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Researchers Customize Broadband Light Sources Using a Photonic Chip and AI

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Researchers from Institut National de la Recherche Scientifique (INRS) and the University of Sussex have collaborated to create an optical device that uses AI to control the properties of light. Using an actively controlled photonic chip, the researchers prepared and manipulated patterns of femtosecond (fs) optical pulses. These pulses enabled access to an enhanced parameter space within the framework of supercontinuum generation (i.e., the generation of extended light spectra through intense light-matter interactions). The researchers used machine learning techniques to tune their approach.

The development of lasers featuring intense and ultrashort laser pulses, along with ways to spatially confine and guide light propagation, has led to an array of possibilities for optical systems, including the generation of supercontinuum.

Femtosecond pulse patterns, prepared by a photonic chip to seed the generation of supercontinuum. INRS and University of Sussex.

Spectrotemporal representation of femtosecond pulse patterns, prepared by a photonic chip to seed the generation of supercontinuum. The patterns are optimized via machine learning to select and enhance desired properties in the output supercontinuum. Here, the pulses are separated by 1 picosecond and measured experimentally via frequency-resolved optical gating (FROG). Courtesy of Benjamin Wetzel.

By exploiting the ability of powerful, miniature, optical chips to shape and control laser light, the researchers developed a way to divide and recombine laser pulses so as to control the individual characteristics of the light pulses. They created and manipulated intense ultrashort pulse patterns, demonstrating diverse patterns of fs optical pulses. These pulses could be used to generate a broadband optical spectrum.

“We have taken advantage of the compactness, stability, and subnanometer resolution offered by integrated photonic structures to generate reconfigurable bunches of ultrashort optical pulses,” said Benjamin Wetzel, a principal investigator at the University of Sussex. “The exponential scaling of the parameter space obtained yields to over 1036 different configurations of achievable pulse patterns, more than the number of stars estimated in the universe.”

An ultrashort pulse is sent into an optical fiber and produces new frequency components via intense light-matter interactions. INRS and University of Sussex.

An ultrashort pulse is sent into an optical fiber and produces new frequency components via intense light-matter interactions. The progressive spectral broadening of the initial light pulse occurring during propagation ultimately leads to the formation of a so-called supercontinuum. In the example here, this corresponds to a “white light” source that, similar to a rainbow, is composed of all the colors seen in the visible region of the electromagnetic spectrum. Courtesy of Benjamin Wetzel.


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To meet the computing power requirements required for its approach, the team used an automatic learning algorithm to help determine the best parameter combinations for obtaining the exact type of light they desired. The researchers showed that the control and customization of the output light could be performed efficiently, when they conjointly used their system and an algorithm to explore the multitude of available light pulse patterns possible for tailoring complex physical dynamics.

This approach, which combines an AI algorithm and a photonic chip, could lead to a better understanding of light-matter interactions and enable ultrafast nonlinear optics.

To keep pushing the limits of laser science, metrology, sensing, and biomedical imaging technologies, additional tailoring capability of light properties is needed, the researchers said. With this work, the international research team has unveiled a potential solution to customizing light properties that is scalable and practical.

This work could affect fundamental and applied research in a number of fields, because many current optical systems rely on the same physical and nonlinear effects as those underlying supercontinuum generation. The team’s novel approach could seed the development of other smart optical systems via self-optimization techniques, including the control of optical frequency for metrology applications, self-adjusting lasers, pulse processing, and amplification, as well as the implementation of more fundamental approaches to machine learning, such as photonic neural network systems.

The research was published in Nature Communications (https://doi.org/10.1038/s41467-018-07141-w).

Published: November 2018
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