Title :
One Stroke Complementarity for Poisson-Like Problems
Author_Institution :
Dipt. di Ing. ElettricaGestionale e Meccanica, Univ. di Udine, Udine, Italy
Abstract :
Taking electrokinetics as a paradigm problem for the sake of simplicity, complementarity originates when an irrotational electric field and a solenoidal current density satisfying boundary conditions are in hand. We first compare three formulations to obtain a solenoidal current density, both in terms of pure computational advantage and in the ability to pursue symmetric energy bounds with respect to the standard electric scalar potential formulation. For these formulations, we devise post-processing techniques that promise to provide bilateral bounds in one stroke, hence requiring the solution of just one linear system.
Keywords :
Poisson equation; boundary-value problems; current density; electric fields; electrokinetic effects; Poisson-like problems; boundary value problems; electrokinetics; irrotational electric field; linear system; solenoidal current density; standard electric scalar potential formulation; stroke complementarity; symmetric energy bounds; Current density; Electric potential; Face; Linear systems; Matrix decomposition; Resistance; Resistors; Complementarity; Poisson problem; complementary-dual; error bounds; mixed-hybrid formulation;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2014.2358264
