Estimating PM10 Concentration from Drilling Operations in Open-Pit Mines Using an Assembly of SVR and PSO

Dust is one of the components causing heavy environmental pollution in open-pit mines, especially PM10. Some pathologies related to the lung, respiratory system, and occupational diseases have been identified due to the effects of PM10 in open-pit mines. Therefore, the prediction and control of PM10 concentration in the production process are necessary for environmental and health protection. In this study, PM10 concentration from drilling operations in the Coc Sau open-pit coal mine (Vietnam) was investigated and considered through a database including 245 datasets collected. A novel hybrid artificial intelligence model was developed based on support vector regression (SVR) and a swarm optimization algorithm (i.e., particle swarm optimization (PSO)), namely PSO-SVR, for estimating PM10 concentration from drilling operations at the mine. Polynomial (P), radial basis function (RBF), and linear (L) kernel functions were considered and applied to the development of the PSO-SVR models in the present study, abbreviated as PSO-SVR-P, PSO-SVR-RBF, and PSO-SVR-L. Also, three benchmark artificial intelligence techniques, such as k-nearest neighbors (KNN), random forest (RF), and classification and regression trees (CART), were applied and developed for estimating PM10 concentration and then compared with the PSO-SVR models. Root-mean-squared error (RMSE) and determination coefficient (R2) were used as the statistical criteria for evaluating the performance of the developed models. The results exhibited that the PSO algorithm had an essential role in the optimization of the hyper-parameters of the SVR models. The PSO-SVR models (i.e., PSO-SVR-L, PSO-SVR-P, and PSO-SVR-RBF) had higher performance levels than the other models (i.e., RF, CART, and KNN) with an RMSE of 0.040, 0.042, and 0.043; and R2 of 0.954, 0.948, and 0.946; for the PSO-SVR-L, PSO-SVR-P, and PSO-SVR-RBF models, respectively. Of these PSO-SVR models, the PSO-SVR-L model was the most dominant model with an RMSE of 0.040 and R2 of 0.954. The remaining three benchmark models (i.e., RF, CART, and KNN) yielded a more unsatisfactory performance with an RMSE of 0.060, 0.052, and 0.067; and R2 of 0.894, 0.924, and 0.867, for the RF, CART, and KNN models, respectively. Furthermore, the findings of this study demonstrated that the density of rock mass, moisture content, and the penetration rate of the drill were essential parameters on the PM10 concentration caused by drilling operations in open-pit mines.

[1]  Sébastien Da Veiga,et al.  Global sensitivity analysis with dependence measures , 2013, ArXiv.

[2]  Davor Z Antanasijević,et al.  PM(10) emission forecasting using artificial neural networks and genetic algorithm input variable optimization. , 2013, The Science of the total environment.

[3]  Hoang Nguyen,et al.  A Novel Artificial Intelligence Approach to Predict Blast-Induced Ground Vibration in Open-Pit Mines Based on the Firefly Algorithm and Artificial Neural Network , 2019, Natural Resources Research.

[4]  Bernhard Schölkopf,et al.  A tutorial on support vector regression , 2004, Stat. Comput..

[5]  Robin L. Dennis,et al.  Development of an Aggregation and Episode Selection Scheme to Support the Models-3 Community Multiscale Air Quality Model , 2001 .

[6]  Richard A. Olshen,et al.  CART: Classification and Regression Trees , 1984 .

[7]  X. Bui,et al.  Developing an XGBoost model to predict blast-induced peak particle velocity in an open-pit mine: a case study , 2019, Acta Geophysica.

[8]  Liborio Cavaleri,et al.  Krill herd algorithm-based neural network in structural seismic reliability evaluation , 2019 .

[9]  Dayana Agudelo-Castañeda,et al.  Cytogenetic instability in populations with residential proximity to open-pit coal mine in Northern Colombia in relation to PM10 and PM2.5 levels. , 2018, Ecotoxicology and environmental safety.

[10]  Bindhu Lal,et al.  Prediction of dust concentration in open cast coal mine using artificial neural network , 2012 .

[11]  Aditya Kumar Patra,et al.  Prediction of particulate matter concentration profile in an opencast copper mine in India using an artificial neural network model , 2016, Air Quality, Atmosphere & Health.

[12]  A. Wardoyo,et al.  Measurements of PM2.5 motor emission concentrations and the lung damages from the exposure mice , 2016, 2016 International Seminar on Sensors, Instrumentation, Measurement and Metrology (ISSIMM).

[13]  Aminaton Marto,et al.  Prediction of blast-induced air overpressure: a hybrid AI-based predictive model , 2015, Environmental Monitoring and Assessment.

[14]  Hoang Nguyen,et al.  Prediction of Blast-induced Air Over-pressure in Open-Pit Mine: Assessment of Different Artificial Intelligence Techniques , 2019, Natural Resources Research.

[15]  Martha Cobo,et al.  Discovering relationships and forecasting PM10 and PM2.5 concentrations in Bogotá, Colombia, using Artificial Neural Networks, Principal Component Analysis, and k-means clustering , 2018, Atmospheric Pollution Research.

[16]  Sébastien Da Veiga Global sensitivity analysis with dependence measures , 2015 .

[17]  Norhashidah Awang,et al.  Multiple linear regression and regression with time series error models in forecasting PM10 concentrations in Peninsular Malaysia , 2018, Environmental Monitoring and Assessment.

[18]  Bulent Tiryaki,et al.  Predicting intact rock strength for mechanical excavation using multivariate statistics, artificial neural networks, and regression trees , 2008 .

[19]  R. Lawrence Rule-Based Classification Systems Using Classification and Regression Tree (CART) Analysis , 2001 .

[20]  Hoang Nguyen,et al.  A new soft computing model for estimating and controlling blast-produced ground vibration based on Hierarchical K-means clustering and Cubist algorithms , 2019, Appl. Soft Comput..

[21]  S. K. Chaulya Air Quality Status of an Open Pit Mining Area in India , 2005, Environmental monitoring and assessment.

[22]  P. Goyal,et al.  Artificial intelligence based approach to forecast PM2.5 during haze episodes: A case study of Delhi, India , 2015 .

[23]  Walter L. Ruzzo,et al.  A Regression-based K nearest neighbor algorithm for gene function prediction from heterogeneous data , 2006, BMC Bioinformatics.

[24]  K. Pericleous,et al.  Modelling air quality in street canyons : a review , 2003 .

[25]  Simon Albert,et al.  Environmental change in a modified catchment downstream of a gold mine, Solomon Islands. , 2017, Environmental pollution.

[26]  Hui Chen,et al.  Assessing Dynamic Conditions of the Retaining Wall: Developing Two Hybrid Intelligent Models , 2019, Applied Sciences.

[27]  L. Serra,et al.  Variability of PM10 in industrialized-urban areas. New coefficients to establish significant differences between sampling points. , 2018, Environmental pollution.

[28]  R. Eberhart,et al.  Comparing inertia weights and constriction factors in particle swarm optimization , 2000, Proceedings of the 2000 Congress on Evolutionary Computation. CEC00 (Cat. No.00TH8512).

[29]  Wei-Yin Loh,et al.  Classification and regression trees , 2011, WIREs Data Mining Knowl. Discov..

[30]  Ian D. Williams,et al.  Characterisation of Particulate Matter Sampled during a Study of Children's Personal Exposure to Airborne Particulate Matter in a UK Urban Environment , 2000 .

[31]  S. K. Chaulya Assessment and management of air quality for an opencast coal mining area. , 2004, Journal of environmental management.

[32]  Garimella Raghu Chandra,et al.  Development of empirical model to predict particulate matter , 2018 .

[33]  P. Pokorná,et al.  Impact of Mining Activities on the Air Quality in The Village Nearby a Coal Strip Mine , 2016 .

[34]  P. G. Asteris,et al.  Modeling of masonry failure surface under biaxial compressive stress using Neural Networks , 2014 .

[35]  Hossam Faris,et al.  Prediction of PM10 and TSP Air Pollution Parameters Using Artificial Neural Network Autoregressive, External Input Models: A Case Study in Salt, Jordan , 2013 .

[36]  Hoang Nguyen,et al.  Proposing a novel predictive technique using M5Rules-PSO model estimating cooling load in energy-efficient building system , 2019, Engineering with Computers.

[37]  Atac Bascetin,et al.  A decision support system using analytical hierarchy process (AHP) for the optimal environmental reclamation of an open-pit mine , 2007 .

[38]  Loke Kok Foong,et al.  Optimizing ANN models with PSO for predicting short building seismic response , 2019, Engineering with Computers.

[39]  Andy Liaw,et al.  Classification and Regression by randomForest , 2007 .

[40]  Ian G. McKendry,et al.  Evaluation of Artificial Neural Networks for Fine Particulate Pollution (PM10 and PM2.5) Forecasting , 2002, Journal of the Air & Waste Management Association.

[41]  Piero Toscano,et al.  Forecasting PM10 hourly concentrations in northern Italy: Insights on models performance and PM10 drivers through self-organizing maps , 2018, Atmospheric Pollution Research.

[42]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[43]  Panagiotis G. Asteris,et al.  Anisotropic masonry failure criterion using artificial neural networks , 2017, Neural Computing and Applications.

[44]  Masoud Monjezi,et al.  Forecasting blast-induced ground vibration developing a CART model , 2017, Engineering with Computers.

[45]  Luis Felipe Gonzalez,et al.  A Methodology to Monitor Airborne PM10 Dust Particles Using a Small Unmanned Aerial Vehicle , 2017, Sensors.

[46]  X. Bui,et al.  Predicting Blast-Induced Air Overpressure: A Robust Artificial Intelligence System Based on Artificial Neural Networks and Random Forest , 2018, Natural Resources Research.

[47]  Pasi Liljeberg,et al.  Energy Aware Consolidation Algorithm Based on K-Nearest Neighbor Regression for Cloud Data Centers , 2013, 2013 IEEE/ACM 6th International Conference on Utility and Cloud Computing.

[48]  Robert P. Sheridan,et al.  Random Forest: A Classification and Regression Tool for Compound Classification and QSAR Modeling , 2003, J. Chem. Inf. Comput. Sci..

[49]  Mrinal K Ghose,et al.  Generation and Quantification of Hazardous Dusts from Coal Mining in the Indian Context , 2007, Environmental monitoring and assessment.

[50]  D G Gajghate,et al.  Prediction of Ambient PM10 and Toxic Metals Using Artificial Neural Networks , 2002, Journal of the Air & Waste Management Association.

[51]  Panagiotis G. Asteris,et al.  Prediction of self-compacting concrete strength using artificial neural networks , 2016 .

[52]  Masoud Monjezi,et al.  Feasibility of indirect determination of blast induced ground vibration based on support vector machine , 2015 .

[53]  Aminaton Marto,et al.  Neuro-fuzzy technique to predict air-overpressure induced by blasting , 2015, Arabian Journal of Geosciences.

[54]  J. Huertas,et al.  Air quality impact assessment of multiple open pit coal mines in northern Colombia. , 2012, Journal of Environmental Management.

[55]  Wsd Wong,et al.  Statistical Analysis of Geographic Information with ArcView GIS And ArcGIS , 2005 .

[56]  Weiwei Lin,et al.  An Ensemble Random Forest Algorithm for Insurance Big Data Analysis , 2017, IEEE Access.

[57]  Bernhard Schölkopf,et al.  Measuring Statistical Dependence with Hilbert-Schmidt Norms , 2005, ALT.

[58]  Hoang Nguyen,et al.  A comparative study of artificial neural networks in predicting blast-induced air-blast overpressure at Deo Nai open-pit coal mine, Vietnam , 2018, Neural Computing and Applications.

[59]  Xuan-Nam Bui,et al.  Novel Soft Computing Model for Predicting Blast-Induced Ground Vibration in Open-Pit Mines Based on Particle Swarm Optimization and XGBoost , 2019, Natural Resources Research.

[60]  Timothy C. Au Random Forests, Decision Trees, and Categorical Predictors: The "Absent Levels" Problem , 2017, J. Mach. Learn. Res..

[61]  Piotr Duda,et al.  The CART decision tree for mining data streams , 2014, Inf. Sci..

[62]  Ari Karppinen,et al.  Evaluation of a multiple regression model for the forecasting of the concentrations of NOx and PM10 in Athens and Helsinki. , 2011, The Science of the total environment.

[63]  Arvinder Kaur,et al.  A Comprehensive Comparison of Ant Colony and Hybrid Particle Swarm Optimization Algorithms Through Test Case Selection , 2018 .

[64]  Vladimir Vapnik,et al.  Three remarks on the support vector method of function estimation , 1999 .

[65]  Maurice Clerc,et al.  The particle swarm - explosion, stability, and convergence in a multidimensional complex space , 2002, IEEE Trans. Evol. Comput..

[66]  Liborio Cavaleri,et al.  Prediction of the Fundamental Period of Infilled RC Frame Structures Using Artificial Neural Networks , 2015, Comput. Intell. Neurosci..

[67]  Panagiotis G. Asteris,et al.  Feed-Forward Neural Network Prediction of the Mechanical Properties of Sandcrete Materials , 2017, Sensors.

[68]  James Kennedy,et al.  The Behavior of Particles , 1998, Evolutionary Programming.

[69]  Russell C. Eberhart,et al.  A new optimizer using particle swarm theory , 1995, MHS'95. Proceedings of the Sixth International Symposium on Micro Machine and Human Science.

[70]  G. De’ath,et al.  CLASSIFICATION AND REGRESSION TREES: A POWERFUL YET SIMPLE TECHNIQUE FOR ECOLOGICAL DATA ANALYSIS , 2000 .

[71]  S. Vincenzi,et al.  Application of a Random Forest algorithm to predict spatial distribution of the potential yield of Ruditapes philippinarum in the Venice lagoon, Italy , 2011 .

[72]  Puqiang Zhang,et al.  Data-driven method based on particle swarm optimization and k-nearest neighbor regression for estimating capacity of lithium-ion battery , 2014 .

[73]  M. R. Moghaddam,et al.  Application of two intelligent systems in predicting environmental impacts of quarry blasting , 2015, Arabian Journal of Geosciences.

[74]  Chang‐Hoi Ho,et al.  Evaluating the predictability of PM10 grades in Seoul, Korea using a neural network model based on synoptic patterns. , 2016, Environmental pollution.

[75]  Aditya Kumar Patra,et al.  Opencast mines: a subject to major concern for human health , 2012 .

[76]  P Hyde,et al.  Forecasting PM10 in metropolitan areas: Efficacy of neural networks. , 2012, Environmental pollution.

[77]  Cardona Alzate,et al.  Predicción y selección de variables con bosques aleatorios en presencia de variables correlacionadas , 2020 .

[78]  Yan Zhang,et al.  Estimating ground-level PM(10) in a Chinese city by combining satellite data, meteorological information and a land use regression model. , 2016, Environmental pollution.

[79]  S. K. Chaulya,et al.  Determination of the emission rate from various opencast mining operations , 2002, Environ. Model. Softw..

[80]  Hoang Nguyen Support vector regression approach with different kernel functions for predicting blast-induced ground vibration: a case study in an open-pit coal mine of Vietnam , 2019, SN Applied Sciences.

[81]  Paula Alvarenga,et al.  A contribution towards the risk assessment of soils from the São Domingos Mine (Portugal): chemical, microbial and ecotoxicological indicators. , 2012, Environmental pollution.

[82]  Athanasios Migdalas,et al.  A hybrid Particle Swarm Optimization - Variable Neighborhood Search algorithm for Constrained Shortest Path problems , 2017, Eur. J. Oper. Res..

[83]  Janusz A. Pudykiewicz,et al.  A numerical global meteorological sulfur transport model and its application to Arctic air pollution , 1996 .

[84]  J. Kukkonen,et al.  Intercomparison of air quality data using principal component analysis, and forecasting of PM₁₀ and PM₂.₅ concentrations using artificial neural networks, in Thessaloniki and Helsinki. , 2011, The Science of the total environment.

[85]  Riccardo Poli,et al.  Particle swarm optimization , 1995, Swarm Intelligence.

[86]  Jerzy Bartnicki,et al.  Norwegian Meteorological Institute’s real-time dispersion model snap (Severe Nuclear Accident Program): Runs for ETEX and ATMES II experiments with different meteorological input , 1998 .

[87]  Viney P. Aneja,et al.  Characterization of particulate matter (PM10) related to surface coal mining operations in Appalachia , 2012 .

[88]  Liborio Cavaleri,et al.  Modeling of surface roughness in electro-discharge machining using artificial neural networks , 2017 .

[89]  Panagiotis G. Asteris,et al.  Artificial bee colony-based neural network for the prediction of the fundamental period of infilled frame structures , 2019, Neural Computing and Applications.

[90]  Aminaton Marto,et al.  Blasting-induced flyrock and ground vibration prediction through an expert artificial neural network based on particle swarm optimization , 2014, Arabian Journal of Geosciences.

[91]  Jie Dou,et al.  A Comparative Study of PSO-ANN, GA-ANN, ICA-ANN, and ABC-ANN in Estimating the Heating Load of Buildings’ Energy Efficiency for Smart City Planning , 2019, Applied Sciences.

[92]  Hoang Nguyen,et al.  Optimizing Levenberg–Marquardt backpropagation technique in predicting factor of safety of slopes after two-dimensional OptumG2 analysis , 2019, Engineering with Computers.

[93]  S R Majee,et al.  Sources of air pollution due to coal mining and their impacts in Jharia coalfield. , 2000, Environment international.

[94]  P. J. García Nieto,et al.  PM10 concentration forecasting in the metropolitan area of Oviedo (Northern Spain) using models based on SVM, MLP, VARMA and ARIMA: A case study. , 2018, The Science of the total environment.

[95]  Xavier Querol,et al.  2005-2014 trends of PM10 source contributions in an industrialized area of southern Spain. , 2018, Environmental pollution.

[96]  Özgür Kisi,et al.  Daily pan evaporation modeling using chi-squared automatic interaction detector, neural networks, classification and regression tree , 2016, Comput. Electron. Agric..

[97]  Carsten Drebenstedt,et al.  Prediction of Blast-Induced Ground Vibration in an Open-Pit Mine by a Novel Hybrid Model Based on Clustering and Artificial Neural Network , 2019, Natural Resources Research.