Extended topologies of tapped-inductor Z-source inverters

In this paper, two distinct types of tapped-inductor Z-source impedance networks are proposed for implementing high-performance voltage-type inverters topologies with strong voltage boost inversion abilities and less components' stresses. All proposed topologies can in principle be unified into a generic network entity, which is termed hybrid-source tapped-inductor impedance network. The resulting novel Z-source inverters would have a higher output voltage gain and other unique advantages that currently have not yet been investigated. Theoretical analysis for explaining these operating features has already been discussed throughout the paper, before experimental results are presented for verifying them. It is anticipated that these advantages would help the formed inverters find applications in photovoltaic and other renewable systems, where a high voltage gain is usually requested.

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