In Situ Optimization of an Optoelectronic Reservoir Computer with Digital Delayed Feedback

TL;DR

This paper introduces an in situ optimization method for an optoelectronic reservoir computer with digital delayed feedback, improving performance in signal processing tasks without relying on simulations.

Contribution

The paper presents a novel in situ optimization technique for physical reservoir computing systems, enabling direct parameter tuning in hardware for improved performance.

Findings

Achieved low NMSE in waveform classification, time series prediction, and speech recognition.

Outperformed simulation-based optimization in two of three benchmark tasks.

Demonstrated practical applicability of in situ optimization in physical neuromorphic systems.

Abstract

Reservoir computing (RC) is an innovative paradigm in neuromorphic computing that leverages fixed, randomized, internal connections to address the challenge of overfitting. RC has shown remarkable effectiveness in signal processing and pattern recognition tasks, making it well-suited for hardware implementations across various physical substrates, which promise enhanced computation speeds and reduced energy consumption. However, achieving optimal performance in RC systems requires effective parameter optimization. Traditionally, this optimization has relied on software modeling, limiting the practicality of physical computing approaches. Here, we report an \emph{in situ} optimization method for an optoelectronic delay-based RC system with digital delayed feedback. By simultaneously optimizing five parameters, normalized mean squared error (NMSE) of 0.028, 0.561, and 0.271 is achieved in three benchmark tasks: waveform classification, time series prediction, and speech recognition outperforming simulation-based optimization (NMSE 0.054, 0.543, and 0.329, respectively) in the two of the three tasks. This method marks a significant advancement in physical computing, facilitating the optimization of RC and neuromorphic systems without the need for simulation, thus enhancing their practical applicability.