On Discrete-Time/Frequency-Periodic End-to-End Fiber-Optical Channel Models
Felix Frey, Johannes K. Fischer, Robert F.H. Fischer

TL;DR
This paper develops a novel discrete-time and frequency-periodic end-to-end fiber-optical channel model based on perturbation theory, offering a new perspective on nonlinear interference and efficient computational implementation.
Contribution
It introduces a new frequency-domain periodic model with aliasing considerations and extends the regular model to include multiplicative distortions, improving analysis accuracy.
Findings
Model aligns well with split-step Fourier method in MSE sense
Provides a single-step computational algorithm
Incorporates aliasing effects in frequency domain
Abstract
A discrete-time end-to-end fiber-optical channel model is derived based on the first-order perturbation approach. The model relates the discrete-time input symbol sequences of co-propagating wavelength channels to the received symbol sequence after matched filtering and T-spaced sampling. To this end, the interference from both self- and cross-channel nonlinear interactions of the continuous-time optical signal is represented by a single discrete-time perturbative term. Two equivalent discrete-time models can be formulated---one in the time-domain, the other in the 1/T-periodic continuous-frequency domain. The time-domain formulation coincides with the well-known pulse-collision picture. The novel frequency-domain picture incorporates the sampling operation via an aliased and periodic kernel description. This gives rise to an alternative perspective on the end-to-end input/output…
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Taxonomy
TopicsOptical Network Technologies · Advanced Photonic Communication Systems · Advanced Fiber Laser Technologies
