSYNC to GND. Calculate the resistor value in kΩ from
the following equation:
⎛V
⎞
R4 = R6 × ⎜ OUT − 1⎟
⎝ VOVP ⎠
30600
− 9.914
fS
where fS is the desired switching frequency in kHz.
Setting the Slope Compensation
where VOVP = 1.15 x VFB.
Inductor Selection
There are several parameters that must be examined
when determining which inductor is to be used. Input
voltage, output voltage, load current, switching frequency, and LIR. LIR is the ratio of the inductor current
ripple to the maximum DC load current. A higher LIR
value allows for a smaller inductor, but results in higher
losses and higher output ripple. A good compromise
between size and efficiency is an LIR of 0.3. Once all
the parameters are chosen, the inductor value is determined as follows:
VOUT × (VIN − VOUT )
L=
VIN × fS × ILOAD(MAX) × LIR
where fS is the switching frequency. Choose a standard-value inductor close to the calculated value. The
exact inductor value is not critical and can be adjusted
to make trade-offs among size, cost, and efficiency.
Lower inductor values minimize size and cost, but they
also increase the output ripple and reduce the efficiency due to higher peak currents. On the other hand,
higher inductor values increase efficiency, but eventually resistive losses due to extra turns of wire exceed
the benefit gained from lower AC current levels. This is
especially true if the inductance is increased without
also increasing the physical size of the inductor. Find a
low-loss inductor having the lowest possible DC resistance that fits the allotted dimensions. The chosen
inductor’s saturation current rating must exceed the
peak inductor current determined as:
IPEAK = ILOAD(MAX) +
RFSYNC =
LIR
× ILOAD(MAX)
2
For most applications where the duty cycle is less than
40%, connect SCOMP to GND to set the internal slope
compensation to the default of 125mV/T, where T is the
oscillator period (T = 1 / fS).
For a slope compensation of 250mV/T, connect
SCOMP to AVL.
For applications with a duty cycle greater than 40%, set
the SCOMP voltage with a resistor voltage-divider from
AVL to GND (R11 and R12 in Figure 6). First, use the
following equation to find the SCOMP voltage:
VSCOMP =
120 × RL
× (VO − 0.182 × VIN _ MIN )
fS × L
where RL is the DC resistance of the inductor, VIN_MIN
is the minimum operating input voltage, and fS is the
switching frequency.
Next, select a value for R11, typically 10kΩ, and solve
for R12 as follows:
R12 =
(5V − VSCOMP ) × R11
VSCOMP
This sets the internal slope-compensation voltage rate
to VSCOMP / (10 x T).
AVL
MAX8655
R12
SCOMP
R11
Figure 6. Resistor-Divider for Setting the Slope Compensation
______________________________________________________________________________________
15
MAX8655
Setting the Output Overvoltage Protection
To set the overvoltage threshold voltage for the
MAX8655, connect OVP to the center of an external
resistor-divider connected between the output and GND
(R4 and R6 of Figure 3). Select R6 between 5kΩ and
24kΩ, then calculate R4 with the following equation:
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
Setting the Current Limit
Valley Current Limit
The MAX8655 has an adjustable valley current limit, configurable for foldback with automatic recovery, or constant-current limit with latch-up. To set the constantcurrent limit for the latch-up mode, connect a single
resistor RILIM2 from ILIM2 to GND. For latch-up currentlimit mode, set RILIM2 equal to RVALLEY obtained from
the RVALLEY vs. Valley Current Limit graph in the Typical
Operating Characteristics section for the required valley
current IVALLEY. IVALLEY is the value of the inductor valley current at maximum load (ILOAD(MAX) - 1/2 IP-P)
To set the current limit for foldback mode, connect a
resistor from ILIM2 to the output (RFOBK), and another
resistor from ILIM2 to GND (RILIM2). See Figure 7. The
values of RFOBK and RILIM2 are calculated as follows.
First, select the percentage of foldback (PFB). This percentage corresponds to the current limit when VOUT
equals zero divided by the current limit when V OUT
equals its nominal voltage. A typical value of PFB is in
the 15% to 40% range. A lower value of P FB yields
lower short-circuit current. The following equations are
used to calculate RFOBK and RILIM2:
RFOBK =
RILIM 2 =
PFB × VOUT
IILIM2 × (1− PFB )
IILIM 2 × RVALLEY × RFOBK
VOUT + (IILIM 2 × (RFOBK − RVALLEY ))
where IILIM2 is 5µA.
If the resulting value of RILIM2 is negative, increase PFB.
Peak Current Limit
The peak current-limit threshold (VTH) is set by a resistor
connected from ILIM1 to GND (RILIM1). VTH corresponds
to the peak voltage across the sensing element (inductor
or current-sense resistor). RILIM1 is calculated as follows:
LX
ILIM2
7.5 × VTH
10μA
This allows a maximum DC output current of:
V
I
ILIM = TH − P−P
RL
2
where RL is the DC resistance of the inductor.
To ensure maximum output current, use the minimum
value of VTH from each setting, and the maximum RL
values at the highest expected operating temperature.
The DC resistance of the inductor’s copper wire has a
+0.38%/°C temperature coefficient.
An RC circuit is connected across the inductor (see
Figure 8). The RC time constant is set to be 1.1 to 1.2
times the inductor (L/RL) time constant. Pick the value
of C9 in the 0.1µF to 0.47µF range, and then calculate
R1 from:
R1 = 1.2L / (RL x C9)
Add a resistor (R2 in Figure 8) to the CS- connection to
minimize input offset error. Calculate the value of R2 as
follows:
• When VOUT ≥ 2.4V:
RILIM1 × 10μA ⎞
⎛
⎜ 20μA +
⎟ × R1
⎝
⎠
32kΩ
R2 =
20μA
• When VOUT < 2.4V:
R2 =
15μA x R1
RILIM1 x 10μA ⎞
⎛
⎜15μA +
⎟
32kΩ
⎝
⎠
L1
OUT
RFOBK
MAX8655
RILIM1 =
R1
C9
MAX8655
CS+
C10
RILIM2
Figure 7. ILIM2 Resistor Connections
16
VOUT
LX
R2
C11
CS-
Figure 8. Current Sense Using the Inductor’s DC Resistance
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
Add a 100pF (C10) capacitor across the CS+ and CSinputs close to the IC.
Input Capacitor
The input filter capacitor reduces peak currents drawn
from the power source and reduces noise and voltage
ripple on the input caused by the circuit’s switching.
The input capacitors must meet the ripple-current
requirement (IRMS) imposed by the switching currents
defined by the following equation:
IRMS =
ILOAD VOUT × (VIN − VOUT )
VIN
I RMS has a maximum value when the input voltage
equals twice the output voltage (VIN = 2 x VOUT), so
IRMS(MAX) = ILOAD / 2. Ceramic capacitors are recommended due to the low ESR and ESL at high frequency
with relatively low cost. Choose a capacitor that
exhibits less than 10°C temperature rise at the maximum operating RMS current for optimum long-term reliability. Ceramic capacitors with an X5R or better
temperature characteristic are recommended.
Output Capacitor
The key selection parameters for the output capacitor
are the actual capacitance value, the equivalent series
resistance (ESR), the equivalent series inductance
(ESL), and the voltage-rating requirements. These
parameters affect the overall stability, output-voltage
ripple, and transient response. The output ripple has
three components: variations in the charge stored in
the output capacitor, the voltage drop across the
capacitor’s ESR, and ESL caused by the current into
and out of the capacitor. The maximum output-voltage
ripple is estimated as follows:
VRIPPLE = VRIPPLE(ESR) + VRIPPLE(C) + VRIPPLE(ESL)
The output-voltage ripple as a consequence of the
ESR, ESL, and output capacitance is:
VRIPPLE(ESR) = IP−P × ESR
VRIPPLE(ESL) =
VRIPPLE(C) =
VIN
× ESL
L + ESL
IP−P
8 × COUT × fS
where IP-P is the peak-to-peak inductor current.
V −V
V
IP−P = IN OUT × OUT
fS × L
VIN
These equations are suitable for initial capacitor selection, but final values should be chosen based on a prototype or evaluation circuit. As a general rule, a smaller
current ripple results in less output-voltage ripple.
Since the inductor ripple current is a factor of the
inductor value and input voltage, the output-voltage ripple decreases with larger inductance, and increases
with higher input voltages. The MAX8655 is designed to
work with polymer, tantalum, aluminum electrolytic, or
ceramic output capacitors. The aluminum electrolytic
capacitor is the least expensive; however, it has higher
ESR. To compensate for this, use a ceramic capacitor
in parallel to reduce the switching ripple and noise.
Ceramic capacitors are recommended for high-frequency (500kHz to 1MHz) designs. For reliable and
safe operation, ensure that the capacitor’s voltage and
ripple-current ratings exceed the calculated values.
The response to a load transient depends on the
selected output capacitors. During a load transient, the
output voltage instantly changes by ESR x ΔI LOAD.
Before the regulator can respond, the output voltage
deviates further, depending on the inductor and outputcapacitor values. After a short time (see the Typical
Operating Characteristics section), the regulator
responds by regulating the output voltage back to its
nominal state. The regulator response time depends on
its closed-loop bandwidth. With a higher bandwidth,
the response time is faster, thus preventing the output
voltage from further deviation from its regulating value.
Compensation Design
The MAX8655 uses an internal transconductance error
amplifier whose output compensates the control loop.
The external inductor, output capacitor, compensation
resistor, and compensation capacitors determine the
loop stability. The inductor and output capacitor are chosen based on performance, size, and cost. Additionally,
the compensation resistor and capacitors are selected to
optimize control-loop stability. The component values,
shown in Figures 3 and 4, yield stable operation over the
given range of input-to-output voltages.
The regulator uses a current-mode control scheme that
regulates the output voltage by forcing the required current through the external inductor. The voltage drop
across the DC resistance of the inductor or the alternate
series current-sense resistor is used to measure the
inductor current. Current-mode control eliminates the
double pole in the feedback loop caused by the
______________________________________________________________________________________
17
MAX8655
Capacitor C11 is connected in parallel with R2 and is
equal in value with C9.
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
inductor and output capacitor resulting in a smaller
phase shift and requiring a less elaborate error-amplifier
compensation than voltage-mode control. A simple
series RC and CC is all that is needed to have a stable,
high-bandwidth loop in applications where ceramic
capacitors are used for output filtering. For other types
of capacitors, due to the higher capacitance and ESR,
the frequency of the zero created by the capacitance
and ESR is lower than the desired closed-loop crossover
frequency. To stabilize a nonceramic output-capacitor
loop, add another compensation capacitor from COMP
to GND to cancel this ESR zero. See Figure 9.
The basic regulator loop is modeled as a power modulator, an output feedback divider, and an error amplifier. The power modulator has DC gain GMOD(dc), set by
gmc x RLOAD, with a pole and zero pair set by RLOAD,
the output capacitor (COUT), and its equivalent series
resistance (ESR). Below are equations that define the
power modulator:
RLOAD
GMOD(dc) = gmc ×
⎡ RLOAD
× KS × (1 − D) − 0.5
⎢1 +
L × fS
⎣
where RLOAD = VOUT / IOUT(MAX), fS is the switching
frequency, L is the output inductance, gmc = 1 / (AVCS x
RL), where AVCS is the gain of the current-sense amplifier (12 typ), RL is the DC resistance of the inductor, the
duty cycle D = VOUT / VIN. KS is a slope compensation
factor calculated from the following equation:
[(
)
]
When COUT comprises “n” identical capacitors in parallel, the resulting COUT = n x COUT(EACH), and ESR =
ESR(EACH) / n. Note that the capacitor zero for a parallel combination of like capacitors is the same as for an
individual capacitor. Figure 10 is the simplified gain
plot for the fzMOD > fC case.
The feedback voltage-divider has a gain of GFB = VFB /
VOUT, where VFB is equal to 0.7V.
The transconductance error amplifier has a DC gain,
GEA(DC) = gmEA x RO, where gmEA is the error-amplifier transconductance, which is equal to 110µS, and RO
is the output resistance of the error amplifier, which is
30MΩ. A dominant pole (fpdEA) is set by the compensation capacitor (CC), the amplifier output resistance
(RO), and the compensation resistor (RC); a zero (fzEA)
is set by the compensation resistor (RC) and the compensation capacitor (CC). There is an optional pole
(fpEA) set by CF and RC to cancel the output capacitor
ESR zero if it occurs near the crossover frequency (fC).
Thus:
fpdEA =
VSCOMP × L × fS
KS = 1 +
120 × (VIN − VO ) × RL
When SCOMP is connected to GND, use VSCOMP = 1.25V;
when SCOMP is connected to AVL, use VSCOMP = 2.5V.
Find the pole and zero frequencies created by the
power modulator as follows:
1
fpMOD =
+
2π × RLOAD × COUT
⎡
⎤
1
× [KS × (1 − D) − 0.5]⎥
⎢
⎣ 2π × L × fS × COUT
⎦
1
2π × COUT × ESR
fzMOD =
1
2π × CC × (RO + RC )
fzEA =
1
2π × CC × RC
fpEA =
1
2π × CF × RC
CLOSED LOOP
GAIN
(dB)
POWER
MODULATOR
ERROR
AMPLIFIER
COMP
CF
MAX8655
RC
CC
Figure 9. Compensation Components
18
fc
0dB
FREQUENCY
fpMOD
FB
DIVIDER
fzMOD
Figure 10. Simplified Gain Plot for the fzMOD > fC Case
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
f
fpMOD << fC ≤ S
5
The error-amplifier gain at fC is:
f
GEA(fc) = gmEA × RC × zMOD
fC
Figure 11 is the simplified gain plot for the fzMOD < fC
case.
At the crossover frequency, the total loop gain must
equal 1, and is expressed as:
GEA(fc) × GMOD(fc) ×
VFB
=1
VOUT
For the case where fzMOD is greater than fC:
CLOSED LOOP
GAIN
(dB)
POWER
MODULATOR
ERROR
AMPLIFIER
GEA(fc) = gmEA × RC
GMOD(fc) = GMOD(dc) ×
fpMOD
fC
0dB
FREQUENCY
fpMOD
FB
DIVIDER
fzMOD
fc
Then RC can be calculated as:
VOUT
RC =
gmEA × VFB × GMOD(fc)
where gmEA = 110µS.
The error-amplifier compensation zero formed by RC
and CC should be set at the modulator pole fPMOD.
Calculate the value of CC as follows:
CC =
1
2π × fp
MOD
× RC
If fzMOD is less than 5 x fC, add a second capacitor CF
from COMP to GND. The value of CF is:
CF =
1
2π × RC × fzMOD
As the load current decreases, the modulator pole
also decreases; however, the modulator gain increases
accordingly and the crossover frequency remains
the same.
For the case where fzMOD is less than fC:
The power modulator gain at fC is:
GMOD(fc) = GMOD(dc) ×
fpMOD
fzMOD
Figure 11. Simplified Gain Plot for the fzMOD < fC Case
RC is calculated as:
V
fC
RC = OUT ×
VFB
gmEA × GMOD(fc) × fzMOD
where gmEA = 110µS.
CC is calculated from:
1
CC =
2π × fp
MOD
× RC
CF is calculated from:
CF =
1
2π × RC × fzMOD
The current-mode control model on which the above
design procedure is based requires an additional highfrequency term, GS(s), to account for the effect of sampling the peak inductor current. The term G S (s)
produces additional phase lag at crossover and should
be modeled to estimate the phase margin obtainable
by the selected compensation components. As a final
step, it is useful to plot the dB gain and phase of the
following loop-gain transfer function and check the
______________________________________________________________________________________
19
MAX8655
The crossover frequency, fC, should be much higher
than the power-modulator pole fPMOD. Also, fC should
be less than or equal to 1/5 the switching frequency.
Select a value for fC in the range:
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
obtained phase margin. A phase margin of at least 45°
is recommended:
GLOOP (s) =
gmc × RLOAD
⎡ RLOAD
⎤
× (KS × (1 − D)) − 0.5 ⎥
⎢1 +
L × fS
⎣
⎦
(1 + s / 2π × fzMOD )
×
(1 + s / 2π × fpMOD )
[
]
×
RLOAD
=
⎡ RLOAD
⎤
⎢1 + L × fs × KS × (1 − D) − 0.5 ⎥
⎣
⎦
0.06
= 2.53
46.29 ×
0.06
× [1.18(1 − 0.1) − 0.5]
1+
(0.56 x10 −6 )(600000)
GMOD(dc) = gmc ×
fpMOD =
gmEA × Ro × VFB
GS (s)
VO
where the sampling effect quality factor:
QC =
1
[π.(KS.(1 − D) − 0.5)]
,
Below is a numerical example to calculate RC and CC
values of the typical operating circuit of Figure 3:
AVCS = 12
L = 0.56µH
]
1
+
2π × RLOAD × COUT × 0.9
⎡
⎤
1
⎢
(1.18(1 − 0.1) − 0.5)⎥⎥ = 8.18kHz
⎢ 2π(0.56 x10 −6 )(600000)(400x10 −6 ) × 0.8
⎣
⎦
f
fpMOD << fC ≤ S
5
1
⎛
⎞
s
s2
⎜1 +
⎟
+
⎜ π.Qc.fS ( π.f )2 ⎟
⎝
S ⎠
)
⎡
⎤
1
× [KS × (1 − D) − 0.5]⎥ =
⎢
⎣ 2π × L × fS × COUT × 0.8
⎦
1
+
2π(400x10 −6 )(0.06) × 0.9
(1 + s / 2π × fzEA )
×
(1 + s / 2π × fpEA ) × (1 + s / 2π × fpdEA )
GS (s) =
[(
8.18kHz << fC ≤ 120kHz, select fC = 60kHz.
fzMOD =
1
1
=
= 884.2kHz
2π × 0.9 × COUT × ESR 2π × 0.9 × (400 × 10 −6 ) × 0.0005
Since fzMOD > fC:
GMOD( fc) = GMOD(dc) ×
fpMOD
fc
= 2.53 ×
8118
= 0.345
60000
V
1
RC = OUT ×
VFB
gmEA × GMOD( fc)
1.2
1
=
×
−
0.7 (110 x10 6 )(0.307)
RL = 1.8mΩ
fS = 600kHz
gmc = 1 / (AVCS x RL) = 1 / (12 x 0.0018) = 46.29S
VOUT = 1.2V
IOUT(MAX) = 20A
RLOAD = VOUT / IOUT(MAX) = 1.2 / 20 = 0.06Ω
RC = 44.7kΩ
Select the nearest standard value: RC = 40.2kΩ:
COUT = 4 x 100µF = 400µF
ESR = 2mΩ/4 = 0.5mΩ
D = VOUT / VIN = 1.2/12 = 0.1:
Select the nearest standard value: CC = 470pF:
KS = 1 +
VSCOMP × L × fS
120 × (VIN − VO ) × RL
1.25(0.56 x10 −6 )(600000)
= 1+
120(12 − 1.2)(0.0018)
= 1.18
20
CC =
CF =
1
2π × fp
MOD
× RC
=
1
2π × 8181 × (40.2 x103 )
= 483.9pF
1
1
=
= 5pF
2π × RC × fzMOD 2π × (40.2 × 103 ) × (884.2 x103 )
R7 = RC = 40.2kΩ
C12 = CC = 470pF
C11 = CF = 5pF (not used)
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
PCB Layout Guidelines
Careful PCB layout is critical to achieve low losses and
clean, stable operation. Refer to the MAX8655
Evaluation Kit for an example layout. If it is necessary to
deviate from this layout, follow the procedure below.
Follow these guidelines for good PCB layout:
1) Place IC decoupling capacitors as close as possible to the IC pins. Separate the power and analog
ground planes. Place the input ceramic decoupling
capacitor directly across and as close as possible
to PVIN and PGND. This is to help contain the high
switching current within this small loop.
2) For output current greater than 10A, a four-layer
PCB is recommended. Pour an analog ground
plane in the second layer underneath the IC to minimize noise coupling.
3) Connect input, output, and VL capacitors to the
power ground plane; connect all other capacitors to
the signal ground plane. Connect analog and
power ground planes at the output capacitor.
4) Place the inductor current-sense resistor and
capacitor as close as possible to the inductor.
Make a Kelvin connection to minimize the effect of
PCB trace resistance. Place the input bias balance
resistor (R2 in Figure 8) near CS-. Run two closely
parallel traces from across capacitor C9 to CS+
and the input bias balance resistor R2.
5) Connect the exposed pad sections to the corresponding IC pins and allow sufficient copper area
to help cooling the device.
6) Place the feedback and compensation components
as close as possible to the IC pins. Connect the
feedback resistor-divider from FB to VOUT as close
as possible to the farthest output capacitor.
Chip Information
PROCESS: BiCMOS
______________________________________________________________________________________
21
MAX8655
Applications Information
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
N.C.
N.C.
CS+
CS-
ILIM1
OVP
FB
COMP
SS
REFIN
GND
ILIM2
N.C.
TOP VIEW
SCOMP
MAX8655
Pin Configuration
42 41 40 39 38 37 36 35 34 33 32 31 30 29
POK 43
28 GND
FSYNC 44
27 AVL
MODE 45
26 EN
GND-EP
SYNCO 46
25 IN
BST 47
24 VL
GND 48
23 GND
MAX8655ETN
N.C. 49
22 VLGND
LXB 50
21 LX
PVIN 51
20 LX
PVIN 52
PVIN-EP
19 LX
LX-EP
PVIN 53
18 LX
PVIN 54
17 LX
PVIN 55
16 LX
+
10 11 12 13 14
PGND
9
PGND
PVIN
8
PGND
PVIN
7
PGND
PVIN
6
PGND
5
PGND
4
PGND
3
PGND
2
LX
1
PVIN
15 PGND
PVIN
PVIN 56
THIN QFN
(8mm x 8mm)
22
______________________________________________________________________________________
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
56L THIN QFN.EPS
______________________________________________________________________________________
23
MAX8655
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)
MAX8655
Highly Integrated, 25A, Wide-Input,
Internal MOSFET, Step-Down Regulator
Package Information (continued)
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
24 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2007 Maxim Integrated Products
is a registered trademark of Maxim Integrated Products, Inc.