Your search keyword '"Bilicz, Sandor"' showing total 6 results

1. Integral Equation Formulations for Modeling Wireless Power Transfer Systems in Close Proximity to Foreign Objects.

Author

Bingler, Arnold, Bilicz, Sandor, Badics, Zsolt, Gyimothy, Szabolcs, and Pavo, Jozsef

Subjects

*WIRELESS power transmission, *FOREIGN bodies, *INTEGRAL equations, *GREEN'S functions, *DEGREES of freedom, *TECHNOLOGY transfer

Abstract

Integral equation (IE) methods have recently been proposed for the modeling of inductively coupled resonant wireless power transfer. These approaches usually result in a low number of degrees of freedom. However, their applicability is mostly limited to homogeneous background media. In the present contribution, integral formulations are extended to take certain foreign objects into account in the model. By using quasi-static approximations, homogeneous foreign objects of canonical shape (e.g., spheres, plates) modify the Green’s function such that it can still be analytically expressed; thus, the computational cost of the IE method remains low. The method is validated against 3-D finite-element simulation and experimental data. [ABSTRACT FROM AUTHOR]

Published

2019

2. Loss Computation Method for Litz Cables With Emphasis on Bundle-Level Skin Effect.

Author

Gyimothy, Szabolcs, Kaya, Shusuke, Obara, Daiki, Shimada, Mamoru, Masuda, Mitsuru, Bilicz, Sandor, Pavo, Jozsef, and Varga, Gabor

Subjects

SKIN effect, CABLES, WIRELESS power transmission

Abstract

An efficient method is proposed for the numerical simulation of the bundle-level skin effect and its consequences arising in certain types of litz wires. The method is based on a probabilistic approach. The theory presented allows characterization of the repartition of currents between bundles and predicts some unexpected unique features. The method is tested on a coil unit that is used for inductive wireless power transfer. Simulations are verified by experimental data. [ABSTRACT FROM AUTHOR]

Published

2019

3. A Full-Wave Integral Equation Method Including Accurate Wide-Frequency-Band Wire Models for WPT Coils.

Author

Bilicz, Sandor, Badics, Zsolt, Gyimothy, Szabolcs, and Pavo, Jozsef

Subjects

*INTEGRAL equations, *ENERGY bands, *WIRELESS power transmission, *BOUNDARY value problems, *ELECTROMAGNETIC fields

Abstract

A full-wave surface integral equation method is used for modeling coils in a wide frequency range. This is of high importance in the analysis of resonant wireless power transfer links, for example. This paper presents a nonlocal generalization of the impedance boundary condition (BC) concept by incorporating a 2-D model (using the finite element method here) of the quasi-static electromagnetic field within the wire. This yields a numerical approximation of the nonlocal impedance BC on the wire surface that holds true at any frequency. The 2-D eddy-current model has to be evaluated only twice at one frequency, which makes the scheme computationally efficient. The method accurately predicts the ohmic loss as shown by the validations against alternative methods. [ABSTRACT FROM AUTHOR]

Published

2018

4. Efficient Perturbation Method for Computing Two-Port Parameter Changes Due to Foreign Objects for WPT Systems.

Author

Pavo, Jozsef, Badics, Zsolt, Bilicz, Sandor, and Gyimothy, Szabolcs

Subjects

PERTURBATION theory, PARAMETER estimation, WIRELESS power transmission, POISSON integral formula, ELECTROMAGNETIC fields

Abstract

The change in the two-port parameters of a wireless power transfer (WPT) chain is evaluated when an object (foreign object) with given material parameters is placed in the vicinity of the WPT transmitter and receiver. An integral formula for the change of the two-port parameters due to the presence of a foreign object has been derived by using the generalized theory of reciprocity. It is emphasized that—instead of taking the differences of the two-port parameters calculated with and without the presence of the foreign object—the presented method provides the change of the two-port parameters directly from the calculated electromagnetic field at the location of the foreign object. As a result, the relatively small parameter changes can be predicted with good accuracy. Based on the application of the Born approximation, the possibility of computing an approximation of the changes of the two-port parameters is explored. [ABSTRACT FROM AUTHOR]

Published

2018

5. Modeling of Dense Windings for Resonant Wireless Power Transfer by an Integral Equation Formulation.

Author

Bilicz, Sandor, Badics, Zsolt, Gyimothy, Szabolcs, and Pavo, Jozsef

Subjects

*FUNCTIONAL equations, *INTEGRAL equations, *COMPUTATIONAL mechanics, *WIRELESS power transmission, *NUMERICAL analysis

Abstract

A full-wave integral equation scheme for modeling resonant coils applied in wireless power transfer systems is presented. An A-\Phi formulation is applied with current and charge densities on the wire surface as unknowns. The method overcomes the limitation of the “thin-wire approximation” as it enables the unknowns to vary on the wire surface. Thus, proximity effects (that typically emerge when modeling dense windings) are taken into account. The numerical implementation of the formulation has smaller computation cost than, for example, finite element methods. The proposed scheme is tested against closed-form solutions and alternative simulations. [ABSTRACT FROM AUTHOR]

Published

2017

6. Modeling of Resonant Wireless Power Transfer With Integral Formulations in Heterogeneous Media.

Author

Bilicz, Sandor, Gyimothy, Szabolcs, Pavo, Jozsef, Toth, Laszlo Levente, Badics, Zsolt, and Balint, Botond

Subjects

*WIRELESS power transmission, *RESONANT states, *MAGNETIC fields, *DIELECTRIC properties, *COMPARATIVE studies

Abstract

A full-wave integral formulation has recently been proposed for the simulation of magnetically coupled resonant wireless power transfer (WPT) arrangements in homogeneous medium. In this paper, the formulation is extended to the case where two different types of dielectrics are separated by a planar interface. This configuration has extensive practical interest nowadays, especially for modeling biomedical WPT applications. The new formulation is based on a stationary approximation, which is valid at the typical operating frequencies. The proposed scheme requires much less computational resources compared with standard finite-element simulations. The results are validated against alternative simulations and measured data as well. [ABSTRACT FROM AUTHOR]

Published

2016