Mutual Inductance Behavioral Modeling for Wireless Power Transfer System Coils

Capua, Giulia Di; Femia, N.; Stoyka, Kateryna; Mambro, G. Di; Maffucci, Antonio; Ventre, Salvatore; Villone, F.

doi:10.1109/tie.2019.2962432

Cited by 23 publications

(11 citation statements)

References 15 publications

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“…However, the proposed modeling approach is fully general and can be also implemented to search analytical expressions of the inductance values as a function of misalignment parameters. For instance, this approach is adopted in [14], where the mutual inductance value of a coil pair for an automotive IPT system is derived as a function of the axial and lateral misalignments of the coils and parametrized with respect to their reciprocal rotation angle. Therefore, in this paper we will only focus on analytical expressions that relate the selfinductance L and the mutual inductance M to geometrical design variables under perfect alignment conditions for fast prototyping of IPT systems by obtaining geometries that match the desired inductance and coupling factor.…”

Section: Problem Statementmentioning

confidence: 99%

“…The behavioral modeling approach has been recently demonstrated to be extremely helpful in both static and dynamic IPT system-level simulations. In [14], a behavioral analytical modeling of the mutual inductance of a coupled coil pair used in a static WPT system has been proposed. The paper also shows that it is possible to use the same behavioral model for modeling different coil pairs with the same shape (e.g., rectangular coils) but different dimensions and form factors.…”

Section: Self-inductance and Mutual Inductance Behavioral Modelingmentioning

confidence: 99%

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Self and Mutual Inductance Behavioral Modeling of Square-Shaped IPT Coils With Air Gap and Ferrite Core Plates

et al. 2022

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The design and optimization of coils for Inductive Power Transfer (IPT) systems is an iterative process conducted in Finite Element (FE) tools that takes a lot of time and computational resources. In order to overcome such limitations in the design process, new empirical equations for the evaluation of the self-inductance and mutual inductance values are proposed in this work. By means of a multi-objective genetic programming algorithm, the self-inductance, the mutual inductance and the coupling factor values obtained from FE simulations of IPT link are accounted by analytical equations based on the geometric parameters defining the IPT link. The behavioral modeling results are compared with both FE-based and experimental results, showing a good accuracy.

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Section: Problem Statementmentioning

confidence: 99%

Section: Self-inductance and Mutual Inductance Behavioral Modelingmentioning

confidence: 99%

Self and Mutual Inductance Behavioral Modeling of Square-Shaped IPT Coils With Air Gap and Ferrite Core Plates

et al. 2022

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“…As the efficiency is function of M according to (9), the proposed behavioral model allows calculating the derivative of the efficiency with respect to ∆z. By using the first-order linear approximation (14), it is possible to obtain the function ∆z max (∆y) given in (15):…”

Section: Wpts Performance Sensitivity Analysismentioning

confidence: 99%

“…In this paper, we follow the second approach, by deriving, validating and using an analytical behavioral model of M. This modeling approach has been previously used to assess the losses and performances in power devices and power modules, like IGBTs [12], inductors [13], and inverter modules [14], and to study static WPTSs [15]. Compared to the static condition analyzed in [15], the dynamic problem analyzed herein introduces new challenges and features, related to the geometry and to the time-domain behavior. Indeed, the paper focuses on the misalignments of the EV trajectory [16], and on their impact on the operation of the entire WPTS [17].…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2021

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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.

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“…In [13], circular coils were designed and investigated for planar and angular misalignment through the FEM model. Reference [14] proposed the use of an analytical behavioral model, able to relate mutual inductance to a wide range of misalignment conditions for IPT coil system (axial, lateral, and rotational). However, in such previous publications, the number of possible misalignments conditions was limited, and no accurate comparison among different coupling coils was given.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Coupling Coils for Static Inductive Power-Transfer Systems Taking into Account Sources of Uncertainty

et al. 2021

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The present work aims at comparing different coupling coils by taking into account sources of uncertainty for static inductive power-transfer (SIPT) systems. Due to the maximum transmission efficiency for the SIPT system related to the mutual inductance between coils, the key point here is to make use of a sparse polynomial chaos expansion (PCE) method to analyze the mutual inductance between the transmitter and the receiver. A fast postprocess-sensitivity analysis allowed the identification of which source of uncertainty was the most influential factor to the mutual inductance for different coupling coils. Furthermore, in view of the relationship between the maximum transmission efficiency and the ratio of the length of wires of a coil and the mutual inductance, circular coupling coils should be recommended for SIPT systems.

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Mutual Inductance Behavioral Modeling for Wireless Power Transfer System Coils

Cited by 23 publications

References 15 publications

Self and Mutual Inductance Behavioral Modeling of Square-Shaped IPT Coils With Air Gap and Ferrite Core Plates

Self and Mutual Inductance Behavioral Modeling of Square-Shaped IPT Coils With Air Gap and Ferrite Core Plates

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

Comparison of Coupling Coils for Static Inductive Power-Transfer Systems Taking into Account Sources of Uncertainty

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