Estimating UCS of South China sandstones using mineralogical and machine learning approaches

IF 4.1 3区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Physics and Chemistry of the Earth Pub Date : 2025-08-14 DOI:10.1016/j.pce.2025.104048

Jin Lu , Xiaofan Liao , Ahmad Rastegarnia , Jafar Qajar

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Abstract

Slope stability analysis, rock mass classification, and foundation modeling necessitate measuring rocks' uniaxial compressive strength (UCS). Direct measurement is costly and time-consuming, prompting researchers to seek indirect methods. This research aimed to predict the UCS of sandstone samples using the quartz ratio and index properties. Models—including Feed-Forward Artificial Neural Network (FANN), Adaptive Neuro-Fuzzy Inference System (ANFIS), Support Vector Regression (SVR), K-Nearest Neighbor (KNN), and Multivariate Linear Regression (MLR)—were tested with varying input quantities and evaluated using Taylor's diagram, error level, A20 index, agreement index, and Calculated Performance Index (CPI). Petrography classified the sandstones as arenite, litharenite, and feldspathic litharenite; based on the results, the latter showed higher UCS, and fracture modes shifted from axial to multiple types as strength increased. Modeling revealed that KNN and FANN performance varied with distance metrics and training algorithms. Increasing inputs improved KNN and MLR accuracy but reduced SVR, ANFIS, and FANN accuracy. Additionally, the MLR's sensitivity to changes in inputs was greater than that of other methods. Comparing modeling results showed that the SVR based on the radial basis function with, CPI of 1.98, mean absolute percentage error of 0.75, A20 index of 1.00, and agreement index of 1.00, displayed the highest performance in UCS prediction.

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利用矿物学和机器学习方法估算华南砂岩的UCS

边坡稳定性分析、岩体分类和地基建模都需要测量岩石的单轴抗压强度（UCS）。直接测量既昂贵又耗时，促使研究人员寻求间接方法。本研究的目的是利用石英比和指数性质预测砂岩样品的UCS。模型——包括前馈人工神经网络（FANN）、自适应神经模糊推理系统（ANFIS）、支持向量回归（SVR）、k近邻（KNN）和多元线性回归（MLR）——在不同的输入量下进行测试，并使用泰勒图、误差水平、A20指数、协议指数和计算性能指数（CPI）进行评估。岩石学将砂岩分为砂屑岩、岩屑岩和长石岩屑岩；结果表明，随着强度的增加，后者具有较高的UCS，且断裂模式由轴向向多类型转变。建模表明，KNN和FANN的性能随距离度量和训练算法的不同而变化。增加输入提高了KNN和MLR的精度，但降低了SVR、ANFIS和FANN的精度。此外，MLR对输入变化的敏感性高于其他方法。对比建模结果表明，基于径向基函数的SVR在UCS预测中表现最好，CPI为1.98，平均绝对百分比误差为0.75，A20指数为1.00，一致性指数为1.00。

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来源期刊

Physics and Chemistry of the Earth 地学-地球科学综合

CiteScore

5.40

自引率

2.70%

发文量

176

审稿时长

31.6 weeks

期刊介绍： Physics and Chemistry of the Earth is an international interdisciplinary journal for the rapid publication of collections of refereed communications in separate thematic issues, either stemming from scientific meetings, or, especially compiled for the occasion. There is no restriction on the length of articles published in the journal. Physics and Chemistry of the Earth incorporates the separate Parts A, B and C which existed until the end of 2001. Please note: the Editors are unable to consider submissions that are not invited or linked to a thematic issue. Please do not submit unsolicited papers. The journal covers the following subject areas: -Solid Earth and Geodesy: (geology, geochemistry, tectonophysics, seismology, volcanology, palaeomagnetism and rock magnetism, electromagnetism and potential fields, marine and environmental geosciences as well as geodesy). -Hydrology, Oceans and Atmosphere: (hydrology and water resources research, engineering and management, oceanography and oceanic chemistry, shelf, sea, lake and river sciences, meteorology and atmospheric sciences incl. chemistry as well as climatology and glaciology). -Solar-Terrestrial and Planetary Science: (solar, heliospheric and solar-planetary sciences, geology, geophysics and atmospheric sciences of planets, satellites and small bodies as well as cosmochemistry and exobiology).