Optimization of Industrial Robot Grasping Processes with Q-Learning
Manuel Belke, Till Joeressen, Oliver Petrović, Christian Brecher
- Year
- 2023
- Citations
- 3
Abstract
Grasping objects in unstructured and dynamic environments remains a challenging task for robotic systems. Traditional grasp planning algorithms often struggle to adapt to the variability and uncertainty present in real-world scenarios. Deep reinforcement learning has emerged as a promising approach for training robotic agents to improve their grasping capabilities. This paper presents a novel grasp refinement s trategy that exploits a deep Q-learning algorithm to improve the precision of robotic grasping despite the presence of position and orientation inaccuracies. The proposed strategy focuses on industrial robot grasping processes which are predominantly comprised of a robot with force and torque sensor values and parallel jaw grippers with force and position feedback. Experimental results demonstrate that our RL-based approach increases the grasping accuracy without the presence of complex and high-dimensional tactile sensor input. Moreover, the learned grasping policies exhibit a higher level of robustness against noise in the preceding pose estimation system and object uncertainties.
Keywords
Related papers
Statistical Learning Theory
Yuhai Wu, Vladimir Vapnik
1999
Artificial intelligence: a modern approach
1995
Applied Nonlinear Control
Jean-Jacques Slotine, Weiping Li
1991
A new optimizer using particle swarm theory
R.C. Eberhart, James Kennedy
2002