{"title":"小行星行为的时间趋势:机器学习和 N 体集成方法","authors":"Chetan Abhijnanam Bora, Badam Singh Kushvah, Gunda Chandra Mouli, Saleem Yousuf","doi":"10.1093/mnras/stae2083","DOIUrl":null,"url":null,"abstract":"Asteroids pose significant threats to Earth, necessitating early detection for potential deflection. Leveraging machine learning (ML), we classify asteroids into Near-Earth Asteroids (particularly Atens, Amors, Apollos, and Apoheles) and Non Near-Earth Asteroids, further categorizing them based on hazard potential. Training the seven models on a comprehensive dataset of 4687 asteroids, we achieve high accuracy in prediction. The predictive capability of these models is critical for informed decision-making in planetary defense strategies. We apply different regularization techniques to prevent overfitting and validate the models using a large unseen dataset. A rigorous long-term N-body integration spanning 1 million years is executed utilizing the Mercury N-body integrator to illuminate the evolution of asteroid properties over extended temporal scales. Following this integration process, the best-performing ML model is employed to classify asteroids based on their orbital characteristics and hazardous status respectively. Our findings highlight the effectiveness of ML in asteroid classification and prediction, paving the way for large-scale applications. By dividing a 1 million-year integration into intervals, we uncover temporal trends in asteroid behavior, revealing insights into hazard evolution and ejection patterns. Notably, initially, hazardous asteroids tend to transition to non-hazardous states over time, elucidating key dynamics in planetary defense. We illustrate these findings through plotted graphs, providing valuable insights into asteroid dynamics. These insights are instrumental in advancing our understanding of long-term asteroid behavior, with significant implications for future research and planetary protection efforts.","PeriodicalId":18930,"journal":{"name":"Monthly Notices of the Royal Astronomical Society","volume":"9 1","pages":""},"PeriodicalIF":4.7000,"publicationDate":"2024-09-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Temporal Trends in Asteroid Behavior: A Machine Learning and N-Body Integration Approach\",\"authors\":\"Chetan Abhijnanam Bora, Badam Singh Kushvah, Gunda Chandra Mouli, Saleem Yousuf\",\"doi\":\"10.1093/mnras/stae2083\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Asteroids pose significant threats to Earth, necessitating early detection for potential deflection. Leveraging machine learning (ML), we classify asteroids into Near-Earth Asteroids (particularly Atens, Amors, Apollos, and Apoheles) and Non Near-Earth Asteroids, further categorizing them based on hazard potential. Training the seven models on a comprehensive dataset of 4687 asteroids, we achieve high accuracy in prediction. The predictive capability of these models is critical for informed decision-making in planetary defense strategies. We apply different regularization techniques to prevent overfitting and validate the models using a large unseen dataset. A rigorous long-term N-body integration spanning 1 million years is executed utilizing the Mercury N-body integrator to illuminate the evolution of asteroid properties over extended temporal scales. Following this integration process, the best-performing ML model is employed to classify asteroids based on their orbital characteristics and hazardous status respectively. 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引用次数: 0
摘要
小行星对地球构成重大威胁,必须及早探测,以便进行潜在的偏转。利用机器学习(ML)技术,我们将小行星分为近地小行星(尤其是阿坦斯、阿莫斯、阿波罗斯和阿波赫勒斯)和非近地小行星,并根据潜在危害对其进行进一步分类。我们在一个包含 4687 颗小行星的综合数据集上对这七个模型进行了训练,从而获得了较高的预测精度。这些模型的预测能力对于行星防御战略的明智决策至关重要。我们采用了不同的正则化技术来防止过拟合,并利用大量未见数据集对这些模型进行了验证。我们利用水星 N-body 积分器执行了跨越 100 万年的严格长期 N-body 积分,以揭示小行星特性在更长时间尺度上的演变。在这一整合过程之后,利用性能最佳的 ML 模型,分别根据小行星的轨道特征和危险状态对其进行分类。我们的研究结果凸显了 ML 在小行星分类和预测中的有效性,为大规模应用铺平了道路。通过将 100 万年的整合划分为若干区间,我们发现了小行星行为的时间趋势,揭示了危险演化和弹射模式。值得注意的是,随着时间的推移,最初的危险小行星往往会过渡到非危险状态,从而阐明了行星防御的关键动态。我们通过绘制的图表说明了这些发现,提供了对小行星动态的宝贵见解。这些见解有助于推进我们对小行星长期行为的理解,对未来的研究和行星保护工作具有重要意义。
Temporal Trends in Asteroid Behavior: A Machine Learning and N-Body Integration Approach
Asteroids pose significant threats to Earth, necessitating early detection for potential deflection. Leveraging machine learning (ML), we classify asteroids into Near-Earth Asteroids (particularly Atens, Amors, Apollos, and Apoheles) and Non Near-Earth Asteroids, further categorizing them based on hazard potential. Training the seven models on a comprehensive dataset of 4687 asteroids, we achieve high accuracy in prediction. The predictive capability of these models is critical for informed decision-making in planetary defense strategies. We apply different regularization techniques to prevent overfitting and validate the models using a large unseen dataset. A rigorous long-term N-body integration spanning 1 million years is executed utilizing the Mercury N-body integrator to illuminate the evolution of asteroid properties over extended temporal scales. Following this integration process, the best-performing ML model is employed to classify asteroids based on their orbital characteristics and hazardous status respectively. Our findings highlight the effectiveness of ML in asteroid classification and prediction, paving the way for large-scale applications. By dividing a 1 million-year integration into intervals, we uncover temporal trends in asteroid behavior, revealing insights into hazard evolution and ejection patterns. Notably, initially, hazardous asteroids tend to transition to non-hazardous states over time, elucidating key dynamics in planetary defense. We illustrate these findings through plotted graphs, providing valuable insights into asteroid dynamics. These insights are instrumental in advancing our understanding of long-term asteroid behavior, with significant implications for future research and planetary protection efforts.
期刊介绍:
Monthly Notices of the Royal Astronomical Society is one of the world''s leading primary research journals in astronomy and astrophysics, as well as one of the longest established. It publishes the results of original research in positional and dynamical astronomy, astrophysics, radio astronomy, cosmology, space research and the design of astronomical instruments.