ENHANCING ENERGY BALANCING IN COMPACT MULTILEVEL INVERTERS USING SELF-REGULATION TECHNIQUES

Abstract

This research introduces an updated approach to the integration of self-regulation approaches in order to enhance energy balance in tiny multilayer inverters. The performance and reliability of multilayer inverters may be adversely affected by issues with energy imbalance and the irregular distribution of capacitor voltage. Common applications for these inverters include renewable energy systems and electric motors. Feedback-based self-regulation mechanisms and adaptive control algorithms dynamically monitor and equalize energy levels across the inverter stages, thereby eradicating the necessity for intricate external balancing circuits. The system enhances voltage stability, minimizes harmonic distortion, and enhances overall efficiency by employing real-time voltage sensing and intelligent switching algorithms. The self-regulated multilevel inverter is an ideal candidate for implementation in next-generation compact power conversion systems due to its superior energy balance, scalability, and robustness, which surpass those of conventional designs.