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Full Description
Godunov-type schemes appear as good candidates for the next generation of commercial modelling software packages, the capability of which to handle discontinuous solution will be a basic requirement. It is in the interest of practising engineers and developers to be familiar with the specific features of discontinuous wave propagation problems and to be aware of the possibilities offered by Godunov-type schemes for their solution. This book aims to present the principles of such schemes in a way that is easily understandable to practising engineers. The features of hyperbolic conservation laws and their solutions are presented in the first two chapters. The principles of Godunov-type schemes are outlined in a third chapter. Chapters four and five cover the application of the original Godunov scheme to scalar laws and to hyperbolic systems of conservation laws respectively. Chapter six is devoted to higher-order schemes in one dimension of space. The design of such a scheme is described for the general case and applied to some well-known schemes such as the MUSCL and PPM schemes. Chapter seven focuses on multidimensional problems.
The classical alternate directions and finite volume approaches are presented together with the wave splitting technique that is described in depth with an application to two-dimensional systems. Chapter eight deals with large-time step algorithms. These include front tracking-based methods, explicit-implicit techniques and the time-line interpolation technique. Three appendices provide notions on accuracy and stability issues, Riemann solvers and the user instructions for the computational codes provided in the enclosed CD-ROM.
Contents
Scalar conservation laws; hyperbolic systems of conservation laws; an outline of Godunov-type schemes; the Godunov method for scalar laws in one dimension; the Godunov method for systems of conservation laws; higher-order schemes; multidimensional schemes; large-time-step algorithms; concluding remarks. Appendices: notions in mathematics; Riemann solvers; sample codes.
