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Broadband terahertz communication technologies / / Jianjun Yu
| Broadband terahertz communication technologies / / Jianjun Yu |
| Autore | Yu Jianjun |
| Pubbl/distr/stampa | Gateway East, Singapore : , : Springer, , [2021] |
| Descrizione fisica | 1 online resource (280 pages) |
| Disciplina | 621.38133 |
| Soggetto topico | Terahertz technology |
| ISBN | 981-16-3160-3 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
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. |
| Record Nr. | UNISA-996466847603316 |
Yu Jianjun
|
||
| Gateway East, Singapore : , : Springer, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
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Broadband terahertz communication technologies / / Jianjun Yu
| Broadband terahertz communication technologies / / Jianjun Yu |
| Autore | Yu Jianjun |
| Pubbl/distr/stampa | Gateway East, Singapore : , : Springer, , [2021] |
| Descrizione fisica | 1 online resource (280 pages) |
| Disciplina | 621.38133 |
| Soggetto topico | Terahertz technology |
| ISBN | 981-16-3160-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
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. |
| Record Nr. | UNINA-9910488693203321 |
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Yu Jianjun
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| Gateway East, Singapore : , : Springer, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Digital Signal Processing In High-Speed Optical Fiber Communication Principle and Application [[electronic resource] /] / by Jianjun Yu, Nan Chi
| Digital Signal Processing In High-Speed Optical Fiber Communication Principle and Application [[electronic resource] /] / by Jianjun Yu, Nan Chi |
| Autore | Yu Jianjun |
| Edizione | [1st ed. 2020.] |
| Pubbl/distr/stampa | Singapore : , : Springer Singapore : , : Imprint : Springer, , 2020 |
| Descrizione fisica | 1 online resource (XLII, 542 p. 466 illus., 374 illus. in color.) |
| Disciplina | 621.3822 |
| Soggetto topico |
Electrical engineering
Microwaves Optical engineering Signal processing Image processing Speech processing systems Lasers Photonics Communications Engineering, Networks Microwaves, RF and Optical Engineering Signal, Image and Speech Processing Optics, Lasers, Photonics, Optical Devices |
| ISBN | 981-15-3098-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Introduction -- Single-carrier advanced modulation formats -- Basic Digital signal processing for single carrier signals -- Quasi-linear coherent optical transmission system and digital signal processing -- Super Nyquist wavelength division multiplexing system -- All-optical Nyquist signal -- Nonlinear compensation in optical fiber -- Probabilistic Shaping -- High baud signal transmission -- Advanced modulation code optical signal transmission technology -- Carrierless amplitude and phase modulation -- PAM 4 signal modulation and digital signal processing-based detection technology -- Optical OFDM -- Direct Detection OFDM -- Intensity Modulation Direct Detection High Speed Fiber Access System -- High-speed fiber access system based on direct detection of I/Q modulation -- Forward Error Correction -- High Spectral Efficiency Optical Four-Dimensional Modulation -- Machine Learning Algorithm in the Optical Communication System -- Kramers-Kronig receiver in direct detection. |
| Record Nr. | UNINA-9910411935103321 |
|
Yu Jianjun
|
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| Singapore : , : Springer Singapore : , : Imprint : Springer, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||