In this paper, we consider planning motions of objects of regular shape rolling on a plane among obstacles. Theoretical foundations and applications of this type of operations in robotic manipulation and locomotion have been discussed elsewhere. In this paper, we propose a novel algorithm that improves upon existing techniques in that: i) it is finitely computable and predictable (an upper bound on the computations necessary to reach a given goal within a tolerance can be given), and ii) it possesses a topological (local-local) property which enables obstacles and workspace limitations to be dealt with in an effective way
Rolling between rigid surfaces in space is a well-known nonholonomic system, whose mathematical mode...
Summary. This paper presents artificial constraints as a method for guiding heuris-tic search in the...
In this paper, we address the issue of motion planning for the control system L R that results from ...
International audienceIn this paper, we consider the control system Σ defined by the rolling of a st...
Path planning of polyhedrons by rolling on edges includes arbitrary relocation, obstacle avoidance a...
We consider the issues involved in writing path planners that can work well with complex geometric m...
International audienceThe authors address the motion planning problem for a robot and a movable obje...
A new approach to motion planning for manipulators is presented. A measure based on the factor neede...
This paper addresses the manipulation planning problem which deals with motion planning for robots m...
We present a local approach for planning the motion of a car-like robot navigating among obstacles, ...
The nonholonomic nature of rolling between rigid bodies can be exploited to achieve dextrous manipul...
Controlling the relative motion between two contacting rigid bodies is necessary when manipulation a...
International audienceIn this paper, we address the issues of controllability and motion planning fo...
Rolling between rigid surfaces in space is a well-known nonholonomic system, whose mathematical mode...
Artificial Constraints In this paper we present artificial constraints as a method for guiding heuri...
Rolling between rigid surfaces in space is a well-known nonholonomic system, whose mathematical mode...
Summary. This paper presents artificial constraints as a method for guiding heuris-tic search in the...
In this paper, we address the issue of motion planning for the control system L R that results from ...
International audienceIn this paper, we consider the control system Σ defined by the rolling of a st...
Path planning of polyhedrons by rolling on edges includes arbitrary relocation, obstacle avoidance a...
We consider the issues involved in writing path planners that can work well with complex geometric m...
International audienceThe authors address the motion planning problem for a robot and a movable obje...
A new approach to motion planning for manipulators is presented. A measure based on the factor neede...
This paper addresses the manipulation planning problem which deals with motion planning for robots m...
We present a local approach for planning the motion of a car-like robot navigating among obstacles, ...
The nonholonomic nature of rolling between rigid bodies can be exploited to achieve dextrous manipul...
Controlling the relative motion between two contacting rigid bodies is necessary when manipulation a...
International audienceIn this paper, we address the issues of controllability and motion planning fo...
Rolling between rigid surfaces in space is a well-known nonholonomic system, whose mathematical mode...
Artificial Constraints In this paper we present artificial constraints as a method for guiding heuri...
Rolling between rigid surfaces in space is a well-known nonholonomic system, whose mathematical mode...
Summary. This paper presents artificial constraints as a method for guiding heuris-tic search in the...
In this paper, we address the issue of motion planning for the control system L R that results from ...