Base resistance of super-large and long piles in soft soil: performance of artificial neural network model and field implications

Huynh, Quoc Thien; Nguyên, Thanh Trung; Nguyen, Hoang

doi:10.1007/s11440-022-01736-w

Cited by 14 publications

(8 citation statements)

References 59 publications

(72 reference statements)

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“…On the other hand, in Case 2, the base resistance is negligible as the soil underneath the pile tip is soft and gives insignificant resistance to the applied load (Figure 1b). This case can be observed in many coastal regions such as the Mekong Delta, Bangkok and Jakarta, where soft soil layers (SPT < 10) can reach up to 40 m [9,10]. In this context, despite using very long piles, the pile tip cannot reach a rigid layer, so there is a minimal contribution from the base to the pile bearing capacity.…”

Section: Introductionmentioning

confidence: 95%

“…For example, when the base soil is medium and fine sand, the base resistance can slowly increase due to the high compressibility of the soil underneath before reaching a larger magnitude at later stages. In fact, Case 3 is very common in practice, especially when piles, even when very long, cannot reach the rigid layer [9,13]. In this process, the development of settlement (i.e., the displacement of pile head) is the key indicator for the mobilization of the load bearing mechanism.…”

Section: Introductionmentioning

confidence: 99%

“…Further, the database collected for establishing ML models was relatively limited in past investigations, e.g., only short and medium piles were considered, while mobilized base resistance with increasing load was still overlooked due to the lack of appropriate field tests. Recent efforts have been made to predict base resistance of long piles based on more than 1100 datapoints collected from different real-life projects [9]; however, this study used a conventional basic ANN model, resulting in a relatively medium level of prediction quality (i.e., R 2 = 0.8-0.87). More importantly, the past applications of ML for pile foundation were often criticized for their black-box nature regarding, e.g., the unseen interactions among different features and the lack of validation with existing methods.…”

Section: Introductionmentioning

confidence: 99%

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Influence of Settlement on Base Resistance of Long Piles in Soft Soil—Field and Machine Learning Assessments

Nguyen,

Le,

Huynh

et al. 2024

Geotechnics

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Understanding the role that settlement can have on the base resistance of piles is a crucial matter in the design and safety control of deep foundations under various buildings and infrastructure, especially for long to super-long piles (60–90 m length) in soft soil. This paper presents a novel assessment of this issue by applying explainable machine learning (ML) techniques to a robust database (1131 datapoints) of fully instrumented pile tests across 37 real-life projects in the Mekong Delta. The analysis of data based on conventional methods shows distinct responses of long piles to rising settlement, as compared to short piles. The base resistance can rapidly develop at a small settlement threshold (0.015–0.03% of pile’s length) and contribute up to 50–55% of the total bearing capacity in short piles, but it slowly rises over a wide range of settlement to only 20–25% in long piles due to considerable loss of settlement impact over the depth. Furthermore, by leveraging the advantages of ML methods, the results significantly enhance our understanding of the settlement–base resistance relationship through explainable computations. The ML-based prediction method is compared with popular practice codes for pile foundations, further attesting to the high accuracy and reliability of the newly established model.

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Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Influence of Settlement on Base Resistance of Long Piles in Soft Soil—Field and Machine Learning Assessments

Nguyen,

Le,

Huynh

et al. 2024

Geotechnics

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“…All the pile foundation sample data in this study were obtained from Ho Chi Minh City, Vietnam, as detailed in reference [9]. The project is located at the edge of the Meizhou River Delta, downstream of the Saigon River.…”

Section: Case Study and Sample Preparationmentioning

confidence: 99%

Predicting base resistance of super-long piles using a random forest model: A case study from Ho Chi Minh city

Weng,

Jia

2024

IOP Conf. Ser.: Earth Environ. Sci.

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The prediction of the base resistance for long piles is usually challenging because of the impact of material characteristics and the influence of the nature of the surrounding soil. Artificial intelligence models have been applied in various geotechnical engineering fields, and significant results have been achieved. Based on a well-instrumented static load test dataset (1131 data points) from various projects in the soft soil area of Ho Chi Minh City, this study established a random forest (RF) model considering five input parameters, including the applied load, load point displacement, axial stiffness, standard penetration test value of the soil beneath the pile toe, and the distance from the load point to the pile toe. Twenty percent of the data was designated as the test set, which was used to make predictions using the established model. The results show that the RF model has good predictive performance in terms of prediction accuracy and reliability. A sensitivity analysis of the input factors provided a deeper understanding of the base resistance mechanism, which is important in pile foundation design practice.

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“…To address these challenges, Ouyang et al [59] proposed a flexible solution for the analysis of laterally loaded piles, leveraging the power of machine learning. Machine learning, an emerging artificial intelligence technology, offers distinct advantages in intensive computation and universal approximation capabilities (He et al [37], Huynh et al [42], Hsiao et al [40], Zhang et al [83], Zhang et al [84], Nguen et al [57], [58]). It commonly utilizes neural networks, which are mathematical models with layered structures comprising linear transformations and nonlinear activation functions.…”

Section: Introductionmentioning

confidence: 99%

Analyzing Laterally Loaded Piles in Multi-layered Cohesive Soils: a Hybrid Bnwf Approach With Validation and Parametric Study

Gendy

2024

Preprint

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Pile foundations frequently encounter lateral loads originating from various hazards. These types of foundations are commonly utilized in structures like bridges, retaining walls, and high-rise buildings. Analyzing laterally loaded piles presents a complex geotechnical problem that entails considering multiple interrelated design factors. It requires accounting for structural bending behavior, soil-structure interaction, soil nonlinearity, and optimizing for cost-effectiveness. In this paper, the commonly used approach beam on nonlinear Winkler foundation is developed. This methodology involves representing the pile using one-dimensional finite elements in the vertical direction, incorporating nonlinear bending stiffness. Additionally, soil deformation is determined using empirically derived P-y curves, which are obtained from full-scale field tests. By combining the pile stiffness with the soil stiffness considering the full interaction between the pile and the surrounding soil, the complete stiffness matrix of the single pile is formed, leading to a reduction in the number of equations that need to be solved. Both Euler and Timoshenko beams are considered, and the analysis is conducted using both finite elements and finite difference methods. The proposed hybrid approach is validated by comparing its results from analyzing laterally loaded piles in multi-layered soil profiles with those obtained from different models in existing literature and available field measurements. The well-known software ELPLA is equipped with the proposed hybrid technique. Furthermore, a parametric study investigates the behavior of laterally loaded pipe piles in soft and stiff clay, culminating in the presentation of dimensionless curves from this study.

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Base resistance of super-large and long piles in soft soil: performance of artificial neural network model and field implications

Cited by 14 publications

References 59 publications

Influence of Settlement on Base Resistance of Long Piles in Soft Soil—Field and Machine Learning Assessments

Influence of Settlement on Base Resistance of Long Piles in Soft Soil—Field and Machine Learning Assessments

Predicting base resistance of super-long piles using a random forest model: A case study from Ho Chi Minh city

Analyzing Laterally Loaded Piles in Multi-layered Cohesive Soils: a Hybrid Bnwf Approach With Validation and Parametric Study

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