Novel optimization techniques such as nanophotonic inverse design are promising tools to significantly reduce the size of silicon photonic components while maintaining their functionality and performance. Such techniques, on the other hand, generate discrete designs that are characterized by a large number of variables, requiring computation-intensive design process. AI tools can help identify patterns in the high-dimensional design space through the analysis of a dataset of simulated designs. Those patterns can further guide the search for better performing designs and shed light on the behavior of the design space as a whole, revealing its specificities and limitations. Use of various machine learning methods to identify such patterns will be investigated, in particular in the context of designing in-plane devices such as mode and frequency (de)multiplexers. This project is a collaboration between McGill University and the NRC. McGill University will provide experience in the designs of photonic integrated devices and circuits while the NRC will provide expertise in machine learning and photonics.
Dr. Odile Liboiron-Ladouceur
Dr. Odile Liboiron-Ladouceur is Canada Research Chair in Photonic Interconnects at McGill University. She is currently working on the development of device integration and energy-efficient interconnection architectures that use photonic (or optical) technologies. This will allow large amounts of data to be transferred at the speed of light. Dr. Liboiron-Ladouceur is internationally recognized as an experimentalist developing proof-of-concept prototypes of novel integrated photonic devices and subsystems for data communication.
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Dr. Yuri Grinberg
Dr. Yuri Grinberg is an associate research officer with the National Research Council and is an expert in applied and theoretical machine learning and reinforcement learning. His primary research interests are in advancing the machine learning state of the art to address problems in physics and engineering. In particular, he is interested in development of appropriate AI methodologies for the design of efficient, small-footprint, easy-to-fabricate photonic components with significantly reduced human effort.
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Dr. Dan-Xia Xu
Dan-Xia Xu is a Principal Research Officer of the National Research Council, a Fellow of the Royal Society of Canada, Fellow of the Optical Society (OSA), and an adjunct professor with Carleton University. Her research field focusses on silicon photonics for optical communications, photonic thermometry, molecular sensing and beyond. She has led pioneering work in cladding stress engineering for polarization control of photonic components, and in high-sensitivity biosensor systems using silicon wire spiral resonators. One particular recent interest is to transform the traditional photonic design and discovery cycle through the use of artificial intelligence (AI) and machine learning (ML) methods. The ultimate goal of this work is to create AI/ML-enabled computational methods that augment designers’ knowledge and intuition, accelerate the photonic design process, and enable the autonomous discovery of non-intuitive and high-performance designs.
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