BIAS is connected to the output. This example assumes that the load is connected to the output through long wires so a 3-Ω resistor is inserted to minimize risks of damage to the part during load shorts. In addition 0.1-µF capacitor is required close to the bias pin.
FB is connected directly to the output. BIAS and FB are connected to the output through separate traces. This is important to reduce noise and achieve good performances. See Section 11.1 for more details on the proper layout method.
SYNC is connected to ground through a pulldown resistor, and an external synchronization signal can be applied. The pulldown resistor ensures that the pin is not floating when the SYNC pin is not driven by any source.
EN is connected to VIN so the device operates as soon as the input voltage rises above the VIN-OPERATE threshold.
FPWM is connected to VIN. This causes the device to operate in FPWM mode. In this mode, the device remains in CCM operation regardless of the output current and is ensured to be within the boundaries set by FSW. To prevent frequency foldback behavior at low duty cycles, provide a 200-mA load. The drawback is that the efficiency is not optimized for light loads. See Section 8.4 for more details.
A 4.7-µF capacitor is connected between VCC and GND close to the VCC pin. This ensures stable operation of the internal LDO.
RESET is biased to the output in this example. A pullup resistor is necessary. A 100-kΩ is selected for this application and is generally sufficient. The value can be selected to match the needs of the application but must not lead to excessive current into the
RESET pin when
RESET is in a low state. Consult Section 7.1 for the maximum current allowed. In addition, a low pullup resistor could lead to an incorrect logic level due to the value of RRESET. Consult Section 7.6 for details on the
RESET pin.
Input capacitor selection is detailed in Section 9.2.1.2.2.1. It is important to connect small high-frequency capacitors CIN_HF1 and CIN_HF2 as close to both inputs PVIN1 and PVIN2 as possible.
Inductor selection is detailed in Section 9.2.1.2.2.2.1. In general, a 10-µH inductor is recommended for the fixed output options. For the adjustable output configurations, the inductance can vary with the output voltage due to ripple and current limit requirements.