Abstract
Reservoir computing (RC) is a recently introduced bio-inspired computational framework capable of excellent performances in the temporal data processing, owing to its derivation from the recurrent neural network (RNN). It is well-known for the fast and effective training scheme, as well as the ease of the hardware implementation, but also the problematic sensitivity of its performance to the optimizable architecture parameters. In this article, a particular time-delayed RC with a single clamped–clamped silicon beam resonator that exhibits a classical Duffing nonlinearity is presented and its optimization problem is studied. Specifically, we numerically analyze the nonlinear response of the resonator and find a quasi-linear bifurcation point shift of the driving voltage with the driving frequency sweeping, which is called Bifurcation Point Frequency Modulation (BPFM). Furthermore, we first proposed that this method can be used to find the optimal driving frequency of RC with a Duffing mechanical resonator for a given task, and then put forward a comprehensive optimization process. The high performance of RC presented on four typical tasks proves the feasibility of this optimization method. Finally, we envision the potential application of the method based on the BPFM in our future work to implement the RC with other mechanical oscillators.
Highlights
Reservoir computing (RC) is a recently introduced bio-inspired computational framework capable of excellent performances in the temporal data processing, owing to its derivation from the recurrent neural network (RNN)
We propose a novel method called Bifurcation Point Frequency Modulation (BPFM) to find the optimal driving frequency and put forward a comprehensive optimization process for the time-delayed Reservoir computing with a nonlinear Duffing mechanical oscillator
BPFM describes the relationship between the driving voltage of the bifurcation point and the driving frequency near the resonant frequency
Summary
Details of this task are explained below) reveal that the NMSE of the first bifurcation (Point B) is better than that of the second bifurcation (Point D) for different virtual node N and different delay feedback gain α. The results of the Parity benchmark task are shown in the Supplemental Information 1. These results prove that the first bifurcation (Point B) is the optimal operating point of our RC system. According to the Multiple Scale Method, the smaller the detuning of the system is (that is, the driving frequency is closer to the natural frequency), the more obvious the linear relationship is. To ensure this quasi-linear relationship, the range of frequency scanning is limited from 345 to 355 kHz
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