Since the early twentieth century, induction heating have been widely used and rapidly developed in the industrial applications because of their distinctive advantages such as high-speed heating, safety, high products quality, cleanliness, and etc.. In addition to this, with tremendous advance in the latest power semiconductor devices permiting switches of inverters to operate under high frequencies, the induction heating systems have become lighter, compacter, and more efficience. The main purpose of this study is to investigate the application of a single chip, TMS320C240, microprocessor to a fully digital high frequency induction heating system. By using the phase-shifted full-bridge zero-voltage-switched PWM technique, this system can reduce switching loss, component stress, and electromagnetic interference of power semiconductor devices. In induction heating applications, because the electrical characteristics of the workpieces will change in the processing, the circuit resonant frequency must be changed in accordance. Hence, the variable frequency control technique is used for tracking the resonant frequency to keep the system operating at the optimal condition. The phase-shift Pulse-Width-Modulated (PWM) is used for regulating the duty-cycle to control the output power. Finally, the efficiency of this heater are measured and analyzed under load variations. Experimental results show that the ZVS PWM technique can improve the efficiency of this system.