Machine Learning Predictive Analysis of Liquefaction Resistance for Sandy Soils Enhanced by Chemical Injection
Abstract
:1. Introduction
2. General Evaluation and Countermeasures to Liquefaction of Sandy Soils
2.1. Chemical Injection Method
2.2. Cyclic Undrained Triaxial Test
2.3. Liquefaction Resistance Ratio
3. Machine Learning Predictive Analysis
3.1. Ensemble Learning
- (1)
- Interpretability and transparency: Decision trees provide a clear and interpretable structure, making it easy to understand how predictions are made. This is particularly important in this study because it involves complex geotechnical data, where providing clear insight into how the model reaches its conclusions is critical to gaining acceptance and trust from the engineering community.
- (2)
- Handling of non-linear relationships: The nature of the dataset in this study, which includes various soil parameters and their interactions, exhibits non-linear patterns. Gradient boosting decision trees are adept at handling such non-linear relationships, making them a suitable choice for predictive analysis in this study.
- (3)
- Flexibility with different types of data: The dataset in this study includes a mix of numeric and categorical variables (such as soil type, chemical composition, etc.). Decision trees can handle this variety without extensive preprocessing, simplifying the modeling process.
- (4)
- Robustness against outliers and missing values: Decision trees are less sensitive to outliers and can handle missing data efficiently, which is a significant advantage given the variability and occasional gaps in geotechnical data.
- (5)
- Effective with ensemble methods: Ensemble learning techniques, which combine multiple machine learning models to improve prediction accuracy, were used. Decision trees integrate well with such ensemble methods (e.g., gradient boosting decision tree) and often result in models that are more accurate and robust than those based on a single algorithm.
3.2. Preparation of Dataset
3.2.1. Details of Training Data
3.2.2. Details of Test Data
3.3. Distinguishing Explanatory and Target Variables
3.4. Evaluation of Prediction Accuracy
- (1)
- Interpretability in the context of geotechnical engineering: In geotechnical engineering, particularly in studies involving practitioners and engineers, the interpretability of the model output is critical. , as a widely recognized and understood metric, provides a clear and direct measure of how well the model’s predictions match the actual observed data.
- (2)
- Quantifying the explanation of variance: The primary goal of this study was to develop a model that could accurately predict liquefaction resistance based on various input characteristics. effectively quantifies the proportion of variance in the dependent variable that can be predicted from the independent variables, which directly aligns with the goal of this study.
- (3)
- Model evaluation in machine learning: In the context of machine learning, particularly ensemble methods, is still a relevant metric for evaluating predictive models. It provides a concise summary of model performance, especially when dealing with continuous outcome variables, as in this study.
4. Results and Discussion
4.1. Selecting Target Variables
4.2. Selecting Explanatory Variables
5. Conclusions
- (1)
- For the development of a predictive model, it is highly recommended to designate the liquefaction resistance ratio as a dependent variable and the other parameters as explanatory variables. This approach allows for a more focused analysis and provides more reliable predictions of the soil behavior under liquefaction conditions.
- (2)
- The exploration of combinations of explanatory variables revealed that using all available variables tends to produce a more stable coefficient of determination (). This stability is critical to the reliability of the model, especially in applications where precision is paramount.
- (3)
- Including the liquefaction resistance ratio in the training dataset significantly increases the predictive accuracy of the model. This finding underscores the importance of this particular variable in understanding and predicting the behavior of chemically enhanced sandy soils under stress.
- (4)
- The results of using AI for making predictions highlight the potential of accurately predicting liquefaction resistance using historical data. This approach not only saves time and resources, but also opens new avenues for studies in soil mechanics and geotechnical engineering.
- (5)
- In addition, this study aimed to validate the effectiveness of the solution-type chemical improvement of sandy soils against liquefaction through an AI-based analysis of existing data from cyclic undrained triaxial tests. The results of this study confirmed that high-precision predictions are achievable using the explanatory variables listed in Table 1. In particular, excluding uniaxial compressive strength as an explanatory variable resulted in the highest accuracy, followed closely by scenarios using all explanatory variables. This suggests a nuanced relationship between the variables and their predictive power that warrants further investigation.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Category | Variable Elements |
---|---|
Condition parameters for specimens of chemically improved sandy soils | Dry density (g/cm3) |
Fine particle content (%) | |
Effective confining pressure (kN/m2) | |
Unconfined compressive strength (kN/m2) | |
Silica gel concentration of injected chemical solution (%) | |
Increase in silica content (mg/g) | |
Results obtained by cyclic undrained triaxial test | Number of cycles to reach 5% strain in both amplitudes |
Number of cycles to reach 95% excess pore pressure ratio | |
Cyclic stress amplitude ratio | |
Liquefaction resistance ratio * |
Case | Explanatory Variables | Target Variables |
---|---|---|
Case-1 | Variable elements shown in Table 1 excluding the liquefaction resistance ratio and the target variable | Number of cycles to reach 5% strain in both amplitudes |
Case-2 | Variable elements shown in Table 1 excluding the liquefaction resistance ratio and the target variable | Number of cycles to reach 95% excess pore pressure ratio |
Case-3 | Variable elements shown in Table 1 excluding the liquefaction resistance ratio and the target variable | Cyclic stress amplitude ratio |
Case-4 | Variable elements shown in Table 1 excluding the target variable | Cyclic stress amplitude ratio |
Variable | Variable Elements | Data for 2 of 272 Specimens | |
---|---|---|---|
Explanatory variables | Dry density (g/cm3) | 1.684 | 1.484 |
Effective confining pressure (kN/m2) | 90 | 165 | |
Fine particle content (%) | 14.8 | 11.4 | |
Unconfined compressive strength (kN/m2) | 539 | 483 | |
Silica gel concentration of injected chemical solution (%) | 12 | 12 | |
Increase in silica content (mg/g) | 11.62 | 7.79 | |
Number of cycles to reach 5% strain in both amplitudes | 18 | 6.5 | |
Number of cycles to reach 95% excess pore pressure ratio | 37 | 38.4 | |
Target variable | Repetitive stress amplitude ratio |
Case-3 and Case-4 | ||||||||
---|---|---|---|---|---|---|---|---|
Explanatory Variables | (a) | (b) | (c) | (d) | (e) | (f) | (g) | (h) |
Dry density (g/cm3) | x | |||||||
Effective confining pressure (kN/m2) | x | |||||||
Fine particle content (%) | x | |||||||
Unconfined compressive strength (kN/m2) | x | |||||||
Silica gel concentration of injected chemical solution (%) | x | |||||||
Increase in silica content (mg/g) | x | |||||||
Number of cycles to reach 5% strain in both amplitudes | x | |||||||
Number of cycles to reach 95% excess pore pressure ratio | x |
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Cong, Y.; Motohashi, T.; Nakao, K.; Inazumi, S. Machine Learning Predictive Analysis of Liquefaction Resistance for Sandy Soils Enhanced by Chemical Injection. Mach. Learn. Knowl. Extr. 2024, 6, 402-419. https://doi.org/10.3390/make6010020
Cong Y, Motohashi T, Nakao K, Inazumi S. Machine Learning Predictive Analysis of Liquefaction Resistance for Sandy Soils Enhanced by Chemical Injection. Machine Learning and Knowledge Extraction. 2024; 6(1):402-419. https://doi.org/10.3390/make6010020
Chicago/Turabian StyleCong, Yuxin, Toshiyuki Motohashi, Koki Nakao, and Shinya Inazumi. 2024. "Machine Learning Predictive Analysis of Liquefaction Resistance for Sandy Soils Enhanced by Chemical Injection" Machine Learning and Knowledge Extraction 6, no. 1: 402-419. https://doi.org/10.3390/make6010020
APA StyleCong, Y., Motohashi, T., Nakao, K., & Inazumi, S. (2024). Machine Learning Predictive Analysis of Liquefaction Resistance for Sandy Soils Enhanced by Chemical Injection. Machine Learning and Knowledge Extraction, 6(1), 402-419. https://doi.org/10.3390/make6010020