Back analysis of geomechanical parameters based on a data augmentation algorithm and machine learning technique

IF 8.2 1区工程技术 Q1 ENGINEERING, CIVIL Underground Space Pub Date : 2024-10-22 DOI:10.1016/j.undsp.2024.08.002

Hui Li, Weizhong Chen, Xianjun Tan

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Abstract

Accurate geomechanical parameters are key factors for stability evaluation, disaster forecasting, structural design, and supporting optimization. The intelligent back analysis method based on the monitored information is widely recognized as the most efficient and cost-effective technique for inverting parameters. To address the low accuracy of measured data, and the scarcity of comprehensive datasets, this study proposes an innovative back analysis framework tailored for small sample sizes. We introduce a multi-faceted back analysis approach that combines data augmentation with advanced optimization and machine learning techniques. The auxiliary classifier generative adversarial network (ACGAN)-based data augmentation algorithm is first employed to generate synthetic yet realistic samples that adhere to the underlying probability distribution of the original data, thereby expanding the dataset and mitigating the impact of small sample sizes. Subsequently, we harness the power of optimized particle swarm optimization (OPSO) integrated with support vector machine (SVM) to mine the intricate nonlinear relationships between input and output variables. Then, relying on a case study, the validity of the augmented data and the performance of the developed OPSO-SVM algorithms based on two different sample sizes are studied. Results show that the new datasets generated by ACGAN almost coincide with the actual monitored convergences, exhibiting a correlation coefficient exceeding 0.86. Furthermore, the superiority of the OPSO-SVM algorithm is also demonstrated by comparing the displacement prediction capability of various algorithms through four indices. It is also indicated that the relative error of the predicted displacement values reduces from almost 20% to 5% for the OPSO-SVM model trained with 25 samples and that trained with 625 samples. Finally, the inversed parameters and corresponding convergences predicted by the two OPSO-SVM models trained with different samples are discussed, indicating the feasibility of the combination application of ACGAN and OPSO-SVM in back analysis of geomechanical parameters. This endeavor not only facilitates the progression of underground engineering analysis in scenarios with limited data, but also serves as a pivotal reference for both researchers and practitioners alike.

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基于数据增强算法和机器学习技术的地质力学参数回溯分析

准确的地质力学参数是稳定性评估、灾害预报、结构设计和配套优化的关键因素。基于监测信息的智能反演分析方法被公认为是最高效、最经济的参数反演技术。针对测量数据准确度低、综合数据集稀缺的问题，本研究提出了一种针对小样本量量身定制的创新反演分析框架。我们引入了一种多方面的回溯分析方法，将数据增强与先进的优化和机器学习技术相结合。首先，我们采用基于辅助分类器生成对抗网络（ACGAN）的数据增强算法，生成符合原始数据基本概率分布的合成但真实的样本，从而扩展数据集，减轻小样本量的影响。随后，我们利用集成了支持向量机（SVM）的优化粒子群优化（OPSO）功能，挖掘输入和输出变量之间错综复杂的非线性关系。然后，我们以案例研究为基础，研究了基于两种不同样本量的增强数据的有效性和所开发的 OPSO-SVM 算法的性能。结果表明，ACGAN 生成的新数据集与实际监测到的收敛数据几乎一致，相关系数超过 0.86。此外，通过四项指标比较各种算法的位移预测能力，也证明了 OPSO-SVM 算法的优越性。结果表明，用 25 个样本训练的 OPSO-SVM 模型和用 625 个样本训练的 OPSO-SVM 模型预测位移值的相对误差从近 20% 降至 5%。最后，讨论了用不同样本训练的两个 OPSO-SVM 模型预测的反演参数和相应的收敛性，表明 ACGAN 和 OPSO-SVM 联合应用于地质力学参数反演分析的可行性。这项工作不仅有助于在数据有限的情况下推进地下工程分析，而且对研究人员和从业人员都具有重要的参考价值。

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来源期刊

Underground Space ENGINEERING, CIVIL-

CiteScore

10.20

自引率

14.10%

发文量

审稿时长

63 days

期刊介绍： Underground Space is an open access international journal without article processing charges (APC) committed to serving as a scientific forum for researchers and practitioners in the field of underground engineering. The journal welcomes manuscripts that deal with original theories, methods, technologies, and important applications throughout the life-cycle of underground projects, including planning, design, operation and maintenance, disaster prevention, and demolition. The journal is particularly interested in manuscripts related to the latest development of smart underground engineering from the perspectives of resilience, resources saving, environmental friendliness, humanity, and artificial intelligence. The manuscripts are expected to have significant innovation and potential impact in the field of underground engineering, and should have clear association with or application in underground projects.