Related papers: High-Degrees-of-Freedom Dynamic Neural Fields for Robot Self-Modeling and Motion Planning

High-Degrees-of-Freedom Dynamic Neural Fields for Robot Self-Modeling and Motion Planning

URL: http://arxiv.org/abs/2310.03624v2
Date: Fri, 19 Apr 2024 03:48:13 GMT
Title: High-Degrees-of-Freedom Dynamic Neural Fields for Robot Self-Modeling and Motion Planning
Authors: Lennart Schulze, Hod Lipson,
Abstract summary: A robot self-model is a representation of the robot's physical morphology that can be used for motion planning tasks. We propose a new encoder-based neural density field architecture for dynamic object-centric scenes conditioned on high numbers of degrees of freedom. In a 7-DOF robot test setup, the learned self-model achieves a Chamfer-L2 distance of 2% of the robot's dimension workspace.
Score: 6.229216953398305
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: A robot self-model is a task-agnostic representation of the robot's physical morphology that can be used for motion planning tasks in the absence of a classical geometric kinematic model. In particular, when the latter is hard to engineer or the robot's kinematics change unexpectedly, human-free self-modeling is a necessary feature of truly autonomous agents. In this work, we leverage neural fields to allow a robot to self-model its kinematics as a neural-implicit query model learned only from 2D images annotated with camera poses and configurations. This enables significantly greater applicability than existing approaches which have been dependent on depth images or geometry knowledge. To this end, alongside a curricular data sampling strategy, we propose a new encoder-based neural density field architecture for dynamic object-centric scenes conditioned on high numbers of degrees of freedom (DOFs). In a 7-DOF robot test setup, the learned self-model achieves a Chamfer-L2 distance of 2% of the robot's workspace dimension. We demonstrate the capabilities of this model on motion planning tasks as an exemplary downstream application.

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