Multilevel Inverters (MLIs) gained significant attention due to their ability to produce high-quality output voltage waveforms with high efficiency. Switched-Capacitor (SC)-based MLI topology achieves higher voltage levels using relatively simple circuit configuration. This paper proposes, design and analysis of Single-Phase 29-Level Switched-Capacitor Boost Multilevel Inverter (SCBMLI), aiming to enhance voltage levels and efficiency in power conversion systems. The innovative design focuses on reducing the number of components required, thereby optimizing the inverter’s size and cost without compromising its functionality. SCBMLI’s architecture allows for significant improvements in output waveform quality. Comprehensive simulations using MATLAB validate, proposed inverter’s effectiveness, demonstrating its ability to deliver enhanced performance, increased reliability, and potential scalability for higher power applications.

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Design and Analysis of a Single-Phase 29-Level Switched-Capacitor Boost Multilevel Inverter

  • K. S. Kavitha Kumari,
  • L. Chitra,
  • K. Boopathy,
  • P. Poornima,
  • K. Suresh Kumar

摘要

Multilevel Inverters (MLIs) gained significant attention due to their ability to produce high-quality output voltage waveforms with high efficiency. Switched-Capacitor (SC)-based MLI topology achieves higher voltage levels using relatively simple circuit configuration. This paper proposes, design and analysis of Single-Phase 29-Level Switched-Capacitor Boost Multilevel Inverter (SCBMLI), aiming to enhance voltage levels and efficiency in power conversion systems. The innovative design focuses on reducing the number of components required, thereby optimizing the inverter’s size and cost without compromising its functionality. SCBMLI’s architecture allows for significant improvements in output waveform quality. Comprehensive simulations using MATLAB validate, proposed inverter’s effectiveness, demonstrating its ability to deliver enhanced performance, increased reliability, and potential scalability for higher power applications.