PreprintWe propose and demonstrate how attractor dynamics can be used to design and implement a distributed dynamic control architecture that enables a team of two robots, without force/torque sensors and equipped solely with low-level sensors, to carry a long object and simultaneously avoid obstacles. The explicit required communication between robots is minimal. The robots have no prior knowledge of their environment. Experimental results in indoor environments show that if parameter values are chosen within reasonable ranges then the overall system works quite well even in cluttered environments. The robots’ behavior is stable and the generated trajectories are smooth
International audienceWe solve the formation-tracking control problem for mobile robots via linear c...
We describe a framework and control algorithms for coordinating multiple mobile robots with manipula...
Distributed coordination of groups of individuals accomplishing a common task without leaders, with ...
PreprintWe propose and demonstrate how attractor dynamics can be used to design and implement a dis...
In this paper dynamical systems theory is used as a theoretical language and tool to design a distri...
Dynamical systems theory is used here as a theoretical language and tool to design a distributed co...
We present a distributed architecture for teams of two autonomous mobile robots that act in coordina...
Dynamical systems theory in this work is used as a theoretical language and tool to design a distri...
We address the problem of coordinating two non-holonomic mobile robots that move in formation while...
Dynamical systems theory is used as a theoretical language and tool to design a distributed control...
We present a distributed leader-helper architecture for teams of two autonomous mobile robots that j...
AbstractThis paper presents an application of multi-robot system using nonholonomic wheeled mobile r...
Several tasks cannot be accomplished by a single robot working in isolation. Obvious examples includ...
This paper addresses the problem of cooperative object transportation in a constrained workspace inv...
Abstract—In this paper we address the problem of human-robot joint transportation of large payloads....
International audienceWe solve the formation-tracking control problem for mobile robots via linear c...
We describe a framework and control algorithms for coordinating multiple mobile robots with manipula...
Distributed coordination of groups of individuals accomplishing a common task without leaders, with ...
PreprintWe propose and demonstrate how attractor dynamics can be used to design and implement a dis...
In this paper dynamical systems theory is used as a theoretical language and tool to design a distri...
Dynamical systems theory is used here as a theoretical language and tool to design a distributed co...
We present a distributed architecture for teams of two autonomous mobile robots that act in coordina...
Dynamical systems theory in this work is used as a theoretical language and tool to design a distri...
We address the problem of coordinating two non-holonomic mobile robots that move in formation while...
Dynamical systems theory is used as a theoretical language and tool to design a distributed control...
We present a distributed leader-helper architecture for teams of two autonomous mobile robots that j...
AbstractThis paper presents an application of multi-robot system using nonholonomic wheeled mobile r...
Several tasks cannot be accomplished by a single robot working in isolation. Obvious examples includ...
This paper addresses the problem of cooperative object transportation in a constrained workspace inv...
Abstract—In this paper we address the problem of human-robot joint transportation of large payloads....
International audienceWe solve the formation-tracking control problem for mobile robots via linear c...
We describe a framework and control algorithms for coordinating multiple mobile robots with manipula...
Distributed coordination of groups of individuals accomplishing a common task without leaders, with ...