Entropic sub-cell shock capturing schemes via Jin-Xin relaxation and glimm front sampling for scalar conservation laws

Frédéric Coquel; Shi Jin; Jian Guo Liu; Li Wang

doi:10.1090/mcom/3253

Entropic sub-cell shock capturing schemes via Jin-Xin relaxation and glimm front sampling for scalar conservation laws

Frédéric Coquel, Shi Jin, Jian Guo Liu, Li Wang

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2 Scopus citations

Abstract

We introduce a sub-cell shock capturing method for scalar conservation laws built upon the Jin-Xin relaxation framework. Here, sub-cell shock capturing is achieved using the original defect measure correction technique. The proposed method exactly restores entropy shock solutions of the exact Riemann problem and, moreover, it produces monotone and entropy satisfying approximate self-similar solutions. These solutions are then sampled using Glimm's random choice method to advance in time. The resulting scheme combines the simplicity of the Jin-Xin relaxation method with the resolution of the Glimm's scheme to achieve the sharp (no smearing) capturing of discontinuities. The benefit of using defect measure corrections over usual sub-cell shock capturing methods is that the scheme can be easily made entropy satisfying with respect to infinitely many entropy pairs. Consequently, under a classical CFL condition, the method is proved to converge to the unique entropy weak solution of the Cauchy problem for general non-linear flux functions. Numerical results show that the proposed method indeed captures shocks-including interacting shocks-sharply without any smearing.

Original language	English (US)
Pages (from-to)	1083-1126
Number of pages	44
Journal	Mathematics of Computation
Volume	87
Issue number	311
DOIs	https://doi.org/10.1090/mcom/3253
State	Published - 2018
Externally published	Yes

Bibliographical note

Funding Information:
The second author was partly supported by NSF grants DMS-1522184 and DMS-1107291 (RNMS:KI-Net), and NSFC grant No. 91330203. The research of the third author was partially supported by KI-Net NSF RNMS grant No. 1107444 and NSF grant DMS 0514826. The fourth author was partially supported by NSF grant DMS-1620135. Support for this research was also provided by the Office of the Vice Chancellor for Research and Graduate Education at the University of Wisconsin-Madison with funding from the Wisconsin Alumni Research Foundation.

Publisher Copyright:
© 2017 American Mathematical Society.

Keywords

Cell entropy condition
Conservation laws
Defect measure
Glimm's random choice
Relaxation
Riemann problem
Shock capturing methods

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title = "Entropic sub-cell shock capturing schemes via Jin-Xin relaxation and glimm front sampling for scalar conservation laws",

abstract = "We introduce a sub-cell shock capturing method for scalar conservation laws built upon the Jin-Xin relaxation framework. Here, sub-cell shock capturing is achieved using the original defect measure correction technique. The proposed method exactly restores entropy shock solutions of the exact Riemann problem and, moreover, it produces monotone and entropy satisfying approximate self-similar solutions. These solutions are then sampled using Glimm's random choice method to advance in time. The resulting scheme combines the simplicity of the Jin-Xin relaxation method with the resolution of the Glimm's scheme to achieve the sharp (no smearing) capturing of discontinuities. The benefit of using defect measure corrections over usual sub-cell shock capturing methods is that the scheme can be easily made entropy satisfying with respect to infinitely many entropy pairs. Consequently, under a classical CFL condition, the method is proved to converge to the unique entropy weak solution of the Cauchy problem for general non-linear flux functions. Numerical results show that the proposed method indeed captures shocks-including interacting shocks-sharply without any smearing.",

keywords = "Cell entropy condition, Conservation laws, Defect measure, Glimm's random choice, Relaxation, Riemann problem, Shock capturing methods",

author = "Fr{\'e}d{\'e}ric Coquel and Shi Jin and Liu, {Jian Guo} and Li Wang",

note = "Funding Information: The second author was partly supported by NSF grants DMS-1522184 and DMS-1107291 (RNMS:KI-Net), and NSFC grant No. 91330203. The research of the third author was partially supported by KI-Net NSF RNMS grant No. 1107444 and NSF grant DMS 0514826. The fourth author was partially supported by NSF grant DMS-1620135. Support for this research was also provided by the Office of the Vice Chancellor for Research and Graduate Education at the University of Wisconsin-Madison with funding from the Wisconsin Alumni Research Foundation. Publisher Copyright: {\textcopyright} 2017 American Mathematical Society.",

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AU - Coquel, Frédéric

AU - Jin, Shi

AU - Liu, Jian Guo

AU - Wang, Li

N1 - Funding Information: The second author was partly supported by NSF grants DMS-1522184 and DMS-1107291 (RNMS:KI-Net), and NSFC grant No. 91330203. The research of the third author was partially supported by KI-Net NSF RNMS grant No. 1107444 and NSF grant DMS 0514826. The fourth author was partially supported by NSF grant DMS-1620135. Support for this research was also provided by the Office of the Vice Chancellor for Research and Graduate Education at the University of Wisconsin-Madison with funding from the Wisconsin Alumni Research Foundation. Publisher Copyright: © 2017 American Mathematical Society.

PY - 2018

Y1 - 2018

N2 - We introduce a sub-cell shock capturing method for scalar conservation laws built upon the Jin-Xin relaxation framework. Here, sub-cell shock capturing is achieved using the original defect measure correction technique. The proposed method exactly restores entropy shock solutions of the exact Riemann problem and, moreover, it produces monotone and entropy satisfying approximate self-similar solutions. These solutions are then sampled using Glimm's random choice method to advance in time. The resulting scheme combines the simplicity of the Jin-Xin relaxation method with the resolution of the Glimm's scheme to achieve the sharp (no smearing) capturing of discontinuities. The benefit of using defect measure corrections over usual sub-cell shock capturing methods is that the scheme can be easily made entropy satisfying with respect to infinitely many entropy pairs. Consequently, under a classical CFL condition, the method is proved to converge to the unique entropy weak solution of the Cauchy problem for general non-linear flux functions. Numerical results show that the proposed method indeed captures shocks-including interacting shocks-sharply without any smearing.

AB - We introduce a sub-cell shock capturing method for scalar conservation laws built upon the Jin-Xin relaxation framework. Here, sub-cell shock capturing is achieved using the original defect measure correction technique. The proposed method exactly restores entropy shock solutions of the exact Riemann problem and, moreover, it produces monotone and entropy satisfying approximate self-similar solutions. These solutions are then sampled using Glimm's random choice method to advance in time. The resulting scheme combines the simplicity of the Jin-Xin relaxation method with the resolution of the Glimm's scheme to achieve the sharp (no smearing) capturing of discontinuities. The benefit of using defect measure corrections over usual sub-cell shock capturing methods is that the scheme can be easily made entropy satisfying with respect to infinitely many entropy pairs. Consequently, under a classical CFL condition, the method is proved to converge to the unique entropy weak solution of the Cauchy problem for general non-linear flux functions. Numerical results show that the proposed method indeed captures shocks-including interacting shocks-sharply without any smearing.

KW - Cell entropy condition

KW - Conservation laws

KW - Defect measure

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KW - Relaxation

KW - Riemann problem

KW - Shock capturing methods

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Entropic sub-cell shock capturing schemes via Jin-Xin relaxation and glimm front sampling for scalar conservation laws

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