: We are concerned with a special class of discretizations of general linear transmission problems stated in the calculus of differential forms and posed on Rn . In the spirit of domain decomposition, we partition Rn=Ω∪Γ∪Ω+ , Ω a bounded Lipschitz polyhedron, Γ:=∂Ω , and Ω+ unbounded. In Ω , we employ a mesh-based discrete co-chain model for differential forms, which includes schemes like finite element exterior calculus and discrete exterior calculus. In Ω+ , we rely on a meshless Trefftz-Galerkin approach, i.e., we use special solutions of the homogeneous PDE as trial and test functions. Our key contribution is a unified way to couple the different discretizations across Γ . Based on the theory of discrete Hodge operators, we derive the resulting linear system of equations. As a concrete application, we discuss an eddy-current problem in frequency domain, for which we also give numerical results.
Trefftz co-chain calculus
Codecasa, Lorenzo;
2022-01-01
Abstract
: We are concerned with a special class of discretizations of general linear transmission problems stated in the calculus of differential forms and posed on Rn . In the spirit of domain decomposition, we partition Rn=Ω∪Γ∪Ω+ , Ω a bounded Lipschitz polyhedron, Γ:=∂Ω , and Ω+ unbounded. In Ω , we employ a mesh-based discrete co-chain model for differential forms, which includes schemes like finite element exterior calculus and discrete exterior calculus. In Ω+ , we rely on a meshless Trefftz-Galerkin approach, i.e., we use special solutions of the homogeneous PDE as trial and test functions. Our key contribution is a unified way to couple the different discretizations across Γ . Based on the theory of discrete Hodge operators, we derive the resulting linear system of equations. As a concrete application, we discuss an eddy-current problem in frequency domain, for which we also give numerical results.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
