Wireless Power Transfer Based Charging System for Electric Vehicles
Bhim Singh
Assistant Professor, Department of Electronics & Communication Engineering, KIPM College of Engineering and Technology, U.P., India
Ashutosh Srivastav
Scholar, Department of Electronics & Communication Engineering , KIPM College of Engineering and Technology, U.P., India
Shivam Pandey
Scholar, Department of Electronics & Communication Engineering , KIPM College of Engineering and Technology, U.P., India
Shivendra Pratap Tripathi
Scholar, Department of Electronics & Communication Engineering , KIPM College of Engineering and Technology, U.P., India
Mohd Asama Shahi4,
Scholar, Department of Electronics & Communication Engineering , KIPM College of Engineering and Technology, U.P., India
π DOI: https://doi.org/10.63920/tjths.52037
π Keywords: DC to AC conversion; MOSFET inverter; inductive coupling; wireless power transfer; rectifier; LED indicator
π Publication Date: 29 April 2026
π License:
This work is licensed under a Creative Commons Attribution 4.0 International License
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Abstract:
This project presents a wireless power transfer system in which direct current (DC) input is first converted into high-frequency alternating current (AC) using MOSFET-based inverters and rectifiers. The high-frequency AC is then applied to a transmitting coil, which creates a magnetic field that wirelessly transfers energy to a receiving coil. The receiving coil captures this alternating current, which is then converted back to DC using a separate rectifier circuit. The stable DC output is used to power a load, represented by LED indicators that light up when energy transfer occurs. This approach showcases a safe, contactless charging solution, suitable for small-scale applications and paving the way for future wireless EV infrastructure
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π How to Cite
Ashutosh S., Shivam P., Shivendra Pratap T., Mohd Asama S., Bhim S.(2026). Wireless Power Transfer Based Charging System for Electric Vehicles. TEJAS J. Technol. Humanit. Sci.,, Vol. 05, Issue 02. https://doi.org/10.63920/tjths.52037
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References
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