Lower Bound on the Capacity of the Continuous-Space SSFM Model of Optical Fiber

Abstract

The capacity of a discrete-time model of optical fiber described by the split-step Fourier method (SSFM) as a function of the signal-to-noise ratio SNR and the number of segments in distance K is considered. It is shown that if K≥ SNR2/3 and SNR → ∞, the capacity of the resulting continuous-space lossless model is lower bounded by 122(1+SNR) - 12+ o(1), where o(1) tends to zero with SNR. As K→ ∞, the inter-symbol interference (ISI) averages out to zero due to the law of large numbers and the SSFM model tends to a diagonal phase noise model. It follows that, in contrast to the discrete-space model where there is only one signal degree-of-freedom (DoF) at high powers, the number of DoFs in the continuous-space model is at least half of the input dimension n. Intensity-modulation and direct detection achieves this rate. The pre-log in the lower bound when K= [δ]SNR is generally characterized in terms of δ. It is shown that if the nonlinearity parameter γ→ ∞, the capacity of the continuous-space model is 122(1+SNR)+ o(1). The SSFM model when the dispersion matrix does not depend on K is considered. It is shown that the capacity of this model when K= [δ]SNR, δ>3, and SNR → ∞ is 12n2(1+SNR)+ O(1). Thus, there is only one DoF in this model. Finally, it is found that the maximum achievable information rates (AIRs) of the SSFM model with back-propagation equalization obtained using numerical simulation follows a double-ascent curve.