FAIRCHILD FDMF6707V

FDMF6707V — Extra-Small, High-Performance,
High-Frequency DrMOS Module
Benefits
Description

Ultra-Compact 6x6mm PQFN, 72% Space-Saving
Compared to Conventional Discrete Solutions



Fully Optimized System Efficiency
The XS™ DrMOS family is Fairchild’s next-generation,
fully optimized, ultra-compact, integrated MOSFET plus
driver power stage solution for high-current, highfrequency, synchronous buck DC-DC applications. The
FDMF6707V integrates a driver IC, two power MOSFETs,
and a bootstrap Schottky diode into a thermally
enhanced, ultra-compact 6x6mm PQFN package.
Clean Switching Waveforms with Minimal Ringing
High-Current Handling
Features
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


Over 93% Peak-Efficiency


Driver Output Disable Function (DISB# Pin)

Fairchild PowerTrench® Technology MOSFETs for
Clean Voltage Waveforms and Reduced Ringing

Fairchild SyncFET™ (Integrated Schottky Diode)
Technology in the Low-Side MOSFET

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Under-Voltage Lockout (UVLO)
Internal 12V to 5V Linear Regulator
High-Current Handling: 50A
High-Performance PQFN Copper-Clip Package
3-State 3.3V PWM Input Driver
Skip-Mode SMOD# (Low-Side Gate Turn Off) Input
Thermal Warning Flag for Over-Temperature
Condition
Internal Pull-Up and Pull-Down for SMOD# and
DISB# Inputs, Respectively
With an integrated approach, the complete switching
power stage is optimized for driver and MOSFET
dynamic performance, system inductance, and power
MOSFET RDS(ON). XS™ DrMOS uses Fairchild's highperformance PowerTrench® MOSFET technology,
which dramatically reduces switch ringing, eliminating
the snubber circuit in most buck converter applications.
A new driver IC, with reduced dead times and
propagation delays, further enhances performance. An
internal 12V to 5V linear regulator enables the
FDMF6707V to operate from a single 12V supply. A
thermal warning function warns of potential overtemperature situations. FDMF6707V also incorporates
features such as Skip Mode (SMOD) for improved lightload efficiency, along with a 3-state 3.3V PWM input for
compatibility with a wide range of PWM controllers.
Applications
High-Performance Gaming Motherboards
Integrated Bootstrap Schottky Diode


Adaptive Gate Drive Timing for Shoot-through
Protection

Desktop Computers, V-Core and Non-V-Core
DC-DC Converters


Workstations

Networking and Telecom Microprocessor Voltage
Regulators

Small Form-Factor Voltage Regulator Modules
Optimized for Switching Frequencies up to 1MHz
Low-Profile SMD Package
Fairchild Green Packaging and RoHS Compliant
Based on the Intel® 4.0 DrMOS Standard
Compact Blade Servers, V-Core and Non-V-Core
DC-DC Converters
High-Current DC-DC Point-of-Load (POL)
Converters
Ordering Information
Part Number
Current Rating
Package
Top Mark
FDMF6707V
50A
40-Lead, Clipbond PQFN DrMOS, 6.0mm x 6.0mm Package
FDMF6707V
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
June 2012
Figure 1.
Typical Application Circuit
DrMOS Block Diagram
VDRV
VCIN
BOOT
VIN
DBoot
VIN
UVLO
5V
LDO
VCC
UVLO
DISB #
GH
Logic
(Q1)
HS Power
MOSFET
GH
Level Shift
10µA
30k
VCI
PHASE
1 k
RUP_PWM
Dead Time
Control
Input
3 - State
Logic
PWM
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Typical Application Circuit
VSWH
RDN_PWM
VCIN
THWN#
(Q2)
LS Power
MOSFET
GL
GL
Logic
30k
VCIN
Temp.
Sense
10µA
CGND
SMOD #
Figure 2.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
PGND
DrMOS Block Diagram
www.fairchildsemi.com
2
Figure 3.
Bottom View
Figure 4.
Top View
Pin Definitions
Pin #
1
Name
Description
When SMOD#=HIGH, the low-side driver is the inverse of PWM input. When SMOD#=LOW, the
SMOD# low-side driver is disabled. This pin has a 10µA internal pull-up current source. Do not add a noise
filter capacitor.
2
VCIN
Linear regulator 5V output. Minimum 1µF ceramic capacitor recommended from this pin to CGND.
3
VDRV
Linear regulator input. Minimum 1µF ceramic capacitor is recommended connected as close as
possible from this pin to CGND.
4
BOOT
Bootstrap supply input. Provides voltage supply to the high-side MOSFET driver. Connect a
bootstrap capacitor from this pin to PHASE.
5, 37,
41
6
7
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Pin Configuration
CGND IC ground. Ground return for driver IC.
GH
For manufacturing test only. This pin must float: it must not be connected to any pin.
PHASE Switch node pin for bootstrap capacitor routing; electrically shorted to VSWH pin.
8
NC
No connect. The pin is not electrically connected internally, but can be connected to VIN for
convenience.
9 - 14,
42
VIN
Power input. Output stage supply voltage.
15, 29 35, 43
VSWH
16 – 28
PGND Power ground. Output stage ground. Source pin of the low-side MOSFET.
Switch node input. Provides return for high-side bootstrapped driver and acts as a sense point for
the adaptive shoot-through protection.
36
GL
For manufacturing test only. This pin must float. It must not be connected to any pin.
38
THWN#
Thermal warning flag, open collector output. When temperature exceeds the trip limit, the output
is pulled LOW. THWN# does not disable the module.
39
DISB#
Output disable. When LOW, this pin disables the power MOSFET switching (GH and GL are held
LOW). This pin has a 10µA internal pull-down current source. Do not add a noise filter capacitor.
40
PWM
PWM signal input. This pin accepts a 3-state 3.3V PWM signal from the controller.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
3
Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be
operable above the recommended operating conditions and stressing the parts to these levels is not recommended.
In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability.
The absolute maximum ratings are stress ratings only.
Symbol
Parameter
Min.
Max.
VCIN, DISB#, PWM, SMOD#, GL, THWN# to CGND Pins
-0.3
6.0
VIN to PGND, CGND Pins
-0.3
25.0
VDRV to PGND, CGND Pins
16.0
BOOT, GH to VSWH, PHASE Pins
-0.3
6.0
BOOT, PHASE, GH to CGND Pins
-0.3
25.0
VSWH to CGND/PGND (DC Only)
-0.3
25.0
VSWH to PGND (< 20ns)
-8.0
25.0
BOOT to VCIN
ITHWN#
IO(AV)(1)
θJPCB
Unit
V
22.0
THWN# Sink Current
-0.1
VIN=12V, VO=1.0V
45
fSW=1MHz
42
Junction-to-PCB Thermal Resistance
TA
Ambient Temperature Range
TJ
Maximum Junction Temperature
TSTG
Storage Temperature Range
ESD
Electrostatic Discharge Protection
7.0
fSW=350kHz
-40
-55
Human Body Model, JESD22-A114
2000
Charged Device Model, JESD22-C101
1000
mA
A
3.5
°C/W
+125
°C
+150
°C
+150
°C
V
Note:
1. IO(AV) is rated using Fairchild’s DrMOS evaluation board, TA = 25°C, natural convection cooling. This rating is limited
by the peak DrMOS temperature, TJ = 150°C, and varies depending on operating conditions and PCB layout. This
rating can be changed with different application settings.
Recommended Operating Conditions
The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended
operating conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not
recommend exceeding them or designing to Absolute Maximum Ratings.
Symbol
VDRV
VIN
Parameter
Gate Drive Circuit Supply Voltage
Output Stage Supply Voltage
Min.
Typ.
Max.
Unit
8
12
15
V
3
12
(2)
15
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Absolute Maximum Ratings
V
Note:
2. Operating at high VIN can create excessive AC overshoots on the VSWH-to-GND and BOOT-to-GND nodes
during MOSFET switching transients. For reliable DrMOS operation, VSWH-to-GND and BOOT-to-GND must
remain at or below the Absolute Maximum Ratings shown in the table above. Refer to the “Application
Information” and “PCB Layout Guidelines” sections of this datasheet for additional information.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
4
Typical values are VIN = 12V, VDRV = 12V, and TA = +25°C unless otherwise noted.
Symbol
Parameter
Condition
Min. Typ. Max. Unit
Basic Operation
IQ
Quiescent Current
IQ=IVDRV, PWM=LOW or HIGH or Float
2
36
5
mA
Internal 5V Linear regulator
IVDRV
Input Current
8V<VDRV<14V, fSW=1MHz
VCIN
Output Voltage
VDRV=8V, ILOAD=5mA
4.8
5.0
mA
5.2
250
V
PVDRV
Power Dissipation
VDRV=12V, fSW=1MHz
CVCIN
VCIN Bypass Capacitor
X7R or X5R Ceramic
Line Regulation
8V<VDRV<14V, ILOAD=5mA
20
mV
Load Regulation
VDRV=8V, 5mA<ILOAD<100mA
75
mV
1
mW
10
200
µF
Short-Circuit Current Limit
8V<VDRV<14V
UVLO
UVLO Threshold
VDRV Rising
UVLO_Hyst
UVLO Hysteresis
435
mV
RUP_PWM
Pull-Up Impedance
26
kΩ
RDN_PWM
Pull-Down Impedance
12
kΩ
VIH_PWM
PWM High Level Voltage
2.01
2.25
2.48
V
VTRI_HI
3-State Upper Threshold
1.96
2.20
2.44
V
VTRI_LO
3-State Lower Threshold
0.76
0.95
1.14
V
VIL_PWM
PWM Low Level Voltage
0.67
0.85
1.08
V
160
200
ns
1.6
1.9
V
0.8
V
6.8
7.3
mA
7.8
V
PWM Input
tD_HOLD-OFF 3-State Shutoff Time
VHiZ_PWM
3-State Open Voltage
1.4
DISB# Input
VIH_DISB
High-Level Input Voltage
VIL_DISB
Low-Level Input Voltage
IPLD
Pull-Down Current
tPD_DISBL
Propagation Delay
tPD_DISBH
Propagation Delay
2
V
10
µA
PWM=GND, Delay Between DISB# from
HIGH to LOW to GL from HIGH to LOW
25
ns
PWM=GND, Delay Between DISB# from
LOW to HIGH to GL from LOW to HIGH
25
ns
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Electrical Characteristics
SMOD# Input
VIH_SMOD
High-Level Input Voltage
VIL_SMOD
Low-Level Input Voltage
IPLU
2
V
0.8
Pull-Up Current
tPD_SLGLL
Propagation Delay
PWM=GND, Delay Between SMOD# from
HIGH to LOW to GL from HIGH to LOW
tPD_SHGLH
Propagation Delay
PWM=GND, Delay Between SMOD# from
LOW to HIGH to GL from LOW to HIGH
V
10
µA
10
ns
10
ns
Continued on the following page…
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
5
Typical values are VIN = 12V, VDRV = 12V, and TA = +25°C unless otherwise noted.
Symbol
Parameter
Condition
Min. Typ. Max. Unit
Thermal Warning Flag
TACT
TRST
RTHWN
Activation Temperature
Reset Temperature
Pull-Down Resistance
150
°C
135
°C
IPLD=5mA
30
Ω
SW=0V, Delay Between GH from HIGH to
LOW and GL from LOW to HIGH
250
ns
1
Ω
0.8
Ω
250ns Timeout Circuit
tD_TIMEOUT
Timeout Delay
High-Side Driver
RSOURCE_GH Output Impedance, Sourcing Source Current=100mA
RSINK_GH
Output Impedance, Sinking
Sink Current=100mA
tR_GH
Rise Time
GH=10% to 90%, CLOAD=1.1nF
6
ns
tF_GH
Fall Time
GH=90% to 10%, CLOAD=1.1nF
5
ns
tD_DEADON
LS to HS Deadband Time
GL going LOW to GH going HIGH,
1V GL to 10 % GH
10
ns
tPD_PLGHL
PWM LOW Propagation
Delay
PWM going LOW to GH going LOW,
VIL_PWM to 90% GH
16
tPD_PHGHH
PWM HIGH Propagation
Delay (SMOD# Held LOW)
PWM going HIGH to GH going HIGH,
VIH_PWM to 10% GH (SMOD#=LOW)
30
ns
tPD_TSGHH
Exiting 3-State Propagation
Delay
PWM (from 3-State) going HIGH to GH
going HIGH, VIH_PWM to 10% GH
30
ns
1
Ω
30
ns
Low-Side Driver
RSOURCE_GL Output Impedance, Sourcing Source Current=100mA
RSINK_GL
Output Impedance, Sinking
Sink Current=100mA
0.5
Ω
tR_GL
Rise Time
GL=10% to 90%, CLOAD=5.9nF
20
ns
tF_GL
Fall Time
GL=90% to 10%, CLOAD=5.9nF
13
ns
SW going LOW to GL going HIGH,
2.2V SW to 10% GL
12
ns
tD_DEADOFF HS to LS Deadband Time
tPD_PHGLL
PWM-HIGH Propagation
Delay
PWM going HIGH to GL going LOW,
VIH_PWM to 90% GL
9
tPD_TSGLH
Exiting 3-State Propagation
Delay
PWM (from 3-State) going LOW to GL
going HIGH, VIL_PWM to 10% GL
20
ns
VF
Forward-Voltage Drop
IF=10mA
0.35
V
VR
Breakdown Voltage
IR=1mA
25
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Electrical Characteristics
ns
Boot Diode
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
22
V
www.fairchildsemi.com
6
V IH_PWM
V IL_PWM
PWM
90%
GL
1.0V
10%
90%
GH
to
VSWH
10%
1.2V
t D_TIMEOUT
(250ns Timeout)
2.2V
VSWH
t PD
t PD
PHGLL
PLGHL
tD_DEADOFF
t D_DEADON
Figure 5.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
PWM Timing Diagram
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Timing Diagram
www.fairchildsemi.com
7
Test Conditions: VIN=12V, VOUT=1.0V, VCIN=5V, VDRV=5V, LOUT=320nH, TA=25°C, and natural convection cooling,
unless otherwise specified.
12
50
11
300kHz
45
10
500kHz
9
800kHz
8
1MHz
40
Module Power Loss (W)
Module Output current, IOUT (A)
55
fSW = 1MHz
35
30
fSW = 300kHz
25
20
15
VIN = 12V, VOUT = 1.0V
10
 JPCB = 3.5°C/W
5
7
6
5
4
3
2
1
0
0
0
25
50
75
100
125
150
0
5
10
PCB Temperature (°C)
Figure 6.
Safe Operating Area
Figure 7.
Normalized Module Power Loss
IOUT = 30A
Normalized Module Power Loss
20
25
30
35
40
45
Module Power Loss vs. Output Current
1.3
1.6
1.5
1.4
1.3
1.2
1.1
1
IOUT = 30A, fSW = 300kHz
1.2
1.1
1.0
0.9
0.9
200
300
400
500
600
700
800
900
4
1000
6
Figure 8.
Power Loss vs. Switching Frequency
Figure 9.
IOUT = 30A, fSW = 300kHz
12
14
16
Power Loss vs. Input Voltage
IOUT = 30A, fSW = 300kHz
Normalized Module Power Loss
2.0
1.05
1.00
0.95
1.8
1.6
1.4
1.2
1.0
0.8
0.6
9.00
10.00
11.00
12.00
13.00
14.00
0.6
1.0
Power Loss vs. Driver Supply Voltage
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
1.4
1.8
2.2
2.6
3.0
3.4
Output Voltage, VOUT (V)
Driver Supply Voltage, VDRV (V)
Figure 10.
10
2.2
1.10
0.90
8.00
8
Module Input Voltage, VIN (V)
Module Switching Frequency, fSW (kHz)
Normalized Module Power Loss
15
Module Output Current, IOUT (A)
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Typical Performance Characteristics
Figure 11.
Power Loss vs. Output Voltage
www.fairchildsemi.com
8
Test Conditions: VIN=12V, VOUT=1.0V, VCIN=5V, VDRV=5V, LOUT=320nH, TA=25°C, and natural convection cooling,
unless otherwise specified.
1.06
50
IOUT = 30A, fSW = 300kHz
Normalized Module Power Loss
1.05
IOUT==30A
0A
IOUT
45
1.04
40
1.03
35
1.02
30
1.01
25
1.00
20
0.99
15
0.98
10
0.97
5
225
275
325
375
200
425
300
Output Inductance, LOUT (nH)
Figure 12.
Power Loss vs. Output Inductance
Figure 13.
Normalized Driver Supply Current
IOUT = 0A, fSW = 300kHz
16
15
14
13
12
8
600
700
800
900
1000
Driver Supply Current vs. Frequency
9
10
11
12
13
1.08
1.06
1.04
1.02
300kHz
1.00
1MHz
0.98
0.96
0.94
0
14
5
10
Driver Supply Voltage, VDRV (V)
Figure 14.
Driver Supply Current vs. Driver
Supply Voltage
Figure 15.
25
30
35
40
45
Driver Supply Current vs. Output Current
PWM Threshold Voltage (V)
VCIN = 5V
VIH_PWM
2.0
VTRI_HI
VHiZ_PWM
1.5
VTRI_LO
1.0
VIL_PWM
0.5
0.0
4.80
20
3.0
TA = 25°C
2.5
15
Module Output Current, IOUT (A)
3.0
PWM Threshold Voltage (V)
500
1.10
17
Driver Supply Current, IVDRV (mA)
400
Module Switching Frequency, fSW (kHz)
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Typical Performance Characteristics (Continued)
2.5
VIH_PWM
2.0
VTRI_HI
1.5
VTRI_LO
1.0
VIL_PWM
0.5
0.0
4.90
5.00
5.10
5.20
-50
-25
Driver Supply Voltage, VCIN (V)
Figure 16. PWM Thresholds vs. Driver Supply Voltage
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
0
25
50
75
100
125
150
Driver IC Junction Temperature, TJ (oC)
Figure 17.
PWM Thresholds vs. Temperature
www.fairchildsemi.com
9
Test Conditions: VIN=12V, VOUT=1.0V, VCIN=5V, VDRV=5V, LOUT=320nH, TA=25°C, and natural convection cooling,
unless otherwise specified.
2.2
2.0
VCIN = 5V
SMOD Threshold Voltage (V)
SMOD Threshold Voltage (V)
TA = 25oC
2.0
VIH
1.8
1.6
VIL
1.4
1.2
4.80
4.90
5.00
5.10
1.9
1.8
VIH_SMOD
1.7
1.6
VIL_SMOD
1.5
1.4
1.3
5.20
-50
-25
Driver Supply Voltage (V)
Figure 18.
SMOD# Thresholds vs. Driver
Supply Voltage
Figure 19.
25
50
75
100
125
150
SMOD# Thresholds vs. Temperature
2.2
-9.0
TA = 25oC
VCIN = 5V
SMOD# Pull-up Current, IPLU (uA)
0
Driver IC Junction Temperature (oC)
DISB Threshold Voltage (V)
-9.5
-10.0
-10.5
-11.0
2.0
VIH
1.8
VIL
1.6
1.4
-11.5
1.2
-12.0
-50
-25
0
25
50
75
100
125
4.80
150
4.90
Driver IC Junction Temperature, TJ (oC)
Figure 20.
SMOD# Pull-Up Current vs. Temperature
Figure 21.
2.00
5.10
5.20
Disable Thresholds vs. Driver
Supply Voltage
12.0
DISB # Pull-Down Current , IPLD (µA)
VCIN = 5V
DISB Threshold Voltage (V)
5.00
Driver Supply Voltage (V)
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Typical Performance Characteristics (Continued)
1.90
1.80
VIH_DISB
1.70
1.60
VIL_DISB
1.50
1.40
VCI = 5V
11.5
11.0
10.5
10.0
9.5
9.0
8.5
8.0
-50
-25
0
25
50
75
100
125
150
Driver IC Junction Temperature, TJ (°C)
Figure 22.
-25
0
25
50
75
100
125
150
Driver IC Junction Temperature ( oC)
Disable Thresholds vs. Temperature
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
-50
Figure 23.
Disable Pull-Down Current
vs. Temperature
www.fairchildsemi.com
10
The FDMF6707V is a driver-plus-FET module optimized
for the synchronous buck converter topology. A single
PWM input signal is all that is required to properly drive
the high-side and the low-side MOSFETs. Each part is
capable of driving speeds up to 1MHz.
3-State PWM Input
The FDMF6707V incorporates a 3-state 3.3V PWM
input gate drive design. The 3-state gate drive has both
logic HIGH level and LOW level, along with a 3-state
shutdown window. When the PWM input signal enters
and remains within the 3-state window for a defined
hold-off time (tD_HOLD-OFF), both GL and GH are pulled
LOW. This feature enables the gate drive to shut down
both high-and low-side MOSFETs to support features
such as phase shedding, a common feature on multiphase voltage regulators.
VDRV and Disable (DISB#)
The VDRV pin is monitored by an under-voltage lockout
(UVLO) circuit. When VDRV rises above ~7.5V, the
driver is enabled. When VDRV falls below ~7.0V, the
driver is disabled (GH, GL = 0). The driver can also be
disabled by pulling the DISB# pin LOW (DISB# <
VIL_DISB), which holds both GL and GH LOW regardless
of the PWM input state. The driver can be enabled by
raising the DISB# pin voltage HIGH (DISB# > VIH_DISB).
Table 1.
Exiting 3-State Condition
When exiting a valid 3-state condition, the FDMF6707V
design follows the PWM input command. If the PWM
input goes from 3-state to LOW, the low-side MOSFET
is turned on. If the PWM input goes from 3-state to
HIGH, the high-side MOSFET is turned on, as illustrated
in Figure 25. The FDMF6707V design allows for short
propagation delays when exiting the 3-state window
(see Electrical Characteristics).
UVLO and Disable Logic
UVLO
DISB#
Driver State
0
X
Disabled (GH, GL=0)
1
0
Disabled (GH, GL=0)
1
1
Enabled (See Table 2)
1
Open
Disabled (GH, GL=0)
Low-Side Driver
The low-side driver (GL) is designed to drive a groundreferenced low RDS(ON) N-channel MOSFET. The bias
for GL is internally connected between VDRV and
CGND. When the driver is enabled, the driver's output is
180° out of phase with the PWM input. When the driver
is disabled (DISB#=0V), GL is held LOW.
Note:
3. DISB# internal pull-down current source is 10µA.
Thermal Warning Flag (THWN#)
The FDMF6707V provides a thermal warning flag
(THWN#) to advise of over-temperature conditions. The
thermal warning flag uses an open-drain output that
pulls to CGND when the activation temperature (150°C)
is reached. The THWN# output returns to highimpedance state once the temperature falls to the reset
temperature (135°C). For use, the THWN# output
requires a pull-up resistor, which can be connected to
VCIN. THWN# does NOT disable the DrMOS module.
HIGH
THWN#
Logic
State
High-Side Driver
The high-side driver is designed to drive a floating Nchannel MOSFET. The bias voltage for the high-side
driver is developed by a bootstrap supply circuit
consisting of the internal Schottky diode and external
bootstrap capacitor (CBOOT). During startup, VSWH is
held at PGND, allowing CBOOT to charge to VDRV
through the internal diode. When the PWM input goes
HIGH, GH begins to charge the gate of the high-side
MOSFET (Q1). During this transition, the charge is
removed from CBOOT and delivered to the gate of Q1.
As Q1 turns on, VSWH rises to VIN, forcing the BOOT
pin to VIN + VBOOT, which provides sufficient VGS
enhancement for Q1. To complete the switching cycle,
Q1 is turned off by pulling GH to VSWH. CBOOT is then
recharged to VDRV when VSWH falls to PGND. GH
output is in-phase with the PWM input. The high-side
gate is held LOW when the driver is disabled or the
PWM signal is held within the 3-state window for
longer than the 3-state hold-off time, tD_HOLD-OFF.
135°C Reset 150°C
Temperature Activation
Temperature
Normal
Operation
Thermal
Warning
LOW
TJ_driver IC
Figure 24.
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Functional Description
THWN Operation
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
11
To prevent overlap during the HIGH-to-LOW transition
(Q1 off to Q2 on), the adaptive circuitry monitors the
voltage at the VSWH pin. When the PWM signal goes
LOW, Q1 begins to turn off after a propagation delay
(tPD_PLGHL). Once the VSWH pin falls below ~2.2V, Q2
begins to turn on after adaptive delay tD_DEADOFF.
Additionally, VGS(Q1) is monitored. When VGS(Q1) is
discharged below ~1.2V, a secondary adaptive delay is
initiated that results in Q2 being driven on after
tD_TIMEOUT, regardless of VSWH state. This function is
implemented to ensure CBOOT is recharged each
switching cycle in the event that the VSWH voltage does
not fall below the 2.2V adaptive threshold. Secondary
delay tD_TIMEOUT is longer than tD_DEADOFF.
The driver IC design ensures minimum MOSFET dead
time while eliminating potential shoot-through (crossconduction) currents. It senses the state of the
MOSFETs and adjusts the gate drive adaptively to
prevent simultaneous conduction. Figure 25 provides
the relevant timing waveforms. To prevent overlap
during the LOW-to-HIGH switching transition (Q2 off to
Q1 on), the adaptive circuitry monitors the voltage at the
GL pin. When the PWM signal goes HIGH, Q2 begins to
turn off after a propagation delay (tPD_PHGLL). Once the
GL pin is discharged below ~1V, Q1 begins to turn on
after adaptive delay tD_DEADON.
V IH_PWM
V IH_PWM
V IH_PWM
V IH PWM
V TRI_HI
V TRI_HI
V TRI_LO
V IL_PWM
V IL_PWM
tR_GH
PWM
less than t D_HOLD ‐ OFF
GH
to
VSWH
tF_GH
90%
tD_HOLD ‐OFF
10%
V IN
CCM
DCM
DCM
V OUT
2.2V
VSWH
GL
90%
1.0V
tPD_PHGLL
tD_DEADON
90%
10%
10%
tPD_PLGHL tR_GL tF_GL
tD_DEADOFF
Enter 3‐State
tPD_TSGHH
tD_HOLD ‐OFF
Enter 3 ‐State
Exit 3‐State
tPD_TSGHH
Exit
3 State
less than t D_HOLD ‐ OFF
tD_HOLD‐OFF tPD_TSGLH
Enter 3 ‐State
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Adaptive Gate Drive Circuit
Exit
3‐State
Notes: tPD_xxx = propagation delay from external signal (PWM, SMOD#, etc.) to IC generated signal. Example (tPD_PHGLL – PWM going HIGH to LS VGS (GL) going LOW) tD_xxx = delay from IC generated signal to IC generated signal. Example (tD_DEADON – LS VGS (GL) LOW to HS VGS (GH) HIGH) PWM Exiting 3‐state tPD_TSGHH = PWM 3‐state to HIGH to HS VGS rise, VIH_PWM to 10% HS VGS tPD_PHGLL = PWM rise to LS VGS fall, VIH_PWM to 90% LS VGS tPD_PLGHL = PWM fall to HS VGS fall, VIL_PWM to 90% HS VGS tPD_TSGLH = PWM 3‐state to LOW to LS VGS rise, VIL_PWM to 10% LS VGS tPD_PHGHH = PWM rise to HS VGS rise, VIH_PWM to 10% HS VGS (SMOD# held LOW) SMOD# Dead Times tPD_SLGLL = SMOD# fall to LS VGS fall, VIL_SMOD to 90% LS VGS tD_DEADON = LS VGS fall to HS VGS rise, LS‐comp trip value (~1.0V GL) to 10% HS VGS tD_DEADOFF = VSWH fall to LS VGS rise, SW‐comp trip value (~2.2V VSWH) to 10% LS VGS tPD_SHGLH = SMOD# rise to LS VGS rise, VIH_SMOD to 10% LS VGS Figure 25.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
PWM and 3-StateTiming Diagram
www.fairchildsemi.com
12
The SMOD function allows for higher converter
efficiency under light-load conditions. During SMOD, the
low-side FET gate signal is disabled (held LOW),
preventing discharging of the output capacitors as the
filter inductor current attempts reverse current flow –
also known as “Diode Emulation” Mode.
Table 2.
When the SMOD# pin is pulled HIGH, the synchronous
buck converter works in Synchronous Mode. This mode
allows for gating on the low-side FET. When the
SMOD# pin is pulled LOW, the low-side FET is gated
off. If the SMOD# pin is connected to the PWM
controller, the controller can actively enable or disable
SMOD when the controller detects light-load condition
from output current sensing. This pin is active LOW.
See Figure 26 for timing delays.
SMOD# Logic
DISB#
PWM
SMOD#
GH
GL
0
X
X
0
0
1
3-State
X
0
0
1
0
0
0
0
1
1
0
1
0
1
0
1
0
1
1
1
1
1
0
Note:
4. The SMOD feature is intended to have low
propagation delay between the SMOD signal and
the low-side FET VGS response time to control
diode emulation on a cycle-by-cycle basis.
SMOD#
V IH_SMOD
V IL_SMOD
V IH_PWM
V IH_PWM
V IL_PWM
PWM
90%
GH
to
VSWH
10%
10%
DCM
V OUT
CCM
CCM
2.2V
VSWH
GL
90%
1.0V
tPD_PHGLL
tD_DEADON
10%
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Skip Mode (SMOD#)
10%
tPD_PLGHL
tPD_PHGHH
tPD_SLGLL
tD_DEADOFF
Delay from SMOD# going LOW to LS VGS LOW
tPD_SHGLH
Delay from SMOD# going HIGH to LS V GS HIGH
HS turn ‐on with SMOD# LOW
Figure 26.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
SMOD# Timing Diagram
www.fairchildsemi.com
13
boot resistor may be required when operating near the
maximum rated VIN and is effective at controlling the
high-side MOSFET turn-on slew rate and VSHW
overshoot. Typical RBOOT values from 0.5Ω to 2.0Ω are
effective in reducing VSWH overshoot.
5V Linear Regulator Capacitor Selection
For the linear regulator output (VCIN), a local ceramic
bypass capacitor is required for linear regulator stability.
This capacitor is also needed to reduce noise and is
used to supply the peak Power MOSFET low side gate
current and boot capacitor charging current. Use at least
a 1µF, X7R, or X5R capacitor. Keep this capacitor close
to the VCIN pin and connect it to ground plane with vias.
A bypass capacitor of 1µF, X7R or X5R, is also
recommended from VDRV to ground.
Power Loss and Efficiency
Measurement and Calculation
Refer to Figure 27 for power loss testing method. Power
loss calculations are:
PIN=(VIN x IIN) + (V5V x I5V) (W)
PSW=VSW x IOUT (W)
POUT=VOUT x IOUT (W)
PLOSS_MODULE=PIN - PSW (W)
PLOSS_BOARD=PIN - POUT (W)
EFFMODULE=100 x PSW/PIN (%)
EFFBOARD=100 x POUT/PIN (%)
Bootstrap Circuit
The bootstrap circuit uses a charge storage capacitor
(CBOOT), as shown in Figure 27. A bootstrap capacitance
of 100nF X7R or X5R capacitor is typically adequate. A
series bootstrap resistor may be needed for specific
applications to improve switching noise immunity. The
VDRV
A
IVDRV
A
CVCIN
CVDR
VDRV
DISB
VCI
VIN
IIN
CVIN
VI
DISB
RBOOT
PWM Input
BOOT
PWM
OF
FDMF6707V
CBOOT
VOUT
VSWH
O
Open Drain
Output
SMOD
A
L OUT
PHAS
IOUT
VOUT
THWN
CGN
Figure 27.
V
PGND
VSW
COUT
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Application Information
Power Loss Measurement Block Diagram
PCB Layout Guidelines
Figure 28 and Figure 29 provide the top and bottom
views of an example of a proper layout for the
FDMF6707V and critical components. All of the highcurrent paths, such as VIN, VSWH, VOUT, and GND
copper, should be short and wide for low inductance
and resistance. This technique achieves a more stable
and evenly distributed current flow, along with enhanced
heat radiation and system performance.
2. The VSWH copper trace serves two purposes. In
addition to being the high-frequency current path
from the DrMOS package to the output inductor, it
also serves as a heat sink for the low-side MOSFET
in the DrMOS package. The trace should be short
and wide enough to present a low-impedance path
for the high-frequency, high-current flow between the
DrMOS and inductor to minimize losses and
temperature rise. Note that the VSWH node is a
high-voltage and high-frequency switching node with
high noise potential. Care should be taken to
minimize coupling to adjacent traces. Since this
copper trace also acts as a heat sink for the lower
FET, balance using the largest area possible to
improve
DrMOS
cooling
while
maintaining
acceptable noise emission.
The following guidelines are recommendations for the
PCB designer:
1. Input ceramic bypass capacitors must be placed
close to the VIN and PGND pins. This helps reduce
the high-current power loop inductance and the input
current ripple induced by the power MOSFET
switching operation.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
14
11. The SMOD# and DISB# pins have weak internal
pull-up and pull-down current sources, respectively.
These pins should not have any noise filter
capacitors. Do not to float these pins unless
absolutely necessary.
4. PowerTrench® MOSFETs are used in the output
stage. The power MOSFETs are effective at
minimizing ringing due to fast switching. In most
cases, no VSWH snubber is required. If a snubber is
used, it should be placed close to the VSWH and
PGND pins. The resistor and capacitor need to be of
proper size for the power dissipation.
12. Use multiple vias on each copper area to
interconnect top, inner, and bottom layers to help
distribute current flow and heat conduction. Vias
should be relatively large and of reasonably low
inductance. Critical high-frequency components,
such as RBOOT, CBOOT, the RC snubber, and bypass
capacitors should be located as close to the
respective DrMOS module pins as possible on the
top layer of the PCB. If this is not feasible, they
should be connected from the backside through a
network of low-inductance vias.
5. VCIN, VDRV, and BOOT capacitors should be
placed as close as possible to the VCIN to CGND,
VDRV to CGND, and BOOT to PHASE pins to
ensure clean and stable power. Routing width and
length should be considered as well.
6. Include a trace from PHASE to VSWH to improve
noise margin. Keep the trace as short as possible.
7. The layout should include a placeholder to insert a
small-value series boot resistor (RBOOT) between the
boot capacitor (CBOOT) and DrMOS BOOT pin. The
BOOT-to-VSWH loop size, including RBOOT and
CBOOT, should be as small as possible. The boot
resistor may be required when operating near the
maximum rated VIN. The boot resistor is effective at
controlling the high-side MOSFET turn-on slew rate
and VSHW overshoot. RBOOT can improve noise
operating margin in synchronous buck designs that
may have noise issues due to ground bounce or high
positive and negative VSWH ringing. However,
inserting a boot resistance lowers the DrMOS
efficiency. Efficiency versus noise trade-offs must be
considered. RBOOT values from 0.5Ω to 2.0Ω are
typically effective in reducing VSWH overshoot.
Figure 28.
PCB Layout Example (Top View)
8. The VIN and PGND pins handle large current
transients with frequency components greater than
100MHz. If possible, these pins should be connected
directly to the VIN and board GND planes. The use
of thermal relief traces in series with these pins is
discouraged because this adds inductance to the
power path. Added inductance in series with the VIN
or PGND pin degrades system noise immunity by
increasing positive and negative VSWH ringing.
9. CGND pad and PGND pins should be connected to
the GND plane copper with multiple vias for stable
grounding. Poor grounding can create a noise
transient offset voltage level between CGND and
PGND. This could lead to faulty operation of the gate
driver and MOSFETs.
Figure 29.
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
3. An output inductor should be located close to the
FDMF6707V to minimize the power loss due to the
VSWH copper trace. Care should also be taken so
the inductor dissipation does not heat the DrMOS.
PCB Layout Example (Bottom View)
10. Ringing at the BOOT pin is most effectively
controlled by close placement of the boot capacitor.
Do not add an additional BOOT to the PGND
capacitor: this may lead to excess current flow
through the BOOT diode.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
15
B
0.10 C
PIN#1
INDICATOR
6.00
2X
5.80
A
4.50
30
21
31
6.00
20
0.40
2.50
0.65
0.25
1.60
0.10 C
11
40
2X
1
SEE 0.60
DETAIL 'A' 0.50 TYP
TOP VIEW
10
0.35
0.15
2.10
0.40 21
FRONT VIEW
4.40±0.10
(2.20)
0.10
C A B
0.05
C
0.30
30 0.20 (40X)
31
20
0.50
2.40±0.10
(0.70)
1.50±0.10
11
10
0.40
2.00±0.10
(0.20)
40
0.50 (40X)
0.30
2.00±0.10
0.50
NOTES: UNLESS OTHERWISE SPECIFIED
(0.20)
A) DOES NOT FULLY CONFORM TO JEDEC
REGISTRATION MO-220, DATED
MAY/2005.
B) ALL DIMENSIONS ARE IN MILLIMETERS.
C) DIMENSIONS DO NOT INCLUDE BURRS
OR MOLD FLASH. MOLD FLASH OR
BURRS DOES NOT EXCEED 0.10MM.
D) DIMENSIONING AND TOLERANCING PER
ASME Y14.5M-1994.
E) DRAWING FILE NAME: PQFN40AREV3
1.10
0.90
0.10 C
0.30
0.20
PIN #1 INDICATOR
0.20 MAY APPEAR AS
OPTIONAL
1
BOTTOM VIEW
0.08 C
2.10
LAND PATTERN
RECOMMENDATION
0.05
0.00
DETAIL 'A'
C
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
Physical Dimensions
SEATING
PLANE
SCALE: 2:1
Figure 30.
40-Lead, Clipbond PQFN DrMOS, 6.0x6.0mm Package
Package drawings are provided as a service to customers considering Fairchild components. Drawings may change in any manner
without notice. Please note the revision and/or date on the drawing and contact a Fairchild Semiconductor representative to verify or
obtain the most recent revision. Package specifications do not expand the terms of Fairchild’s worldwide terms and conditions, specifically the
warranty therein, which covers Fairchild products.
Always visit Fairchild Semiconductor’s online packaging area for the most recent package drawings:
http://www.fairchildsemi.com/packaging/.
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
16
FDMF6707V — Extra-Small High-Performance, High-Frequency DrMOS Module
© 2011 Fairchild Semiconductor Corporation
FDMF6707V • Rev. 1.0.3
www.fairchildsemi.com
17