@inproceedings{scholars20566, publisher = {Institute of Electrical and Electronics Engineers Inc.}, doi = {10.1109/SCOReD68498.2025.11398941}, title = {Effect of Inductive Compensation Design on Wireless Power Transfer Efficiency in Low Power Applications}, year = {2025}, journal = {2025 IEEE 23rd Student Conference on Research and Development, SCOReD 2025 - Conference Proceedings}, keywords = {Capacitance; Heat losses; Inductive power transmission; Low power electronics; Radio; Compensation circuits; Compensation designs; Energy; Inductive compensation; Inductive power; Low power application; Power; Power transfer efficiency; Power transfers; Wireless power; MATLAB}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-105035726242&doi=10.1109\%2fSCOReD68498.2025.11398941&partnerID=40&md5=aa626012603f0c76e42e0220976f2f73}, author = {Sepeeh, Muhamad Syazmie and Nguba, Miriam Elena Ondo and Jamahori, Hanis Farhah and Zulkifli, Shamsul Aizam and Jackson, Ronald and Ismail, Nadiah}, abstract = {Wireless Power Transfer (WPT) has emerged as a game-changing technique for transferring energy without the use of physical connectors. However, heat dissipation continues to be a significant barrier in terms of efficiency. This study investigates inductive circuit compensation techniques to optimise WPT efficiency, focusing on minimising heat losses and enhancing power transfer stability. A comparative analysis of compensation circuits with varying capacitance values of 47 {\ensuremath{\mu}}F for a few numbers of capacitors is conducted using MATLAB/Simulink simulation. The results show that effective compensation increases efficiency significantly at 98.2, lowering losses while maintaining a stable output DC voltage of 12 V at 2.1 A. This effort adds to the advancement of low-power WPT applications by improving compensation strategies for practical feasibility. {\copyright} 2025 IEEE.}, isbn = {979-833157136-8} }