实现精确的长期岩爆预测:SVM 与前沿元启发式算法的融合

IF 4.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Danial Jahed Armaghani, Peixi Yang, Xuzhen He, Biswajeet Pradhan, Jian Zhou, Daichao Sheng
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引用次数: 0

摘要

岩爆是地下工程中最危险的地质灾害之一,原因复杂,破坏性大。为解决这一问题,迫切需要一种能够快速有效地预测岩爆的方法,以预先降低岩爆的风险和损失。本研究分析了 259 个岩爆实例,采用了六个岩爆特征参数作为输入:最大切向应力 (σθ)、岩石单轴抗压强度 (σc)、岩石单轴抗拉强度 (σt)、应力系数 (σθ/σt)、岩石脆性系数 (σc/σt),以及弹性能量指数 (Wet)。通过将三种新型元启发式算法--Dingo 优化算法(DOA)、Osprey 优化算法(OOA)和 Rime-ice 优化算法(RIME)--与支持向量机(SVM)相结合,构建了用于长期岩爆趋势预测的混合模型。通过五重交叉验证进行的性能评估表明,对于无岩爆,DOA-SVM(Pop = 200)表现出更优越的预测性能,准确率达到 0.9808,精确度达到 0.9231,召回率达到 1,F1 分数达到 0.96。对于中度岩爆,OOA-SVM(Pop = 100)最为有效,准确率为 0.9808,精确率为 0.9545,召回率为 1,F1 分数为 0.9767。对于轻度和重度岩爆,DOA-SVM、OOA-SVM 和 RIME-SVM 的预测结果相当。然而,在所有岩爆危害等级中,这些混合模型的准确性都优于采用传统算法优化的传统 SVM 模型。此外,混合模型还通过全球收集的 20 个岩爆实例的新数据集进行了额外验证,证实了其强大的功效和卓越的泛化能力。随后,利用对六个关键特征参数的局部可解释模型失真解释(LIME)进行的分析表明,σθ 和 Wet 与岩爆严重程度之间存在显著的正相关关系。这些结果不仅肯定了 DOA、OOA 和 RIME 算法的卓越优化性能,还肯定了它们在提高机器学习模型预测长期岩爆的准确性方面的巨大潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Toward Precise Long-Term Rockburst Forecasting: A Fusion of SVM and Cutting-Edge Meta-heuristic Algorithms

Toward Precise Long-Term Rockburst Forecasting: A Fusion of SVM and Cutting-Edge Meta-heuristic Algorithms

Rockburst is one of the most hazardous geological disasters in underground engineering due to its complex causes and destructive nature. To address this, there is an imperative for methodologies that can predict rockbursts quickly and effectively to mitigate preemptively the risks and damages. In this study, 259 rockburst instances were analyzed, employing six rockburst feature parameters: maximum tangential stress (σθ), uniaxial compressive strength of rock (σc), uniaxial tensile strength of rock (σt), stress coefficient (σθt), rock brittleness coefficient (σct), and elastic energy index (Wet) as inputs. By integrating three novel meta-heuristic algorithms—dingo optimization algorithm (DOA), osprey optimization algorithm (OOA), and rime-ice optimization algorithm (RIME)—with support vector machine (SVM), hybrid models for long-term rockburst trend prediction were constructed. Performance evaluations through fivefold cross-validation revealed that for the no rockbursts, DOA–SVM (Pop = 200) demonstrated superior predictive performance, achieving an accuracy of 0.9808, precision of 0.9231, recall of 1, and an F1-score of 0.96. For moderate rockbursts, OOA–SVM (Pop = 100) emerged as the most effective, registering an accuracy of 0.9808, precision of 0.9545, recall of 1, and an F1-score of 0.9767. For light and severe rockbursts, DOA–SVM, OOA–SVM, and RIME–SVM showcased comparable predictive outcomes. However, these hybrid models outperformed traditional SVM models optimized with conventional algorithms in terms of accuracy across all rockburst hazard levels. Moreover, the hybrid models underwent additional validation with a new dataset of 20 rockburst instances collected globally, confirming their robust efficacy and exceptional generalization capabilities. An ensuing analysis using local interpretable model-agnostic explanations (LIME) on the six key feature parameters revealed a significant positive correlation between σθ and Wet with the severity of rockbursts. These results not only affirm the superior optimization performance of the DOA, OOA, and RIME algorithms but also their substantial potential to enhance the predictive accuracy of machine learning models in forecasting long-term rockbursts.

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来源期刊
Natural Resources Research
Natural Resources Research Environmental Science-General Environmental Science
CiteScore
11.90
自引率
11.10%
发文量
151
期刊介绍: This journal publishes quantitative studies of natural (mainly but not limited to mineral) resources exploration, evaluation and exploitation, including environmental and risk-related aspects. Typical articles use geoscientific data or analyses to assess, test, or compare resource-related aspects. NRR covers a wide variety of resources including minerals, coal, hydrocarbon, geothermal, water, and vegetation. Case studies are welcome.
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