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Main Authors: Manchingal, Shireen Kudukkil, Amaritei, Armand, Gohad, Mihir, Sultana, Maryam, Kooij, Julian F. P., Cuzzolin, Fabio, Bradley, Andrew
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.22680
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author Manchingal, Shireen Kudukkil
Amaritei, Armand
Gohad, Mihir
Sultana, Maryam
Kooij, Julian F. P.
Cuzzolin, Fabio
Bradley, Andrew
author_facet Manchingal, Shireen Kudukkil
Amaritei, Armand
Gohad, Mihir
Sultana, Maryam
Kooij, Julian F. P.
Cuzzolin, Fabio
Bradley, Andrew
contents Autonomous Vehicle (AV) perception systems have advanced rapidly in recent years, providing vehicles with the ability to accurately interpret their environment. Perception systems remain susceptible to errors caused by overly-confident predictions in the case of rare events or out-of-sample data. This study equips an autonomous vehicle with the ability to 'know when it is uncertain', using an uncertainty-aware image classifier as part of the AV software stack. Specifically, the study exploits the ability of Random-Set Neural Networks (RS-NNs) to explicitly quantify prediction uncertainty. Unlike traditional CNNs or Bayesian methods, RS-NNs predict belief functions over sets of classes, allowing the system to identify and signal uncertainty clearly in novel or ambiguous scenarios. The system is tested in a real-world autonomous racing vehicle software stack, with the RS-NN classifying the layout of the road ahead and providing the associated uncertainty of the prediction. Performance of the RS-NN under a range of road conditions is compared against traditional CNN and Bayesian neural networks, with the RS-NN achieving significantly higher accuracy and superior uncertainty calibration. This integration of RS-NNs into Robot Operating System (ROS)-based vehicle control pipeline demonstrates that predictive uncertainty can dynamically modulate vehicle speed, maintaining high-speed performance under confident predictions while proactively improving safety through speed reductions in uncertain scenarios. These results demonstrate the potential of uncertainty-aware neural networks - in particular RS-NNs - as a practical solution for safer and more robust autonomous driving.
format Preprint
id arxiv_https___arxiv_org_abs_2510_22680
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Uncertainty-Aware Autonomous Vehicles: Predicting the Road Ahead
Manchingal, Shireen Kudukkil
Amaritei, Armand
Gohad, Mihir
Sultana, Maryam
Kooij, Julian F. P.
Cuzzolin, Fabio
Bradley, Andrew
Robotics
Artificial Intelligence
Autonomous Vehicle (AV) perception systems have advanced rapidly in recent years, providing vehicles with the ability to accurately interpret their environment. Perception systems remain susceptible to errors caused by overly-confident predictions in the case of rare events or out-of-sample data. This study equips an autonomous vehicle with the ability to 'know when it is uncertain', using an uncertainty-aware image classifier as part of the AV software stack. Specifically, the study exploits the ability of Random-Set Neural Networks (RS-NNs) to explicitly quantify prediction uncertainty. Unlike traditional CNNs or Bayesian methods, RS-NNs predict belief functions over sets of classes, allowing the system to identify and signal uncertainty clearly in novel or ambiguous scenarios. The system is tested in a real-world autonomous racing vehicle software stack, with the RS-NN classifying the layout of the road ahead and providing the associated uncertainty of the prediction. Performance of the RS-NN under a range of road conditions is compared against traditional CNN and Bayesian neural networks, with the RS-NN achieving significantly higher accuracy and superior uncertainty calibration. This integration of RS-NNs into Robot Operating System (ROS)-based vehicle control pipeline demonstrates that predictive uncertainty can dynamically modulate vehicle speed, maintaining high-speed performance under confident predictions while proactively improving safety through speed reductions in uncertain scenarios. These results demonstrate the potential of uncertainty-aware neural networks - in particular RS-NNs - as a practical solution for safer and more robust autonomous driving.
title Uncertainty-Aware Autonomous Vehicles: Predicting the Road Ahead
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2510.22680