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More About This Title Indoor Radio Planning - A Practical Guide for GSM, DCS, UMTS, HSPA and LTE, 2e
- English
English
Morten Tolstrup is the Director of TE Wireless Group, International Service & Solutions. Prior to working for LGC/ADC/TE he spent 13 years in a number of different engineering positions with a mobile operator in Denmark, mainly focusing on indoor RF planning, tunnels, Airports, Pico-cells and micro cells. Over the past 15 years Morten has presented more than 50 papers and workshops at conferences around the world.
- English
English
Preface to the Second Edition xvii
This is Still Not a Book for Scientists! xvii
The Practical Approach xvii
Keep the Originals! xviii
Preface to the First Edition xix
This is Not a Book for Scientists xix
The Practical Approach xix
Acknowledgments xxi
Second Edition xxi
First Edition xxii
1. Introduction 1
2. Overview of Cellular Systems 5
2.1 Mobile Telephony 5
2.2 Introduction to GSM 10
2.3 Universal Mobile Telecommunication System 28
2.4 Introduction to HSPA 58
2.5 Modulation 69
2.6 Advanced Antenna Systems for HSPA + and LTE 75
2.7 Short Introduction to LTE 81
3. Indoor Radio Planning 101
3.1 Why is In-building Coverage Important? 101
3.2 Indoor Coverage from the Macro Layer 104
3.3 The Indoor UMTS/HSPA Challenge 107
3.4 Common UMTS Rollout Mistakes 112
3.5 The Basics of Indoor RF Planning 114
4. Distributed Antenna Systems 123
4.1 What Type of Distributed Antenna System is Best? 123
4.2 Passive Components 125
4.3 The Passive DAS 133
4.4 Active DAS 136
4.5 Hybrid Active DAS Solutions 145
4.6 Other Hybrid DAS Solutions 148
4.7 Indoor DAS for MIMO Applications 153
4.8 Using Repeaters for Indoor DAS Coverage 162
4.9 Repeaters for Rail Solutions 174
4.10 Designing with Pico and Femtocells 179
4.11 Active DAS Data 188
4.12 Electromagnetic Radiation, EMR 198
4.13 Conclusion 202
5. Designing Indoor DAS Solutions 203
5.1 The Indoor Planning Procedure 203
5.2 The RF Design Process 208
5.3 Designing the Optimum Indoor Solution 217
5.4 Indoor Design Strategy 236
5.5 Handover Considerations Inside Buildings 240
5.6 Elevator Coverage 244
5.7 Multioperator Systems 258
5.8 Co-existence Issues for GSM/UMTS 265
5.9 Co-existence Issues for UMTS/UMTS 267
5.10 Multioperator Requirements 270
6. Traffic Dimensioning 275
6.1 Erlang, the Traffic Measurement 275
7. Noise 295
7.1 Noise Fundamentals 295
7.2 Cascaded Noise 302
7.3 Noise Power 310
7.4 Noise Power from Parallel Systems 314
7.5 Noise Control 316
7.6 Updating a Passive DAS from 2G to 3G 317
8. The Link Budget 329
8.1 The Components and Calculations of the RF Link 329
9. Tools for Indoor Radio Planning 345
9.1 Live and Learn 345
9.2 Diagram Tools 346
9.3 Radio Survey Tools 347
9.4 The Simple Tools and Tips 347
9.5 Tools for Link Budget Calculations 348
9.6 Tools for Indoor Predications 348
9.7 The Advanced Toolkit (RF-vu from iBwave.com) 351
10. Optimizing the Radio Resource Management Parameters on Node B When Interfacing to an Active DAS, BDA, LNA or TMA 357
10.1 Introduction 357
10.2 Impact of DL Power Offset 359
10.3 Impact of Noise Power 362
10.4 Delay of the Active DAS 362
10.5 Impact of External Noise Power 363
11. Tunnel Radio Planning 367
11.1 The Typical Tunnel Solution 368
11.2 The Tunnel HO Zone 369
11.3 Covering Tunnels with Antennas 376
11.4 Radiating Cable Solutions 378
11.5 Tunnel Solutions, Cascaded BDAs 383
11.6 Tunnel Solutions, T-Systems 385
11.7 Handover Design inside Tunnels 390
11.8 Redundancy in Tunnel Coverage Solutions 396
11.9 Sector Strategy for Larger Metro Tunnel Projects 399
11.10 RF Test Specifications of Tunnel Projects 404
11.11 Timing Issues in DAS for Tunnels 405
12. Covering Indoor Users From the Outdoor Network 413
12.1 The Challenges of Reaching Indoor Users From the Macro Network 413
12.2 Micro Cell Capacity 418
12.3 ODAS –Outdoor Distributed Antenna Systems 420
12.4 Digital Distribution of DAS 423
12.5 High Speed Rail Solutions 429
References 437
Appendix 439
Reference Material 439
Index 451