09862nam 2200457 450 991048869320332120220329105629.0981-16-3160-3(CKB)5590000000517976(MiAaPQ)EBC6676331(Au-PeEL)EBL6676331(OCoLC)1258664829(PPN)269153233(EXLCZ)99559000000051797620220329d2021 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierBroadband terahertz communication technologies /Jianjun YuGateway East, Singapore :Springer,[2021]©20211 online resource (280 pages)981-16-3159-X Intro -- Contents -- 1 Introduction -- 1.1 Research Background and Significance -- 1.2 Research Status at Home and Abroad -- 1.2.1 International Research Status -- 1.2.2 Domestic Research Status -- 1.3 Challenges of Terahertz Communication Research -- 1.4 Main Contents and Structure of the Book -- References -- 2 Generation and Detection of Terahertz Signal -- 2.1 The Generation of Terahertz Signal -- 2.1.1 Generating Terahertz Signal by Electronic Devices -- 2.1.2 Generating Terahertz Signal by Photonics Methods -- 2.2 The Reception of Terahertz Signal -- 2.2.1 Direct Detection of Terahertz Signal -- 2.2.2 Heterodyne Coherent Detection -- 2.3 Comparison of Two Kinds of Photodetectors -- 2.4 Transmission Link of Terahertz Signal -- 2.4.1 Free Space Channel Transmission Model -- 2.4.2 Atmospheric Absorption of Terahertz Signal -- 2.5 Conclusion -- References -- 3 Basic Algorithm and Experimental Verification of Single-Carrier Terahertz Communication System -- 3.1 Introduction -- 3.2 Basic DSP Algorithm in High-Speed Single-Carrier Terahertz Communication System -- 3.2.1 Basic DSP Algorithm in Single-Carrier Terahertz Communication System -- 3.2.2 Back-End Signal Processing Algorithm in Single-Carrier Terahertz Communication System -- 3.3 Experimental Research on Electro-Generated Terahertz Wireless Communication System -- 3.3.1 Experimental Setup of Electric Generation Terahertz Wireless Communication System -- 3.3.2 Experimental Results and Analysis -- 3.4 Experimental Research on Photogenerated Single-Carrier 16QAM Terahertz Signal Transmission System -- 3.4.1 Experimental Setup -- 3.4.2 Experimental Results and Analysis -- 3.5 Conclusion -- References -- 4 Basic Algorithms and Experimental Verification of Multi-carrier Terahertz Communication -- 4.1 Introduction.4.2 Terahertz Communication System Based on Optical Heterodyne Beat Frequency Scheme and Coherent Reception -- 4.3 Multi-carrier OFDM Modulation Format -- 4.4 Discrete-Fourier-Transform Spread Technology -- 4.4.1 Principle of Discrete-Fourier-Transform Spread Technology -- 4.4.2 Applications of Discrete-Fourier-Transform Spread Technology -- 4.4.3 Test Experiment -- 4.5 Intrasymbol Frequency-Domain Averaging Technology -- 4.5.1 Channel Estimation -- 4.5.2 Principle of Intrasymbol Frequency-Domain Averaging Technology -- 4.6 OFDM Millimeter Wave Coherent Reception System Based on DFT-S and ISFA -- 4.6.1 Experimental Setup -- 4.6.2 Experiment Results -- 4.7 Volterra Nonlinear Compensation Technology -- 4.7.1 Principle of Parallel Volterra Nonlinear Compensation Technology -- 4.8 Experimental Verification of Terahertz RoF-OFDM Communication System -- 4.8.1 Experimental Setup of 350−510 GHz Terahertz RoF-OFDM Communication System -- 4.8.2 Experimental Results and Analysis of 350-510 GHz Terahertz RoF-OFDM Communication System -- 4.8.3 High-Order QAM Terahertz RoF-OFDM Communication System Experiment -- 4.8.4 Experimental Results of High-Order QAM Terahertz RoF-OFDM Communication System -- 4.9 Conclusion -- References -- 5 Terahertz Signal MIMO Transmission -- 5.1 Introduction -- 5.2 2 × 2 MIMO Wireless Link Based on Optical Polarization Multiplexing -- 5.3 4 × 4 MIMO Wireless Link Based on Antenna Polarization Multiplexing -- 5.3.1 Study of Antenna Isolation and Crosstalk -- 5.3.2 Principle of Antenna Polarization Multiplexing -- 5.4 Wireless Crosstalk in MIMO Wireless Link -- 5.5 2 × 2 MIMO Wireless Link Based on Antenna Polarization Diversity with Low Wireless Crosstalk and a Simple Structure -- 5.6 2 × 2 MIMO Wireless Terahertz Wave Signal Transmission System -- 5.6.1 Introduction -- 5.6.2 Experimental Setup -- 5.6.3 Experimental Results.5.7 Conclusion -- References -- 6 Multi-band Terahertz Signal Generation and Transmission -- 6.1 Introduction -- 6.2 Multi-band Terahertz MIMO Transmission Architecture -- 6.3 Multi-band Terahertz Transmission Experimental Device Diagram -- 6.4 Experimental Results of Multi-band Terahertz Transmission -- 6.5 Summary -- References -- 7 Frequency-Stable Photogenerated Vector Terahertz Signal Generation -- 7.1 Introduction -- 7.2 Principle of Optical External Modulator -- 7.2.1 Phase Modulator -- 7.2.2 Mach-Zehnder Modulator -- 7.2.3 Optical I/Q Modulator -- 7.3 Multi-Frequency Vector Terahertz Signal Generation Scheme Based on Cascaded Optical External Modulator -- 7.3.1 Technical Scheme of Multi-frequency Vector Terahertz Signal Generation Based on Cascaded Optical External Modulator -- 7.3.2 Optical Terahertz Signal Transmission Experiment Setup -- 7.3.3 Experimental Results and Analysis -- 7.4 Vector Terahertz Signal Generation Scheme Based on Carrier Suppression Eighth Frequency and Optical Single Sideband -- 7.4.1 Technical Scheme of Vector Terahertz Signal Based on Optical Carrier Suppression Eighth Frequency and Optical Single-Sideband Modulation -- 7.4.2 Experimental Setup of D-band Terahertz Signal Transmission Based on CSFE Scheme and Optical SSB Modulation -- 7.4.3 Experimental Results and Analysis -- 7.5 Summary -- References -- 8 Application of Probabilistic Shaping Technology in Terahertz Communication -- 8.1 Introduction -- 8.2 Principles of Probabilistic Shaping Technology -- 8.2.1 Probabilistic Shaping Modulation Principle Based on Maxwell-Boltzmann Distribution -- 8.2.2 Probabilistic Shaping Realization Method Combined with FEC Coding and Decoding Technology -- 8.3 Simulation Research on Probabilistic Shaping Technology -- 8.4 Experimental Research on Probabilistic Shaping Technology in Single-Carrier Terahertz Communication.8.5 Experimental Study of Probabilistic Shaping Technology in Multi-Carrier W-band Communication System -- 8.5.1 Experimental Setup -- 8.5.2 Experimental Results -- 8.6 Summary -- References -- 9 Terahertz Communication System Based on KK Receiver -- 9.1 The Introduction -- 9.2 The Principle and Application of KK Algorithm -- 9.2.1 Intersignal Beat Frequency Interference (SSBI) Generation -- 9.2.2 Minimum Phase Condition -- 9.3 Application of KK Receiver -- 9.4 KK Algorithm Performance Simulation -- 9.5 Experimental Research on Photon-Assisted Single-Carrier RoF Communication System -- 9.5.1 Experimental Setup -- 9.5.2 Experimental Results and Analysis -- 9.6 Summary -- References -- 10 Ultra-Large-Capacity Terahertz Signal Wireless Transmission System -- 10.1 Introduction -- 10.2 Methods of High-Speed Wireless Transmission -- 10.2.1 Photon-Assisted Methods -- 10.2.2 Multi-dimensional Multiplexing -- 10.2.3 High-Order QAM Modulation Combined with Probabilistic Shaping Technology -- 10.2.4 Advanced DSP Algorithm -- 10.3 Large-Capacity Terahertz Transmission -- 10.3.1 328 Gb/s Dual Polarization D-band Terahertz 2 × 2 MU-MIMO Optical Carrier Wireless Transmission -- 10.3.2 Wireless Transmission of 1 Tb/s Terahertz Signal in D-band -- 10.4 Summary -- References -- 11 Application of Chaotic Encryption Technology in Terahertz Communication -- 11.1 Introduction -- 11.2 The Principle of Chaotic Encryption Technology -- 11.3 Application of Third-Order Chaotic Encryption Technology in Terahertz Communication -- 11.3.1 Experimental Setup of Third-Order Chaotic Encryption Terahertz Communication System -- 11.3.2 Experimental Results and Analysis -- 11.4 Summary -- References -- 12 Large-Capacity Optical and Wireless Seamless Integration and Real-Time Transmission System -- 12.1 Introduction -- 12.2 Principle of Photonic Millimeter Wave Demodulation.12.2.1 Principle of Photon Demodulation Based on Push-Pull MZM -- 12.2.2 PM-Based Photon Demodulation Principle -- 12.2.3 Polarization Demultiplexing of PDM-QPSK-Modulated Fiber-Wireless-Fiber Fusion System -- 12.3 Experiment of Q-band Fiber-Wireless-Fiber Fusion System Based on Push-Pull MZM -- 12.4 Experiment of W-band Fiber-Wireless-Fiber Fusion System Based on Push-Pull MZM -- 12.5 Experiment of W-band Fiber-Wireless-Fiber Fusion System Based on PM -- 12.6 Real-Time Transmission Experiment Based on Heterodyne Detection -- 12.6.1 Real-Time Transmission Experiment Graph -- 12.6.2 Experimental Results -- 12.7 Summary -- References -- 13 THz and Optical Fiber Communication Seamless Integration System -- 13.1 Introduction -- 13.2 Process Algorithm for Heterodyne Coherent Detection -- 13.3 Optical Fibe-Terahertz Wireless-Fiber Seamless Fusion Communication System -- 13.3.1 System Experiment -- 13.3.2 Experimental Results -- 13.4 Optical Fiber-Terahertz Wireless-Optical Fiber 2 × 2MIMO Transmission System -- 13.4.1 System Experiment -- 13.4.2 Experimental Results -- 13.5 Summary -- References.Terahertz technologyTerahertz technology.621.38133Yu Jianjun966315MiAaPQMiAaPQMiAaPQBOOK9910488693203321Broadband Terahertz Communication Technologies2193144UNINA