A fast, robust, and simple implicit method for adaptive time-stepping on adaptive mesh-refinement grids

被引:0
|
作者
机构
[1] [1,Commerçon, B.
[2] Debout, V.
[3] Teyssier, R.
来源
| 1600年 / EDP Sciences卷 / 563期
关键词
Context. Implicit solvers present strong limitations when used on supercomputing facilities and in particular for adaptive mesh-refinement codes. Aims. We present a new method for implicit adaptive time-stepping on adaptive mesh-refinement grids. We implement it in the radiation-hydrodynamics solver we designed for the RAMSES code for astrophysical purposes and; more particularly; for protostellar collapse. Methods. We briefly recall the radiation- hydrodynamics equations and the adaptive time-stepping methodology used for hydrodynamical solvers. We then introduce the different types of boundary conditions (Dirichlet; Neumann; and Robin) that are used at the interface between levels and present our implementation of the new method in the RAMSES code. The method is tested against classical diffusion and radiation- hydrodynamics tests; after which we present an application for protostellar collapse. Results. We show that using Dirichlet boundary conditions at level interfaces is a good compromise between robustness and accuracy and that it can be used in structure formation calculations. The gain in computational time over our former unique time step method ranges from factors of 5 to 50 depending on the level of adaptive time-stepping and on the problem. We successfully compare the old and new methods for protostellar collapse calculations that involve highly non linear physics. Conclusions. We have developed a simple but robust method for adaptive time-stepping of implicit scheme on adaptive mesh-refinement grids. It can be applied to a wide variety of physical problems that involve diffusion processes. © ESO; 2014;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
相关论文
共 50 条
  • [41] An Adaptive Time-Stepping Algorithm for the Allen-Cahn Equation
    Lee, Chaeyoung
    Park, Jintae
    Kwak, Soobin
    Kim, Sangkwon
    Choi, Yongho
    Ham, Seokjun
    Kim, Junseok
    JOURNAL OF FUNCTION SPACES, 2022, 2022
  • [42] Shape Optimization of Rotating Machines Using Time-Stepping Adaptive Finite Element Method
    Yamazaki, Katsumi
    Kanou, Yuji
    IEEE TRANSACTIONS ON MAGNETICS, 2010, 46 (08) : 3113 - 3116
  • [43] Study of Seabed Pullout Resistance on a Quadrate Foundation Using Adaptive Time-Stepping Method
    Zhang, X. W.
    Uzuoka, R.
    Tang, X. W.
    Shao, Q.
    MARINE GEORESOURCES & GEOTECHNOLOGY, 2016, 34 (03) : 234 - 243
  • [44] AN ADAPTIVE TIME-STEPPING ALGORITHM FOR QUASI-STATIC PROCESSES
    VANDENBOOGAARD, AH
    DEBORST, R
    VANDENBOGERT, PAJ
    COMMUNICATIONS IN NUMERICAL METHODS IN ENGINEERING, 1994, 10 (10): : 837 - 844
  • [45] AN ADAPTIVE TIME-STEPPING SCHEME FOR THE VISCOPLASTICITY THEORY BASED ON OVERSTRESS
    CHEN, H
    KREMPL, E
    COMPUTERS & STRUCTURES, 1986, 22 (04) : 573 - 578
  • [46] An Adaptive Time-Stepping Strategy for the Cahn-Hilliard Equation
    Zhang, Zhengru
    Qiao, Zhonghua
    COMMUNICATIONS IN COMPUTATIONAL PHYSICS, 2012, 11 (04) : 1261 - 1278
  • [47] AN ADAPTIVE TIME-STEPPING PROCEDURE BASED ON THE SCALED BOUNDARY FINITE ELEMENT METHOD FOR ELASTODYNAMICS
    Zhang, Z. H.
    Yang, Z. J.
    Liu, Guohua
    INTERNATIONAL JOURNAL OF COMPUTATIONAL METHODS, 2012, 9 (01)
  • [48] Local error estimator of energy and adaptive time-stepping procedure for direct integration method
    Yantu Gongcheng Xuebao, 6 (32-41):
  • [49] On approximation classes for adaptive time-stepping finite element methods
    Actis, Marcelo
    Morin, Pedro
    Schneider, Cornelia
    IMA JOURNAL OF NUMERICAL ANALYSIS, 2023, 43 (05) : 2817 - 2855
  • [50] AN ADAPTIVE TIME-STEPPING STRATEGY FOR THE MOLECULAR BEAM EPITAXY MODELS
    Qiao, Zhonghua
    Zhang, Zhengru
    Tang, Tao
    SIAM JOURNAL ON SCIENTIFIC COMPUTING, 2011, 33 (03): : 1395 - 1414
12345