Theory-guided machine learning for predicting and minimising surface settlement caused by the excavation of twin tunnels / Chia Yu Huat
In response to worsening urban traffic congestion, metro tunnels have emerged as a solution to ease pressure on road networks. Shield machines, like earth pressure balance and slurry machines, are pivotal in modern tunnel construction. However, twin tunnel construction in urban areas commonly fac...
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| Format: | Thesis |
| Published: |
2024
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| Subjects: | |
| Online Access: | http://studentsrepo.um.edu.my/15379/1/Chia_Yu_Huat.pdf http://studentsrepo.um.edu.my/15379/2/Chia_Yu_Huat.pdf http://studentsrepo.um.edu.my/15379/ |
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| Institution: | Universiti Malaya |
| Summary: | In response to worsening urban traffic congestion, metro tunnels have emerged as a
solution to ease pressure on road networks. Shield machines, like earth pressure balance
and slurry machines, are pivotal in modern tunnel construction. However, twin tunnel
construction in urban areas commonly faces surface settlement (SS) issues, which
threaten nearby structures. Traditional empirical formulas for SS estimation are limited
to specific soil types and lack consideration of other factors. To overcome these
limitations, this study introduces a comprehensive approach that combines 3D numerical
analysis and machine learning to predict SS during twin tunnel excavation. The 3D
numerical analysis factors in construction stages, tunnel geometry, and operational
parameters while incorporating in-situ and lab test results to establish engineering soil
parameters. Validation against field measurements yields R2 values of 0.94 and 0.96 for
the first and second bored tunnels. While 3D numerical analysis provides accurate SS
estimates, it is time-consuming. To enhance prediction efficiency, validated numerical
models serve as the foundation for data generation. This dataset, alongside key parameters
like cover-to-depth ratio, pillar width, soil stiffness, cohesion, friction angle, and
overburden-to-face pressure ratio, integrates into a machine learning framework using a
theory-guided approach. Conditional Tabular Generative Adversarial Networks
(CTGAN) generate additional data from 20% of the 3D numerical analysis results. The
study primarily focuses on tree-based techniques, including Random Forest (RF),
Adaptive Boost (ADABoost), Gradient Boosting Tree (GBT), Extreme Gradient
Boosting (XGBoost), Light Gradient Boosting (LGBoost), and Categorical Gradient
Boosting (CatBoost). Comparative analyses highlight CatBoost as the most accurate SS
predictor among all machine learning (ML) models. Besides, in comparison with the
CTGAN data generated for the ML analysis, data generated from the finite element model used in the ML analysis has outperform the prediction than the CTGAN of synthetic and
hybrid data. This is due to the data generated from the numerical model possess the
pattern for the ML algorithm ease of prediction. In addition, Coati Optimization
algorithm, Particle Swarm Opimisation (PSO) and Bayesian Optimsiation (BO) are
integrated to identify optimal parameters and minimize settlement during twin tunnel
excavation and GBT with the optimisation algorithm has shown consistent capability
identifying the least SS induced by twin tunnels Keyword:
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