Powiadomienia systemowe
- Sesja wygasła!
Tytuł artykułu
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The blast-induced ground vibration (BIGV) is a severe environmental impact of blasting as it can afect the integrity of the structures and cause civil unrest. In this study, the BIGV of Daejeon tunnel was predicted taking into consideration parameters such as hole length, the charge per delay, number of holes, total charge, distance from the measuring station to the blasting point and the rock mass rating as the input parameters, while the peak particle velocity (PPV) was the targeted output parameter. An artifcial neural network (ANN) model was frst simulated. The optimum ANN structure obtained was optimized using a novel moth-fame optimization algorithm (MFO). The gene expression program (GEP) was also used to develop another new model. The proposed models were compared with the multilinear regression (MLR) model and the selected empirical models for the PPV predictions. The performance of the proposed model was evaluated using statistical indices such as adjusted coefcient of determination (adj R2 ), mean square error (MSE), mean absolute error (MAE), and the variance accounted for (VAF). The proposed MFO-ANN outperformed other models with the adj R2 of 0.9702 and 0.9577, VAF of 97.0472 and 95.9832, MSE of 0.0009 and 0.0008, and MAE of 0.0233 and 0.0216 for the respective training and testing phases. The sensitivity analysis was conducted using the weight partitioning method (WPM), and the charge per delay has the highest infuence on the predicted PPV. This study indicates the suitability of the proposed models for the prediction of PPV.
Wydawca
Czasopismo
Rocznik
Tom
Strony
161--174
Opis fizyczny
Bibliogr. 30 poz.
Twórcy
autor
- Department of Energy Resources Engineering, Inha University Yong-Hyun Dong, Nam Ku, Incheon, Korea
- Department of Mining Engineering, Federal University of Technology, Akure, Nigeria
autor
- Department of Energy Resources Engineering, Inha University Yong-Hyun Dong, Nam Ku, Incheon, Korea
autor
- Korea Atomic Energy Research Institute (KAERI), Yuseong-gu, Daejeon 305-701, Republic of Korea
Bibliografia
- 1. Abdel-Rasoul EI (2000) Assessment of the particle velocity characteristics of blasting vibrations at Bani Khalid quarries. Bull Faculty Eng 28(2):135–150
- 2. Akande JM, Aladejare AE, Lawal AI (2014) Evaluation of the environmental impacts of blasting in Okorusu Fluorspar Mine. Namibia Int J Eng Tech 4(2):101–108
- 3. Armaghani DJ, Hajihassani M, Mohamad ET, Marto A, Noorani SA (2014) Blasting induced flyrock and ground vibration prediction through an expert artificial neural network based on particle swarm optimization. Arab J Geosci 7(12):5383–5396
- 4. Duvall WI, Petkof B (1959) Spherical propagation of explosion generated strain pulses in rock. U.S. Department of the Interior, Bureau of Mines
- 5. Fausett L (1994) Fundamentals of neural networks. Prentice Hall, Englewood Cliffs
- 6. Ferreira C (2001) Gene expression programming: a new adaptive algorithm for solving problems. Complex Sys 13(2):87–129
- 7. Fine TL (1999) Feedforward neural network methodology. Springer, New York
- 8. Garson GD (1991) Interpreting neural network connection weights. Art Intel Expert 6:47–51
- 9. Goh ATC (1995) Back-propagation neural networks for modeling complex systems. Art Intel Eng 9:143–151
- 10. Hagan TN (1973) Rock breakage by explosive. In: Proceedings of the national symposium on rock fragmentation, Adelaide, pp 1–17.
- 11. Hagan MT, Menhaj M (1994) Training feed-forward networks with the Marquardt algorithm. IEEE Trans Neu Nets 5(6):989–993
- 12. IS 6922 (1973) Criteria for safety and design of structures subject to underground blast. Bureau of Indian Standards (BIS), New Delhi, India.
- 13. Khandelwal M, Singh TN (2009) Prediction of blast-induced ground vibration using artificial neural network. Int J R Mech M Sci 46(7):1214–1222
- 14. Khandelwal M, Kumar DL, Yellishetty M (2011) Application of soft computing to predict blast-induced ground vibration. Eng Comp 27(2):117–125
- 15. Kwon S, Cho WJ, Han PS (2006) Concept development of an underground research tunnel for validating the Korean reference HLW disposal system. Tunnel Under S Tech 21:203–217
- 16. Langefors U, Kihlstrom B (1963) The modern technique of rock blasting. Wiley, New York
- 17. Lawal AI (2020) An artificial neural network-based mathematical model for the prediction of blast-induced ground vibration in granite quarries in Ibadan, Oyo State. Nigeria Scic African 8:e00413
- 18. Lawal AI, Idris MA (2019) An artificial neural network-based mathematical model for the prediction of blast-induced ground vibrations. Int J Env Sts. https://doi.org/10.1080/00207233.2019.1662186
- 19. Lawal AI, Kwon S (2020) Application of artificial intelligence to rock mechanics: an overview. J R Mech Geotech Eng. https://doi.org/10.1016/j.jrmge.2020.05.010
- 20. Lee C, Joen S (2015) Current status of KURT and its long-term experimental research programme. The 13th International Congress of Rock Mechanics.
- 21. Li G, Kumar D, Samui P, Rad HN, Roy B, Hasanipanah M (2020) Developing a new computational intelligence approach for approximating the blast-induced ground vibration. Appl Sci 10:434
- 22. Marquardt D (1963) An Algorithm for least-squares estimation of nonlinear parameters. SIAM J Appl Maths 11(2):431–441
- 23. Mirjalili S (2015) Moth-flame optimization algorithm: a novel nature-inspired heuristic paradigm. Knowledge-Based Sys 89:228–249
- 24. Mirjalili S, Mirjalili SM, Lewis A (2014) Grey wolf optimizer. Adv Eng Soft 69:46–61
- 25. Mohammadnejad M, Gholami R, Ramazanzadeh A, Jalali ME (2012) Prediction of blast-induced vibrations in limestone quarries using Support Vector Machine. J Vib Cont 18(9):1322–1329
- 26. Monjezi M, Ghafurikalajahi M, Bahrami A (2011) Prediction of blast-induced ground vibration using artificial neural networks. Tunnel Under S Tech 26(1):46–50
- 27. Monjezi M, Hasanipanah M, Khandelwal M (2013) Evaluation and prediction of blast-induced ground vibration at Shur River Dam, Iran, by artificial neural network. Neu Comp App 22(7–8):1637–1643
- 28. Shakeri J, Shokri BJ, Dehghani H (2020) Prediction of blast-induced ground vibration using gene expression programming (GEP), artificial neural networks (ANNs), and linear multivariate regression (LMR). Arch Min Sci 65(2):317–335
- 29. Vasović D, Kostić S, Ravilić M, Trajković S (2014) Environmental impact of blasting at Drenovac limestone quarry (Serbia). Env Earth Sci 72(10):3915–3928
- 30. Wolpert DH, Macready WG (1997) No free lunch theorems for optimization. Evol Comp IEEE Trans 1:67–82
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-3b2ec013-0a22-4512-bcf1-4875939ed6cf