Introduction to Structural Analysis Displacement and Force Methods

Truss Analysis: Matrix Displacement Method
What Is a Truss?
A Truss Member
Member Stiffness Equation in Global Coordinates
Unconstrained Global Stiffness Equation
Constrained Global Stiffness Equation and Its Solution
Procedures of Truss Analysis
Kinematic Stability
Summary

Truss Analysis: Force Method—Part I
Introduction
Statically Determinate Plane Truss Types
Method of Joints and Method of Sections
Matrix Method of Joints

Truss Analysis: Force Method—Part II
Truss Deflection
Indeterminate Truss Problems: Method of Consistent Deformations
Laws of Reciprocity
Concluding Remarks

Beam and Frame Analysis: Force Method—Part I
What Are Beams and Frames?
Statical Determinacy and Kinematic Stability
Shear and Moment Diagrams
Statically Determinate Beams and Frames

Beam and Frame Analysis: Force Method—Part II
Deflection of Beams and Frames
Integration Methods
Energy Methods
Frame Deflection

Beam and Frame Analysis: Force Method—Part III
Statically Indeterminate Beams and Frames
Indeterminate Beam Analysis
Indeterminate Frame Analysis

Beam and Frame Analysis: Displacement Method—Part I
Introduction
Moment Distribution Method

Beam and Frame Analysis: Displacement Method—Part II
Slope-Deflection Method
Matrix Stiffness Analysis of Frames

Influence Lines
What Is an Influence Line?
Beam Influence Lines
Truss Influence Lines

Other Topics
Introduction
Non-Prismatic Beam and Frame Members
Effects of Support Movement, Temperature, and Construction Error
Secondary Stresses in Trusses
Composite Structures
Materials Nonlinearity
Geometric Nonlinearity
Structural Stability
Dynamic Effects
Finite Element Method

Biography

S.T. Mau, PhD, PE, is a professor in the Department of Civil Engineering and Applied Mechanics at California State University, Northridge. He was formerly Dean of Engineering at New Jersey Institute of Technology and California State University, Northridge, and department chair at National Taiwan University and University of Houston. He is also the co-author of a previous textbook, Elementary Theory of Structures, Fourth Edition (1995), and a recipient of the Moisseiff Award of the American Society of Civil Engineers.

"This book covers most important materials of a first course on structural analysis. It is organized logically, presented concisely and written well. Classical analysis methods and modern matrix stiffness methods are of good balance. ... a very readable textbook."
—Liang-Jenq Leu, Department of Civil Engineering, National Taiwan University, Taiwan

"This book has two important features that make it unique - Both the force and displacement methods of analysis are given equal emphasis, and the matrix method is introduced at a very early stage. While the force method is important for students to learn how structures behave, the displacement method on which the matrix method is based has indubitable practical significance. Dr. Mau has done a superb job in espousing both theory and practice in his textbook."
—Eric Lui, Syracuse University, New York, USA