Transmission operators for the non-overlapping Schwarz method for solving Helmholtz problems in rectangular cavities
Copyright policy )Transmission operators for the non-overlapping Schwarz method for solving Helmholtz problems in rectangular cavities
In this paper we discuss different transmission operators for the non-overlapping Schwarz method which are suited for solving the time-harmonic Helmholtz equation in cavities (i.e. closed domains which do not feature an outgoing wave condition). Such problems are heavily impacted by back-propagating waves which are often neglected when devising optimized transmission operators for the Schwarz method. This work explores new operators taking into account those back-propagating waves and compares them with well-established operators neglecting these contributions. Notably, this paper focuses on the case of rectangular cavities, as the optimal (non-local) transmission operator can be easily determined. Nonetheless, deviations from this ideal geometry are considered as well. In particular, computations of the acoustic noise in a three-dimensional model of the helium vessel of a beamline cryostat with optimized Schwarz schemes are discussed. Those computations show a reduction of 46% in the iteration count, when comparing an operator optimized for cavities with those optimized for unbounded problems.
37 pages, 23 figures. Changes with respect to the previous version: i) one more reference (original GMRES paper) and ii) fixing more typos. This version is published in Computers & Mathematics with Applications
- University of Liège Belgium
- Université de Liège (University of Liège) Belgium
- Université de Liège (ULiège) Belgium
- TU Darmstadt Germany
- Universié de Liège Belgium
Iterative numerical methods for linear systems, Helmholtz problems, Multigrid methods; domain decomposition for boundary value problems involving PDEs, Optimized Schwarz method, Physique, chimie, mathématiques & sciences de la terre, Schwarz method, Domain-decomposition methods, Helmholtz's equations, Physical, chemical, mathematical & earth Sciences, Optimized Schwarz methods, FOS: Mathematics, Domain decomposition method, Helmholtz equation, Mathematics - Numerical Analysis, domain decomposition method, cavity problem, Error bounds for boundary value problems involving PDEs, Computer Science - Numerical Analysis, Propagating waves, Numerical Analysis (math.NA), Stability and convergence of numerical methods for boundary value problems involving PDEs, Cavity problems, Transmission operators, Technical applications of optics and electromagnetic theory, Computational Mathematics, Mathématiques, Computational Theory and Mathematics, Modeling and Simulation, optimized Schwarz method, Rectangular cavity, Cavity problem, Overlapping Schwarz, Mathematics
Iterative numerical methods for linear systems, Helmholtz problems, Multigrid methods; domain decomposition for boundary value problems involving PDEs, Optimized Schwarz method, Physique, chimie, mathématiques & sciences de la terre, Schwarz method, Domain-decomposition methods, Helmholtz's equations, Physical, chemical, mathematical & earth Sciences, Optimized Schwarz methods, FOS: Mathematics, Domain decomposition method, Helmholtz equation, Mathematics - Numerical Analysis, domain decomposition method, cavity problem, Error bounds for boundary value problems involving PDEs, Computer Science - Numerical Analysis, Propagating waves, Numerical Analysis (math.NA), Stability and convergence of numerical methods for boundary value problems involving PDEs, Cavity problems, Transmission operators, Technical applications of optics and electromagnetic theory, Computational Mathematics, Mathématiques, Computational Theory and Mathematics, Modeling and Simulation, optimized Schwarz method, Rectangular cavity, Cavity problem, Overlapping Schwarz, Mathematics
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