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MA5251: Spectral Methods & Applications. Weizhu Bao Department of Mathematics & Center for Computational Science and Engineering National University of Singapore Email: bao@math.nus.edu.sg URL: http://www.math.nus.edu.sg/~bao. Contents. Introduction and Preliminaries
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MA5251: Spectral Methods & Applications Weizhu Bao Department of Mathematics & Center for Computational Science and Engineering National University of Singapore Email: bao@math.nus.edu.sg URL: http://www.math.nus.edu.sg/~bao
Contents • Introduction and Preliminaries • Some numerical examples • Review of different numerical methods of PDE • Historical background of spectral methods • Some examples of spectral methods • Fourier series and orthogonal polynomials • Review of iterative solvers and preconditioning • Review of time discretization methods • Spectral-Collocation Methods • Introduction • Differentiation matrices • Fourier, Chebyshev collocation methods
Contents • Spectral-Galerkin methods • Introduction • Fourier spectral method • Legendre spectral method • Chebyshev spectral method • Error estimates • Spectral methods in unbounded domains • Introduction • Hermite spectral method • Laguerre specreal methods,….
Contents • Applications • In fluid dynamics • In heat transfer • In material sciences • In quantum physics and nonlinear optics • In plasma and particle physics • In biology • …………..
Main numerical methods for PDEs • Finite difference method (FDM) – MA5233 • Advantages: • Simple and easy to design the scheme • Flexible to deal with the nonlinear problem • Widely used for elliptic, parabolic and hyperbolic equations • Most popular method for simple geometry, …. • Disadvantages: • Not easy to deal with complex geometry • Not easy for complicated boundary conditions • ……..
Main numerical methods • Finite element method (FEM) – MA5240 • Advantages: • Flexible to deal with problems with complex geometry and complicated boundary conditions • Keep physical laws in the discretized level • Rigorous mathematical theory for error analysis • Widely used in mechanical structure analysis, computational fluid dynamics (CFD), heat transfer, electromagnetics, … • Disadvantages: • Need more mathematical knowledge to formulate a good and equivalent variational form
Main numerical methods • Spectral method – This module • High (spectral) order of accuracy • Usually restricted for problems with regular geometry • Widely used for linear elliptic and parabolic equations on regular geometry • Widely used in quantum physics, quantum chemistry, material sciences, … • Not easy to deal with nonlinear problem • Not easy to deal with hyperbolic problem • …..
Main numerical methods • Finite volume method (FVM) – MA5250 • Flexible to deal with problems with complex geometry and complicated boundary conditions • Keep physical laws in the discretized level • Widely used in CFD • Boundary element method (BEM) • Reduce a problem in one less dimension • Restricted to linear elliptic and parabolic equations • Need more mathematical knowledge to find a good and equivalent integral form • Very efficient fast Poisson solver when combined with the fast multipole method (FMM), …..
Historical background • Method of weighted residuals (MWR) – Finlayson & Scriven (1966) • Trial functions (or expansion or approximation functions): are used as the basis functions for a truncated series expansion of the solution. • Test functions (or weight functions): are used to ensure that the differential equation is satisfied as closely as possible by the truncated series expansion. • This is achieved by minimizing the residual, i.e. the error in the differential equation produced by using the truncated expansion instead of the exact solution, with respect to a suitable norm. • An equivalent requirement is that the residual satisfy a suitable orthogonality condition with respect to each of the test functions.
Historical background • Trial functions • Spectral method: infinitely differentiable global functions, i.e. eigenfunctions of singular Sturm-Liouville problems • Finite Element Method (FEM): partition the domain into small elements, and a trial function (usually polynomial) is specified in each element and thus local in character & well suited for handling complex geometries. • Finite Difference Method (FDM): similar as FEM. • Test functions • Spectral methods: three different ways • FEM: similar as trial functions • FDM: Dirac delta functions centered at the grid points
Historical background • Different test functions of spectral methods • Galerkin method: same as the trial functions which are infinitely smooth functions & individually satisfy the boundary conditions. The differential equation is enforced by requiring that the integral of the residual times each test function be zero. • Collocation method: Dirac delta functions centered at the collocation points. The differential is required to be satisfied exactly at the collocation points. • Spectral tau method: Similar as the Galerkin method except that no need the trial and test functions satisfy the boundary conditions. A supplementary set of equations is used to apply the boundary conditions.
Historical background • Collocation approach (simplest of the MWR) –Slater (1934); Kantorovic (1934); Frazer, Jones and Skan (1937). • Proper choice of trial functions and distribution of collocation points – Lanczos (1938) • Orthogonal collocation method – Clenshaw (1957); Clenshaw and Norton (1963); Wright (1964). • Earliest application of spectral methods to PDE – Kreiss and Oliger (1972)—Fourier method; Orszag (1972) –pseudospectral. • Spectral-Galerkin method – Silberman (1954) in meteorological modeling; Orszag (1969, 1970); etc.
Historical background • Theory of spectral method -- Gottlieb and Orszag (1977) • Symposium Proceedings – Voigt, Gottlieb and Hussaini (1984) • First International Conference on Spectral and High Order Methods (ICOSAHOM) -- Como, Italy in 1989. It becomes series conference every three years. The next one is http://www.math.ntnu.no/icosahom/