This paper presents an embedded system for a ballbot robotic platform, which is a balanced omnidirectional mobile robot that moves on a sphere. It provides a higher degree of maneuverability compared to the wheeled mobile robots. The robot balances it on a ball and gives to the system only one contact point with the ground. This allows to reduce the friction and the space needed by the system to turn around a point. This is a major feature for a mobile vehicle, considering that most of them rotate their whole body to obtain a change in direction. The proposed platform is self-contained with on-board sensing and computation, it uses only off-the-shelf components and is designed to perform maneuvers when operating in tight spaces as in the human environments. The proposed embedded system is based on a general pourpose embedded board equipped with a 32bit microcontroller which is able to manage all the basic tasks of this robotic platform: sensing, actuation, control and communication. The proposed system is described and initial experimental results are introduced, furthermore the challenges faced are presented.
Embedded system for a Ballbot robot / Bonci, Andrea; Pirani, Massimiliano; Rossi, Massimiliano; Gabbanini, Enrico Maria. - STAMPA. - 1:(2015), pp. 157-161. (Intervento presentato al convegno WISES 2015, Proceeedings of 12th Workshop on Intelligent Solutions in Embedded Systems tenutosi a Ancona, Italy nel October 29-30 2015).
Embedded system for a Ballbot robot
BONCI, Andrea;PIRANI, MASSIMILIANO;
2015-01-01
Abstract
This paper presents an embedded system for a ballbot robotic platform, which is a balanced omnidirectional mobile robot that moves on a sphere. It provides a higher degree of maneuverability compared to the wheeled mobile robots. The robot balances it on a ball and gives to the system only one contact point with the ground. This allows to reduce the friction and the space needed by the system to turn around a point. This is a major feature for a mobile vehicle, considering that most of them rotate their whole body to obtain a change in direction. The proposed platform is self-contained with on-board sensing and computation, it uses only off-the-shelf components and is designed to perform maneuvers when operating in tight spaces as in the human environments. The proposed embedded system is based on a general pourpose embedded board equipped with a 32bit microcontroller which is able to manage all the basic tasks of this robotic platform: sensing, actuation, control and communication. The proposed system is described and initial experimental results are introduced, furthermore the challenges faced are presented.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
