Abstract
References
- S. Personick, Fiber Optics. New York, NY: Springer, 2013.
- J. Benzoni and D. Orletsky, Military applications of fiber optics technology. Santa Monica, Calif.: Rand, 1989.
- J. Buydos, Fiber optics. Washington, D.C.: Science Reference Section, Science and Technology Division, Library of Congress, 1988.
- N. Kapany, Fiber optics. New York: Academic Press, 1967.
- C. Hentschel, Fiber optics handbook. Boeblingen: Hewlett-Packard, Instruments Division, 1989.
- J. Petersen, Fiber optics illustrated dictionary. Boca Raton, Fla.: CRC Press, 2003.
- B. Smith, Careers in fiber optics. New York: Rosen Pub. Group, 1998.
- R. Clark and R. Hester, Advances in non-linear spectroscopy. Chichester: Wiley, 1988.
- K. Linden, Laser diode and LED applications III. Bellingham, Wash.: Society of Photo-optical Instrumentation Engineers, 1997.
IMPROVING THE LIMITATIONS IN THE CAPACITY OF FIBER OPTICS USING MODIFIED NONLINEAR FOURIER TRANSFORM
Abstract
The central objective of this work is to suggest and develop one simple, unified method for communication over optical fiber networks, valid for all values of dispersion and nonlinearity parameters, and for a single-user channel or a multiple-user network. The method is based on the nonlinear Fourier transform (NFT), a powerful tool in soliton theory and exactly solvable models for solving integral partial differential equations governing wave propagation in certain nonlinear media. The NFT related signal degrees of freedom in such models, in much the same way that the Fourier transform does for linear systems. In this thesis, this observation is exploited for data transmission over integral channels such as optical fibers, where pulse propagation is governed by the nonlinear Schödinger (NLS) equation. In this transmission scheme, which can be viewed as a nonlinear analogue of orthogonal frequency-division multiplexing commonly used in linear channels, information is encoded in the nonlinear spectrum of the signal. Just as the (ordinary) Fourier transform converts a linear convolutional channel into a number of parallel scalar channels, the nonlinear Fourier transform converts a nonlinear dispersive channel described by a lax convolution into a number of parallel scalar channels. Since, in the spectral coordinates the NLS equation is multiplicative, users of a network can operate in independent nonlinear frequency bands with no deterministic inter-channel interference.
Keywords
Vertical cavity surface emitting laser Data transmission Fiber optics Dispersion shifted fiber Power consumption Fourier transform
References
- S. Personick, Fiber Optics. New York, NY: Springer, 2013.
- J. Benzoni and D. Orletsky, Military applications of fiber optics technology. Santa Monica, Calif.: Rand, 1989.
- J. Buydos, Fiber optics. Washington, D.C.: Science Reference Section, Science and Technology Division, Library of Congress, 1988.
- N. Kapany, Fiber optics. New York: Academic Press, 1967.
- C. Hentschel, Fiber optics handbook. Boeblingen: Hewlett-Packard, Instruments Division, 1989.
- J. Petersen, Fiber optics illustrated dictionary. Boca Raton, Fla.: CRC Press, 2003.
- B. Smith, Careers in fiber optics. New York: Rosen Pub. Group, 1998.
- R. Clark and R. Hester, Advances in non-linear spectroscopy. Chichester: Wiley, 1988.
- K. Linden, Laser diode and LED applications III. Bellingham, Wash.: Society of Photo-optical Instrumentation Engineers, 1997.
Details
| Primary Language | English |
|---|---|
| Subjects | Communication and Media Studies |
| Journal Section | Research Article |
| Authors | |
| Publication Date | December 31, 2024 |
| Submission Date | January 18, 2021 |
| Acceptance Date | March 14, 2024 |
| Published in Issue | Year 2024 Volume: 8 Issue: 2 |
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