Experimental solid mechanics is the study of materials to determine their physical properties. This study might include performing a stress analysis or measuring the extent of displacement, shape, strain and stress which a material suffers under controlled conditions. In the last few years there have been remarkable developments in experimental techniques that measure shape, displacement and strains and these sorts of experiments are increasingly conducted using computational techniques.

Experimental Mechanics of Solids is a comprehensive introduction to the topics, technologies and methods of experimental mechanics of solids. It begins by establishing the fundamentals of continuum mechanics, explaining key areas such as the equations used, stresses and strains, and two and three dimensional problems. Having laid down the foundations of the topic, the book then moves on to look at specific techniques and technologies with emphasis on the most recent developments such as optics and image processing. Most of the current computational methods, as well as practical ones, are included to ensure that the book provides information essential to the reader in practical or research applications.

Key features:

• Presents widely used and accepted methodologies that are based on research and development work of the lead author
• Systematically works through the topics and theories of experimental mechanics including detailed treatments of the Moire, Speckle and holographic optical methods
• Includes illustrations and diagrams to illuminate the topic clearly for the reader
• Provides a comprehensive introduction to the topic, and also acts as a quick reference guide

This comprehensive book forms an invaluable resource for graduate students and is also a point of reference for researchers and practitioners in structural and materials engineering.

Cesar & Federico Sciammarella, University of Illinois, USA Cesar A Sciammarella is Adjunct Professor in the Department of Mechanical Engineering, University of Illinois, USA. In the past he has worked as a consultant for companies including: General Motors, Goodyear, Honeywell Corporation, Rand Corporation, Rockwell International, Sundstran, Uniroyal Tires, IBM, Tryodyne, Samsung, Case Corporation. A renowned experimentalist, his research currently focuses on developing techniques in solid mechanics and he has spoken at many conferences and published prolifically in journals which include Strain; Optical Engineering; SEM Conference on Experimental Mechanics and Journal of Strain Analysis for Engineering Design. Federico Sciammarella is Assistant Professor in the Department of Mechanical Engineering, University of Illinois. His research interests centre upon using optical methods for characterization of materials and structures including failure analysis. Over the past five years he has written multiple journal and conference research papers.

About the Authors xvii

Preface xix

Foreword xxi

1 Continuum Mechanics - Historical Background 1

1.1 Definition of the Concept of Stress 4

1.2 Transformation of Coordinates 5

1.3 Stress Tensor Representation 6

1.4 Principal Stresses 8

1.5 Principal Stresses in Two Dimensions 10

1.6 The Equations of Equilibrium 11

1.7 Strain Tensor 13

1.8 Stress - Strain Relations 15

1.9 Equations of Compatibility 18

References 19

2 Theoretical Stress Analysis - Basic Formulation of Continuum Mechanics. Theory of Elasticity 21

2.1 Introduction 21

2.2 Fundamental Assumptions 21

2.3 General Problem 22

2.4 St. Venant's Principle 25

2.5 Plane Stress, Plane Strain 28

2.6 Plane Stress Solution of a Simply Supported Beam with a Uniform Load 30

2.7 Solutions in Plane Strain and in Plane Stress 33

2.8 The Plane Problem in Polar Coordinates 35

2.9 Thick Wall Cylinders 36

References 39

3 Strain Gages - Introduction to Electrical Strain Gages 41

3.1 Strain Measurements - Point Methods 41

3.2 Electrical Strain Gages 42

3.3 Basics of Electrical Strain Gages 43

3.4 Gage Factor 45

3.5 Basic Characteristics of Electrical Strain Gages 48

3.6 Errors Due to the Transverse Sensitivity 54

3.7 Errors Due to Misalignment of Strain Gages 58

3.8 Reinforcing Effect of the Gage 60

3.9 Effect of the Resistance to Ground 61

3.10 Linearity of the Gages. Hysteresis 63

3.11 Maximum Deformations 64

3.12 Stability in Time 64

3.13 Heat Generation and Dissipation 64

3.14 Effect of External Ambient Pressure 65

3.15 Dynamic Effects 67

References 71

4 Strain Gages Instrumentation - TheWheatstone Bridge 75

4.1 Introduction 75

References 109

5 Strain Gage Rosettes: Selection, Application and Data Reduction 111

5.1 Introduction 111

5.2 Errors, Corrections, and Limitations for Rosettes 119

5.3 Applications of Gages to Load Cells 119

References 121

6 Optical Methods - Introduction 123

6.1 Historical Perspective and Overview 123

6.2 Fundamental Basic Definitions of Optics 127

6.3 The Electromagnetic Theory of Light 128

6.4 Properties of Polarized Light 137

6.5 The Jones Vector Representation 138

6.6 Light Intensity 141

6.7 Refraction of the Light 141

6.8 Geometrical Optics. Lenses and Mirrors 146

References 154

7 Optical Methods - Interference and Diffraction of Light 155

7.1 Connecting Light Interference with Basic Optical Concepts 155

7.2 Light Sources 155

7.3 Interference 161

7.4 Interferometers 166

7.5 Diffraction of the Light 171

References 181

8 Optical Methods - Fourier Transform 183

8.1 Introduction 183

8.2 Simple Properties 185

8.3 Transition to Two Dimensions 187

8.4 Special Functions 188

8.5 Applications to Diffraction Problems 191

8.6 Diffraction Patterns of Gratings 193

8.7 Angular Spectrum 195

8.8 Utilization of the FT in the Analysis of Diffraction Gratings 199

References 205

9 Optical Methods - Computer Vision 207

9.1 Introduction 207

9.2 Study of Lens Systems 208

9.3 Lens System, Coordinate Axis and Basic Layout 210

9.4 Diffraction Effect on Images 211

9.5 Analysis of the Derived Pupil Equations for Coherent Illumination 216

9.6 Imaging with Incoherent Illumination 217

9.7 Digital Cameras 230

9.8 Illumination Systems 242

9.9 Imaging Processing Systems 245

9.10 Getting High Quality Images 246

References 249

10 Optical Methods - Discrete Fourier Transform 251

10.1 Extension to Two Dimensions 253

10.2 The Whittaker-Shannon Theorem 257

10.3 General Representation of the Signals Subjected to Analysis 261

10.4 Computation of the Phase of the Fringes 271

10.5 Fringe Patterns Singularities 276

10.6 Extension of the Fringes beyond Boundaries 279

References 283

11 Photoelasticity - Introduction 285

11.1 Introduction 285

11.2 Derivation of the Fundamental Equations 286

11.3 Wave Plates 291

11.4 Polarizers 293

11.5 Instrument Matrices 294

11.6 Polariscopes 296

11.7 Artificial Birefringence 304

11.8 Polariscopes 307

11.9 Equations of the Intensities of the Plane Polariscope and the Circular Polariscope for a Stressed Plate 309

References 311

12 Photoelasticity Applications 313

12.1 Calibration Procedures of a Photoelastic Material 313

12.2…