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Experimental data – driven algorithm to predict muckpile characteristics in jointed overburden bench using unmanned aerial vehicle and AI tools

N. Sri Chandrahas, Yewuhalashet Fissha, Bhanwar Singh Choudhary, Blessing Olamide Taiwo, M. S. Venkataramayya, Tsuyoshi Adachi

2024International Journal of Mining Reclamation and Environment10 citationsDOI

Abstract

In the current investigation, an intriguing method called Firefly-XGBoost was put up to predict and integrate blast muck-pile results notably drop, throw, and lateral spread, which are instrumental in regulating and remedying the loading problems by loader as well as deceiving factors in type of loader selection. As a result, the particle swarm optimisation (PSO) algorithm and the firefly algorithm were relied on to shore up the efficacy of the XG Boost conventional model. A total of 164 blast experiments were executed in two different mines and the data collected from these trials data were used to train the model. This data includes specific features such as joints spanning height (JSH) as well as other blast characteristics such as the number of joint sets, decking length, total quantity of explosives, stemming length, decking length and firing pattern. The Firefly-XG Boost algorithm yielded better outcomes in terms of RMSE and R2 values when compared to the XG Boost, and PSO-XG Boost algorithms. The developed model was found to be suitable in predicting muck-pile parameters for practical application.

Topics & Concepts

Firefly algorithmParticle swarm optimizationMuckLoaderAlgorithmPileEngineeringStructural engineeringComputer scienceEnvironmental scienceSoil scienceMechanical engineeringStructural Response to Dynamic LoadsHigh-Velocity Impact and Material BehaviorTransportation Safety and Impact Analysis
Experimental data – driven algorithm to predict muckpile characteristics in jointed overburden bench using unmanned aerial vehicle and AI tools | Litcius