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Main Authors: Louëdec, Justin Le, Bauer, Maike, Amerstorfer, Tanja, Davies, Jackie A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.15288
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author Louëdec, Justin Le
Bauer, Maike
Amerstorfer, Tanja
Davies, Jackie A.
author_facet Louëdec, Justin Le
Bauer, Maike
Amerstorfer, Tanja
Davies, Jackie A.
contents Observing and forecasting coronal mass ejections (CME) in real-time is crucial due to the strong geomagnetic storms they can generate that can have a potentially damaging effect, for example, on satellites and electrical devices. With its near-real-time availability, STEREO/HI beacon data is the perfect candidate for early forecasting of CMEs. However, previous work concluded that CME arrival prediction based on beacon data could not achieve the same accuracy as with high-resolution science data due to data gaps and lower quality. We present our novel machine-learning pipeline entitled ``Beacon2Science'', bridging the gap between beacon and science data to improve CME tracking. Through this pipeline, we first enhance the quality (signal-to-noise ratio and spatial resolution) of beacon data. We then increase the time resolution of enhanced beacon images through learned interpolation to match science data's 40-minute resolution. We maximize information coherence between consecutive frames with adapted model architecture and loss functions through the different steps. The improved beacon images are comparable to science data, showing better CME visibility than the original beacon data. Furthermore, we compare CMEs tracked in beacon, enhanced beacon, and science images. The tracks extracted from enhanced beacon data are closer to those from science images, with a mean average error of $\sim 0.5 ^\circ$ of elongation compared to $1^\circ$ with original beacon data. The work presented in this paper paves the way for its application to forthcoming missions such as Vigil and PUNCH.
format Preprint
id arxiv_https___arxiv_org_abs_2503_15288
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beacon2Science: Enhancing STEREO/HI beacon data with machine learning for efficient CME tracking
Louëdec, Justin Le
Bauer, Maike
Amerstorfer, Tanja
Davies, Jackie A.
Space Physics
Computer Vision and Pattern Recognition
Machine Learning
Observing and forecasting coronal mass ejections (CME) in real-time is crucial due to the strong geomagnetic storms they can generate that can have a potentially damaging effect, for example, on satellites and electrical devices. With its near-real-time availability, STEREO/HI beacon data is the perfect candidate for early forecasting of CMEs. However, previous work concluded that CME arrival prediction based on beacon data could not achieve the same accuracy as with high-resolution science data due to data gaps and lower quality. We present our novel machine-learning pipeline entitled ``Beacon2Science'', bridging the gap between beacon and science data to improve CME tracking. Through this pipeline, we first enhance the quality (signal-to-noise ratio and spatial resolution) of beacon data. We then increase the time resolution of enhanced beacon images through learned interpolation to match science data's 40-minute resolution. We maximize information coherence between consecutive frames with adapted model architecture and loss functions through the different steps. The improved beacon images are comparable to science data, showing better CME visibility than the original beacon data. Furthermore, we compare CMEs tracked in beacon, enhanced beacon, and science images. The tracks extracted from enhanced beacon data are closer to those from science images, with a mean average error of $\sim 0.5 ^\circ$ of elongation compared to $1^\circ$ with original beacon data. The work presented in this paper paves the way for its application to forthcoming missions such as Vigil and PUNCH.
title Beacon2Science: Enhancing STEREO/HI beacon data with machine learning for efficient CME tracking
topic Space Physics
Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2503.15288