Research on Slope Early Warning and Displacement Prediction Based on Multifractal Characterization
Abstract
:1. Introduction
2. Materials and Methods
2.1. Projiect Overview and Monitoring Data
2.2. MF-DFA
2.3. M-K Test Method
2.4. PSO-LSTM Prediction Modeling
2.4.1. LSTM
- Forgetting Gate: This gate determines whether information should be discarded or retained. It processes relevant information through the sigmoid function, producing an output between 0 and 1, where values closer to 0 indicate less importance and greater likelihood of being discarded, while values closer to 1 signify critical information.
- Input Gate: This gate updates the cell state. After processing by both sigmoid and hyperbolic tangent () functions, a final output value closer to 0 indicates less importance, whereas a value closer to 1 indicates significant information.
- Output Gate: Similar to the input gate, the output gate determines the value of the next hidden state in the cell structure. The processed value from this gate is used to decide the information the hidden state should carry, which is then passed along with the new cell state.
2.4.2. Improvement of PSO Algorithm
2.4.3. PSO-LSTM
3. Results and Discussion
3.1. Multifractal Characterization of Slope Surface Displacement
3.2. Early Warning Grading Study of landslides on Slopes
3.2.1. Criteria for Classifying the Warning Level of Landslides on Slopes
- Level I warnings indicate that slope deformation is trending in an extremely unfavorable direction, posing a significant risk of damage and serving as a precursor to imminent disaster. In this scenario, it is recommended to implement necessary disaster prevention and management measures, including evacuation and relocation, to mitigate potential losses.
- Level II warnings indicate that deformation is moving in an unfavorable direction, presenting a general risk of damage.
- Level III warnings suggest that deformation is trending towards stabilization.
3.2.2. Slope Landslide Warning Classification
3.3. Prediction of Slope Surface Displacements
3.3.1. Optimization of Model Parameters
3.3.2. Model Predictions
4. Conclusions
- The application of the MF-DFA method reveals that the slope surface displacements exhibit multiple fractal characteristics, indicating a stable developmental trend toward stabilization.
- The PSO-LSTM prediction model was employed to forecast the deformation trends of slope surface displacements. The results for the test set yielded R2 = 0.91, MAE = 0.55, and RMSE = 0.72. The prediction errors associated with the PSO-LSTM model were minimal, demonstrating that the model effectively meets the requirements for slope surface displacement prediction.
- Synthesis of results from the analysis of multifractal characteristics and deformation predictions indicates that the current warning level for the slope is III, with subsequent deformations trending toward stabilization. Continued routine monitoring and inspections are recommended.
- The slopes analyzed in this study were characterized by a homogenous rock body and limited monitoring point locations. In future studies, a comprehensive fractal characterization of surface displacement monitoring results across multiple slopes with varying rock properties will be conducted. Additionally, numerical modeling of these slopes will be performed to further validate the accuracy of the proposed method. Additionally, incorporating more influencing factors related to slope deformation could further enhance the predictive accuracy of the PSO-LSTM model.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Eigenvalue (Math.) | Group I | Group II | Group III | Group IV |
---|---|---|---|---|
1.19744 | 0.67596 | 0.36077 | 0.2713 | |
0.06878 | −0.1566 | −0.1539 | 0.17519 |
Warning Level | Indicator Criterion | Indicator Criterion | Treatment Measures |
---|---|---|---|
I | Decreasing trend | Increasing trend | Suspend construction and carry out necessary disaster prevention and management or relocation to avoid disaster damage. |
II | Increasing trend | Decreasing trend | Enhance the frequency of monitoring and patrols and make disaster preparedness plans. |
III | Steady trend | Steady trend | Normal monitoring and patrolling. |
Indicators | Z-Value | Growing Trend | Warning Level | Integrated Early Warning |
---|---|---|---|---|
−2.0412 | steady trend | III | III | |
0.4082 | steady trend | III |
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Sun, X.; Su, Y.; Yang, C.; Tan, J.; Liu, D. Research on Slope Early Warning and Displacement Prediction Based on Multifractal Characterization. Fractal Fract. 2024, 8, 522. https://doi.org/10.3390/fractalfract8090522
Sun X, Su Y, Yang C, Tan J, Liu D. Research on Slope Early Warning and Displacement Prediction Based on Multifractal Characterization. Fractal and Fractional. 2024; 8(9):522. https://doi.org/10.3390/fractalfract8090522
Chicago/Turabian StyleSun, Xiaofei, Ying Su, Chengtao Yang, Junzhe Tan, and Dunwen Liu. 2024. "Research on Slope Early Warning and Displacement Prediction Based on Multifractal Characterization" Fractal and Fractional 8, no. 9: 522. https://doi.org/10.3390/fractalfract8090522
APA StyleSun, X., Su, Y., Yang, C., Tan, J., & Liu, D. (2024). Research on Slope Early Warning and Displacement Prediction Based on Multifractal Characterization. Fractal and Fractional, 8(9), 522. https://doi.org/10.3390/fractalfract8090522