Memristor-based adaptive neuromorphic perception in unstructured environments.
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Peer-reviewed
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Abstract
Efficient operation of control systems in robotics or autonomous driving targeting real-world navigation scenarios requires perception methods that allow them to understand and adapt to unstructured environments with good accuracy, adaptation, and generality, similar to humans. To address this need, we present a memristor-based differential neuromorphic computing, perceptual signal processing, and online adaptation method providing neuromorphic style adaptation to external sensory stimuli. The adaptation ability and generality of this method are confirmed in two application scenarios: object grasping and autonomous driving. In the former, a robot hand realizes safe and stable grasping through fast ( ~ 1 ms) adaptation based on the tactile object features with a single memristor. In the latter, decision-making information of 10 unstructured environments in autonomous driving is extracted with an accuracy of 94% with a 40×25 memristor array. By mimicking human low-level perception mechanisms, the electronic neuromorphic circuit-based method achieves real-time adaptation and high-level reactions to unstructured environments.
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Acknowledgements: S.G. acknowledges funding from National Key Research and Development Program of China (grant No. 2023YFB3208003), National Natural Science Foundation of China (grant No. 62171014), and Beihang University (grants No.KG161250 and ZG16S2103). L.G.O. acknowledges funding from EPSRC (grants No. EP/W024284/1, EP/P027628/1, EP/K03099X/1), E.O. was supported by UK Research and Innovation (UKRI Centre for Doctoral Training in AI for Healthcare grant No. EP/S023283/1).
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2041-1723
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Engineering and Physical Sciences Research Council (EP/P027628/1)
EPSRC (EP/W024284/1)