This paper presents a hysteresis prediction voltage control (HPVC) method using the predictive strategy with early operations to reduce the transient ripple and minimizes the transient time in dc-dc converter. This HPVC control is composed of on-chip compensated two-stage EA PWM for steady-state PWM control. During transient, the buck converter switches to the HPVC mode to speed up the transient response. This technique is implemented in a standard 0.35-μm 2P4M 3.3V/5V Mixed Signal CMOS process. The analysis and simulation show that without using the HPVC technique in typical PWM dc-dc converter, the transient ripple is larger in magnitude and the transient time is lengthening. After the HPVC technique is applied, the prediction circuit will estimate the variation of voltage that is going to change by detect the capacitor current any time. In this way, the transient ripple can be greatly decreased and the transient time is also reduced. According to the measurement results, the function of HPVC control failed because of the spike of output voltage. The measurement shows that the recovery time can be improved to 25 μs by using the two-stage EA PWM compared to conventional PWM. The switching frequency of the chip operates at 1MHz, and the maximum efficiency is 87% when load current is 190 mA. The total chip area with on-chip compensated components is 1.518 × 1.643 mm2, and the other detailed measurement is included in this thesis.