LM27222 [NSC]
High-Speed 4.5A Synchronous MOSFET Driver; 高速4.5A同步MOSFET驱动器型号: | LM27222 |
厂家: | National Semiconductor |
描述: | High-Speed 4.5A Synchronous MOSFET Driver |
文件: | 总11页 (文件大小:602K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
March 2006
LM27222
High-Speed 4.5A Synchronous MOSFET Driver
General Description
Features
n Adaptive shoot-through protection
n 10ns dead time
The LM27222 is a dual N-channel MOSFET driver designed
to drive MOSFETs in push-pull configurations as typically
used in synchronous buck regulators. The LM27222 takes
the PWM output from a controller and provides the proper
timing and drive levels to the power stage MOSFETs. Adap-
tive shoot-through protection prevents damaging and effi-
ciency reducing shoot-through currents, thus ensuring a ro-
bust design capable of being used with nearly any MOSFET.
The adaptive shoot-through protection circuitry also reduces
the dead time down to as low as 10ns, ensuring the highest
operating efficiency. The peak sourcing and sinking current
for each driver of the LM27222 is about 3A and 4.5Amps
respectively with a Vgs of 5V. System performance is also
enhanced by keeping propagation delays down to 8ns. Effi-
ciency is once again improved at all load currents by sup-
porting synchronous, non-synchronous, and diode emulation
modes through the LEN pin. The minimum output pulse
width realized at the output of the MOSFETs is as low as
30ns. This enables high operating frequencies at very high
conversion ratios in buck regulator designs. To support low
power states in notebook systems, the LM27222 draws only
5µA from the 5V rail when the IN and LEN inputs are low or
floating.
n 8ns propagation delay
n 30ns minimum on-time
n 0.4Ω pull-down and 0.9Ω pull-up drivers
n 4.5A peak driving current
n MOSFET tolerant design
n 5µA quiescent current
n 30V maximum input voltage in buck configuration
n 4V to 6.85V operating voltage
n SO-8 and LLP packages
Applications
n High Current Buck And Boost Voltage Converters
n Fast Transient DC/DC Power Supplies
n Single Ended Forward Output Rectification
n CPU And GPU Core Voltage Regulators
Typical Application
20117902
FIGURE 1.
© 2006 National Semiconductor Corporation
DS201179
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Connection Diagram
20117901
Top View
SO-8 (NS Package # M08A) θJA = 172˚C/W
or
LLP-8 (NS Package # SDC08A) θJA = 39˚C/W
Ordering Information
Order Number
LM27222M
Size
NSC Drawing #
Package Type
Rail
Supplied As
95 Units/Rail
SO-8
M08A
LM27222MX
LM27222SD
LM27222SDX
Tape and Reel
Tape and Reel
Tape and Reel
2500 Units/Reel
1000 Units/Reel
4500 Units/Reel
LLP-8
SDC08A
Pin Descriptions
Pin #
Pin Name
SW
Pin Function
1
2
High-side driver return. Should be connected to the common node of high and low-side MOSFETs.
High-side gate drive output. Should be connected to the high-side MOSFET gate. Pulled down
internally to SW with a 10K resistor to prevent spurious turn on of the high-side MOSFET when the
driver is off.
HG
3
4
CB
IN
Bootstrap. Accepts a bootstrap voltage for powering the high-side driver.
Accepts a PWM signal from a controller. Active High. Pulled down internally to GND with a 150K
resistor to prevent spurious turn on of the high-side MOSFET when the controller is inactive.
Low-side gate enable. Active High. Pulled down internally to GND with a 150K resistor to prevent
spurious turn-on of the low-side MOSFET when the controller is inactive.
Connect to +5V supply.
5
LEN
6
7
VCC
LG
Low-side gate drive output. Should be connected to low-side MOSFET gate. Pulled down internally to
GND with a 10K resistor to prevent spurious turn on of the low-side MOSFET when the driver is off.
Ground.
8
GND
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2
Block Diagram
20117903
3
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Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Power Dissipation (Note 3)
Storage Temperature
ESD Susceptibility
720mW
−65˚ to 150˚C
Human Body Model
2kV
VCC to GND
-0.3V to 7V
-0.3V to 36V
CB to GND
Operating Ratings (Note 1)
VCC
CB to SW
-0.3V to 7V
4V to 6.85V
−40˚ to 125˚C
33V
SW to GND (Note 2)
LEN, IN, LG to GND
HG to GND
-2V to 36V
Junction Temperature Range
CB (max)
-0.3V to VCC + 0.3V ≤ 7V
-0.3V to 36V
Junction Temperature
+150˚C
Electrical Characteristics (Note 4)
VCC = CB = 5V, SW = GND = 0V, unless otherwise specified. Typicals and limits appearing in plain type apply for TA = TJ =
+25˚C. Limits appearing in boldface type apply over the entire operating temperature range (-40˚C ≤ TJ ≤ 125˚C).
Symbol
Parameter
Conditions
Min
Typ
5
Max
Units
µA
POWER SUPPLY
Iq_op
Operating Quiescent Current IN = 0V, LEN = 0V
IN = 0V, LEN = 5V
15
30
500
540
650
825
µA
HIGH-SIDE DRIVER
Peak Pull-up Current
3
0.9
4.5
0.4
17
A
Ω
RH-pu
Pull-up Rds_on
Peak Pull-down Current
Pull-down Rds_on
Rise Time
ICB = IHG = 0.3A
2.5
1.5
A
RH-pd
ISW = IHG = 0.3A
Ω
t4
t6
Timing Diagram, CLOAD = 3.3nF
Timing Diagram, CLOAD = 3.3nF
Timing Diagram
ns
ns
ns
ns
ns
Fall Time
12
t3
Pull-up Dead Time
Pull-down Delay
Minimum Positive Output
Pulse Width
9.5
16.5
30
t5
Timing Diagram
ton_min
LOW-SIDE DRIVER
Peak Pull-up Current
3.2
0.9
4.5
0.4
17
A
Ω
RL-pu
Pull-up Rds_on
Peak Pull-down Current
Pull-down Rds_on
Rise Time
IVCC = ILG = 0.3A
2.5
1.5
A
RL-pd
t8
IGND = ILG = 0.3A
Ω
Timing Diagram, CLOAD = 3.3nF
Timing Diagram, CLOAD = 3.3nF
Timing Diagram
ns
ns
ns
ns
t2
Fall Time
14
t7
Pull-up Dead Time
Pull-down Delay
11.5
7.7
t1
Timing Diagram
PULL-DOWN RESISTANCES
HG-SW Pull-down Resistance
10k
10k
Ω
Ω
LG-GND Pull-down
Resistance
LEN-GND Pull-down
Resistance
150K
150K
Ω
Ω
IN-GND Pull-down Resistance
LEAKAGE CURRENTS
Ileak_IN
IN pin Leakage Current
IN = 0V, Source Current
IN = 5V, Sink Current
50
33
nA
µA
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4
Electrical Characteristics (Note 4) (Continued)
VCC = CB = 5V, SW = GND = 0V, unless otherwise specified. Typicals and limits appearing in plain type apply for TA = TJ =
+25˚C. Limits appearing in boldface type apply over the entire operating temperature range (-40˚C ≤ TJ ≤ 125˚C).
Symbol
Parameter
Conditions
LEN = 0V, Source Current
LEN = 5V, Sink Current
Min
Typ
200
33
Max
Units
nA
Ileak_LEN
LEN pin Leakage Current
µA
LOGIC
VIH_LEN
VIL_LEN
VIH_IN
LEN Low to High Threshold
LEN High to Low Threshold
IN Low to High Threshold
IN High to Low Threshold
Threshold Hysteresis
Low to High Transition
High to Low Transition
Low to High Transition
High to Low Transition
65
65
% of VCC
% of VCC
% of VCC
% of VCC
V
30
30
VIL_IN
0.7
Note 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating ratings are conditions under which the device operates
correctly. Operating Ratings do not imply guaranteed performance limits.
Note 2: The SW pin can have -2V to -0.5 volts applied for a maximum duty cycle of 10% with a maximum period of 1 second. There is no duty cycle or maximum
period limitation for a SW pin voltage range of -0.5V to 30 Volts.
Note 3: Maximum allowable power dissipation is a function of the maximum junction temperature, T
, the junction-to-ambient thermal resistance, θ , and the
JA
JMAX
ambient temperature, T . The maximum allowable power dissipation at any ambient temperature is calculated using: P
= (T -T ) / θ . The junction-to-
JMAX A JA
A
MAX
ambient thermal resistance, θ , for the LM27222M, it is 165˚C/W. For a T
of 150˚C and T of 25˚C, the maximum allowable power dissipation is 0.76W. The
JA
JMAX
A
θ
for the LM27222SD is 42˚C/W. For a T
of 150˚C and TA of 25˚C, the maximum allowable power dissipation is 3W.
JA
JMAX
Note 4: Min and Max limits are 100% production tested at 25˚C. Limits over the operating temperature range are guaranteed through correlation using Statistical
Quality Control (SQC) methods. Limits are used to calculate National’s Average Outgoing Quality Level (AOQL).
Timing Diagram
20117904
5
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Typical Waveforms
20117908
20117907
FIGURE 3. PWM High-to-Low Transition at IN Input
FIGURE 2. PWM Low-to-High Transition at IN Input
20117909
FIGURE 4. LEN Operation
The typical waveforms are from a circuit similar to Figure 1 with:
Q1: 2 x Si7390DP
Q2: 2 x Si7356DP
L1: 0.4 µH
VIN: 12V
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6
Application Information
GENERAL
The LM27222 is designed for high speed and high operating
reliability. The driver can handle very narrow, down to zero,
PWM pulses in a guaranteed, deterministic way. Therefore,
the HG and LG outputs are always in predictable states. No
latches are used in the HG and LG control logic so the
drivers cannot get "stuck" in the wrong state. The driver
design allows for powering up with a pre-biasing voltage
being present at the regulator output. To reduce conduction
losses in DC-DC converters with low duty factors the
LM27222 driver can be powered from a 6.5V 5% power
rail.
It is recommended to use the same power rail for both the
controller and driver. If two different power rails are used,
never allow the PWM pulse magnitude at the IN input or the
control voltage at the LEN input to be above the driver VCC
voltage or unpredictable HG and LG outputs pulse widths
may result.
20117906
MINIMUM PULSE WIDTH
As the input pulse width to the IN pin is decreased, the pulse
width of the high-side gate drive (HG-SW) also decreases.
However, for input pulse widths 60ns and smaller, the
HG-SW remains constant at 30ns. Thus the minimum pulse
width of the driver output is 30ns. Figure 5 shows an input
pulse at the IN pin 20ns wide, and the output of the driver, as
measured between the nodes HG and SW is a 30ns wide
pulse. Figure 6 shows the variation of the SW node pulse
width vs IN pulse width. At the IN pin, if a falling edge is
followed by a rising edge within 5ns, the HG may ignore the
rising edge and remain low until the IN pin toggles again. If a
rising edge is followed by a falling edge within 5ns, the pulse
may be completely ignored.
FIGURE 6.
ADAPTIVE SHOOT-THROUGH PROTECTION
The LM27222 prevents shoot-through power loss by ensur-
ing that both the high- and low-side MOSFETs are not con-
ducting at the same time. When the IN signal rises, LG is first
pulled down. The adaptive shoot-through protection circuit
waits for LG to reach 0.9V before turning on HG. Similarly,
when IN goes low, HG is pulled down first, and the circuit
turns LG on only after the voltage difference between the
high-side gate and the switch node, i.e. HG-SW, has fallen to
0.9V.
It is possible in some applications that at power-up the
driver’s SW pin is above 3V in either buck or boost com-
verter applications. For instance, in a buck configuration a
pre-biasing voltage can be either a voltage from anothert
power rail connected to the load, or a leakage voltage
through the load, or it can be an output capacitor pre-
charged above 3V while no significant load is present. In a
boost application it can be an input voltage rail above 3V.
In the case of insufficient initial CB-SW voltage (less than
2V) such as when the output rail is pre-biased, the shoot-
through protection circuit holds LG low for about 170ns,
beginning from the instant when IN goes high. After the
170ns delay, the status of LG is dictated by LEN and IN.
Once LG goes high and SW goes low, the bootstrap capaci-
tor will be charged up (assuming SW is grounded for long
enough time). As a result, CB-SW will be close to 5V and the
LM27222 will now fully support synchronous operation.
20117905
The dead-time between the high- and low-side pulses is kept
as small as possible to minimize conduction through the
body diode of the low-side MOSFET(s).
FIGURE 5. Min On Time
7
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4. The high-current loop between the high-side and low-
side MOSFETs and the input capacitors should be as
small as possible.
Application Information (Continued)
POWER DISSIPATION
The power dissipated in the driver IC when switching syn-
chronously can be calculated as follows:
5. There should be enough copper area near the MOS-
FETs and the inductor for heat dissipation. Vias may
also be added to carry the heat to other layers.
TYPICAL APPLICATION CIRCUIT DESCRIPITON
The Application Example on the following page shows the
LM27222 being used with National’s LM27212, a 2-phase
hysteretic current mode controller. Although this circuit is
capable of operating from 5V to 28V, the components are
optimized for an input voltage range of 9V to 28V. The
high-side FET is selected for low gate charge to reduce
switching losses. For low duty cycles, the average current
through the high-side FET is relatively small and thus we
trade off higher conduction losses for lower switching losses.
The low-side FET is selected solely on RDS_ON to minimize
conduction losses. If the input voltage range were 4V to 6V,
the MOSFET selection should be changed. First, much lower
voltage FETs can be used, and secondly, high-side FET
RDS_ON becomes a larger loss factor than the switching
losses. Of course with a lower input voltage, the input ca-
pacitor voltage rating can be reduced and the inductor value
can be reduced as well. For a 4V to 6V application, the
inductor can be reduced to 200nH to 300nH. The switching
frequency of the LM27212 is determined by the allowed
ripple current in the inductor. This circuit is set for approxi-
mately 300kHz. At lower input voltages, higher frequencies
are possible without suffering a significant efficiency loss.
Although the LM27222 can support operating frequencies up
to 2MHz in many applications, the LM27212 should be lim-
ited to about 1MHz. The control architecture of the LM27212
and the low propagation times of the LM27222 potentially
gives this solution the fastest transient response in the
industry.
where fSW = switching frequency
VCC = voltage at the VCC pin,
QG_H = total gate charge of the (parallel combination of the)
high-side MOSFET(s)
QG_L = total gate charge of the (parallel combination of the)
low-side MOSFET(s)
RG_H = gate resistance of the (parallel combination of the)
high-side MOSFET(s)
RG_L = gate resistance of the (parallel combination of the)
low-side MOSFET(S)
RH_pu = pull-up RDS_ON of the high-side driver
RH_pd = pull-down RDS_ON of the high-side driver
RL_pu = pull-up RDS_ON of the low-side driver
RL_pd = pull-down RDS_ON of the low-side driver
PC BOARD LAYOUT GUIDELINES
1. Place the driver as close to the MOSFETs as possible.
2. HG, SW, LG, GND: Run short, thick traces between the
driver and the MOSFETs. To minimize parasitics, the
traces for HG and SW should run parallel and close to
each other. The same is true for LG and GND.
3. Driver VCC: Place the decoupling capacitor close to the
VCC and GND pins.
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8
9
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Physical Dimensions inches (millimeters) unless otherwise noted
8-Lead Small Outline Package
Order Number: LM27222M, LM27222MX
NS Package Number M08A
8-Lead LLP Package
Order Number: LM27222SD, LM27222SDX
NS Package Number SDC08A
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10
Notes
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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