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Abstract

This research article explores the control strategies for managing the battery charging and discharging operations using a bidirectional converter. Bidirectional converters offer flexibility and allow batteries to receive and deliver power. Battery systems are an important part of electrical vehicles (EVs), and they can be charged by renewable energy integration and the public grid. The battery bank manages the DC (Direct Current) link and fulfills the load requirement for charging. The main aim of this article, the proportional integral derivative (PID) controller, is to design and control the duty cycle of the bidirectional converter to ensure efficient and safe battery operation. In this regard, the current of battery banks is regulated during the charging and discharging phases. To ensure optimum charging and discharging control, further work can be implemented using artificial intelligence (AI) based technology in the battery management system (BMS) operation.

Keywords

Electrical vehicles Battery management system Bidirectional converter Proportional integral derivative Artificial intelligence

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How to Cite
Khan, M. J., Akhtar, M. N. ., & Afthanorhan, A. . (2025). An innovative control of the charging and discharging for the battery management operation using a bidirectional converter. Future Technology, 4(1), 23–28. Retrieved from https://fupubco.com/futech/article/view/231
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