融合固结模型和Transformer填海造地InSAR形变预测

InSAR Deformation Prediction for Land Reclamation Integrating Consolidation Model and Transformer

  • 摘要: 海岸带大规模填海造地工程缓解了土地资源短缺现状,但复杂地质条件易导致填海区地基承载力不足,引发沉降,且持续时间较长。在海岸带填海造地形变未来演化预测中,传统物理和统计方法泛化性与鲁棒性不足,深度学习方法物理特征利用有限。本研究融合固结模型与Transformer预测填海造地InSAR形变趋势。该方法基于固结模型分解InSAR时序形变的物理趋势与残差部分,利用Transformer 编码器捕获残差的时序依赖关系,并通过注意力池化机制增强关键时间特征,实现了沉降的高精度预测。实验区域位于宁德市福宁湾、福州长乐国际机场与漳州市双鱼岛,共计662景Sentinel-1A影像。结果表明所提预测模型在测试集上性能最优,相比传统机器学习方法(SVR和RF)、固结模型、Transformer、LSTM和Informer模型,RMSE分别降低87.3%、83.7%、54.7%、20.4%、24.7%和10.0%。本研究融合物理先验模型与深度学习提升InSAR形变时序预测中的有效性,为海岸带及填海区沉降预测与治理提供了有效技术支撑。

     

    Abstract: Objectives: Large-scale coastal land reclamation often triggers prolonged and uneven subsidence in soft-soil areas, making reliable deformation prediction essential for infrastructure safety. Existing methods face inherent limitations: physics-based consolidation models capture primary trends but generalize poorly to complex nonlinear signals; statistical machine learning approaches such as SVR and RF lack physical constraints and extrapolate unreliably; and deep learning architectures like LSTM, Transformer and Informer rarely incorporate domain-specific physical knowledge, compromising interpretability and physical consistency. Methods: A hybrid framework is developed that tightly couples a consolidation model with a Transformer encoder. The InSAR deformation time series is first decomposed into a physically governed consolidation trend and a residual component. A consolidation model is fitted to extract the long-term subsidence trend, while the residual—containing seasonal fluctuations, secondary compression, and anthropogenic disturbances—is modeled by a Transformer encoder. Multi-head self-attention captures long-range temporal dependencies within the residual, and an attention pooling mechanism adaptively emphasizes the most critical time steps for forecasting. The final prediction is obtained by summing the extrapolated physical trend and the predicted residual. Validation is conducted at three reclaimed coastal sites in Fujian Province—Funing Bay (Ningde), Fuzhou Changle International Airport, and Shuangyu Island (Zhangzhou)—using 662 Sentinel-1A images processed by time-series InSAR. Results: The hybrid model achieves the highest test-set accuracy across all sites. Compared with SVR, RF, a standalone consolidation model, a standard Transformer, LSTM, and Informer, RMSE is reduced by 87.3%, 83.7%, 54.7%, 20.4%, 24.7%, and 10.0%, respectively. The drastic improvement over the pure consolidation model confirms the necessity of capturing residual dynamics, and the clear gains over deep learning baselines demonstrate the value of physical priors. Conclusions: Integrating a consolidation model with Transformer-based deep learning markedly enhances InSAR deformation forecasting accuracy and physical credibility. The proposed approach provides an effective tool for subsidence monitoring, early warning, and risk mitigation in coastal reclamation zones.

     

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