Dian-Zuo Yue scite author profile

In this work, the performance of an optoelectronic time-delay reservoir computing system for performing a handwritten digit recognition task is numerically investigated, and a scheme to improve the recognition speed using multiple parallel reservoirs is proposed. By comparing four image injection methods based on a single time-delay reservoir, we find that when injecting the histograms of oriented gradient (HOG) features of the digit image, the accuracy rate (AR) is relatively high and is less affected by the offset phase. To improve the recognition speed, we construct a parallel time-delay reservoir system including multi-reservoirs, where each reservoir processes part of the HOG features of one image. Based on 6 parallel reservoirs with each reservoir possessing 100 virtual nodes, the AR can reach about 97.8%, and the reservoir processing speed can reach about 1 × 106 digits per second. Meanwhile, the parallel reservoir system shows strong robustness to the parameter mismatch between multi-reservoirs.

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Performance optimization of a reservoir computing system based on a solitary semiconductor laser under electrical-message injection

Zeng

Yue

et al. 2020

Appl. Opt.

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A simple reservoir computing (RC) system based on a solitary semiconductor laser under an electrical message injection is proposed, and the performances of the RC are numerically investigated. Considering the lack of memory capacity (MC) in such a system, some auxiliary methods are introduced to enhance the MC and optimize the performances for processing complex tasks. In the pre-existing method, the input information is the current input data combined with some past input data in a weighted sum in the input layer (named as M -input). Another auxiliary method (named as M -output) is proposed to introduce the output layer for optimizing the performances of the RC system. The simulated results demonstrate that the MC of the system can be improved after adopting the auxiliary methods, and the effectiveness under adopting the M -input integrated with the M -output (named as M -both) is the most significant. Furthermore, we analyze the system performances for processing the Santa Fe time series prediction task and the nonlinear channel equalization (NCE) task after adopting the above three auxiliary methods. Results show that the M -input is the most suitable for the prediction task while the M -both is the most appropriate for the NCE task.

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Parallel information processing using a reservoir computing system based on mutually coupled semiconductor lasers

et al. 2020

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Prediction and classification performance of reservoir computing system using mutually delay-coupled semiconductor lasers

Hou

Xia

Jayaprasath

et al. 2019

Optics Communications

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Dian-Zuo Yue

Performance optimization research of reservoir computing system based on an optical feedback semiconductor laser under electrical information injection

Handwritten Digits Recognition Based on a Parallel Optoelectronic Time-Delay Reservoir Computing System

Performance optimization of a reservoir computing system based on a solitary semiconductor laser under electrical-message injection

Parallel information processing using a reservoir computing system based on mutually coupled semiconductor lasers

Prediction and classification performance of reservoir computing system using mutually delay-coupled semiconductor lasers

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