A Systematic Review on the Application of Machine Learning in Exploiting Mineralogical Data in Mining and Mineral Industry

Machine learning is a subcategory of artificial intelligence, which aims to make computers capable of solving complex problems without being explicitly programmed. Availability of large datasets, development of effective algorithms, and access to the powerful computers have resulted in the unprecedented success of machine learning in recent years. This powerful tool has been employed in a plethora of science and engineering domains including mining and minerals industry. Considering the ever-increasing global demand for raw materials, complexities of the geological structure of ore deposits, and decreasing ore grade, high-quality and extensive mineralogical information is required. Comprehensive analyses of such invaluable information call for advanced and powerful techniques including machine learning. This paper presents a systematic review of the efforts that have been dedicated to the development of machine learning-based solutions for better utilizing mineralogical data in mining and mineral studies. To that end, we investigate the main reasons behind the superiority of machine learning in the relevant literature, machine learning algorithms that have been deployed, input data, concerned outputs, as well as the general trends in the subject area.

[1]  Matti Lehtonen,et al.  Incorporating the effects of service quality regulation in decision-making framework of distribution companies , 2018 .

[2]  Pablo Coelho,et al.  Automatic near-infrared hyperspectral image analysis of copper concentrates , 2019, IFAC-PapersOnLine.

[3]  Pejman Tahmasebi,et al.  Segmentation of digital rock images using deep convolutional autoencoder networks , 2019, Comput. Geosci..

[4]  M. Cracknell,et al.  Quantitative Mineral Mapping of Drill Core Surfaces II: Long-Wave Infrared Mineral Characterization Using μXRF and Machine Learning , 2021, Economic Geology.

[5]  B. Sørensen,et al.  A neural network approach for spatial variation assessment – A nepheline syenite case study , 2020 .

[6]  J. Rosenkranz,et al.  Automated drill core mineralogical characterization method for texture classification and modal mineralogy estimation for geometallurgy , 2019, Minerals Engineering.

[7]  Reliability incentive regulation based on reward‐penalty mechanism using distribution feeders clustering , 2021 .

[8]  Renguang Zuo,et al.  Mapping Geochemical Anomalies Through Integrating Random Forest and Metric Learning Methods , 2019, Natural Resources Research.

[9]  Saman Taheri,et al.  Long-term planning of integrated local energy systems using deep learning algorithms , 2021, International Journal of Electrical Power & Energy Systems.

[10]  G. Fotopoulos,et al.  Geological Mapping Using Machine Learning Algorithms , 2016 .

[11]  Anne-Laure Boulesteix,et al.  Overview of random forest methodology and practical guidance with emphasis on computational biology and bioinformatics , 2012, WIREs Data Mining Knowl. Discov..

[12]  Matthew J. Cracknell,et al.  Geological mapping using remote sensing data: A comparison of five machine learning algorithms, their response to variations in the spatial distribution of training data and the use of explicit spatial information , 2014, Comput. Geosci..

[13]  Eldad Haber,et al.  Mineral prospectivity mapping using a VNet convolutional neural network , 2021 .

[14]  Matthew J. Cracknell,et al.  Geological Mapping in Western Tasmania Using Radar and Random Forests , 2018, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[15]  Michael I. Jordan,et al.  Machine learning: Trends, perspectives, and prospects , 2015, Science.

[16]  Iosif I. Vaisman,et al.  Machine learning approach for structure-based zeolite classification , 2009 .

[17]  M. Mckee,et al.  International experiences with co-production and people centredness offer lessons for covid-19 responses , 2021, BMJ.

[18]  Qingfeng Guan,et al.  A Multi-Convolutional Autoencoder Approach to Multivariate Geochemical Anomaly Recognition , 2019, Minerals.

[19]  Mahmut Çavur,et al.  Assessment of chromite liberation spectrum on microscopic images by means of a supervised image classification , 2017 .

[20]  Rodrigo A. Lobos,et al.  Variogram-Based Descriptors for Comparison and Classification of Rock Texture Images , 2019, Mathematical Geosciences.

[21]  M. Kubát An Introduction to Machine Learning , 2017, Springer International Publishing.

[22]  Sharif,et al.  A RISK-BASED FRAMEWORK TO OPTIMIZE DISTRIBUTED GENERATION INVESTMENT PLANS CONSIDERING INCENTIVE RELIABILITY REGULATIONS , 2019 .

[23]  Jan Rosenkranz,et al.  Application of machine learning techniques in mineral phase segmentation for X-ray microcomputed tomography (µCT) data , 2019, Minerals Engineering.

[24]  J. C. Ordóñez-Calderón,et al.  Machine learning strategies for classification and prediction of alteration facies: Examples from the Rosemont Cu-Mo-Ag skarn deposit, SE Tucson Arizona , 2018, Journal of Geochemical Exploration.

[25]  Fionn Murtagh,et al.  Algorithms for hierarchical clustering: an overview , 2012, WIREs Data Mining Knowl. Discov..

[26]  Mahdi Khodadadzadeh,et al.  Drill-Core Mineral Abundance Estimation Using Hyperspectral and High-Resolution Mineralogical Data , 2020, Remote. Sens..

[27]  Julio Cesar Alvarez Iglesias,et al.  Deep learning discrimination of quartz and resin in optical microscopy images of minerals , 2019, Minerals Engineering.

[28]  M. Fotuhi‐Firuzabad,et al.  Designing a new procedure for reward and penalty scheme in performance-based regulation of electricity distribution companies , 2018, International Transactions on Electrical Energy Systems.

[29]  M. Khodadadzadeh,et al.  MULTI-LABEL CLASSIFICATION FOR DRILL-CORE HYPERSPECTRAL MINERAL MAPPING , 2020 .

[30]  W. Kracht,et al.  Machine Learning and Deep Learning Methods in Mining Operations: a Data-Driven SAG Mill Energy Consumption Prediction Application , 2020, Mining, Metallurgy & Exploration.

[31]  PRISMA 2020 explanation and elaboration: updated guidance and exemplars for reporting systematic reviews , 2021, BMJ.

[32]  Pedram Ghamisi,et al.  A Machine Learning Framework for Drill-Core Mineral Mapping Using Hyperspectral and High-Resolution Mineralogical Data Fusion , 2019, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[33]  R. Zuo Machine Learning of Mineralization-Related Geochemical Anomalies: A Review of Potential Methods , 2017, Natural Resources Research.

[34]  Pratama Istiadi Guntoro,et al.  Textural Quantification and Classification of Drill Cores for Geometallurgy: Moving Toward 3D with X-ray Microcomputed Tomography (µCT) , 2020, Natural Resources Research.

[35]  C. L. Lin,et al.  Improved 3D image segmentation for X-ray tomographic analysis of packed particle beds , 2015 .

[36]  K. Hattori,et al.  A multivariate statistical approach identifying the areas underlain by potential porphyry-style Cu mineralization, south-central British Columbia, Canada , 2019, Journal of Geochemical Exploration.

[37]  Keng Siau,et al.  Artificial Intelligence, Machine Learning, and Autonomous Technologies in Mining Industry , 2019, J. Database Manag..

[38]  Radial basis function link nets method for predicting gold mineral potential from geological and geophysical data in the Swayze greenstone belt (SGB) , 2018 .

[39]  O. Gomes,et al.  Classification of hematite types in iron ores through circularly polarized light microscopy and image analysis , 2013 .

[40]  Richard J. Murphy,et al.  Evaluating the performance of a new classifier – the GP-OAD: A comparison with existing methods for classifying rock type and mineralogy from hyperspectral imagery , 2014 .

[41]  M. Buxton,et al.  Performance Improvements during Mineral Processing Using Material Fingerprints Derived from Machine Learning—A Conceptual Framework , 2020 .

[42]  E. Grunsky,et al.  Identification of sandstones above blind uranium deposits using multivariate statistical assessment of compositional data, Athabasca Basin, Canada , 2018 .

[43]  Mohcine Chakouri Geological and Mineralogical mapping in Moroccan central Jebilet using multispectral and hyperspectral satellite data and Machine Learning , 2020 .

[44]  M. Cracknell,et al.  Linking protolith rocks to altered equivalents by combining unsupervised and supervised machine learning , 2018 .

[45]  J. Rao,et al.  Indicator element selection and geochemical anomaly mapping using recursive feature elimination and random forest methods in the Jingdezhen region of Jiangxi Province, South China , 2020 .

[46]  Yongzhang Zhou,et al.  Identification of multi-element geochemical anomalies using unsupervised machine learning algorithms: A case study from Ag–Pb–Zn deposits in north-western Zhejiang, China , 2020 .

[47]  Bijan Roshanravan,et al.  Translating a mineral systems model into continuous and data-driven targeting models: An example from the Dolatabad chromite district, southeastern Iran , 2020 .

[48]  Samuel Frimpong,et al.  Artificial intelligence, machine learning and process automation: existing knowledge frontier and way forward for mining sector , 2020, Artificial Intelligence Review.

[49]  Carlos Roberto de Souza Filho,et al.  Artificial neural networks applied to mineral potential mapping for copper‐gold mineralizations in the Carajás Mineral Province, Brazil , 2009 .

[50]  Ravi Kiran Inapakurthi,et al.  Recurrent neural networks based modelling of industrial grinding operation , 2020, Chemical Engineering Science.

[51]  Virginia C. Gulick,et al.  An automated mineral classifier using Raman spectra , 2013, Comput. Geosci..

[52]  V. Rodriguez-Galiano,et al.  Machine learning predictive models for mineral prospectivity: an evaluation of neural networks, random forest, regression trees and support vector machines , 2015 .

[53]  Li Deng,et al.  Artificial Intelligence in the Rising Wave of Deep Learning: The Historical Path and Future Outlook [Perspectives] , 2018, IEEE Signal Processing Magazine.

[54]  R. Zuo,et al.  Recognition of geochemical anomalies using a deep variational autoencoder network , 2020 .

[55]  Moein Moeini-Aghtaie,et al.  Joint Expansion Planning Studies of EV Parking Lots Placement and Distribution Network , 2020, IEEE Transactions on Industrial Informatics.

[56]  Wolfram Rühaak,et al.  Processing of rock core microtomography images: Using seven different machine learning algorithms , 2016, Comput. Geosci..

[57]  Yosoon Choi,et al.  Systematic Review of Machine Learning Applications in Mining: Exploration, Exploitation, and Reclamation , 2021, Minerals.

[58]  Akshi Kumar,et al.  Machine Learning from Theory to Algorithms: An Overview , 2018, Journal of Physics: Conference Series.

[59]  A. Tessema,et al.  Support vector machine and artificial neural network modelling of orogenic gold prospectivity mapping in the Swayze greenstone belt, Ontario, Canada , 2021 .

[60]  Eric Pirard,et al.  Mineral recognition of single particles in ore slurry samples by means of multispectral image processing , 2019, Minerals Engineering.

[61]  Shai Ben-David,et al.  Understanding Machine Learning: From Theory to Algorithms , 2014 .

[62]  Manuel Graña,et al.  Blurred Labeling Segmentation Algorithm for Hyperspectral Images , 2015, ICCCI.

[63]  M. Jessell,et al.  Automated regolith landform mapping using airborne geophysics and remote sensing data, Burkina Faso, West Africa , 2018 .

[64]  He Li,et al.  Convolutional neural network and transfer learning based mineral prospectivity modeling for geochemical exploration of Au mineralization within the Guandian–Zhangbaling area, Anhui Province, China , 2020 .

[65]  Clark Glymour,et al.  Automated Remote Sensing with Near Infrared Reflectance Spectra: Carbonate Recognition , 2002, Data Mining and Knowledge Discovery.

[66]  D.M. Mount,et al.  An Efficient k-Means Clustering Algorithm: Analysis and Implementation , 2002, IEEE Trans. Pattern Anal. Mach. Intell..

[67]  B. Kjarsgaard,et al.  Rapid geochemical imaging of rocks and minerals with handheld laser induced breakdown spectroscopy (LIBS) , 2020 .

[68]  Renguang Zuo,et al.  Recognizing multivariate geochemical anomalies for mineral exploration by combining deep learning and one-class support vector machine , 2020, Comput. Geosci..

[69]  Mahdi Khodadadzadeh,et al.  Multi-Sensor Spectral Imaging of Geological Samples: A Data Fusion Approach Using Spatio-Spectral Feature Extraction , 2019, Sensors.

[70]  Charles L. Bérubé,et al.  Predicting rock type and detecting hydrothermal alteration using machine learning and petrophysical properties of the Canadian Malartic ore and host rocks, Pontiac Subprovince, Québec, Canada , 2018 .

[71]  Ashis Pradhan,et al.  SUPPORT VECTOR MACHINE-A Survey , 2012 .

[72]  Greg Smith,et al.  Association Between Imaging and XRF Sensing: A Machine Learning Approach to Discover Mineralogy in Abandoned Mine Voids , 2016, IEEE Sensors Journal.

[73]  Jacinto Mata,et al.  Application of classification trees for improving optical identification of common opaque minerals , 2020, Comput. Geosci..

[74]  Guigang Zhang,et al.  Deep Learning , 2016, Int. J. Semantic Comput..

[75]  M. Fotuhi-Firuzabad,et al.  A new reward-penalty mechanism for distribution companies based on concept of competition , 2014, IEEE PES Innovative Smart Grid Technologies, Europe.

[76]  Mahdi Khodadadzadeh,et al.  Drill-Core Hyperspectral and Geochemical Data Integration in a Superpixel-Based Machine Learning Framework , 2020, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[77]  Ciarán M Lee,et al.  Improving the accuracy of medical diagnosis with causal machine learning , 2020, Nature Communications.

[78]  Renguang Zuo,et al.  Mapping geochemical anomalies related to Fe–polymetallic mineralization using the maximum margin metric learning method , 2019, Ore Geology Reviews.

[79]  R. Zuo,et al.  Big Data Analytics of Identifying Geochemical Anomalies Supported by Machine Learning Methods , 2017, Natural Resources Research.

[80]  A. Harti,et al.  Assessment of the image-based atmospheric correction of multispectral satellite images for geological mapping in arid and semi-arid regions , 2020 .

[81]  Renguang Zuo,et al.  Recognition of geochemical anomalies using a deep autoencoder network , 2016, Comput. Geosci..