Oxford University Press, USA
Applied Shape Optimization for Fluids
Applied Shape Optimization for Fluids
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Computational fluid dynamics (CFD) and optimal shape design (OSD) are of practical importance for many engineering applications - the aeronautic, automobile, and nuclear industries are all major users of these technologies. Giving the state of the art in shape optimization for an extended range of applications, this new edition explains the equations needed to understand OSD problems for fluids (Euler and Navier Strokes, but also those for microfluids) and covers numerical simulation techniques. Automatic
differentiation, approximate gradients, unstructured mesh adaptation, multi-model configurations, and time-dependent problems are introduced, illustrating how these techniques are implemented within the industrial environments of the aerospace and automobile industries. With the dramatic increase in computing power since the first edition, methods that were previously unfeasible have begun giving results. The book remains primarily one on differential shape optimization, but the coverage of evolutionary algorithms, topological optimization methods, and level set
algortihms has been expanded so that each of these methods is now treated in a separate chapter. Presenting a global view of the field with simple mathematical explanations, coding tips and tricks, analytical and numerical tests, and exhaustive referencing, the book will be essential reading for engineers interested in the implementation and solution of optimization problems. Whether using
commercial packages or in-house solvers, or a graduate or researcher in aerospace or mechanical engineering, fluid dynamics, or CFD, the second edition will help the reader understand and solve design problems in this exciting area of research and development, and will prove especially useful in
showing how to apply the methodology to practical problems.
Author: Bijan Mohammadi, Olivier Pironneau
Publisher: Oxford University Press, USA
Published: 11/30/2009
Pages: 304
Binding Type: Hardcover
Weight: 1.36lbs
Size: 9.20h x 6.10w x 0.70d
ISBN: 9780199546909
Review Citation(s):
Scitech Book News 03/01/2010 pg. 132
differentiation, approximate gradients, unstructured mesh adaptation, multi-model configurations, and time-dependent problems are introduced, illustrating how these techniques are implemented within the industrial environments of the aerospace and automobile industries. With the dramatic increase in computing power since the first edition, methods that were previously unfeasible have begun giving results. The book remains primarily one on differential shape optimization, but the coverage of evolutionary algorithms, topological optimization methods, and level set
algortihms has been expanded so that each of these methods is now treated in a separate chapter. Presenting a global view of the field with simple mathematical explanations, coding tips and tricks, analytical and numerical tests, and exhaustive referencing, the book will be essential reading for engineers interested in the implementation and solution of optimization problems. Whether using
commercial packages or in-house solvers, or a graduate or researcher in aerospace or mechanical engineering, fluid dynamics, or CFD, the second edition will help the reader understand and solve design problems in this exciting area of research and development, and will prove especially useful in
showing how to apply the methodology to practical problems.
Author: Bijan Mohammadi, Olivier Pironneau
Publisher: Oxford University Press, USA
Published: 11/30/2009
Pages: 304
Binding Type: Hardcover
Weight: 1.36lbs
Size: 9.20h x 6.10w x 0.70d
ISBN: 9780199546909
Review Citation(s):
Scitech Book News 03/01/2010 pg. 132
About the Author
Bijan Mohammadi is Director of Institut de Mathématiques et de Modélisation de Montpellier and Professor at the Université Montpellier II.
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