Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
162 tokens/sec
GPT-4o
7 tokens/sec
Gemini 2.5 Pro Pro
45 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
38 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

High order Well-Balanced Arbitrary-Lagrangian-Eulerian ADER discontinuous Galerkin schemes on general polygonal moving meshes (2403.10917v1)

Published 16 Mar 2024 in math.NA and cs.NA

Abstract: In this work, we present a novel family of high order accurate numerical schemes for the solution of hyperbolic partial differential equations (PDEs) which combines several geometrical and physical structure preserving properties. First, we settle our methods in the Lagrangian framework, where each element of the mesh evolves following as close as possible the local fluid flow, so to reduce the numerical dissipation at contact waves and moving interfaces and to satisfy the Galilean and rotational invariance properties of the studied PDEs system. In particular, we choose the direct Arbitrary-Lagrangian-Eulerian (ALE) approach which, in order to always guarantee the high quality of the moving mesh, allows to combine the Lagrangian motion with mesh optimization techniques. The employed polygonal tessellation is thus regenerated at each time step, the previous one is connected with the new one by space-time control volumes, including hole-like sliver elements in correspondence of topology changes, over which we integrate a space-time divergence form of the original PDEs through a high order accurate ADER discontinuous Galerkin (DG) scheme. Mass conservation and adherence to the GCL condition are guaranteed by construction thanks to the integration over closed control volumes, and robustness over shock discontinuities is ensured by the use of an a posteriori subcell finite volume (FV) limiting technique.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (175)
  1. R. Abgrall and M. Ricchiuto. Hyperbolic balance laws: residual distribution, local and global fluxes. Numerical Fluid Dynamics, pages 177–222, 2022.
  2. R. Abgrall and R. Saurel. Discrete equations for physical and numerical compressible multiphase mixtures. Journal of Computational Physics, 186:361–396, 2003.
  3. High-order multi-material ALE hydrodynamics. SIAM Journal on Scientific Computing, 40(1):B32–B58, 2018.
  4. P.F. Antonietti and E. Manuzzi. Refinement of polygonal grids using convolutional neural networks with applications to polygonal discontinuous galerkin and virtual element methods. Journal of Computational Physics, 452:110900, 2022.
  5. L. Arpaia and M. Ricchiuto. Well balanced residual distribution for the ALE spherical shallow water equations on moving adaptive meshes. Journal of Computational Physics, 405:109173, 2020.
  6. A fast and stable well-balanced scheme with hydrostatic reconstruction for shallow water flows. SIAM Journal on Scientific Computing, 25(6):2050–2065, 2004.
  7. A two-phase mixture theory for the deflagration-to-detonation transition (DDT) in reactive granular materials. J. Multiphase Flow, 12:861–889, 1986.
  8. D.S. Balsara. Second-Order Accurate Schemes for Magnetohydrodynamics with Divergence-Free Reconstruction. The Astrophysical Journal Supplement Series, 151:149–184, 2004.
  9. A Staggered Mesh Algorithm Using High Order Godunov Fluxes to Ensure Solenoidal Magnetic Fields in Magnetohydrodynamic Simulations. Journal of Computational Physics, 149:270–292, 1999.
  10. Arbitrary Lagrangian–Eulerian methods for modeling high-speed compressible multimaterial flows. Journal of Computational Physics, 322:603–665, 2016.
  11. A neural network based shock detection and localization approach for discontinuous Galerkin methods. Journal of Computational Physics, 423:109824, 2020.
  12. High order well-balanced finite volume methods for multi-dimensional systems of hyperbolic balance laws. Computers & Fluids, 219:104858, 2021.
  13. Numerical solution of non-isothermal non-adiabatic flow of real gases in pipelines. Journal of Computational Physics, 323:126–148, 2016.
  14. A. Bermudez and M.E. Vazquez. Upwind methods for hyperbolic conservation laws with source terms. Computers & Fluids, 23(8):1049–1071, 1994.
  15. Two–step hybrid conservative remapping for multimaterial arbitrary Lagrangian–Eulerian methods. Journal of Computational Physics, 230:6664–6687, 2011.
  16. A Well-Balanced Semi-implicit IMEX Finite Volume Scheme for Ideal Magnetohydrodynamics at All Mach Numbers. Journal of Scientific Computing, 98:34, 2024.
  17. W. Bo and M.J. Shashkov. Adaptive reconnection-based arbitrary Lagrangian Eulerian method. Journal of Computational Physics, 299:902–939, 2015.
  18. Fast optimization-based conservative remap of scalar fields through aggregate mass transfer. Journal of Computational Physics, 246:37–57, 2013.
  19. A cell-centered implicit-explicit Lagrangian scheme for a unified model of nonlinear continuum mechanics on unstructured meshes. Journal of Computational Physics, 451:110852, 2022.
  20. W. Boscheri and M. Dumbser. Arbitrary–Lagrangian–Eulerian One–Step WENO Finite Volume Schemes on Unstructured Triangular Meshes. Communications in Computational Physics, 14:1174–1206, 2013.
  21. W. Boscheri and M. Dumbser. A direct Arbitrary-Lagrangian-Eulerian ADER-WENO finite volume scheme on unstructured tetrahedral meshes for conservative and non-conservative hyperbolic systems in 3d. Journal of Computational Physics, 275:484 – 523, 2014.
  22. W. Boscheri and M. Dumbser. High order accurate direct Arbitrary-Lagrangian-Eulerian ADER-WENO finite volume schemes on moving curvilinear unstructured meshes. Computers and Fluids, 136:48–66, 2016.
  23. Continuous Finite Element Subgrid Basis Functions for Discontinuous Galerkin Schemes on Unstructured Polygonal Voronoi Meshes. Communications in Computational Physics, 32(1):259–298, 2022.
  24. High order cell-centered Lagrangian-type finite volume schemes with time-accurate local time stepping on unstructured triangular meshes. Journal of Computational Physics, 291:120–150, 2015.
  25. W. Boscheri and R. Loubère. High order accurate direct Arbitrary-Lagrangian-Eulerian ADER-MOOD finite volume schemes for non-conservative hyperbolic systems with stiff source terms. Communications in Computational Physics, 21:271–312, 2017.
  26. Direct Arbitrary-Lagrangian-Eulerian ADER-MOOD finite volume schemes for multidimensional hyperbolic conservation laws. Journal of Computational Physics, 292:56–87, 2015.
  27. Well balanced finite volume methods for nearly hydrostatic flows. Journal of Computational Physics, 196(2):539–565, 2004.
  28. F. Bouchut. Nonlinear stability of finite Volume Methods for hyperbolic conservation laws: And Well-Balanced schemes for sources. Springer Science & Business Media, 2004.
  29. A. Bowyer. Computing dirichlet tessellations. The computer journal, 24(2):162–166, 1981.
  30. Dynamo action in thick discs around Kerr black holes: high-order resistive GRMHD simulations. Monthly Notices of the Royal Astronomical Society: Letters, 440(1):L41–L45, 2014.
  31. High order ADER schemes for continuum mechanics. Frontiers in Physics, 8:32, 2020.
  32. On high order ader discontinuous galerkin schemes for first order hyperbolic reformulations of nonlinear dispersive systems. Journal of Scientific Computing, 87(2):48, 2021.
  33. J. C. Butcher. A history of runge-kutta methods. Applied numerical mathematics, 20(3):247–260, 1996.
  34. E.J. Caramana. The implementation of slide lines as a combined force and velocity boundary condition. Journal of Computational Physics, 228:3911–3916, 2009.
  35. M.G. Carlino and E. Gaburro. Well balanced finite volume schemes for shallow water equations on manifolds. Applied Mathematics and Computation, 441:127676, 2023.
  36. Well-balanced high order extensions of godunov's method for semilinear balance laws. SIAM Journal of Numerical Analysis, 46:1012–1039, 2008.
  37. High-order finite volume schemes based on reconstruction of states for solving hyperbolic systems with nonconservative products. Applications to shallow-water systems. Mathematics of Computation, 75:1103–1134, 2006.
  38. Well-balanced numerical schemes based on a generalized hydrostatic reconstruction technique. Mathematical Models and Methods in Applied Sciences, 17(12):2055–2113, 2007.
  39. M.J. Castro and C. Parés. Well-balanced high-order finite volume methods for systems of balance laws. Journal of Scientific Computing, 82(2):1–48, 2020.
  40. A conservative finite volume scheme with time-accurate local time stepping for scalar transport on unstructured grids. Advances in water resources, 86:217–230, 2015.
  41. P. Chandrashekar and C. Klingenberg. A second order well-balanced finite volume scheme for Euler equations with gravity. SIAM Journal on Scientific Computing, 37(3):B382–B402, 2015.
  42. S. Chiocchetti and M. Dumbser. An Exactly Curl-Free Staggered Semi-Implicit Finite Volume Scheme for a First Order Hyperbolic Model of Viscous Two-Phase Flows with Surface Tension. Journal of Scientific Computing, 94, 2023.
  43. High order ADER schemes and GLM curl cleaning for a first order hyperbolic formulation of compressible flow with surface tension. Journal of Computational Physics, 426:109898, 2021.
  44. Shifted boundary polynomial corrections for compressible flows: high order on curved domains using linear meshes. Applied Mathematics and Computation, 441:127698, 2023.
  45. A high-order finite volume method for systems of conservation laws—Multi-dimensional Optimal Order Detection (MOOD). Journal of Computational Physics, 230(10):4028–4050, 2011.
  46. The Runge-Kutta local projection discontinuous Galerkin finite element method for conservation laws. IV. The multidimensional case. Mathematics of Computation, 54(190):545–581, 1990.
  47. The development of discontinuous Galerkin methods. In Discontinuous Galerkin Methods, pages 3–50. Springer, 2000.
  48. B. Cockburn and C.-W. Shu. Runge–Kutta discontinuous Galerkin methods for convection-dominated problems. Journal of scientific computing, 16(3):173–261, 2001.
  49. A lagrangian finite element approach for the analysis of fluid–structure interaction problems. International Journal for Numerical Methods in Engineering, 84(5):610–630, 2010.
  50. An explicit lagrangian finite element method for free-surface weakly compressible flows. Computational Particle Mechanics, 4(3):357–369, 2017.
  51. R. Davies-Jones. Comments on “A kinematic analysis of frontogenesis associated with a nondivergent vortex.”. J. Atmos. Sci, 42(19):2073–2075, 1985.
  52. J. Núñez de la Rosa and C.-D. Munz. Hybrid DG/FV schemes for magnetohydrodynamics and relativistic hydrodynamics. Computer Physics Communications, 222:113 – 135, 2018.
  53. Hyperbolic divergence cleaning for the MHD equations. Journal of Computational Physics, 175:645–673, 2002.
  54. ECHO: a Eulerian conservative high-order scheme for general relativistic magnetohydrodynamics and magnetodynamics. Astronomy & Astrophysics, 473(1):11–30, 2007.
  55. Optimization-based mesh correction with volume and convexity constraints. Journal of Computational Physics, 313:455–477, 2016.
  56. B. Després. Numerical methods for Eulerian and Lagrangian conservation laws. Birkhäuser, 2017.
  57. B. Després. Lagrangian voronoï meshes and particle dynamics with shocks. Computer Methods in Applied Mechanics and Engineering, 418:116427, 2024.
  58. A well-balanced scheme to capture non-explicit steady states in the Euler equations with gravity. International Journal for Numerical Methods in Fluids, 81(2):104–127, 2016.
  59. Simulation-driven optimization of high-order meshes in ALE hydrodynamics. Computers & Fluids, 208:104602, 2020.
  60. Curvilinear finite elements for Lagrangian hydrodynamics. International Journal for Numerical Methods in Fluids, 65:1295–1310, 2011.
  61. High order curvilinear finite elements for Lagrangian hydrodynamics. SIAM Journal on Scientific Computing, 34:606–641, 2012.
  62. High-order curvilinear finite elements for axisymmetric lagrangian hydrodynamics. Computers & Fluids, 83(0):58 – 69, 2013.
  63. High order curvilinear finite elements for axisymmetric Lagrangian hydrodynamics. Computers and Fluids, 83:58–69, 2013.
  64. M. Dumbser. A simple two-phase method for the simulation of complex free surface flows. Computer Methods in Applied Mechanics and Engineering, 200:1204–1219, 2011.
  65. M. Dumbser. A Diffuse Interface Method for Complex Three-Dimensional Free Surface Flows. Computer Methods in Applied Mechanics and Engineering, 257:47–64, 2013.
  66. A unified framework for the construction of one-step finite volume and discontinuous Galerkin schemes on unstructured meshes. Journal of Computational Physics, 227(18):8209–8253, 2008.
  67. On GLM curl cleaning for a first order reduction of the CCZ4 formulation of the Einstein field equations. Journal of Computational Physics, 404:109088, 2020.
  68. Conformal and covariant Z4 formulation of the Einstein equations: strongly hyperbolic first-order reduction and solution with discontinuous Galerkin schemes. Physical Review D, 97(8):084053, 2018.
  69. M. Dumbser and M. Käser. Arbitrary high order non-oscillatory finite volume schemes on unstructured meshes for linear hyperbolic systems. Journal of Computational Physics, 221(2):693–723, 2007.
  70. M. Dumbser and R. Loubère. A simple robust and accurate a posteriori sub-cell finite volume limiter for the discontinuous Galerkin method on unstructured meshes. Journal of Computational Physics, 319:163–199, 2016.
  71. High order ADER schemes for a unified first order hyperbolic formulation of continuum mechanics: Viscous heat–conducting fluids and elastic solids. Journal of Computational Physics, 314:824–862, 2016.
  72. High order ADER schemes for a unified first order hyperbolic formulation of Newtonian continuum mechanics coupled with electro–dynamics. Journal of Computational Physics, 348:298–342, 2017.
  73. M. Dumbser and E. F. Toro. On Universal Osher–Type Schemes for General Nonlinear Hyperbolic Conservation Laws. Communications in Computational Physics, 10:635–671, 2011.
  74. A posteriori subcell limiting of the discontinuous Galerkin finite element method for hyperbolic conservation laws. Journal of Computational Physics, 278:47–75, 2014.
  75. A well-balanced discontinuous galerkin method for the first–order z4 formulation of the einstein–euler system. Journal of Computational Physics, page 112875, 2024.
  76. ADER discontinuous Galerkin schemes for general-relativistic ideal magnetohydrodynamics. Monthly Notices of the Royal Astronomical Society, 477(4):4543–4564, 2018.
  77. A well-balanced and exactly divergence-free staggered semi-implicit hybrid finite volume / finite element scheme for the incompressible MHD equations. Journal of Computational Physics, 493:112493, 2023.
  78. A unified first-order hyperbolic model for nonlinear dynamic rupture processes in diffuse fracture zones. Philosophical Transactions of the Royal Society A, 379(2196):20200130, 2021.
  79. E. Gaburro. A unified framework for the solution of hyperbolic PDE systems using high order direct Arbitrary-Lagrangian–Eulerian schemes on moving unstructured meshes with topology change. Archives of Computational Methods in Engineering, 28(3):1249–1321, 2021.
  80. High order direct arbitrary-lagrangian-eulerian schemes on moving voronoi meshes with topology changes. Journal of Computational Physics, 407:109167, 2020.
  81. Well-balanced Arbitrary-Lagrangian-Eulerian finite volume schemes on moving nonconforming meshes for the Euler equations of gas dynamics with gravity. Monthly Notices of the Royal Astronomical Society, 477(2):2251–2275, 2018.
  82. A well balanced diffuse interface method for complex nonhydrostatic free surface flows. Computers & Fluids, 175:180–198, 2018.
  83. A well balanced finite volume scheme for general relativity. SIAM Journal on Scientific Computing, 43(6):B1226–B1251, 2021.
  84. E. Gaburro and S. Chiocchetti. High-order Arbitrary-Lagrangian-Eulerian schemes on crazy moving Voronoi meshes. In Young Researchers Conference, pages 99–119. Springer, 2021.
  85. E. Gaburro and M. Dumbser. A Posteriori Subcell Finite Volume Limiter for General PNPM Schemes: Applications from Gasdynamics to Relativistic Magnetohydrodynamics. Journal of Scientific Computing, 86(3):1–41, 2021.
  86. Direct Arbitrary-Lagrangian-Eulerian finite volume schemes on moving nonconforming unstructured meshes. Computers & Fluids, 159:254–275, 2017.
  87. Shock capturing for a high-order ALE discontinuous Galerkin method with applications to fluid flows in time-dependent domains. Computers & Fluids, 269:106124, 2024.
  88. D. Ghosh and E.M. Constantinescu. Well-Balanced, Conservative Finite Difference Algorithm for Atmospheric Flows. AIAA Journal, 54(4):1370–1385, 2016.
  89. S.K. Godunov. Finite Difference Methods for the Computation of Discontinuous Solutions of the Equations of Fluid Dynamics. Mathematics of the USSR: Sbornik, 47:271–306, 1959.
  90. High-order well-balanced methods for systems of balance laws: a control-based approach. Applied Mathematics and Computation, 394:125820, 2021.
  91. L. Gosse. A well-balanced scheme using non-conservative products designed for hyperbolic systems of conservation laws with source terms. Mathematical Models and Methods in Applied Sciences, 11(02):339–365, 2001.
  92. L. Grosheintz-Laval and R. Käppeli. High-order well-balanced finite volume schemes for the euler equations with gravitation. Journal of Computational Physics, 378:324–343, 2019.
  93. Second-order invariant domain preserving approximation of the Euler equations using convex limiting. SIAM Journal on Scientific Computing, 40(5):A3211–A3239, 2018.
  94. Invariant domain preserving discretization-independent schemes and convex limiting for hyperbolic systems. Computer Methods in Applied Mechanics and Engineering, 347:143–175, 2019.
  95. A second-order well-balanced finite volume scheme for the multilayer shallow water model with variable density. Mathematics, 8(5):848, 2020.
  96. Well-Balanced High-Order Discontinuous Galerkin Methods for Systems of Balance Laws. Mathematics, 10(01):15, 2021.
  97. High-order magnetohydrodynamics for astrophysics with an adaptive mesh refinement discontinuous Galerkin scheme. Monthly Notices of the Royal Astronomical Society, 485(3):4209–4246, 2019.
  98. New directional vector limiters for discontinuous Galerkin methods. Journal of Computational Physics, 384:308–325, 2019.
  99. Dec and ader: similarities, differences and a unified framework. Journal of Scientific Computing, 87(1):1–35, 2021.
  100. Uniformly high order essentially non-oscillatory schemes, III. Journal of Computational Physics, 71:231–303, 1987.
  101. On upstream differencing and Godunov-type schemes for hyperbolic conservation laws. SIAM Review, 25(1):35–61, 1983.
  102. A. Hidalgo and M. Dumbser. ADER schemes for nonlinear systems of stiff advection–diffusion–reaction equations. Journal of Scientific Computing, 48(1-3):173–189, 2011.
  103. C. Hu and C.W. Shu. A high-order WENO finite difference scheme for the equations of ideal magnetohydrodynamics. Journal of Computational Physics, 150:561 – 594, 1999.
  104. H. Jackson and N. Nikiforakis. A numerical scheme for non-Newtonian fluids and plastic solids under the GPR model. Journal of Computational Physics, 387:410–429, 2019.
  105. Well-Balanced Central Scheme for the System of MHD Equations with Gravitational Source Term. Communications in Computational Physics, 32(3):878–898, 2022.
  106. R. Käppeli and S. Mishra. Well-balanced schemes for the Euler equations with gravitation. Journal of Computational Physics, 259:199–219, 2014.
  107. R. Käppeli and S. Mishra. A well-balanced finite volume scheme for the euler equations with gravitation-the exact preservation of hydrostatic equilibrium with arbitrary entropy stratification. Astronomy & Astrophysics, 587:A94, 2016.
  108. A simple diffuse interface approach for compressible flows around moving solids of arbitrary shape based on a reduced Baer–Nunziato model. Computers & fluids, 204:104536, 2020.
  109. A positivity-preserving and conservative intersection-distribution-based remapping algorithm for staggered ale hydrodynamics on arbitrary meshes. Journal of Computational Physics, 435:110254, 2021.
  110. Unified description of fluids and solids in Smoothed Particle Hydrodynamics. Applied Mathematics and Computation, 439:127579, 2023.
  111. Arbitrary order finite volume well-balanced schemes for the Euler equations with gravity. SIAM Journal on Scientific Computing, 41(2):A695–A721, 2019.
  112. Reference Jacobian optimization-based rezone strategies for arbitrary Lagrangian Eulerian methods. Journal of Computational Physics, 176(1):93–128, 2002.
  113. Shock detection and limiting with discontinuous Galerkin methods for hyperbolic conservation laws. Applied Numerical Mathematics, 48(3-4):323–338, 2004.
  114. Enhancement of Lagrangian slide lines as a combined force and velocity boundary condition. Computers & Fluids, 83:3–14, 2013.
  115. D. Kuzmin. Entropy stabilization and property-preserving limiters for p1 discontinuous galerkin discretizations of scalar hyperbolic problems. Journal of Numerical Mathematics, 29(4):307–322, 2021.
  116. D. Kuzmin. A new perspective on flux and slope limiting in discontinuous galerkin methods for hyperbolic conservation laws. Computer Methods in Applied Mechanics and Engineering, 373:113569, 2021.
  117. Limiter-based entropy stabilization of semi-discrete and fully discrete schemes for nonlinear hyperbolic problems. Computer Methods in Applied Mechanics and Engineering, 389:114428, 2022.
  118. Dmitri Kuzmin. Gradient-based limiting and stabilization of continuous Galerkin methods. Springer, 2020.
  119. A high order positivity-preserving polynomial projection remapping method. Journal of Computational Physics, 474:111826, 2023.
  120. R.J. LeVeque. Balancing source terms and flux gradients in high-resolution Godunov methods: the quasi-steady wave-propagation algorithm. Journal of computational physics, 146(1):346–365, 1998.
  121. Review of smoothed particle hydrodynamics: towards converged lagrangian flow modelling. Proceedings of the royal society A, 476(2241):20190801, 2020.
  122. R. Liska and B. Wendroff. Comparison of several difference schemes on 1D and 2D test problems for the Euler equations. SIAM Journal on Scientific Computing, 25(3):995–1017, 2003.
  123. High order conservative Lagrangian schemes with Lax–Wendroff type time discretization for the compressible Euler equations. Journal of Computational Physics, 228:8872–8891, 2009.
  124. A new family of high order unstructured MOOD and ADER finite volume schemes for multidimensional systems of hyperbolic conservation laws. Communications in Computational Physics, 16(3):718–763, 2014.
  125. ReALE: A Reconnection Arbitrary-Lagrangian–Eulerian method in cylindrical geometry. Computers and Fluids, 46:59–69, 2011.
  126. ReALE: A reconnection-based arbitrary-Lagrangian–Eulerian method. Journal of Computational Physics, 229:4724–4761, 2010.
  127. R. Loubère and M.J. Shashkov. A subcell remapping method on staggered polygonal grids for arbitrary–lagrangian–eulerian methods. Journal of Computational Physics, 23:155–160, 2004.
  128. P.H. Maire. A unified sub-cell force-based discretization for cell-centered Lagrangian hydrodynamics on polygonal grids. International Journal for Numerical Methods in Fluids, 65:1281–1294, 2011.
  129. Y. Mantri and S. Noelle. Well-balanced discontinuous galerkin scheme for 2×\times× 2 hyperbolic balance law. Journal of Computational Physics, 429:110011, 2021.
  130. A sub-element adaptive shock capturing approach for discontinuous Galerkin methods. Communications on Applied Mathematics and Computation, pages 1–43, 2021.
  131. Efficient iterative arbitrary high-order methods: an adaptive bridge between low and high order. Communications on Applied Mathematics and Computation, pages 1–38, 2023.
  132. A well–balanced scheme for the shallow-water equations with topography. Computers & Mathematics with Applications, 72(3):568–593, 2016.
  133. Arbitrary High Order Methods for Conservation Laws I: The One Dimensional Scalar Case. PhD thesis, Manchester Metropolitan University, Department of Computing and Mathematics, June 1999.
  134. On the origins of Lagrangian hydrodynamic methods. Nuclear Technology, 207(sup1):S147–S175, 2021.
  135. Fast randomized point location without preprocessing in two-and three-dimensional Delaunay triangulations. Computational Geometry, 12(1-2):63–83, 1999.
  136. A sharp interface framework based on the inviscid Godunov-Peshkov-Romenski equations: Simulation of evaporating fluids. Journal of Computational Physics, 473:111737, 2023.
  137. C.D. Munz. On Godunov–type schemes for Lagrangian gas dynamics. SIAM Journal on Numerical Analysis, 31:17–42, 1994.
  138. Well-balanced finite volume schemes of arbitrary order of accuracy for shallow water flows. Journal of Computational Physics, 213:474–499, 2006.
  139. High-order well-balanced finite volume WENO schemes for shallow water equation with moving water. Journal of Computational Physics, 226:29–58, 2007.
  140. S. Osher and F. Solomon. Upwind Difference Schemes for Hyperbolic Conservation Laws. Math. Comput., 38:339–374, 1982.
  141. CD. Munz P. Mossier, A. Beck. A p-adaptive discontinuous galerkin method with hp-shock capturing. Journal of Scientific Computing, 91, 2022.
  142. C. Parés. Numerical methods for nonconservative hyperbolic systems: a theoretical framework. SIAM Journal on Numerical Analysis, 44:300–321, 2006.
  143. P.-O. Persson and J. Peraire. Sub-cell shock capturing for discontinuous Galerkin methods. In 44th AIAA Aerospace Sciences Meeting and Exhibit, page 112, 2006.
  144. I. Peshkov and E. Romenski. A hyperbolic model for viscous Newtonian flows. Continuum Mechanics and Thermodynamics, 28:85–104, 2016.
  145. In-cell discontinuous reconstruction path-conservative methods for non conservative hyperbolic systems - Second-order extension. Journal of Computational Physics, 459:111152, 2022.
  146. S. Del Pino. A curvilinear finite-volume method to solve compressible gas dynamics in semi-Lagrangian coordinates. Comptes Rendus de l'Académie des Sciences - Series I - Mathematics, 348:1027–1032, 2010.
  147. Implicit discretization of lagrangian gas dynamics. ESAIM: Mathematical Modelling and Numerical Analysis, 57(2):717–743, 2023.
  148. I.S. Popov. Space-Time Adaptive ADER-DG Finite Element Method with LST-DG Predictor and a posteriori Sub-cell WENO Finite-Volume Limiting for Simulation of Non-stationary Compressible Multicomponent Reactive Flows. Journal of Scientific Computing, 95(2):44, 2023.
  149. J. Qiu and C.-W. Shu. Hermite WENO schemes and their application as limiters for Runge–Kutta discontinuous Galerkin method: one-dimensional case. Journal of Computational Physics, 193(1):115–135, 2004.
  150. J. Qiu and C.-W. Shu. Runge–Kutta discontinuous Galerkin method using WENO limiters. SIAM Journal on Scientific Computing, 26(3):907–929, 2005.
  151. Conservative models and numerical methods for compressible two-phase flow. Journal of Scientific Computing, 42:68–95, 2010.
  152. Subcell limiting strategies for discontinuous Galerkin spectral element methods. Computers & Fluids, 247:105627, 2022.
  153. V. V. Rusanov. Calculation of Interaction of Non–Steady Shock Waves with Obstacles. J. Comput. Math. Phys. USSR, 1:267–279, 1961.
  154. A finite volume cell-centered Lagrangian hydrodynamics approach for solids in general unstructured grids. International Journal for Numerical Methods in Fluids, 72:770–810, 2013.
  155. G. Scovazzi. Lagrangian shock hydrodynamics on tetrahedral meshes: A stable and accurate variational multiscale approach. Journal of Computational Physics, 231:8029–8069, 2012.
  156. M. Sonntag and C.D. Munz. Shock Capturing for discontinuous Galerkin methods using Finite Volume Subcells. In J. Fuhrmann, M. Ohlberger, and C. Rohde, editors, Finite Volumes for Complex Applications VII, pages 945–953. Springer, 2014.
  157. M. Sonntag and C.D. Munz. Efficient Parallelization of a Shock Capturing for Discontinuous Galerkin Methods using Finite Volume Sub-cells. Journal of Scientific Computing, 70:1262–1289, 2017.
  158. V. Springel. E pur si muove: Galilean-invariant cosmological hydrodynamical simulations on a moving mesh. Monthly Notices of the Royal Astronomical Society, 401(2):791–851, 2010.
  159. A.H. Stroud. Approximate Calculation of Multiple Integrals. Prentice-Hall Inc., Englewood Cliffs, New Jersey, 1971.
  160. An all speed second order well-balanced IMEX relaxation scheme for the Euler equations with gravity. Journal of Computational Physics, 4201:109723, 2020.
  161. A second-order positivity-preserving well-balanced finite volume scheme for Euler equations with gravity for arbitrary hydrostatic equilibria. International Journal for Numerical Methods in Fluids, 89(11):465–482, 2019.
  162. ADER: Arbitrary high order Godunov approach. Journal of Scientific Computing, 17(1-4):609–618, December 2002.
  163. E. F. Toro. Riemann Solvers and Numerical Methods for Fluid Dynamics. A Practical Introduction, Third edition. Springer-Verlag, Berlin, 2009.
  164. Towards very high order Godunov schemes. In E.F. Toro, editor, Godunov Methods. Theory and Applications, pages 905–938. Kluwer/Plenum Academic Publishers, 2001.
  165. ADER schemes for scalar non-linear hyperbolic conservation laws with source terms in three-space dimensions. Journal of Computational Physics, 202(1):196–215, 2005.
  166. F. Vilar. A posteriori correction of high-order discontinuous galerkin scheme through subcell finite volume formulation and flux reconstruction. Journal of Computational Physics, 387:245–279, 2019.
  167. A method for the calculation of hydrodynamics shocks. Journal of Applied Physics, 21:232–237, 1950.
  168. An improved total lagrangian sph method for modeling solid deformation and damage. Engineering Analysis with Boundary Elements, 133:286–302, 2021.
  169. D.F. Watson. Computing the n-dimensional Delaunay tessellation with application to Voronoi polytopes. The computer journal, 24(2):167–172, 1981.
  170. M. L. Wilkins. Calculation of elastic-plastic flow. Methods in Computational Physics, 3, 1964.
  171. K. Wu and Y. Xing. Uniformly high-order structure-preserving discontinuous galerkin methods for euler equations with gravitation: Positivity and well-balancedness. SIAM Journal on Scientific Computing, 43(1):A472–A510, 2021.
  172. A cell-centered indirect arbitrary-lagrangian-eulerian discontinuous galerkin scheme on moving unstructured triangular meshes with topological adaptability. Journal of Computational Physics, 438:110368, 2021.
  173. Y. Xing and C.-W. Shu. High-order well-balanced finite difference WENO schemes for a class of hyperbolic systems with source terms. Journal of Scientific Computing, 27(1):477–494, 2006.
  174. Solving the relativistic magnetohydrodynamics equations with ADER discontinuous Galerkin methods, a posteriori subcell limiting and adaptive mesh refinement. Mon. Not. R. Astron. Soc., 452:3010–3029, September 2015.
  175. Space–time adaptive ADER discontinuous Galerkin finite element schemes with a posteriori sub–cell finite volume limiting. Computers and Fluids, 118:204–224, 2015.

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now