NSC LM5110-2SD Dual 5a compound gate driver with negative output voltage capability Datasheet

LM5110
Dual 5A Compound Gate Driver with Negative Output
Voltage Capability
General Description
The LM5110 Dual Gate Driver replaces industry standard
gate drivers with improved peak output current and efficiency. Each “compound” output driver stage includes MOS
and bipolar transistors operating in parallel that together sink
more than 5A peak from capacitive loads. Combining the
unique characteristics of MOS and bipolar devices reduces
drive current variation with voltage and temperature. Separate input and output ground pins provide Negative Drive
Capability allowing the user to drive MOSFET gates with
positive and negative VGS voltages. The gate driver control
inputs are referenced to a dedicated input ground (IN_REF).
The gate driver outputs swing from VCC to the output ground
VEE which can be negative with respect to IN_REF. The
ability to hold MOSFET gates off with a negative VGS voltage reduces losses when driving low threshold voltage
MOSFETs often used as synchronous rectifiers. When driving with conventional positive only gate voltage, the IN_REF
and VEE pins are connected together and referenced to a
common ground. Under-voltage lockout protection and a
shutdown input pin are also provided. The drivers can be
operated in parallel with inputs and outputs connected to
double the drive current capability. This device is available in
the SOIC-8 and the thermally-enhanced LLP-10 packages.
n 5A sink/3A source current capability
n Two channels can be connected in parallel to double the
drive current
n Independent inputs (TTL compatible)
n Fast propagation times (25 ns typical)
n Fast rise and fall times (14 ns/12 ns rise/fall with 2 nF
load)
n Dedicated input ground pin (IN_REF) for split supply or
single supply operation
n Outputs swing from VCC to VEE which can be negative
relative to input ground
n Available in dual non-inverting, dual inverting and
combination configurations
n Shutdown input provides low power mode
n Supply rail under-voltage lockout protection
n Pin-out compatible with industry standard gate drivers
Typical Applications
n
n
n
n
Synchronous Rectifier Gate Drivers
Switch-mode Power Supply Gate Driver
Solenoid and Motor Drivers
Power Level Shifter
Package
Features
n SOIC-8
n LLP-10 (4 mm x 4 mm)
n Independently drives two N-Channel MOSFETs
n Compound CMOS and bipolar outputs reduce output
current variation
Ordering Information
Order Number
Package Type
NSC Package Drawing
Supplied As
LM5110-1/2/3 M
SOIC-8
M08A
Shipped in anti-static units
LM5110-1/2/3 MX
SOIC-8
M08A
2500 shipped in Tape & Reel
LM5110-1/2/3 SD
LLP-10
SDC10A
1000 shipped in Tape & Reel
LM5110-1/2/3 SDX
LLP-10
SDC10A
4500 shipped in Tape & Reel
© 2003 National Semiconductor Corporation
DS200792
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LM5110 Dual 5A Compound Gate Driver with Negative Output Voltage Capability
October 2003
LM5110
Pin Configurations
20079201
20079202
SOIC-8
LLP-10
NC - NOT CONNECTED
Block Diagram
20079203
Block Diagram of LM5110
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LM5110
Typical Application
20079204
Simplified Power Converter Using Synchronous Rectifiers
with Negative Off Gate Voltage
3
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LM5110
Pin Description
Pin
Description
Name
Description
Application Information
SOIC-8
LLP-10
1
1
IN_REF
Ground reference for control
inputs
Connect to VEE for standard positive only output
voltage swing. Connect to system logic ground
reference for positive and negative output voltage
swing.
2
2
IN_A
‘A’ side control input
TTL compatible thresholds.
3
3
VEE
Power ground of the driver
outputs
Connect to either power ground or a negative gate
drive supply.
4
4
IN_B
‘B’ side control input
TTL compatible thresholds.
5
7
OUT_B
Output for the ‘B’ side driver.
Capable of sourcing 3A and sinking 5A. Voltage
swing of this output is from VCC to VEE.
6
8
VCC
Positive supply
Locally decouple to VEE and IN_REF.
7
9
OUT_A.
Output for the ‘A’ side driver.
Capable of sourcing 3A and sinking 5A. Voltage
swing of this output is from VCC to VEE .
8
10
nSHDN
Shutdown input pin
Pull below 1.5V to activate low power shutdown
mode.
Note: Pins 5 and 6 are No Connect for LLP-10 package.
Configuration Table
Part Number
“A” Output Configuration
“B” Output Configuration
Package
LM5110-1M
Non-Inverting
Non-Inverting
SOIC- 8
LM5110-2M
Inverting
Inverting
SOIC- 8
LM5110-3M
Inverting
Non-Inverting
SOIC- 8
LM5110-1SD
Non-Inverting
Non-Inverting
LLP-10
LM5110-2SD
Inverting
Inverting
LLP-10
LM5110-3SD
Inverting
Non-Inverting
LLP-10
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4
(Note 1)
−0.3V to 5V
IN_REF to VEE
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Storage Temperature Range, (TSTG)
Maximum Junction Temperature,
(TJ(max))
+150˚C
VCC to VEE
−0.3V to 15V
Operating Junction Temperature
+125˚C
VCC to IN_REF
−0.3V to 15V
ESD Rating
IN to IN_REF, nSHDN to IN_REF
−0.3V to 15V
−55˚C to +150˚C
2kV
Electrical Characteristics
TJ = −40˚C to +125˚C, VCC = 12V, VEE = IN_REF = 0V, nSHDN = VCC, No Load on OUT_A or OUT_B, unless otherwise
specified.
Symbol
Parameter
Conditions
Min
3.5
VCC Operating Range
VCC−IN_REF and VCC−VEE
VCCR
VCC Under Voltage Lockout
(rising)
VCC−IN_REF
VCCH
VCC Under Voltage Lockout
Hysteresis
ICC
VCC Supply Current (ICC)
ICCSD
VCC Shutdown Current (ICC)
2.3
Typ
2.9
Max
Units
14
V
3.5
V
230
mV
IN_A = IN_B = 0V (5110-1)
1
2
IN_A = IN_B = VCC
(5110-2)
1
2
IN_A = VCC, IN_B = 0V
(5110-3)
1
2
nSHDN = 0V
18
25
µA
1.75
2.2
V
mA
CONTROL INPUTS
VIH
Logic High
VIL
Logic Low
HYS
Input Hysteresis
IIL
Input Current Low
IN_A=IN_B=VCC
(5110-1-2-3)
IIH
Input Current High
IN_A=IN_B=VCC (5110-1)
IN_A=IN_B=VCC (5110-2)
IN_A=VCC (5110-3)
-1
0.1
1
IN_B=VCC (5110-3)
10
18
25
−18
−25
1.5
2.2
0.8
−1
1.35
V
400
mV
0.1
1
10
18
25
−1
0.1
1
µA
SHUTDOWN INPUT
ISD
Pull-up Current
nSHDN = 0 V
VSDR
Shutdown Threshold
nSHDN rising
VSDH
Shutdown Hysteresis
0.8
165
µA
V
mV
OUTPUT DRIVERS
ROH
Output Resistance High
IOUT = −10 mA
30
50
Ω
ROL
Output Resistance Low
IOUT = + 10 mA
1.4
2.5
Ω
ISource
Peak Source Current
OUTA/OUTB = VCC/2,
200 ns Pulsed Current
3
A
ISink
Peak Sink Current
OUTA/OUTB = VCC/2,
200 ns Pulsed Current
5
A
5
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LM5110
Absolute Maximum Ratings
LM5110
Electrical Characteristics
(Continued)
TJ = −40˚C to +125˚C, VCC = 12V, VEE = IN_REF = 0V, nSHDN = VCC, No Load on OUT_A or OUT_B, unless otherwise
specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
SWITCHING CHARACTERISTICS
td1
Propagation Delay Time Low to
High, IN rising (IN to OUT)
CLOAD = 2 nF, see Figure
1
25
40
ns
td2
Propagation Delay Time High to CLOAD = 2 nF, see Figure
1
Low, IN falling (IN to OUT)
25
40
ns
tr
Rise Time
CLOAD = 2.0 nF, see Figure
1
14
25
ns
tf
Fall Time
CLOAD = 2 nF, see Figure
1
12
25
ns
TJ = 150˚C
500
LATCHUP PROTECTION
AEC - Q100, Method 004
mA
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.
Timing Waveforms
20079206
20079205
(b)
(a)
FIGURE 1. (a) Inverting, (b) Non-Inverting
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LM5110
Typical Performance Characteristics
Supply Current vs Frequency
Supply Current vs Capacitive Load
20079211
20079210
Rise and Fall Time vs Supply Voltage
Rise and Fall Time vs Temperature
20079212
20079213
Rise and Fall Time vs Capacitive Load
Delay Time vs Supply Voltage
20079214
20079215
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LM5110
Typical Performance Characteristics
(Continued)
Delay Time vs Temperature
RDSON vs Supply Voltage
20079217
20079216
UVLO Thresholds and Hysteresis vs Temperature
20079218
ground. The LM5110 pinout was designed for compatibility
with industry standard gate drivers in single supply gate
driver applications. Pin 1 (IN_REF) on the LM5110 is a
no-connect on standard driver IC’s. Connecting pin 1 to pin 3
(VEE) on the printed circuit board accommodates the pin-out
of both the LM5110 and competitive drivers.
The isolated input/output grounds provide the capability 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 LM5110 inputs. The VEE pin is connected to
a negative bias supply that can range from the IN-REF as
much as 14V below the VCC gate drive supply. The maximum recommended voltage difference between VCC and
IN_REF or between VCC and VEE is 14V. The minimum
voltage difference between VCC and IN_REF is 3.5V.
Enhancement mode MOSFETs do not inherently require a
negative bias on the gate to turn off the FET. However,
certain applications may benefit from the capability of negative VGS voltage during turn-off including:
1. when the gate voltages cannot be held safely below the
threshold voltage due to transients or coupling in the
printed circuit board.
Detailed Operating Description
LM5110 dual gate driver consists of two independent and
identical driver channels with TTL compatible logic inputs
and high current totem-pole outputs that source or sink
current to drive MOSFET gates. The driver output consist of
a compound structure with MOS and bipolar transistor operating in parallel to optimize current capability over a wide
output voltage and operating temperature range. The bipolar
device provides high peak current at the critical threshold
region of the MOSFET VGS while the MOS devices provide
rail-to-rail output swing. The totem pole output drives the
MOSFET gate between the gate drive supply voltage VCC
and the power ground potential at the VEE pin.
The control inputs of the drivers 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 circuit and separate input/output ground pins provide the option of single supply or split supply configurations.
When driving MOSFET gates from a single positive supply,
the IN_REF and VEE pins are both connected to the power
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8
high peak currents being drawn from VCC during turn-on
of the MOSFET.
(Continued)
2.
2.
when driving low threshold MOSFETs at high junction
temperatures
3.
when high switching speeds produce capacitive gatedrain current that lifts the internal gate potential of the
MOSFET
Proper grounding is crucial. The drivers need a very low
impedance path for current return to ground avoiding
inductive loops. The two paths for returning current to
ground are a) between LM5110 IN-REF pin and the
ground of the circuit that controls the driver inputs, b)
between LM5110 VEE pin and the source of the power
MOSFET being driven. All these paths should be as
short as possible to reduce inductance and be as wide
as possible to reduce resistance. All these ground paths
should be kept distinctly separate to avoid coupling between the high current output paths and the logic signals
that drive the LM5110. A good method is to dedicate one
copper plane in a multi-layered PCB to provide a common ground surface.
3. With the rise and fall times in the range of 10 ns to 30 ns,
care is required to minimize the lengths of current carrying conductors to reduce their inductance and EMI
from the high di/dt transients generated by the LM5110.
4. The LM5110 SOIC footprint is compatible with other
industry standard drivers. Simply connect IN_REF pin of
the LM5110 to VEE (pin 1 to pin 3) to operate the LM5110
in a standard single supply configuration.
5. If either channel is not being used, the respective input
pin (IN_A or IN_B) should be connected to either
IN_REF or VCC to avoid spurious output signals. If the
shutdown feature is not used, the nSHDN pin should be
connected to VCC to avoid erratic behavior that would
result if system noise were coupled into a floating
’nSHDN’ pin.
The two driver channels of the LM5110 are designed as
identical cells. Transistor matching inherent to integrated
circuit manufacturing ensures that the ac and dc performance of the channels are nearly identical. Closely matched
propagation delays allow the dual driver to be operated as a
single driver if inputs and output pins are connected. The
drive current capability in parallel operation is 2X the drive of
either channel. Small differences in switching speed between the driver channels will produce a transient current
(shoot-through) in the output stage when two output pins are
connected to drive a single load. The efficiency loss for
parallel operation has been characterized at various loads,
supply voltages and operating frequencies. The power dissipation in the LM5110 increases by less than 1% relative to
the dual driver configuration when operated as a single
driver with inputs and outputs connected.
An Under-voltage lockout (UVLO) circuit is included in the
LM5110, which senses the voltage difference between VCC
and the input ground pin, IN_REF. When the VCC to IN_REF
voltage difference falls below 2.7V both driver channels are
disabled. The driver will resume normal operation when the
VCC to IN_REF differential voltage exceeds approximately
2.9V. UVLO hysteresis prevents chattering during brown-out
conditions.
The Shutdown pin (nSHDN) is a TTL compatible logic input
provided to enable/disable both driver channels. When
nSHDN is in the logic low state, the LM5110 is switched to a
low power standby mode with total supply current less than
25 µA. This function can be effectively used for start-up,
thermal overload, or short circuit fault protection. It is recommended that this pin be connected to VCC when the shutdown function is not being used. The shutdown pin has an
internal 18µA current source pull-up to VCC.
The input pins of non-inverting drivers have an internal 18µA
current source pull-down to IN-REF. The input pins of inverting driver channels have neither pull-up nor pull-down current sources.
The LM5110 is available in dual non-inverting (-1), dual
inverting (-2) and the combination inverting plus noninverting (-3) configurations. All three configurations are offered in the SOIC-8 and LLP-10 plastic packages.
Thermal Performance
INTRODUCTION
The primary goal of thermal management is to maintain the
integrated circuit (IC) junction temperature (TJ) below a
specified maximum operating temperature to ensure reliability. It is essential to estimate the maximum TJ of IC components in worst case operating conditions. The junction temperature is estimated based on the power dissipated in 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 printed circuit board design and the operating environment.
DRIVE POWER REQUIREMENT CALCULATIONS IN
LM5110
The LM5110 dual low side MOSFET driver is capable of
sourcing/sinking 3A/5A peak currents for short intervals to
drive a MOSFET without exceeding package power dissipation limits. High peak currents are required to switch the
MOSFET gate very quickly for operation at high frequencies.
Layout Considerations
Attention must be given to board layout when using LM5110.
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
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LM5110
Detailed Operating Description
LM5110
Thermal Performance
(Continued)
20079207
FIGURE 2.
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.
The schematic above shows a conceptual diagram of the
LM5110 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 capacitance of the MOSFET. The gate resistance Rg is usually very
small and losses in it can be neglected. The equivalent gate
capacitance is a difficult parameter to measure since it is the
combination of CGS (gate to source capacitance) and CGD
(gate to drain capacitance). Both of these MOSFET capacitances are not constants and vary with the gate and drain
voltage. The better way of quantifying gate capacitance is
the total gate charge QG in coloumbs. QG combines the
charge required by CGS and CGD for a given gate drive
voltage VGATE.
Assuming negligible gate resistance, the total power dissipated in the MOSFET driver due to gate charge is approximated by
PDRIVER = VGATE x QG x FSW
Where
FSW = switching frequency of the MOSFET.
As an example, consider the MOSFET MTD6N15 whose
gate charge specified as 30 nC for VGATE = 12V.
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
PDRIVER = 12V x 30 nC x 300 kHz = 0.108W.
If both channels of the LM5110 are operating at equal frequency with equivalent loads, the total losses will be twice as
this value which is 0.216W.
In addition to the above gate charge power dissipation, transient power is dissipated in the driver during output
transitions. When either output of the LM5110 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 LM5110 provides accurate estimates
of the transient and quiescent power dissipation components. At 300 kHz switching frequency and 30 nC load used
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Therefore the total power dissipation
PD = 0.216 + 0.008 + 0.012 = 0.236W.
We know that the junction temperature is given by
TJ = PD x θJA + TA
Or the rise in temperature is given by
TRISE = TJ − TA = PD x θJA
For SOIC-8 package θJA is estimated as 170˚C/W for the
conditions of natural convection.
Therefore TRISE is equal to
TRISE = 0.236 x 170 = 40.1˚C
For LLP-10 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
ambient thermal resistance (θJA). θJA as low as 40˚C/W is
achievable with the LLP10 package. The resulting TRISE for
the dual driver example above is thereby reduced to just 9.5
degrees.
CONTINUOUS CURRENT RATING OF LM5110
The LM5110 can deliver pulsed source/sink currents of 3A
and 5A to capacitive loads. In applications requiring continuous load current (resistive or inductive loads), package
power dissipation, limits the LM5110 current capability far
below the 5A sink/3A source capability. Rated continuous
current can be estimated both when sourcing current to or
sinking current from the load. For example when sinking, the
maximum sink current can be calculated as
where RDS(on) is the on resistance of lower MOSFET in the
output stage of LM5110.
Consider TJ(max) of 125˚C and θJA of 170˚C/W for an SO-8
package under the condition of natural convection and no air
flow. If the ambient temperature (TA) is 60˚C, and the RD-
10
LM5110
Thermal Performance
(Continued)
S(on) of the LM5110 output at TJ(max) is 2.5Ω, this equation
yields ISINK(max) of 391mA which is much smaller than 5A
peak pulsed currents.
Similarly, the maximum continuous source current can be
calculated as
where VDIODE is the voltage drop across hybrid output stage
which varies over temperature and can be assumed to be
about 1.1V at TJ(max) of 125˚C. Assuming the same parameters as above, this equation yields ISOURCE(max) of 347mA.
11
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LM5110
Physical Dimensions
inches (millimeters)
unless otherwise noted
NOTES: UNLESS OTHERWISE SPECIFIED
1.
STANDARD LEAD FINISH TO BE 200 MICROINCHES/5.08 MICROMETERS MINIMUM LEAD/TIN(SOLDER) ON
COPPER.
2. DIMENSION DOES NOT INCLUDE MOLD FLASH.
3.
REFERENCE JEDEC REGISTRATION MS-012, VARIATION AA, DATED MAY 1990.
8-Lead SOIC Package
NS Package Number M08A
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12
inches (millimeters) unless otherwise noted (Continued)
NOTES: UNLESS OTHERWISE SPECIFIED
1.
FOR SOLDER THICKNESS AND COMPOSITION, SEE “SOLDER INFORMATION” IN THE PACKAGING SECTION OF
THE NATIONAL SEMICONDUCTOR WEB PAGE (www.national.com).
2. MAXIMUM ALLOWABLE METAL BURR ON LEAD TIPS AT THE PACKAGE EDGES IS 76 MICRONS.
3.
NO JEDEC REGISTRATION AS OF MAY 2003.
10-Lead LLP Package
NS Package Number SDC10A
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LM5110 Dual 5A Compound Gate Driver with Negative Output Voltage Capability
Physical Dimensions
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