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621.3845/6 5G for the connected world / edited by Devaki Chandramouli, Rainer Liebhart,, Juho Pirskanen,

Contributor(s): Electronic books.1 Chandramou | Liebha [editor.1 ] | Pirsk [editor.1 ] | IEEE Xplore (Online Ser [editor.2 ] | [distributor.2 ].
Material type: materialTypeLabelBookFirst edition. 1 Hoboken, New Jersey : John Wiley [Piscataqay, New Jersey] : 2019. 2Description: [2019] 1 PD. Media type: text, e Carrier type: online ISBN: 1085890372 ; 9781119247.Subject(s): Mobile communication systems -- Techno | Broadband communication systems -- Techno | Wireless sensor networks -- Techno | Broadband communic | Mobile communication systems -- Technologica | Wireless seGenre/Form: DDC classification: Online resources: Abstract with links to resource Also
Contents:
Cover; Title Page; Copyright; Contents; About the Editors; List of Contributors; Foreword by Tommi Uitto; Foreword by Karri Kuoppamaki; Preface; Acknowledgements; Introduction; Terminology; Chapter 1 Drivers and Motivation for 5G; 1.1 Drivers for 5G; 1.2 ITU-R and IMT 2020 Vision; 1.3 NGMN (Next Generation Mobile Networks); 1.4 5GPPP (5G Public-Private Partnership); 1.5 Requirements for Support of Known and New Services; 1.5.1 Massive IoT; 1.5.2 Time Critical Communication; 1.5.3 Enhanced Mobile Broadband (eMBB); 1.5.4 Enhanced Vehicular Communications; 1.5.
1.6 5G Use Cases1.6.1 5G to the Home; 1.6.2 In-Vehicle Infotainment; 1.6.3 Hot Spots; 1.6.4 Truck Platooning; 1.6.5 Connected Health Care; 1.6.6 Industry 4.0; 1.6.7 Megacities; 1.7 Business Models; 1.7.1 Asset Provider Role; 1.7.2 Connectivity Provider Role; 1.7.3 Partner Service Provider Role; 1.8 Deployment Strategies; 1.9 3GPP Role and Timelines; References; Chapter 2 Wireless Spectrum for 5G; 2.1 Current Spectrum for Mobile Communication; 2.2 Spectrum Considerations for 5G; 2.3 Identified New Spectrum; 2.4 Spectrum Regulations; 2.4.1 Licensed Spectrum; 2.4.2 Lic
2.4.3 New Regulatory Approaches2.5 Characteristics of Spectrum Available for 5G; 2.5.1 Pathloss; 2.5.2 Multipath Propagation; 2.6 NR Bands Defined by 3GPP; References; Chapter 3 Radio Access Technology; 3.1 Evolution Toward 5G; 3.1.1 Introduction; 3.1.2 Pre-Standard Solutions; 3.2 Basic Building Blocks; 3.2.1 Waveforms for Downlink and Uplink; 3.2.2 Multiple Access; 3.2.3 5G Numerology and Frame Structures; 3.2.4 Bandwidth and Carrier Aggregation; 3.2.5 Massive MIMO (Massive Multiple Input Multiple Output); 3.2.6 Channel Coding; 3.2.6.1 Channel Coding
3.2.6.2 Channel Coding for Physical Control Channels3.3 Downlink Physical Layer; 3.3.1 Synchronization and Cell Detection; 3.3.1.1 Primary Synchronization Signal (PSS); 3.3.1.2 Secondary Synchronization Signal (SSS); 3.3.1.3 Physical Broadcast Channel (PBCH); 3.3.1.4 SS Block Burst Set; 3.3.2 System Information Broadcast (SIB); 3.3.2.1 Remaining Minimum System Information (RMSI); 3.3.2.2 Other System Information; 3.3.3 Downlink Data Transmission; 3.4 Uplink Physical Layer; 3.4.1 Random Access; 3.4.1.1 Long Sequence; 3.4.1.2 Short Sequence; 3.4.2 Upli
3.4.3 Contention-Based Access3.5 Radio Protocols; 3.5.1 Overall Radio Protocol Architecture; 3.5.2 Medium Access Control (MAC); 3.5.2.1 Logical Channels and Transport Channels; 3.5.2.2 MAC PDU Structures for Efficient Processing; 3.5.2.3 Procedures to Support UL Scheduling; 3.5.2.4 Discontinuous Reception and Transmission; 3.5.2.5 Random Access Procedure; 3.5.2.6 Beam Failure Management; 3.5.3 Radio Link Control (RLC); 3.5.3.1 Segmentation; 3.5.3.2 Error Correction Through ARQ; 3.5.3.3 Reduced RLC Functions for Efficient Processing; 3.5.4 Packet Data Converg
Summary: "After the considerable success of LTE, why do we need a new system with a new radio and a new core? First, 5G will boost some of the LTE key performance indicators to a new horizon: capacity, latency, energy efficiency, spectral efficiency and reliability. We will describe the relevant radio and core features to enable optimizations (5G to be 10, 100 or 1000 times better than LTE) in these areas in respective chapters of the book"-- Pr
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rdacarrier Includes bibliographical r

Cover; Title Page; Copyright; Contents; About the Editors; List of Contributors; Foreword by Tommi Uitto; Foreword by Karri Kuoppamaki; Preface; Acknowledgements; Introduction; Terminology; Chapter 1 Drivers and Motivation for 5G; 1.1 Drivers for 5G; 1.2 ITU-R and IMT 2020 Vision; 1.3 NGMN (Next Generation Mobile Networks); 1.4 5GPPP (5G Public-Private Partnership); 1.5 Requirements for Support of Known and New Services; 1.5.1 Massive IoT; 1.5.2 Time Critical Communication; 1.5.3 Enhanced Mobile Broadband (eMBB); 1.5.4 Enhanced Vehicular Communications; 1.5.

1.6 5G Use Cases1.6.1 5G to the Home; 1.6.2 In-Vehicle Infotainment; 1.6.3 Hot Spots; 1.6.4 Truck Platooning; 1.6.5 Connected Health Care; 1.6.6 Industry 4.0; 1.6.7 Megacities; 1.7 Business Models; 1.7.1 Asset Provider Role; 1.7.2 Connectivity Provider Role; 1.7.3 Partner Service Provider Role; 1.8 Deployment Strategies; 1.9 3GPP Role and Timelines; References; Chapter 2 Wireless Spectrum for 5G; 2.1 Current Spectrum for Mobile Communication; 2.2 Spectrum Considerations for 5G; 2.3 Identified New Spectrum; 2.4 Spectrum Regulations; 2.4.1 Licensed Spectrum; 2.4.2 Lic

2.4.3 New Regulatory Approaches2.5 Characteristics of Spectrum Available for 5G; 2.5.1 Pathloss; 2.5.2 Multipath Propagation; 2.6 NR Bands Defined by 3GPP; References; Chapter 3 Radio Access Technology; 3.1 Evolution Toward 5G; 3.1.1 Introduction; 3.1.2 Pre-Standard Solutions; 3.2 Basic Building Blocks; 3.2.1 Waveforms for Downlink and Uplink; 3.2.2 Multiple Access; 3.2.3 5G Numerology and Frame Structures; 3.2.4 Bandwidth and Carrier Aggregation; 3.2.5 Massive MIMO (Massive Multiple Input Multiple Output); 3.2.6 Channel Coding; 3.2.6.1 Channel Coding

3.2.6.2 Channel Coding for Physical Control Channels3.3 Downlink Physical Layer; 3.3.1 Synchronization and Cell Detection; 3.3.1.1 Primary Synchronization Signal (PSS); 3.3.1.2 Secondary Synchronization Signal (SSS); 3.3.1.3 Physical Broadcast Channel (PBCH); 3.3.1.4 SS Block Burst Set; 3.3.2 System Information Broadcast (SIB); 3.3.2.1 Remaining Minimum System Information (RMSI); 3.3.2.2 Other System Information; 3.3.3 Downlink Data Transmission; 3.4 Uplink Physical Layer; 3.4.1 Random Access; 3.4.1.1 Long Sequence; 3.4.1.2 Short Sequence; 3.4.2 Upli

3.4.3 Contention-Based Access3.5 Radio Protocols; 3.5.1 Overall Radio Protocol Architecture; 3.5.2 Medium Access Control (MAC); 3.5.2.1 Logical Channels and Transport Channels; 3.5.2.2 MAC PDU Structures for Efficient Processing; 3.5.2.3 Procedures to Support UL Scheduling; 3.5.2.4 Discontinuous Reception and Transmission; 3.5.2.5 Random Access Procedure; 3.5.2.6 Beam Failure Management; 3.5.3 Radio Link Control (RLC); 3.5.3.1 Segmentation; 3.5.3.2 Error Correction Through ARQ; 3.5.3.3 Reduced RLC Functions for Efficient Processing; 3.5.4 Packet Data Converg

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"After the considerable success of LTE, why do we need a new system with a new radio and a new core? First, 5G will boost some of the LTE key performance indicators to a new horizon: capacity, latency, energy efficiency, spectral efficiency and reliability. We will describe the relevant radio and core features to enable optimizations (5G to be 10, 100 or 1000 times better than LTE) in these areas in respective chapters of the book"-- Pr

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