Abstract In this paper, we propose a new method for the online redundancy resolution of robot manipulators, which implements a predictive strategy to calculate the optimal control action. In this way, it is possible to obtain a more efficient handling of the constraints, which represents one of the main issues in online resolution methods. The predictive model has been obtained by considering every joint as a k th-order integral system, and the predictive equations are derived from a continuous-time formulation. This allows the use of an irregular distribution of the prediction and control time instants and, as a consequence, longer prediction and control horizons can be obtained, without increasing the computational complexity of the algorithm. Finally, joint hard bounds are easily included in a linear-model-predictive-like framework, and the optimal control action is calculated by solving a linear quadratic problem. Simulation results for a 4-degree-of-freedom planar arm show the effectiveness of the method compared to purely local resolution techniques.
[1]
A. Liegeois,et al.
Automatic supervisory control of the configuration and behavior of multi-body mechanisms
,
1977
.
[2]
Oussama Khatib,et al.
Control of Redundant Robots Under Hard Joint Constraints: Saturation in the Null Space
,
2015,
IEEE Transactions on Robotics.
[3]
Christian Kirches,et al.
qpOASES: a parametric active-set algorithm for quadratic programming
,
2014,
Mathematical Programming Computation.
[4]
Bruno Siciliano,et al.
Kinematic control of redundant robot manipulators: A tutorial
,
1990,
J. Intell. Robotic Syst..
[5]
Pierre-Brice Wieber,et al.
Kinematic Control of Redundant Manipulators: Generalizing the Task-Priority Framework to Inequality Task
,
2011,
IEEE Transactions on Robotics.