Fully body visual self-modeling of robot morphologies.
Internal computational models of physical bodies are fundamental to the ability of robots and animals alike to plan and control their actions. These "self-models" allow robots to consider outcomes of multiple possible future actions without trying them out in physical reality. Recent progress in fully data-driven self-modeling has enabled machines to learn their own forward kinematics directly from task-agnostic interaction data. However, forward kinematic models can only predict limited aspects of the morphology, such as the position of end effectors or velocity of joints and masses. A key challenge is to model the entire morphology and kinematics without prior knowledge of what aspects of the morphology will be relevant to future tasks. Here, we propose that instead of directly modeling forward kinematics, a more useful form of self-modeling is one that could answer space occupancy queries, conditioned on the robot's state. Such query-driven self-models are continuous in the spatial domain, memory efficient, fully differentiable, and kinematic aware and can be used across a broader range of tasks. In physical experiments, we demonstrate how a visual self-model is accurate to about 1% of the workspace, enabling the robot to perform various motion planning and control tasks. Visual self-modeling can also allow the robot to detect, localize, and recover from real-world damage, leading to improved machine resiliency.
Duke Scholars
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Related Subject Headings
- Robotics
- Motion
- Learning
- Knowledge
- Biomechanical Phenomena
- Animals
- 4608 Human-centred computing
- 4602 Artificial intelligence
- 4007 Control engineering, mechatronics and robotics
Citation
Published In
DOI
EISSN
ISSN
Publication Date
Volume
Issue
Start / End Page
Related Subject Headings
- Robotics
- Motion
- Learning
- Knowledge
- Biomechanical Phenomena
- Animals
- 4608 Human-centred computing
- 4602 Artificial intelligence
- 4007 Control engineering, mechatronics and robotics