Research on the blasting effect prediction and blasting parameter optimization based on PCA-PSO-DBN Research on the blasting effect prediction

• Published in: Discover applied sciences Vol. 7; no. 6
• Main Authors: Ma, Weilong, Qiao, Biao, Wen, Tongkai, Song, Zhanping, Ren, Zhenzhong
• Format: Journal Article
• Language: English
• Published: Cham Springer International Publishing 09.06.2025
• Subjects: Applied and Technical Physics; Chemistry/Food Science; Earth Sciences; Engineering; Environment; Materials Science; Blasting parameters; Smooth tunnel blasting; Deep belief network; Particle swarm optimization; Principal component analysis
• ISSN: 3004-9261
• DOI: 10.1007/s42452-025-07094-y

In mountain tunnel blasting construction, challenges such as over-excavation and improper particle size distribution are frequently encountered. Traditional neural network prediction models and empirical formulas have proven inadequate for optimizing construction parameters. To improve the accuracy of prediction models, this study employed Principal Component Analysis (PCA) to identify three key factors influencing construction outcomes as input variables for the model. Additionally, Particle Swarm Optimization (PSO) was integrated for parameter adjustment, leading to the optimization of the parameters within the Deep Belief Network (DBN) model. Two PCA-PSO-DBN models were developed, specifically addressing tunnel over-excavation and the equivalent size of crushed rocks. By training and predicting data from Sect. 3 of the NEOM New City tunnel project, the feasibility of the model was validated through on-site data analysis. The results indicated that compared to traditional DBN and PCA-DBN models, the proposed model reduced maximum errors by 16.98, 7.68, and 11.37, 4.85%, respectively, demonstrating higher precision. Following blasting parameter optimization, the reductions in maximum linear over- or under-excavation and the equivalent size of crushed rocks in the tunnel reached 40.94% and 18.70%, respectively, compared to the original blasting plan. This model introduces innovative methodologies and possibilities, offering valuable insights and references for similar endeavors. Article Highlights The three key factors influencing the tunnel blasting effect were extracted using the PCA method as input variables for the DBN model. A tunnel blasting effect prediction model based on PCA-PSO-DBN was established. The prediction accuracy of PCA-PSO-DBN in predicting tunnel blasting effect surpasses that of DBN and PCA-DBN.