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Main Authors: Rose, Nathaniel, Ahmed, Arif, Gutierrez-Cornejo, Emanuel, Maini, Parikshit
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.12731
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author Rose, Nathaniel
Ahmed, Arif
Gutierrez-Cornejo, Emanuel
Maini, Parikshit
author_facet Rose, Nathaniel
Ahmed, Arif
Gutierrez-Cornejo, Emanuel
Maini, Parikshit
contents Navigating in off-road environments for wheeled mobile robots is challenging due to dynamic and rugged terrain. Traditional physics-based stability metrics, such as Static Stability Margin (SSM) or Zero Moment Point (ZMP) require knowledge of contact forces, terrain geometry, and the robot's precise center-of-mass that are difficult to measure accurately in real-world field conditions. In this work, we propose a learning-based approach to estimate robot platform stability directly from proprioceptive data using a lightweight neural network, IMUnet. Our method enables data-driven inference of robot stability without requiring an explicit terrain model or force sensing. We also develop a novel vision-based ArUco tracking method to compute a scalar score to quantify robot platform stability called C3 score. The score captures image-space perturbations over time as a proxy for physical instability and is used as a training signal for the neural network based model. As a pilot study, we evaluate our approach on data collected across multiple terrain types and speeds and demonstrate generalization to previously unseen conditions. These initial results highlight the potential of using IMU and robot velocity as inputs to estimate platform stability. The proposed method finds application in gating robot tasks such as precision actuation and sensing, especially for mobile manipulation tasks in agricultural and space applications. Our learning method also provides a supervision mechanism for perception based traversability estimation and planning.
format Preprint
id arxiv_https___arxiv_org_abs_2507_12731
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning to Predict Mobile Robot Stability in Off-Road Environments
Rose, Nathaniel
Ahmed, Arif
Gutierrez-Cornejo, Emanuel
Maini, Parikshit
Robotics
Navigating in off-road environments for wheeled mobile robots is challenging due to dynamic and rugged terrain. Traditional physics-based stability metrics, such as Static Stability Margin (SSM) or Zero Moment Point (ZMP) require knowledge of contact forces, terrain geometry, and the robot's precise center-of-mass that are difficult to measure accurately in real-world field conditions. In this work, we propose a learning-based approach to estimate robot platform stability directly from proprioceptive data using a lightweight neural network, IMUnet. Our method enables data-driven inference of robot stability without requiring an explicit terrain model or force sensing. We also develop a novel vision-based ArUco tracking method to compute a scalar score to quantify robot platform stability called C3 score. The score captures image-space perturbations over time as a proxy for physical instability and is used as a training signal for the neural network based model. As a pilot study, we evaluate our approach on data collected across multiple terrain types and speeds and demonstrate generalization to previously unseen conditions. These initial results highlight the potential of using IMU and robot velocity as inputs to estimate platform stability. The proposed method finds application in gating robot tasks such as precision actuation and sensing, especially for mobile manipulation tasks in agricultural and space applications. Our learning method also provides a supervision mechanism for perception based traversability estimation and planning.
title Learning to Predict Mobile Robot Stability in Off-Road Environments
topic Robotics
url https://arxiv.org/abs/2507.12731