SM74101SD/NOPB [TI]
用于双电源操作、具有输入接地的 3A/7A 单通道栅极驱动器 | NGG | 6 | -40 to 125;![SM74101SD/NOPB](http://pdffile.icpdf.com/pdf1/p00191/img/icpdf/SM7410_1079604_icpdf.jpg)
型号: | SM74101SD/NOPB |
厂家: | ![]() |
描述: | 用于双电源操作、具有输入接地的 3A/7A 单通道栅极驱动器 | NGG | 6 | -40 to 125 栅极驱动 CD 光电二极管 接口集成电路 驱动器 驱动程序和接口 |
文件: | 总14页 (文件大小:314K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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SM74101
SM74101 Tiny 7A MOSFET Gate Driver
Literature Number: SNOSBA2
July 18, 2011
SM74101
Tiny 7A MOSFET Gate Driver
General Description
Features
The SM74101 MOSFET gate driver provides high peak gate
drive current in the tiny LLP-6 package (SOT23 equivalent
footprint), with improved power dissipation required for high
frequency operation. The compound output driver stage in-
cludes MOS and bipolar transistors operating in parallel that
together sink more than 7A peak from capacitive loads. Com-
bining the unique characteristics of MOS and bipolar devices
reduces drive current variation with voltage and temperature.
Under-voltage lockout protection is provided to prevent dam-
age to the MOSFET due to insufficient gate turn-on voltage.
The SM74101 provides both inverting and non-inverting in-
puts to satisfy requirements for inverting and non-inverting
gate drive with a single device type.
Renewable Energy Grade
■
■
Compound CMOS and bipolar outputs reduce output
current variation
7A sink/3A source current
■
■
■
■
Fast propagation times (25 ns typical)
Fast rise and fall times (14 ns/12 ns rise/fall with 2 nF load)
Inverting and non-inverting inputs provide either
configuration with a single device
Supply rail under-voltage lockout protection
■
■
Dedicated input ground (IN_REF) for split supply or single
supply operation
Power Enhanced 6-pin LLP package (3.0mm x 3.0mm)
■
■
Output swings from VCC to VEE which can be negative
relative to input ground
Block Diagram
30159901
Block Diagram of SM74101
© 2011 National Semiconductor Corporation
301599
www.national.com
Pin Configurations
30159902
LLP-6
Ordering Information
Order Number
Package Type
NSC Package
Drawing
Package Marking
Supplied As
SM74101SD
SM74101SDE
SM741SDX
LLP-6
LLP-6
LLP-6
SDE06A
SDE06A
SDE06A
L264B
L264B
L264B
1000 shipped on Tape & Reel
250 units on Tape & Reel
4500 Units on Tape & Reel
Pin Descriptions
Pin
1
Name
Description
Non-inverting input pin
Application Information
IN
TTL compatible thresholds. Pull up to VCC when not used.
2
VEE
Power ground for driver outputs
Positive Supply voltage input
Gate drive output
Connect to either power ground or a negative gate drive supply
for positive or negative voltage swing.
3
4
5
VCC
Locally decouple to VEE. The decoupling capacitor should be
located close to the chip.
OUT
Capable of sourcing 3A and sinking 7A. Voltage swing of this
output is from VEE to VCC.
IN_REF
Ground reference for control inputs
Connect to power ground (VEE) for standard positive only output
voltage swing. Connect to system logic ground when VEE is
connected to a negative gate drive supply.
6
INB
Inverting input pin
TTL compatible thresholds. Connect to IN_REF when not used.
- - -
Exposed
Pad
Exposed Pad, underside of package
Internally bonded to the die substrate. Connect to VEE ground
pin for low thermal impedance.
www.national.com
2
IN/INB to IN_REF
IN_REF to VEE
−0.3V to 15V
−0.3V to 5V
−55°C to +150°C
+150°C
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Storage Temperature Range
Maximum Junction Temperature
Operating Junction Temperature
ESD Rating
−40°C+125°C
2kV
VCC to VEE
−0.3V to 15V
−0.3V to 15V
VCC to IN_REF
Electrical Characteristics TJ = −40°C to +125°C, VCC = 12V, INB = IN_REF = VEE = 0V, No Load on output,
unless otherwise specified.
Symbol
SUPPLY
VCC
Parameter
Conditions
Min
Typ
Max
Units
VCC Operating Range
VCC – IN_REF and VCC - VEE
3.5
2.4
14
V
V
UVLO
VCCH
VCC Under-voltage Lockout (rising) VCC – IN_REF
VCC Under-voltage Hysteresis
3.0
230
1.0
3.5
mV
mA
ICC
VCC Supply Current
2.0
CONTROL INPUTS
VIH
VIL
Logic High
2.3
V
V
Logic Low
0.8
2.3
2.0
VthH
VthL
HYS
IIL
High Threshold
Low Threshold
Input Hysteresis
Input Current Low
Input Current High
1.3
0.8
1.75
1.35
400
0.1
V
V
mV
µA
µA
IN = INB = 0V
IN = INB = VCC
-1
-1
1
1
IIH
0.1
OUTPUT DRIVER
ROH
Output Resistance High
IOUT = -10mA (Note 2)
30
1.4
3
50
Ω
Ω
A
A
ROL
Output Resistance Low
Peak Source Current
Peak Sink Current
IOUT = 10mA (Note 2)
2.5
ISOURCE
ISINK
OUT = VCC/2, 200ns pulsed current
OUT = VCC/2, 200ns pulsed current
7
SWITCHING CHARACTERISTICS
td1
Propagation Delay Time Low to
High,
IN/ INB rising ( IN to OUT)
CLOAD = 2 nF, see Figure 1
CLOAD = 2 nF, see Figure 1
25
25
40
40
ns
ns
td2
Propagation Delay Time High to
Low,
IN / INB falling (IN to OUT)
tr
tf
Rise time
Fall time
CLOAD = 2 nF , see Figure 1
CLOAD = 2 nF , see Figure 1
14
12
ns
ns
LATCHUP PROTECTION
AEC –Q100, METHOD 004
THERMAL RESISTANCE
TJ = 150°C
500
mA
Junction to Ambient,
0 LFPM Air Flow
Junction to Case
LLP-6 Package
LLP-6 Package
θJA
40
°C/W
°C/W
θJC
7.5
Note 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating Ratings are conditions under which operation of the
device is intended to be functional. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: The output resistance specification applies to the MOS device only. The total output current capability is the sum of the MOS and Bipolar devices.
3
www.national.com
Timing Waveforms
30159905
30159904
(b)
(a)
FIGURE 1. (a) Inverting, (b) Non-Inverting
www.national.com
4
Typical Performance Characteristics
Supply Current vs Frequency
Supply Current vs Capacitive Load
30159908
30159907
Rise and Fall Time vs Supply Voltage
Rise and Fall Time vs Temperature
30159909
30159910
Rise and Fall Time vs Capacitive Load
Delay Time vs Supply Voltage
30159911
30159912
5
www.national.com
Delay Time vs Temperature
RDSON vs Supply Voltage
30159913
30159914
UVLO Thresholds and Hysteresis vs Temperature
Peak Current vs Supply Voltage
30159916
30159915
www.national.com
6
Simplified Application Block Diagram
30159903
FIGURE 2. Simplified Application Block Diagram
circuit and separate input/output ground pins provide the op-
tion of single supply or split supply configurations. When
driving the MOSFET gates from a single positive supply, the
IN_REF and VEE pins are both connected to the power
ground.
Detailed Operating Description
The SM74101 is a high speed , high peak current (7A) single
channel MOSFET driver. The high peak output current of the
SM74101 will switch power MOSFET’s on and off with short
rise and fall times, thereby reducing switching losses consid-
erably. The SM74101 includes both inverting and non-invert-
ing inputs that give the user flexibility to drive the MOSFET
with either active low or active high logic signals. The driver
output stage consists of a compound structure with MOS and
bipolar transistor operating in parallel to optimize current ca-
pability over a wide output voltage and operating temperature
range. The bipolar device provides high peak current at the
critical Miller plateau region of the MOSFET VGS , while the
MOS device provides rail-to-rail output swing. The totem pole
output drives the MOSFET gate between the gate drive sup-
ply voltage VCC and the power ground potential at the VEE
pin.
The isolated input and output stage grounds provide the ca-
pability to drive the MOSFET to a negative VGS voltage for a
more robust and reliable off state. In split supply configuration,
the IN_REF pin is connected to the ground of the controller
which drives the SM74101 inputs. The VEE pin is connected
to a negative bias supply that can range from the IN_REF
potential to as low as 14 V below the Vcc gate drive supply.
For reliable operation, the maximum voltage difference be-
tween VCC and IN_REF or between VCC and VEE is 14V.
The minimum recommended operating voltage between Vcc
and IN_REF is 3.5V. An Under Voltage Lock Out (UVLO) cir-
cuit is included in the SM74101 which senses the voltage
difference between VCC and the input ground pin, IN_REF.
When the VCC to IN_REF voltage difference falls below 2.8V
the driver is disabled and the output pin is held in the low state.
The UVLO hysteresis prevents chattering during brown-out
conditions; the driver will resume normal operation when the
VCC to IN_REF differential voltage exceeds 3.0V.
The control inputs of the driver are high impedance CMOS
buffers with TTL compatible threshold voltages. The negative
supply of the input buffer is connected to the input ground pin
IN_REF. An internal level shifting circuit connects the logic
input buffers to the totem pole output drivers. The level shift
7
www.national.com
Layout Considerations
Attention must be given to board layout when using SM74101.
Some important considerations include:
1. A Low ESR/ESL capacitor must be connected close to
the IC and between the VCC and VEE pins to support high
peak currents being drawn from VCC during turn-on of the
MOSFET.
2. Proper grounding is crucial. The driver needs a very low
impedance path for current return to ground avoiding
inductive loops. Two paths for returning current to ground
are a) between SM74101 IN_REF pin and the ground of
the circuit that controls the driver inputs and b) between
SM74101 VEE pin and the source of the power MOSFET
being driven. Both paths should be as short as possible
to reduce inductance and be as wide as possible to
reduce resistance. These ground paths should be
distinctly separate to avoid coupling between the high
current output paths and the logic signals that drive the
SM74101. With rise and fall times in the range of 10 to
30nsec, care is required to minimize the lengths of
current carrying conductors to reduce their inductance
and EMI from the high di/dt transients generated when
driving large capacitive loads.
30159906
FIGURE 3.
The schematic above shows a conceptual diagram of the
SM74101 output and MOSFET load. Q1 and Q2 are the
switches within the gate driver. Rg is the gate resistance of
the external MOSFET, and Cin is the equivalent gate capac-
itance of the MOSFET. The equivalent gate capacitance is a
difficult parameter to measure as it is the combination of Cgs
(gate to source capacitance) and Cgd (gate to drain capaci-
tance). The Cgd is not a constant and varies with the drain
voltage. The better way of quantifying gate capacitance is the
gate charge Qg in coloumbs. Qg combines the charge re-
quired by Cgs and Cgd for a given gate drive voltage Vgate.
The gate resistance Rg is usually very small and losses in it
can be neglected. The total power dissipated in the MOSFET
driver due to gate charge is approximated by:
3. If either channel is not being used, the respective input
pin (IN or INB) should be connected to either VEE or
VCC to avoid spurious output signals.
Thermal Performance
INTRODUCTION
The primary goal of the thermal management is to maintain
the integrated circuit (IC) junction temperature (Tj) below a
specified limit to ensure reliable long term operation. The
maximum TJ of IC components should be estimated in worst
case operating conditions. The junction temperature can be
calculated based on the power dissipated on the IC and the
junction to ambient thermal resistance θJA for the IC package
in the application board and environment. The θJA is not a
given constant for the package and depends on the PCB de-
sign and the operating environment.
PDRIVER = VGATE x QG x FSW
Where
FSW = switching frequency of the MOSFET.
For example, consider the MOSFET MTD6N15 whose gate
charge specified as 30 nC for VGATE = 12V.
Therefore, the power dissipation in the driver due to charging
and discharging of MOSFET gate capacitances at switching
frequency of 300 kHz and VGATE of 12V is equal to
DRIVE POWER REQUIREMENT CALCULATIONS IN
SM74101
SM74101 is a single low side MOSFET driver capable of
sourcing / sinking 3A / 7A peak currents for short intervals to
drive a MOSFET without exceeding package power dissipa-
tion limits. High peak currents are required to switch the
MOSFET gate very quickly for operation at high frequencies.
PDRIVER = 12V x 30 nC x 300 kHz = 0.108W.
In addition to the above gate charge power dissipation, - tran-
sient power is dissipated in the driver during output transi-
tions. When either output of the SM74101 changes state,
current will flow from VCC to VEE for a very brief interval of time
through the output totem-pole N and P channel MOSFETs.
The final component of power dissipation in the driver is the
power associated with the quiescent bias current consumed
by the driver input stage and Under-voltage lockout sections.
Characterization of the SM74101 provides accurate esti-
mates of the transient and quiescent power dissipation com-
ponents. At 300 kHz switching frequency and 30 nC load used
in the example, the transient power will be 8 mW. The 1 mA
nominal quiescent current and 12V VGATE supply produce a
12 mW typical quiescent power.
Therefore the total power dissipation
PD = 0.118 + 0.008 + 0.012 = 0.138W.
We know that the junction temperature is given by
TJ = PD x θJA + TA
Or the rise in temperature is given by
www.national.com
8
copper pad, which can readily dissipate heat to the surround-
ings, θJA as low as 40°C / Watt is achievable with the package.
The resulting Trise for the driver example above is thereby
reduced to just 5.5 degrees.
TRISE = TJ − TA = PD x θJA
For LLP-6 package, the integrated circuit die is attached to
leadframe die pad which is soldered directly to the printed
circuit board. This substantially decreases the junction to am-
bient thermal resistance (θJA). By providing suitable means of
heat dispersion from the IC to the ambient through exposed
Therefore TRISE is equal to
TRISE = 0.138 x 40 = 5.5°C
9
www.national.com
Physical Dimensions inches (millimeters) unless otherwise noted
6-Lead LLP Package
NS Package Number SDE06A
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10
Notes
11
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