Summary: | The matrix converter is a power electronic device that can be used to control the flow of electricity in various industrial and commercial applications. In recent years, the matrix converter has become increasingly popular as a means of decarbonizing energy production. One of the primary benefits of the matrix converter is its ability to efficiently convert AC power to DC power, and vice versa. This is critical in renewable energy systems that rely on DC power, such as solar panels and wind turbines. Therefore, this paper presents the revolution of the matrix converter, which focuses on the single-phase topology, and its applications, especially for renewable energy and battery storage. The operations of a matrix converter to convert DC power from solar panels and wind turbine sources to AC power suitable for use on the power grid are presented as well as the appropriate switching algorithms. To achieve this, the SPMC can be designed to handle multiple input voltages and frequencies and to generate multiple output voltages and frequencies. This can be done by using a combination of modulation techniques, such as carrier based PWM, along with appropriate switching patterns. Therefore, a multi-input multi-output converter (MIMO) using matrix converter is a power electronics converter that can handle multiple inputs and multiple outputs voltages and frequencies using only one circuit topology. Thus, the topology can offer several advantages over traditional power converters such as reduced size and cost, high efficiency, improved power quality and flexibility. This is crucial for a decarbonized energy system because it makes renewable energy sources more effective. Its ability to efficiently convert power, regulate power flows, and operate reliably makes it an important tool in the transition to a decarbonized energy system. © 2023 Institute of Physics Publishing. All rights reserved.
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