This paper presents the development of a time-dependent trajectory generation method for nonholonomic mobile robots using a geometry-based approach. In this study, cubic and quintic polynomials have been adapted to obtain a smooth trajectory for a single mobile robot. The generated trajectory is time dependent with the required position, orientation and velocity of the mobile robot taken into account during generation. The presented simulation results demonstrate the effectiveness of this trajectory generation method for a single mobile robot navigating in the environment that contains static obstacles.Mohd Sani Mohamad Hashim, Tien-Fu Luhttp://www.syroco2009.org
Trajectory planning is one of the fundamental problems in mobile robotics. A wide variety of approac...
Abstract—In this paper, we present a suboptimal and an-alytical solution to the trajectory generatio...
We address the global trajectory planning problem of non-holonomic mobile robots in environments wit...
This paper presents an extension of motion planning in consideration of travel time and velocity dur...
This paper proposes a new approach to plan the motion for a car-like mobile robot navigating in stat...
We consider the problem of trajectory generation of non-holonomic mobile robots. We propose two traj...
Trajectory planning and obstacle avoidance are very important issues to obtain a smooth and collisio...
In our recent work [5], by explicitly considering kinematic model of the robot, the family of feasib...
In this paper, the problem of determining an optimal collision-free path is studied for a mobile rob...
The question of timing in mobile robot navigation still remains an area of research not thoroughly i...
In order for a mobile robot to complete its task it must be able to plan and follow a trajectory. De...
A planning methodology for nonholonomic mobile manipulators that employs smooth and continuous funct...
In this paper, the problem of determining a collision-free trajectory for a car-like mobile robot mo...
In this paper, the problem of determining a collision-free trajectory for a car-like mobile robot mo...
This paper develops a method for generating smooth trajectories for mobile robots in formation. The ...
Trajectory planning is one of the fundamental problems in mobile robotics. A wide variety of approac...
Abstract—In this paper, we present a suboptimal and an-alytical solution to the trajectory generatio...
We address the global trajectory planning problem of non-holonomic mobile robots in environments wit...
This paper presents an extension of motion planning in consideration of travel time and velocity dur...
This paper proposes a new approach to plan the motion for a car-like mobile robot navigating in stat...
We consider the problem of trajectory generation of non-holonomic mobile robots. We propose two traj...
Trajectory planning and obstacle avoidance are very important issues to obtain a smooth and collisio...
In our recent work [5], by explicitly considering kinematic model of the robot, the family of feasib...
In this paper, the problem of determining an optimal collision-free path is studied for a mobile rob...
The question of timing in mobile robot navigation still remains an area of research not thoroughly i...
In order for a mobile robot to complete its task it must be able to plan and follow a trajectory. De...
A planning methodology for nonholonomic mobile manipulators that employs smooth and continuous funct...
In this paper, the problem of determining a collision-free trajectory for a car-like mobile robot mo...
In this paper, the problem of determining a collision-free trajectory for a car-like mobile robot mo...
This paper develops a method for generating smooth trajectories for mobile robots in formation. The ...
Trajectory planning is one of the fundamental problems in mobile robotics. A wide variety of approac...
Abstract—In this paper, we present a suboptimal and an-alytical solution to the trajectory generatio...
We address the global trajectory planning problem of non-holonomic mobile robots in environments wit...