Purpose
The electromagnetic modeling of inductively coupled, resonant wireless power transfer (WPT) is dealt with. This paper aims to present a numerically efficient simulation method.
Design/methodology/approach
Recently, integral equation formulations have been proposed, using piecewise constant basis functions for the series expansion of the current along the coil wire. In the present work, this scheme is improved by introducing global basis functions.
Findings
The use of global basis functions provides a stronger numerical stability and a better control over the convergence of the simulation; moreover, the associated computational cost is lower than for the previous schemes. These advantages are demonstrated in numerical examples, with special attention to the achievable efficiency of the power transfer.
Practical implications
The method can be efficiently used, e.g., in the optimal design of resonant WPT systems.
Originality/value
The presented computation scheme is original in the sense that global series expansion has not been previously applied to the numerical simulation of resonant WPT.
Numerical Exposure Assessment Method for Low Frequency Range and Application to Wireless Power Transfer