ENHANCING EV INVERTER PERFORMANCE THROUGH INTEGRATED POWER AND COMMUNICATION ARCHITECTURES

Abstract

This research aims to enhance the efficiency, dependability, and real-time control of modern electric vehicle (EV) systems by optimizing the performance of EV inverters through the integration of power and communication architectures. The suggested approach integrates embedded communication protocols with modern power electronic configurations to ensure flawless coordination across motor drives, battery management systems, and inverter modules. The technology advances switching processes, eliminates harmonic distortion, and improves thermal management through high-speed data exchange and sophisticated control algorithms. The integration facilitates adaptive functioning under diverse load conditions and predictive diagnostics, leading to enhanced energy efficiency and stable voltage output. The results of the modeling and experiment validate that the proposed architecture markedly enhances overall inverter efficiency, dynamic response, and system scalability, rendering it a feasible choice for next-generation electric car applications.