Predicting different components of blast-induced ground vibration using earthworm optimisation-based adaptive neuro-fuzzy inference system

IF 2.7 3区工程技术 Q3 ENVIRONMENTAL SCIENCES

International Journal of Mining Reclamation and Environment Pub Date : 2023-09-18 DOI:10.1080/17480930.2023.2254147

Hoang Nguyen, Yosoon Choi, Masoud Monjezi, Nguyen Van Thieu, Trung-Tin Tran

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引用次数: 0

Abstract

ABSTRACTThis study focuses on addressing the complexity inherent in various amplitude components of blast-induced ground vibration (BIGV), encompassing vertical, radial, transversal, and the vectoral sum of PPVs of particle velocity. It takes into account their nonlinearity across diverse quarry environments, and aims to present an enhanced nonlinear intelligent system for accurate prediction of these components. Multiple artificial intelligence models were explored and developed for this purpose, including a support vector machine (SVM), an adaptive neural network based on the fuzzy inference system (ANFIS), and a novel hybrid model that combines earthworm optimisation (EO) and ANFIS (EO-ANFIS). The study also leverages the empirical model offered by the United States Bureau of Mines. The outcomes highlighted that the predictions of the three individual components prove to be more accurate compared to the vectoral sum of PPVs of particle velocity. However, the latter remains a valuable metric for evaluating the magnitude of BIGV in open-pit mines. Notably, the hybrid EO-ANFIS model emerges as the most accurate, achieving an impressive ~ 75% accuracy across 10 quarries characterised by distinct geological conditions.KEYWORDS: Rock blastingground vibrationpeak particle velocityearthworm optimisationANFISquarry AcknowledgmentsThe authors would like to thank Drs. O.S. Hammed, O.I. Popoola, A.A. Adetoyinbo, M.O. Awoyemi, T.A. Adagunodo, O. Olubosede, and A.K. Bello for sharing the dataset that facilitated the completion of this study.Disclosure statementNo potential conflict of interest was reported by the authors.Author contributionsHoang Nguyen: Conceptualisation, Investigation, Methodology, Visualisation, Writing – Original Draft, Writing – Review & Editing, Project Administration, Revise the revision version.Yosoon Choi, Masoud Monjezi, Nguyen Van Thieu, and Trung-Tin Tran: Conceptualisation, Methodology, Software, Formal Analysis, Writing – Review & Editing, Revise the revision version.

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基于蚯蚓优化的自适应神经模糊推理系统预测爆破诱发地面振动的不同分量

摘要本文重点研究了爆炸诱发地面振动(BIGV)的各种振幅分量的复杂性，包括垂直、径向、横向和粒子速度ppv的矢量总和。它考虑到它们在不同采石场环境中的非线性，并旨在提出一个增强的非线性智能系统来准确预测这些组件。为此，我们探索并开发了多种人工智能模型，包括支持向量机(SVM)、基于模糊推理系统(ANFIS)的自适应神经网络，以及结合蚯蚓优化(EO)和模糊推理系统(EO-ANFIS)的新型混合模型。本研究还利用了美国矿产局提供的经验模型。结果强调，与粒子速度的ppv矢量和相比，三个单独分量的预测被证明是更准确的。然而，后者仍然是评估露天矿BIGV大小的一个有价值的指标。值得注意的是，混合EO-ANFIS模型是最准确的，在10个具有不同地质条件的采石场中达到了令人印象深刻的75%的精度。关键词:岩石爆破;地面振动;峰值粒子速度;O.S. Hammed、O.I. Popoola、A.A. Adetoyinbo、M.O. Awoyemi、T.A. Adagunodo、O. Olubosede和A.K. Bello分享数据集，促进了本研究的完成。披露声明作者未报告潜在的利益冲突。shoang Nguyen:概念化，调查，方法论，可视化，写作-原稿，写作-审查和编辑，项目管理，修订修订版本。Yosoon Choi, Masoud Monjezi, Nguyen Van Thieu和Trung-Tin Tran:概念化，方法论，软件，形式分析，写作-审查和编辑，修改修订版本。

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来源期刊

International Journal of Mining Reclamation and Environment ENVIRONMENTAL SCIENCES-MINING & MINERAL PROCESSING

CiteScore

5.70

自引率

8.30%

发文量

审稿时长

>12 weeks

期刊介绍： The International Journal of Mining, Reclamation and Environment published research on mining and environmental technology engineering relating to metalliferous deposits, coal, oil sands, and industrial minerals. We welcome environmental mining research papers that explore: -Mining environmental impact assessment and permitting- Mining and processing technologies- Mining waste management and waste minimization practices in mining- Mine site closure- Mining decommissioning and reclamation- Acid mine drainage. The International Journal of Mining, Reclamation and Environment welcomes mining research papers that explore: -Design of surface and underground mines (economics, geotechnical, production scheduling, ventilation)- Mine planning and optimization- Mining geostatics- Mine drilling and blasting technologies- Mining material handling systems- Mine equipment