Toward grouped-reservoir computing: organic neuromorphic vertical transistor with distributed reservoir states for efficient recognition and prediction

Toward grouped-reservoir computing: organic neuromorphic vertical transistor with distributed reservoir states for efficient recognition and prediction

Reservoir computing has attracted considerable attention due to its low training cost. However, existing neuromorphic hardware, focusing mainly on shallow-reservoir computing, faces challenges in providing adequate spatial and temporal scales characteristic for effective computing. Here, we report a...

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Bibliographic Details
Published in:Nature communications Vol. 15; no. 1; pp. 740 - 13
Main Authors: Gao, Changsong, Liu, Di, Xu, Chenhui, Xie, Weidong, Zhang, Xianghong, Bai, Junhua, Lin, Zhixian, Zhang, Cheng, Hu, Yuanyuan, Guo, Tailiang, Chen, Huipeng
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 25-01-2024
Nature Publishing Group
Nature Portfolio
Subjects:
147/3
639/166/987
639/766/1130/2798
639/925/927/1007
Hardware
Humanities and Social Sciences
multidisciplinary
Neuromorphic computing
Recognition
Science
Science (multidisciplinary)
Transistors
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Summary:Reservoir computing has attracted considerable attention due to its low training cost. However, existing neuromorphic hardware, focusing mainly on shallow-reservoir computing, faces challenges in providing adequate spatial and temporal scales characteristic for effective computing. Here, we report an ultra-short channel organic neuromorphic vertical transistor with distributed reservoir states. The carrier dynamics used to map signals are enriched by coupled multivariate physics mechanisms, while the vertical architecture employed greatly increases the feedback intensity of the device. Consequently, the device as a reservoir, effectively mapping sequential signals into distributed reservoir state space with 1152 reservoir states, and the range ratio of temporal and spatial characteristics can simultaneously reach 2640 and 650, respectively. The grouped-reservoir computing based on the device can simultaneously adapt to different spatiotemporal task, achieving recognition accuracy over 94% and prediction correlation over 95%. This work proposes a new strategy for developing high-performance reservoir computing networks. Existing neuromorphic hardware, focusing mainly on shallow-reservoir computing, is challenged in providing adequate spatial and temporal scales characteristic for effective computing. Here, Gao et al. report an ultra-short channel organic neuromorphic vertical transistor with distributed reservoir states.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-44942-8