ebook img

Variational Methods in Theoretical Mechanics PDF

312 Pages·1976·9.113 MB·English
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Variational Methods in Theoretical Mechanics

Un iversitext J. T. Oden J. N. Reddy Variational Methods in Theoretical Mechanics Springer-Verlag Berlin Heidelberg New York 1976 Prof. J. T. Oden The University of Texas at Austin Prof. J. N. Reddy The University of Oklahoma AMS Subject Classification (1970): 35 A 15; 49 H 05; 73 B 99; 73 E 99; 73F99; 73G05; 73K25; 76005. ISBN-13: 978-3-540-07600-1 e-ISBN-13: 978-3-642-96312-4 001: 10.1007/978-3-642-96312-4 Library of Congress Cataloging in Publication Data. Oden, John Tinsley, 1936-Variational methods in theoretical mechanics. (Universitext). Bibliography: p. Includes index. 1. Mechanics. 2. Continuum mechanics. 3. Calculus of variations. I. Reddy, Junuthula Narasimha, 1945-II. Title. QA80S.03. 531'.01'5157. 75-45099. This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher. the amount of the fee to be determined by agreement with the publisher. © by Springer-Verlag Berlin Heidelberg 1976. To Walker, Lee, Anita, and Anil Preface This is a textbook written for use in a graduate-level course for students of mechanics and engineering science. It is designed to cover the essential features of modern variational methods and to demonstrate how a number of basic mathematical concepts can be used to produce a unified theory of variational mechanics. As prerequisite to using this text, we assume that the student is equipped with an introductory course in functional analysis at a level roughly equal to that covered, for example, in Kolmogorov and Fomin (Functional Analysis, Vol. I, Graylock, Rochester, 1957) and possibly a graduate-level course in continuum mechanics. Numerous references to supplementary material are listed throughout the book. We are indebted to Professor Jim Douglas of the University of Chicago, who read an earlier version of the manuscript and whose detailed suggestions were extremely helpful in preparing the final draft. He also gratefully acknowledge that much of our own research work on variational theory was supported by the U.S. Air Force Office of Scientific Research. He are indebted to Mr. Ming-Goei Sheu for help in proofreading. Finally, we wish to express thanks to Mrs. Marilyn Gude for her excellent and pains taking job of typing the manuscript. J. T. ODEN J. N. REDDY Table of Contents PREFACE 1. INTRODUCTION 1.1 The Role of Variational Theory in Mechanics. 1 1.2 Some Historical Comments ......... . 2 1.3 Plan of Study ............... . 5 2. MATHEMATICAL FOUNDATIONS OF CLASSICAL VARIATIONAL THEORY 7 2.1 Introduction . . . . . . . . 7 2.2 Nonlinear Operators ..... 9 2.3 Differentiation of Operators 17 2.4 Mean Value Theorems .... . 25 2.5 Taylor Formulas ...... . 28 2.6 Gradients of Functionals .. 32 2.7 Minimization of Functionals. 35 2.8 Convex Functionals ..... 39 2.9 Potential Operators and the Inverse Problem. 41 2.10 Sobo 1e v Spaces . . . . . . 45 3. MECHANICS OF CONTINUA- A BRIEF REVIEW. 52 3.1 Introduction .•........ 52 3.2 Kinematics .......... . 53 3.3 Stress and the Mechanical Laws of Balance. 57 The Principle of Conservation of Mass .... 59 The Principle of Balance of Linear Momentum. 60 The Principle of Balance of Angular Momentum 62 3.4 Thermodynamic Principles .... 63 The Principle of Conservation of Energy. 63 The Clausius-Duhem Inequality. 66 3.5 Constitutive Theory ..... . 68 Rules of Constitutive Theory . 68 Special Forms of Constitutive Equations. 72 3.6 Jump Conditions for Discontinuous Fields 77 IX 4. COMPLEMENTARY AND DUAL VARIATIONAL PRINCIPLES IN MECHANICS . • • .. .. . . 82 4.1 Introduction.. .•.•.. .. 82 4.2 Boundary Conditions and Green's Formulas 87 94 4.3 Examples from Mechanics and Physics. 4.4 The Fourteen Fundamental Complementary-Dual Principles . .•... ... 104 4.5 Some Complementary-Dual Variational Principles of Mechanics and Physics . .. . .. 114 4.6 Legendre Transformations . . • . 123 4.7 Generalized Hamiltonian Theory.. .. 128 4.8 Upper and Lower Bounds and Existence Theory. 131 4.9 Lagrange Multipliers. .• .. 136 5. VARIATIONAL PRINCIPLES IN CONTINUUM MECHANICS. 139 5.1 Introduction.. . . .. . ... 139 5.2 Some Preliminary Properties and Lemmas. 140 5.3 General Variational Principles for Linear Theory of Dynamic Viscoelasticity ....•.... 143 5.4 Gurtin's Variational Principles for the Linear Theory of Dynamic Viscoelasticity. • 153 5.5 Variational Principles for Linear Coupled Dynamic Thermoviscoelasticity. 158 Linear (coupled) Thermoe1asticity. . 161 5.6 Variational Principles in Linear E1astodynamics. 162 5.7 Variational Principles for Linear Piezoelectric E1astodynamic Problems . . .. .•.• 169 5.8 Variational Principles for Hypere1astic Materials. 173 Fi nite Elasticity. . . 175 Quasi-Static Problems .• . . 182 5.9 Variational Principles in the Flow Theory of Plasticity . . . • . . .. .. .• 184 5.10 Variational Principles for a" Large Displacement Theory of E1astop1asticity . . . • • • •. . 186 5.11 Variational Principles in Heat Conduction. • . 189 5.12 Biot's Quasi-Variational Principle in Heat Transfer. 191 5.13 Some Variational Principles in Fluid Mechanics and Magnetohydrodynamics 195 Non-Newtonian Fluids. . 197 Perfect Fluids ..... . . . . . . . . 198 An Alternate Principle for Invicid Flow. 199 Magnetohydrodynamics 200 x 5.14 Variational Principles for Discontinuous Fields. 202 Hybrid Vari ati ona 1 Princi pl es. • • • . • 208 6. VARIATIONAL BOUNDARY-VALUE PROBLEMS, MONOTONE OPERATORS, AND VARIATIONAL INEQUALITIES • • • • . . . • • • • • . • 215 6.1 Direct Variational Methods. . . . . . • . . . . . . 215 6.2 Linear Elliptic Variational Boundary-Value Problems. 216 Regularity • . . • • . • . . • • • . . . • • • • . . 222 6.3 The Lax-Milgram-Babuska Theorem. • . . . • . . . . . 223 6.4 Existence Theory in Linear Incompressible Elasticity 227 6.5 Monotone Operators • . . . • . . • . • . 235 6.6 Existence Theory in Nonlinear Elasticity 248 6.7 Variational Inequalities. . • 253 6.8 Applications in Mechanics. ". • 258 7. VARIATIONAL METHODS OF APPROXIMATION 262 7.1 Introduction .•..........•... 262 7.2 Several Variational Methods of Approximation 262 Galerkin's Method .•..•.. 265 The Rayleigh-Ritz Method ... 266 Semidiscrete Galerkin Methods. 266 Methods of Weighted Residuals. 267 Least Square Methods • . . • • 268 Collocation Methods ....•• 268 Funct i ona 1 Imbedd i ngs. . . • • 269 7.3 Finite-Element Approximations. . 270 7.4 Finite-Element Interpolation Theory. . • • . • . 273 7.5 Existence and Uniqueness of Galerkin Approximations. 281 7.6 Convergence and Accuracy of Finite-Element Galerkin Approximations 285 REFERENCES . . . . . • . . . • . . . . • • . . . . • . . . . . 291 1. Introduction 1.1 The Role of Variational Theory in Mechanics. Variational principles have always played an important role in theoretical mechanics. To most students of mechanics, they provide alternate approaches to direct appli cations of local physical laws. The principle of minimum potential energy, for example, can be regarded as a substitute to the equations of equili brium of elastic bodies, as well as a basis for the study of stability. Hamilton's principle can be used in lieu of the equations governing dynami cal systems, and the variational forms presented by Biot displace certain equations in linear continuum thermodynamics. However, the importance of variational statements of physical laws, in the general sense of these terms, goes far beyond their use as simply an alternate to other formulations. In fact, variational or weak forms of the laws of continuum physics may be the only natural and rigorously correct way to think of them. The idea that they are only equivalent substitutes for local statements of these laws is an all too common mis conception. The fundamental principles of mechanics are global principles; they may require local integrability of certain fields, but not local differentiability. Hence, we can generate local forms of these laws only if we endow all physical field quantities with a possibly unnatural degree of smoothness. This done, we rule out all traces of point sources, dis continuities, and their derivatives, and we restrict ourselves to a rather 2 unrealistic view of the universe. While all sufficiently smooth fields lead to meaningful variational forms, the converse is not true: there exist physical phenomena which can be adequately modeled mathematically only in a variational setting; they are nonsense when viewed locally. Aside from this basic observation, the use of variational statements of physical laws makes it possible to concentrate in a single functional all of the intrinsic features of the problem at hand: the governing equations, the boundary conditions, initial conditions, conditions of constraint, even jump conditions. Variational formulations can serve not only to unify diverse fields but also to suggest new theories, and they provide a powerful means for studying the existence of solutions to partial differ ential equations. Finally, and perhaps most importantly, variational methods provide a natural means for approximation; they are at the heart of the most powerful approximate methods in use in mechanics, and in many cases they can be used to establish upper and/or lower bounds on approximate solutions. 1.2 Some Historical Comments. In modern times, the term "variational theory" applies to a wide spectrum of concepts having to do with weak, generalized, or direct variational formulations of boundary- and initial value problems. Still, many of the essential features of variational methods remain the same as they were over 200 years ago when the first notions of variational calculus began to be formulated. Actually, the most primitive ideas of variational theory are present in Aristotle's writings on "virtual velocities" in 300 B.C., to be revived again by Galileo in the sixteenth century and finally to be formulated into a principle of virtual work by John Bernoulli in 1717. The development

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.