Subgridding Boundary Conditions to Model Arbitrarily Dispersive Thin Planar Materials
Metadatos
Afficher la notice complèteAuteur
Ruiz-Cabello Núñez, Miguel David; Díaz Angulo, Luis Manuel; Álvarez, Jesús; Rubio Bretones, Amelia Consuelo; González García, SalvadorEditorial
IEEE
Materia
Finite differences Subcell models Thin-layer modeling Time domain
Date
2018Referencia bibliográfica
Publisher version: M. Ruiz Cabello, L. D. Angulo, J. Alvarez, A. R. Bretones and S. G. Garcia, "Subgridding Boundary Conditions to Model Arbitrarily Dispersive Thin Planar Materials," in IEEE Transactions on Antennas and Propagation, vol. 66, no. 11, pp. 6429-6434, Nov. 2018, [doi: 10.1109/TAP.2018.2862241]
Patrocinador
Spanish MINECO, EU FEDER, under Project TEC2013-48414-C3-01, ProjectTEC2016-79214-C3-3-R, and Project TEC2015-68766-REDC; J. de Andalucia, Spain, under GrantP12-TIC-1442; AIRBUS DSthrough Alhambra-UGRFDTD; CSIRC alhambra.ugr.es Supercomputing CenterRésumé
In a previous work, we presented a hybrid implicit–explicit Crank–Nicolson finite-difference time-domain method for treatingmultilayered lossy thin slabs. The main advantage of this methodwas its capability to overcome certain late-time stability issues of theconventional surface impedance boundary condition approaches. In thiscommunication, we extend this method to deal with thin slabs havingarbitrarily dispersive profiles. This approach is validated with the analysisof a spherical shell made of a metallic wire mesh whose macroscopicequivalent constitutive parameters are derived from its microscopicstructure. The results for the electric field inside the sphere are comparedagainst the analytical data and show good agreement with them.