5 research outputs found
Rearrangement with Nonprehensile Manipulation Using Deep Reinforcement Learning
Rearranging objects on a tabletop surface by means of nonprehensile
manipulation is a task which requires skillful interaction with the physical
world. Usually, this is achieved by precisely modeling physical properties of
the objects, robot, and the environment for explicit planning. In contrast, as
explicitly modeling the physical environment is not always feasible and
involves various uncertainties, we learn a nonprehensile rearrangement strategy
with deep reinforcement learning based on only visual feedback. For this, we
model the task with rewards and train a deep Q-network. Our potential
field-based heuristic exploration strategy reduces the amount of collisions
which lead to suboptimal outcomes and we actively balance the training set to
avoid bias towards poor examples. Our training process leads to quicker
learning and better performance on the task as compared to uniform exploration
and standard experience replay. We demonstrate empirical evidence from
simulation that our method leads to a success rate of 85%, show that our system
can cope with sudden changes of the environment, and compare our performance
with human level performance.Comment: 2018 International Conference on Robotics and Automatio