Yen‐Hsi Richard Tsai scite author profile

We derive a Godunov-type numerical flux for the class of strictly convex, homogeneous Hamiltonians that includes H(p, q) = ap 2 + bq 2 − 2cpq, c 2 < ab. We combine our Godunov numerical fluxes with simple GaussSeidel type iterations for solving the corresponding Hamilton-Jacobi Equations. The resulting algorithm is fast since it does not require a sorting strategy as found, e.g., in the fast marching method. In addition, it provides a way to compute solutions to a class of HJ equations for which the conventional fast marching method is not applicable. Our experiments indicate convergence after a few iterations, even in rather difficult cases.

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Threshold dynamics for the piecewise constant Mumford–Shah functional

Esedoḡlu

Tsai

2006

Journal of Computational Physics

176

173

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Geometric Optics in a Phase-Space-Based Level Set and Eulerian Framework

Osher

Cheng²,

Kang

et al. 2002

Journal of Computational Physics

111

165

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Heterogeneous multiscale methods for stiff ordinary differential equations

Engquist¹,

Tsai²

2005

Math. Comp.

148

152

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Abstract. The heterogeneous multiscale methods (HMM) is a general framework for the numerical approximation of multiscale problems. It is here developed for ordinary differential equations containing different time scales. Stability and convergence results for the proposed HMM methods are presented together with numerical tests. The analysis covers some existing methods and the new algorithms that are based on higher-order estimates of the effective force by kernels satisfying certain moment conditions and regularity properties. These new methods have superior computational complexity compared to traditional methods for stiff problems with oscillatory solutions.

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Computing multivalued physical observables for the semiclassical limit of the Schrödinger equation

Jin

Liu

Osher

et al. 2005

Journal of Computational Physics

133

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