29,575 research outputs found
Fast Object Learning and Dual-arm Coordination for Cluttered Stowing, Picking, and Packing
Robotic picking from cluttered bins is a demanding task, for which Amazon
Robotics holds challenges. The 2017 Amazon Robotics Challenge (ARC) required
stowing items into a storage system, picking specific items, and packing them
into boxes. In this paper, we describe the entry of team NimbRo Picking. Our
deep object perception pipeline can be quickly and efficiently adapted to new
items using a custom turntable capture system and transfer learning. It
produces high-quality item segments, on which grasp poses are found. A planning
component coordinates manipulation actions between two robot arms, minimizing
execution time. The system has been demonstrated successfully at ARC, where our
team reached second places in both the picking task and the final stow-and-pick
task. We also evaluate individual components.Comment: In: Proceedings of the International Conference on Robotics and
Automation (ICRA) 201
Dexterous Manipulation Graphs
We propose the Dexterous Manipulation Graph as a tool to address in-hand
manipulation and reposition an object inside a robot's end-effector. This graph
is used to plan a sequence of manipulation primitives so to bring the object to
the desired end pose. This sequence of primitives is translated into motions of
the robot to move the object held by the end-effector. We use a dual arm robot
with parallel grippers to test our method on a real system and show successful
planning and execution of in-hand manipulation
A Learning-based Adaptive Compliance Method for Symmetric Bi-manual Manipulation
Symmetric bi-manual manipulation is essential for various on-orbit operations
due to its potent load capacity. As a result, there exists an emerging research
interest in the problem of achieving high operation accuracy while enhancing
adaptability and compliance. However, previous works relied on an inefficient
algorithm framework that separates motion planning from compliant control.
Additionally, the compliant controller lacks robustness due to manually
adjusted parameters. This paper proposes a novel Learning-based Adaptive
Compliance algorithm (LAC) that improves the efficiency and robustness of
symmetric bi-manual manipulation. Specifically, first, the algorithm framework
combines desired trajectory generation with impedance-parameter adjustment to
improve efficiency and robustness. Second, we introduce a centralized
Actor-Critic framework with LSTM networks, enhancing the synchronization of
bi-manual manipulation. LSTM networks pre-process the force states obtained by
the agents, further ameliorating the performance of compliance operations. When
evaluated in the dual-arm cooperative handling and peg-in-hole assembly
experiments, our method outperforms baseline algorithms in terms of optimality
and robustness.Comment: 12 pages, 10 figure
A Certified-Complete Bimanual Manipulation Planner
Planning motions for two robot arms to move an object collaboratively is a
difficult problem, mainly because of the closed-chain constraint, which arises
whenever two robot hands simultaneously grasp a single rigid object. In this
paper, we propose a manipulation planning algorithm to bring an object from an
initial stable placement (position and orientation of the object on the support
surface) towards a goal stable placement. The key specificity of our algorithm
is that it is certified-complete: for a given object and a given environment,
we provide a certificate that the algorithm will find a solution to any
bimanual manipulation query in that environment whenever one exists. Moreover,
the certificate is constructive: at run-time, it can be used to quickly find a
solution to a given query. The algorithm is tested in software and hardware on
a number of large pieces of furniture.Comment: 12 pages, 7 figures, 1 tabl
A hyper-redundant manipulator
“Hyper-redundant” manipulators have a very large number of actuatable degrees of freedom. The benefits of hyper-redundant robots include the ability to avoid obstacles, increased robustness with respect to mechanical failure, and the ability to perform new forms of robot locomotion and grasping. The authors examine hyper-redundant manipulator design criteria and the physical implementation of one particular design: a variable geometry truss
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