Parameter Tuning Method for a Lattice Compensated Wireless Power Transfer System

This study presents a new charging system with lattice compensation for wireless power transfer (WPT) applications. A mathematical model is developed for the proposed system to accurately estimate power transfer capabilities. Furthermore, a linear programming algorithm is used to find the proper values for lattice compensation, which helps achieve high efficiency over a wide range of loads and zero voltage switching (ZVS) for the proposed system. The approach is validated through analysis, modeling, and simulation of a 3-kilowatt WPT system. Additionally, a 200-watt prototype with a 100 mm air gap was built and tested, showing an efficiency of 86.3% during charging. This method eliminates the need for an auxiliary DC-DC converter, ensuring efficient charging across various load conditions. The prototype's performance closely matches the simulation results, indicating its potential for scaling up to electric vehicle (EV) battery charging applications.