The LM25149 high-side and low-side gate drivers incorporate short
propagation delays, adaptive deadtime control, and low-impedance output stages
capable of delivering large peak currents with very fast rise and fall times to
facilitate rapid turn-on and turnoff transitions of the power MOSFETs. Very high
di/dt can cause unacceptable ringing if the trace lengths and impedances are not
well controlled.
Minimization
of stray or parasitic gate loop inductance is key to optimizing gate drive switching
performance, whether it be series gate inductance that resonates with MOSFET gate
capacitance or common source inductance (common to gate and power loops) that
provides a negative feedback component opposing the gate drive command, thereby
increasing MOSFET switching times. The following loops are important:
- Loop 2: high-side MOSFET,
Q1. During the high-side MOSFET turn-on, high current flows
from the bootstrap (boot) capacitor through the gate driver and high-side
MOSFET, and back to the negative terminal of the boot capacitor through the
SW connection. Conversely, to turn off the high-side MOSFET, high current
flows from the gate of the high-side MOSFET through the gate driver and SW,
and back to the source of the high-side MOSFET through the SW trace. Refer
to loop 2 of Figure 11-1.
- Loop 3: low-side MOSFET,
Q2. During the low-side MOSFET turn-on, high current flows
from the VCC decoupling capacitor through the gate driver and low-side
MOSFET, and back to the negative terminal of the capacitor through ground.
Conversely, to turn off the low-side MOSFET, high current flows from the
gate of the low-side MOSFET through the gate driver and GND, and back to the
source of the low-side MOSFET through ground. Refer to loop 3 of Figure 11-1.
TI strongly recommends
following circuit layout guidelines when designing with high-speed MOSFET gate drive
circuits.
- Connections from gate driver
outputs, HO and LO, to the respective gates of the high-side or low-side
MOSFETs must be as short as possible to reduce series parasitic inductance.
Be aware that peak gate drive currents can be as high as 3.3 A. Use 0.65 mm
(25 mils) or wider traces. Use via or vias, if necessary, of at least 0.5 mm
(20 mils) diameter along these traces. Route HO and SW gate traces as a
differential pair from the LM25149 to the high-side MOSFET,
taking advantage of flux cancellation.
- Minimize the current loop
path from the VCC and HB pins through their respective capacitors as these
provide the high instantaneous current, up to 3.3 A, to charge the MOSFET
gate capacitances. Specifically, locate the bootstrap capacitor,
CBST, close to the CBOOT and SW pins of the LM25149 to minimize the area of
loop 2 associated with the high-side driver. Similarly, locate the VCC
capacitor, CVCC, close to the VCC and PGND pins of the LM25149 to minimize the area of
loop 3 associated with the low-side driver.