This tutorial can serve as an introduction to fiber optics, i.e., for learning basic of fiber optics, but it also helps to improve the understanding for people who already have a substantial experience with optical fibers. The focus is on the physics of wave propagation and its technical consequences. We do not go into mathematical details, but rather try to create an intuitive understanding of the operation principles — often by demonstrating certain effects with numerical simulations. The simulation and design software RP Fiber Power of RP Photonics is an excellent tool for such purposes and has been extensively used for this tutorial.
Click on the headings to get to the following parts of the tutorial:
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Part 2: Fiber Modes What are fiber modes? What determines the number of guided modes? What are core and cladding modes, and what are their basic properties? How and when can we calculate light propagation based on modes, and what are the limitations of the mode decomposition technique?
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Part 3: Single-mode Fibers What is the criterion for single-mode guidance? How does light in a single-mode fiber behave? How does the mode size depend on the core size and numerical aperture? How can we calculate the efficiency of launching light into a single-mode fiber?
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Part 4: Multimode Fibers What determines the number of guided modes of a multimode fiber? What are step-index and graded-index fibers, and how do they differ in terms of intermodal dispersion? Why does the output beam profile sensitively depend on launch conditions and the state of the fiber? Can we use a multimode fiber for single-mode transmission?
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Part 5: Fiber Ends How to strip, cleave and polish fiber endfaces? How large does the cleave angle have to be to suppress back-reflections?
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Part 6: Fiber Joints How can fibers be spliced together or mated with connectors? What coupling losses arise from non-perfect alignment?
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Part 7: Propagation Losses What are the origins of propagation losses (attenuation) in optical fibers? Where is the loss optimum of silica fibers? Why do single-mode fibers typically exhibit lower losses? What are bend losses, and which design details determine the critical bend radius?
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Part 8: Fiber Couplers and Splitters How does a directional fiber coupler work? Which parameters are most essential for its performance? What are the typical applications of fiber couplers and splitters? Why does the splitting ratio strongly depend on the wavelength? In which wavelength range does such a coupler work?
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Part 9: Polarization Issues What are the origins of birefringence in fibers? How do fiber polarization controllers and polarization-maintaining fibers work? How to make polarization-insensitive fiber devices?
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Part 10: Chromatic Dispersion of Fibers What is chromatic dispersion? How can we understand waveguide dispersion? How does the dispersion change near the cut-off of a fiber mode? What is intermodal dispersion, and how does chromatic dispersion affect fiber-optic links?
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Part 11: Nonlinearities of Fibers What kind of nonlinear effects occur in fibers? Why can nonlinear self-focusing not be avoided by larger mode areas, in contrast to self-phase modulation, stimulated Brillouin and Raman scattering, and other nonlinear effects? What happens to higher-order modes under conditions of very high optical intensities?
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Part 12: Ultrashort Pulses and Signals in Fibers How do dispersive and nonlinear effects work together for ultrashort pulses in fibers? How can a fiber temporally separate different spatial components of a pulsed input? How can soliton pulses be formed? What is supercontinuum generation?
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Part 13: Fiber Accessories and Tools What types of tools can be used for stripping, cleaving and splicing of fibers? How to inspect fiber ends? What can be used to connectorize fibers, or to collimate their output?
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What are fiber modes? What determines the number of guided modes? What are core and cladding modes, and what are their basic properties? How and when can we calculate light propagation based on modes, and what are the limitations of the mode decomposition technique?
What is the criterion for single-mode guidance? How does light in a single-mode fiber behave? How does the mode size depend on the core size and numerical aperture? How can we calculate the efficiency of launching light into a single-mode fiber?
What determines the number of guided modes of a multimode fiber? What are step-index and graded-index fibers, and how do they differ in terms of intermodal dispersion? Why does the output beam profile sensitively depend on launch conditions and the state of the fiber? Can we use a multimode fiber for single-mode transmission?
How to strip, cleave and polish fiber endfaces? How large does the cleave angle have to be to suppress back-reflections?
How can fibers be spliced together or mated with connectors? What coupling losses arise from non-perfect alignment?
What are the origins of propagation losses (attenuation) in optical fibers? Where is the loss optimum of silica fibers? Why do single-mode fibers typically exhibit lower losses? What are bend losses, and which design details determine the critical bend radius?
How does a directional fiber coupler work? Which parameters are most essential for its performance? What are the typical applications of fiber couplers and splitters? Why does the splitting ratio strongly depend on the wavelength? In which wavelength range does such a coupler work?
What are the origins of birefringence in fibers? How do fiber polarization controllers and polarization-maintaining fibers work? How to make polarization-insensitive fiber devices?
What is chromatic dispersion? How can we understand waveguide dispersion? How does the dispersion change near the cut-off of a fiber mode? What is intermodal dispersion, and how does chromatic dispersion affect fiber-optic links?
What kind of nonlinear effects occur in fibers? Why can nonlinear self-focusing not be avoided by larger mode areas, in contrast to self-phase modulation, stimulated Brillouin and Raman scattering, and other nonlinear effects? What happens to higher-order modes under conditions of very high optical intensities?
How do dispersive and nonlinear effects work together for ultrashort pulses in fibers? How can a fiber temporally separate different spatial components of a pulsed input? How can soliton pulses be formed? What is supercontinuum generation?