Handbook of optical fibers /
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| Imprint: | Singapore : Springer, 2019. |
|---|---|
| Description: | 1 online resource : illustrations (some color) |
| Language: | English |
| Subject: | |
| Format: | E-Resource Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/11939030 |
Table of Contents:
- Intro; Preface; Contents; About the Editor; Section Editors; Contributors; Part I Optical Fiber for Communication; 1 Single-Mode Fibers for High Speed and Long-HaulTransmission; Introduction; Background and History of Optical Fiber; History of Fiber Evolution (1966-1987); History of Fiber Evolution (1987-2007); History of Fiber Evolution (2007 Onwards); Optical Fiber Designs for Long-Haul Transmission; Quantification of System Level Performance; Long-Haul and Ultra-Long-Haul Transmission Systems; Raman Gain Considerations; Unrepeatered Span Transmission Systems
- Transmission System Modeling and ExperimentsOther Factors and Considerations; Splice Loss; Practical Benefits of Ultra-Low Attenuation and Large Effective Area Fibers; Potential Future Directions; Conclusions; References; 2 Multimode Fibers for Data Centers; Introduction of Multimode Fibers; Basics of Multimode Optical Fibers; Light Propagation, Characterization, and Link Performance; MMF Characterization: Modal Bandwidth and DMD; Source Characterization (Encircled Flux); System Link Models; Limitation of VCSEL-MMF Transmission and Novel Solutions; Limiting Factors for VCSEL-MMF Transmission
- Chromatic Dispersion CompensationPerformance of MMF with Different Peak Wavelength in WDM-Based Transceivers; Modal Dispersion Compensation for SWDM Applications; Multimode Fiber for Long Wavelength Applications; Motivation for Long Wavelength MMF Systems; Design of MMF for Long Wavelength Transceivers; System Testing of MMF Optimized for 1060 nm; System Testing of MMF Optimized for 1310 nm; Universal Fibers, a New Fiber Concept Bridging SM and MM Transmissions in Data Centers; Universal Fiber Concept and Benefits; Fiber Designs
- System Level Testing and Verification for Major MM and SM ApplicationsOptical Trends in Data Centers and Concluding Remarks; Optical Trends in the Data Center; Concluding Remarks; References; 3 Multi-core Fibers for Space Division Multiplexing; Introduction; Basics of the Coupled-Mode Theory for Optical Fibers; Coupled-Mode Theory for Orthogonal Modes; Coupled-Mode Theory for Non-orthogonal Modes; Reciprocity of the Mode Coupling Coefficient; Uncoupled Multi-core Fibers; Mode Coupling in Weakly Coupled MCF; Random Mode Coupling Due to Longitudinal Perturbations
- Discrete Coupling Model and Statistical Distribution of the CrosstalkCoupled Power Theory for Predicting the Statistical Mean of the Crosstalk; Local Power Coupling Coefficient Under High-Spatial-Frequency Perturbations Without Bend Radius Change and Fiber Twisting; Power Coupling Coefficient Averaged Over Fiber Twisting; Crosstalk Suppression Strategy; Suppression of the Mode Coupling Coefficient; Suppression of the Phase Matching; Coupled Multi-core Fibers; Systematically Coupled Multi-core Fiber; Randomly Coupled Multi-core Fiber; Mechanism of Random Mode Coupling