Humanlike spontaneous motion coordination of robotic fingers through spatial multi-input spike signal multiplexing

Dong Gue Roe; Dong Hae Ho; Yoon Young Choi; Young Jin Choi; Seongchan Kim; Sae Byeok Jo; Moon Sung Kang; Jong Hyun Ahn; Jeong Ho Cho

doi:10.1038/s41467-022-34324-3

Humanlike spontaneous motion coordination of robotic fingers through spatial multi-input spike signal multiplexing

Dong Gue Roe
, Dong Hae Ho
, Yoon Young Choi
, Young Jin Choi
, Seongchan Kim
, Sae Byeok Jo
, Moon Sung Kang
, Jong Hyun Ahn
, Jeong Ho Cho

Department of Chemical Engineering

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

With advances in robotic technology, the complexity of control of robot has been increasing owing to fundamental signal bottlenecks and limited expressible logic state of the von Neumann architecture. Here, we demonstrate coordinated movement by a fully parallel-processable synaptic array with reduced control complexity. The synaptic array was fabricated by connecting eight ion-gel-based synaptic transistors to an ion gel dielectric. Parallel signal processing and multi-actuation control could be achieved by modulating the ionic movement. Through the integration of the synaptic array and a robotic hand, coordinated movement of the fingers was achieved with reduced control complexity by exploiting the advantages of parallel multiplexing and analog logic. The proposed synaptic control system provides considerable scope for the advancement of robotic control systems.

Original language	English
Article number	5
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-34324-3
State	Published - Dec 2023

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abstract = "With advances in robotic technology, the complexity of control of robot has been increasing owing to fundamental signal bottlenecks and limited expressible logic state of the von Neumann architecture. Here, we demonstrate coordinated movement by a fully parallel-processable synaptic array with reduced control complexity. The synaptic array was fabricated by connecting eight ion-gel-based synaptic transistors to an ion gel dielectric. Parallel signal processing and multi-actuation control could be achieved by modulating the ionic movement. Through the integration of the synaptic array and a robotic hand, coordinated movement of the fingers was achieved with reduced control complexity by exploiting the advantages of parallel multiplexing and analog logic. The proposed synaptic control system provides considerable scope for the advancement of robotic control systems.",

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AU - Roe, Dong Gue

AU - Ho, Dong Hae

AU - Choi, Yoon Young

AU - Choi, Young Jin

AU - Kim, Seongchan

AU - Jo, Sae Byeok

AU - Kang, Moon Sung

AU - Ahn, Jong Hyun

AU - Cho, Jeong Ho

PY - 2023/12

Y1 - 2023/12

N2 - With advances in robotic technology, the complexity of control of robot has been increasing owing to fundamental signal bottlenecks and limited expressible logic state of the von Neumann architecture. Here, we demonstrate coordinated movement by a fully parallel-processable synaptic array with reduced control complexity. The synaptic array was fabricated by connecting eight ion-gel-based synaptic transistors to an ion gel dielectric. Parallel signal processing and multi-actuation control could be achieved by modulating the ionic movement. Through the integration of the synaptic array and a robotic hand, coordinated movement of the fingers was achieved with reduced control complexity by exploiting the advantages of parallel multiplexing and analog logic. The proposed synaptic control system provides considerable scope for the advancement of robotic control systems.

AB - With advances in robotic technology, the complexity of control of robot has been increasing owing to fundamental signal bottlenecks and limited expressible logic state of the von Neumann architecture. Here, we demonstrate coordinated movement by a fully parallel-processable synaptic array with reduced control complexity. The synaptic array was fabricated by connecting eight ion-gel-based synaptic transistors to an ion gel dielectric. Parallel signal processing and multi-actuation control could be achieved by modulating the ionic movement. Through the integration of the synaptic array and a robotic hand, coordinated movement of the fingers was achieved with reduced control complexity by exploiting the advantages of parallel multiplexing and analog logic. The proposed synaptic control system provides considerable scope for the advancement of robotic control systems.

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VL - 14

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JF - Nature Communications

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Humanlike spontaneous motion coordination of robotic fingers through spatial multi-input spike signal multiplexing

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