Litcius/Paper detail

Analysis of Dynamic Wireless Power Transfer Systems Based on Behavioral Modeling of Mutual Inductance

Giulia Di Capua, Antonio Maffucci, Kateryna Stoyka, Gennaro Di Mambro, Salvatore Ventre, Vincenzo Cirimele, Fabio Freschi, F. Villone, N. Femia

2021Sustainability19 citationsDOIOpen Access PDF

Abstract

This paper proposes a system-level approach suitable to analyze the performance of a dynamic Wireless Power Transfer System (WPTS) for electric vehicles, accounting for the uncertainty in the vehicle trajectory. The key-point of the approach is the use of an analytical behavioral model that relates mutual inductance between the coil pair to their relative positions along the actual vehicle trajectory. The behavioral model is derived from a limited training data set of simulations, by using a multi-objective genetic programming algorithm, and is validated against experimental data, taken from a real dynamic WPTS. This approach avoids the massive use of computationally expensive 3D finite element simulations, that would be required if this analysis were performed by means of look-up tables. This analytical model is here embedded into a system-level circuital model of the entire WPTS, thus allowing a fast and accurate analysis of the sensitivity of the performance as the actual vehicle trajectory deviates from the nominal one. The system-level analysis is eventually performed to assess the sensitivity of the power and efficiency of the WPTS to the vehicle misalignment from the nominal trajectory during the dynamic charging process.

Topics & Concepts

TrajectorySensitivity (control systems)InductanceWireless power transferComputer scienceProcess (computing)Electromagnetic coilBehavioral modelingControl theory (sociology)Power (physics)Point (geometry)Set (abstract data type)Key (lock)SimulationWirelessEngineeringElectronic engineeringArtificial intelligenceMathematicsElectrical engineeringComputer securityControl (management)GeometryVoltageAstronomyOperating systemTelecommunicationsProgramming languageQuantum mechanicsPhysicsWireless Power Transfer SystemsEnergy Harvesting in Wireless NetworksAdvanced Battery Technologies Research