Simulating the Evolution of Lethal Non-Trackable Population and its Effect on LEO Sustainability

arXiv - PHYS - Space Physics Pub Date : 2024-08-27 DOI:arxiv-2408.15025

Daniel Jang, Richard Linares

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Abstract

The vast majority of the orbital population today is unobservable and untracked because of their small size. These lethal non-trackable objects will only become more numerous as more payloads and debris are launched into orbit and increase the collision rate. In this paper, the long-term effect of collisions is simulated with an efficient Monte-Carlo method to simulate the future LEO environment including lethal non-trackable objects, which is typically ignored due to the large computational resources required. The results show that simulations that do not incorporate lethal non-trackable debris would be omitting a large number of debilitating collisions with active payloads and catastrophic collisions to a smaller effect. This shows the importance of simulating small debris in the long-term evolution of the orbital population, which is often omitted in the literature. This increased debris population and consequentially the risk to orbital payloads diminishes as smaller lethal non-trackable objects are considered. An efficient and validated model is used to simulate these numerous small objects. Several future cases such as launches of registered megaconstellations, improved post-mission disposal rates and no-future launches are explored to understand the effect of the inclusion or exclusion of lethal non-trackable objects.

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模拟致命性非可追踪种群的演变及其对低地轨道可持续性的影响

目前，轨道上的绝大多数物体由于体积小而无法观测和跟踪。随着越来越多的有效载荷和碎片被送入轨道并增加碰撞率，这些致命的不可追踪物体只会越来越多。本文采用一种高效的蒙特卡洛方法模拟了碰撞的长期影响，以模拟包括致命不可跟踪物体在内的未来低地轨道环境，由于需要大量计算资源，这种环境通常被忽略。结果表明，如果模拟不包括致命的非可跟踪碎片，就会遗漏大量对有效载荷造成损害的碰撞和影响较小的灾难性碰撞。这表明了模拟轨道碎片群长期演变过程中的小型碎片的重要性，而文献中往往忽略了这一点。如果考虑到更小的致命性不可追踪物体，碎片群的增加以及由此对轨道有效载荷造成的风险就会降低。我们使用了一个高效且经过验证的模型来模拟这些数量众多的小物体。对未来的几种情况进行了探讨，如发射已登记的巨型恒星、提高任务后处置率和今后不再发射，以了解纳入或排除致命不可跟踪物体的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Space Physics

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