From collections of independent, mindless robots to flexible, mobile, and directional superstructures
BRÜCKNER, David
Ludwig Maximilian University [Munich] = Ludwig Maximilians Universität München [LMU]
Ludwig Maximilian University [Munich] = Ludwig Maximilians Universität München [LMU]
BARET, Jean-Christophe
Centre de Recherche Paul Pascal [CRPP]
Institut universitaire de France [IUF]
Centre de Recherche Paul Pascal [CRPP]
Institut universitaire de France [IUF]
KELLAY, Hamid
Laboratoire Ondes et Matière d'Aquitaine [LOMA]
Institut universitaire de France [IUF]
< Réduire
Laboratoire Ondes et Matière d'Aquitaine [LOMA]
Institut universitaire de France [IUF]
Langue
en
Article de revue
Ce document a été publié dans
Science Robotics. 2021-07-21, vol. 6, n° 56, p. eabd0272
American Association for the Advancement of Science (AAAS)
Résumé en anglais
A swarm of simple active particles confined in a flexible scaffold is a promising system to make mobile and deformable superstructures. These soft structures can perform tasks that are difficult to carry out for monolithic ...Lire la suite >
A swarm of simple active particles confined in a flexible scaffold is a promising system to make mobile and deformable superstructures. These soft structures can perform tasks that are difficult to carry out for monolithic robots because they can infiltrate narrow spaces, smaller than their size, and move around obstacles. To achieve such tasks, the origin of the forces the superstructures develop, how they can be guided, and the effects of external environment, especially geometry and the presence of obstacles, need to be understood. Here, we report measurements of the forces developed by such superstructures, enclosing a number of mindless active rod-like robots, as well as the forces exerted by these structures to achieve a simple function, crossing a constriction. We relate these forces to the self-organization of the individual entities. Furthermore, and based on a physical understanding of what controls the mobility of these superstructures and the role of geometry in such a process, we devise a simple strategy where the environment can be designed to bias the mobility of the superstructure, giving rise to directional motion. Simple tasks—such as pulling a load, moving through an obstacle course, or cleaning up an arena—are demonstrated. Rudimentary control of the superstructures using light is also proposed. The results are of relevance to the making of robust flexible superstructures with nontrivial space exploration properties out of a swarm of simpler and cheaper robots.< Réduire
Project ANR
Guidage des particules artificielles auto-propulsées - ANR-19-CE06-0012
Origine
Importé de hal