Hybrid Force/Position Control For A 3-DOF 1T2R Parallel Robot: Implementation, Simulations And Experiments (bibtex)
by , , , ,
Abstract:
A robot interacting with the environment requires that the end effector \hboxposition is tracked and that the forces of contact are kept below certain reference values. For instance, in a rehabilitation session using a robotic device, the contact forces are limited by the allowed strength of the human limbs and their complex-joints. In these cases, a control scheme which considers both position and force control is essential to avoid damage to either the end effector or the object interacting with the robot. This paper therefore develops a real-time force/position control scheme for a three-DOF parallel robot whose end effector holds a DOF one translation (1 T) and two rotations (2 R). The implemented hybrid force/position control considers, as a reference, the normal force on the mobile platform, which is measured by means of a load cell installed on the platform. The position control is designed to track the orientations of the robot either in joint or task space using a model-based control scheme with identified parameters. Moreover, the force control is based on a PD action. The control scheme is developed through simulations, before being applied to an actual parallel robot. The findings show that with the implemented controller, the actual robot accomplishes the reference values for the normal force on the mobile platform, while at the same time the platform accurately follows the required angular orientation.
Reference:
Hybrid Force/Position Control For A 3-DOF 1T2R Parallel Robot: Implementation, Simulations And Experiments (Jose Cazalilla, Marina Valles, Angel Valera, Vicente Mata, Miguel Diaz-Rodriguez), In Mechanics Based Design of Structures and Machines, Taylor & Francis Group, volume 44, 2016.
Bibtex Entry:
@article{valles2016,
  title={Hybrid Force/Position Control For A 3-DOF 1T2R Parallel Robot: Implementation, Simulations And Experiments},
  author={Cazalilla, Jose and Valles, Marina  and Valera, Angel and  Mata, Vicente and  Diaz-Rodriguez, Miguel},
  journal={Mechanics Based Design of Structures and Machines},
  volume={44},
  number={1-2},  
  pages={16-31},
  year={2016},
  publisher={Taylor \& Francis Group},
  doi={http://dx.doi.org/10.1080/15397734.2015.1030679},
  url={http://www.tandfonline.com/doi/full/10.1080/15397734.2015.1030679},
  gsid={https://scholar.google.com/scholar?oi=bibs&hl=es&cites=272330267449811638},
  abstract={A robot interacting with the environment requires that the end effector \hboxposition is tracked and that the forces of contact are kept below certain reference values. For instance, in a rehabilitation session using a robotic device, the contact forces are limited by the allowed strength of the human limbs and their complex-joints. In these cases, a control scheme which considers both position and force control is essential to avoid damage to either the end effector or the object interacting with the robot. This paper therefore develops a real-time force/position control scheme for a three-DOF parallel robot whose end effector holds a DOF one translation (1 T) and two rotations (2 R). The implemented hybrid force/position control considers, as a reference, the normal force on the mobile platform, which is measured by means of a load cell installed on the platform. The position control is designed to track the orientations of the robot either in joint or task space using a model-based control scheme with identified parameters. Moreover, the force control is based on a PD action. The control scheme is developed through simulations, before being applied to an actual parallel robot. The findings show that with the implemented controller, the actual robot accomplishes the reference values for the normal force on the mobile platform, while at the same time the platform accurately follows the required angular orientation.},
  keywords={Dynamics, force control, mechatronics, parallel manipulator, robot control},
}
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