Deriving big geochemical data from high-resolution remote sensing data via machine learning: Application to a tailing storage facility in the Witwatersrand goldfields

Steven E. Zhang , Glen T. Nwaila , Julie E. Bourdeau , Yousef Ghorbani , Emmanuel John M. Carranza
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引用次数: 7

Abstract

Remote sensing data is a cheap form of surficial geoscientific data, and in terms of veracity, velocity and volume, can sometimes be considered big data. Its spatial and spectral resolution continues to improve over time, and some modern satellites, such as the Copernicus Programme's Sentinel-2 remote sensing satellites, offer a spatial resolution of 10 m across many of their spectral bands. The abundance and quality of remote sensing data combined with accumulated primary geochemical data has provided an unprecedented opportunity to inferentially invert remote sensing data into geochemical data. The ability to derive geochemical data from remote sensing data would provide a form of secondary big geochemical data, which can be used for numerous downstream activities, particularly where data timeliness, volume and velocity are important. Major benefactors of secondary geochemical data would be environmental monitoring and applications of artificial intelligence and machine learning in geochemistry, which currently entirely relies on manually derived data that is primarily guided by scientific reduction. Furthermore, it permits the usage of well-established data analysis techniques from geochemistry to remote sensing that allows useable insights to be extracted beyond those typically associated with strictly remote sensing data analysis. Currently, no generally applicable and systematic method to derive chemical elemental concentrations from large-scale remote sensing data have been documented in geosciences. In this paper, we demonstrate that fusing geostatistically-augmented geochemical and remote sensing data produces an abundance of data that enables a more generalized machine learning-based geochemical data generation. We use gold grade data from a South African tailing storage facility (TSF) and data from both the Landsat-8 and Sentinel remote sensing satellites. We show that various machine learning algorithms can be used given the abundance of training data. Consequently, we are able to produce a high resolution (10 m grid size) gold concentration map of the TSF, which demonstrates the potential of our method to be used to guide extraction planning, online resource exploration, environmental monitoring and resource estimation.

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通过机器学习从高分辨率遥感数据中获取大地球化学数据:在威特沃特斯兰德金矿尾矿储存设施中的应用
遥感数据是地表地球科学数据的一种廉价形式,就准确性、速度和体积而言,有时可以被视为大数据。随着时间的推移,其空间和光谱分辨率不断提高,一些现代卫星,如哥白尼计划的哨兵2号遥感卫星,在其许多光谱波段上提供了10米的空间分辨率。遥感数据的丰富性和质量与积累的原始地球化学数据相结合,为推断地将遥感数据转化为地球化学数据提供了前所未有的机会。从遥感数据中获得地球化学数据的能力将提供一种次级大地球化学数据形式,可用于许多下游活动,特别是在数据及时性、体积和速度很重要的情况下。二次地球化学数据的主要受益者将是环境监测以及人工智能和机器学习在地球化学中的应用,目前地球化学完全依赖于主要以科学还原为指导的人工衍生数据。此外,它允许使用从地球化学到遥感的成熟数据分析技术,从而可以提取出超出通常与严格遥感数据分析相关的有用见解。目前,地球科学中还没有记录从大规模遥感数据中得出化学元素浓度的普遍适用和系统的方法。在本文中,我们证明了融合地质统计学增强的地球化学和遥感数据可以产生丰富的数据,从而实现更通用的基于机器学习的地球化学数据生成。我们使用南非尾矿储存设施(TSF)的黄金品位数据以及陆地卫星-8号和哨兵遥感卫星的数据。我们表明,在训练数据丰富的情况下,可以使用各种机器学习算法。因此,我们能够生成TSF的高分辨率(10米网格大小)黄金浓度图,这表明了我们的方法用于指导开采规划、在线资源勘探、环境监测和资源估计的潜力。
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