Title :
Enhanced Analysis of Multiconductor Nanostructured Devices via a Compact Block FDTD/VFETD Method
Author :
Kantartzis, N.V. ; Zygiridis, T.T. ; Tsiboukis, T.D.
Author_Institution :
Dept. of Electr. & Comput. Eng., Aristotle Univ. of Thessaloniki, Thessaloniki, Greece
Abstract :
A reduced-order modeling FDTD/vector finite-element time-domain technique is introduced in this paper, for the rigorous and cost-effective study of multiconductor nanoscale structures. The new methodology blends a compact stencil-optimized discretization process with general vector finite elements via the pertinent coupling conditions and divides the domain into tightly coupled blocks. A key asset is that both approaches are time advanced independently while their state-space models are derived via a Krylov-based scheme with scaled Laguerre functions, which drastically decreases the order of the transfer matrix. Therefore, complex geometries are consistently treated without the need of excessively fine grid tessellations. Numerical results from various nanocomposite devices validate the hybrid method and reveal its applicability.
Keywords :
carbon nanotubes; finite difference time-domain analysis; finite element analysis; matrix algebra; nanocomposites; reduced order systems; Krylov-based scheme; Laguerre functions; compact block FDTD-VFETD method; compact stencil-optimized discretization; complex geometry; coupled blocks; finite elements; multiconductor nanoscale structures; multiconductor nanostructured devices; nanocomposite; pertinent coupling conditions; reduced-order modeling; state-space models; transfer matrix; vector finite-element time-domain technique; Antennas; Couplings; Finite difference methods; Nanoscale devices; Random access memory; Time-domain analysis; Vectors; Carbon nanotubes (CNTs); finite-difference time-domain (FDTD) methods; finite-element time-domain (FETD) schemes; model-order reduction; nanostructured devices;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2283220
