Abstract
Because nearby construction has harmful effects, precisely predicting blast-induced ground vibration is critical. In this paper, a hybrid artificial bee colony (ABC) and support vector machine (SVM) model was proposed for predicting the value of peak particle velocity (PPV), which is used to describe blast-induced ground vibration. To construct the model, 5 potentially relevant factors, including controllable and uncontrollable parameters, were considered as input parameters, and PPV was set as the output parameter. Forty-five samples were recorded from the Hongling lead-zinc mine. An ABC-SVM model was developed and trained on 35 samples via 5-fold cross-validation (CV). A testing set (10 samples) was used to evaluate the prediction performance of the ABC-SVM model. SVM and four empirical models (United States Bureau of Mines (USBM), Amraseys-Hendron (A-H), Langefors-Kihstrom (L-K), and Central Mining Research Institute (CMRI)) also were introduced for comparison. Next, the performances of the models were analyzed by using 3 statistical parameters: the correlation coefficient (R2), root-mean-square error (RMSE), and variance accounted for (VAF). ABC-SVM had the highest R2 and VAF values followed by the SVM, A-H, USBM, CMRI, and L-K methods. The results demonstrated that ABC-SVM outperformed SVM and the empirical predictors for predicting PPV. Moreover, the best results from the R2, RMSE, and VAF indices were 0.9628, 0.2737, and 96.05% for the ABC- SVM model. The sensitivities of the parameters also were investigated, and the height difference between the blast point and the monitoring station was found to be the parameter that had the most influence on PPV.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alshamlan HM, Badr GH, Alohali YA (2016), “ABC-SVM: Artificial Bee Colony and SVM Method for Microarray Gene Selection and Multi Class Cancer Classification”, International Journal of Machine Learning and Computing, 6(3): 184–190.
Ambraseys N and Hendron A 1968, Dynamic Behavior of Rock Masses in Rock Mechanics in Engineering Practice, New York: John Wiley and Sons, USA.
Amiri M, Bakhshandeh Amnieh H, Hasanipanah M, Mohammad Khanli L (2016), “A New Combination of Artificial Neural Network and K-Nearest Neighbors Models to Predict Blast-Induced Ground Vibration and Air-Overpressure”, Engineering with Computers, 32(4): 631–644.
Amiri M, Hasanipanah M and Amnieh BH (2020), “Predicting Ground Vibration Induced by Rock Blasting Using a Novel Hybrid of Neural Network and Itemset Mining”, Neural Computing and Applications, 32(18): 14681–14699.
Armaghani DJ, Hajihassani M, Mohamad ET, Marto A, Noorani SA (2013), “Blasting-Induced Flyrock and Ground Vibration Prediction Through an Expert Artificial Neural Network Based on Particle Swarm Optimization”, Arabian Journal of Geosciences, 7(12): 5383–5396.
Armaghani DJ, Hasanipanah M, Amnieh HB and Mohamad ET (2016), “Feasibility of ICA in Approximating Ground Vibration Resulting from Mine Blasting”, Neural Computing and Applications, 29(9): 457–465.
Badrinath N, Gopinath G, Ravichandran K (2013), “Design of Automatic Detection of Erythemato-Squamous Diseases Through Threshold-Based ABC-FELM Algorithm”, Journal of Artificial Intelligence, 6(4): 245–256.
Bakhshandeh Amnieh H, Mozdianfard MR and Siamaki A (2010), “Predicting of Blasting Vibrations in Sarcheshmeh Copper Mine by Neural Network”, Safety Science, 48(3): 319–325.
Capraz O, Gungor A, Mutlu O and Sagbas A (2020), “Optimal Sizing of Grid-Connected Hybrid Renewable Energy Systems Without Storage: A Generalized Optimization Model,” Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 1–34.
Deng Z, Liu X, Liu Y, Liu S, Han Y, Liu J and Tu Y (2020), “Model Test and Numerical Simulation on the Dynamic Stability of the Bedding Rock Slope Under Frequent Microseisms”, Earthquake Engineering and Engineering Vibration, 19(4): 919–935.
Ding Z, Nguyen H, Bui X, Zhou J and Moayedi H (2020), “Computational Intelligence Model for Estimating Intensity of Blast-Induced Ground Vibration in a Mine Based on Imperialist Competitive and Extreme Gradient Boosting Algorithms”, Natural Resources Research, 29(2): 751–769.
Duvall W (1963) “Vibrations from Blasting at Iowa Limestone Quarries,” Report, vol 6270, US Dept. of the Interior, Bureau of Mines.
Esfeh PK, Nadi B and Fantuzzi N (2020), “Influence of Random Heterogeneity of Shear Wave Velocity on Sliding Mass Response and Seismic Deformations of Earth Slopes”, Earthquake Engineering and Engineering Vibration, 19(2): 269–287.
Fan X, Zhou C and Chen G (2005), “The Influential Factors of Blasting Vibration by Grey Correlation Analysis”, Blasting, 22(2): 100–102. (in Chinese)
Fattahi H and Hasanipanah M (2021a), “An Integrated Approach of ANFIS-Grasshopper Optimization Algorithm to Approximate Flyrock Distance in Mine Blasting”, Engineering with Computers, 38(3): 2619–2631. doi: https://doi.org/10.1007/S00366-020-01231-4
Fattahi H and Hasanipanah M (2021b), “Prediction of Blast-Induced Ground Vibration in a Mine Using Relevance Vector Regression Optimized by Metaheuristic Algorithms”, Natural Resources Research, 30(2): 1849–1863.
García Nieto PJ, García-Gonzalo E, Alonso Fernández JR and Díaz Muñiz C (2017), “A Hybrid Wavelet Kernel SVM-Based Method Using Artificial Bee Colony Algorithm for Predicting the Cyanotoxin Content from Experimental Cyanobacteria Concentrations in the Trasona Reservoir (Northern Spain)”, Journal of Computational and Applied Mathematics, 309: 587–602.
Ghasemi E, Kalhori H and Bagherpour R (2016), “A New Hybrid ANFIS—PSO Model for Prediction of Peak Particle Velocity Due to Bench Blasting”, Engineering with Computers, 32(4): 607–614.
Gong FQ, Yan JY and Li XB (2018), “A New Criterion of Rock Burst Proneness Based on the Linear Energy Storage Law and the Residual Elastic Energy Index”, Chinese Journal of Rock Mechanics and Engineering, 37(9): 1993–2014.
Gui YL, Zhao ZY, Jayasinghe LB, Zhou HY, Goh ATC and Tao M (2018), “Blast Wave Induced Spatial Variation of Ground Vibration Considering Field Geological Conditions”, International Journal of Rock Mechanics and Mining Sciences, 101: 63–68.
Hajihassani M, Jahed Armaghani D, Marto A and Tonnizam Mohamad E (2014), “Ground Vibration Prediction in Quarry Blasting Through an Artificial Neural Network Optimized by Imperialist Competitive Algorithm”, Bulletin of Engineering Geology and the Environment, 74(3): 873–886.
Harandizadeh H, Toufigh MM and Toufigh V (2018), “Application of Improved ANFIS Approaches to Estimate Bearing Capacity of Piles”, Soft Computing, 23(19): 9537–9549.
Hasanipanah M and Amnieh BH (2020a), “A Fuzzy Rule-Based Approach to Address Uncertainty in Risk Assessment and Prediction of Blast-Induced Flyrock in a Quarry”, Natural Resources Research, 29: 669–689.
Hasanipanah M and Amnieh BH (2020b), “Developing a New Uncertain Rule-Based Fuzzy Approach for Evaluating the Blast-Induced Backbreak”, Engineering with Computers, 37(3): 1879–1893.
Hasanipanah M, Faradonbeh RS, Amnieh HB, Armaghani DJ and Monjezi M (2016), “Forecasting Blast-Induced Ground Vibration Developing a CART Model”, Engineering with Computers, 33(2): 307–316.
Hasanipanah M, Keshtegar B and Thai DK (2022), “An ANN-Adaptive Dynamical Harmony Search Algorithm to Approximate the Flyrock Resulting from Blasting”, Engineering with Computers, 38(2): 1257–1269. doi: https://doi.org/10.1007/s00366-020-01105-9
Hasanipanah M, Meng D, Keshtegar B, Trung NT and Thai DK (2021), “Nonlinear Models Based on Enhanced Kriging Interpolation for Prediction of Rock Joint Shear Strength”, Neural Computing and Applications, 33(9): 4205–4215.
Hasanipanah M, Monjezi M, Shahnazar A, Jahed Armaghani D and Farazmand A (2015), “Feasibility of Indirect Determination of Blast Induced Ground Vibration Based on Support Vector Machine”, Measurement, 75: 289–297.
Hasanipanah M, Zhang DJ, Armaghani H and Rad N (2020), “The Potential Application of a New Intelligent Based Approach in Predicting the Tensile Strength of Rock”, IEEE Access, 8: 57148–57157.
Heydari A, Majidi Nezhad M, Neshat M, Garcia DA, Keynia F, De Santoli L and Bertling Tjernberg L (2021a), “A Combined Fuzzy GMDH Neural Network and Grey Wolf Optimization Application for Wind Turbine Power Production Forecasting Considering SCADA Data”, Energies, 14(12): 3459.
Heydari A, Nezhad M, Garcia AD, Keynia F and Santoli LD (2021b), “Air Pollution Forecasting Application Based on Deep Learning Model and Optimization Algorithm”, Clean Techn Environ Policy, 24(2): 607–621.
Iphar M, Yavuz M and Ak H (2008), “Prediction of Ground Vibrations Resulting from the Blasting Operations in an Open-Pit Mine by Adaptive Neuro-Fuzzy Inference System”, Environmental Geology, 56(1): 97–107.
Jiang W, Arslan CA, Soltani Tehrani M, Khorami M and Hasanipanah M (2019), “Simulating the Peak Particle Velocity in Rock Blasting Projects Using a Neuro-Fuzzy Inference System”, Engineering with Computers, 35(4): 1203–1211.
Jiang Z, Xu H, Chen H, Gao B, Jia S, Yu Z and Zhou J (2021), “Indirect Determination Approach of Blast-Induced Ground Vibration Based on a Hybrid SSA-Optimized GP-Based Technique”, Advances in Civil Engineering, 2021: 6694918.
Karaboga D (2005), “An Idea Based on Honey Bee Swarm for Numerical Optimization”, Technical Report-tr06, Erciyes University, Engineering Faculty, Computer Engineering Department, Kayseri, Turkey.
Khandelwal M (2010), “Blast-Induced Ground Vibration Prediction Using Support Vector Machine”, Engineering with Computers, 27(3): 193–200.
Khandelwal M, Kankar PK and Harsha SP (2010), “Evaluation and Prediction of Blast Induced Ground Vibration Using Support Vector Machine”, Mining Science and Technology (China), 20: 64–70.
Khandelwal M, Lalit Kumar D and Yellishetty M (2009), “Application of Soft Computing to Predict Blast-Induced Ground Vibration”, Engineering with Computers, 27(2): 117–125.
Khandelwal M and Singh TN (2006), “Prediction of Blast Induced Ground Vibrations and Frequency in Opencast Mine: A Neural Network Approach”, Journal of Sound and Vibration, 289(4–5): 711–725.
Khandelwal M and Singh TN (2007), “Evaluation of Blast-Induced Ground Vibration Predictors”, Soil Dynamics and Earthquake Engineering, 27(2): 116–125.
Langefors U and Kihlström B 1978, The Modern Technique of Rock Blasting, Wiley, New York, USA.
Lei C, Deng J, Cao K, Xiao Y, Ma L, Wang W, Ma T and Shu C (2019), “A Comparison of Random Forest and Support Vector Machine Approaches to Predict Coal Spontaneous Combustion in Gob”, Fuel, 239: 297–311.
Lin Y, Zhou K and Li J (2018a), “Application of Cloud Model in Rock Burst Prediction and Performance Comparison with Three Machine Learning Algorithms”, IEEE Access, 6: 30958–30968.
Lin Y, Zhou K and Li J (2018b), “Prediction of Slope Stability Using Four Supervised Learning Methods”, IEEE Access, 6: 31169–31179.
Liu Z, Shao J, Xu W, Chen H and Zhang Y (2014), “An Extreme Learning Machine Approach for Slope Stability Evaluation and Prediction”, Natural Hazards, 73(2): 787–804.
Liu Z, Shao J, Xu W and Shi C (2013), “Estimation of Elasticity of Porous Rock Based on Mineral Composition and Microstructure”, Advances in Materials Science Engineering, 2013: 512727.
Mohamadnejad M, Gholami R and Ataei M (2012), “Comparison of Intelligence Science Techniques and Empirical Methods for Prediction of Blasting Vibrations”, Tunnelling and Underground Space Technology, 28: 238–244.
Mohamadnejad M, Gholami R, Ramezanzadeh A and Jalali ME (2011), “Prediction of Blast-Induced Vibrations in Limestone Quarries Using Support Vector Machine”, Journal of Vibration and Control, 18(9): 1322–1329.
Mohamed MT (2011), “Performance of Fuzzy Logic and Artificial Neural Network in Prediction of Ground and Air Vibrations”, International Journal of Rock Mechanics Mining Sciences, 48(5): 845–851.
Mokfi T, Shahnazar A, Bakhshayeshi I, Derakhsh AM and Tabrizi O (2018), “Proposing of a New Soft Computing-Based Model to Predict Peak Particle Velocity Induced by Blasting”, Engineering with Computers, 34(4): 881–888.
Monjezi M, Ahmadi M, Sheikhan M, Bahrami A and Salimi AR (2010), “Predicting Blast-Induced Ground Vibration Using Various Types of Neural Networks”, Soil Dynamics and Earthquake Engineering, 30(11): 1233–1236.
Monjezi M, Baghestani M, Shirani Faradonbeh R, Pourghasemi Saghand M and Jahed Armaghani D (2016), “Modification and Prediction of Blast-Induced Ground Vibrations Based on Both Empirical and Computational Techniques”, Engineering with Computers, 32(4): 717–728.
Monjezi M, Ghafurikalajahi M and Bahrami A (2011), “Prediction of Blast-Induced Ground Vibration Using Artificial Neural Networks”, Tunnelling and Underground Space Technology, 26(1): 46–50.
Monjezi M, Hasanipanah M and Khandelwal M (2012), “Evaluation and Prediction of Blast-Induced Ground Vibration at Shur River Dam, Iran, by Artificial Neural Network”, Neural Computing and Applications, 22(7–8): 1637–1643.
Murmu S, Maheshwari P and Verma HK (2018), “Empirical and Probabilistic Analysis of Blast-Induced Ground Vibrations”, International Journal of Rock Mechanics and Mining Sciences, 103: 267–274.
Perumal Sankar S, Vishwanath N and Jer Lang H (2017), “An Effective Content Based Medical Image Retrieval by Using ABC Based Artificial Neural Network (ANN)”, Current Medical Imaging Reviews, 13(3): 223–230.
Prashanth R and Nimaje DS (2018a), “Estimation of Ambiguous Blast-Induced Ground Vibration Using Intelligent Models: A Case Study”, Noise and Vibration Worldwide, 49: 147–157.
Prashanth R and Nimaje DS (2018b), “Estimation of Peak Particle Velocity Using Soft Computing Technique Approaches: A Review”, Noise and Vibration Worldwide, 49: 302–310.
Qi C, Chen Q, Fourie A, Tang X, Zhang Q, Dong X and Feng Y (2019), “Constitutive Modelling of Cemented Paste Backfill: A Data-Mining Approach”, Construction and Building Materials, 197: 262–270.
Qi C, Chen Q, Fourie A and Zhang Q (2018a), “An Intelligent Modelling Framework for Mechanical Properties of Cemented Paste Backfill”, Minerals Engineering, 123: 16–27.
Qi C, Fourie A and Chen Q (2018b), “Neural Network and Particle Swarm Optimization for Predicting the Unconfined Compressive Strength of Cemented Paste Backfill”, Construction and Building Materials, 159: 473–478.
Qi C, Fourie A, Du X and Tang X (2018c), “Prediction of Open Stope Hangingwall Stability Using Random Forests”, Natural Hazards, 92(2): 1179–1197.
Qi C, Fourie A, Ma G, Tang X and Du X (2017), “Comparative Study of Hybrid Artificial Intelligence Approaches for Predicting Hangingwall Stability”, Journal of Computing in Civil Engineering, 32(2): 04017086.
Qiu Y, Zhou J, Khandelwal M, Yang H, Yang P and Li CQ (2021), “Performance Evaluation of Hybrid WOA-XGBoost, GWO-XGBoost and BO-XGBoost Models to Predict Blast-Induced Ground Vibration,” Engineering with Computers, https://doi.org/10.1007/s00366-021-01393-9.
Ragam P and Nimaje DS (2018), “Assessment of Blast-Induced Ground Vibration Using Different Predictor Approaches- A Comparison”, Chemical Engineering Transactions, 66: 487–492.
Roy P (1993), “Putting Ground Vibration Predictions into Practice”, Colliery Guardian, 241(2): 63–67.
Shen W and Xu Q (2000), “Determination of Main Influencing Factors on Blasting Vibration Parameters by Grey Correlation Analysis”, Engineering Blasting, 6(4): 6–8.
Sheykhi H, Bagherpour R, Ghasemi E and Kalhori H (2017), “Forecasting Ground Vibration Due to Rock Blasting: a Hybrid Intelligent Approach Using Support Vector Regression and Fuzzy C-Means Clustering”, Engineering with Computers, 34(2): 357–365.
Shi X, Zhou J and Li X (2012a), “Utilization of a Nonlinear Support Vector Machine to Predict Blasting Vibration Characteristic Parameters in Opencast Mine”, Przegląd Elektrotechniczny, 88(9B): 127–132.
Shi X, Zhou J, Wu B, Huang D and Wei W (2012b), “Support Vector Machines Approach to Mean Particle Size of Rock Fragmentation Due to Bench Blasting Prediction”, Transactions of Nonferrous Metals Society of China, 22(2): 432–441.
Singh TN and Singh V (2005), “An Intelligent Approach to Prediction and Control Ground Vibration in Mines”, Geotechnical and Geological Engineering, 23: 249–262.
Taheri K, Hasanipanah M, Golzar SB and Majid MZA (2016), “A Hybrid Artificial Bee Colony Algorithm-Artificial Neural Network for Forecasting the Blast-Produced Ground Vibration”, Engineering with Computers, 33(3): 689–700.
Tao ZG, Shu Y, Yang XJ, Peng YY, Chen QH and Zhang HJ (2020), “Physical Model Test Study on Shear Strength Characteristics of Slope Sliding Surface in Nanfen Open-Pit Mine”, International Journal of Mining Science and Technology, 30(3): 421–429.
Taylor KE (2001), “Summarizing Multiple Aspects of Model Performance in a Single Diagram”, Journal of Geophysical Research Atmospheres, 106(D7): 7183–7192.
Tian E, Zhang J, Soltani Tehrani M, Surendar A and Ibatova AZ (2018), “Development of GA-Based Models for Simulating the Ground Vibration in Mine Blasting”, Engineering with Computers, 35(3): 849–855.
Turker H and Ozge A (2021), “An Alternative Approach to Predict Human Response to Blast Induced Ground Vibration”, Earthquake Engineering and Engineering Vibration, 20(1): 257–273.
Wang Y, Wang J, Zhou X, Zhao T and Gu J (2018), “Prediction of Blasting Vibration Intensity by Improved PSO-SVR on Apache Spark Cluster,” In: International Conference on Computational Science, vol. 10861, Springer, Cham, pp. 748–759, Wuxi, China.
Wu ZJ, Fan LF, Liu QS and Ma GW (2017), “Micro-Mechanical Modeling of the Macro-Mechanical Response and Fracture Behavior of Rock Using the Numerical Manifold Method”, Engineering Geology, 225: 49–60.
Wu ZJ, Xu XY, Liu QS and Yang YT (2018), “A Zero-Thickness Cohesive Element-Based Numerical Manifold Method for Rock Mechanical Behavior with Micro-Voronoi Grains”, Engineering Analysis with Boundary Elements, 96: 94–108.
Xue XH (2019) “Neuro-Fuzzy Based Approach for Prediction of Blast-Induced Ground Vibration”, Applied Acoustics, 152: 73–78.
Yang D, Liu Y, Li S, Li X and Ma L (2015), “Gear Fault Diagnosis Based on Support Vector Machine Optimized by Artificial Bee Colony Algorithm”, Mechanism and Machine Theory, 90: 219–229.
Yang Y and Zhang Q (1997), “A Hierarchical Analysis for Rock Engineering Using Artificial Neural Networks”, Rock Mechanics Rock Engineering, 30: 207–222.
Yu Z, Shi X, Zhou J, Chen X and Qiu X (2020), “Effective Assessment of Blast-Induced Ground Vibration Using an Optimized Random Forest Model Based on a Harris Hawks Optimization Algorithm”, Applied Sciences, 10(4): 1403.
Yu Z, Shi X, Zhou J, Gou Y, Huo X, Zhang J and Armaghani DJ (2022), “A New Multikernel Relevance Vector Machine Based on the HPSOGWO Algorithm for Predicting and Controlling Blast-Induced Ground Vibration”, Engineering with Computers, 38(2): 1905–1920. https://doi.org/10.1007/s00366-020-01136-2
Zhang L, Xu YJ, Wang JT and Zhang CH (2018a), “Velocity Structure Building and Ground Motion Simulation of the 2014 Ludian Ms 6.5 Earthquake”, Earthquake Engineering and Engineering Vibration, 17(4): 719–727.
Zhang N, Gao YF, Wu YX and Zhang F (2018b), “A Note on Near-Field Site Amplification Effects of Ground Motion from a Radially Inhomogeneous Valley”, Earthquake Engineering and Engineering Vibration, 17(4): 707–718.
Zhang Y, Yao D, Xie Z, Xu Y, Li G and Ye Y (2010), “Analysis of Master Control Factor of Blasting Seismic Effect and Discussion on Shock Absorption Measures”, Rock and Soil Mechanics, 31: 304–308.
Zhou J, Li E, Wang M, Chen X, Shi X and Jiang L (2019a), “Feasibility of Stochastic Gradient Boosting Approach for Evaluating Seismic Liquefaction Potential Based on SPT and CPT Case Histories”, Journal of Performance of Constructed Facilities, 33(3): 04019024.
Zhou J, Li E, Wei H, Li C, Qiao Q and Armaghani DJ (2019b), “Random Forests and Cubist Algorithms for Predicting Shear Strengths of Rockfill Materials,” Applied Sciences, 9(8), https://doi.org/10.3390/app9081621.
Zhou J, Li E, Yang S, Wang M, Shi X, Yao S and Mitri HS (2019c), “Slope Stability Prediction for Circular Mode Failure Using Gradient Boosting Machine Approach Based on an Updated Database of Case Histories”, Safety Science, 118: 505–518.
Zhou J, Panagiotis GA, Danial JA and Binh TP (2020), “Prediction of Ground Vibration Induced by Blasting Operations Through the Use of the Bayesian Network and Random Forest Models”, Soil Dynamics and Earthquake Engineering, 139: 106390.
Zhou J, Shi X, Du K, Qiu X, Li X and Mitri HS (2017), “Feasibility of Random-Forest Approach for Prediction of Ground Settlements Induced by the Construction of a Shield-Driven Tunnel”, International Journal of Geomechanics, 17(6): 04016129.
Zhou K, Yun L, Deng H, Li J and Liu C (2016), “Prediction of Rock Burst Classification Using Cloud Model with Entropy Weight”, Transactions of Nonferrous Metals Society of China, 26(7): 1995–2002.
Zhu W, Nikafshan RH and Hasanipanah M (2021), “A Chaos Recurrent ANFIS Optimized by PSO to Predict Ground Vibration Generated in Rock Blasting”, Applied Soft Computing Journal, 108: 107434.
Acknowledgment
National Natural Science Foundation of China (NSFC) under Grant Nos. 52104125 and 52104109, the Fundamental Research Funds for the Central Universities under Grant No. B220202056, the Opening Fund of State Key Laboratory of Mining Response and Disaster Prevention and Control in Deep Coal Mines under Grant No. SKLMRDPC21KF04, the Natural Science Basic Research Plan in Shaanxi Province of China (2022JQ-304), and the Fund of Young Elite Scientists Sponsorship Program by CAST under Grant No. 2021QNRC001.
Author information
Authors and Affiliations
Corresponding authors
Additional information
Supported by: National Natural Science Foundation of China (NSFC) under Grant Nos. 52104125 and 52104109, the Fundamental Research Funds for the Central Universities under Grant No. B220202056, the Opening Fund of State Key Laboratory of Mining Response and Disaster Prevention and Control in Deep Coal Mines under Grant No. SKLMRDPC21KF04, the Natural Science Basic Research Plan in Shaanxi Province of China (2022JQ-304), and the Fund of Young Elite Scientists Sponsorship Program by CAST under Grant No. 2021QNRC001
Rights and permissions
About this article
Cite this article
Zhu, C., Xu, Y., Wu, Y. et al. A hybrid artificial bee colony algorithm and support vector machine for predicting blast-induced ground vibration. Earthq. Eng. Eng. Vib. 21, 861–876 (2022). https://doi.org/10.1007/s11803-022-2125-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11803-022-2125-0