In recent years, there are more and more sensors combing with wireless transmis-sion capability have been invented and implemented into our daily life. As the result, the demand for micropower level is getting higher and higher. Traditionally, most of these products are powered by batteries. However, the replacement of batteries and the labor cost accompanied with cannot be ignored after a working period. To overcome this dilemma, scientists are trying to scavenge the energy from the environment. To make a comprehensive survey of energy resource, the vibration energy is the second place of energy sources with high energy density and high stability in the environment. To scavenge the vibration energy, the piezoelectric materials are used to fabricate the harvesters to convert vibration into electricity. However, the electricity is in form of AC after scavenging by harvesters which cannot be used for electronics devices di-rectly. Thus, the interface circuit required for an energy harvesting system. In this work, we try to design a universal synchronous switching circuit in integrated type fabricated by TSMC with 0.25-μm high voltage CMOS technology. It can be reconfig-ured into different topologies. With pre-programmed MCU, circuit topologies can be changed into different form to extract power for different excitation and loading con-dition by controlling the different patterns of signal sequence. Therefore, we realize a reconfigurable method that can optimize to power output by switching into a load-independent topology or optimal load topology based on application condition. The proposed circuit could be switched into different switching topologies, including Switch-only rectifier, P-SSHI, S-SSHI, SICE, SECE and S3BF. We propose and realize a reconfigurable interface circuit for piezoelectric energy extraction systems in this thesis that can be adopted for different applying condition.