A hierarchical system for a distributed representation of the peripersonal space of a humanoid robot

Marco Antonelli; Agostino Gibaldi; Frederik Beuth; Angel J. Duran; Andrea Canessa; Manuela Chessa; Fabio Solari; Angel P. Del Pobil; Fred Hamker; Eris Chinellato; Silvio P. Sabatini

doi:10.1109/TAMD.2014.2332875

A hierarchical system for a distributed representation of the peripersonal space of a humanoid robot

Marco Antonelli^*, Agostino Gibaldi, Frederik Beuth, Angel J. Duran, Andrea Canessa, Manuela Chessa, Fabio Solari, Angel P. Del Pobil, Fred Hamker, Eris Chinellato, Silvio P. Sabatini

^*Corresponding author for this work

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

24 Citations (Scopus)

Abstract

Reaching a target object in an unknown and unstructured environment is easily performed by human beings. However, designing a humanoid robot that executes the same task requires the implementation of complex abilities, such as identifying the target in the visual field, estimating its spatial location, and precisely driving the motors of the arm to reach it. While research usually tackles the development of such abilities singularly, in this work we integrate a number of computationalmodels into a unified framework, and demonstrate in a humanoid torso the feasibility of an integrated working representation of its peripersonal space. To achieve this goal, we propose a cognitive architecture that connects several models inspired by neural circuits of the visual, frontal and posterior parietal cortices of the brain. The outcome of the integration process is a system that allows the robot to create its internal model and its representation of the surrounding space by interacting with the environment directly, through a mutual adaptation of perception and action. The robot is eventually capable of executing a set of tasks, such as recognizing, gazing and reaching target objects, which can work separately or cooperate for supporting more structured and effective behaviors.

Original language	English
Article number	6844843
Pages (from-to)	259-273
Number of pages	15
Journal	IEEE Transactions on Autonomous Mental Development
Volume	6
Issue number	4
DOIs	https://doi.org/10.1109/TAMD.2014.2332875
Publication status	Published - Dec 2014
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2014 IEEE.

Keywords

Humanoid robot
Implicit distributed representation
Object recognition
Sensorimotor learning
Visual cortex

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10.1109/TAMD.2014.2332875

Cite this

Antonelli, M., Gibaldi, A., Beuth, F., Duran, A. J., Canessa, A., Chessa, M., Solari, F., Del Pobil, A. P., Hamker, F., Chinellato, E., & Sabatini, S. P. (2014). A hierarchical system for a distributed representation of the peripersonal space of a humanoid robot. IEEE Transactions on Autonomous Mental Development, 6(4), 259-273. Article 6844843. https://doi.org/10.1109/TAMD.2014.2332875

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abstract = "Reaching a target object in an unknown and unstructured environment is easily performed by human beings. However, designing a humanoid robot that executes the same task requires the implementation of complex abilities, such as identifying the target in the visual field, estimating its spatial location, and precisely driving the motors of the arm to reach it. While research usually tackles the development of such abilities singularly, in this work we integrate a number of computationalmodels into a unified framework, and demonstrate in a humanoid torso the feasibility of an integrated working representation of its peripersonal space. To achieve this goal, we propose a cognitive architecture that connects several models inspired by neural circuits of the visual, frontal and posterior parietal cortices of the brain. The outcome of the integration process is a system that allows the robot to create its internal model and its representation of the surrounding space by interacting with the environment directly, through a mutual adaptation of perception and action. The robot is eventually capable of executing a set of tasks, such as recognizing, gazing and reaching target objects, which can work separately or cooperate for supporting more structured and effective behaviors.",

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author = "Marco Antonelli and Agostino Gibaldi and Frederik Beuth and Duran, \{Angel J.\} and Andrea Canessa and Manuela Chessa and Fabio Solari and \{Del Pobil\}, \{Angel P.\} and Fred Hamker and Eris Chinellato and Sabatini, \{Silvio P.\}",

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Antonelli, M, Gibaldi, A, Beuth, F, Duran, AJ, Canessa, A, Chessa, M, Solari, F, Del Pobil, AP, Hamker, F, Chinellato, E & Sabatini, SP 2014, 'A hierarchical system for a distributed representation of the peripersonal space of a humanoid robot', IEEE Transactions on Autonomous Mental Development, vol. 6, no. 4, 6844843, pp. 259-273. https://doi.org/10.1109/TAMD.2014.2332875

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AU - Antonelli, Marco

AU - Gibaldi, Agostino

AU - Beuth, Frederik

AU - Duran, Angel J.

AU - Canessa, Andrea

AU - Chessa, Manuela

AU - Solari, Fabio

AU - Del Pobil, Angel P.

AU - Hamker, Fred

AU - Chinellato, Eris

AU - Sabatini, Silvio P.

PY - 2014/12

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AB - Reaching a target object in an unknown and unstructured environment is easily performed by human beings. However, designing a humanoid robot that executes the same task requires the implementation of complex abilities, such as identifying the target in the visual field, estimating its spatial location, and precisely driving the motors of the arm to reach it. While research usually tackles the development of such abilities singularly, in this work we integrate a number of computationalmodels into a unified framework, and demonstrate in a humanoid torso the feasibility of an integrated working representation of its peripersonal space. To achieve this goal, we propose a cognitive architecture that connects several models inspired by neural circuits of the visual, frontal and posterior parietal cortices of the brain. The outcome of the integration process is a system that allows the robot to create its internal model and its representation of the surrounding space by interacting with the environment directly, through a mutual adaptation of perception and action. The robot is eventually capable of executing a set of tasks, such as recognizing, gazing and reaching target objects, which can work separately or cooperate for supporting more structured and effective behaviors.

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KW - Implicit distributed representation

KW - Object recognition

KW - Sensorimotor learning

KW - Visual cortex

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M1 - 6844843

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A hierarchical system for a distributed representation of the peripersonal space of a humanoid robot

Abstract

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Keywords

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