Optical fiber sensing technologies principles, techniques and applications
Optical Fiber Sensing TechnologiesExplore foundational and advanced topics in optical fiber sensing technologiesIn Optical Fiber Sensing Technologies: Principles, Techniques, and Applications, a team of distinguished researchers delivers a comprehensive overview of all critical aspects of optical fi...
| Otros Autores: | , , , |
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Hoboken, New Jersey :
John Wiley & Sons, Inc
[2022]
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| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009811312306719 |
Tabla de Contenidos:
- CHAPTER 1 OPTICAL FIBER AND OPTICAL DEVICES; 1.1 Optical Fiber; 1.2 Light Source; 1.2.1 Semiconductor Laser; 1.2.2 Optical Fiber Laser; 1.3 Optical Amplifier; 1.3.1 Erbium Doped Fiber Amplifier; 1.3.2 Semiconductor Optical Amplifier; 1.4 Detector; 1.5 Optical Fiber Passive Device; 1.5.1 Optical Fiber Coupler; 1.5.2 Optical Fiber Isolator; 1.5.3 Optical Fiber Circulator; 1.5.4 Optical Fiber Polarizer; 1.5.5 Optical Fiber Switcher; 1.6 Optical Fiber Modulator; ; CHAPTER 2 OPTICAL FIBER BRAGG GRATING SENSING TECHNOLOGY; 2.1 Principle of Fiber Bragg Grating Sensing; 2.2 Photosensitivity of Ge-Doped Fiber; 2.3 Fabrication of Fiber Bragg Grating; 2.4 Package Design for Strain and Temperature Sensing; 2.4.1 Package Design for Strain Sensing; 2.4.2 Package Design for Temperature Sensing; 2.4.3 Performance Evaluation Under Cryogenic Temperature; 2.5 Demodulation of Fiber Bragg Grating Sensing for Space Application; 2.5.1 Demodulation Theory of Fiber Bragg Grating Sensing; 2.5.2 Demodulation Instrument Development; 2.5.3 Effect of Environment Temperature Variation; ; CHAPTER 3 EXTRINSIC-FABRY-PEROT-INTERFEROMETER-BASED OPTICAL FIBER SENSING TECHNOLOGY; 3.1 Principle of Fabry-Perot Interferometer; 3.2 Fabry-Perot Interferometer Based Optical Fiber Sensor Structure; 3.3 Silicon-Diaphragm Optical Fiber Sensor; 3.3.1 Silicon-Diaphragm Optical Fiber Pressure Sensor; 3.3.2 Silicon-Diaphragm Optical Fiber Temperature Sensor; 3.3.3 Non-Intrusive Optical Fiber Sensor Head Chip Inspection Method; 3.4 Polarization Low Coherence Interference Demodulation for Pressure Sensing; 3.4.1 Demodulation Theory; 3.4.2 Demodulation Instrument; 3.4.3 Demodulation Algorithm; 3.4.4 Low Coherence Interference Multiplexing; 3.5 Application; 3.5.1 Optical Fiber Pressure Sensing in Ocean Application; 3.5.2 Optical Fiber Pressure Sensing in Aviation Application; ; CHAPTER 4 EXTRINSIC-FABRY-PEROT-INTERFEROMETER-BASED OPTICAL FIBER ACOUSTIC SENSING TECHNOLOGY; 4.1 Polymer-Diaphragm; 4.2 Senor Design and Parameters Optimization; 4.3 Demodulation; 4.3.1 Quadrature Phase Demodulation Theory; 4.3.2 Dual-Laser Quadrature Phase Demodulation Instrument; 4.3.3 Phase-Shifting Demodulation Instrument Using Birefringence Crystals; 4.4 Optical Fiber Acoustic Sensing in Space Application; ; CHAPTER 5 EXTRINSIC-FABRY-PEROT-INTERFEROMETER-BASED OPTICAL FIBER HIGH TEMPERATURE SENSING TECHNOLOGY; 5.1 Sapphire Material Characteristic and Solid Cavity; 5.2 Sensor Design and Parameters Optimization; 5.3 Spectrum Demodulation Theory; 5.4 Spectrum Demodulation Instrument; 5.5 Optical Fiber High Temperature Sensing in Aviation Application; ; CHAPTER 6 ASSEMBLE FREE MICRO-INTERFEROMETER?BASED OPTICAL FIBER SENSING TECHNOLOGY; 6.1 Optical Fiber Sensor Based on Fiber Tip Micro-Michelson Interferometer; 6.2 Optical Fiber Sensor Based on Angled Fiber End; 6.3 Optical Fiber Sensor Based on In-Line Interferometer; ; CHAPTER 7 SURFACE-PLASMON-RESONANCE-BASED OPTICAL FIBER SENSING TECHNOLOGY; 7.1 Coating of Optical Fiber; 7.2 Theoretical Modeling Multimode Optical Fiber Sensor Based on SPR; 7.3 EMD-Based Filtering Algorithm; ; CHAPTER 8 SAGNAC-INTERFEROMETER-BASED OPTICAL FIBER SENSING TECHNOLOGY; 8.1 Principle of Sagnac Interferometer; 8.2 Optical Fiber Gyroscope; 8.3 The Optical Fiber Coil Quality Inspection Method; 8.3.1 Group Birefringence Thermal Coefficient of Polarization-Maintaining Fibers; 8.3.2 Optical Fiber Coil Winding Method; 8.3.3 Polarization Crosstalk Measurement; 8.3.4 Transient Characteristics Measurement with Temperature Stimulation; 8.4 Optical Fiber Current Sensing; ; CHAPTER 9 MODE-INTERFERENCE-BASED OPTICAL FIBER SENSING TECHNOLOGY; 9.1 Mode Interference Theory of Singlemode-Multimode-Singlemode; 9.2 Optical Fiber Refractive Index Sensor Based on SMS; 9.2.1 Sensor Design and Fabrication; 9.2.2 Self-Temperature-Compensation Sensing; 9.2.3 Simultaneous Refractive Index and Temperature Sensing; 9.3 Optical Fiber Magnetic Field Sensor Based on SMS; 9.3.1 Magnetic Fluid; 9.3.2 Sensor Design and Fabrication; 9.3.3 Simultaneous Magnetic Field and Temperature Sensing; ; CHAPTER 10 WHISPER-GALLERY-MODE-BASED OPTICAL FIBER SENSING TECHNOLOGY; 10.1 Whisper-Gallery-Mode Theory; 10.2 Process of Micro Capillary With Inner Pressure Air; 10.2.1 Drawing System and Drawing Model; 10.2.2 Fabrication of Microtube; 10.2.3 Fabrication of Hollow Microsphere; 10.3 Optical Fiber Magnetic Field Sensor Based on Microtube WGM; 10.3.1 Magnetic Nanoparticle Assembly; 10.3.2 Sensor Fabrication and Measurement; 10.4 Optical Fiber Dual Parameters Sensor Based on Hollow Microsphere WGM; 10.5 Ultraprecise Resonance Wavelength Determination Method; ; CHAPTER 11 OPTICAL FIBER INTRA-CAVITY LASER GAS SENSING TECHNOLOGY; 11.1 Theory of Optical Fiber Intra-Cavity Laser Gas Sensing; 11.1.1 Principle of Optical Fiber Laser; 11.1.2 Sensitivity Enhancement of Gas Sensing by Direct Absorption; 11.1.3 Optical Fiber Intra-Cavity Laser Gas Sensing by Wavelength Modulation; 11.1.4 Effect of Temperature on Performance of Gas Sensing; 11.2 Optical Fiber Intra-Cavity Laser Gas Sensing System Design; 11.3 Spectrum Signal Process; 11.3.1 De-Noise with EMD; 11.3.2 Baseline Extraction; 11.3.3 Spectrum Separation; 11.3.4 Concentration Demodulation; 11.4 Wavelength Calibration Analysis and Gas Recognition; ; CHAPTER 12 OPTICAL FIBER BASED OPTICAL COHERENCE TOMOGRAPHY; 12.1 Optical Fiber Coherence Tomography Theory; 12.1.1 Time-Domain Optical Fiber Based Optical Coherence Tomography; 12.1.2 Frequency-Domain Optical Fiber Based Optical Coherence Tomography; 12.2 Functional Optical Fiber Based Optical Coherence Tomography; 12.2.1 Doppler Optical Coherence Tomography; 12.2.2 Polarization Sensitive Optical Coherence Tomography; 12.3 Biomedical Applications; 12.3.1 Dentistry; 12.3.2 Cardiovasology; 12.3.3 Neurology; ; CHAPTER 13 DISCRETE OPTICAL FIBER SENSING NETWORK TECHNOLOGY; 13.1 Topology of Optical Fiber Sensing Network; 13.2 Robustness Evaluation of Optical Fiber Sensing Network; 13.2.1 Robustness Evaluation Model; 13.2.2 Robustness Affection Factor; 13.2.3 Optimization Arrangement; ; CHAPTER 14 DISTRIBUTED VIBRATION SENSING BASED ON DUAL MACH-ZEHNDER INTERFEROMETER; 14.1 Theory of Distributed Vibration Sensing Based on Dual Mach-Zehnder Interferometer; 14.1.1 Principle of System; 14.1.2 Performance Affection Factor; 14.2 Polarization Control Method; 14.2.1 Polarization-Induced Phase Shift and Polarization-Induced Fading; 14.2.2 Chaotic Particle Swarm Optimization Algorithm; 14.2.3 Genetic Algorithm; 14.2.4 Annealing Algorithm; 14.3 Interferometer Based Distributed Vibration Sensing Instrument Design; 14.4 Signal Process Algorithm and Instrument; 14.3.1 Endpoint Detection; 14.3.2 Position Determination; 14.3.3 Intrusion Pattern Recognition; ; CHAPTER 15 REGIONAL STYLE INTELLIGENT PERIMETER SECURITY TECHNIQUE BASE ON MICHELSON INTERFEROMETER; 15.1 Principle of System; 15.2 Instrument Design; 15.3 Perimeter Security Application; ; CHAPTER 16 DISTRIBUTED TEMPERATURE SENSING BASED ON RAMAN SCATTERING; 16.1 Raman Scattering Theory; 16.2 Principle of System; 16.3 Systemn Design; 16.4 De-Noising Algorithm Based on EEMD; 16.5 Applicaion on Electric Power Industry; ; CHAPTER 17 DISTRIBUTED ACOUSTIC SENSING BASED ON OPTICAL TIME DOMAIN REFLECTOMETRY; 17.1 Theory of Optical Time Domain Reflectometry; 17.1.1 Direct-Detection-Based Phase Optical Time Domain Reflectometry; 17.1.2 Coherent-Detection-Based Phase Optical Time Domain Reflectometry; 17.2 Pulse Modulation Method; 17.3 Acoustic Sensitivity Enhance Method of Optical Fiber; 17.4 Dual-Pulse Coherent Phase Optical Time Domain Reflectometry; 17.5 Chirp-Pulse Phase Optical Time Domain Reflectometry; ; CHAPTER 18 DISTRIBUTED SENSING BASED ON OPTICAL FREQUENCY DOMAIN REFLECTOMETRY; 18.1 Principle of Optical Frequency Domain Reflectometry; 18.2 Measurement Range OFDR Beyond Laser Coherence Length; 18.3 Laser Frequency Tuning Nonlinearity and Compensation; 18.3.1 Laser Frequency Tuning Nonlinearity; 18.3.2 Compensation Using Non-Uniform Fast Fourier Transform; 18.3.3 Compensation Using Deskew Filter; 18.4 Distributed Sensing System and Application; 18.4.1 Distributed Vibration Sensing Base on Correlation Analysis; 18.4.2 Distributed Strain and Temperature Measurement; 18.4.3 Distributed Magnetic Field and Current Sensor Bas.
