Machine learning applied to simulations of collisions between rotating, differentiated planets

Miles L. Timpe, Maria Han Veiga, Mischa Knabenhans, Joachim Stadel, Stefano Marelli
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引用次数: 10

Abstract

In the late stages of terrestrial planet formation, pairwise collisions between planetary-sized bodies act as the fundamental agent of planet growth. These collisions can lead to either growth or disruption of the bodies involved and are largely responsible for shaping the final characteristics of the planets. Despite their critical role in planet formation, an accurate treatment of collisions has yet to be realized. While semi-analytic methods have been proposed, they remain limited to a narrow set of post-impact properties and have only achieved relatively low accuracies. However, the rise of machine learning and access to increased computing power have enabled novel data-driven approaches. In this work, we show that data-driven emulation techniques are capable of classifying and predicting the outcome of collisions with high accuracy and are generalizable to any quantifiable post-impact quantity. In particular, we focus on the dataset requirements, training pipeline, and classification and regression performance for four distinct data-driven techniques from machine learning (ensemble methods and neural networks) and uncertainty quantification (Gaussian processes and polynomial chaos expansion). We compare these methods to existing analytic and semi-analytic methods. Such data-driven emulators are poised to replace the methods currently used in N-body simulations, while avoiding the cost of direct simulation. This work is based on a new set of 14,856 SPH simulations of pairwise collisions between rotating, differentiated bodies at all possible mutual orientations.

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机器学习应用于模拟旋转、分化的行星之间的碰撞
在类地行星形成的后期,行星大小的天体之间的成对碰撞是行星成长的基本动力。这些碰撞可能导致相关天体的成长或破坏,并在很大程度上决定了行星的最终特征。尽管它们在行星形成中起着至关重要的作用,但对碰撞的精确处理尚未实现。虽然已经提出了半解析方法,但它们仍然局限于一组狭窄的撞击后属性,并且只能达到相对较低的精度。然而,机器学习的兴起和计算能力的增强使得新的数据驱动方法成为可能。在这项工作中,我们证明了数据驱动的仿真技术能够以高精度分类和预测碰撞的结果,并且可以推广到任何可量化的碰撞后数量。特别是,我们专注于数据集需求,训练管道,以及机器学习(集成方法和神经网络)和不确定性量化(高斯过程和多项式混沌展开)四种不同数据驱动技术的分类和回归性能。我们将这些方法与现有的解析和半解析方法进行了比较。这种数据驱动的仿真器有望取代目前在n体仿真中使用的方法,同时避免直接仿真的成本。这项工作是基于一组新的14,856 SPH模拟,模拟了旋转的、不同的物体在所有可能的相互方向上的成对碰撞。
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