Related papers: Multi-Task Wavelength-Multiplexed Reservoir Computing Using a Silicon Microring Resonator

Multi-Task Wavelength-Multiplexed Reservoir Computing Using a Silicon Microring Resonator

URL: http://arxiv.org/abs/2310.16588v2
Date: Sat, 27 Apr 2024 18:25:51 GMT
Title: Multi-Task Wavelength-Multiplexed Reservoir Computing Using a Silicon Microring Resonator
Authors: Bernard J. Giron Castro, Christophe Peucheret, Darko Zibar, Francesco Da Ros,
Abstract summary: We numerically demonstrate the simultaneous use of time and frequency (equivalently wavelength) multiplexing to solve three independent tasks at the same time on the same photonic circuit. This work provides insight into the potential of WDM-based schemes for improving the computing capabilities of reservoir computing schemes.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Among the promising advantages of photonic computing over conventional computing architectures is the potential to increase computing efficiency through massive parallelism by using the many degrees of freedom provided by photonics. Here, we numerically demonstrate the simultaneous use of time and frequency (equivalently wavelength) multiplexing to solve three independent tasks at the same time on the same photonic circuit. In particular, we consider a microring-based time-delay reservoir computing (TDRC) scheme that simultaneously solves three tasks: Time-series prediction, classification, and wireless channel equalization. The scheme relies on time-division multiplexing to avoid the necessity of multiple physical nonlinear nodes, while the tasks are parallelized using wavelength division multiplexing (WDM). The input data modulated on each optical channel is mapped to a higher dimensional space by the nonlinear dynamics of the silicon microring cavity. The carrier wavelength and input power assigned to each optical channel have a high influence on the performance of its respective task. When all tasks operate under the same wavelength/power conditions, our results show that the computing nature of each task is the deciding factor of the level of performance achievable. However, it is possible to achieve good performance for all tasks simultaneously by optimizing the parameters of each optical channel. The variety of applications covered by the tasks shows the versatility of the proposed photonic TDRC scheme. Overall, this work provides insight into the potential of WDM-based schemes for improving the computing capabilities of reservoir computing schemes.

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