In order to predict backfill strength rapidly with high accuracy and provide a new technical support for digitization and intelligentization of mine, a support vector regression (SVR) model improved by grey wolf optimization (GWO), GWO-SVR model, is established. First, GWO is used to optimize penalty term and kernel function parameter in SVR model with high accuracy based on the experimental data of uniaxial compressive strength of filling body. Subsequently, a prediction model which uses the best two parameters of best c and best g is established with the slurry density, cement dosage, ratio of artificial aggregate to tailings, and curing time taken as input factors, and uniaxial compressive strength of backfill as the output factor. The root mean square error of this GWO-SVR model in predicting backfill strength is 0.143 and the coefficient of determination is 0.983, which means that the predictive effect of this model is accurate and reliable. Compared with the original SVR model without the optimization of GWO and particle swam optimization (PSO)-SVR model, the performance of GWO-SVR model is greatly promoted. The establishment of GWO-SVR model provides a new tool for predicting backfill strength scientifically.
ZHANG Bo(张博),LI Keqing (李克庆),HU Yafei(胡亚飞),JI Kun(吉坤),HAN Bin*(韩斌)
. Prediction of Backfill Strength Based on Support Vector Regression Improved by Grey Wolf Optimization[J]. Journal of Shanghai Jiaotong University(Science), 2023
, 28(5)
: 686
-694
.
DOI: 10.1007/s12204-022-2408-7
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