This work addresses the development of a distributed switching control strategy to drive the group of mobile robots in both backward and forward motion in a tightly coupled geometric pattern, as a solution for the deadlock situation that arises while navigating the unknown environment. A generalized closed-loop tracking controller considering the leader referenced model is used for the robots to remain in the formation while navigating the environment. A tracking controller using the simple geometric approach and the Instantaneous Centre of Radius (ICR), to drive the robot in the backward motion during deadlock situation is developed and presented. State-Based Modelling is used to model the behaviors/motion states of the proposed approach i...
Abstract. In this paper we consider the formation control of multiple nonholo-nomic mobile robots wi...
The first contribution of this work corresponds to a computationally efficient geometric method for ...
AbstractThis paper extends the synchronization approach for formation control of multiple mobile rob...
This work addresses the development of a distributed switching control strategy to drive the group o...
This work addresses the development of a distributed switching control strategy to drive the group o...
This work addresses the development of a distributed switching control strategy to drive the group o...
This paper presents a new method for controlling a group of nonholonomic mobile robots to achieve pr...
Collision avoidance is a critical problem in motion planning and control of multirobot systems. More...
This paper proposes a new synchronous control law to perform multiple mobile robots trajectory track...
The paper presents a study of a mobile multi-robot formation (MRF) control problem. The robots are n...
International audience— In this paper, the control problem for a group of mobile robots keeping a ge...
A novel formation control and switching approach for multiple robots in uncertain environments is pr...
We describe a framework for coordination and control of a group of nonholonomic mobile robots that a...
In this paper, a distributed controller–observer schema for tracking control of the centroid and of ...
This paper presents control algorithms for multiple non-holonomic mobile robots moving in formation....
Abstract. In this paper we consider the formation control of multiple nonholo-nomic mobile robots wi...
The first contribution of this work corresponds to a computationally efficient geometric method for ...
AbstractThis paper extends the synchronization approach for formation control of multiple mobile rob...
This work addresses the development of a distributed switching control strategy to drive the group o...
This work addresses the development of a distributed switching control strategy to drive the group o...
This work addresses the development of a distributed switching control strategy to drive the group o...
This paper presents a new method for controlling a group of nonholonomic mobile robots to achieve pr...
Collision avoidance is a critical problem in motion planning and control of multirobot systems. More...
This paper proposes a new synchronous control law to perform multiple mobile robots trajectory track...
The paper presents a study of a mobile multi-robot formation (MRF) control problem. The robots are n...
International audience— In this paper, the control problem for a group of mobile robots keeping a ge...
A novel formation control and switching approach for multiple robots in uncertain environments is pr...
We describe a framework for coordination and control of a group of nonholonomic mobile robots that a...
In this paper, a distributed controller–observer schema for tracking control of the centroid and of ...
This paper presents control algorithms for multiple non-holonomic mobile robots moving in formation....
Abstract. In this paper we consider the formation control of multiple nonholo-nomic mobile robots wi...
The first contribution of this work corresponds to a computationally efficient geometric method for ...
AbstractThis paper extends the synchronization approach for formation control of multiple mobile rob...