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Bibliographic Details
Main Authors: Lottermoser, Clemens, Damm, Simon, Schmid, Stefan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.14008
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author Lottermoser, Clemens
Damm, Simon
Schmid, Stefan
author_facet Lottermoser, Clemens
Damm, Simon
Schmid, Stefan
contents This paper presents an empirical study of dynamic factors affecting link quality in Low Earth Orbit (LEO) satellite communications, using Starlink as a case study. Over 56 days, 112 high-quality meteorological measurements in mostly 1-min intervals, co-located with a user terminal, were collected, alongside frequent network performance data. Cloud characteristics were estimated using professional weather instruments such as a ceilometer, microwave radiometer, and vision-language model on sky images. Our results show that general cloud presence does not significantly impact throughput or latency. The impact of cloud coverage rather depends on the presence of liquid water in the atmosphere, quantified by liquid water path (LWP), which correlates with notable download throughput reductions (up to 60 MBit/s), especially during rain. Upload and latency were largely unaffected. Analysis of the evolving satellite network revealed that newer satellite hardware and infrastructural upgrades also contributed to performance increases during the experiment period. These findings highlight atmospheric liquid water as the key weather-related factor affecting link quality and underscore the influence of network changes over time.
format Preprint
id arxiv_https___arxiv_org_abs_2603_14008
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Measuring Weather Effects and Link Quality Dynamics in LEO Satellite Networks
Lottermoser, Clemens
Damm, Simon
Schmid, Stefan
Networking and Internet Architecture
This paper presents an empirical study of dynamic factors affecting link quality in Low Earth Orbit (LEO) satellite communications, using Starlink as a case study. Over 56 days, 112 high-quality meteorological measurements in mostly 1-min intervals, co-located with a user terminal, were collected, alongside frequent network performance data. Cloud characteristics were estimated using professional weather instruments such as a ceilometer, microwave radiometer, and vision-language model on sky images. Our results show that general cloud presence does not significantly impact throughput or latency. The impact of cloud coverage rather depends on the presence of liquid water in the atmosphere, quantified by liquid water path (LWP), which correlates with notable download throughput reductions (up to 60 MBit/s), especially during rain. Upload and latency were largely unaffected. Analysis of the evolving satellite network revealed that newer satellite hardware and infrastructural upgrades also contributed to performance increases during the experiment period. These findings highlight atmospheric liquid water as the key weather-related factor affecting link quality and underscore the influence of network changes over time.
title Measuring Weather Effects and Link Quality Dynamics in LEO Satellite Networks
topic Networking and Internet Architecture
url https://arxiv.org/abs/2603.14008