Single-Mode Fibers for High Speed and Long-Haul Transmission

Multimode Fibers for Data Centers

Multi-core Fibers for Space Division Multiplexing

Optical Coherent Detection and Digital Signal Processing of Channel Impairments

A Brief History of Fiber-Optic Soliton Transmission

Perturbations of Solitons in Optical Fibers

Emission of Dispersive Waves from Solitons in Axially Varying Optical Fibers

Nonlinear Waves in Multimode Fibers

Shock Waves

A Variety of Dynamical Settings in Dual-Core Nonlinear Fibers

Advanced Nano-engineered Glass-Based Optical Fibers for Photonics Applications

Fabrication of Negative Curvature Hollow Core Fiber

Optimized Fabrication of Thulium Doped Silica Optical Fiber Using MCVD

Microfiber: Physics and Fabrication

Flat Fibers: Fabrication and Modal Characterization

3D Silica Lithography for Future Optical Fiber Fabrication

Rare-Earth-Doped Laser Fiber Fabrication Using Vapor Deposition Technique

Powder Process for Fabrication of Rare Earth-Doped Fibers for Lasers and Amplifiers

Progress in Mid-infrared Fiber Source Development

Crystalline Fibers for Fiber Lasers and Amplifiers

Cladding-Pumped Multicore Fiber Amplifier for Space Division Multiplexing

Optical Fibers for High-Power Lasers

Multicore Fibers

Polymer Optical Fibers

Optical Fibers in Terahertz Domain

Optical Fibers for Biomedical Applications

Basics of Optical Fiber Measurements

Measurement of Active Optical Fibers

Characterization of Specialty Fibers

Characterization of Distributed Birefringence in Optical Fibers

Characterization of Distributed Polarization-Mode Coupling for Fiber Coils

Materials Development for Advanced Optical Fiber Sensors and Lasers

Optoelectronic Fibers

Fiber Grating Devices

CO2-laser-inscribed long period fiber gratings: from fabrication to applications

Micro-/Nano-optical Fiber Devices

Measurement of Optical Fiber Grating

Measurement of Optical Fibre Amplifier

Measurement of Optical Fiber Laser

Distributed Rayleigh Sensing

Distributed Raman Sensing

Distributed Brillouin Sensing: Time-Domain Techniques

Distributed Brillouin Sensing: Frequency-Domain Techniques

Distributed Brillouin Sensing: Correlation-Domain Techniques

Optical Fibre Sensors for Remote Condition Monitoring of Industrial Structures

Optical Fiber Sensor Network and Industrial Applications

Fibre Optic Sensors for Coal Mine Hazard Detection

Optical Fiber Sensors in Ionizing Radiation Environments

Polymer Optical Fiber Sensors and Devices

Solid Core Single-Mode Polymer Fiber Gratings and Sensors

Microstructured Polymer Optical Fiber Gratings and Sensors

Polymer Fiber Sensors for Structural and Civil Engineering Applications

Photonic Microcells for Sensing Applications

Filling Technologies of Photonic Crystal Fibers and Their Applications

Photonic Crystal Fiber-Based Grating Sensors

Optical Fiber Microfluidic Sensors Based on Opto-physical Effects

Micro-/Nano-Optical Fiber Microfluidic Sensors

All Optical Fiber Optofluidic or Ferrofluidic Microsensors Fabricated by Femtosecond Laser Micromachining

Gang-Ding Peng received his B.Sc. degree in physics from Fudan University, Shanghai, China, in 1982, and the M.Sc. degree in applied physics and Ph.D. in electronic engineering from Shanghai Jiao Tong University, Shanghai, China, in 1984 and 1987, respectively. From 1987 through 1988 he was a lecturer at Jiao Tong University. He was a postdoctoral research fellow in the Optical Sciences Centre of the Australian National University, Canberra, from 1988 to 1991. He has been working at the University of NSW in Sydney, Australia, since 1991; was a Queen Elizabeth II Fellow from 1992 to 1996; and is currently a professor in the same university. He is a fellow and life member of both Optical Society of America (OSA) and The International Society for Optics and Photonics (SPIE). His research interests include silica and polymer optical fibers, optical fiber and waveguide devices, optical fiber sensors, and nonlinear optics. He has worked in research and teaching in photonics and fiber optics for more than 30 years and maintained a high research profile internationally.

This handbook aims to be a comprehensive and up-to-date reference tool for students, scientists, engineers and industrial practitioners who are working in an area of the optical fiber field. 

The book includes five sections that cover the following subtopics as follows:

• Optical Fiber Fundamentals including fiber materials and characteristics, fiber design, analysis, fabrication, test, etc; 

• Optical Fibers including all conventional and special fibers; 

• Optical Fiber Devices including all passive and active fiber devices and components, such as fiber couplers, fiber connectors, fiber gratings, fiber amplifiers and fiber lasers; 

• Optical Fiber Communication including main optical fiber communication techniques and systems 

• Optical Fiber Sensing including main optical fiber sensing and systems