A new flux splitting scheme for the Euler equations II: E-AUSMPWAS for all speeds

Feng Qu; Di Sun; Chao Yan

doi:10.1016/j.cnsns.2017.09.002

A new flux splitting scheme for the Euler equations II: E-AUSMPWAS for all speeds

Feng Qu, Di Sun, Chao Yan

School of Aeronautics

Beihang University

Research output: Contribution to journal › Article › peer-review

33 Scopus citations

Abstract

We propose a new scheme called E-AUSMPWAS (E-AUSMPW modified for all speeds) for both cases of low speeds and high speeds. This scheme adopts the Zha–Bilgen splitting procedure and constructs the mass flux as E-AUSMPW. Also, it improves the construction of the pressure flux for low speeds according to theoretical analyses. In terms of the component pu, the E-AUSMPWAS scheme adopts a different method to make it accord with theory better. Series of numerical experiments show that both E-AUSMPWAS and E-AUSMPW are robust against the shock anomaly and the unphysical ‘overheating’ phenomenon in the receding problem. Also, the E-AUSMPWAS scheme is with a high resolution at both high speeds and low speeds. These properties suggest that the E-AUSMPWAS scheme is promising to be widely used to accurately and efficiently simulate both simple and complex flows at all speeds.

Original language	English
Pages (from-to)	58-79
Number of pages	22
Journal	Communications in Nonlinear Science and Numerical Simulation
Volume	57
DOIs	https://doi.org/10.1016/j.cnsns.2017.09.002
State	Published - Apr 2018

Keywords

All speeds
Flux splitting
Overheating phenomenon
Shock anomaly

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10.1016/j.cnsns.2017.09.002

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title = "A new flux splitting scheme for the Euler equations II: E-AUSMPWAS for all speeds",

abstract = "We propose a new scheme called E-AUSMPWAS (E-AUSMPW modified for all speeds) for both cases of low speeds and high speeds. This scheme adopts the Zha–Bilgen splitting procedure and constructs the mass flux as E-AUSMPW. Also, it improves the construction of the pressure flux for low speeds according to theoretical analyses. In terms of the component pu, the E-AUSMPWAS scheme adopts a different method to make it accord with theory better. Series of numerical experiments show that both E-AUSMPWAS and E-AUSMPW are robust against the shock anomaly and the unphysical {\textquoteleft}overheating{\textquoteright} phenomenon in the receding problem. Also, the E-AUSMPWAS scheme is with a high resolution at both high speeds and low speeds. These properties suggest that the E-AUSMPWAS scheme is promising to be widely used to accurately and efficiently simulate both simple and complex flows at all speeds.",

keywords = "All speeds, Flux splitting, Overheating phenomenon, Shock anomaly",

author = "Feng Qu and Di Sun and Chao Yan",

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year = "2018",

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doi = "10.1016/j.cnsns.2017.09.002",

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T1 - A new flux splitting scheme for the Euler equations II

T2 - E-AUSMPWAS for all speeds

AU - Qu, Feng

AU - Sun, Di

AU - Yan, Chao

PY - 2018/4

Y1 - 2018/4

N2 - We propose a new scheme called E-AUSMPWAS (E-AUSMPW modified for all speeds) for both cases of low speeds and high speeds. This scheme adopts the Zha–Bilgen splitting procedure and constructs the mass flux as E-AUSMPW. Also, it improves the construction of the pressure flux for low speeds according to theoretical analyses. In terms of the component pu, the E-AUSMPWAS scheme adopts a different method to make it accord with theory better. Series of numerical experiments show that both E-AUSMPWAS and E-AUSMPW are robust against the shock anomaly and the unphysical ‘overheating’ phenomenon in the receding problem. Also, the E-AUSMPWAS scheme is with a high resolution at both high speeds and low speeds. These properties suggest that the E-AUSMPWAS scheme is promising to be widely used to accurately and efficiently simulate both simple and complex flows at all speeds.

AB - We propose a new scheme called E-AUSMPWAS (E-AUSMPW modified for all speeds) for both cases of low speeds and high speeds. This scheme adopts the Zha–Bilgen splitting procedure and constructs the mass flux as E-AUSMPW. Also, it improves the construction of the pressure flux for low speeds according to theoretical analyses. In terms of the component pu, the E-AUSMPWAS scheme adopts a different method to make it accord with theory better. Series of numerical experiments show that both E-AUSMPWAS and E-AUSMPW are robust against the shock anomaly and the unphysical ‘overheating’ phenomenon in the receding problem. Also, the E-AUSMPWAS scheme is with a high resolution at both high speeds and low speeds. These properties suggest that the E-AUSMPWAS scheme is promising to be widely used to accurately and efficiently simulate both simple and complex flows at all speeds.

KW - All speeds

KW - Flux splitting

KW - Overheating phenomenon

KW - Shock anomaly

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DO - 10.1016/j.cnsns.2017.09.002

M3 - 文章

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SN - 1007-5704

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JO - Communications in Nonlinear Science and Numerical Simulation

JF - Communications in Nonlinear Science and Numerical Simulation

ER -

A new flux splitting scheme for the Euler equations II: E-AUSMPWAS for all speeds

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Keywords

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