The cerebellum has a central role in fine motor control and in various neural processes, as in associative paradigms. In this work, a bioinspired adaptive model, developed by means of a spiking neural network made of thousands of artificial neurons, has been leveraged to control a humanoid NAO robot in real-time. The learning properties of the system have been challenged in a classic cerebellum-driven paradigm, the Pavlovian timing association between two provided stimuli, here implemented as a laser-avoidance task. The neurophysiological principles used to develop the model, succeeded in driving an adaptive motor control protocol with acquisition and extinction phases. The spiking neural network model showed learning behaviors similar to t...
AbstractThe cerebellum plays an essential role in adaptive motor control. Once we are able to build ...
Edited version embargoed until 12.02.2019 Full version: Access restricted permanently due to 3rd pa...
Compared to biological systems, existing learning systems lack the ability to learn autonomously, es...
The cerebellum has a central role in fine motor control and in various neural processes, as in assoc...
A bioinspired adaptive model, developed by means of a spiking neural network made of thousands of ar...
A bioinspired adaptive model, developed by means of a spiking neural network made of thousands of ar...
The cerebellum is involved in a large number of different neural processes, especially in associativ...
The cerebellum is involved in a large number of different neural processes, especially in associativ...
International audienceWe embed a spiking cerebellar model within an adaptive real-time (RT) control ...
This study explores the design and control of the behaviour of agents and robots using simple circui...
Abstract—In this paper, we introduce a network of spiking neurons devoted to navigation control. Thr...
The cerebellum plays a crucial role in motor learning and it acts as a predictive controller. Modeli...
AbstractWe describe a sequence of experiments in which a robot “brain” was evolved to mimic the beha...
AbstractThe cerebellum plays an essential role in adaptive motor control. Once we are able to build ...
Edited version embargoed until 12.02.2019 Full version: Access restricted permanently due to 3rd pa...
Compared to biological systems, existing learning systems lack the ability to learn autonomously, es...
The cerebellum has a central role in fine motor control and in various neural processes, as in assoc...
A bioinspired adaptive model, developed by means of a spiking neural network made of thousands of ar...
A bioinspired adaptive model, developed by means of a spiking neural network made of thousands of ar...
The cerebellum is involved in a large number of different neural processes, especially in associativ...
The cerebellum is involved in a large number of different neural processes, especially in associativ...
International audienceWe embed a spiking cerebellar model within an adaptive real-time (RT) control ...
This study explores the design and control of the behaviour of agents and robots using simple circui...
Abstract—In this paper, we introduce a network of spiking neurons devoted to navigation control. Thr...
The cerebellum plays a crucial role in motor learning and it acts as a predictive controller. Modeli...
AbstractWe describe a sequence of experiments in which a robot “brain” was evolved to mimic the beha...
AbstractThe cerebellum plays an essential role in adaptive motor control. Once we are able to build ...
Edited version embargoed until 12.02.2019 Full version: Access restricted permanently due to 3rd pa...
Compared to biological systems, existing learning systems lack the ability to learn autonomously, es...