Full-Spectrum Periodic Nonlinear Fourier Transform Optical Communication Through Solving the Riemann-Hilbert Problem

• Published in: Journal of lightwave technology Vol. 38; no. 14; pp. 3602 - 3615
• Main Authors: Kamalian-Kopae, Morteza, Vasylchenkova, Anastasiia, Shepelsky, Dmitry, Prilepsky, Jaroslaw E., Turitsyn, Sergei K.
• Format: Journal Article
• Language: English
• Published: New York IEEE 15.07.2020; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Bit error rate; coherent communications; Communications systems; Computer simulation; Fibre-optic communications; Fourier transforms; Inverse problems; inverse scattering; Mathematical model; Nonlinear control; nonlinear Fourier transform; Nonlinear optics; Optical communication; Optical fiber communication; Riemann-Hilbert problem; Signal processing; Time domain analysis
• ISSN: 0733-8724; 1558-2213
• DOI: 10.1109/JLT.2020.2979322

In this article, for the first time, a full-spectrum periodic nonlinear Fourier transform (NFT)-based communication system with the inverse transformation at the transmitter performed by using the solution of Riemann-Hilbert problem (RHP), is proposed and studied. The entire control over the nonlinear spectrum rendered by our technique, where we operate with two qualitatively different components of this spectrum represented, correspondingly, in terms of the main spectrum and the phases, allows us to design a time-domain signal tailored to the characteristics of the transmission channel. In the heart of our system is the RHP-based signal processing utilised to generate the time-domain signal from the modulated nonlinear spectrum. This type of NFT processing leads to a computational complexity that scales linearly with the number of time-domain samples, and we can process signal samples in parallel. In this article, we suggest the way of getting an exactly periodic signal through the correctly formulated RHP, and present evidence of the analogy between band-limited (in ordinary Fourier sense) signals and finite-band (in RHP sense) signals. Also, for the first time, we explain how to modulate the phases of individual periodic nonlinear modes. The performance of our transmission system is evaluated through numerical simulations in terms of bit error rate and Q<inline-formula><tex-math notation="LaTeX">^2</tex-math></inline-formula>-factor dependencies on the transmission distance and power, and the results demonstrate the good potential of the approach.