Integral equations for the current density in thin conductors and their solution by the finite-element method

A direct superposition procedure is used in order to solve the problem of a generally cracked body: The regular field is generated by the finite element method whereas the singular field is by the singular integral equation method. This process, combined in a one-step technique, was applied to three

Finite element solutions of the Euler and Navier-Stokes equations are presented, using a simple dissipation model. The discretization is based on the weak-Galerkin weighted residual method and equal interpolation functions for all the unknowns are permitted. The nonlinearity is iterated upon using a

A domain decomposition method (DDM) is presented for the solution of the timeharmonic electromagnetic scattering problem by inhomogeneous 3-D objects. The computational domain is partitioned into concentric subdomains on the interfaces of which Robin-type transmission conditions are prescribed. On t

The problem of a branched crack in a finite sheet is considered in this paper. The solution is given by Schwarz's alternating method, using two sequences of solutions. The first sequence corresponds to the finite, but untracked, body, and the finite element method was used, whereas for the other seq