Indoor Radio Planning : a Practical Guide for GSM, DCS, UMTS, HSPA and LTE.

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Why is indoor coverage needed, and how it is best implemented? As the challenge of providing higher data speeds and quality for mobile applications intensifies, ensuring adequate in-building and tunnel coverage and capacity is increasingly important. A unique, single-source reference on the theoreti...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Tolstrup, Morten
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken : John Wiley & Sons, 2011.
Edición:2nd ed.
Temas:
Mobile communication systems.
Wireless communication systems.
Wireless LANs.
Radiocommunications mobiles.
Transmission sans fil.
Réseaux locaux sans fil.
Mobile communication systems
Wireless communication systems
Wireless LANs
Acceso en línea:Texto completo
Tabla de Contenidos:
  • INDOOR RADIO PLANNING: A Practical Guide for GSM, DCS, UMTS, HSPA and LTE; Contents; Foreword by Professor Simon Saunders; Preface to the Second Edition; This is Still Not a Book for Scientists!; The Practical Approach; Keep the Originals!; Preface to the First Edition; This is Not a Book for Scientists; The Practical Approach; Acknowledgments; Second Edition; First Edition; 1 Introduction; 2 Overview of Cellular Systems; 2.1 Mobile Telephony; 2.1.1 Cellular Systems; 2.1.2 Radio Transmission in General; 2.1.3 The Cellular Concept; 2.1.4 Digital Cellular Systems; 2.2 Introduction to GSM.
  • 2.2.1 GSM2.2.2 GSM Radio Features; 2.2.3 Mobility Management in GSM; 2.2.4 GSM Signaling; 2.2.5 GSM Network Architecture; 2.3 Universal Mobile Telecommunication System; 2.3.1 The Most Important UMTS Radio Design Parameters; 2.3.2 The UMTS Radio Features; 2.3.3 UMTS Noise Control; 2.3.4 UMTS Handovers; 2.3.5 UMTS Power Control; 2.3.6 UMTS and Multipath Propagation; 2.3.7 UMTS Signaling; 2.3.8 The UMTS Network Elements; 2.4 Introduction to HSPA; 2.4.1 Introduction; 2.4.2 Wi-Fi; 2.4.3 Introduction to HSDPA; 2.4.4 Indoor HSPA Coverage; 2.4.5 Indoor HSPA Planning for Maximum Performance.
  • 2.4.6 HSDPA Coverage from the Macro Network2.4.7 Passive DAS and HSPA; 2.4.8 Short Introduction to HSPA+; 2.4.9 Conclusion; 2.5 Modulation; 2.5.1 Shannon's Formula; 2.5.2 BPSK; 2.5.3 QPSK
  • Quadrature Phase Shift Keying; 2.5.4 Higher Order Modulation 16-64QAM; 2.5.5 EVM Error Vector Magnitude; 2.5.6 Adaptive Modulation, Planning for Highest Data Speed; 2.6 Advanced Antenna Systems for HSPA+ and LTE; 2.6.1 SISO/MIMO Systems; 2.6.2 SISO, Single Input Single Output; 2.6.3 SIMO, Single Input Multiple Output; 2.6.4 MISO, Multiple Inputs Single Output; 2.6.5 MIMO, Multiple Inputs Multiple Outputs.
  • 2.6.6 Planning for Optimum Data Speeds Using MIMO2.7 Short Introduction to LTE; 2.7.1 Motivation behind LTE and E-UTRAN; 2.7.2 Key Features of LTE E-UTRAN; 2.7.3 System Architecture Evolution
  • SAE; 2.7.4 EPS
  • Evolved Packet System; 2.7.5 Evolved Packet Core Network
  • EPC; 2.7.6 LTE Reference Points/Interfaces; 2.7.7 The LTE RF Channel Bandwidth; 2.7.8 OFDM
  • Orthogonal Frequency Division Multiplexing; 2.7.9 OFDMA
  • Orthogonal Frequency Division Multiple Access; 2.7.10 SC-FDMA
  • Single Carrier Frequency Division Multiple Access; 2.7.11 LTE Slot Structure; 2.7.12 User Scheduling.
  • 2.7.13 Downlink Reference Signals2.7.14 The LTE Channel; 2.7.15 LTE Communication and Control Channels; 2.7.16 Radio Recourse Management in LTE; 3 Indoor Radio Planning; 3.1 Why is In-building Coverage Important?; 3.1.1 Commercial and Technical Evaluation; 3.1.2 The Main Part of the Mobile Traffic is Indoors; 3.1.3 Some 70-80% of Mobile Traffic is Inside Buildings; 3.1.4 Indoor Solutions Can Make a Great Business Case; 3.1.5 Business Evaluation; 3.1.6 Coverage Levels/Cost Level; 3.1.7 Evaluate the Value of the Proposed Solution; 3.2 Indoor Coverage from the Macro Layer.

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