Numerical dissipation switch for two-dimensional central-upwind schemes

Kurganov, Alexander; Liu, Yongle; Zeitlin, Vladimir

doi:10.1051/m2an/2021009

Cited by 16 publications

(21 citation statements)

References 53 publications

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“…In this example, we consider the explosion problem studied in [8,16,18,27]. This is a circularly symmetric problem with an initial circular region of higher density and pressure with the following initial conditions, (ρ(x, y, 0), u(x, y, 0), v(x, y, 0), p(x, y, 0)) = (1, 0, 0, 1), x 2 + y 2 < 0.16, (0.125, 0, 0, 0.1), otherwise, prescribed in the computational domain [0, 1.5] × [0, 1.5].…”

Section: Example 6-explosion Problemmentioning

confidence: 99%

“…In this example, we consider the implosion problem taken from [8,16,18,27]. The initial conditions, (ρ(x, y, 0), u(x, y, 0), v(x, y, 0), p(x, y, 0)) = (0.125, 0, 0, 0.14…”

Section: Example 7-implosion Problemmentioning

confidence: 99%

“…This shows that the New CU scheme is capable of resolving the same details on a substantially coarser grid due to the smaller amount of numerical diffusion present in the scheme. In this example, we study the KH instability, which develops in the test problem taken from [5,6,8,16,32]. We take the following initial data:…”

Section: Example 7-implosion Problemmentioning

confidence: 99%

“…In the last example taken from [8,16,36,41], we investigate the RT instability, which is a physical phenomenon occurring when a layer of heavier fluid is placed on top of a layer of lighter fluid. The model is governed by the 2-D Euler equations (1.1), (B.1)-(B.2) with added gravitational source terms.…”

Section: Example 7-implosion Problemmentioning

confidence: 99%

“…Even though the CU schemes from [17,19] are quite accurate, efficient and robust tools for a wide variety of hyperbolic systems, higher resolution of the numerical solutions can be achieved by further reducing numerical dissipation. This can be done in a number of different ways, for example: (i) by introducing a more accurate evolution procedure, which leads to a "built-in" antidiffusion term [18]; (ii) by implementing a numerical dissipation switch to control the amount of numerical dissipation present in the CU schemes [16]; (iii) by obtaining more accurate estimates for the one-sided local speeds of propagation using the discrete Rankine-Hugoniot conditions [8].…”

Section: Introductionmentioning

confidence: 99%

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Local Characteristic Decomposition Based Central-Upwind Scheme

Chertock,

Chu,

Herty

et al. 2022

Preprint

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We propose novel less diffusive schemes for conservative one-and two-dimensional hyperbolic systems of nonlinear partial differential equations (PDEs). The main challenges in the development of accurate and robust numerical methods for the studied systems come from the complicated wave structures, such as shocks, rarefactions and contact discontinuities, arising even for smooth initial conditions. In order to reduce the diffusion in the original central-upwind schemes, we use a local characteristic decomposition procedure to develop a new class of central-upwind schemes. We apply the developed schemes to the one-and two-dimensional Euler equations of gas dynamics to illustrate the performance on a variety of examples. The obtained numerical results clearly demonstrate that the proposed new schemes outperform the original central-upwind schemes.

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Section: Example 6-explosion Problemmentioning

confidence: 99%

“…In this example, we consider the implosion problem taken from [8,16,18,27]. The initial conditions, (ρ(x, y, 0), u(x, y, 0), v(x, y, 0), p(x, y, 0)) = (0.125, 0, 0, 0.14…”

Section: Example 7-implosion Problemmentioning

confidence: 99%

Section: Example 7-implosion Problemmentioning

confidence: 99%

Section: Example 7-implosion Problemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Local Characteristic Decomposition Based Central-Upwind Scheme

Chertock,

Chu,

Herty

et al. 2022

Preprint

Self Cite

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Using Numerical Dissipation Rate and Viscosity to Assess Turbulence‐Related Data Accuracy – Part 1: Experimental Setup

Turek

Jegla

Dohnal

et al. 2022

Chemie Ingenieur Technik

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This is the first part of a two‐part paper focusing on the assessment of accuracy of turbulence‐related data from computational fluid dynamics (CFD) simulations using effective numerical dissipation rate and effective numerical viscosity. Setup of the CFD cases replicating a swirling pipe flow experiment from literature, for which turbulence‐related data measured via laser Doppler anemometry (LDA) had been reported, is presented. The way effective numerical dissipation rate and effective numerical viscosity were obtained for each mesh cell is also discussed. The results of the study are presented in the second part of this series.

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Experimental convergence rate study for three shock‐capturing schemes and development of highly accurate combined schemes

Chu

Ковыркина

Kurganov

et al. 2023

Numerical Methods Partial

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We study experimental convergence rates of three shock‐capturing schemes for hyperbolic systems of conservation laws: the second‐order central‐upwind (CU) scheme, the third‐order Rusanov‐Burstein‐Mirin (RBM), and the fifth‐order alternative weighted essentially non‐oscillatory (A‐WENO) scheme. We use three imbedded grids to define the experimental pointwise, integral, and convergence rates. We apply the studied schemes to the shallow water equations and conduct their comprehensive numerical convergence study. We verify that while the studied schemes achieve their formal orders of accuracy on smooth solutions, after the shock formation, a part of the computed solutions is affected by shock propagation and both the pointwise and integral convergence rates reduce there. Moreover, while the convergence rates for the CU and A‐WENO schemes, which rely on nonlinear stabilization mechanisms, reduce to the first order, the RBM scheme, which utilizes a linear stabilization, is clearly second‐order accurate. Finally, relying on the conducted experimental convergence rate study, we develop two new combined schemes based on the RBM and either the CU or A‐WENO scheme. The obtained combined schemes can achieve the same high order of accuracy as the RBM scheme in the smooth areas while being non‐oscillatory near the shocks.

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Numerical dissipation switch for two-dimensional central-upwind schemes

Cited by 16 publications

References 53 publications

Local Characteristic Decomposition Based Central-Upwind Scheme

Local Characteristic Decomposition Based Central-Upwind Scheme

Using Numerical Dissipation Rate and Viscosity to Assess Turbulence‐Related Data Accuracy – Part 1: Experimental Setup

Experimental convergence rate study for three shock‐capturing schemes and development of highly accurate combined schemes

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