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Main Authors: Stock, Gregory F., Fraire, Juan A., Hermanns, Holger, Mosiężny, Jędrzej, Al-Khazraji, Yusra, Molina, Julio Ramírez, Ntagiou, Evridiki V.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.15574
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author Stock, Gregory F.
Fraire, Juan A.
Hermanns, Holger
Mosiężny, Jędrzej
Al-Khazraji, Yusra
Molina, Julio Ramírez
Ntagiou, Evridiki V.
author_facet Stock, Gregory F.
Fraire, Juan A.
Hermanns, Holger
Mosiężny, Jędrzej
Al-Khazraji, Yusra
Molina, Julio Ramírez
Ntagiou, Evridiki V.
contents The rapid expansion of satellite constellations in near-Earth orbits presents significant challenges in satellite network management, requiring innovative approaches for efficient, scalable, and resilient operations. This paper explores the role of Artificial Intelligence (AI) in optimizing the operation of satellite mega-constellations, drawing from the ConstellAI project funded by the European Space Agency (ESA). A consortium comprising GMV GmbH, Saarland University, and Thales Alenia Space collaborates to develop AI-driven algorithms and demonstrates their effectiveness over traditional methods for two crucial operational challenges: data routing and resource allocation. In the routing use case, Reinforcement Learning (RL) is used to improve the end-to-end latency by learning from historical queuing latency, outperforming classical shortest path algorithms. For resource allocation, RL optimizes the scheduling of tasks across constellations, focussing on efficiently using limited resources such as battery and memory. Both use cases were tested for multiple satellite constellation configurations and operational scenarios, resembling the real-life spacecraft operations of communications and Earth observation satellites. This research demonstrates that RL not only competes with classical approaches but also offers enhanced flexibility, scalability, and generalizability in decision-making processes, which is crucial for the autonomous and intelligent management of satellite fleets. The findings of this activity suggest that AI can fundamentally alter the landscape of satellite constellation management by providing more adaptive, robust, and cost-effective solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2507_15574
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On the Role of AI in Managing Satellite Constellations: Insights from the ConstellAI Project
Stock, Gregory F.
Fraire, Juan A.
Hermanns, Holger
Mosiężny, Jędrzej
Al-Khazraji, Yusra
Molina, Julio Ramírez
Ntagiou, Evridiki V.
Machine Learning
Artificial Intelligence
The rapid expansion of satellite constellations in near-Earth orbits presents significant challenges in satellite network management, requiring innovative approaches for efficient, scalable, and resilient operations. This paper explores the role of Artificial Intelligence (AI) in optimizing the operation of satellite mega-constellations, drawing from the ConstellAI project funded by the European Space Agency (ESA). A consortium comprising GMV GmbH, Saarland University, and Thales Alenia Space collaborates to develop AI-driven algorithms and demonstrates their effectiveness over traditional methods for two crucial operational challenges: data routing and resource allocation. In the routing use case, Reinforcement Learning (RL) is used to improve the end-to-end latency by learning from historical queuing latency, outperforming classical shortest path algorithms. For resource allocation, RL optimizes the scheduling of tasks across constellations, focussing on efficiently using limited resources such as battery and memory. Both use cases were tested for multiple satellite constellation configurations and operational scenarios, resembling the real-life spacecraft operations of communications and Earth observation satellites. This research demonstrates that RL not only competes with classical approaches but also offers enhanced flexibility, scalability, and generalizability in decision-making processes, which is crucial for the autonomous and intelligent management of satellite fleets. The findings of this activity suggest that AI can fundamentally alter the landscape of satellite constellation management by providing more adaptive, robust, and cost-effective solutions.
title On the Role of AI in Managing Satellite Constellations: Insights from the ConstellAI Project
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2507.15574