Self-sustaining Learning for Robotic Ecologies

D Bacciu; M Broxvall; SA Coleman; M Dragone; C Gallicchio; C Gennaro; R Guzman; R Lopez; H Lozano-Peiteado; Anjan Ray; A Renteria; A Saffiotti; C Vairo

Self-sustaining Learning for Robotic Ecologies

D Bacciu, M Broxvall, SA Coleman, M Dragone, C Gallicchio, C Gennaro, R Guzman, R Lopez, H Lozano-Peiteado, Anjan Ray, A Renteria, A Saffiotti, C Vairo

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

4 Citations (Scopus)

Abstract

The most common use of wireless sensor networks (WSNs) is to collect environmental data from a specific area, and to channel it to a central processing node for on-line or off-line analysis. The WSN technology, however, can be used for much more ambitious goals. We claim that merging the concepts and technology of WSN with the concepts and technology of distributed robotics and multi-agent systems can open new ways to design systems able to provide intelligent services in our homes and working places. We also claim that endowing these systems with learning capabilities can greatly increase their viability and acceptability, by simplifying design, customization and adaptation to changing user needs. To support these claims, we illustrate our architecture for an adaptive robotic ecology, named RUBICON, consisting of a network of sensors,effectors and mobile robots.

Original language	English
Title of host publication	Unknown Host Publication
Publisher	SciTePress
Pages	99-103
Number of pages	5
ISBN (Print)	978-989-8565-01-3
Publication status	Published (in print/issue) - 22 Feb 2012
Event	1st International Conference on Sensor Networks - Rome, Italy Duration: 22 Feb 2012 → …

Conference

Conference	1st International Conference on Sensor Networks
Period	22/02/12 → …

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

Cite this

@inproceedings{4873dbd959f543ca812733b701e8efd1,

title = "Self-sustaining Learning for Robotic Ecologies",

abstract = "The most common use of wireless sensor networks (WSNs) is to collect environmental data from a specific area, and to channel it to a central processing node for on-line or off-line analysis. The WSN technology, however, can be used for much more ambitious goals. We claim that merging the concepts and technology of WSN with the concepts and technology of distributed robotics and multi-agent systems can open new ways to design systems able to provide intelligent services in our homes and working places. We also claim that endowing these systems with learning capabilities can greatly increase their viability and acceptability, by simplifying design, customization and adaptation to changing user needs. To support these claims, we illustrate our architecture for an adaptive robotic ecology, named RUBICON, consisting of a network of sensors,effectors and mobile robots.",

author = "D Bacciu and M Broxvall and SA Coleman and M Dragone and C Gallicchio and C Gennaro and R Guzman and R Lopez and H Lozano-Peiteado and Anjan Ray and A Renteria and A Saffiotti and C Vairo",

year = "2012",

month = feb,

day = "22",

language = "English",

isbn = "978-989-8565-01-3",

pages = "99--103",

booktitle = "Unknown Host Publication",

publisher = "SciTePress",

address = "Portugal",

note = "1st International Conference on Sensor Networks ; Conference date: 22-02-2012",

}

TY - GEN

T1 - Self-sustaining Learning for Robotic Ecologies

AU - Bacciu, D

AU - Broxvall, M

AU - Coleman, SA

AU - Dragone, M

AU - Gallicchio, C

AU - Gennaro, C

AU - Guzman, R

AU - Lopez, R

AU - Lozano-Peiteado, H

AU - Ray, Anjan

AU - Renteria, A

AU - Saffiotti, A

AU - Vairo, C

PY - 2012/2/22

Y1 - 2012/2/22

N2 - The most common use of wireless sensor networks (WSNs) is to collect environmental data from a specific area, and to channel it to a central processing node for on-line or off-line analysis. The WSN technology, however, can be used for much more ambitious goals. We claim that merging the concepts and technology of WSN with the concepts and technology of distributed robotics and multi-agent systems can open new ways to design systems able to provide intelligent services in our homes and working places. We also claim that endowing these systems with learning capabilities can greatly increase their viability and acceptability, by simplifying design, customization and adaptation to changing user needs. To support these claims, we illustrate our architecture for an adaptive robotic ecology, named RUBICON, consisting of a network of sensors,effectors and mobile robots.

AB - The most common use of wireless sensor networks (WSNs) is to collect environmental data from a specific area, and to channel it to a central processing node for on-line or off-line analysis. The WSN technology, however, can be used for much more ambitious goals. We claim that merging the concepts and technology of WSN with the concepts and technology of distributed robotics and multi-agent systems can open new ways to design systems able to provide intelligent services in our homes and working places. We also claim that endowing these systems with learning capabilities can greatly increase their viability and acceptability, by simplifying design, customization and adaptation to changing user needs. To support these claims, we illustrate our architecture for an adaptive robotic ecology, named RUBICON, consisting of a network of sensors,effectors and mobile robots.

M3 - Conference contribution

SN - 978-989-8565-01-3

SP - 99

EP - 103

BT - Unknown Host Publication

PB - SciTePress

T2 - 1st International Conference on Sensor Networks

Y2 - 22 February 2012

ER -

Self-sustaining Learning for Robotic Ecologies

Abstract

Conference

UN SDGs

Access to Document

Fingerprint

Cite this