This book provides a comprehensive overview of analytical methods for solving optimization problems, covering principles and mathematical techniques alongside numerical solution routines, including MAPLE and MAXIMA optimization routines. Each method is explained with practical applications and ANSYS APDL scripts for select problems. Chapters delve into topics such as scaling methods, torsion compliance, shape variation, topological optimization, anisotropic material properties, and differential geometry. Specific optimization problems, including stress minimization and mass reduction under constraints, are addressed. The book also explores isoperimetric inequalities and optimal material selection principles. Appendices offer insights into tensors, differential geometry, integral equations, and computer algebra codes. Overall, it's a comprehensive guide for engineers and researchers in structural optimization.
Series
Edition
Language
Place of publication
Publishing group
Springer International Publishing
Target group
Professional and scholarly
Illustrations
4 s/w Abbildungen, 68 farbige Abbildungen
XXX, 336 p. 72 illus., 68 illus. in color.
Dimensions
Height: 241 mm
Width: 160 mm
Thickness: 25 mm
Weight
ISBN-13
978-3-031-59139-6 (9783031591396)
DOI
10.1007/978-3-031-59140-2
Schweitzer Classification
Vladimir Kobelev, Ph.D., Dr. rer. nat. habil., received the Dipl. In Physics and Ph.D. degrees from the Department of Aerophysics and Space Research, Moscow Institute of Physics and Technology, Dolgoprudny, Russia. Since 2000, he has been an APL professor with the Department of Mechanical Engineering, Universität Siegen, Siegen, Germany. He is the author of three books, "Durability of Springs", "Design and Analysis of Composite Structures for Automotive Applications" and "Fundamentals of structural optimization".
Scaling Methods. Optimality of Michell Structures and membrane shells.- One-Dimensional Variational Methods. Optimization of twisted spherical shell.- Methods of Domain Variations for Shape Optimization.- Methods of Local Variations. Topological derivatives and Bubble Methods.- Methods of Tensor Transformations for Anisotropic Medium.- Methods of Differential Geometry. Optimal distributions of the residual stresses.- Integral Equation Methods. Optimization of stiffeners and needle-shaped inclusions.- Isoperimetric Inequalities. Structural optimization problems of stability.
