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Autori principali: Chen, Junan, Monica, Josephine, Chao, Wei-Lun, Campbell, Mark
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2305.20044
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author Chen, Junan
Monica, Josephine
Chao, Wei-Lun
Campbell, Mark
author_facet Chen, Junan
Monica, Josephine
Chao, Wei-Lun
Campbell, Mark
contents The uncertainty quantification of prediction models (e.g., neural networks) is crucial for their adoption in many robotics applications. This is arguably as important as making accurate predictions, especially for safety-critical applications such as self-driving cars. This paper proposes our approach to uncertainty quantification in the context of visual localization for autonomous driving, where we predict locations from images. Our proposed framework estimates probabilistic uncertainty by creating a sensor error model that maps an internal output of the prediction model to the uncertainty. The sensor error model is created using multiple image databases of visual localization, each with ground-truth location. We demonstrate the accuracy of our uncertainty prediction framework using the Ithaca365 dataset, which includes variations in lighting, weather (sunny, snowy, night), and alignment errors between databases. We analyze both the predicted uncertainty and its incorporation into a Kalman-based localization filter. Our results show that prediction error variations increase with poor weather and lighting condition, leading to greater uncertainty and outliers, which can be predicted by our proposed uncertainty model. Additionally, our probabilistic error model enables the filter to remove ad hoc sensor gating, as the uncertainty automatically adjusts the model to the input data
format Preprint
id arxiv_https___arxiv_org_abs_2305_20044
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Probabilistic Uncertainty Quantification of Prediction Models with Application to Visual Localization
Chen, Junan
Monica, Josephine
Chao, Wei-Lun
Campbell, Mark
Robotics
The uncertainty quantification of prediction models (e.g., neural networks) is crucial for their adoption in many robotics applications. This is arguably as important as making accurate predictions, especially for safety-critical applications such as self-driving cars. This paper proposes our approach to uncertainty quantification in the context of visual localization for autonomous driving, where we predict locations from images. Our proposed framework estimates probabilistic uncertainty by creating a sensor error model that maps an internal output of the prediction model to the uncertainty. The sensor error model is created using multiple image databases of visual localization, each with ground-truth location. We demonstrate the accuracy of our uncertainty prediction framework using the Ithaca365 dataset, which includes variations in lighting, weather (sunny, snowy, night), and alignment errors between databases. We analyze both the predicted uncertainty and its incorporation into a Kalman-based localization filter. Our results show that prediction error variations increase with poor weather and lighting condition, leading to greater uncertainty and outliers, which can be predicted by our proposed uncertainty model. Additionally, our probabilistic error model enables the filter to remove ad hoc sensor gating, as the uncertainty automatically adjusts the model to the input data
title Probabilistic Uncertainty Quantification of Prediction Models with Application to Visual Localization
topic Robotics
url https://arxiv.org/abs/2305.20044