A hybrid framework for modelling domains using quantitative covariates

IF 2.6 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Yerniyaz Abildin , Chaoshui Xu , Peter Dowd , Amir Adeli
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引用次数: 2

Abstract

Domains define the boundaries of mineralisation zones, within which the grade distribution of the target minerals can be quantified via an established mineral resource estimation procedure. Available domain modelling techniques include manual interpretation, implicit modelling and advanced geostatistical approaches. In mining applications, the most commonly used method is manual domaining, which is labour-intensive and prone to subjective judgement errors. In addition, the output is largely deterministic and ignores the significant uncertainty associated with the domain interpretation and boundary definitions. There is, therefore, a need for a more objective framework that can automatically define mineral domains and quantify the associated uncertainty. This paper describes such a framework, which consists of a hybrid approach based on simulated grade distributions and a machine learning (ML) classification technique, XGBoost, trained on lithological properties. Data from an Iron Oxide Copper Gold (IOCG) deposit are used as a case study to demonstrate the application of the proposed method. The study shows that the approach can handle complex multi-class problems with imbalanced features, and it can quantify the uncertainty of domain boundaries. A noise filtering method is used as a pre-processing step to improve the performance of the ML classification, especially in the case of problematic classes where domain boundaries are difficult to predict due to the similarity in geological characteristics.

使用定量协变量建模域的混合框架
区域定义了矿化带的边界,在这个边界内,目标矿物的品位分布可以通过既定的矿产资源估计程序进行量化。可用的领域建模技术包括人工解释、隐式建模和先进的地质统计学方法。在采矿应用中,最常用的方法是人工定域,这是一种劳动密集型的方法,容易产生主观判断错误。此外,输出在很大程度上是确定性的,忽略了与领域解释和边界定义相关的重要不确定性。因此,需要一个更客观的框架,能够自动确定矿物领域和量化相关的不确定性。本文描述了这样一个框架,该框架由基于模拟品位分布的混合方法和基于岩性特性训练的机器学习(ML)分类技术XGBoost组成。以氧化铁铜金(IOCG)矿床的数据为例,验证了该方法的应用。研究表明,该方法可以处理具有不平衡特征的复杂多类问题,并能量化领域边界的不确定性。使用噪声滤波方法作为预处理步骤来提高ML分类的性能,特别是在由于地质特征相似而难以预测领域边界的问题类的情况下。
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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来源期刊
Applied Computing and Geosciences
Applied Computing and Geosciences Computer Science-General Computer Science
CiteScore
5.50
自引率
0.00%
发文量
23
审稿时长
5 weeks
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