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Photonic applications for radio systems and networks /

This hands-on, practical new resource provides optical network designers with basic but necessary information about radio systems air interface and radio access network architecture, protocols, and interfaces, using 5G use cases as relevant example. The book introduces mobile network designers to th...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Cavaliere, Fabio (Autor), D'Errico, Antonio (Senior researcher) (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Boston : Artech House, [2019]
Colección:Artech House applied photonics series.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro; Photonic Applications for Radio Systems and Networks; Contents; Chapter 1 Introduction; Chapter 2 Radio Systems Physical Layer; 2.1 Introduction; 2.2 Physical Layer of 4G Radio Systems; 2.2.1 Orthogonal Frequency Division Multiplexing; 2.2.2 Orthogonal Frequency Division Multiplexing Access; 2.2.3 LTE Frame Structure; 2.2.4 LTE Systems Bandwidth; 2.2.5 TDD Frame Structure; 2.2.6 LTE Physical Layer Parameters; 2.3 Physical Layer of 5G Radio Systems; 2.3.1 Modulation Schemes; 2.3.2 5G Numerology and Frame Structure; 2.3.3 5G Resource Grid and Bandwidth
  • 2.3.4 Time Division Duplex 5G Systems; 2.3.5 5G Physical Layer Parameters; 2.4 Multiple Antenna Systems and Beamforming; 2.5 Signal Processing Chain in 5G; 2.6 Conclusions; References; Chapter 3 Radio Access Network Architecture; 3.1 Introduction; 3.2 5G Use Cases and Requirements; 3.3 The Radio Protocol Stack; 3.4 The HARQ Protocol; 3.5 Latency Budget in Mobile Communication Systems; 3.6 RAN Functional Split; 3.6.1 Radio Split Architecture; 3.6.2 Functional Split Options; 3.7 The 5G Transport Network Architecture; 3.7.1 RAN Logical Interfaces
  • 3.7.2 Definition of Fronthaul, Midhaul, and Backhaul; 3.7.3 Mapping of Functional Split Options onto the Transport Network; 3.8 RAN Deployment Scenarios; 3.9 Network Slicing; 3.10 Bit Rate and Latency with Different Functional Split Options; 3.10.1 Bit Rate Dependency on the Split Option; 3.10.2 Bit Rate Calculation; 3.10.3 Latency Calculation; 3.11 Summary; References; Chapter 4 Optical Transmission Modeling in Digital RANs; 4.1 Introduction; 4.2 Fiber Attenuation; 4.3 Performance Metrics in Optical Communication Systems; 4.3.1 Bit Error Rate; 4.3.2 Q Factor; 4.3.3 Optical Modulation Amplitude
  • 4.3.4 Error Vector Magnitude; 4.3.5 Optical Signal-to-Noise Ratio; 4.3.6 Using Different Penalty Definitions; 4.4 Optical Receiver Model; 4.5 Fiber Propagation Penalties; 4.5.1 Chromatic Dispersion; 4.5.2 Polarization Mode Dispersion; 4.5.3 Chromatic and Polarization Mode Dispersion Tolerance of Direct Detection Modulation Formats; 4.5.4 Self-Phase Modulation; 4.5.5 Cross-Phase Modulation; 4.5.6 Four-Wave Mixing; 4.6 Stimulated Raman Scattering; 4.6.1 Stimulated Brillouin Scattering; 4.7 Rayleigh Backscattering; 4.8 Summary; References
  • Chapter 5 Optical Systems and Technologies for Digital Radio Access Networks; 5.1 Introduction; 5.2 Point-to-Point Fiber Systems; 5.2.1 Optical Modules for Point-to-Point Links; 5.2.2 Modulation Formats in Point-to-Point Links; 5.3 Dense WDM Systems; 5.3.1 Optical Amplifiers; 5.3.2 Statistical Design of DWDM Links; 5.3.3 Wavelength Dependent Losses and Gains; 5.3.4 Modulation Formats in a DWDM RAN; 5.3.5 Further Considerations on DWDM RANs; 5.4 Mobile Transport over Fixed-Access Networks; 5.4.1 Passive Optical Networks; 5.4.2 Mobile Transport over PON; 5.4.3 Dimensioning of a Backhaul Network