Published in 1991, the first edition ofForecasting and Management of Technology was one of the leading handful of books to deal with the topic of forecasting of technology and technology management as this discipline was emerging. The new, revised edition of this book will build on this knowledge in the context of business organizations that now place a greater emphasis on technology to stay on the cutting edge of development. The scope of this edition has broadened to include management of technology content that is relevant to now to executives in organizations while updating and strengthening the technology forecasting and analysis content that the first edition is reputed for.

Updated by the original author team, plus new author Scott Cunningham, the book takes into account what the authors see as the innovations to technology management in the last 17 years: the Internet; the greater focus on group decision-making including process management and mechanism design; and desktop software that has transformed the analytical capabilities of technology managers. Included in this book will be 5 case studies from various industries that show how technology management is applied in the real world.

ALAN THOMAS ROPER (retired) was a professor at Rose-Hulman Institute of Technology in Terre Haute, Indiana. He is the past editor of the journal Impact Assessment and Project Appraisal and the past director of the Center for Technology and Policy Studies at Rose-Hulman.

SCOTT W. CUNNINGHAM obtained a MSc in public policy from the Georgia Institute of Technology and a DPhil in science, technology, and innovation policy from the University of Sussex. He is currently Assistant Professor of Policy Analysis in the Department of Technology, Policy, and Management at Delft University of Technology.

ALAN L. PORTER has led development of "technology opportunity analysis" and mining electronic, bibliographic data sources to generate intelligence on emerging technologies. He holds an MA in psychology and a PhD in engineering psychology, both from UCLA. He is currently Director of Research and Development for Search Technology, Inc., in Norcross, Georgia.

THOMAS W. MASON was the founding head of the Engineering Management Department (www.rose-hulman.edu/msem). While on a three-year leave from Rose-Hulman, he served as CFO and CEO of a 140-person network management systems business.

FREDERICK A. ROSSINI (retired) is a former provost at George Mason University in Fairfax, Virginia.

JERRY BANKS is Professor Emeritus, Department of Industrial and Systems Engineering, Georgia Institute of Technology in Atlanta, Georgia.

Acknowledgments xv

1 Introduction 1

1.1 About This Book 1

1.2 Technology and Society 2

1.2.1 Social Change 3

1.2.2 Technological Change 4

1.3 Management and the Future 6

1.3.1 Management and Innovation Processes 7

1.3.2 The Role of Technology Forecasting 9

1.3.3 The Importance of Technology Forecasting 10

1.3.4 The Role of Social Forecasting 12

1.4 Conclusions 13

References 13

2 Technology Forecasting 15

2.1 What Is Technology Forecasting? 15

2.1.1 Models of Technology Growth and Diffusion 17

2.1.2 Technology Forecasting in Context 18

2.1.3 What Makes a Forecast Good? 20

2.1.4 Common Errors in Forecasting Technology 21

2.2 Methodological Foundations 23

2.2.1 The Technology Delivery System 24

2.2.2 Inquiring Systems 28

2.3 Technology Forecasting Methods 31

2.3.1 Overview of the Most Frequently Used Forecasting Methods 33

2.3.2 Method Selection 37

2.4 Conclusion 37

References 38

3 Managing the Forecasting Project 40

3.1 Information Needs of the Forecasting Project 40

3.1.1 The Technology Managers Needs 42

3.1.2 The Forecast Managers Needs 43

3.1.3 Information about Team Members 44

3.2 Planning the Technology Forecast 46

3.3 Team Organization, Management, and Communications 47

3.3.1 Organizing and Managing the Technology Forecast 50

3.3.2 Communications 54

3.3.3 Summary Conclusions about Project Management and Organization 55

3.4 Success: The Right Information at the Right Time 56

3.5 Project Scheduling 57

3.5.1 Program Evaluation and Review Technique (PERT) 58

3.5.2 Gantt Chart 60

3.5.3 Project AccountabilityChart (PAC) 60

3.5.4 Project Scheduling Software 61

3.6 Conclusions 62

References 62

4 Exploring 65

4.1 Establishing the Contextthe TDS 65

4.1.1 Societal and Institutional Contexts 66

4.1.2 Technology Context 67

4.1.3 Stakeholders 68

4.1.4 Understanding the TDS 69

4.1.5 An Example TDS Model 70

4.2 Monitoring 72

4.2.1 Why Monitor? 74

4.2.2 Who Should Monitor? 75

4.2.3 Monitoring Strategy 76

4.2.4 Monitoring Focused on Management of Technology Issues 79

4.2.5 Monitoring Focused on the Stage of the Technology Development 81

4.3 The Stimulation of Creativity 81

4.3.1 Five Elements of Creativity 81

4.3.2 Group Creativity 92

4.4 Conclusion 95

References 95

5 Gathering and Using Information 98

5.1 Expert Opinion 99

5.1.1 Selecting Experts 99

5.1.2 Selecting Expert Opinion Techniques 100

5.2 Gathering Information on the Internet 105

5.2.1 Science and Technology on the Internet 106

5.2.2 Society and Culture on the Internet 109

5.3 Structuring the Search 113

5.4 Preparing Search Results 116

5.5 Using Search Results 117

5.6 Developing Science, Technology, and Social Indicators 119

5.6.1 Science and Technology Indicators 119

5.6.2 Social Indicators 122

5.7 Communicating Search Results 122

5.8 Conclusions 123

References 124

6 Analyzing Phase 129

6.1 Perspective on Data and Methods 129

6.1.1 Overview and Caveats 130

6.1.2 Internet Time Series Data and Trends 132

6.1.3 Analytical Modeling 133

6.2 Linear Regression and Extensions 134

6.3 Growth Models 138

6.3.1 The Models 138

6.3.2 Dealing with the Data 143

6.3.3 Regression and Growth Modeling: What Can Go Wrong? 144

6.4 Simulation 145

6.4.1 Quantitative Cross-Impact Analysis 146

6.4.2 Qualitative Cross-Impact Analysis 152

6.5 Monte Carlo Simulation 153

6.5.1 Generating and Displaying Random Values 153

6.5.2 Sampling Multiple Random Variables 154

6.5.3 RFID Application in a Hospital Decision 156

6.6 System Dynamics 158

6.6.1 The System Dynamics Modeling Cycle 159

6.6.2 A Technology Forecasting Example: The Cable-to-the-Curb Model 162

6.7 Gaming 164

6.7.1 Decision Trees 165

6.7.2 Bayesian Estimation 166

6.7.3 Value of Information 167

6.7.4 Real Options Analysis 169

6.8 Software Suggestions 170

6.8.1 Software for Regression 170

6.8.2 Simulation Analysis Software 170

6.8.3 Software for Analysis of Decisions 170

6.8.4 Real Options Super Lattice Software 170

6.8.5 Software Sites 171

References 171

7 Focusing Phase: Using Scenario Analysis 174

7.1 Uncertainty 175

7.1.1 Uncertainty Frameworks 175

7.1.2 Source and Nature of Uncertainty 176

7.1.3 Uncertainty and the Adaptive Paradigm 177

7.1.4 Techniques for Addressing Uncertainty 177

7.2 Scenarios 178

7.2.1 Steps in Creating Scenarios 178

7.2.2 Types of Scenarios 182

7.3 Examples and Applications 184

7.3.1 Scenarios for Renewable Energy Planning 184

7.3.2 Pervasive Computing Scenarios 185

7.3.3 Scenarios for Social Change 186

7.4 Scenarios: Extensions and Advanced Techniques 187

7.4.1 Scenarios in Multimethodology Forecasts 187

7.4.2 Extensions of Scenario Analysis 189

7.5 Conclusions 191

References 192

8 Economic and Market Analysis 194

8.1 The Context 194

8.1.1 Markets and Innovation 197

8.1.2 Technology and Institutions 199

8.2 Forecasting the Market 203

8.2.1 The Consumer/Customer Marketplace 204

8.2.2 Qualitative Techniques for Appraising Market Potential 206

8.2.3 A Quantitative ApproachAdoption and Substitution: S-Curve Models 207

8.3 Forecasting the Economic Context 208

8.3.1 Macroeconomic Forecasting 209

8.3.2 Input-Output Analysis 210

8.3.3 General Equilibrium Models 214

8.3.4 Hedonic Technometrics 215

8.4 Forecasting in an Institutional Context 216

8.4.1 Institutional Arrangements and the Market 216

8.4.2 Game Theory 218

8.4.3 Agent-Based Models 219

8.5 Conclusion 219

References 220

9 Impact Assessment 223

9.1 Impact Assessment in Technology Forecasting 223

9.2 Impacts on Technology and Impacts of Technology 224

9.3 A Comprehensive Approach to Impact Assessment 225

9.4 Impact Identification 226

9.4.1 Scanning Techniques 226

9.4.2 Tracing Techniques 227

9.4.3 Narrowing the Impact Set and Estimating Effects 229

9.4.4 A Final Word 229

9.5 Impact Analysis 230

9.5.1 Analyzing Impacts on and Impacts of the Technology 230

9.5.2 Analyzing Technological Impacts 232

9.5.3 Analyzing Economic Impacts 234

9.5.4 Analyzing Environmental Impacts 234

9.5.5 Analyzing Social Impacts 238

9.5.6 Analyzing Institutional Impacts 239

9.5.7 Analyzing Political Impacts 240

9.5.8 Analyzing Legal and Regulatory Impacts 241

9.5.9 Analyzing Behavioral, Cultural, and Values Impacts 242

9.5.10 Analyzing Health-Related Impacts 243

9.6 Impact Evaluation 244

9.7 Conclusion 245

References 245

10 Cost-Benefit and Risk Analysis 248

10.1 Opportunity Costs and Choices 248

10.2 Cost-Benefit Analysis 249

10.2.1 Cost-Benefit Analysis within the Organization 249

10.2.2 Societal Stake and the Organizational Response 253

10.2.3 Cost-Benefit Analysis Methods 260

10.2.4 Economic Value Added 263

10.2.5 Earned Value Management 264

10.2.6 The Balanced Scorecard 265

10.3 Accounting for Risk and Uncertainty 265

10.3.1 Accounting for Risk within Organizations 265

10.3.2 Accounting for Riskthe Social Dimension 269

10.4 Concluding the Focusing Phase 273

References 274

11 Implementing the Technology 277

11.1 Forecasting Continues 277

11.2 Implementation Issues 278

11.3 Strategic Planning for Technology Implementation 278

11.4 Selecting from among Alternative Implementations of the Technology 279

11.4.1 Measurement 282

11.4.2 Interpretive Structural Modeling 284

11.4.3 Analytic Hierarchy Process 285

11.4.4 Wrap-Up 286

11.5 Technology Roadmapping 286

11.6 Summary and Concluding Observations 287

References 287

12 Managing the Present from the Future 289

12.1 The Overall Approach 289

12.2 Selecting Methods and Techniques 290

12.2.1 Using the TDS and the Major Families of Techniques 290

12.2.2 The 8020 Rule 291

12.3 Alternative Perspectives 291

12.4 Learning from Past Forecasts and Assessments 293

12.5 Visions 295

12.6 A Final Word 295

References 296

Appendix A Case Study on Forecasting Dye-Sensitized Solar Cells 297

A.1 Framing the Case Study 297

A.1.1 Characterizing the Technology 298

A.1.2 Dye-Sensitized Solar Cells 299

A.2 Methods 299

A.2.1 Engaging Experts and Multipath Mapping 299

A.2.2 Developing the TDS 300

A.2.3 Tech Mining (Chapter 5) and Science Overlay Mapping 304

A.2.4 Trend Analyses 310

A.2.5 Cross-charting and Social Network Analyses 311

A.3 The Rest of the Story 313

A.3.1 Market Forecasts 314

A.3.2 Scenarios 315

A.3.3 Technology Assessment 315

A.3.4 Further Analyses and Communicating Results 316

References 316

Index 319