DETERMINATION OF THE FORCE IMPACT OF AN ION THRUSTER PLUME ON AN ORBITAL OBJECT VIA DEEP LEARNING

Pub Date : 2022-10-28 DOI:10.15407/knit2022.05.015

M. Redka, S. Khoroshylov

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引用次数: 1

Abstract

The subject of research is the process of creating a neural network model (NNM) for determining the force impact of an ion thruster (IT) plume on an orbital object during non-contact space debris removal. The work aims to develop NNMs and study the influence of various factors on the accuracy of determining the force transmitted by the ion plume of the thruster to a space debris object (SDO). The tasks to resolve are to choose the structures of the NNMs, form a data set and use this data to train and validate the NNMs, and to explore the influence of the model structure and optimizer parameters on the accuracy of force determination. The methods used are plasma physics, computer simulation, deep learning, and optimization using an improved version of stochastic gradient descent. As a result of research, three NNMs have been developed, which differ in the number of hidden layers and neurons in hidden layers. For training and validation of the NNMs, a data set was generated for an SDO approximated by a cylinder using an autosimilar description of the ion plasma propagation. The data set was obtained for various relative positions and orientations of the object in the process of its removal from an orbit. Using this data set, the NNM parameters were optimized with the supervised learning method. The optimizer and its parameters are selected, providing a small error at the stage of validating learning outcomes. It was found that the accuracy of determining the force depends on the relative position and orientation of the SDO, as well as the architecture of the NNM, and the features of this influence were identified. The approach applied allows us to obtain the possibility of using methods of deep learning to determine the force impact of the IT plume on the SDO. The proposed models provide the accuracy of the force impact determination, which is sufficient for solving the considered class of problems. At the same time, NNM makes it possible to obtain results much faster in comparison with the methods used previously. This fact makes the NNMs promising to use both on-board and in mathematical modeling of missions to remove space debris.

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通过深度学习确定离子推力器羽流对轨道物体的力影响

研究的主题是创建一个神经网络模型(NNM)的过程，用于确定离子推进器(IT)羽流在非接触式空间碎片清除过程中对轨道物体的力影响。该工作旨在开发NNMs，并研究各种因素对确定由推进器离子羽流传递给空间碎片物体(SDO)的力的准确性的影响。要解决的任务是选择NNMs的结构，形成一个数据集并使用该数据集对NNMs进行训练和验证，并探索模型结构和优化器参数对力确定精度的影响。使用的方法是等离子体物理、计算机模拟、深度学习和使用改进版本的随机梯度下降的优化。通过研究，我们开发了三种不同隐藏层数量和隐藏层神经元数量的神经网络。为了训练和验证NNMs，使用离子等离子体传播的自相似描述，为SDO生成了一个数据集。该数据集用于获得目标在其从轨道移除过程中的各种相对位置和方向。利用该数据集，采用监督学习方法对NNM参数进行优化。选择优化器及其参数，在验证学习结果的阶段提供一个小误差。研究发现，确定力的精度取决于SDO的相对位置和方向，以及NNM的结构，并确定了这种影响的特征。所应用的方法使我们能够获得使用深度学习方法来确定IT羽流对SDO的力影响的可能性。所提出的模型提供了力冲击确定的准确性，足以解决所考虑的一类问题。同时，与以前使用的方法相比，NNM可以更快地获得结果。这一事实使得NNMs有望同时使用机载和任务的数学建模来清除空间碎片。

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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