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Bimanual Manipulation Learning from Single Human Demonstration Using Screw Space Projection


Temel Kavramlar
SCREWMIMIC enables robots to learn complex bimanual manipulation behaviors from a single human video demonstration by modeling the interaction between the two hands as a screw motion, which provides an efficient action representation for learning and fine-tuning.
Özet

The paper presents SCREWMIMIC, a novel framework for learning bimanual manipulation behaviors from a single human video demonstration. The key insight is that the relative motion between the two hands during bimanual manipulation can be effectively modeled as a screw motion, which constrains the motion in a way that matches physical constraints in the environment or facilitates the manipulation.

SCREWMIMIC consists of three main modules:

  1. Extracting a screw action from a human demonstration: SCREWMIMIC uses off-the-shelf hand tracking to extract the trajectories of the human hands, and then interprets these trajectories as a screw motion between the hands. This provides a compact representation of the demonstrated bimanual behavior.

  2. Predicting a screw action from a point cloud: SCREWMIMIC trains a PointNet-based model to predict the screw action parameters from the 3D point cloud of a novel object. This allows the robot to generalize the learned behavior to new object instances and configurations.

  3. Self-supervised screw-action policy fine-tuning: SCREWMIMIC uses the predicted screw action as an initialization and then refines it through an iterative self-supervised exploration process. This allows the robot to overcome differences in embodiment between the human and the robot.

The experiments demonstrate that SCREWMIMIC can successfully learn complex bimanual manipulation behaviors, such as opening bottles, closing zippers, and stirring pots, from a single human video demonstration. The use of the screw action representation is critical, as it enables efficient exploration and fine-tuning, leading to significantly better performance compared to baselines that do not use this representation.

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Kaynak

İstatistikler
The robot applies lower force for the manipulation, which is considered more efficient. The robot loses grasp or exceeds a force-torque threshold, indicating a failed manipulation attempt.
Alıntılar
"Bimanual manipulation is a longstanding challenge in robotics due to the large number of degrees of freedom and the strict spatial and temporal synchronization required to generate meaningful behavior." "Inspired by seminal work in psychology and biomechanics, we propose modeling the interaction between two hands as a serial kinematic linkage — as a screw motion, in particular, that we use to define a new action space for bimanual manipulation: screw actions."

Daha Derin Sorular

How can SCREWMIMIC be extended to handle bimanual manipulation tasks that cannot be easily represented by a single screw motion, such as cutting in a zig-zag pattern?

To handle bimanual manipulation tasks that involve complex motions like cutting in a zig-zag pattern, SCREWMIMIC can be extended by incorporating sequences of screw axes. Instead of relying on a single screw motion to represent the entire task, the framework can be modified to interpret a series of interconnected screw motions that collectively capture the intricate bimanual actions required for tasks like cutting in a zig-zag pattern. By allowing for the chaining of screw motions, SCREWMIMIC can model the dynamic and multi-dimensional nature of such tasks more effectively.

How can SCREWMIMIC be scaled to handle a wider range of bimanual manipulation tasks and object classes by leveraging large-scale human activity datasets?

To scale SCREWMIMIC for a wider range of bimanual manipulation tasks and object classes, leveraging large-scale human activity datasets can be highly beneficial. By training the prediction model on diverse and extensive datasets that encompass various bimanual manipulation scenarios, SCREWMIMIC can learn a more comprehensive set of screw actions and improve its generalization capabilities. Additionally, incorporating transfer learning techniques can help the model adapt to new tasks and objects more efficiently by leveraging knowledge gained from the large-scale datasets.

Can SCREWMIMIC be further improved by incorporating fine-tuning of the grasp contact points in addition to the screw axis parameters?

Incorporating fine-tuning of the grasp contact points along with the screw axis parameters can indeed enhance the performance of SCREWMIMIC. By refining both the grasp contact points and the screw axis parameters during the self-supervised policy fine-tuning stage, the framework can achieve more precise and accurate bimanual manipulation actions. This dual refinement approach can help optimize the entire manipulation process, ensuring that the robot not only moves in the correct trajectory but also grasps and interacts with objects more effectively. Fine-tuning the grasp contact points can improve the overall stability and success rate of the bimanual tasks executed by SCREWMIMIC.
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