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Main Authors: Dong, Zihao, Papalia, Alan, Jung, Leonard, Spiro, Alenna, Osteen, Philip R., Robison, Christa S., Everett, Michael
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.04362
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author Dong, Zihao
Papalia, Alan
Jung, Leonard
Spiro, Alenna
Osteen, Philip R.
Robison, Christa S.
Everett, Michael
author_facet Dong, Zihao
Papalia, Alan
Jung, Leonard
Spiro, Alenna
Osteen, Philip R.
Robison, Christa S.
Everett, Michael
contents A key open challenge in off-road autonomy is that the traversability of terrain often depends on the vehicle's state. In particular, some obstacles are only traversable from some orientations. However, learning this interaction by encoding the angle of approach as a model input demands a large and diverse training dataset and is computationally inefficient during planning due to repeated model inference. To address these challenges, we present SPARTA, a method for estimating approach angle conditioned traversability from point clouds. Specifically, we impose geometric structure into our network by outputting a smooth analytical function over the 1-Sphere that predicts risk distribution for any angle of approach with minimal overhead and can be reused for subsequent queries. The function is composed of Fourier basis functions, which has important advantages for generalization due to their periodic nature and smoothness. We demonstrate SPARTA both in a high-fidelity simulation platform, where our model achieves a 91\% success rate crossing a 40m boulder field (compared to 73\% for the baseline), and on hardware, illustrating the generalization ability of the model to real-world settings. Our code will be available at https://github.com/neu-autonomy/SPARTA.
format Preprint
id arxiv_https___arxiv_org_abs_2506_04362
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning Smooth State-Dependent Traversability from Dense Point Clouds
Dong, Zihao
Papalia, Alan
Jung, Leonard
Spiro, Alenna
Osteen, Philip R.
Robison, Christa S.
Everett, Michael
Robotics
Computer Vision and Pattern Recognition
A key open challenge in off-road autonomy is that the traversability of terrain often depends on the vehicle's state. In particular, some obstacles are only traversable from some orientations. However, learning this interaction by encoding the angle of approach as a model input demands a large and diverse training dataset and is computationally inefficient during planning due to repeated model inference. To address these challenges, we present SPARTA, a method for estimating approach angle conditioned traversability from point clouds. Specifically, we impose geometric structure into our network by outputting a smooth analytical function over the 1-Sphere that predicts risk distribution for any angle of approach with minimal overhead and can be reused for subsequent queries. The function is composed of Fourier basis functions, which has important advantages for generalization due to their periodic nature and smoothness. We demonstrate SPARTA both in a high-fidelity simulation platform, where our model achieves a 91\% success rate crossing a 40m boulder field (compared to 73\% for the baseline), and on hardware, illustrating the generalization ability of the model to real-world settings. Our code will be available at https://github.com/neu-autonomy/SPARTA.
title Learning Smooth State-Dependent Traversability from Dense Point Clouds
topic Robotics
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2506.04362