Title :
Modelling optical pulse propagation in nonlinear media using wavelets
Author :
Pierce, Iestyn ; Watkins, Lionel
Author_Institution :
Sch. of Electron. Eng. & Comput. Syst., Wales Univ., Bangor, UK
Abstract :
A wavelet based model for propagation of optical pulses in nonlinear media is presented. We obtain an O(N) algorithm for linear propagation by replacing the wavelet-domain propagation operator by its Taylor series approximation. Nonlinear propagation is then achieved by adding the nonlinear term in mid-step in a method analogous to the split-step Fourier method. Using wavelets offers the advantage of O(N) computational complexity compared with O(N log N) for fast Fourier transform methods. Using a wavelet basis also leads naturally to the time-resolved spectrum of the signal. Another advantage is that the local properties of wavelets will allow locally adaptive algorithms to be implemented
Keywords :
adaptive signal processing; computational complexity; nonlinear optics; optical fibre communication; optical fibre theory; optical information processing; series (mathematics); spectral analysis; wavelet transforms; Taylor series approximation; algorithm; computational complexity; fast Fourier transform methods; linear propagation; local properties; locally adaptive algorithms; nonlinear media; nonlinear propagation; optical fibre communication; optical pulse propagation; split-step Fourier method; time-resolved spectrum; wavelet based model; wavelet basis; wavelet-domain propagation operator; Computational complexity; Integral equations; Optical fiber dispersion; Optical fibers; Optical propagation; Optical pulses; Polynomials; Pulse measurements; Taylor series; Wavelet transforms;
Conference_Titel :
Time-Frequency and Time-Scale Analysis, 1996., Proceedings of the IEEE-SP International Symposium on
Conference_Location :
Paris
Print_ISBN :
0-7803-3512-0
DOI :
10.1109/TFSA.1996.547488
