3D scanning for advanced manufacturing, design, and construction / Gary C. Confalone, John Smits, Thomas Kinnare.

Includes bibliographical references and index.

Table of Contents
Preface xi

How to Use This Book xiii

Chapter 1 History of Metrology 1

1.1 Introduction 2

1.2 The History of Metrology 2

1.3 The International System of Units (SI) 3

1.4 The History of the Metric System 3

1.5 The History of the British Imperial System (IS) 4

1.6 Evolution of Metrology 13

1.7 Milestones of Metrology 22

Chapter 2 3D Scanning Basics 25

2.1 Basics of Laser Light Technology 25

2.2 Laser Safety 25

2.3 So What Exactly Is a Laser? 28

2.4 Laser Types 29

2.5 LIDAR vs Laser-Radar 32

2.6 Laser-Radar 32

2.7 Basics of 3D Scanning 35

2.8 How It Works 35

2.9 Limitations 35

2.10 Accuracy 36

2.11 Modern Metrology 37

Chapter 3 Scanning Equipment 39

3.1 Introduction 39

3.2 Triangulating Laser Scanners 39

3.3 Data Acquisition Variables 41

Chapter 4 Data Acquisition and Processing Software 65

4.1 Introduction 65

4.2 Data Acquisition Software 66

4.3 Inspection Software 71

4.4 Data Export Options 72

4.5 Point Clouds 73

4.6 Processing and Registration 78

4.7 Survey Controls 80

4.8 Polygonal Mesh 81

4.9 Using Processed Datasets 82

Chapter 5 Post-Processing 85

5.1 Introduction 85

5.2 Coordinate Systems 86

5.3 Scaling 93

5.4 Mapping Techniques 93

5.5 CAD to Part Comparison 97

5.6 Root Mean Square and Standard Deviation 98

5.7 The Method of Least Squares 99

5.8 What Is Uncertainty? 102

5.9 Contributing Factors to Uncertainty 105

5.10 Typical Post-processing Workflow 108

Chapter 6 Reverse Engineering for Industrial and Consumer Applications 111

6.1 Introduction 111

6.2 Industrial Applications 112

6.3 Case Studies 118

6.4 Racing Yacht Boat Build 118

6.5 Reverse Engineering: Cessna Caravan Performance Upgrade 121

6.6 Replication of a Classic Propeller Design 123

6.7 Roller Coaster Inspection 126

6.8 Argomaiden Sculpture 129

Chapter 7 Reverse Engineering for Architecture, Engineering, and Construction 133

7.1 Introduction 133

7.2 Modeling for Architects and Engineers 134

7.3 Case Studies 142

7.4 Research Facility Coordinate Control System 142

7.5 Architectural Ornament Replication 146

7.6 Fonthill Castle, Bronx, NY 149

7.7 Infrastructure Preservation 153

7.8 Generating Station Turbine Replacement 158

Chapter 8 Future Directions 161

8.1 Software Development 162

8.2 Technology 162

8.3 Extended Reality 163

8.4 UAV and AV 165

8.5 Industry Trends 165

8.6 Summary 168

Chapter 9 Resources 169

9.1 Units of Measure 175

9.2 Coordinate Metrology Society (CMS) Certification 181

9.3 Certification Committee 181

9.4 CMS Certification Levels 183

9.5 CMS Level-Two Certification 185

9.6 National Metrology Laboratories and Institutes 187

Metrology Glossary 191

Index 201

"As discussed in the introductory chapter of this textbook, power electronics is an enabling technology for powering information technology and making factory automation feasible. In addition, power electronics has a crucial role to play in providing sustainable electric energy. Most scientists now believe that carbon-based fuels for energy production con- tribute to climate change, which is a serious threat facing human civilization. In the United States, the Department of Energy reports that approximately 40% of all the energy consumed is first converted into electricity. Potentially, use of electric and plug-in hybrid cars, high speed rails, and so on may increase this to even 60%. Therefore, it is essential that we generate electricity from renewable sources such as wind and solar, which at present represent only slightly over 4%, build the next-generation smarter and robust grid to utilize renewable resources often in remote locations, and use electricity in more energy-efficient ways. Undoubtedly, using electricity efficiently and generating it from renewable sources are the twin pillars of sustainability, and as described in this textbook, power electronic systems are a key to them both."-- Provided by publisher.

About the Author
Gary C. Confalone, BSEE, MSME, is the CEO of ECM Global, a company specializing in 3D scanning and reverse engineering. He has spent the past three decades working in the metrology industry with the first half of his career focused on the development of laser-based measurement systems, and processes, for the aerospace industry. He has served as Chair for both the Coordinate Metrology Society and the 3D Certification Committee, and was recently awarded the American Society for Quality (ASQ) Hromi Medal. Gary received a Bachelor's degree from the University of Massachusetts, and a Master’s Degree from Boston University.

John Smits, AIA, is VP of ECM, AEC Division, a registered architect, and one of the initial adopters of large volume 3D laser scanning technology as applied specifically to the architecture, engineering, and construction professions. He has shared his expertise as a speaker at trade shows, conferences, and online webinars, and authored articles in academic journals and trade magazines. John earned a Bachelor’s degree in Architecture from the University of Virginia and a Master’s degree in Architecture from Washington University in St. Louis.

Thomas Kinnare, BSME, is Principal Engineer and lead developer of the ECM Training Division. Over the past two decades, Tom has been instrumental in the advancement of 3D metrology practices throughout the industry, working to institute an international metrology education and certification training program. He currently serves on the American Society of Mechanical Engineers (ASME) Y14.45, GD&T Reporting Subcommittee, and the Coordinate Measurement Society Certification Committee. Tom earned his Bachelor’s degree from Massachusetts Institute of Technology.