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Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network

The cerebellum is involved in a large number of different neural processes, especially in associative learning and in fine motor control. To develop a comprehensive theory of sensorimotor learning and control, it is crucial to determine the neural basis of coding and plasticity embedded into the cer...

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Autores principales: Casellato, Claudia, Antonietti, Alberto, Garrido, Jesus A., Carrillo, Richard R., Luque, Niceto R., Ros, Eduardo, Pedrocchi, Alessandra, D'Angelo, Egidio
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2014
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4229206/
https://www.ncbi.nlm.nih.gov/pubmed/25390365
http://dx.doi.org/10.1371/journal.pone.0112265
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author Casellato, Claudia
Antonietti, Alberto
Garrido, Jesus A.
Carrillo, Richard R.
Luque, Niceto R.
Ros, Eduardo
Pedrocchi, Alessandra
D'Angelo, Egidio
author_facet Casellato, Claudia
Antonietti, Alberto
Garrido, Jesus A.
Carrillo, Richard R.
Luque, Niceto R.
Ros, Eduardo
Pedrocchi, Alessandra
D'Angelo, Egidio
author_sort Casellato, Claudia
collection PubMed
description The cerebellum is involved in a large number of different neural processes, especially in associative learning and in fine motor control. To develop a comprehensive theory of sensorimotor learning and control, it is crucial to determine the neural basis of coding and plasticity embedded into the cerebellar neural circuit and how they are translated into behavioral outcomes in learning paradigms. Learning has to be inferred from the interaction of an embodied system with its real environment, and the same cerebellar principles derived from cell physiology have to be able to drive a variety of tasks of different nature, calling for complex timing and movement patterns. We have coupled a realistic cerebellar spiking neural network (SNN) with a real robot and challenged it in multiple diverse sensorimotor tasks. Encoding and decoding strategies based on neuronal firing rates were applied. Adaptive motor control protocols with acquisition and extinction phases have been designed and tested, including an associative Pavlovian task (Eye blinking classical conditioning), a vestibulo-ocular task and a perturbed arm reaching task operating in closed-loop. The SNN processed in real-time mossy fiber inputs as arbitrary contextual signals, irrespective of whether they conveyed a tone, a vestibular stimulus or the position of a limb. A bidirectional long-term plasticity rule implemented at parallel fibers-Purkinje cell synapses modulated the output activity in the deep cerebellar nuclei. In all tasks, the neurorobot learned to adjust timing and gain of the motor responses by tuning its output discharge. It succeeded in reproducing how human biological systems acquire, extinguish and express knowledge of a noisy and changing world. By varying stimuli and perturbations patterns, real-time control robustness and generalizability were validated. The implicit spiking dynamics of the cerebellar model fulfill timing, prediction and learning functions.
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spelling pubmed-42292062014-11-18 Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network Casellato, Claudia Antonietti, Alberto Garrido, Jesus A. Carrillo, Richard R. Luque, Niceto R. Ros, Eduardo Pedrocchi, Alessandra D'Angelo, Egidio PLoS One Research Article The cerebellum is involved in a large number of different neural processes, especially in associative learning and in fine motor control. To develop a comprehensive theory of sensorimotor learning and control, it is crucial to determine the neural basis of coding and plasticity embedded into the cerebellar neural circuit and how they are translated into behavioral outcomes in learning paradigms. Learning has to be inferred from the interaction of an embodied system with its real environment, and the same cerebellar principles derived from cell physiology have to be able to drive a variety of tasks of different nature, calling for complex timing and movement patterns. We have coupled a realistic cerebellar spiking neural network (SNN) with a real robot and challenged it in multiple diverse sensorimotor tasks. Encoding and decoding strategies based on neuronal firing rates were applied. Adaptive motor control protocols with acquisition and extinction phases have been designed and tested, including an associative Pavlovian task (Eye blinking classical conditioning), a vestibulo-ocular task and a perturbed arm reaching task operating in closed-loop. The SNN processed in real-time mossy fiber inputs as arbitrary contextual signals, irrespective of whether they conveyed a tone, a vestibular stimulus or the position of a limb. A bidirectional long-term plasticity rule implemented at parallel fibers-Purkinje cell synapses modulated the output activity in the deep cerebellar nuclei. In all tasks, the neurorobot learned to adjust timing and gain of the motor responses by tuning its output discharge. It succeeded in reproducing how human biological systems acquire, extinguish and express knowledge of a noisy and changing world. By varying stimuli and perturbations patterns, real-time control robustness and generalizability were validated. The implicit spiking dynamics of the cerebellar model fulfill timing, prediction and learning functions. Public Library of Science 2014-11-12 /pmc/articles/PMC4229206/ /pubmed/25390365 http://dx.doi.org/10.1371/journal.pone.0112265 Text en © 2014 Casellato et al http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are properly credited.
spellingShingle Research Article
Casellato, Claudia
Antonietti, Alberto
Garrido, Jesus A.
Carrillo, Richard R.
Luque, Niceto R.
Ros, Eduardo
Pedrocchi, Alessandra
D'Angelo, Egidio
Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title_full Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title_fullStr Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title_full_unstemmed Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title_short Adaptive Robotic Control Driven by a Versatile Spiking Cerebellar Network
title_sort adaptive robotic control driven by a versatile spiking cerebellar network
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4229206/
https://www.ncbi.nlm.nih.gov/pubmed/25390365
http://dx.doi.org/10.1371/journal.pone.0112265
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