Abstract
Supercontinuum generation is a highly nonlinear process that exhibits unstable and chaotic characteristics when developing from long pump pulses injected into the anomalous dispersion regime of an optical fiber. A particular feature associated with this regime is the long-tailed “rogue wave”-like statistics of the spectral intensity on the long-wavelength edge of the supercontinuum, linked to the generation of a small number of “rogue solitons” with extreme red-shifts. Whilst the statistical properties of rogue solitons can be conveniently measured in the spectral domain using the real-time dispersive Fourier transform technique, we cannot use this technique to determine any corresponding temporal properties since it only records the spectral intensity and one loses information about the spectral phase. And direct temporal characterization using methods such as the time-lens has resolution of typically 100’s of fs, precluding the measurement of solitons which possess typically much shorter durations. Here, we solve this problem by using machine learning. Specifically, we show how supervised learning can train a neural network to predict the peak power, duration, and temporal walk-off with respect to the pump pulse position of solitons at the edge of a supercontinuum spectrum from only the supercontinuum spectral intensity without phase information. Remarkably, the network accurately predicts soliton characteristics for a wide range of scenarios, from the onset of spectral broadening dominated by pure modulation instability to near octave-spanning supercontinuum with distinct rogue solitons.
Highlights
Supercontinuum generation is a highly nonlinear process that exhibits unstable and chaotic characteristics when developing from long pump pulses injected into the anomalous dispersion regime of an optical fiber
We extend the scope of machine learning applications to the analysis of SC instabilities and show how machine learning can overcome the current limitations of real-time experimental techniques by analyzing real-time spectral intensity measurements in a way that allows key temporal characteristics of SC rogue solitons to be determined
Using a feed-forward neural network trained on numerical simulations of the generalized nonlinear Schrödinger equation (GNLSE), we have shown how the temporal characteristics of solitons with extreme red-shift can be predicted with high accuracy based only on single-shot SC spectral intensity profiles without any spectral phase information
Summary
Supercontinuum generation is a highly nonlinear process that exhibits unstable and chaotic characteristics when developing from long pump pulses injected into the anomalous dispersion regime of an optical fiber. In order to characterize real-time temporal fluctuations associated with incoherent dynamics, more complex techniques using time-lens or heterodyne approaches need to be used[19,21,22,23,24], yet measurements in this case are generally restricted to specific (narrow bandwidth) wavelength ranges with sub-ps timescale resolution. These limitations preclude the characterization of solitons or localized structures with 10’s of femtosecond duration which is typically the duration of solitons emerging in supercontinuum generation. Machine learning is a powerful tool to correlate quantitative characteristics in a complex system with multiple data features, a strength which has been successfully exploited to determine the maximum intensity of temporal peaks in modulation instability based only on spectral measurements[30]
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