Structural Analysis

About our author For over 20 years, Dr. James Hanson has blended his two greatest passions: engineering and teaching. His undergraduate and graduate degrees come from Cornell University where his engineering and teaching skills started developing. He further developed those skills as a structural engineer for a large chemical company and as an engineer officer in the US Army. As a result, he is a licensed professional engineer in New York and Indiana. Now he is a Professor of Civil and Environmental Engineering at Rose-Hulman Institute of Technology which means he gets to focus on developing pedagogies and testing their effectiveness. His specialty is speeding up the novice-to-expert transition in the area of evaluating the reasonableness of analysis and design results. Jim's passion for blending engineering and teaching have led to awards from the American Society for Engineering Education, the American Society of Civil Engineers and the American Concrete Institute. Perhaps the most telling awards, however, are the ones he received based on nominations from his current and former students: the Rose-Hulman Honorary Alumni Award and the Dean's Outstanding Teaching Award.

Loads and Structure Idealization

1.1 Loads
1.2 Load Combinations
1.3 Structure Idealization
1.4 Application of Gravity Loads
1.5 Application of Lateral Loads
1.6 Distribution of Lateral Loads by Flexible Diaphragm


Predicting Results

2.1 Qualitative Truss Analysis
2.2 Principle of Superposition
2.3 Principle of Superposition
2.4 Approximating Loading Conditions


Cables and Arches

3.1 Cables with Point Loads
3.2 Cables with Uniform Loads
3.3 Arches


Internal Force Diagrams

4.1 Internal Forces by Integration
4.2 Constructing Diagrams by Deduction
4.3 Diagrams for Frames


Deformations

5.1 Double Integration Method
5.2 Conjugate Beam Method
5.3 Virtual Work Method


Influence Lines

6.1 Table-of-Points Method
6.2 Müller-Breslau Method
6.3 Using Influence Lines


Introduction to Computer Aided Analysis

7.1 Why Computer Results are Always Wrong
7.2 Checking Fundamental Principles
7.3 Checking Features of the Solution


Approximate Analysis of Indeterminate Trusses and Braced Frames

8.1 Indeterminate Trusses
8.2 Braced Frames with Lateral Loads
8.3 Braced Frames with Gravity Loads


Approximate Analysis of Rigid Frames

9.1 Gravity Load Method
9.2 Portal Method for Lateral Loads
9.3 Cantilever Method for Lateral Loads
9.4 Combined Gravity and Lateral Loads


Approximate Lateral Displacements

10.1 Braced Frames — Story Drift Method
10.2 Braced Frames — Virtual Work Method
10.3 Rigid Frames — Stiff Beam Method
10.4 Rigid Frames — Virtual Work Method
10.5 Solid Walls — Single Story
10.6 Solid Walls — Multistory


Diaphragms

11.1 Distribution of Lateral Loads by Rigid Diaphragm
11.2 In Plane Shear: Collector Beams
11.3 In Plane Moment: Diaphragm Chords


Force Method

12.1 One Degree Indeterminate Beams
12.2 Multi-Degree Indeterminate Beams
12.3 Indeterminate Trusses


Moment Distribution Method

13.1 Overview of Method
13.2 Fixed End Moments and Distribution Factors
13.3 Beams and Sidesway Inhibited Frames
13.4 Sidesway Frames


Direct Stiffness Method for Trusses

14.1 Overview of Method
14.2 Transformation and Element Stiffness Matrices
14.3 Compiling the System of Equations
14.4 Finding Deformations, Reactions and Internal Forces
14.5 Additional Loadings


Direct Stiffness Method for Frames

15.1 Element Stiffness Matrix
15.2 Transformation Matrix
15.3 Global Stiffness Matrix
15.4 Loads Between Nodes
15.5 Direct Stiffness Method
15.6 Internal Forces