In this thesis, a novel double-line-frequency current ripple cancellation control for the three-phase quasi-Z-source inverter (qZSI) is proposed. The qZSI has the single stage DC/AC conversion with buck-boost capability, which is good for the application of the grid-connected photovoltaic (PV) power system or energy storage system. However, when the grid voltage sag occurs, the three-phase output current become unbalanced and containing harmonic components. Also, the input current and power will have double-line-frequency ripple. Under the unbalanced situation, the conventional three-phase inverter with the positive-sequence and negative-sequence control can reduce the harmonic components to improve the power factor. But it can not achieve the balanced three-phase current and eliminate double-line-frequency input current ripple at the same time. In order to solve the problem, a double-line-frequency current ripple cancellation control strategy for qZSI under unbalanced condition is proposed. It can achieve three-phase output current balancing and double-line-frequency input current ripple cancelation simultaneously. In this thesis, operation principle of the qZSI under unbalanced grid voltage is first introduced. Then, the mathematical derivation of the proposed control method is presented. Both computer simulations and hardware experimental results of a 3kW phototype circuit are presented to verify the performance of qZSI with the proposed double-line-frequency current ripple cancellation control.