Quantitative Inversion Modeling Method for Grading Deerni Copper Deposits Based on Visible and Near-Infrared Hyperspectral Data

IF 2 4区地球科学 Q3 REMOTE SENSING

Canadian Journal of Remote Sensing Pub Date : 2022-04-21 DOI:10.1080/07038992.2022.2059755

Jingli Wang, Jingxiang Gao, Jiaqi Huang, Qinghui Qi, Xinqi Mao, Wang Cao, Ruibo Ding, Yachun Mao

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引用次数: 4

Abstract

Abstract Quantitative metal grade inversion based on hyperspectral data is an effective approach to achieve the real-time in situ determination of ore body grades and has the advantages of low cost compared with traditional chemical analysis methods. However, the redundant nature of hyperspectral data and the parameter-limiting nature of machine learning algorithms reduce the modeling accuracy and precision, resulting in severe limitations on the application of hyperspectral techniques for the grade inversion of Deerni copper ore bodies. In this paper, we first obtained visible-NIR hyperspectral data for 190 ore samples using a spectrometer and determined the copper content of the sample set using chemical analysis; then, we processed the raw hyperspectral data using three dimensionality reduction algorithms and optimized a BP neural network based on an evolutionary algorithm. Finally, a Deerni copper grade inversion model was established using the hyperspectral data before and after dimensionality reduction, and the inversion accuracy and precision was compared and analyzed with that obtained by the BP neural network, the random forest and the variable hidden layer nodes models. The combination of the LLE dimensionality reduction algorithm and the optimized BP neural network algorithm achieves the highest modeling precision, with an R 2 of 0.950.

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基于可见光和近红外高光谱数据的Deerni铜矿分级定量反演建模方法

基于高光谱数据的金属品位定量反演是实现矿体品位实时就地测定的有效途径，与传统化学分析方法相比具有成本低的优点。然而，高光谱数据的冗余性和机器学习算法的参数限制特性降低了建模的精度和精度，严重限制了高光谱技术在Deerni铜矿体品位反演中的应用。在本文中，我们首先使用光谱仪获得了190个矿石样品的可见-近红外高光谱数据，并使用化学分析确定了样品组的铜含量;然后，采用三维降维算法对原始高光谱数据进行处理，并基于进化算法对BP神经网络进行优化。最后，利用降维前后的高光谱数据建立了Deerni铜品位反演模型，并与BP神经网络、随机森林和变隐层节点模型的反演精度和精度进行了对比分析。LLE降维算法与优化后的BP神经网络算法组合建模精度最高，r2为0.950。

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来源期刊

Canadian Journal of Remote Sensing REMOTE SENSING-

自引率

3.80%

发文量

期刊介绍： Canadian Journal of Remote Sensing / Journal canadien de télédétection is a publication of the Canadian Aeronautics and Space Institute (CASI) and the official journal of the Canadian Remote Sensing Society (CRSS-SCT). Canadian Journal of Remote Sensing provides a forum for the publication of scientific research and review articles. The journal publishes topics including sensor and algorithm development, image processing techniques and advances focused on a wide range of remote sensing applications including, but not restricted to; forestry and agriculture, ecology, hydrology and water resources, oceans and ice, geology, urban, atmosphere, and environmental science. Articles can cover local to global scales and can be directly relevant to the Canadian, or equally important, the international community. The international editorial board provides expertise in a wide range of remote sensing theory and applications.