Introduction to the Finite Element Method 4E

J. N. Reddy, Ph.D. is an ISI Highly Cited Researcher and the author of over 650 journal papers and 21 books. He is a Life Fellow and ASME Medalist of the American Society of Mechanical Engineers (ASME), and a Fellow of all major professional societies of engineering. He has also received top mechanics medals from various societies. Dr. Reddy is a Member of the U.S. National Academy of Engineering and Foreign Fellow of the Canadian Academy of Engineering, Indian National Academy of Engineering, and Brazilian National Academy of Engineering.

1 General Introduction 
1.1 Background
1.2 Mathematical Model Development 
1.3 Numerical Simulations 
1.4 The Finite Element Method
1.5 The Present Study 
1.6 Summary 
Problems 
References for Additional Reading 


2 Mathematical Preliminaries and Classical Variational Methods
2.1 General Introduction 
2.2 Some Mathematical Concepts and Formulae
2.3 Energy and Virtual Work Principles 
2.4 Integral Formulations of Differential Equations
2.5 Variational Methods
2.6 Equations of Continuum Mechanics
2.7 Summary 
Problems 
References for Additional Reading


3 1-D Finite Element Models of Second-Order Differential Equations
3.1 Introduction 
3.2 Finite Element Analysis Steps 
3.3 Finite Element Models of Discrete Systems
3.4 Finite Element Models of Continuous Systems
3.5 Axisymmetric Problems
3.6 Errors in Finite Element Analysis 
3.7 Summary 
Problems
References for Additional Reading 


4 Applications to 1-D Heat Transfer and Fluid and Solid
Mechanics Problems 
4.1 Preliminary Comments 
4.2 Heat Transfer 
4.3 Fluid Mechanics
4.4 Solid and Structural Mechanics 
4.5 Summary 
Problems
References for Additional Reading


5 Finite Element Analysis of Beams and Circular Plates 
5.1 Introduction 
5.2 Euler–Bernoulli Beam Element 
5.3 Timoshenko Beam Elements
5.4 Axisymmetric Bending of Circular Plates 
5.5 Summary 
Problems 
References for Additional Reading 


6 Plane Trusses and Frames 
6.1 Introduction 
6.2 Analysis of Trusses 
6.3 Analysis of Plane Frame Structures
6.4 Inclusion of Constraint Conditions 
6.5 Summary 
Problems 
References for Additional Reading 


7 Eigenvalue and Time-Dependent Problems in 1-D 
7.1 Introduction 
7.2 Equations of Motion 
7.3 Eigenvalue Problems 
7.4 Transient Analysis
7.5 Summary 
Problems 
References for Additional Reading


8 Numerical Integration and Computer Implementation 
8.1 Introduction 
8.2 Numerical Integration 
8.3 Computer Implementation 
8.4 Applications of Program FEM1D 
8.5 Summary 
Problems
References for Additional Reading 


9 Single-Variable Problems in Two Dimensions 
9.1 Introduction 
9.2 Boundary Value Problems 
9.3 Modeling Considerations 
9.4 Numerical Examples 
9.5 Eigenvalue and Time-Dependent Problems
9.6 Summary 
Problems 
References for Additional Reading 


10 2-D Interpolation Functions, Numerical Integration, and Computer Implementation 
10.1 Introduction 
10.2 2-D Element Library
10.3 Numerical Integration 
10.4 Modeling Considerations 
10.5 Computer Implementation and FEM2D
10.6 Summary
Problems
References for Additional Reading


11 Flows of Viscous Incompressible Fluids
11.1 Introduction
11.2 Governing Equations
11.3 Velocity–Pressure Formulation
11.4 Penalty Function Formulation 
11.5 Computational Aspects 
11.6 Numerical Examples 
11.7 Summary 
Problems 
References for Additional Reading


12 Plane Elasticity 
12.1 Introduction
12.2 Governing Equations 
12.3 Virtual Work and Weak Formulations
12.4 Finite Element Model 
12.5 Elimination of Shear Locking in Linear Elements
12.6 Numerical Examples 
12.7 Summary
Problems 
References for Additional Reading 


13 3-D Finite Element Analysis 
13.1 Introduction 
13.2 Heat Transfer
13.3 Flows of Viscous Incompressible Fluids 
13.4 Elasticity 
13.5 Element Interpolation Functions and Numerical Integration 
13.6 Numerical Examples
13.7 Summary 
Problems
References for Additional Reading 


Index