Dynamic load balancing for adaptive mesh coarsening in computational fluid dynamics

被引:0
|
作者
Gutzmer, T [1 ]
机构
[1] ETH Zentrum, Seminar Appl Math, CH-8092 Zurich, Switzerland
来源
PARALLEL COMPUTATIONAL FLUID DYNAMICS: RECENT DEVELOPMENTS AND ADVANCES USING PARALLEL COMPUTERS | 1998年
关键词
D O I
10.1016/B978-044482849-1/50008-7
中图分类号
TP39 [计算机的应用];
学科分类号
081203 ; 0835 ;
摘要
In this paper we present a new adaptation technique (AMCIT) for the calculation of highly unsteady flows. Because of the time dependence of the investigated problems a dynamic load balancing strategy is required. A special block data structure in AMCIT allows the efficient use of massively parallel machines, and numerical examples were compare on Intel Paragon MP, Gray T3D and GigaBooster.
引用
收藏
页码:57 / 64
页数:8
相关论文
共 50 条
  • [21] A space-time parallel algorithm with adaptive mesh refinement for computational fluid dynamics
    Christopher, Joshua
    Falgout, Robert D.
    Schroder, Jacob B.
    Guzik, Stephen M.
    Gao, Xinfeng
    COMPUTING AND VISUALIZATION IN SCIENCE, 2020, 23 (1-4)
  • [22] Moving mesh methods for computational fluid dynamics
    Tang, T
    RECENT ADVANCES IN ADAPTIVE COMPUTATION, PROCEEDINGS, 2005, 383 : 141 - 173
  • [23] Massively parallel adaptive mesh refinement and coarsening for dynamic fracture simulations
    Alhadeff, Andrei
    Leon, Sofie E.
    Celes, Waldemar
    Paulino, Glaucio H.
    ENGINEERING WITH COMPUTERS, 2016, 32 (03) : 533 - 552
  • [24] Adaptive mesh refinement and coarsening for cohesive zone modeling of dynamic fracture
    Park, Kyoungsoo
    Paulino, Glaucio H.
    Celes, Waldemar
    Espinha, Rodrigo
    INTERNATIONAL JOURNAL FOR NUMERICAL METHODS IN ENGINEERING, 2012, 92 (01) : 1 - 35
  • [25] Massively parallel adaptive mesh refinement and coarsening for dynamic fracture simulations
    Andrei Alhadeff
    Sofie E. Leon
    Waldemar Celes
    Glaucio H. Paulino
    Engineering with Computers, 2016, 32 : 533 - 552
  • [26] Complex-Geometry 3D Computational Fluid Dynamics with Automatic Load Balancing
    Bakosi, Jozsef
    Constans, Matyas
    Horvath, Zoltan
    Kovacs, Akos
    Kornyei, Laszlo
    Charest, Marc
    Pandare, Aditya
    Rutherford, Paula
    Waltz, Jacob
    FLUIDS, 2023, 8 (05)
  • [27] Dynamic load balancing for a mesh-based scientific application
    Zhai, Keke
    Banerjee, Tania
    Zwick, David
    Hackl, Jason
    Koneru, Rahul
    Ranka, Sanjay
    CONCURRENCY AND COMPUTATION-PRACTICE & EXPERIENCE, 2020, 32 (09):
  • [28] PERFORMANCE OF DYNAMIC LOAD BALANCING ALGORITHMS FOR UNSTRUCTURED MESH CALCULATIONS
    WILLIAMS, RD
    CONCURRENCY-PRACTICE AND EXPERIENCE, 1991, 3 (05): : 457 - 481
  • [29] A generic strategy for dynamic load balancing of dynamic parallel distributed mesh generation
    Yuan, Youwei
    Guo, Qingqing
    DCABES 2006 PROCEEDINGS, VOLS 1 AND 2, 2006, : 199 - 202
  • [30] A Dual-Mesh Unstructured Adaptive Cartesian Computational Fluid Dynamics Approach for Hover Prediction
    Wissink, Andrew M.
    Potsdam, Mark
    Sankaran, Venkateswaran
    Sitaraman, Jayanarayanan
    Mavriplis, Dimitri
    JOURNAL OF THE AMERICAN HELICOPTER SOCIETY, 2016, 61 (01)
12345