MPS MPQ8632-4

MPQ8632
High Efficiency 18V Synchronous
Step-down Converter Family for 4A to 20A
FEATURES
Part Number
Current
Rating (A)
Input Voltage
OVP Mode
MPQ8632GLE-4
4
2.5V to 18V
Non-Latch
MPQ8632GLE-6
6
2.5V to 18V
Non-Latch
MPQ8632GLE-8
8
2.5V to 18V
Non-Latch
MPQ8632HGLE-10
10
2.5V to 18V
Non-Latch
MPQ8632GLE-10
10
2.5V to 18V
Latch-Off
MPQ8632GLE-12
12
2.5V to 18V
Non-Latch
MPQ8632GVE-15
15
2.5V to 18V
Non-Latch
MPQ8632GVE-20
20
2.5V to 18V
Non-Latch



DESCRIPTION

The MPQ8632 is a fully integrated high
frequency synchronous rectified step-down
switch mode converter. It offers a very compact
solution to achieve 4A/6A/8A/10A/12A/15A/20A
output current over a wide input supply range
with excellent load and line regulation.





The MPQ8632 uses Constant-On-Time (COT)
control mode to provide fast transient response
and ease loop stabilization.
An external resistor programs the operating
frequency from 200kHz to 1MHz and the
frequency keeps nearly constant as input
supply
varies
with
the
feedforward
compensation.
The default under voltage lockout threshold is
internally set at 4.1V, but a resistor network on
the enable pin can increase this threshold. The
soft start pin controls the output voltage startup
ramp. An open drain power good signal
indicates that the output is within nominal
voltage range.
It has fully integrated protection features that
include over-current protection, over-voltage
protection and thermal shutdown.
The MPQ8632 requires a minimal number of
readily available standard external components
and is available in a 16-Pin QFN 3mm×4mm or
a 29-Pin QFN 5mm×4mm package.


Low Input Voltage Range from 2.5V:
-- 2.5V to 18V with External 5V Bias
-- 4.5V to 18V with Internal Bias
Scalable Family of Products for 4A to 20A
Output Current Applications
-- 4A/6A/8A/10A/12A Share the Same
Footprint
--15A/20A Share the Same Footprint, with
Slight Change on Power Stage Section
from 4A/6A/8A/10A/12A
Optimal Low RDS(ON) Internal Power
MOSFETs Per Device
Proprietary Switching Loss Reduction
Technique
Adaptive COT for Ultrafast Transient
Response
0.5% Reference Voltage Over 0C to
70C Junction Temperature Range
Programmable Soft Start Time
Pre-Bias Start up
Programmable Switching Frequency from
200kHz to 1MHz
Non-latch OCP, OVP and Thermal
Shutdown Protection
Output Adjustable from 0.611V to 13V
APPLICATIONS






Telecom and Networking Systems
Base Stations
Servers
Personal Video Recorders
Flat Panel Television and Monitors
Distributed Power Systems
All MPS parts are lead-free and adhere to the RoHS directive. For MPS green
status, please visit MPS website under Products, Quality Assurance page.
“MPS” and “The Future of Analog IC Technology” are registered trademarks of
Monolithic Power Systems, Inc.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
1
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL APPLICATION
VIN
BST
IN
C1
C3
RFREQ
FREQ
EN
ON/OFF
VOUT
R4
C4
R1
MPQ8632
C2
FB
VCC
C5
L1
SW
R2
R3
SS
C6
PG
PGND
AGND
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
2
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
ORDERING INFORMATION
Part Number
Package
MPQ8632GLE-4*
QFN(3X4mm)
MPQ8632GLE-6
QFN(3X4mm)
MPQ8632GLE-8
QFN(3X4mm)
MPQ8632GLE-10
QFN(3X4mm)
MPQ8632HGLE-10
QFN(3X4mm)
MPQ8632GLE-12
QFN(3X4mm)
MPQ8632GVE-15
QFN(5X4mm)
MPQ8632GVE-20
QFN(5X4mm)
Top Marking
MP8632
E4
MP8632
E6
MP8632
E8
MP8632
E10
MP8632H
E10
MP8632
E12
MP8632
E15
MP8632
E20
* For Tape & Reel, add suffix –Z (e.g. MPQ8632GLE–4–Z)
PACKAGE REFERENCE
TOP VIEW
PG
6
PG
6
VCC
7
VCC
7
BST
8
BST
8
PGND
12
PGND
14
VIN
PGND
VIN
11
5
PGND
AGND
16
5
SW
AGND
PGND 10
4
13
VIN
SS
15
4
11
SS
PGND 10
FB 3
9
FB 3
SW
PGND
12
2
9
PGND
13
FREQ
16
1
SW
VIN
2
14
FREQ
EN
15
1
SW
EN
TOP VIEW
Part Number*
Package
Part Number*
Package
MPQ8632GLE-4
Junction Temperature
QFN (3x4mm)
Top Marking
MPQ8632GLE-6
Junction Temperature
QFN (3x4mm)
Top Marking
–40C to +125C
MP8632
E4
–40C to +125C
MP8632
E6
* For Tape & Reel, add suffix –Z (eg. MPQ8632GLE-4–Z)
* For Tape & Reel, add suffix –Z (eg. MPQ8632GLE-6–Z)
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
3
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TOP VIEW
AGND
5
PG
6
PG
6
VCC
7
VCC
7
BST
8
BST
8
PGND
12
PGND
14
VIN
PGND
PGND 10
9
VIN
11
5
PGND
AGND
16
4
SW
SS
PGND 10
4
13
VIN
SS
15
FB 3
11
FB 3
SW
PGND
12
2
9
PGND
13
FREQ
16
1
SW
VIN
2
14
FREQ
EN
15
1
SW
EN
TOP VIEW
Part Number*
Package
Part Number*
Package
MPQ8632GLE-8
Junction Temperature
QFN (3x4mm)
MPQ8632GLE-10
Junction Temperature
QFN (3x4mm)
–40C to +125C
MP8632
E8
–40C to +125C
MP8632
E10
Top Marking
* For Tape & Reel, add suffix –Z (eg. MPQ8632GLE-8–Z)
* For Tape & Reel, add suffix –Z (eg. MPQ8632GLE-10–Z)
TOP VIEW
PG
6
PG
6
VCC
7
VCC
7
BST
8
BST
8
PGND
12
PGND
14
VIN
PGND
VIN
11
5
PGND
AGND
16
5
SW
AGND
PGND 10
4
13
VIN
SS
15
4
11
SS
PGND 10
FB 3
9
FB 3
SW
PGND
12
2
9
PGND
13
FREQ
16
1
SW
VIN
2
14
FREQ
EN
15
1
TOP VIEW
SW
EN
Top Marking
Part Number*
Package
Part Number*
Package
MPQ8632HGLE-10
Junction Temperature
QFN (3x4mm)
Top Marking
MPQ8632GLE-12
Junction Temperature
QFN (3x4mm)
Top Marking
–40C to +125C
MP8632H
E10
–40C to +125C
MP8632
E12
* For Tape & Reel, add suffix –Z (eg. MPQ8632HGLE-10–Z)
* For Tape & Reel, add suffix –Z (eg. MPQ8632GLE-12–Z)
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
4
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
PGND
22
21 PGND
PGND
23
26
27
28
29
SW
SW
SW
SW
8
12
BST
PGND
13 PGND
11
8
PGND
BST
10
7
18 SW
PGND
VCC
12
14 PGND
PGND
7
11
VCC
PGND
15 SW
10
6
PGND
PG
9
IN
14 PGND
16 SW
IN
24
15 SW
29
6
SW
PG
28
16 SW
AGND 5
SW
AGND 5
27
17 SW
SW
4
26
SS
17 SW
SW
FB 3
25
18 SW
4
SS
19 PGND
25
FREQ 2
20 PGND
SW
19 PGND
SW
FB 3
EN 1
9
PGND
22
FREQ 2
20 PGND
IN
PGND
23
TOP VIEW
21 PGND
IN
EN 1
24
TOP VIEW
13 PGND
Part Number*
Package
Part Number*
Package
MPQ8632GVE-15
Junction Temperature
QFN (5x4mm)
Top Marking
MPQ8632GVE-20
Junction Temperature
QFN (5x4mm)
Top Marking
–40C to +125C
MP8632
E15
–40C to +125C
MP8632
E20
* For Tape & Reel, add suffix –Z (eg. MPQ8632GVE-15–Z)
* For Tape & Reel, add suffix –Z (eg. MPQ8632GVE-20–Z)
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
5
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
ABSOLUTE MAXIMUM RATINGS (1)
Supply Voltage VIN .......................................21V
VSW ....................................... -0.3V to VIN + 0.3V
VSW (30ns) ..................................-3V to VIN + 3V
VBST .....................................................VSW + 6V
VBST (30ns) ........................................VSW + 6.5V
Enable Current IEN(2)................................ 2.5mA
All Other Pins ................................ –0.3V to +6V
(3)
Continuous Power Dissipation (TA=+25)
QFN3X4……………………….…..…………2.7W
QFN5X4……………………….…..…………3.3W
Junction Temperature .............................. 150C
Lead Temperature ................................... 260C
Storage Temperature ............... -65C to +150C
Recommended Operating Conditions
Thermal Resistance
(5)
θJA
θJC
QFN (3x4mm) ........................ 46 ....... 9 .... C/W
QFN (5x4mm) ........................ 38 ....... 6 .... C/W
Notes:
1) Exceeding these ratings may damage the device.
2) Refer to the section “Configuring the EN Control”.
3) The maximum allowable power dissipation is a function of the
maximum junction temperature TJ(MAX), the junction-toambient thermal resistance θJA, and the ambient temperature
TA. The maximum allowable continuous power dissipation at
any ambient temperature is calculated by PD(MAX)=(TJ(MAX)TA)/θJA. Exceeding the maximum allowable power dissipation
will cause excessive die temperature, and the regulator will go
into thermal shutdown. Internal thermal shutdown circuitry
protects the device from permanent damage.
4) The device is not guaranteed to function outside of its
operating conditions.
5) Measured on JESD51-7, 4-layer PCB.
(4)
Supply Voltage VIN .......................... 4.5V to 18V
Output Voltage VOUT.................... 0.611V to 13V
Enable Current IEN...................................... 1mA
Operating Junction Temp. (TJ).-40°C to +125°C
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
6
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
ELECTRICAL CHARACTERISTICS
VIN = 12V, TJ = -40C to +125C, unless otherwise noted.
Parameters
Symbol
Condition
Min
Typ
Max
Units
700
0
860
1
1000
μA
μA
Supply Current
Supply Current (Shutdown)
Supply Current (Quiescent)
IIN
IIN
VEN = 0V
VEN = 2V, VFB = 1V
MOSFET
High-side Switch On Resistance
Low-side Switch On Resistance
Switch Leakage
HSRDS-ON
LSRDS-ON
SW LKG
MPQ8632GLE-4,6,8,
TJ =25C
MPQ8632GLE-10,12,
MPQ8632HGLE-10,
TJ =25C
MPQ8632GVE-15,20,
TJ =25C
28
mΩ
19.6
mΩ
9.9
mΩ
MPQ8632GLE-4, TJ =25C
16.4
MPQ8632GLE-6, TJ =25C
15.8
MPQ8632GLE-8, TJ =25C
15.3
MPQ8632GLE-10,
MPQ8632HGLE-10,
TJ =25C
5.7
MPQ8632GLE-12, TJ =25C
5.2
MPQ8632GVE-15, TJ =25C
3
MPQ8632GVE-20, TJ =25C
2.4
VEN = 0V, VSW = 0V or 12V
mΩ
0
10
μA
A
Current Limit
High-side Peak Current Limit
Low-side Valley Current Limit
Low-side Negative Current
(6)
Limit
ILIMIT_PEAK
(6)
ILIMIT_VALLEY
MPQ8632GLE-10
13
17.3
21.6
MPQ8632GLE-4
4
5
6
MPQ8632GLE-6
6.5
7.5
8.5
MPQ8632GLE-8
8
10
12
MPQ8632GLE-10
9.5
11
12.5
MPQ8632HGLE-10
10
13
16
MPQ8632GLE-12
12
15
18
MPQ8632GVE-15
15
20
25
MPQ8632GVE-20
20
25
30
MPQ8632GVE-15
-6.6
-5.6
-4.6
-4
-2.5
-1
ILIMIT_NEGATIVE
A
A
All other parts
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
7
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
ELECTRICAL CHARACTERISTICS (continued)
VIN = 12V, TJ = -40C to +125C, unless otherwise noted.
Parameters
Symbol
Condition
Min
Typ
Max
Units
Timer
One-Shot On Time
TON
Minimum On Time
(6)
TON_MIN
Minimum Off Time
(6)
TOFF_MIN
Over-voltage and Under-voltage Protection
(6)
OVP Latch Threshold
VOVP_LATCH
OVP Non-latch Threshold
RFREQ=453kΩ, VOUT=1.2V
250
ns
20
30
40
ns
MPQ8632GLE-10
Other parts
50
200
100
360
150
420
ns
MPQ8632GLE-10
127%
130%
133%
VFB
117%
120%
123%
VFB
VOVP_NONLATCH
OVP Delay
(6)
UVP Threshold
Reference And Soft Start
Reference Voltage
Feedback Current
Soft Start Charging Current
TOVP
VUVP
VREF
IFB
ISS
μs
2
TJ = 0°C to +70°C
TJ = 0°C to +125°C
TJ = -40°C to +125°C
VFB = 611mV
VSS=0V
47%
50%
53%
VFB
608
605
602
611
611
611
50
20
614
617
620
100
25
mV
mV
mV
nA
μA
1.3
250
0
0
1.5
V
mV
16
Enable And UVLO
Enable Input Low Voltage
Enable Hysteresis
Enable Input Current
VILEN
VEN-HYS
IEN
1.1
VEN = 2V
VEN = 0V
μA
VCC Regulator
VCC Under Voltage Lockout
Threshold Rising
VCC Under Voltage Lockout
Threshold Hysteresis
VCC Regulator
VCCVth
3.8
V
VCCHYS
500
mV
VCC
4.8
V
0.5
%
VCC Load Regulation
Power Good
Power Good Rising Threshold
Power Good Falling Threshold
Power Good Lower to High Delay
Power Good Sink Current
Capability
Power Good Leakage Current
Icc=5mA
PGVth-Hi
PGVth-Lo
PGTd
87%
IOL
VOL=600mV
IPG_LEAK
VPG = 3.3V
91%
80%
2.5
10
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
94%
VFB
VFB
ms
12
mA
nA
8
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
ELECTRICAL CHARACTERISTICS (continued)
VIN = 12V, TJ = -40C to +125C, unless otherwise noted.
Parameters
Thermal Protection
Symbol
Condition
Min
Typ
Max
Units
(6)
Thermal Shutdown
Thermal Shutdown Hysteresis
TSD
150
25
°C
°C
Note:
6) Guaranteed by design.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
9
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
PIN FUNCTIONS
MPQ8632GLE-4, MPQ8632GLE-6,
MPQ8632HGLE-10, MPQ8632GLE-12
MPQ8632GLE-8,
MPQ8632GLE-10,
PIN #
Name
1
EN
2
FREQ
3
FB
4
SS
5
AGND
6
PG
7
VCC
8
BST
9, 14
IN
10-13
PGND
System Ground. Reference ground of the regulated output voltage. PCB layout
requires extra care. Connect using wide PCB traces.
SW
Switch Output. Connect to the inductor and bootstrap capacitor. The high-side
switch drives the pin up to the VIN during the PWM duty cycle’s ON time. The
inductor current drives the SW pin negative during the OFF-time. The low-side
switch’s ON-resistance and the internal Schottky diode clamp the negative voltage.
Connect using wide PCB traces.
15, 16
Description
Enable. Digital input that turns the regulator on or off. Drive EN high to turn on the
regulator, drive it low to turn it off. Connect EN to IN through a pull-up resistor or a
resistive voltage divider for automatic startup. Do not float this pin.
Frequency Set. Require a resistor connected between FREQ and IN to set the
switching frequency. The input voltage and the resistor connected to the FREQ pin
determine the ON time. The connection to the IN pin provides line feed-forward and
stabilizes the frequency during input voltage’s variation.
Feedback. Connect to the tap of an external resistor divider from the output to GND
to set the output voltage. FB is also configured to realize over-voltage protection
(OVP) by monitoring output voltage. MPQ8632 and MPQ8632H provide different
OVP mode. Please refer to the section “Over-Voltage-Protection (OVP)”. Place the
resistor divider as close to FB pin as possible. Avoid using vias on the FB traces.
Soft Start. Connect an external capacitor to program the soft start time for the
switch mode regulator.
Analog ground. The control circuit reference.
Power Good. The output is an open drain signal. Require a pull-up resistor to a DC
voltage to indicate high if the output voltage exceeds 91% of the nominal voltage.
There is a delay from FB ≥ 91% to PG goes high.
Internal 4.8V LDO Output. Power the driver and control circuits. 5V external bias
can disable the internal LDO. Decouple with a ≥ 1µF ceramic capacitor as close to
the pin as possible. For best results, use X7R or X5R dielectric ceramic capacitors
for their stable temperature characteristics.
Bootstrap. Require a capacitor connected between SW and BST pins to form a
floating supply across the high-side switch driver.
Supply Voltage. Supply power to the internal MOSFET and regulator. The
MPQ8632 operates from a +2.5V to +18V input rail with 5V external bias and a
+4.5V to +18V input rail with internal bias. Require an input decoupling capacitor.
Connect using wide PCB traces and multiple vias.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
10
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
MPQ8632GVE-15, MPQ8632GVE-20
PIN #
Name
1
EN
2
FREQ
3
FB
4
SS
5
AGND
6
PG
7
VCC
8
BST
15-18,
25-29
SW
10-14, 19-23
PGND
9, 24
IN
Description
Enable. Digital input that turns the regulator on or off. Drive EN high to turn on the
regulator; drive it low to turn it off. Connect EN to IN through a pull-up resistor or a
resistive voltage divider for automatic startup. Do not float this pin.
Frequency Set. Require a resistor connected between FREQ and IN to set the
switching frequency. The input voltage and the resistor connected to the FREQ pin
determine the ON time. The connection to the IN pin provides line feed-forward and
stabilizes the frequency during input voltage’s variation.
Feedback. Connect to the tap of an external resistor divider from the output to GND
to set the output voltage. Place the resistor divider as close to FB pin as possible.
Avoid using vias on the FB traces.
Soft-Start. Connect an external capacitor to program the soft start time for the switch
mode regulator.
Analog Ground. The control circuit reference.
Power-Good. The output is an open drain signal. Requires a pull-up resistor to a DC
voltage to indicate HIGH if the output voltage exceeds 91% of the nominal voltage.
There is a delay from FB ≥ 91% to when PG goes high.
Internal 4.8V LDO Output. Powers the driver and control circuits. 5V external bias
can disable the internal LDO. Decouple with a ≥1µF ceramic capacitor as close to the
pin as possible. For best results, use X7R or X5R dielectric ceramic capacitors for
their stable temperature characteristics.
Bootstrap. Require a capacitor connected between SW and BST pins to form a
floating supply across the high-side switch driver.
Switch Output. Connect to the inductor and bootstrap capacitor. The high-side switch
drives these pins up to VIN during the PWM duty cycle’s ON time. The inductor
current drives the SW pin negative during the OFF-time. The low-side switch’s ONresistance and the internal Schottky diode holds the negative voltage. Connect all
SW pins using wide PCB traces.
System Ground. Reference ground of the regulated output voltage. PCB layout
requires extra care. Connect using wide PCB traces.
Supply Voltage. Supplies power to the internal MOSFET and regulator. The
MPQ8632GVE operate from a 4.5V-to-18V input rail. If 5V external bias is tied to
VCC pin, the input voltage can be low as 2.5V. Requires an input decoupling
capacitor. Connect using wide PCB traces and multiple vias.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
© 2013 MPS. All Rights Reserved.
11
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL CHARACTERISTICS
MPQ8632GLE-10, VIN = 12V, VOUT = 1V, L = 1µH, TA = 25ºC, unless otherwise noted.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited.
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12
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL CHARACTERISTICS (continued)
MPQ8632GLE-10, VIN = 12V, VOUT = 1V, L = 1µH, TA = 25ºC, unless otherwise noted.
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
MPQ8632GLE-10, VIN = 12V, VOUT = 1V, L = 1µH, TA = 25ºC, unless otherwise noted.
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
MPQ8632GLE-10, VIN=12V, VOUT =1V, L=1µH, TA=+25°C, unless otherwise noted.
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
MPQ8632GLE-10, VIN=12V, VOUT =1V, L=1µH, TA=+25°C, unless otherwise noted.
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
MPQ8632GLE-10, VIN=12V, VOUT =1V, L=1µH, TA=+25°C, unless otherwise noted.
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
BLOCK DIAGRAM
IN
FREQ
VCC
VCC
EN
LDO
BST
BIAS
Minimum
OFF Timer
REFERENCE
ON
Timer
BST
HS
Driver
HS-FET
LOGIC
SS
SW
SOFT START
VCC
FB
LS
Driver
FB
Comparator
PG
UV
PGOOD
Comparator
UV Detect
Comparator
OV
LS-FET
ZCD
Current
Modulator
GND
LS Current
Limit
AGND
OV Detect
Comparator
Figure 1—Functional Block Diagram
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
OPERATION
PWM Operation
The MPQ8632 is a fully integrated synchronous
rectified step-down switch mode converter. It
uses Constant-on-time (COT) control to provide a
fast transient response and ease loop
stabilization.
At the beginning of each cycle, the high-side
MOSFET (HS-FET) turns ON when the feedback
voltage (VFB) drops below the reference voltage
(VREF), which indicates an insufficient output
voltage. The input voltage and the frequency-set
resistor determine the ON period as follows:
TON (ns) 
6.1 RFREQ (k)
VIN (V)  0.4
(1)
After the ON period elapses, the HS-FET turns
off. It turns ON again when VFB drops below VREF.
By repeating this operation, the converter
regulates the output voltage. The integrated lowside MOSFET (LS-FET) turns on when the HSFET is OFF to minimize the conduction loss.
There is a dead short (or shoot-through)
between input and GND if both HS-FET and LSFET turn on at the same time. A dead-time (DT)
internally generated between HS-FET OFF and
LS-FETON, or LS-FET OFF and HS-FET ON
avoids shoot-through.
Heavy-Load Operation
interval determined by the one- shot on-timer as
per equation 1. When the HS-FET turns off, the
LS-FET turns on until the next period.
In CCM operation, the switching frequency is
fairly constant and is also called PWM mode.
Light-Load Operation
As the load decreases, the inductor current
decreases too. When the inductor current
touches zero, the operation is transited from
continuous-conduction-mode
(CCM)
to
discontinuous-conduction-mode (DCM).
Figure 3 shows the light load operation. When
VFB drops below VREF, HS-FET turns on for a
fixed interval determined by the one- shot ontimer as per equation 1. When the HS-FET turns
off, the LS-FET turns on until the inductor current
reaches zero. In DCM operation, the VFB does
not reach VREF when the inductor current is
approaching zero. The LS-FET driver turns into
tri-state (high Z) whenever the inductor current
reaches zero. A current modulator takes over the
control of LS-FET and limits the inductor current
less than -1mA. Hence, the output capacitors
discharge slowly to GND through LS-FET. As a
result, this mode improves greatly the light load
efficiency. At light load condition, the HS-FET
does not turns ON as frequently as at heavy load
condition. This is called skip mode.
At light load or no load condition, the output
drops very slowly and the MPQ8632 reduces the
switching frequency naturally and then achieves
high efficiency at light load.
Figure 2—Heavy Load Operation
Figure 3—Light Load Operation
When the output current is high and the inductor
current is always above zero amps, it is called
continuous-conduction-mode (CCM). Figure 2
shows the CCM operation. When VFB is below
VREF, HS-FET turns on for a fixed
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
As the output current increases from the light
load condition, the current modulator regulates
the operating period that becomes shorter. The
HS-FET turns ON more frequently. Hence, the
switching frequency increases correspondingly.
The output current reaches the critical level when
the current modulator time decreases to zero.
Determine the critical output current level as
follows:
IOUT 
( VIN  VOUT )  VOUT
2  L  FSW  VIN
(2)
Where FSW is the switching frequency.
high switching frequencies allow for physically
smaller LC filter components to reduce the PCB
footprint.
Jitter and FB Ramp Slope
Figure 4 and Figure 5 show jitter occurring in
both PWM mode and skip mode. When there is
noise on the VFB descending slope, the HS-FET
ON time deviates from its intended point and
produces jitter and influences system stability.
The VFB ripple’s slope steepness dominates the
noise immunity though its magnitude has no
direct effect.
The IC turns into PWM mode once the output
current exceeds the critical level. After that, the
switching frequency stays fairly constant over the
output current range.
Switching Frequency
Selecting the switching frequency requires
trading off between efficiency and component
size. Low frequency operation increases
efficiency by reducing MOSFET switching losses,
but requires larger inductor and capacitor values
to minimize the output voltage ripple.
Figure 4—Jitter in PWM Mode
For MPQ8632，set the on time using the FREQ
pin to set the frequency for steady state
operation at CCM.
The MPQ8632 uses adaptive constant-on-time
(COT) control, though the IC lacks a dedicated
oscillator. Connect the FREQ pin to the IN pin
through the resistor (RFREQ) so that the input
voltage is feed-forwarded to the one-shot on-time
timer. When operating in steady state at CCM,
the duty ratio stays at VOUT/VIN, so the switching
frequency is fairly constant over the input voltage
range. Set the switching frequency as follows:
FSW (kHz) 
106
6.1 RFREQ (k) VIN (V)

 TDELAY (ns)
VIN (V)  0.4
VOUT (V)
(3)
Figure 5—Jitter in Skip Mode
Ramp with a Large ESR Capacitor
Using POSCAPs or other large-ESR capacitors
as the output capacitor results in the ESR ripple
dominating the output ripple. The ESR also
significantly influences the VFB slope. Figure 6
shows the simplified equivalent circuit in PWM
mode with the HS-FET off and without an
external ramp circuit.
Where TDELAY is the comparator delay of about
5ns.
Typically, the MPQ8632 is set to 200kHz to
1MHz applications. It is optimized to operate at
high switching frequencies at high efficiency:
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Where:
SW
L
VOUT
FB
IR4  IC4  IFB  IC4
ESR
R1
(6)
Then estimate the ramp on VFB as:
VRAMP 
POSCAP
R2
VIN  VOUT
 R1// R2 
 TON  

R4  C4
 R1// R2  R9 
(7)
The VFB ripple’s descending slope then follows:
Figure 6—Simplified Circuit in PWM Mode
without External Ramp Compensation
To realize the stability without an external ramp,
usually select the ESR value as follows:
TSW
T
 ON
0
.
7


2
RESR 
COUT
(4)
VSLOPE1 
L
SW
R4
VOUT
C4
IR4
IC4
R9
(8)
Equation 8 shows that if there is instability in
PWM mode, reduce either R4 or C4. If C4 is
irreducible due to equation 5 limitations, then
reduce R4. For a stable PWM operation, design
Vslope1 based on equation 9.
Where TSW is the switching period.
Ramp with a Small ESR Capacitor
Use an external ramp when using ceramic output
capacitors, because the ESR ripple is not high
enough to stabilize the system.
 VOUT
VRAMP

TOFF
R4  C4
 VSLOPE1
TSW
T
 ON  RESR  COUT
I  103
0.7


2

 VOUT  OUT
2  L  COUT
TSW  TON
(9)
Where IOUT is the load current.
In skip mode, The VFB ripple’s descending slope
is almost same whether the external ramp is
used or not. Figure 8 shows the simplified circuit
in skip mode when both the HS-FET and LS-FET
are off.
R1
VOUT
IFB
Ceramic
FB
FB
R2
R1
COUT
ROUT
R2
Figure 7—Simplified Circuit in PWM Mode
with External Ramp Compensation
Figure 7 shows the simplified circuit in PWM
mode with the HS-FET OFF and an external
ramp compensation circuit (R4, C4). Design the
external ramp based on the inductor ripple
current. Select C4, R9, R1 and R2 to meet the
following condition:
1  R1 R2

 
 R9 
2  FSW  C4 5  R1  R2

1
(5)
Figure 8—Simplified Circuit in skip Mode
Determine the VFB ripple’s descending slope in
skip mode as follows:
VSLOPE2 
 VREF
[(R1  R2) // ROUT ]  COUT
(10)
Where ROUT is the equivalent load resistor.
Figure 5 shows that VSLOPE2 in skip mode is lower
than that is in PWM mode, so it is
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
reasonable that the jitter in skip mode is larger
To achieve less jitter during ultra light load
condition, reduce R1 and R2, but that will
decrease the light load efficiency.
Configuring the EN Control
The regulator turns on when En goes high;
conversely it turns off when EN goes low. Do not
float the pin.
For automatic start-up, pull the EN pin up to input
voltage through a resistive voltage divider.
Choose the values of the pull-up resistor (RUP
from the IN pin to the EN pin) and the pull-down
resistor (RDOWN from the EN pin to GND) to
determine the automatic start-up voltage:
VINSTART  1.5 
(RUP  RDOWN )
(V)
RDOWN
(11)
For example, for RUP=100kΩ and RDOWN=51kΩ,
the VIN-START is set at 4.44V.
To reduce noise, add a 10nF ceramic capacitor
from EN to GND.
An internal zener diode on the EN pin clamps the
EN pin voltage to prevent run away. The
maximum pull up current assuming the worst
case 6V for the internal zener clamp should be
less than 1mA.
Therefore, when driving EN with an external logic
signal, use an EN voltage less than 6V. When
connecting EN to IN through a pull-up resistor or
a resistive voltage divider, select a resistance
that ensures a maximum pull-up current less than
1mA.
If using a resistive voltage divider and VIN
exceeds 6V, then the minimum resistance for the
pull-up resistor RUP should meet:
VIN  6V
6V

 1mA
R UP
R DOWN
(12)
With only RUP (the pull-down resistor, RDOWN, is
not connected), then the VCC UVLO threshold
determines VIN-START, so the minimum resistor
value is:
R UP 
VIN  6V
()
1mA
A typical pull-up resistor is 100kΩ.
External VCC bias
An external 5V VCC bias can disable the internal
LDO, in this case, Vin can be as low as 2.5V.
Soft Start
The MPQ8632 employs a soft start (SS)
mechanism to ensure a smooth output during
power-up. When the EN pin goes high, an
internal current source (20μA) charges the SS
capacitor. The SS capacitor voltage takes over
the REF voltage to the PWM comparator. The
output voltage smoothly ramps up with the SS
voltage. Once the SS voltage reaches the REF
voltage, it continues ramping up while VREF takes
over the PWM comparator. At this point, soft start
finishes and the device enters steady state
operation.
Determine the SS capacitor value as follows:
CSS  nF  
TSS  ms   ISS  A 
VREF  V 
(14)
If the output capacitors are large, then avoid
setting a short SS time or risk hitting the current
limit during SS. Use a minimum value of 4.7nF if
the output capacitance value exceeds 330μF.
Pre-Bias Startup
The MPQ8632 has been designed for monotonic
startup into pre-biased loads. If the output is prebiased to a certain voltage during startup, the IC
will disable switching for both high-side and lowside switches until the voltage on the soft-start
capacitor exceeds the sensed output voltage at
the FB pin.
Power Good (PG)
The MPQ8632 has a power-good (PG) output.
The PG pin is the open drain of a MOSFET.
Connect it to VCC or some other voltage source
that measures less than 5.5V through a pull-up
resistor (typically 100kΩ). After applying the input
voltage, the MOSFET turns on so that the PG pin
is pulled to GND before the SS is ready. After the
FB voltage reaches 91% of the REF voltage, the
PG pin is pulled high after a 2.5ms delay.
(13)
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
When the FB voltage drops to 80% of the REF
voltage or exceeds 120% of the nominal REF
voltage, the PG pin is pulled low.
If the input supply fails to power the MPQ8632,
the PG pin is also pulled low even though this pin
is tied to an external DC source through a pull-up
resistor (typically 100kΩ).
Over-Current Protection (OCP)
The MPQ8632 features three current limit levels
for over-current conditions: high-side peak
current limit, low-side valley current limit and lowside negative current limit.
However, the OCP operation mechanism of
MPQ8632GL-10 is different from other parts in
this family.
For MPQ8632GLE-10:
High-Side Peak Current Limit: The part has a
cycle-by-cycle over-current limiting function. The
device monitors the inductor current during the
HS-FET ON state. When the sensed inductor
current hits the peak current limit, the output
over-current comparator goes high, the device
enters OCP mode immediately and turns off the
HS-FET and turns on the LS-FET.
Low-Side Valley Current Limit: The device also
monitors the inductor current during the LS-FET
ON state. When ILIM=1 and at the end of the
OFF time, the LS-FET sourcing current is
compared to the internal positive-valley–current
limit. If the valley current limit is less than the LSFET sourcing current, the HS-FET remains OFF
and the LS-FET remains ON for the next ON time.
When the LS-FET sourcing current drops below
the valley current limit, the HS-FET turns on
again.
For other parts except MPQ8632GLE-10:
These parts enter OCP mode if only the LS-FET
sourcing valley current exceeds the valley current
limit. Once the OCP is triggered, the LS-FET
keeps ON state until the LS-FET sourcing valley
current is less than the valley current limit. And
then the LS-FET turns off, the HS-FET turns on
for a fixed time determined by frequency-set
resistor RFREQ and input voltage.
soft-start capacitor and then automatically retries
soft-start. If the over-current condition still holds
after soft-start ends, the device repeats this
operation cycle until the over-current conditions
disappear and then output rises back to
regulation level. OCP offers non-latch protection.
Low-Side Negative Current Limit: If the sensed
LS-FET negative current exceeds the negative
current limit, the LS-FET turns off immediately
and stays OFF for the remainder of the OFF
period. In this situation, both MOSFETs are OFF
until the end of a fixed interval. The HS-FET body
diode conducts the inductor current for the fixed
time.
Over -Voltage Protection (OVP)
The MPQ8632 monitors the output voltage using
the FB pin connected to the tap of a resistor
divider to detect over-voltage. MPQ8632 and
MPQ8632H provide non-latch and latch off OVP
mode as showed in Table 1.
Table 1—OVP Mode
OVP Mode
Part #
Non-Latch Mode
Latch-Off Mode
MPQ8632-4
MPQ8632-6
MPQ8632-8
MPQ8632H-10
MPQ8632-12
MPQ8632-15
MPQ8632-20
MPQ8632-10
For MPQ8632GLE-10:
If the FB voltage exceeds the nominal REF
voltage but remains lower than 120% of the REF
voltage (0.611V), both MOSFETs are off.
If the FB voltage exceeds 120% of the REF
voltage but remains below 130%, the LS-FET
turns on while the HS-FET remains off. The LSFET remains on until the FB voltage drops below
110% of the REF voltage or the low-side
negative current limit is hit.
If the FB voltage exceeds 130% of the REF
voltage, then the device is latched off. Need
cycle the input power supply or EN to restart.
During OCP, the device tries to recover from the
over-current fault with hiccup mode: the chip
disables the output power stage, discharges the
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
For other parts except MPQ8632GLE-10:
Even the FB voltage exceeds 130% of the REF
voltage, these parts enter a non-latch off mode.
Once the FB voltage comes back to the
reasonable value, they will exit this OVP mode
and operate normally again.
UVLO protection
Thermal Shutdown
The MPQ8632 has thermal shutdown. The IC
internally monitors the junction temperature. If
the junction temperature exceeds the threshold
value (minimum 150ºC), the converter shuts off.
This is a non-latch protection. There is about
25ºC hysteresis. Once the junction temperature
drops to about 125ºC, it initiates a soft startup.
The MPQ8632 has under-voltage lock-out
protection (UVLO). When the VCC voltage
exceeds the UVLO rising threshold voltage, the
MPQ8632 powers up. It shuts off when the VCC
voltage falls below the UVLO falling threshold
voltage. This is non-latch protection.
The MPQ8632 is disabled when the VCC voltage
falls below 3.3 V. If an application requires a
higher UVLO threshold, use the two external
resistors connected to the EN pin as shown in
Figure 9 to adjust the startup input voltage. For
best results, use the enable resistors to set the
input voltage falling threshold (VSTOP) above 3.6 V.
Set the rising threshold (VSTART) to provide
enough hysteresis to account for any input
supply variations.
IN
RUP
R DOWN
EN Comparator
EN
Figure 9—Adjustable UVLO Threshold
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
APPLICATION INFORMATION
Setting the
Capacitors
Output
Voltage-Large
ESR
For applications that electrolytic capacitor or POS
capacitor with a large ESR is set as output
capacitors. The feedback resistors—R1 and R2
as shown in Figure 10—set the output voltage.
SW
L
VOUT
FB
ESR
R1
R1 
Figure10—Simplified POSCAP Circuit
First, choose a value for R2 that balances
between high quiescent current loss (low R2) and
high noise sensitivity on FB (high R2). A typical
value falls within 5kΩ to 50kΩ, using a
comparatively larger R2 when VOUT is low, and a
smaller R2 when VOUT is high. Then calculate R1
as follows, which considers the output ripple:
(15)
Where VOUT is the output ripple determined by
equation 24.
Setting the
Capacitors
Output
SW
FB
Voltage-Small
L
R4
ESR
VOUT
C4
R2
VFB( AVG)
VOUT  VFB( AVG)
POSCAP
R2
1
VOUT   VOUT  VREF
2
R1 
 R2
VREF
to the FB pin consisting of R4 and C4.The ramp
voltage, VRAMP, and the resistor divider influence
the output voltage as shown in Figure 11.
Calculate VRAMP as shown in equation 7. Select
R2 to balance between high quiescent current
loss and FB noise sensitivity. Choose R2 within
5kΩ to 50kΩ, using a larger R2 when VOUT is low,
and a smaller R2 when VOUT is high. Determine
the value of R1 as follows:
R1
R9
Ceramic
R2
(16)
R2

R4  R9
Where VFB(AVG) is the average FB voltage. VFB(AVG)
varies with the VIN, VOUT, and load condition,
where the load regulation is strictly related to the
VFB(AVG). Also the line regulation is related to the
VFB(AVG); improving the load or line regulation
involves a lower VRAMP that meets equation 9.
For PWM operation, estimate VFB(AVG) from
equation 17.
VFB( AVG)  VREF 
1
R1// R2
 VRAMP 
2
R1// R2  R9
(17)
Usually, R9 is 0Ω, though it can also be set
following equation 18 for better noise immunity. It
should also be less than 20% of R1//R2 to
minimize its influence on VRAMP.
1 R1 R2
(18)
R9  
5 R1  R2
Using equations 16 and 17 to calculate the
output voltage can be complicated. To simplify
the R1 calculation in equation 16, add a DCblocking capacitor, CDC, to filter the DC influence
from R4 and R9. Figure 12 shows a simplified
circuit with external ramp compensation and a
DC-blocking capacitor. The addition of this
capacitor, simplifies the R1 calculation as per
equation 19 for PWM mode operation.
Figure11—Simplified Ceramic Capacitor
Circuit
When using a low ESR ceramic capacitor on the
output, add an external voltage ramp
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R1 
1
 VRAMP
2
 R2
1
  VRAMP
2
VOUT  VREF 
VREF
(19)
For best results, select a CDC Value at least 10×
C4 for better DC blocking performance, but
smaller than 0.47µF account for start-up
performance. To use a larger CDC for better FB
noise immunity, reduce R1 and R2 to limit effects
on system start-up. Note that even with Cdc, the
load and line regulation are still related to VRAMP.
SW
FB
L
VOUT
R4
C4
Ceramic
R2
Figure12—Simplified Ceramic Capacitor
Circuit with DC Blocking Capacitor
Input Capacitor
The input current to the step-down converter is
discontinuous, and therefore, requires a
capacitor to supply the AC current to the stepdown converter while maintaining the DC input
voltage. Use ceramic capacitors for best
performance. During layout, Place the input
capacitors as close to the IN pin as possible.
The capacitance can vary significantly with
temperature. Use capacitors with X5R and X7R
ceramic dielectrics because they are fairly stable
over a wide temperature range.
The capacitors must also have a ripple current
rating that exceeds the converter’s maximum
input ripple current. Estimate the input ripple
current as follows:
ICIN  IOUT 
VOUT
V
 (1  OUT )
VIN
VIN
For simplification, choose an input capacitor with
an RMS current rating that exceeds half the
maximum load current.
The input capacitance value determines the
converter input voltage ripple. Select a capacitor
value that meets any input voltage ripple
requirements.
Estimate the input voltage ripple as follows:
IOUT
V
V
(22)
VIN 
 OUT  (1  OUT )
FSW  CIN
VIN
VIN
R1
C DC
The worst-case condition occurs at VIN = 2VOUT,
where:
I
ICIN  OUT
(21)
2
(20)
The worst-case condition occurs at VIN = 2VOUT,
where:
IOUT
1
(23)
VIN  
4 FSW  CIN
Output Capacitor
The output capacitor maintains the DC output
voltage. Use ceramic capacitors or POSCAPs.
Estimate the output voltage ripple as:
VOUT 
VOUT
V
1
 (1  OUT )  (RESR 
)
FSW  L
VIN
8  FSW  COUT
(24)
When using ceramic capacitors, the capacitance
dominates the impedance at the switching
frequency. The capacitance also dominates the
output voltage ripple. For simplification, estimate
the output voltage ripple as:
VOUT 
VOUT
8  FSW  L  COUT
2
 (1 
VOUT
)
VIN
(25)
The ESR only contributes minimally to the output
voltage ripple, thus requiring an external ramp to
stabilize the system. Design the external ramp
with R4 and C4 as per equation 5, 8 and 9.
MPQ8632 Rev.1.24
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26
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
The ESR dominates the switching-frequency
impedance for POSCAPs,. The ESR ramp
voltage is high enough to stabilize the system.
thus eliminating the need for an external ramp.
Select a minimum ESR value around 12mΩ to
ensure stable operation. For simplification, the
output ripple can be approximated as:
VOUT 
VOUT
V
 (1  OUT )  RESR
FSW  L
VIN
(26)
Inductor
The inductor supplies constant current to the
output load while being driven by the switching
input voltage. A larger value inductor results in
less ripple current and lower output ripple voltage,
but is larger physical size, has a higher series
resistance, and/or lower saturation current.
Generally, select an inductor value that allows
the inductor peak-to-peak ripple current to 30%
to 40% of the maximum switch current limit. Also,
design for a peak inductor current that is below
the maximum switch current limit. Calculate the
inductance value as:
L
VOUT
V
 (1  OUT )
FSW  IL
VIN
(27)
Where ΔIL is the peak-to-peak inductor ripple
current.
Choose an inductor that will not saturate under
the maximum inductor peak current. The peak
inductor current can be calculated as:
ILP  IOUT 
VOUT
V
 (1  OUT )
2  FSW  L
VIN
(28)
Table 2 lists a few highly-recommended highefficiency inductors.
Table 2—Inductor Selection Guide
Part Number
Manufacturer
Inductance
(µH)
DCR
(mΩ)
Current
Rating (A)
Dimensions
3
L x W x H (mm )
744325072
FDU1250C-1R0M
FDA1055-1R5M
744325180
FDA1055-2R2M
FDA1055-3R3M
HC7-3R9-R
Wurth
TOKO
TOKO
Wurth
TOKO
TOKO
Cooper
0.72
1
1.5
1.8
2.2
3.3
3.9
1.35
1.72
2.8
3.5
3.94
5.92
7.9
35
31.3
24
18
20.6
15.6
10.6
10.2 x 10.5 x 4.7
13.3 x 12.1 x 5
11.6 x 10.8 x 5.5
10.2 x 10.5 x 4.7
11.6 x 10.8 x 5.5
11.6 x 10.8 x 5.5
13.8 x 13 x 5.5
Typical Design Parameter Tables
The following tables include recommended
component values for typical output voltages (1V,
2.5V, 3.3V) and switching frequency (500kHz).
Refer to Tables 3-9 for design cases without
external ramp compensation. And Tables 10-16
are for design cases with external ramp
compensation. An external ramp is not needed
when using high-ESR output capacitors, such as
electrolytic or POSCAPs. Use an external ramp
when using low-ESR capacitors, such as ceramic
capacitors. For cases not listed in this datasheet,
an excel spreadsheet provided by local sales
representatives can assist with the calculations.
Switching
Frequency
(kHz)
500
500
500
500
500
500
500
Table 3—MPQ8632-4, FSW=500kHz, VIN=12V
VOUT
(V)
1
L
(μH)
1.8
R1
(kΩ)
13.3
R2
(kΩ)
20
R7
(kΩ)
357
2.5
3.3
3.3
3.9
63.4
91
20
20
887
1200
Table 4—MPQ8632-6, FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
1
2.2
3.3
R1
(kΩ)
13.3
63.4
91
R2
(kΩ)
20
20
20
MPQ8632 Rev.1.24
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R7
(kΩ)
357
887
1200
27
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Table 5—MPQ8632-8, FSW=500kHz, VIN=12V
Table 11—MPQ8632-6, FSW=500kHz, VIN=12V
VOUT
(V)
1
L
(μH)
0.72
R1
(kΩ)
13.3
R2
(kΩ)
20
R7
(kΩ)
357
VOUT
(V)
1
L
(μH)
1
R1
(kΩ)
13.7
R2
(kΩ)
20
R4
(kΩ)
750
C4
(pF)
220
R7
(kΩ)
357
2.5
3.3
1.8
2.2
63.4
91
20
20
887
1200
2.5
3.3
2.2
3.3
66.5
95.3
20
20
1000
1200
220
220
887
1200
Table 6—MPQ8632-10, MPQ8632H-10,
FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
1.5
1.8
R1
(kΩ)
13.3
63.4
91
R2
(kΩ)
20
20
20
R7
(kΩ)
357
887
1200
Table 7—MPQ8632-12, FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
1.5
1.8
R1
(kΩ)
13.3
63.4
91
R2
(kΩ)
20
20
20
R7
(kΩ)
357
887
1200
Table 8—MPQ8632GVE-15, FSW=500kHz,
VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
0.72
1
R1
(kΩ)
13.3
63.4
91
R2
(kΩ)
20
20
20
R7
(kΩ)
357
887
1200
Table 9— MPQ8632GVE-20, FSW=500kHz,
VIN=12V
VOUT
(V)
1
2.5
L
(μH)
0.72
0.72
R1
(kΩ)
13.3
63.4
R2
(kΩ)
20
20
R7
(kΩ)
357
887
3.3
0.72
91
20
1200
Table 10—MPQ8632-4, FSW=500kHz, VIN=12V
Table 12—MPQ8632-8, FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
1.8
2.2
R1
(kΩ)
13.7
66.5
95.3
R2
(kΩ)
20
20
20
R4
(kΩ)
750
1000
1200
C4
(pF)
220
220
220
R7
(kΩ)
357
887
1200
Table 13—MPQ8632-10, MPQ8632H-10,
FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
1.5
1.8
R1
(kΩ)
13.7
66.5
95.3
R2
(kΩ)
20
20
20
R4
(kΩ)
750
1000
1200
C4
(pF)
220
220
220
R7
(kΩ)
357
887
1200
Table 14—MPQ8632-12, FSW=500kHz, VIN=12V
VOUT
(V)
1
2.5
L
(μH)
0.72
1.5
R1
(kΩ)
13.7
66.5
R2
(kΩ)
20
20
R4
(kΩ)
750
1000
C4
(pF)
220
220
R7
(kΩ)
357
887
3.3
1.8
95.3
20
1200
220
1200
Table 15—MPQ8632GVE-15, FSW=500kHz,
VIN=12V
VOUT
(V)
1
2.5
3.3
L
(μH)
0.72
0.72
1
R1
(kΩ)
13.7
68
95.3
R2
(kΩ)
20
20
20
R4
(kΩ)
750
1000
1200
C4
(pF)
220
220
220
R7
(kΩ)
357
887
1200
Table 16—MPQ8632GVE-20, FSW=500kHz,
VIN=12V
VOUT
(V)
1
L
(μH)
1.8
R1
(kΩ)
13.7
R2
(kΩ)
20
R4
(kΩ)
750
C4
(pF)
220
R7
(kΩ)
357
VOUT
(V)
1
L
(μH)
0.72
R1
(kΩ)
13.7
R2
(kΩ)
20
R4
(kΩ)
750
C4
(pF)
220
R7
(kΩ)
357
2.5
3.3
3.3
3.9
66.5
95.3
20
20
1000
1200
220
220
887
1200
2.5
3.3
0.72
0.72
68
95.3
20
20
1000
1200
220
220
887
1200
MPQ8632 Rev.1.24
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28
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
TYPICAL APPLICATION (7)
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0
R7
C3
0.1uF L1
1uH, TOKO FDU1250C-1R0M
R5
0.1uF 0.1uF
357K
100K
SW
FREQ
VOUT
R1
+
13.7K
EN
R6
1uF
100K
C2B
0.1uF
MPQ8632
FB
VCC
C5
C2A
220uF/20mΩ
R2
SS
20K
C6
33nF
PG
PGND
AGND
Figure 13 — Typical Application Circuit with No External Ramp
MPQ8632-10, VIN=12V, VOUT=1V, IOUT=10A, FSW=500kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
357K
100K
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
13.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
20K
C6
33nF
PG
PGND
AGND
Figure 14 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1V, IOUT=10A, FSW=500kHz
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
357K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
VOUT
FREQ
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
CDC
10nF
R1
13.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
20K
AGND
Figure 15 — Typical Application Circuit with Low ESR Ceramic Capacitor
and DC-Blocking Capacitor.
MPQ8632-10, VIN=12V, VOUT=1V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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29
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 16 — Efficiency Curve
MPQ8632-10, VOUT=1V, IOUT=0.01A-10A, FSW=500kHz
R3
V IN
BST
IN
C1A
C1B
10uF
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
604K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
270K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
390pF
R9
100
R1
13.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
20K
AGND
Figure 17 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1V, IOUT=10A, FSW=300kHz
Figure 18 — Efficiency Curve
MPQ8632-10, VOUT=1V, IOUT=0.01A-10A, FSW=300kHz
MPQ8632 Rev.1.24
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30
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
220K
100K
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
301K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
28K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
40.2K
C6
33nF
PG
PGND
AGND
Figure 19 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1V, IOUT=10A, FSW=800kHz
Figure 20 — Efficiency Curve
MPQ8632-10, VOUT=1V, IOUT=0.01A-10A, FSW=800kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
475K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
12.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
40.2K
AGND
Figure 21 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=0.8V, IOUT=10A, FSW=300kHz
MPQ8632 Rev.1.24
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31
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 22 — Efficiency Curve
MPQ8632-10, VOUT=0.8V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
287K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
12.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
40.2K
AGND
Figure 23 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=0.8V, IOUT=10A, FSW=500kHz
Figure 24 — Efficiency Curve
MPQ8632-10, VOUT=0.8V, IOUT=0.01A-10A, FSW=500kHz
MPQ8632 Rev.1.24
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32
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
715K
100K
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
20.5K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
20K
C6
33nF
PG
PGND
AGND
Figure 25 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.2V, IOUT=10A, FSW=300kHz
Figure 26 — Efficiency Curve
MPQ8632-10, VOUT=1.2V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
432K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
220K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
10K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 27 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.2V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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33
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 28 — Efficiency Curve
MPQ8632-10, VOUT=1.2V, IOUT=0.01A-10A, FSW=500kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
270K
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
220K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
10K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 29 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.2V, IOUT=10A, FSW=800kHz
Figure 30 — Efficiency Curve
MPQ8632-10, VOUT=1.2V, IOUT=0.01A-10A, FSW=800kHz
MPQ8632 Rev.1.24
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34
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
887K
100K
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
470pF
R9
100
R1
15K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
10K
C6
33nF
PG
PGND
AGND
Figure 31 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.5 V, IOUT=10A, FSW=300kHz
Figure 32 — Efficiency Curve
MPQ8632-10, VOUT=1.5V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
536K
100K
0
C3
0.1uF
L1
1.2uH, TOKO FDA1254-1R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
15.4K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 33 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.5 V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 34 — Efficiency Curve
MPQ8632-10, VOUT=1.5V, IOUT=0.01A-10A, FSW=500kHz
R3
V IN
BST
IN
C1A
C1B
10uF
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
332K
100K
0
C3
0.1uF
L1
1.2uH, TOKO FDA1254-1R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
15.4K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 35 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.5 V, IOUT=10A, FSW=800kHz
Figure 36 — Efficiency Curve
MPQ8632-10, VOUT=1.5V, IOUT=0.01A-10A, FSW=800kHz
MPQ8632 Rev.1.24
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8/28/2013
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36
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
1.1M
100K
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
19.6K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
10K
C6
33nF
PG
PGND
AGND
Figure 37 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.8 V, IOUT=10A, FSW=300kHz
Figure 38 — Efficiency Curve
MPQ8632-10, VOUT=1.8V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
634K
100K
0
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
21K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 39 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.8 V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 40 — Efficiency Curve
MPQ8632-10, VOUT=1.8V, IOUT=0.01A-10A, FSW=500kHz
V IN
BST
IN
C1A C1B
RFREQ
C1C
C3
L1
SW
VOUT
FREQ
R5
R4
C4
R1
EN
MPQ8632
FB
VCC
C5
C2
R3
SS
R2
C6
PG
PGND
AGND
Figure 41 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=1.8 V, IOUT=10A, FSW=800kHz
Figure 42 — Efficiency Curve
MPQ8632-10, VOUT=1.8V, IOUT=0.01A-10A, FSW=800kHz
MPQ8632 Rev.1.24
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
2M
100K
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
48.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
10K
C6
33nF
PG
PGND
AGND
Figure 43 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=3.3 V, IOUT=10A, FSW=300kHz
Figure 44 — Efficiency Curve
MPQ8632-10, VOUT=3.3V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
1.2M
100K
0
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
48.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 45 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=3.3 V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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39
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 46 — Efficiency Curve
MPQ8632-10, VOUT=3.3V, IOUT=0.01A-10A, FSW=500kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
715K
100K
0
C3
0.1uF
L1
2.2uH, TOKO FDA1254-2R2M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
48.7K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 47 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=3.3 V, IOUT=10A, FSW=800kHz
Figure 48 — Efficiency Curve
MPQ8632-10, VOUT=3.3V, IOUT=0.01A-10A, FSW=800kHz
MPQ8632 Rev.1.24
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8/28/2013
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40
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
0
R5
2.7M
100K
C3
0.1uF
L1
3.3uH, TOKO FDA1254-3R3M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
82.5K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
10K
C6
33nF
PG
PGND
AGND
Figure 49 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=5 V, IOUT=10A, FSW=300kHz
Figure 50 — Efficiency Curve
MPQ8632-10, VOUT=5V, IOUT=0.01A-10A, FSW=300kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
1.8M
100K
0
C3
0.1uF
L1
3.3uH, TOKO FDA1254-3R3M
SW
FREQ
VOUT
R4
470K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
330pF
R9
100
R1
84.5K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 51 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=5 V, IOUT=10A, FSW=500kHz
MPQ8632 Rev.1.24
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8/28/2013
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41
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Figure 52 — Efficiency Curve
MPQ8632-10, VOUT=5V, IOUT=0.01A-10A, FSW=500kHz
R3
V IN
BST
IN
C1A
10uF
C1B
10uF
C1C
C1D
0.1uF 0.1uF
R7
R5
1.1M
100K
0
C3
0.1uF
L1
1uH, TOKO FDU1250C-1R0M
SW
FREQ
VOUT
R4
330K
EN
MPQ8632
FB
VCC
C5
R6
1uF
100K
C4
220pF
R9
100
R1
82K
C2A
C2B
C2C
47uF
47uF
47uF 0.1uF
C2D
C2E
0.1uF
R2
SS
C6
33nF
PG
PGND
10K
AGND
Figure 53 — Typical Application Circuit with Low ESR Ceramic Capacitor
MPQ8632-10, VIN=12V, VOUT=5 V, IOUT=10A, FSW=800kHz
Figure 54 — Efficiency Curve
MPQ8632-10, VOUT=5V, IOUT=0.01A-10A, FSW=800kHz
NOTE:
7) The all application circuits’ steady states are OK, but other performances are not tested.
MPQ8632 Rev.1.24
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42
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
LAYOUT RECOMMENDATION
GND
C1E
IN
PGND
PGND
PGND
VCC
SW
SW
SW
R3
C6
SW
SW
AGND
SW
PG
SW
R3
R4
SW
SS
IN
PGND
PGND
EN
R3
R1
PGND
FB
FREQ
R3
C4
SW
PGND
PGND
R3
R3
BST
PGND
R3
R2
C1A
R3
R5
C1B
R3
RFREQ
R3
RFREQ
C1C C1D C1E
PGND
C2
R3
GND
VOUT
VIN
Top Layer
GND
Inner1 Layer
BST
IN
C1A C1B
R3
C3
C1D
R3
C5
VIN
C1E
L1
1. Place high current paths (GND, IN, and SW)
very close to the device with short, direct and
wide traces.
2. Two-layer IN copper layers are required to
achieve better performance. Place at least
one 0.1uF-1uF 0603 or 0402 decoupling input
capacitor on each side of the IC. The input
capacitors should be placed as close to the
IN and GND pins as possible (maximum 2mm
edge-to-edge distance is allowed). Multiple
vias with 18mil diameter and 8mil hole-size
are required to be placed under the device
and near input capacitors. These vias can
help to reduce the parasitic inductance and
optimize the thermal dissipation.
3. Put a decoupling capacitor as close to the
VCC and AGND pins as possible.
4. Keep the switching node (SW) plane as small
as possible and far away from the feedback
network.
5. Place the external feedback resistors next to
the FB pin. Make sure that there are no vias
on the FB trace. The feedback resistors
should refer to AGND instead of PGND.
6. Keep the BST voltage path (BST, C3, and
SW) as short as possible.
7. Recommend strongly a four-layer layout to
improve thermal performance.
C3
L1
SW
VOUT
FREQ
R5
R4
C4
R1
MPQ8632
MPQ8632H
EN
VCC
C5
R3
C2
FB
SS
R2
C6
PG
AGND
PGND
EN
5
FREQ
6
SS
AGND
7
FB
VCC
8
PG
BST
Figure 55—Schematic for PCB Layout
Guideline
4
3
2
1
VIN
VIN
SW
CIN
GND
CIN
CIN
CIN
PGND
PGND
SW
PGND
PGND
To Inductor
Inner2 Layer
Figure 56—Recommend Input Capacitor
Placement for 16-Pin QFN 3mmx4mm
Package Part, including MPQ8632-4/6/8/10/12
and MPQ8632H-10.
MPQ8632 Rev.1.24
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43
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
Design Example
Below is a design example following the
application guidelines for the specifications:
Table 13—Design Example
VIN
4.5-18V
VOUT
1V
FSW
500kHz
C1C
GND
VIN
The detailed application schematic is shown in
Figure 14. The typical performance and circuit
waveforms have been shown in the Typical
Performance Characteristics section. For more
device applications, please refer to the related
Evaluation Board Datasheets.
Bottom Layer
Figure 57—PCB Layout Guideline For 29-Pin
QFN 5mmx4mm Package Part, Including
MPQ8632-15 and MPQ8632-20.
MPQ8632 Rev.1.24
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MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
PACKAGE PACKAGE
INFORMATION
OUTLINE DRAWING FOR 16L FCQFN (3X4MM)
MF-PO-D-0170
revision 0.0
QFN(3X4mm)
PIN 1 ID
0.125x45° TYP.
PIN 1 ID
MARKING
PIN 1 ID
INDEX AREA
BOTTOM VIEW
TOP VIEW
SIDE VIEW
NOTE:
0.125x45°
1) ALL DIMENSIONS ARE IN MILLIMETERS.
2) EXPOSED PADDLE SIZE DOES NOT INCLUDE
MOLD FLASH.
3) LEAD COPLANARITY SHALL BE 0.10
MILLIMETERS MAX.
4) JEDEC REFERENCE IS MO-220.
5) DRAWING IS NOT TO SCALE.
RECOMMENDED LAND PATTERN
MPQ8632 Rev.1.24
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45
MPQ8632 HIGH EFFICIENCY 18V SYNCHRONOUS STEP-DOWN CONVERTER FAMILY FOR 4A TO 20A
QFN(5X4mm)
PIN 1 ID
0.125x45° TYP.
PIN 1 ID
MARKING
PIN 1 ID
INDEX AREA
BOTTOM VIEW
TOP VIEW
SIDE VIEW
NOTE:
0.125x45°
1) ALL DIMENSIONS ARE IN MILLIMETERS.
2) EXPOSED PADDLE SIZE DOES NOT INCLUDE
MOLD FLASH.
3) LEAD COPLANARITY SHALL BE 0.10
MILLIMETERS MAX.
4) JEDEC REFERENCE IS MO-220.
5) DRAWING IS NOT TO SCALE.
RECOMMENDED LAND PATTERN
NOTICE: The information in this document is subject to change without notice. Users should warrant and guarantee that third
party Intellectual Property rights are not infringed upon when integrating MPS products into any application. MPS will not
assume any legal responsibility for any said applications.
MPQ8632 Rev.1.24
www.MonolithicPower.com
8/28/2013
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© 2013 MPS. All Rights Reserved.
46