Recently, people need the solution of DC-DC Converter that can save a lot of cost and size because the application of hundreds of mW wearable devices flourishes. People pay attention to Four-Switch Non-Inverting Buck-Boost DC-DC Converter(FSNIBBC) because it has more power capacity than the Switching-Capacitor Converter, and it can provide both higher and lower than one conversion ratio, which the Linear Regulator cannot. Power management chips focus on high efficiency and small output voltage ripples of wearable devices. However, the FSNIBBC usually has low conversion efficiency because of the high inductor peak-to-peak current. The proposed chip uses a Three-Mode FSNIBBC structure to increase conversion efficiency when the input voltage is much higher or lower than the output voltage. However, when the mode transitions from each mode, it would be a significant Duty gap to let the compensator settle to the new Duty level, which means vast output voltage ripples. This thesis uses the proposed Auto-Delay-Ramp on the Three-Mode FSNIBBC. By doing so, a low mode transition voltage ripples and high-efficiency power converter will be implemented for wearable applications. The proposed chip is fabricated in TSMC 0.18 μm 1P6M High Voltage Mixed-Signal CMOS process. It can provide a fixed output voltage of 3.3V at loading is 20 mA~ 350mA when the input voltage is 2.7V to 4.2V. The measurement results with Auto-Delay-Ramp will effectively reduce output voltage ripples when mode transition to less than 0.848% and settling time less than 21.48uSec, and the maximum efficiency is 96.62% at output current equal to 100mA.