An Efficient Method for Reliability Analysis of High-Speed Railway Tunnel Convergence in Spatially Variable Soil Based on a Deep Convolutional Neural Network

IF 3.3 2区 工程技术 Q2 ENGINEERING, GEOLOGICAL
Houle Zhang, Fang Luo, Weijuan Geng, Haishan Zhao, Yongxin Wu
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引用次数: 0

Abstract

A novel deep learning method based on the two-dimensional convolutional neural network (2D-CNN) was proposed to predict the horizontal and vertical convergences of high-speed railway tunnels considering the spatial variability of soil Young’s modulus. The input and output of the neural network were the soil Young’s modulus random field and tunnel convergence, respectively. The coefficient of determination (R2) and the relative error of the predicted results were determined to evaluate the prediction performance and extrapolating ability of the proposed CNN model. The prediction accuracy increased with increasing scale of fluctuation (SOF) from 10 to 60 m as the R2 increased. Two prediction data sets with 10,000 samples (per set) were generated to illustrate the model, where the R2 values were greater than 0.99. Also, the relative errors of the limit values of 90% and 99% exceeding the probability between the CNN-predicted and random finite difference method (RFDM)-calculated convergences were within 0.64%. The computational efficiency was significantly improved by 2,371 times with satisfactory accuracy. The trained CNN model showed excellent extrapolation ability in solving cases with an anisotropic random field and variation of COV. Results indicated that the proposed CNN model is a promising surrogate of RFDM with Monte Carlo simulations to analyze tunnel convergence considering soil Young’s modulus in an isotropic random field.Practical ApplicationsThe spatial variability of soil parameters is commonly believed to have a significant influence in assessing tunnel reliability. Traditional probabilistic analysis of tunnel deformation was generally conducted by time-inefficient random finite-element/difference methods with Monte Carlo simulations. Recently, machine learning methods are vastly applied in geotechnical engineering with the rapid development of computational techniques, aiming to improve calculation efficiency. This study develops a two-dimensional convolutional neural network-based model to predict tunnel convergence with consideration of soil spatial variability. The input and output of the surrogate model are the soil Young’s modulus random field and tunnel convergence, respectively. The coefficient of determination, mean square error, and relative error are used to evaluate the prediction performance. The surrogate model is trained by isotropic random field data sets and performs excellent extrapolation ability on the data sets of the anisotropic random field. It suggests that the proposed model can conduct a probabilistic analysis of tunnel convergence in spatially variable soil with high accuracy.
基于深度卷积神经网络的空间变土高速铁路隧道收敛可靠性分析方法
考虑土壤杨氏模量的空间变异性,提出了一种基于二维卷积神经网络(2D-CNN)深度学习的高速铁路隧道水平和垂直收敛预测方法。神经网络的输入和输出分别为土壤杨氏模量随机场和隧道收敛。通过测定预测结果的决定系数(R2)和相对误差来评价所提CNN模型的预测性能和外推能力。在10 ~ 60 m波动尺度范围内,随着R2的增大,预测精度逐渐提高。生成两个10000个样本(每组)的预测数据集来说明模型,其中R2值大于0.99。cnn预测与随机有限差分法(RFDM)计算的收敛概率的90%和99%极限值的相对误差在0.64%以内。计算效率提高了2371倍,精度令人满意。训练后的CNN模型在求解具有各向异性随机场和COV变化的情况下表现出良好的外推能力。结果表明,本文提出的CNN模型可作为RFDM的替代模型,在蒙特卡罗模拟中用于分析各向同性随机场中考虑土壤杨氏模量的隧道收敛性。实际应用土壤参数的空间变异性通常被认为对隧道可靠性评估有重要影响。传统的隧道变形概率分析一般采用蒙特卡罗模拟的无时间效率随机有限元/差分法进行。近年来,随着计算技术的飞速发展,机器学习方法被广泛应用于岩土工程中,旨在提高计算效率。本文建立了一种基于二维卷积神经网络的模型来预测考虑土壤空间变异性的隧道收敛。代理模型的输入和输出分别为土壤杨氏模量随机场和隧道收敛。用决定系数、均方误差和相对误差来评价预测效果。该模型采用各向异性随机场数据集进行训练,对各向异性随机场数据集具有良好的外推能力。结果表明,该模型可以高精度地进行空间变化土体中隧道收敛的概率分析。
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来源期刊
International Journal of Geomechanics
International Journal of Geomechanics ENGINEERING, GEOLOGICAL-
CiteScore
6.40
自引率
13.50%
发文量
374
期刊介绍: The International Journal of Geomechanics (IJOG) focuses on geomechanics with emphasis on theoretical aspects, including computational and analytical methods and related validations. Applications of interdisciplinary topics such as geotechnical and geoenvironmental engineering, mining and geological engineering, rock and blasting engineering, underground structures, infrastructure and pavement engineering, petroleum engineering, engineering geophysics, offshore and marine geotechnology, geothermal energy, lunar and planetary engineering, and ice mechanics fall within the scope of the journal. Specific topics covered include numerical and analytical methods; constitutive modeling including elasticity, plasticity, creep, localization, fracture and instabilities; neural networks, expert systems, optimization and reliability; statics and dynamics of interacting structures and foundations; liquid and gas flow through geologic media, contaminant transport and groundwater problems; borehole stability, geohazards such as earthquakes, landslides and subsidence; soil/rock improvement; and the development of model validations using laboratory and field measurements.
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