Locomotion Policy Guided Traversability Learning [IROS 2022]
Вставка
- Опубліковано 1 сер 2022
- by Jonas Frey, David Hoeller, Shehryar Khattak, Marco Hutter
Paper Link: arxiv.org/abs/2203.15854
Accepted for IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS, 2022)
@inproceedings{frey2022traversability,
author={Frey, Jonas and Hoeller, David and Khattak, Shehryar and Marco, Hutter},
journal={IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS, 2022)},
title={Locomotion Policy Guided Traversability Learning using Volumetric Representations of Complex Environments},
year={2022}
}
Video by Jonas Frey
Deployed Locomotion Policy from "Learning robust perceptive locomotion for quadrupedal robots in the wild" by Takahiro Miki, Joonho Lee, Jemin Hwangbo, Lorenz Wellhausen, Vladlen Koltun, Marco Hutter
Paper Link: www.science.org/doi/10.1126/s...
UA-cam Video (14s-23s): • Learning robust percep...
Abstract:
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments remains an open problem. Ideally, the navigation system utilizes the full potential of the robots’ locomotion capabilities while operating within safety limits under uncertainty. The robot must sense and analyze the traversability of the surrounding terrain, which depends on the hardware, locomotion control, and terrain properties. It may contain information about the risk, energy, or time consumption needed to traverse the terrain. To avoid hand-crafted traversability cost functions we propose to collect traversability information about the robot and locomotion policy by simulating the traversal over randomly generated terrains using a physics simulator. Thousand of robots are simulated in parallel controlled by the same locomotion policy used in reality to acquire 57 years of real-world locomotion experience equivalent. For deployment on the real robot, a sparse convolutional network is trained to predict the simulated traversability cost, which is tailored to the deployed locomotion policy, from an entirely geometric representation of the environment in the form of a 3D voxel-occupancy map. This representation avoids the need for commonly used elevation maps, which are error-prone in the presence of overhanging obstacles and multi-floor or low-ceiling scenarios. The effectiveness of the proposed traversability prediction network is demonstrated for path planning for the legged robot ANYmal in various indoor and natural environments. - Наука та технологія
Amazing job. Love the comprehensive explanation with narration.
Glad you liked it!
The next step in traversal! Neat work.
Thanks a lot.
Amazing work !!
Any chances of open-sourcing the source code for research community ?