Open AccessRecent Improvements in Aerodynamic Design Optimization on Unstructured Meshes
Author(s) -
Eric J. Nielsen,
W. Kyle Anderson
Publication year - 2002
Publication title -
aiaa journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.828
H-Index - 158
eISSN - 1081-0102
pISSN - 0001-1452
DOI - 10.2514/2.1765
Subject(s) - aerodynamics , polygon mesh , computer science , linearization , speedup , unstructured grid , mathematical optimization , grid , parallel computing , convergence (economics) , computational science , computation , mesh generation , multiprocessing , algorithm , finite element method , mathematics , nonlinear system , aerospace engineering , engineering , computer graphics (images) , physics , geometry , structural engineering , quantum mechanics , economic growth , economics
Recent improvements in the an unstructured-grid method for large-scale aerodynamic design are presented. Previous work had shown such computations to be prohibitively long in a sequential processing environment. Also, robust adjoint solutions and mesh movement procedures were difficult to realize, particularly for viscous flows. To overcome these limiting factors, a set of design codes based on a discrete adjoint method is extended to a multiprocessor environment using a shared memory approach. A nearly linear speedup is demonstrated, and the consistency of the linearizations is shown to remain valid. The full linearization of the residual is used to preconcondition the adjoint system, and a significantly improved convergence rate is obtained. A new mesh movement algorithm is implemented and several advantages over an existing techniques are presented. Several design cases are shown for turbulent flows in two and three dimensions.
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