In this thesis, a per-phase active power conditioning (PPAPC) strategy for the three-phase four-wire static synchronous compensators (STATCOM) is proposed. The purpose of the PPAPC is to compensate the active power and the reactive power according to the load requirements and the voltage drop of each phase. Conventionally, the DC side of the conventional STATCOM is a large capacitor bank. The STATCOM can help to regulate the voltage, increase the stability and reliability of the microgrids by injecting or absorbing the reactive power when the faults occur. In addition to the original function of reactive power compensation, the proposed PPAPC strategy has an additional active power transferring function to balance the unbalanced loads of the microgrids. Since the STATCOM needs to transfer the active and reactive power simultaneously when the microgrids fault occurs, power flow distribution criteria is also developed in the proposed PPAPC strategy. For the proposed PPAPC stragegy, each phase of the STATCOM will compensate the reactive power first, then transfer the active power based on a distribution ratio. For the case that two phases absorb the active power and one phase provides the active power, an appropriate distribution ratio of active power will be calculated. It can equalize the each phase’s current stress, so the life time of the power switches will not be affected. According to the equivalent circuit of the three-phase four-wire inverter, the sinusoidal control signal of each phase can be derived. Consequently, the output power of each phase can be independently controlled by the corresponding sinusoidal control signal. Both the computer simulations and the hardware experimental results of a 6kVA prototype circuit are presented to verify the performance of the STATCOM with the proposed PPAPC strategy.