Abstract
Magnetically coupled impedance source networks provide a wide range of applications, such as dc to dc, dc to ac, ac to ac, ac to dc unidirectional or bi-directional power conversion. Various impedance source networks are reported in the literature to overcome the barriers of conventional voltage source inverters. They offer high boost with buck-boost capabilities and reduce power conversion stages. Thus, they provide an economical solution to expanding power systems, and are most suitable for renewable sources having low output. The goal of this study is to provide an in-depth comprehensive review of the major topologies of magnetically coupled impedance source networks. The review is more focused towards the fast-growing niche area, which has seen many advancements in the last few years. Best efforts are made to include relevant major topological advancements, with the aim of providing relevant and accessible information for researchers. This research provides a detailed comparison of essential factors and presents a full assessment of major topological improvements in MCIS networks.
Highlights
In the last decade, renewable energy generation has achieved worldwide acclamation as it serves as a solution to the increasing energy demand
This paper presents a comprehensive review of topological advancements in magnetically coupled impedance source (MCIS) networks for power conversion
Coupled impedance source networks have seen rapid advancements in the last few years; they have proven their superiority in efficient power conversion compared to any other two-stage or single-stage converter topologies, as they overcome most of the problems associated with traditional converter topologies
Summary
Arvind Yadav 1 , Subhash Chandra 1 , Mohit Bajaj 2 , Naveen Kumar Sharma 3 , Emad M.
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