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Discontinuous Galerkin Methods for Solving Acoustic Problems
Nytra, Jan ; Hlavička, Rudolf (oponent) ; Čermák, Libor (vedoucí práce)
Partial differential equations play an important role in engineering applications. It is often possible to solve these equations only approximately, i.e. numerically. Therefore number of successful discretization techniques has been developed to solve these equations. The presented discontinuous Galerkin method seems to be very general method to solve this type of equations, especially useful for hyperbolic systems. Our aim is to solve aeroacoustic problems, where propagation of acoustic waves is described using linearized Euler equations. This system of equations is indeed hyperbolic and therefore the discontinuous Galerkin method was chosen. The most important aspects of this method is ability to deal with complex geometries, possibility of high-order method and its local character enabling efficient computation parallelization. We first introduce the discontinuous Galerkin method in general for one- and two-dimensional problems. We then test the algorithm to solve advection equation, which was chosen as a model case of hyperbolic equation. The method will be finally tested using number of verification problems, which were formulated to test methods for computational equations, including verification of boundary conditions, which, similarly to computational fluid dynamics, are important part of computational aeroacoustics.
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Discontinuous Galerkin Methods for Solving Acoustic Problems
Nytra, Jan ; Hlavička, Rudolf (oponent) ; Čermák, Libor (vedoucí práce)
Partial differential equations play an important role in engineering applications. It is often possible to solve these equations only approximately, i.e. numerically. Therefore number of successful discretization techniques has been developed to solve these equations. The presented discontinuous Galerkin method seems to be very general method to solve this type of equations, especially useful for hyperbolic systems. Our aim is to solve aeroacoustic problems, where propagation of acoustic waves is described using linearized Euler equations. This system of equations is indeed hyperbolic and therefore the discontinuous Galerkin method was chosen. The most important aspects of this method is ability to deal with complex geometries, possibility of high-order method and its local character enabling efficient computation parallelization. We first introduce the discontinuous Galerkin method in general for one- and two-dimensional problems. We then test the algorithm to solve advection equation, which was chosen as a model case of hyperbolic equation. The method will be finally tested using number of verification problems, which were formulated to test methods for computational equations, including verification of boundary conditions, which, similarly to computational fluid dynamics, are important part of computational aeroacoustics.
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Programy a algoritmy numerické matematiky 12
Sborník obsahuje více než 30 příspěvků přednesených na semináři Programy a algoritmy numerické matematiky konaném v Dolním Maxově 6.-11. června 2004. Většina příspěvků se zabývá metodou konečných prvků a jejími aplikacemi. Jsou však zastoupena i další témata, např. konstrukce spline funkcí, algoritmy numerické lineární algebry nebo optimalizace.
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