The external bootstrap capacitor needs to maintain operation above the BOOT UVLO falling threshold during normal operation. As a best design practice, size the capacitor to allow for substantial margin this threshold. The first step in determining the bootstrap capacitor value is calculating for ∆V_BOOT. This is the maximum allowable drop on the bootstrap capacitor:

where:

• n is the number of bootstrap diodes used in series
• V_F is the voltage drop of the bootstrap diode chosen
• V_{BOOT_UVLO} is the BOOT UVLO falling threshold voltage

To maintain significant margin and account for any additional voltage drop across the bootstrap resistor used and also for load transients, the capacitor is calculated for ∆V_BOOT of 1.5V. Referring to Bootstrap Capacitor, the value of Q_total needs to first be determined, and then C_BOOT can subsequentially be calculated:

A minimum value of 12.4nF is needed for the design. However, given the potential for capacitance changes with temperature and applied voltage, as well as unexpected circuit behavior such as load transients that impact the bootstrap charging time, a 100nF X7R capacitor is selected.

The VIN capacitor selected must be larger than the bootstrap capacitor. The general recommendation is that this capacitor is at least ten times the bootstrap capacitor value, which gives 1μF capacitor in this instance. For the evaluation setup, a 2.2μF and 1μF capacitor were used at VIN, both ceramic X7R type capacitors. The recommendation is to place these capacitors and the bootstrap capacitors as close the respective pins as possible. Select capacitors with voltage ratings that are suffiently larger than the maximum applied voltage (i.e. greater than two times if possible).

Lastly, as detailed in Linear Regulator Operation, select high-quality 1μF X7R ceramic capacitors for use at BP5H, BP5L, and BP7L outputs. Place these capacitors in close proximity to the respective pins.