Prediction of blasting mean fragment size using support vector regression combined with five optimization algorithms

• Published in: Journal of Rock Mechanics and Geotechnical Engineering Vol. 13; no. 6; pp. 1380 - 1397
• Main Authors: Li, Enming, Yang, Fenghao, Ren, Meiheng, Zhang, Xiliang, Zhou, Jian, Khandelwal, Manoj
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.12.2021; Universidad Politécnica de Madrid-ETSI Minas y Energía,Ríos Rosas 21,Madrid,28003,Spain%College of Locomotive and Rolling Stock Engineering,Dalian Jiaotong University,Dalian,116028,China%Department of Mathematics,University of California Santa Barbara,Santa Barbara,CA,93106,USA%State Key Laboratory of Safety and Health for Metal Mines,Maanshan,243000,China%School of Resources and Safety Engineering,Central South University,Changsha,410083,China%School of Engineering,Information Technology and Physical Sciences,Federation University Australia,Ballarat,VIC,3350,Australia; School of Resources and Safety Engineering,Central South University,Changsha,410083,China; Elsevier
• Subjects: Blasting mean fragment size; e-support vector regression (e-SVR); Intelligent prediction; Meta-heuristic algorithms; V-support vector regression (v-SVR); Intelligent prediction; Meta-heuristic algorithms; e-support vector regression (e-SVR); Blasting mean fragment size; V-support vector regression (v-SVR)
• ISSN: 1674-7755
• DOI: 10.1016/j.jrmge.2021.07.013

The main purpose of blasting operation is to produce desired and optimum mean size rock fragments. Smaller or fine fragments cause the loss of ore during loading and transportation, whereas large or coarser fragments need to be further processed, which enhances production cost. Therefore, accurate prediction of rock fragmentation is crucial in blasting operations. Mean fragment size (MFS) is a crucial index that measures the goodness of blasting designs. Over the past decades, various models have been proposed to evaluate and predict blasting fragmentation. Among these models, artificial intelligence (AI)-based models are becoming more popular due to their outstanding prediction results for multi-influential factors. In this study, support vector regression (SVR) techniques are adopted as the basic prediction tools, and five types of optimization algorithms, i.e. grid search (GS), grey wolf optimization (GWO), particle swarm optimization (PSO), genetic algorithm (GA) and salp swarm algorithm (SSA), are implemented to improve the prediction performance and optimize the hyper-parameters. The prediction model involves 19 influential factors that constitute a comprehensive blasting MFS evaluation system based on AI techniques. Among all the models, the GWO-v-SVR-based model shows the best comprehensive performance in predicting MFS in blasting operation. Three types of mathematical indices, i.e. mean square error (MSE), coefficient of determination (R2) and variance accounted for (VAF), are utilized for evaluating the performance of different prediction models. The R2, MSE and VAF values for the training set are 0.8355, 0.00138 and 80.98, respectively, whereas 0.8353, 0.00348 and 82.41, respectively for the testing set. Finally, sensitivity analysis is performed to understand the influence of input parameters on MFS. It shows that the most sensitive factor in blasting MFS is the uniaxial compressive strength.