2nd Edition
Mechanics of Structures Variational and Computational Methods
Resoundingly popular in its first edition, the second edition of Mechanics of Structures: Variational and Computational Methods promises to be even more so, with broader coverage, expanded discussions, and a streamlined presentation.
The authors begin by describing the behavior of deformable solids through the differential equations for the strength of materials and the theory of elasticity. They next introduce variational principles, including mixed or generalized principles, and derive integral forms of the governing equations. Discussions then move to computational methods, including the finite element method, and these are developed to solve the differential and integral equations.
New in the second edition:
As a textbook or as a reference, Mechanics of Structures builds a unified, variational foundation for structure mechanics, which in turn forms the basis for the computational solid mechanics so essential to modern engineering.
Basic Equations: Differential Form
Principles of Virtual Work: Integral Form of the Basic Equations
Related Variational and Energy Principles
SOLUTION METHODS
Structural Analysis Methods I: Beam Elements
Structural Analysis Methods II: Structural Systems
The Finite Element Method
Direct Variational and Weighted Residual Methods: Classical Trial Function Methods
The Finite Difference Method
The Boundary Element Method
FORMULATIONS FOR DYNAMIC AND STABILITY PROBLEMS
Dynamic Responses
Stability Analysis
BARS AND PLATES
Beams
Plates
APPENDICES
Biography
Wunderlich\, Walter; Pilkey\, Walter D.
"[This book] represents clear progress in this recent custom of popularizing structural mechanics … . The book includes several important and deep topics that are often neglected in other works of the same kind. It shows a great effort towards completeness. It collects all classical variational principles of continuum mechanics … . … [T]he merit of the book resides in its colossal attempt to recombine three branches of the theory of elasticity (foundations, structures, numerical methods), which tend to diverge."
- Meccanica, Vol. 39, 2004