000			06088cam a2200709 i 4500
001			on1076457870
003			OCoLC
005			20220711203453.0
006			m o d
007			cr |||||||||||
008			181126t20192019njua ob 001 0 eng
010			_a 2018056369
040			_aDLC _beng _erda _cDLC _dOCLCO _dOCLCF _dYDX _dN$T _dEBLCP _dDG1 _dYDX
019			_a1085890372
020			_a9781119247074 _qelectronic book
020			_a1119247071 _qelectronic book
020			_a9781119247135 _qelectronic book
020			_a1119247136 _qelectronic book
020			_a9781119247111 _qelectronic book
020			_a111924711X _qelectronic book
020			_z9781119247081 _qhardcover
029	1		_aAU@ _b000065218956
029	1		_aCHVBK _b565571729
029	1		_aCHNEW _b001048773
035			_a(OCoLC)1076457870 _z(OCoLC)1085890372
042			_apcc
050	1	4	_aTK5103.2 _b.A147 2019
072		7	_aTEC _x009070 _2bisacsh
082	0	0	_a621.3845/6 _223
049			_aMAIN
245	0	0	_a5G for the connected world / _cedited by Devaki Chandramouli, Rainer Liebhart,, Juho Pirskanen, Kangasala, Finland.
250			_aFirst edition.
264		1	_aHoboken, NJ : _bJohn Wiley & Sons, Inc., _c2019.
264		4	_c©2019
300			_a1 online resource (xlii, 471 pages)
336			_atext _btxt _2rdacontent
337			_acomputer _bc _2rdamedia
338			_aonline resource _bcr _2rdacarrier
504			_aIncludes bibliographical references and index.
520			_a"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"-- _cProvided by publisher.
505	0		_aCover; 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; 1.5.5 Network Operations
505	8		_a1.6 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 License-Exempt Spectrum
505	8		_a2.4.3 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 for User Plane Data
505	8		_a3.2.6.2 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 Uplink Data Transmission
505	8		_a3.4.3 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 Convergence Protocol (PDCP)
588			_aDescription based on online resource; title from digital title page (viewed on April 11, 2019).
650		0	_aMobile communication systems _xTechnological innovations. _95962
650		0	_aBroadband communication systems _vTechnological innovations. _97981
650		0	_aWireless sensor networks _vTechnological innovations. _97982
650		7	_aBroadband communication systems. _2fast _0(OCoLC)fst00839147 _94551
650		7	_aMobile communication systems _xTechnological innovations. _2fast _0(OCoLC)fst01024219 _95962
650		7	_aWireless sensor networks. _2fast _0(OCoLC)fst01746575 _96945
650		7	_aTECHNOLOGY & ENGINEERING / Mechanical. _2bisacsh _97983
655		4	_aElectronic books. _93294
700	1		_aChandramouli, Devaki, _eeditor. _97984
700	1		_aLiebhart, Rainer, _eeditor. _97985
700	1		_aPirskanen, Juho, _eeditor. _97986
776	0	8	_iPrint version: _t5G for the connected world _bFirst edition. _dHoboken, NJ : John Wiley & Sons, Inc., 2019 _z9781119247081 _w(DLC) 2018051891
856	4	0	_uhttps://doi.org/10.1002/9781119247111 _zWiley Online Library
942			_cEBK
994			_aC0 _bDG1
999			_c68992 _d68992