We present an approach for a fast and accurate determination of the geometrical optics solutions to Maxwell's equations based on the determination of the eikonal function and devised to handle scenarios involving complex spatially varying refraction indices. The explicit solution of the eikonal equation allows to set up an inverse ray tracing scheme, which proves particularly convenient compared to direct ray tracing. The field amplitude and polarization are then found by solving the relative transport equations along each ray. The accuracy of the method is shown in the case of the scattering from a conducting sphere coated by a dielectric. © 2017 ACES.
Accelerating fast marching for geometrical optics / Capozzoli, Amedeo; Curcio, Claudio; Liseno, Angelo; Savarese, Salvatore. - (2017). (Intervento presentato al convegno International Applied Computational Electromagnetics Society Symposium - Italy, ACES 2017 tenutosi a Firenze nel 26-30 March 2017) [10.23919/ROPACES.2017.7916309].
Accelerating fast marching for geometrical optics
CAPOZZOLI, AMEDEO;CURCIO, CLAUDIO;LISENO, ANGELO;SAVARESE, SALVATORE
2017
Abstract
We present an approach for a fast and accurate determination of the geometrical optics solutions to Maxwell's equations based on the determination of the eikonal function and devised to handle scenarios involving complex spatially varying refraction indices. The explicit solution of the eikonal equation allows to set up an inverse ray tracing scheme, which proves particularly convenient compared to direct ray tracing. The field amplitude and polarization are then found by solving the relative transport equations along each ray. The accuracy of the method is shown in the case of the scattering from a conducting sphere coated by a dielectric. © 2017 ACES.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.