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Main Authors: Zhou, Zixin, Jiang, Tianxi, Yang, Menglong, Feng, Zhihua, He, Qingbo, Zhang, Shiwu
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.17277
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author Zhou, Zixin
Jiang, Tianxi
Yang, Menglong
Feng, Zhihua
He, Qingbo
Zhang, Shiwu
author_facet Zhou, Zixin
Jiang, Tianxi
Yang, Menglong
Feng, Zhihua
He, Qingbo
Zhang, Shiwu
contents Physical neural networks offer a transformative route to edge intelligence, providing superior inference speed and energy efficiency compared to conventional digital architectures. However, realizing scalable, end-to-end, fully analog recurrent neural networks for temporal information processing remains challenging due to the difficulty of faithfully mapping trained network models onto physical hardware. Here we present a fully analog resonant recurrent neural network (R$^2$NN) implemented via a metacircuit architecture composed of coupled electrical local resonators. A reformulated mechanical-electrical analogy establishes a direct mapping between the R$^2$NN model and metacircuit elements, enabling accurate physical implementation of trained neural network parameters. By integrating jointly trainable global resistive coupling and local resonances, which generate effective frequency-dependent negative resistances, the architecture shapes an impedance landscape that steers currents along frequency-selective pathways. This mechanism enables direct extraction of discriminative spectral features, facilitating real-time temporal classification of raw analog inputs while bypassing analog-to-digital conversion. We demonstrate the cross-domain versatility of this framework using integrated hardware for tactile perception, speech recognition, and condition monitoring. This work establishes a scalable, fully analog paradigm for intelligent temporal processing and paves the way for low-latency, resource-efficient physical neural hardware for edge intelligence.
format Preprint
id arxiv_https___arxiv_org_abs_2604_17277
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Fully Analog Resonant Recurrent Neural Network via Metacircuit
Zhou, Zixin
Jiang, Tianxi
Yang, Menglong
Feng, Zhihua
He, Qingbo
Zhang, Shiwu
Machine Learning
Artificial Intelligence
Emerging Technologies
Applied Physics
Physical neural networks offer a transformative route to edge intelligence, providing superior inference speed and energy efficiency compared to conventional digital architectures. However, realizing scalable, end-to-end, fully analog recurrent neural networks for temporal information processing remains challenging due to the difficulty of faithfully mapping trained network models onto physical hardware. Here we present a fully analog resonant recurrent neural network (R$^2$NN) implemented via a metacircuit architecture composed of coupled electrical local resonators. A reformulated mechanical-electrical analogy establishes a direct mapping between the R$^2$NN model and metacircuit elements, enabling accurate physical implementation of trained neural network parameters. By integrating jointly trainable global resistive coupling and local resonances, which generate effective frequency-dependent negative resistances, the architecture shapes an impedance landscape that steers currents along frequency-selective pathways. This mechanism enables direct extraction of discriminative spectral features, facilitating real-time temporal classification of raw analog inputs while bypassing analog-to-digital conversion. We demonstrate the cross-domain versatility of this framework using integrated hardware for tactile perception, speech recognition, and condition monitoring. This work establishes a scalable, fully analog paradigm for intelligent temporal processing and paves the way for low-latency, resource-efficient physical neural hardware for edge intelligence.
title Fully Analog Resonant Recurrent Neural Network via Metacircuit
topic Machine Learning
Artificial Intelligence
Emerging Technologies
Applied Physics
url https://arxiv.org/abs/2604.17277