Concept-Oriented Research and Development in Information Technology

KINJI MORI, PhD, is Professor in the Department of Green Computing Systems Research Organization at Waseda University, Japan and Professor Emeritus at the Tokyo Institute of Technology, Japan in the Department of Computer Science. Previously, Dr. Mori worked at Hitachi as Chief Researcher. He is a Fellow of IEEE and IEICE. Dr. Mori is the pioneer of the concept-oriented research and development, and he proposed the Autonomous Decentralized Systems Concept and realized its concept-oriented technologies and applications. He founded the IEEE International Symposium on Autonomous Decentralized Systems. Dr. Mori holds more than 350 patents and has received the Special Distinguished Ichimura Award, the Japan Patent Award, and the Research Achievement Award in Japan, among others.

Foreword xv

Preface xvii

Contributors xxi

Part I Introduction 1

1 Introduction 3
Kinji Mori

1.1 Factors of Research and Development (R&D) Approaches 5

1.1.1 Needs 5

1.1.2 Subjects 6

1.1.3 Situations 6

1.1.4 Evaluation 6

1.2 R&D Approaches 7

1.2.1 Technology-Oriented R&D 7

1.2.2 Solution-Oriented R&D 9

1.2.3 Concept-Oriented R&D 10

1.2.4 R&D Strategies 11

1.3 Autonomous Decentralized System (ADS) Concept and Its R&D 13

1.3.1 Background and Requirements 14

1.3.2 Biological Analogy and Concept 16

1.3.3 System Architecture 18

1.3.4 Chain of Technologies and Markets 20

References 26

Part II Concept Creation 29

2 Challenges in Technology Education and System Development in Software Ecosystem Environment 35
C. V. Ramamoorthy and Xiaodong Lu

Abstract 35

2.1 Introduction 36

2.2 Importance of Education 37

2.2.1 Current State of Education 37

2.2.2 Skills and Approaches 37

2.3 Needs Engineering 39

2.4 Software Ecosystem 40

2.5 Summary and Conclusions 43

References 44

3 Concept-Oriented Research and Development from Social and Cultural Perspectives 45
Katsuhiko Shirai

Abstract 45

3.1 Introduction 46

3.2 R&D and Engineering Education 47

3.3 R&D and Systems Approach 48

3.4 R&D and Social Demand 49

3.5 Autonomous Decentralized System (ADS) Requirements 49

3.6 Concept Creation and Innovation 51

3.7 Conclusions 52

References 53

4 Roads to Smarter Cities 55
Colin Harrison

Abstract 55

4.1 Introduction 55

4.2 IBM’s Strategy 56

4.2.1 Preparing for the Decade of Smart Technology 57

4.2.2 Determining Which Important Problems IBM Should Solve 59

4.2.3 Applying the New Conceptual Framework 60

4.3 Use of Platform in the Deployment Phase 61

4.3.1 Reference Architecture 61

4.3.2 Smarter Planet 63

4.4 Smarter Cities 63

4.4.1 MASDAR City Project 63

4.4.2 Role of Information Technology 65

4.4.3 Global Urban Trends 66

4.4.4 Integrated Intelligent Management System 67

4.5 The Future 68

4.6 Conclusions 69

References 69

5 Advancing Knowledge and Evolving Society 71
Alfonso Fuggetta

Abstract 71

5.1 Introduction 72

5.2 Research and Innovation 72

5.2.1 A Misused Term 72

5.2.2 The Meaning of Innovation 73

5.2.3 Characteristics of Research and Innovation 76

5.3 Innovation and Technology Transfer 79

5.3.1 A Misleading Association 79

5.3.2 The Nature of Technology Transfer 80

5.4 The CEFRIEL Experience 83

5.4.1 Supporting Innovation 83

5.4.2 CEFRIEL 85

5.5 Conclusions 86

References 87

Part III Fusion of Technologies 89

6 Fusion of Technologies 93
Yinong Chen

Abstract 93

6.1 Introduction 94

6.2 Hardware–Software Fusion 95

6.3 Computing and Communication 95

6.4 Virtual and Physical Reality 96

6.5 Service-Oriented Architecture 98

6.6 Mashup 100

6.7 Cloud Computing 102

6.8 Concept-Oriented System Development 105

6.9 Conclusion 106

References 107

7 Fusion of Computer and Communication 109
Hermann Kopetz

Abstract 109

7.1 Introduction 110

7.2 Historical Perspective 110

7.2.1 Early Days 110

7.2.2 Technology Push versus Application Pull 111

7.2.3 Increasing the Level of Abstraction 111

7.3 System of Systems 112

7.3.1 Basic Concepts 114

7.3.2 Constituent System versus System of Systems 114

7.3.3 A Paradigm Shift in Design 116

7.4 Problem Solving 116

7.4.1 Abstract–Concrete Problem Transformation 117

7.4.2 Problem Solving System (PSS) 117

7.4.3 Relied-on Interfaces 119

7.5 Role of Trust 119

7.6 Example: ATM Application 120

7.6.1 The ATM 120

7.6.2 ATM Client Problem Specifi cation 121

7.6.3 Scope of ATM Application 122

7.7 Conclusions 122

References 122

8 Future of Railway Signaling and Train Control 123
Tang Tao and Xun Jing

Abstract 123

8.1 Introduction 124

8.2 History of Developments in the Train Control Industry 124

8.3 The Current Status of Communication-Based Train Control (CBTC) 126

8.3.1 European Train Control System (ETCS) 126

8.3.2 Chinese Train Control System (CTCS) 127

8.3.3 CBTC in Mass Transit 128

8.4 Future Trends in Train Control Technology 130

8.4.1 From Unattended Train Operation (UTO) to Driverless Train Operation (DTO) 130

8.4.2 From Fixed Block to Moving Block 131

8.4.3 From Decentralization to Centralization 132

8.4.4 From Nonstandard to Standard (Modular) 132

8.5 Conclusion 132

References 133

9 Fusion of Control Systems, Computers, and the Real World 135
Yasushi Fukunaga

Abstract 135

9.1 Introduction 136

9.2 Reseach and Development in the “Chaos Era” 137

9.3 Birth and Development of the Computer Control System 139

9.4 New ICT System 140

9.5 Conclusion and Proposed Future Expansion 143

Acknowledgments 144

References 144

10 Fusion of Computer, Communication, and Control Technologies: Needs and Strategies 147
Masayoshi Tomizuka

Abstract 147

10.1 Introduction 148

10.2 Dynamic Systems and Control 148

10.2.1 Historical Perspective 148

10.2.2 Kalman Filtering 150

10.2.3 Rule-Based Control 151

10.3 Computers in Control Systems 151

10.4 Networked Control Systems 152

10.5 Communications in Robotics 153

10.6 Vehicle Applications 153

10.7 Cyberphysical Systems 155

10.8 National Science Foundation 155

10.9 Conclusions 156

References 157

Part IV Glocalization 159

11 Glocalization of the Market 161
Masaki Ogata

Abstract 161

11.1 Introduction 161

11.2 The Term Glocalization 163

11.3 Concept Creation 167

11.4 Fusion of Technologies 167

11.5 Market Glocalization 167

11.5.1 Organization 167

11.5.2 Intellectual Property 168

11.5.3 Value 168

11.5.4 Innovation Chain 168

11.6 Conclusion 170

References 172

12 Thinking Globally, Acting Locally and Thinking Locally, Acting Globally 173
Cathy Lasser

Abstract 173

12.1 Introduction 174

12.2 Transformation Framework 176

12.3 Value-Based Culture 177

12.4 Collaborative Innovation 178

12.5 A Smarter Planet: Collaboration and the Future of Work 179

12.6 Conclusion 181

Reference 181

13 Glocalization: Market Cultivation and the Future of Standards 183
Richard Mark Soley

Abstract 183

13.1 Introduction 184

13.2 Innovation 184

13.3 Standards 185

13.4 Market Ecosystem 187

13.5 Approaches to Developing Standards 188

13.6 Globalization 190

13.7 Glocalization 191

13.8 Successful Standards 192

13.9 Future of Standards 192

13.10 Smart Energy Grids 193

13.11 Conclusion 194

References 194

14 Smart Urban Infrastructure as an Enabler of the Integration of Resident-Oriented Services 195
Yukio Toyoshima and Michinaga Kohno

Abstract 195

14.1 Introduction 196

14.2 New Trends in Urban Development 196

14.2.1 Activities Aimed at Creating Low-Carbon Cities 196

14.2.2 Large Urban Developments in Emerging Markets 197

14.2.3 Emergence of New Players 197

14.2.4 Resilience against Disasters 198

14.3 Authors’ Concept of Smart Cities 199

14.3.1 Modeling of Smart Cities 199

14.3.2 Creation of New Values 202

14.4 “Glocal” Deployment of Smart Cities 204

14.4.1 Deployment of Smart Cities in General 204

14.4.2 Kashiwa City 204

14.4.3 Projects in China 205

14.4.4 Projects in Europe and the United States 206

14.4.5 Recovery in Cities and Towns Devastated by the 2011 Tsunami 207

Acknowledgments 207

References 207

15 Summary of Market Glocalization 209
Masaki Ogata

Abstract 209

15.1 Introduction 209

15.2 Organization 211

15.3 Standardization 213

15.4 Diversification 215

15.5 Smart Grid 216

15.6 Conclusion 219

Part V Conclusion 221

16 Conclusions and Future Directions 223
Kinji Mori

Index 229