5G mobile and wireless communications technology / edited by Afif Osseiran, Ericsson, Jose F. Monserrat, Universitat Politècnica de València, Patrick Marsch, Nokia.

"Written by leading experts in 5G research, this book is a comprehensive overview of the current state of 5G. Covering everything from the most likely use cases, spectrum aspects, and a wide range of technology options to potential 5G system architectures, it is an indispensable reference for academics and professionals involved in wireless and mobile communications. Global research efforts are summarised, and key component technologies including D2D, mm-wave communications, massive MIMO, coordinated multi-point, wireless network coding, interference management and spectrum issues are described and explained. The significance of 5G for the automotive, building, energy, and manufacturing economic sectors is addressed, as is the relationship between IoT, machine type communications, and cyber-physical systems. This essential resource equips you with a solid insight into the nature, impact and opportunities of 5G"-- Provided by publisher.

Includes bibliographical references and index.

Machine generated contents note: 1.Introduction -- 1.1.Historical background -- 1.1.1.Industrial and technological revolution: from steam engines to the Internet -- 1.1.2.Mobile communications generations: from 1G to 4G -- 1.1.3.From mobile broadband (MBB) to extreme MBB -- 1.1.4.IoT: relation to 5G -- 1.2.From ICT to the whole economy -- 1.3.Rationale of 5G: high data volume, twenty-five billion connected devices and wide requirements -- 1.3.1.Security -- 1.4.Global initiatives -- 1.4.1.METIS and the 5G-PPP -- 1.4.2.China: 5G promotion group -- 1.4.3.Korea: 5G Forum -- 1.4.4.Japan: ARIB 2020 and Beyond Ad Hoc -- 1.4.5.Other 5G initiatives -- 1.4.6.IoT activities -- 1.5.Standardization activities -- 1.5.1.ITU-R -- 1.5.2.3GPP -- 1.5.3.IEEE -- 1.6.Scope of the book -- References -- 2.5G use cases and system concept -- 2.1.Use cases and requirements -- 2.1.1.Use cases -- 2.1.2.Requirements and key performance indicators -- 2.2.5G system concept -- 2.2.1.Concept overview --

Note continued: 2.2.2.Extreme mobile broadband -- 2.2.3.Massive machine-type communication -- 2.2.4.Ultra-reliable machine-type communication -- 2.2.5.Dynamic radio access network -- 2.2.6.Lean system control plane -- 2.2.7.Localized contents and traffic flows -- 2.2.8.Spectrum toolbox -- 2.3.Conclusions -- References -- 3.The 5G architecture -- 3.1.Introduction -- 3.1.1.NFV and SDN -- 3.1.2.Basics about RAN architecture -- 3.1.High-level requirements for the 5G architecture -- 3.3.Functional architecture and 5G flexibility -- 3.3.1.Functional split criteria -- 3.3.2.Functional split alternatives -- 3.3.3.Functional optimization for specific applications -- 3.3.4.Integration of LTE and new air interface to fulfill 5G requirements -- 3.3.5.Enhanced Multi-RAT coordination features -- 3.4.Physical architecture and 5G deployment -- 3.4.1.Deployment enablers -- 3.4.2.Flexible function placement in 5G deployments -- 3.5.Conclusions -- References --

Note continued: 4.Machine-type communications -- 4.1.Introduction -- 4.1.1.Use cases and categorization of MTC -- 4.1.2.MTC requirements -- 4.2.Fundamental techniques for MTC -- 4.2.1.Data and control for short packets -- 4.2.2.Non-orthogonal access protocols -- 4.3.Massive MTC -- 4.3.1.Design principles -- 4.3.2.Technology components -- 4.3.3.Summary of mMTC features -- 4.4.Ultra-reliable low-latency MTC -- 4.4.1.Design principles -- 4.4.2.Technology components -- 4.4.3.Summary of uMTC features -- 4.5.Conclusions -- References -- 5.Device-to-device (D2D) communications -- 5.1.D2D: from 4G to 5G -- 5.1.1.D2D standardization: 4G LTE D2D -- 5.1.2.D2D in 5G: research challenges -- 5.1.Radio resource management for mobile broadband D2D -- 5.2.1.RRM techniques for mobile broadband D2D -- 5.2.2.RRM and system design for D2D -- 5.2.3.5G D2D RRM concept: an example -- 5.3.Multi-hop D2D communications for proximity and emergency services --

Note continued: 5.3.1.National security and public safety requirements in 3GPP and METIS -- 5.3.2.Device discovery without and with network assistance -- 5.3.3.Network-assisted multi-hop D2D communications -- 5.3.4.Radio resource management for multi-hop D2D -- 5.3.5.Performance of D2D communications in the proximity communications scenario -- 5.4.Multi-operator D2D communication -- 5.4.1.Multi-operator D2D discovery -- 5.4.2.Mode selection for multi-operator D2D -- 5.4.3.Spectrum allocation for multi-operator D2D -- 5.5.Conclusions -- References -- 6.Millimeter wave communications -- 6.1.Spectrum and regulations -- 6.2.Channel propagation -- 6.3.Hardware technologies for mmW systems -- 6.3.1.Device technology -- 6.3.2.Antennas -- 6.3.3.Beamforming architecture -- 6.4.Deployment scenarios -- 6.5.Architecture and mobility -- 6.5.1.Dual connectivity -- 6.5.2.Mobility -- 6.6.Beamforming -- 6.6.1.Beamforming techniques -- 6.6.2.Beam finding --

Note continued: 6.7.Physical layer techniques -- 6.7.1.Duplex scheme -- 6.7.2.Transmission schemes -- 6.8.Conclusions -- References -- 7.The 5G radio-access technologies -- 7.1.Access design principles for multi-user communications -- 7.1.1.Orthogonal multiple-access systems -- 7.1.2.Spread spectrum multiple-access systems -- 7.1.3.Capacity limits of multiple-access methods -- 7.2.Multi-carrier with filtering: a new waveform -- 7.2.1.Filter-bank based multi-carrier -- 7.2.2.Universal filtered OFDM -- 7.3.Non-orthogonal schemes for efficient multiple access -- 7.3.1.Non-orthogonal multiple access (NOMA) -- 7.3.2.Sparse code multiple access (SCMA) -- 7.3.3.Interleave division multiple access (IDMA) -- 7.4.Radio access for dense deployments -- 7.4.1.OFDM numerology for small-cell deployments -- 7.4.2.Small-cell sub-frame structure -- 7.5.Radio access for V2X communication -- 7.5.1.Medium access control for nodes on the move --

Note continued: 7.6.Radio access for massive machine-type communication -- 7.6.1.The massive access problem -- 7.6.2.Extending access reservation -- 7.6.3.Direct random access -- 7.7.Conclusions -- References -- 8.Massive multiple-input multiple-output (MIMO) systems -- 8.1.Introduction -- 8.1.1.MIMO in LTE -- 8.2.Theoretical background -- 8.2.1.Single user MIMO -- 8.2.2.Multi-user MIMO -- 8.2.3.Capacity of massive MIMO: a summary -- 8.3.Pilot design for massive MIMO -- 8.3.1.The pilot-data trade-off and impact of CSI -- 8.3.2.Techniques to mitigate pilot contamination -- 8.4.Resource allocation and transceiver algorithms for massive MIMO -- 8.4.1.Decentralized coordinated transceiver design for massive MIMO -- 8.4.2.Interference clustering and user grouping -- 8.5.Fundamentals of baseband and RF implementations in massive MIMO -- 8.5.1.Basic forms of massive Ml MO implementation -- 8.5.2.Hybrid fixed BF with CSI-based precoding (FBCP) --

Note continued: 8.5.3.Hybrid beamforming for interference clustering and user grouping -- 8.6.Channel models -- 8.7.Conclusions -- References -- 9.Coordinated multi-point transmission in 5G -- 9.1.Introduction -- 9.2.JT CoMP enablers -- 9.2.1.Channel prediction -- 9.2.2.Clustering and interference floor shaping -- 9.2.3.User scheduling and precoding -- 9.2.4.Interference mitigation framework -- 9.2.5.JT CoMP in 5G -- 9.3.JT CoMP in conjunction with ultra-dense networks -- 9.4.Distributed cooperative transmission -- 9.4.1.Decentralized precoding/filtering design with local CSI -- 9.4.2.Interference alignment -- 9.5.JT CoMP with advanced receivers -- 9.5.1.Dynamic clustering for JT CoMP with multiple antenna UEs -- 9.5.2.Network-assisted interference cancellation -- 9.6.Conclusions -- References -- 10.Relaying and wireless network coding -- 10.1.The role of relaying and network coding in 5G wireless networks -- 10.1.1.The revival of relaying -- 10.1.2.From 4G to 5G --

Note continued: 10.1.3.New relaying techniques for 5G -- 10.1.4.Key applications in 5G -- 10.2.Multi-flow wireless backhauling -- 10.2.1.Coordinated direct and relay (CDR) transmission -- 10.2.2.Four-way relaying (FWR) -- 10.2.3.Wireless-emulated wire (WEW) for backhaul -- 10.3.Highly flexible multi-flow relaying -- 10.3.1.Basic idea of multi-flow relaying -- 10.3.2.Achieving high throughput for 5G -- 10.3.3.Performance evaluation -- 10.4.Buffer-aided relaying -- 10.4.1.Why buffers? -- 10.4.2.Relay selection -- 10.4.3.Handling inter-relay interference -- 10.4.4.Extensions -- 10.5.Conclusions -- References -- 11.Interference management, mobility management, and dynamic reconfiguration -- 11.1.Network deployment types -- 11.1.1.Ultra-dense network or densification -- 11.1.2.Moving networks -- 11.1.3.Heterogeneous networks -- 11.2.Interference management in 5G -- 11.2.1.Interference management in UDN -- 11.2.2.Interference management for moving relay nodes --

Note continued: 11.2.3.Interference cancelation -- 11.3.Mobility management in 5G -- 11.3.1.User equipment-controlled versus network-controlled handover -- 11.3.2.Mobility management in heterogeneous 5G networks -- 11.3.3.Context awareness for mobility management -- 11.4.Dynamic network reconfiguration in 5G -- 11.4.1.Energy savings through control/user plane decoupling -- 11.4.2.Flexible network deployment based on moving networks -- 11.5.Conclusions 330 References -- 12.Spectrum -- 12.1.Introduction -- 12.1.1.Spectrum for 4G -- 12.1.2.Spectrum challenges in 5G -- 12.2.5G spectrum landscape and requirements -- 12.2.1.Bandwidth requirements -- 12.3.Spectrum access modes and sharing scenarios -- 12.4.5G spectrum technologies -- 12.4.1.Spectrum toolbox -- 12.4.2.Main technology components -- 12.5.Value of spectrum for 5G: a techno-economic perspective -- 12.6.Conclusions 352 References -- 13.The 5G wireless propagation channel models -- 13.1.Introduction --

Note continued: 13.2.Modeling requirements and scenarios -- 13.2.1.Channel model requirements -- 13.2.2.Propagation scenarios -- 13.3.The METIS channel models -- 13.3.1.Map-based model -- 13.3.2.Stochastic model -- 13.4.Conclusions -- References -- 14.Simulation methodology -- 14.1.Evaluation methodology -- 14.1.1.Performance indicators -- 14.1.2.Channel simplifications -- 14.2.Calibration -- 14.2.1.Link-level calibration -- 14.2.2.System-level calibration -- 14.3.New challenges in the 5G modeling -- 14.3.1.Real scenarios -- 14.3.2.New waveforms -- 14.3.3.Massive MIMO -- 14.3.4.Higher frequency bands -- 14.3.5.Device-to-device link -- 14.3.6.Moving networks -- 14.4.Conclusions -- References.