English title

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In this paper, a multi-stage Z-source inverter with high boost factor is proposed. The proposed topology by using the combination of a power supply and Z-source networks are increased the voltage. Regarding voltage increase capability over the wide range, good resistance against electromagnetic noise and immunities against shoot through (ST), this inverter can be used widely in the photovoltaic systems, fuel cells, wind energy and UPS systems. The suitable PWM control method for the proposed inverter is presented. Theoretical analysis of proposed inverter in two-stage and N stage for ST mode and non-ST mode are presented too. The case study for power losses analyses and efficiency is presented and the advantages and disadvantages of the increasing the stages are shown too. Moreover, a comparison between the proposed topology with the conventional Z-source inverters is presented. In order to verify the performance of the proposed topology, the simulation results obtained from the PSCAD/EMTDC software are presented

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In this paper, a new control method is proposed that it is suitable for half bridge Z-source inverters. Due to extend of half bridge Z-source inverters and lack of a suitable control method, it is necessary to present a control method with capability to generate low frequency output voltage. According to this fact that, the switching pattern of the half bridge Z-source inverters are different because of their topologies and applications, therefore, each switching method create specific conditions in values of voltage and current ripples, voltage and current stresses and design considerations. This paper while propose a new control method for half bridge Z-source inverters, it is presented completely analyses of a half bridge Z-source inverter based on the proposed method. Different conditions to generate shoot through (ST) modes in the proposed method are presented and mathematical relations between duty cycle and modulation index is shown. Finally, in order to reconfirm the theoretical analyses, the simulation results by using PSCAD/EMTDC are presented.