JAJSVE0C May 2015 – July 2024 UCC27201A-Q1
PRODUCTION DATA
Generally, the switching speed of the power switch during turnon and turnoff should be as fast as possible in order to minimize switching power losses. The gate driver device must be able to provide the required peak current for achieving the targeted switching speeds with the targeted power MOSFET. The system requirement for the switching speed is typically described in terms of the slew rate of the drain-to-source voltage of the power MOSFET (such as dVDS/dt). For example, the system requirement might state that a SPP20N60C3 power MOSFET must be turned-on with a dVDS/dt of 20V/ns or higher with a DC bus voltage of 400V in a continuous-conduction-mode (CCM) boost PFC-converter application. This type of application is an inductive hard-switching application and reducing switching power losses is critical. This requirement means that the entire drain-to-source voltage swing during power MOSFET turnon event (from 400V in the OFF state to VDS(on) in on state) must be completed in approximately 20ns or less. When the drain-to-source voltage swing occurs, the Miller charge of the power MOSFET (QGD parameter in the SPP20N60C3 data sheet is 33nC typical) is supplied by the peak current of gate driver. According to power MOSFET inductive switching mechanism, the gate-to-source voltage of the power MOSFET at this time is the Miller plateau voltage, which is typically a few volts higher than the threshold voltage of the power MOSFET, VGS(TH).
To achieve the targeted dVDS/dt, the
gate driver must be capable of providing the
QGD charge in 20ns or less. In other
words a peak current of 1.65A (= 33nC / 20ns) or
higher must be provided by the gate driver. The
UCC27201A-Q1 gate driver is capable of providing
3A peak sourcing current which clearly exceeds the
design requirement and has the capability to meet
the switching speed needed. The overdrive
capability provides an extra margin against
part-to-part variations in the QGD
parameter of the power MOSFET along with
additional flexibility to insert external gate
resistors and fine tune the switching speed for
efficiency versus EMI optimizations. However, in
practical designs the parasitic trace inductance
in the gate drive circuit of the PCB will have a
definitive role to play on the power MOSFET
switching speed. The effect of this trace
inductance is to limit the dI/dt of the output
current pulse of the gate driver. In order to
illustrate this, consider output current pulse
waveform from the gate driver to be approximated
to a triangular profile, where the area under the
triangle
(½ ×
IPEAK × time) would equal the total
gate charge of the power MOSFET (QG parameter in
SPP20N60C3 power MOSFET datasheet = 87nC typical).
If the parasitic trace inductance limits the dI/dt
then a situation may occur in which the full peak
current capability of the gate driver is not fully
achieved in the time required to deliver the QG
required for the power MOSFET switching. In other
words the time parameter in the equation would
dominate and the IPEAK value of the
current pulse would be much less than the true
peak current capability of the device, while the
required QG is still delivered. Because of this,
the desired switching speed may not be realized,
even when theoretical calculations indicate the
gate driver is capable of achieving the targeted
switching speed. Thus, placing the gate driver
device very close to the power MOSFET and
designing a tight gate drive-loop with minimal PCB
trace inductance is important to realize the full
peak-current capability of the gate driver.