A combined prediction method for reducing prediction uncertainty in the quantitative mineral resources prediction

doi:10.13745/j.esf.sf.2021.1.6

Abstract

Abstract:

Mineralization is a complex physical and chemical process. In the quantitive prediction and evaluation of mineral resources, prediction uncertainties are common in the final predication results due to geologic factors, improper data collection and processing, use of empirical parameters, etc. On the basis of recognizing the sources of uncertainty, uncertainty reduction becomes a major research direction in mineral prospecting. A combined metallogenic prediction method using the forward inverse technique has proven to be an effective solution for reducing uncertainties in the geological anomaly analysis. The combined method is composed of numerical simulation of metallogenic processes based on the genetic model of deposit, and model-driven prediction and evaluation technique based on prospecting model and data. As the combined method takes into account both mineralization processes and model-driven prediction/evaluation in the geo-anomaly analysis, it reduces multiple interpretations of a single metallogenic information therefore reducing prediction uncertainty. In its core contents of analyzing metallogenic patterns and establishing prospecting models, the combined method, mainly using spatial database and geostatistics and GIS analysis techniques as well as 3D geological model building, performs weight of evidence analysis and information value evaluation of the distribution of geological variables to investigate its influence on the prediction result. The aim is to build a “3D cube prediction model” for quantitive prediction, fulfilling the goal of Location, Quantity, Probability quantification in blind orebody prospecting. In conclusion, the combined prediction method, as an important basis for delineating the “5P” prospecting areas, was born by innovatively combining two prediction methods that have complementary predictive functions and values. By doing so, a complete forward inverse combined prediction scheme is realized. We show by example that the combined method can improve accuracy and reduce uncertainties in the quantitative prediction and evaluation of mineral resources, which helps to promote the transformation of geoscience research from qualitative to quantitative.

Key words: geological anomalies, quantitative prediction, uncertainty, combined prediction

CLC Number:

P624
P628.3

KONG Weihao, XIAO Keyan, CHEN Jianping, SUN Li, LI Nan. A combined prediction method for reducing prediction uncertainty in the quantitative mineral resources prediction[J]. Earth Science Frontiers, 2021, 28(3): 128-138.

Figures/Tables 14

Fig.1 Basic workflow chart for numerical simulation of hydrothermal mineralization. Adapted from [42].

Fig.2 Basic workflow chart for mineral prospecting using the “cube prediction model”. Adapted from [59].

Fig.3 A 3D geological model. Modified after [12].

Fig.4 A 3D numerical model. Modified after [12].

Fig.5 Pore pressure (PP) distribution diagram (2D section) for the initial state (left) and after 9×109 s simulation (right). Modified after [12].

Fig.6 Volumetric strain rate (VSR) distribution diagram (2D section) for the initial state (left) and after 9×109 s simulation (right). Modified after [12].

Fig.7 Favorable ore-forming area delineated by PP. Modified after [12].

Fig.8 Favorable ore-forming area delineated by VSR. Modified after [12].

Fig.9 Favorable ore-forming area delineated by both PP and VSR. Modified after [12].

Table 1 List of variables in the comprehensive prediction model

控矿要素	成矿预测因子	特征变量	特征值
地层	有利地层信息	有利成矿地层	大理岩地层
构造	构造展布特征分析	主干断裂分析	(0.084,0.102)
	构造展布特征分析	局部断裂分析	(0.01,63.34)
	构造对称特征	构造中心对称度	(0.01,1.0)
	断裂影响范围	断裂影响范围	断裂缓冲区
夕卡岩	成矿有利蚀变岩体	成矿有利蚀变岩体	夕卡岩
岩体	岩浆热液活动标志	岩体推断区域	花岗闪长岩体

Fig.10 Favorable ore-forming block with posterior probability threshold greater ≥0.77 (green) or ≥0.91 (red) by weight of evidence method. Modified after [12].

Fig.11 Favorable ore-forming block with information value threshold ≥1.6 (green) or ≥3.2 (red). Modified after [12].

Fig.12 Favorable ore-forming area delineated by both posterior probability and information value thresholds. Modified after [12].

Fig.13 Favorable ore-forming (red) and target (purple) areas predicted by the combined prediction method. Modified after [12].

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