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Satellite Collision Detection using Spatial Data Structures

Hellwig, Christian ; Czappa, Fabian ; Michel, Martin ; Bertrand, Reinhold ; Wolf, Felix (2023)
Satellite Collision Detection using Spatial Data Structures.
2023 IEEE International Parallel and Distributed Processing Symposium. St. Petersburg, USA (15.-19.05.2023)
doi: 10.1109/IPDPS54959.2023.00078
Conference or Workshop Item, Bibliographie

Abstract

In recent years, the number of artificial objects in Earth orbit has increased rapidly due to lower launch costs and new applications for satellites. More and more governments and private companies are discovering space for their own purposes. Private companies are using space as a new business field, launching thousands of satellites into orbit to offer services like worldwide Internet access. Consequently, the probability of collisions and, thus, the degradation of the orbital environment is rapidly increasing. To avoid devastating collisions at an early stage, efficient algorithms are required to identify satellites approaching each other. Traditional deterministic filter-based conjunction detection algorithms compare each satellite to every other satellite and pass them through a chain of orbital filters. Unfortunately, this leads to a runtime complexity of O(n 2 ). In this paper, we propose two alternative approaches that rely on spatial data structures and thus allow us to exploit modern hardware’s parallelism efficiently. Firstly, we introduce a purely grid-based variant that relies on non-blocking atomic hash maps to identify conjunctions. Secondly, we present a hybrid method that combines this approach with traditional filter chains. Both implementations make it possible to identify conjunctions in a large population with millions of satellites with high precision in a comparatively short time. While the grid-based variant is characterized by lower memory consumption, the hybrid variant is faster if enough memory is available.

Item Type: Conference or Workshop Item
Erschienen: 2023
Creators: Hellwig, Christian ; Czappa, Fabian ; Michel, Martin ; Bertrand, Reinhold ; Wolf, Felix
Type of entry: Bibliographie
Title: Satellite Collision Detection using Spatial Data Structures
Language: English
Date: 18 July 2023
Publisher: IEEE
Book Title: Proceedings: 2023 IEEE International Parallel and Distributed Processing Symposium: IPDPS 2023
Event Title: 2023 IEEE International Parallel and Distributed Processing Symposium
Event Location: St. Petersburg, USA
Event Dates: 15.-19.05.2023
DOI: 10.1109/IPDPS54959.2023.00078
Abstract:

In recent years, the number of artificial objects in Earth orbit has increased rapidly due to lower launch costs and new applications for satellites. More and more governments and private companies are discovering space for their own purposes. Private companies are using space as a new business field, launching thousands of satellites into orbit to offer services like worldwide Internet access. Consequently, the probability of collisions and, thus, the degradation of the orbital environment is rapidly increasing. To avoid devastating collisions at an early stage, efficient algorithms are required to identify satellites approaching each other. Traditional deterministic filter-based conjunction detection algorithms compare each satellite to every other satellite and pass them through a chain of orbital filters. Unfortunately, this leads to a runtime complexity of O(n 2 ). In this paper, we propose two alternative approaches that rely on spatial data structures and thus allow us to exploit modern hardware’s parallelism efficiently. Firstly, we introduce a purely grid-based variant that relies on non-blocking atomic hash maps to identify conjunctions. Secondly, we present a hybrid method that combines this approach with traditional filter chains. Both implementations make it possible to identify conjunctions in a large population with millions of satellites with high precision in a comparatively short time. While the grid-based variant is characterized by lower memory consumption, the hybrid variant is faster if enough memory is available.

Uncontrolled Keywords: BMBF/HMWK|NHR4CES, Large-scale, Satellite Conjunction, Simulation, Space Debris
Divisions: 20 Department of Computer Science
20 Department of Computer Science > Parallel Programming
Zentrale Einrichtungen
Zentrale Einrichtungen > University IT-Service and Computing Centre (HRZ)
Zentrale Einrichtungen > University IT-Service and Computing Centre (HRZ) > Hochleistungsrechner
Date Deposited: 13 Feb 2024 15:17
Last Modified: 02 May 2024 14:19
PPN: 517701480
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