Title Details

Prof. Simon Saunders, PhD, CEng, FIET
Founding Chairman of the Femto Forum, Independent Wireless Technologist and Visiting Professor, University of Surrey. Professor Simon Saunders is an independent specialist in the technology of wireless communications, with a technical and commercial background derived from senior appointments in both industry (including Philips and Motorola) and academia (University of Surrey). He is an author of over 150 articles, books and book chapters. He has acted as a consultant to companies including BAA, BBC, O2, Ofcom, BT, ntl, Mitsubishi and British Land and was CTO of Red-M and CEO of Cellular Design Services Ltd. Simon speaks at and chairs a wide range of international conferences and training courses and has invented several novel wireless technologies. Particular expertise includes in-building wireless systems, radiowave propagation prediction, smart antenna design and mobile system analysis. He currently serves on technical advisory boards of several companies. He is the founding chairman of the Femto Forum, a Visiting Professor to the University of Surrey and is amember of the Ofcom Spectrum Advisory Board.
See www.simonsaunders.com for further details.

Stuart Carlaw, Vice President Mobile Wireless – ABI Research. StuartCarlawholds a program management role for ABI Research’s Wireless Practice, which includes coordinating and planning its wireless infrastructure, mobile operator, wireless handset semiconductor, short range wireless connectivity, fixed mobile convergence, femtocell, mobile device and business mobility research services. He is also lead analyst for the femtocell, fixed-mobile convergence and mobile devices research services.
He brings to the task a deep understanding of the critical issues and technologies, stemming from his immersion in these markets for over a decade as both an analyst and an engineer.
Prior to joining ABI Research, Stuart was a Telecommunications Technician in the British Army, and then Senior Analyst and laterWireless Research Director at IMS Research. At IMS he was the primary Bluetooth analyst, and responsible for all short range wireless research.
He has been quoted and published in a variety of industry and general media, including BBC TV, BBC Radio 5, the Financial Times, the Wall Street Journal, EE Times and many more, and has spoken, moderated or participated in industry events including WiMAX World, TETRA WorldCongress, Bluetooth SIG AHM, PTTWorldCongress and Freescale Technology Forum.
Stuart earned a BSc (Honours) in Physical Sciences and Business Management from De Montfort University.

Dr Andrea Giustina, Vice President, Systems Engineering – Ubiquisys Ltd.
Dr Giustina joined Ubiquisys in early 2006 where he heads the definition of Femtocell offers and system design. With over 15 years of experience in telecoms, he previously held management positions in Lucent Technologies in Systems Engineering and Professional Services for GPRS, WCDMA and IMS Services and was a Researcher for Telecom Italia.
Dr Giustina holds a Doctor’s degree in Electronics Engineering and a Telecommunications Master, both from Politecnico di Torino, and an MBA from Bath University.

Ravi Raj Bhat, Ravi Raj Bhat is an Engineering Director at Continuous Computing, managing its software R&D organisation. Ravi has published over 25 technical papers and articles in technical magazines including IEEE Communication and Electronic Design. Ravi had also co-authored a book titled, Java in Telecommunication, published by John Wiley & Sons in September 2001. Ravi holds an MBA from the Anderson School of Management at University of California, Los Angeles and BTech in Computer Engineering from National Institute of Technology, Karnataka.

V. Srinivasa Rao, V. Srinivasa Rao is an Architect for Wireless & IMS Trillium Protocol Software at Continuous Computing. In this capacity, Srinivasa is responsible for conceptualising initial product architecture and design. His oversight includes all the wireless and IMS protocol software products developed by CCPU. Srinivasa has published articles in technical magazines including Electronic Design. His expertise of communications systems ranges from the end-to-end network to signalling protocol software, with a primary focus on IMS and 3G wireless.
Mr Srinivasa holds an MTech in Telecommunication Systems & Engineering from the Indian Institute of Technology, Kharagpur.

Rasa Siegberg, Senior Systems Engineer, Mobile & Networking Security Solutions, SafeNet Inc.
Rasa Siegberg joined SafeNet in 2005 as Systems Engineer responsible for technical presales and sales support, and various aspects of product management and marketing for the company’s portfolio of embedded software security solutions.
Currently Rasa provides strategic guidance; sales, product management, and marketing support for all embedded hardware and software security products at SafeNet with a special focus on new technologies within the telecom/mobile industry.
He has more than 10 years of experience in telecom, semiconductor, networking and embedded security industries. Prior to joining SafeNet, Rasa worked as a Senior Consultant at Conformiq Software, and as a Product Manager at SSH Communications Security Ltd. He received his MA from Helsinki University, Finland.

About the Authors xv

Foreword xix

Preface xxi

Acknowledgements xxiii

Abbreviations xxv

List of Figures xxxv

List of Tables xxxix

1 Introduction to Femtocells 1
Simon Saunders

1.1 Introduction 1

1.2 Why Femtocells? The Market Context 1

1.3 The Nature of Mobile Broadband Demand 2

1.4 What is a Femtocell? 4

1.4.1 Femtocell Attributes 6

1.4.2 Femtocell Standards 7

1.4.3 Types of Femtocell 7

1.5 Applications for Femtocells 7

1.6 What a Femtocell is not 8

1.7 The Importance of ‘Zero-Touch’ 10

1.8 User Benefits 11

1.9 Operator Motivations and Economic Impact 13

1.10 Operator Responses 14

1.11 Challenges 15

1.12 Chapter Overview 15

2 Small Cell Background and Success Factors 17
Simon Saunders

2.1 Introduction 17

2.2 Small Cell Motivations 17

2.2.1 Cellular Principles 17

2.2.2 Conventional Cell Types: Why ‘Femtocells’? 18

2.2.3 Challenges of Achieving Indoor Coverage from Outdoor Macrocells 20

2.2.4 Spectrum Efficiency 21

2.2.5 Geometry Factors 23

2.2.6 The Backhaul Challenge 24

2.3 Other Small-Cell Systems 24

2.3.1 Overview 24

2.3.2 Picocells 24

2.3.3 Distributed Antenna Systems 25

2.3.4 Wireless Local Area Networks 27

2.4 The Small-Cell Landscape 28

2.5 Emergence of the Femtocell – Critical Success Factors 29

2.5.1 Mobile Data Adoption and Revenue Growth 30

2.5.2 Broadband Adoption 30

2.5.3 Connecting Four Billion Users – And Counting 31

2.5.4 Internet Applications 33

2.5.5 Fixed–Mobile Substitution 33

2.5.6 User Device Availability 36

2.5.7 Processing Power and Cost 36

2.6 Conclusions 37

3 Market Issues for Femtocells 39
Stuart Carlaw

3.1 Key Benefits of a Femtocell from Market Perspective 39

3.1.1 In-Home Coverage 39

3.1.2 Macro Network Capacity Gain 40

3.1.3 Termination Fees 40

3.1.4 Simplistic Handset Approach 41

3.1.5 Home Footprint and the Quadruple Play 41

3.1.6 Maximising Returns on Spectrum Investment 42

3.1.7 Churn Reduction – The Sticky Bundle 42

3.1.8 Positive Impact on Subsidisation Trends 43

3.1.9 Value-Added Services 43

3.1.10 Changing User Behaviour 43

3.1.11 Reducing Energy Consumption 44

3.2 Key Primers 44

3.2.1 Broadband Penetration 44

3.2.2 Saturation 45

3.2.3 Evolution in Carrier Business Model 46

3.2.4 Competition 47

3.2.5 Technical Feasibility 48

3.2.6 Economics 48

3.2.7 Limitations in Other Services 49

3.2.8 Carrier and Manufacturer Support 49

3.2.9 Consumer Demand 50

3.2.10 Supporting the Data Boom 50

3.2.11 Growing Standardisation 50

3.2.12 Air Interface Technology Evolution 52

3.3 Key Market Challenges 52

3.3.1 Cost Pressure 52

3.3.2 Intellectual Property Rights 53

3.3.3 Technology Issues 53

3.3.4 Establishing a ‘Sellable’ Proposition 54

3.3.5 Disconnect Between OEMs and Carriers 54

3.3.6 Too Much Reliance on Standards 54

3.3.7 Window of Opportunity 55

3.3.8 Developing the Ecosystem 55

3.4 Business Cases for Femtocells 55

3.4.1 Business Case Foundations 55

3.4.2 Exploring the Economics 57

3.5 Air Interface Choices 60

3.5.1 GSM Advantages 60

3.5.2 GSM Disadvantages 61

3.5.3 WCDMA Advantages 61

3.5.4 WCDMA Disadvantages 61

3.5.5 Conclusions 61

3.5.6 HSDPA, HSUPA and HSPA+ 62

3.6 Product Feature Sets 62

3.6.1 Stand-Alone 62

3.6.2 Broadband Gateway 63

3.6.3 Wi-Fi Access Point 63

3.6.4 TV Set-Top Box 63

3.6.5 Video Distribution Mechanisms 64

3.6.6 Segmentation 64

3.7 Additional Considerations 64

3.7.1 Enterprise Femtocells 64

3.7.2 Super-Femtocells and Outdoor Femtocells 65

3.8 Adoption Forecasts and Volumes 65

3.8.1 Methodology 65

3.8.2 Forecasts 68

3.9 Conclusions 70

4 Radio Issues for Femtocells 71
Simon Saunders

4.1 Introduction 71

4.2 Spectrum Scenarios 71

4.3 Propagation in Femtocell Environments 73

4.4 Coverage 74

4.5 Downlink Interference 75

4.6 Interference Challenges and Mitigations 79

4.7 Femtocell-to-Femtocell Interference 80

4.8 System-Level Performance 81

4.9 RF Specifications in WCDMA 84

4.10 Health and Safety Concerns 86

4.11 Conclusions 89

5 Femtocell Networks and Architectures 91
Andrea Giustina

5.1 Introduction 91

5.2 Challenges 92

5.3 Requirements 93

5.4 Femto Architectures and Interfaces 94

5.5 Key Architectural Choices 96

5.5.1 Connecting Remote Femtocells 96

5.5.2 Integrating the Femto Network with the Macro Network 98

5.5.3 Functional Split between the FAP and the FGW 100

5.6 Other Important Femto Solution Aspects 101

5.6.1 End-to-End Quality of Service 102

5.6.2 Local Access (Data and Voice) 103

5.6.3 Femtozone Services 105

5.6.4 Mobility 106

5.6.5 Femtocell Location 108

5.6.6 Enterprise and Open Spaces 109

5.7 UMTS Femtos 110

5.7.1 Iuh Protocol Stacks 110

5.8 CDMA 112

5.9 WiMAX 113

5.10 GSM 114

5.11 LTE 115

5.12 Conclusions 116

6 Femtocell Management 117
Ravi Raj Bhat and V. Srinivasa Rao

6.1 Introduction 117

6.2 Femtocell FCAPS Requirements 118

6.2.1 Fault and Event Management 119

6.2.2 Configuration Management 119

6.2.3 Accounting and Administration Management 119

6.2.4 Performance Management 120

6.2.5 Security Management 120

6.3 Broadband Forum Auto-Configuration Architecture and Framework 120

6.4 Auto-Configuration Data Organisation 121

6.4.1 Data Hierarchy 121

6.4.2 Profiles 123

6.5 CPE WAN Management Protocol Overview 123

6.5.1 Protocol Stack and Operation 124

6.6 FAP Service Data Model 126

6.6.1 Control Object Group 126

6.6.2 Configuration Object Group 126

6.6.3 Monitoring Object Group 128

6.6.4 Management Object Group 129

6.7 DOCSIS OSS Architecture and Framework 129

6.8 Conclusions 132

7 Femtocell Security 133
Rasa Siegberg

7.1 Why is Security Important? 133

7.1.1 Viewpoint: Continuity 133

7.1.2 Viewpoint: (Contained) Change 134

7.2 The Threat Model 134

7.2.1 Threats from ‘Outsiders’ – Third Parties 135

7.2.2 Threats from ‘Insiders’ – Device Owners 135

7.3 Countering the Threats 136

7.3.1 Radio Link Protection 136

7.3.2 Protecting the (IP) Backhaul 138

7.3.3 Device Integrity – Tamper Resistance 143

7.4 Conclusions 145

8 Femtocell Standards and Industry Groups 147
Simon Saunders

8.1 The Importance of Standards 147

8.2 GSM 148

8.3 WCDMA 148

8.3.1 TSG RAN WG2 – Radio Layer 2 and Radio Layer 3 RR 149

8.3.2 TSG RAN WG3 Architecture 149

8.3.3 TSG RAN WG4 Radio Performance and Protocol Aspects RF Parameters and BS Conformance 150

8.3.4 TSG SA WG1 – Services 150

8.3.5 TSG SA WG3 – Security 150

8.3.6 TSG SA WG5 Telecom Management 151

8.3.7 Summary of WCDMA Standards 151

8.4 TD-SCDMA 151

8.5 LTE 151

8.6 CDMA 153

8.7 Mobile WiMAX 155

8.8 The Femto Forum 156

8.9 The Broadband Forum 157

8.10 GSMA 157

8.11 Conclusions 157

9 Femtocell Regulation 159
Simon Saunders

9.1 Introduction 159

9.2 Regulatory Benefits of Femtocells 159

9.3 Spectrum Efficiency 160

9.4 Economic Efficiency 160

9.5 Enabling Competition 160

9.6 Broadening Access to Services 161

9.7 Enabling Innovation 161

9.8 Environmental Goals 161

9.9 Spectrum Licensing Issues 162

9.10 Location 163

9.11 Authentication 163

9.12 Emergency Calls 163

9.13 Lawful Interception and Local IP Access 164

9.14 Backhaul Challenges 165

9.15 Mobile Termination Rates 165

9.16 Competition Concerns 166

9.17 Equipment Approvals 166

9.18 Examples of Femtocell Regulations 166

9.19 Conclusions 168

10 Femtocell Implementation Considerations 169
Simon Saunders

10.1 Introduction 169

10.2 Signal Processing 170

10.3 Location 170

10.4 Frequency and Timing Control 171

10.5 Protocol Implementation 172

10.6 RF Implementation 172

10.7 System Design and Cost 173

10.8 Mobile Device Challenges and Opportunities 175

10.9 Conclusions 176

11 Business and Service Options for Femtocells 177
Simon Saunders and Stuart Carlaw

11.1 Introduction 177

11.2 Ways of being a Femtocell Operator 177

11.3 Femtocells for Fixed-Line Operators 180

11.4 Types of Femtocell Service 181

11.5 Service Examples 182

11.5.1 Femtozone Services 182

11.5.2 Connected Home Services 184

11.6 Service Enablers 185

11.6.1 Service Implementation 186

11.7 Stages of Femtocell Service Introduction 186

11.7.1 Stage 1 – Supporting Fixed Mobile Substitution 187

11.7.2 Stage 2 – Prompting Mobile Data Uptake 187

11.7.3 Stage 3 – Bringing the Mobile Phone into the Connected Home Concept 187

11.7.4 Stage 4 – Taking the Connected Home into the Wider World 187

11.8 Conclusions 188

12 Summary: The Status and Future of Femtocells 189
Simon Saunders

12.1 Summary 189

12.2 Potential Future Femtocell Landscape 191

12.2.1 Growth of Femtocell Adoption 191

12.2.2 Femtocells in Homes and Offices 192

12.2.3 Femtocells in Developing and Rural Markets 192

12.2.4 Femtocells Outdoors 192

12.2.5 Femtocell-Only Operators 193

12.2.6 Femtos Enabling Next-Generation Mobile Networks 193

12.2.7 When is a Femtocell not a Femtocell? 195

12.3 Concluding Remarks 195

References 197

Further Reading 203

Appendix: A Brief Guide to Units and Spectrum 205

Index 207