Eugene L. Poole , Michael A. Heroux , Pravin Vaidya , Anil Joshi
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Performance of iterative methods in ANSYS on cray parallel/vector supercomputers
This paper describes recent work using iterative methods for the solution of linear systems in the ANSYS program. The ANSYS program, a general purpose finite element code widely used in structural analysis applications, has now added an iterative solver option. The development of robust iterative solvers and their use in commercial programs is discussed. Discussion of the applicability of iterative solvers as a general purpose solver will include the topics of robustness; as well as memory requirements and CPU performance. A new iterative solver for general purpose finite element codes which functions as a “black-box” solver using element-specific information and the underlying problem physics to construct an effective and inexpensive preconditioner is described. Some results are given from realistic examples comparing the performance of the iterative solver implemented in ANSYS with the traditional parallel/vector frontal solver used in ANSYS and a robust shifted incomplete Choleski iterative solver.
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