With the strong demand for handheld devices and computer equipment in recent years, the requirements for power management ICs are becoming more and more stringent. The design of power management ICs with high power density, fast dynamic response, and wide input and output range are the main goals of today's power management IC development. Two different types of DC-DC converters are discussed in this thesis. The first architecture focuses on a ripple-based constant on-time buck converter. The purpose is to solve the stability problem and to improve the load transient response by analyzing the small signal model mentioned in the reference. A proposed technique applying to the feedback path is the main research content in this work. The converter can regulate the output voltage with less than 50 mV/A undershoot/overshoot when the load transient occurs. The converter with discontinuous conduction mode (DCM) condition can reduce the switching loss at light load condition. The chip is fabricated in TSMC 180-nm CMOS process and occupies 1.2 x 1.0 mm2. Peak efficiency is 83.4%. The second architecture improves a time-charge-based control buck converter, which has a fixed quality factors to maintain system stability under wide input and output operation range. In this work, the passive components are implemented by stacked capacitors to reduce the chip area. The feedback output voltage is used to realize the DCM operation at light load condition. Owing to the above two reasons, a high power density design can be achieved. Due to the high-gain voltage loop, the line regulation and the load regulation of the circuit are less than 1 mV/V and 1 mV/A respectively. The chip is fabricated in TSMC 180-nm CMOS process and occupies 0.9×1.1 mm2. Peak efficiency is 94.9%.