Lifelong Exploratory Navigation: An Architecture for Safer Mobile Robots

Fabrice Mayran De Chamisso; Daniela Cancila; Laurent Soulier; Roberto Passerone; Michael Aupetit

doi:10.1109/MDAT.2019.2952347

Lifelong Exploratory Navigation: An Architecture for Safer Mobile Robots

Fabrice Mayran De Chamisso^*, Daniela Cancila, Laurent Soulier, Roberto Passerone, Michael Aupetit

^*Corresponding author for this work

Qatar Computing Research Institute

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

2 Citations (Scopus)

Abstract

This article studies a layered architecture for robotics design, proposes a contract-based interface between the layers, and shows how cross-layer adaptation between these layers can be done in response to different scenarios. Mobile robots are highly complex systems whose development covers a large number of fields, from actuator design and mechatronics to scene processing and lifelike interaction with humans. Advanced robotic systems use a layered architecture where each layer represents an abstraction level, with sensors and actuators at the bottom and semantic artificial intelligence (AI) at the top. This article presents a layered architecture, called lifelong exploratory navigation (LEN) for mobile robots, encompassing ‘stacked’ and confined layers going from the physical level to AI functionalities. LEN is capable of autonomous adaptation, so that the robot is never shut down or reset, even when it is transferred to an unknown environment.

Original language	English
Pages (from-to)	57-64
Number of pages	8
Journal	IEEE Design and Test
Volume	38
Issue number	5
DOIs	https://doi.org/10.1109/MDAT.2019.2952347
Publication status	Published - Oct 2021

Keywords

autonomous navigation
contract-based design
cyber-physical systems
lifelong operation
mobile robot
planning
safety
topological map

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10.1109/MDAT.2019.2952347

Cite this

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title = "Lifelong Exploratory Navigation: An Architecture for Safer Mobile Robots",

abstract = "This article studies a layered architecture for robotics design, proposes a contract-based interface between the layers, and shows how cross-layer adaptation between these layers can be done in response to different scenarios. Mobile robots are highly complex systems whose development covers a large number of fields, from actuator design and mechatronics to scene processing and lifelike interaction with humans. Advanced robotic systems use a layered architecture where each layer represents an abstraction level, with sensors and actuators at the bottom and semantic artificial intelligence (AI) at the top. This article presents a layered architecture, called lifelong exploratory navigation (LEN) for mobile robots, encompassing {\textquoteleft}stacked{\textquoteright} and confined layers going from the physical level to AI functionalities. LEN is capable of autonomous adaptation, so that the robot is never shut down or reset, even when it is transferred to an unknown environment.",

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AU - De Chamisso, Fabrice Mayran

AU - Cancila, Daniela

AU - Soulier, Laurent

AU - Passerone, Roberto

AU - Aupetit, Michael

PY - 2021/10

Y1 - 2021/10

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AB - This article studies a layered architecture for robotics design, proposes a contract-based interface between the layers, and shows how cross-layer adaptation between these layers can be done in response to different scenarios. Mobile robots are highly complex systems whose development covers a large number of fields, from actuator design and mechatronics to scene processing and lifelike interaction with humans. Advanced robotic systems use a layered architecture where each layer represents an abstraction level, with sensors and actuators at the bottom and semantic artificial intelligence (AI) at the top. This article presents a layered architecture, called lifelong exploratory navigation (LEN) for mobile robots, encompassing ‘stacked’ and confined layers going from the physical level to AI functionalities. LEN is capable of autonomous adaptation, so that the robot is never shut down or reset, even when it is transferred to an unknown environment.

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KW - contract-based design

KW - cyber-physical systems

KW - lifelong operation

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KW - planning

KW - safety

KW - topological map

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Lifelong Exploratory Navigation: An Architecture for Safer Mobile Robots

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