Control and Detection of Discrete Spectral Amplitudes in Nonlinear Fourier Spectrum

TL;DR

This paper introduces advanced algorithms for controlling and detecting discrete spectral amplitudes in the nonlinear Fourier spectrum, enhancing the design and detection of soliton pulses in nonlinear Fourier division multiplexing.

Contribution

It presents a novel forward-backward method for numerically computing the nonlinear Fourier Transform with high precision, and simplifies the Darboux Transform for generating desired discrete spectra.

Findings

The forward-backward method achieves high numerical accuracy in NFT computations.

The simplified Darboux Transform effectively generates specific discrete spectra.

Algorithms enable precise design and detection of complex soliton pulses.

Abstract

Nonlinear Fourier division Multiplexing (NFDM) can be realized from modulating the discrete nonlinear spectrum of an $N$-solitary waveform. To generate an $N$-solitary waveform from desired discrete spectrum (eigenvalue and discrete spectral amplitudes), we use the Darboux Transform. We explain how to the norming factors must be set in order to have the desired discrete spectrum. To derive these norming factors, we study the evolution of nonlinear spectrum by adding a new eigenvalue and its spectral amplitude. We further simplify the Darboux transform algorithm. We propose a novel algorithm (to the best of our knowledge) to numerically compute the nonlinear Fourier Transform (NFT) of a given pulse. The NFT algorithm, called forward-backward method, is based on splitting the signal into two parts and computing the nonlinear spectrum of each part from boundary ($\pm\infty$) inward. The nonlinear spectrum (discrete and continuous) derived from efficiently combining both parts has a promising numerical precision. This method can use any of one-step discretization NFT methods, e.g. Crank-Nicolson, as an NFT kernel for the forward or backward part. Using trapezoid rule of integral, we use an NFT kernel (we called here Trapezoid discretization NFT) in forward-backward method which results discrete spectral amplitudes with a very good numerical precision. These algorithms, forward-backward method and Darboux transform, are used in [1],[2] for design and detection of phase-modulated 2-soliton pulses, and more recently, in [3] for design and detection of more complex pulses with 7 eigenvalues and modulation of spectral phase. For those soliton pulses, the discrete spectral amplitudes (in particular, phase) of both eigenvalues are quite precisely estimated using the forward-backward method.