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Finite Elements Using Maple Artur Portela

Finite Elements Using Maple By Artur Portela

Finite Elements Using Maple by Artur Portela

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Summary

This text provides the reader with a unique insight into the finite element method, along with symbolic programing that fundamentally changes the way applications can be developed.

Finite Elements Using Maple Summary

Finite Elements Using Maple: A Symbolic Programming Approach by Artur Portela

This text provides the reader with a unique insight into the finite element method, along with symbolic programing that fundamentally changes the way applications can be developed. It is an essential tool for undergraduate or early postgraduate courses as well as an excellent reference book for engineers and scientists who want to quickly develop finite-element programs. The use of symbolic computation in Maple system delivers new benefits in the analysis and understanding of the finite element method.

Finite Elements Using Maple Reviews

From the reviews:

The purpose of this book is to illustrate how the computational environment of Maple can be used in a finite element ... . It gives to the reader a very unique insight into the finite element method together with symbolic programming approach ... . In summary, this book is an excellent introductory book for finite element method and I strongly recommend to all undergraduate and postgraduate students and also to engineers and scientists who wish to program easily the finite element method. (T.E. Simos, Journal of Computational Methods in Sciences and Engineering, Vol. 3 (2), 2003)

This book is an essential tool written to be used as the primary text for an undergraduate or early postgraduate course as well as a reference book for engineers and scientists who want to develop quickly finite-element programs. (European Journal of Mechanical and Environmental Engineering, Vol. 47 (2), 2002)

Table of Contents

1. Introduction to Maple.- 1.1 Basics.- 1.2 Entering Commands.- 1.3 Fundamental Data Types.- 1.4 Mathematical Functions.- 1.5 Names.- 1.6 Basic Types of Maple Objects.- 1.6.1 Sequences.- 1.6.2 Lists.- 1.6.3 Sets.- 1.6.4 Arrays.- 1.6.5 Tables.- 1.6.6 Strings.- 1.7 Evaluation Rules.- 1.7.1 Levels of Evaluation.- 1.7.2 Last-Name Evaluation.- 1.7.3 One-Level Evaluation.- 1.7.4 Special Evaluation Rules.- 1.7.5 Delayed Evaluation.- 1.8 Algebraic Equations.- 1.9 Differentiation and Integration.- 1.10 Solving Differential Equations.- 1.11 Expression Manipulation.- 1.12 Basic Programming Constructs.- 1.13 Functions, Procedures and Modules.- 1.14 Maple's Organization.- 1.15 Linear Algebra Computations.- 1.16 Graphics.- 1.17 Plotter: Package for Finite Element Graphics.- 1.17.1 Example.- 1.17.2 Example.- 1.17.3 Example.- 2. Computational Mechanics.- 2.1 Introduction.- 2.2 Mathematical Modelling of Physical Systems.- 2.3 Continuous Models.- 2.3.1 Equilibrium.- 2.3.2 Propagation.- 2.3.3 Diffusion.- 2.4 Mathematical Analysis.- 2.5 Approximation Methods.- 2.6 Discrete Models.- 2.7 Structural Models.- 3. Approximation Methods.- 3.1 Introduction.- 3.2 Residuals.- 3.3 Weighted-Residual Equation.- 3.3.1 Example.- 3.4 Approximation Functions.- 3.5 Admissibility Conditions.- 3.5.1 Example.- 3.6 Global Indirect Discretization.- 3.6.1 Satisfaction of Boundary Conditions.- 3.6.2 Domain Methods of Approximation.- 3.6.3 Galerkin Method.- 3.6.4 Least Squares Method.- 3.6.5 Moments Method.- 3.6.6 Collocation Method.- 3.6.7 Example.- 3.6.8 Example.- 3.7 Integration by Parts.- 3.7.1 Strong, Weak and Transposed Forms.- 3.7.2 One-Dimensional Case.- 3.7.3 Example.- 3.7.4 Higher-Dimensional Cases.- 3.7.5 Example.- 3.8 Local Direct Discretization.- 3.8.1 Nodes and Local Regions.- 3.8.2 Satisfaction of Boundary Conditions.- 3.8.3 Finite Difference Method.- 3.8.4 Finite Element Method.- 3.8.5 Boundary Element Method.- 3.8.6 Example.- 3.8.7 Example.- 3.8.8 Example.- 4. Interpolation.- 4.1 Introduction.- 4.2 Globally Defined Functions.- 4.2.1 Polynomial Bases.- 4.2.2 Example.- 4.2.3 Example.- 4.2.4 Conclusions.- 4.3 Piecewisely Defined Functions.- 4.3.1 Spline Interpolation.- 4.3.2 Finite Element Interpolation.- 4.4 Finite Element Generalized Coordinates.- 4.4.1 Convergence Conditions.- 4.4.2 Geometric Isotropy.- 4.4.3 Finite Element Families.- 4.5 Finite Element Shape Functions.- 4.5.1 Natural Coordinates.- 4.5.2 Curvilinear Coordinates.- 4.5.3 Example.- 4.6 Parametric Finite Elements.- 4.7 Isoparametric Finite Elements.- 4.7.1 Convergence Conditions.- 4.7.2 Evaluation of Element Equations.- 4.7.3 Numerical Integration.- 4.8 Linear Triangular Isoparametric Element.- 4.8.1 Example.- 4.8.2 Example.- 4.8.3 Example.- 4.8.4 Example.- 5. The Finite Element Method.- 5.1 Introduction.- 5.2 Steady-State Models with Scalar Variable.- 5.2.1 Continuous Model.- 5.2.2 Weighted Residual Galerkin Approximation.- 5.2.3 Discrete Model.- 5.3 Finite Element Mesh.- 5.3.1 Linear Triangular Isoparametric Element.- 5.3.2 Total Potential Energy.- 5.3.3 Internal Potential Energy Density.- 5.3.4 Mesh Topology.- 5.4 Local Finite Element Equations.- 5.5 Global Finite Element Equations.- 5.6 Exact Boundary Conditions.- 5.7 Solution of the System of Equations.- 5.8 Computation of Derivatives.- 5.9 Finite Element Pre- and Post- Processing.- 5.10 Cgt-fem: Package for Finite Element Analysis.- 5.10.1 Data Preparation.- 5.11 Example.- 5.12 Example.- 5.13 Example.- 5.14 Example.- 6. Fluid Mechanics Applications.- 6.1 Introduction.- 6.2 Continuous Models of Fluid Flow.- 6.2.1 Incompressible Fluids.- 6.2.2 Inviscid Fluids.- 6.2.3 Irrotational Flows.- 6.2.4 Steady-State Flows.- 6.2.5 Bernoulli's Energy Conservation.- 6.2.6 Velocity Potential.- 6.2.7 Stream Function.- 6.3 Confined Flows.- 6.4 Unconfined Flows.- 6.5 Groundwater Flows.- 6.5.1 Darcy's Hypothesis.- 6.5.2 Dupuit's Hypothesis.- 6.6 Example.- 6.6.1 Flow Under a Dam.- 6.6.2 Problem's Solution.- 6.7 Example.- 6.7.1 Flow in an Unconfined Aquifer.- 6.7.2 Problem's Solution.- 7. Solid Mechanics Applications.- 7.1 Introduction.- 7.2 Continuous Models.- 7.3 Fundamental Continuous Model: Elasticity Theory.- 7.3.1 Strain-Displacement Equations.- 7.3.2 Equilibrium Equations.- 7.3.3 Stress-Strain Equations.- 7.3.4 Boundary Conditions.- 7.3.5 Elastic Fields.- 7.3.6 The Work Theorem.- 7.3.7 Theorem of Virtual Displacements.- 7.3.8 Theorem of Total Potential Energy.- 7.4 Finite Element Model.- 7.4.1 Weighted Residual Equation.- 7.4.2 Theorem of Work.- 7.4.3 Theorem of Virtual Displacements.- 7.4.4 Discretization.- 7.5 Mesh Topology.- 7.5.1 Total Strain Energy.- 7.5.2 Distribution of the Strain Energy Density.- 7.6 Constrained Displacements.- 7.7 Application of the Finite Element Model.- 7.8 Three-Dimensional Equilibrium States.- 7.8.1 Constant-Strain Tetrahedron Element.- 7.9 Two-Dimensional Equilibrium States.- 7.9.1 Plane Stress and Plane Strain.- 7.9.2 Asymptotic Model: Plane Elasticity.- 7.9.3 Constant-Strain Triangular Isoparametric Element.- 7.9.4 Cst_fem: Package for Finite Element Analysis.- 7.9.5 Data Preparation.- 7.9.6 Example.- 7.9.7 Example.- 7.9.8 Example.- 7.9.9 Example.- 7.10 One-Dimensional Equilibrium States.- 7.10.1 Asymptotic Model: Theory of Bars.- 7.10.2 Truss Element.- 7.10.3 Skew Elements.- 7.10.4 Beam Element.- 7.11 Further Study.

Additional information

NLS9783642627552
9783642627552
3642627552
Finite Elements Using Maple: A Symbolic Programming Approach by Artur Portela
Artur Portela
New
Paperback
Springer-Verlag Berlin and Heidelberg GmbH & Co. KG
2012-10-27
326
N/A
Book picture is for illustrative purposes only, actual binding, cover or edition may vary.
This is a new book - be the first to read this copy. With untouched pages and a perfect binding, your brand new copy is ready to be opened for the first time

Customer Reviews - Finite Elements Using Maple