5G Physical Layer Principles, Models and Technology Components
Auteurs : Zaidi Ali, Athley Fredrik, Medbo Jonas, Gustavsson Ulf, Durisi Giuseppe, Chen Xiaoming
5G Physical Layer: Principles, Models and Technology Components explains fundamental physical layer design principles, models and components for the 5G new radio access technology ? 5G New Radio (NR). The physical layer models include radio wave propagation and hardware impairments for the full range of frequencies considered for the 5G NR (up to 100 GHz). The physical layer technologies include flexible multi-carrier waveforms, advanced multi-antenna solutions, and channel coding schemes for a wide range of services, deployments, and frequencies envisioned for 5G and beyond. A MATLAB-based link level simulator is included to explore various design options.
5G Physical Layer is very suitable for wireless system designers and researchers: basic understanding of communication theory and signal processing is assumed, but familiarity with 4G and 5G standards is not required.
With this book the reader will learn:
- The fundamentals of the 5G NR physical layer (waveform, modulation, numerology, channel codes, and multi-antenna schemes).
- Why certain PHY technologies have been adopted for the 5G NR.
- The fundamental physical limitations imposed by radio wave propagation and hardware impairments.
- How the fundamental 5G NR physical layer functionalities (e.g., parameters/methods/schemes) should be realized.
The content includes:
- A global view of 5G development ? concept, standardization, spectrum allocation, use cases and requirements, trials, and future commercial deployments.
- The fundamentals behind the 5G NR physical layer specification in 3GPP.
- Radio wave propagation and channel modeling for 5G and beyond.
- Modeling of hardware impairments for future base stations and devices.
- Flexible multi-carrier waveforms, multi-antenna solutions, and channel coding schemes for 5G and beyond.
- A simulator including hardware impairments, radio propagation, and various waveforms.
Ali Zaidi is a strategic product manager at Ericsson, Sweden. Fredrik Athley is a senior researcher at Ericsson, Sweden. Jonas Medbo and Ulf Gustavsson are senior specialists at Ericsson, Sweden. Xiaoming Chen is a professor at Xi?an Jiaotong University, China. Giuseppe Durisi is a professor at Chalmers University of Technology, Sweden, and a guest researcher at Ericsson, Sweden.
1. 5G Radio Access 2. NR Physical Layer: Overview 3. Propagation & Channel Modeling 4. Hardware Impairment Modeling 5. Multicarrier Waveforms 6. NR Waveform 7. Multi-antenna Techniques 8. Channel Coding 9. Simulator
Fredrik Athley received the M.Sc. and Ph.D. in Electrical Engineering from Chalmers University of Technology, Göteborg, Sweden, in 1993 and 2003, respectively. In 1993 he received the International Diploma of Imperial College, London, UK. Since 1993 he has been working at Ericsson with system-level analysis and design of radar and wireless communication systems and since 2005 he is a Senior Researcher at Ericsson Research. He is currently working with standardization of multi-antenna techniques in the new radio (NR) access technology for 5G.
Jonas Medbo is currently a senior specialist in applied propagation at Ericsson Research, Sweden. He received his Ph.D. degree in particle physics from Uppsala University, Sweden, in 1997. Since 1997 he has been with Ericsson Research focusing on propagation research. He has co
With this book the reader will learn:
- The fundamentals of the 5G NR physical layer (waveform, modulation, numerology, channel codes, and multi-antenna schemes)
- Why certain PHY technologies have been adopted for the 5G NR
- The fundamental physical limitations imposed by radio wave propagation and hardware impairments
- How the fundamental 5G NR physical layer functionalities (e.g., parameters/methods/schemes) should be realized
The content includes:
- A global view of 5G development – concept, standardization, spectrum allocation, use cases and requirements, trials, and future commercial deployments
- The fundamentals behind the 5G NR physical layer specification in 3GPP
- Radio wave propagation and channel modeling for 5G and beyond
- Modeling of hardware impairments for future base stations and devices
- Flexible multi-carrier waveforms, multi-antenna solutions, and channel coding schemes for 5G and beyond
- A simulator including hardware impairments, radio propagation, and various waveforms
Date de parution : 09-2018
Ouvrage de 322 p.
19x23.3 cm
Thèmes de 5G Physical Layer :
Mots-clés :
3GPP; 3GPP NR channel model; 5G New Radio (NR); 5G waveform comparisons; angle spread; Assistive technologies; carrier-frequency offset; channel modeling; data converter; delay spread; DFTS-OFDM; distortion; eMBB; FBMC; hardware impairments; high-resolution channel; Human computer interactions; Human machine interface; indoor; ITU-R propagation models; local oscillators; Machine learning; macrocell; microcell; millimeter-wave; millimeter-wave communications; millimeter-wave propagation; mMTC; Monitoring; multicarrier waveforms; New Radio (NR); OFDM; OFDM numerology; outdoor-to-indoor; PAPR reduction; phase noise; Power amplifiers; propagation; propagation scenarios; quantization noise; Smart sensor; URLLC; User centred design; User involvement; User profile; waveform design requirements