Sequential Deep Learning for Mars Autonomous Navigation

2023 IEEE Space Computing Conference (SCC) Pub Date : 2023-07-01 DOI:10.1109/SCC57168.2023.00011

Hyoshin Park, M. Ono

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Abstract

Recent advances in computer vision for space exploration have handled prediction uncertainties well by approximating multimodal output distribution rather than averaging the distribution. While those advanced multimodal deep learning models could enhance the scientific and engineering value of autonomous systems by making the optimal decisions in uncertain environments, sequential learning of those approximated information has depended on unimodal or bimodal probability distribution. In a sequence of information learning and transfer decisions, the traditional reinforcement learning cannot accommodate the noise in the data that could be useful for gaining information from other locations, thus cannot handle multimodal and multivariate gains in their transition function. Still, there is a lack of interest in learning and transferring multimodal space information effectively to maximally remove the uncertainty. In this study, a new information theory overcomes the traditional entropy approach by actively sensing and learning information in a sequence. Particularly, the autonomous navigation of a team of heterogeneous unmanned ground and aerial vehicle systems in Mars outperforms benchmarks through indirect learning.

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火星自主导航的顺序深度学习

空间探索计算机视觉的最新进展通过逼近多模态输出分布而不是平均分布，很好地处理了预测的不确定性。虽然这些先进的多模态深度学习模型可以通过在不确定环境中做出最优决策来提高自治系统的科学和工程价值，但这些近似信息的顺序学习依赖于单峰或双峰概率分布。在一系列的信息学习和迁移决策中，传统的强化学习不能适应数据中的噪声，而这些噪声可能对从其他位置获取信息有用，因此不能处理其过渡函数中的多模态和多元增益。然而，对于如何有效地学习和传递多模态空间信息以最大限度地消除不确定性，人们缺乏兴趣。在本研究中，一种新的信息理论通过主动感知和学习序列中的信息来克服传统的熵方法。特别是，在火星上，一组异构无人地面和飞行器系统的自主导航通过间接学习优于基准。

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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2023 IEEE Space Computing Conference (SCC)

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