大洪水
学习迁移
人工神经网络
操作员(生物学)
气象学
洪水预报
计算机科学
人工智能
环境科学
地理
生物化学
转录因子
基因
抑制因子
考古
化学
作者
Qingsong Xu,Leon Frederik De Vos,Yilei Shi,Nils Rüther,Axel Bronstert,Xiao Xiang Zhu
标识
DOI:10.1016/j.jhydrol.2025.133705
摘要
• Deep neural operator is proposed for effective, downscaled urban flood forecasting • Fine-tuning-based DNO is introduced for efficient cross-scenario forecasting. • Domain adaptation-based DNO is presented for continuous learning across domains. • A benchmark dataset is established to assess various urban flood forecasting methods. Physics-based models provide accurate flood modeling but are limited by their dependence on high-quality data and computational demands, particularly in complex urban environments. Machine learning-based surrogate models like neural operators present a promising alternative; however, their practical application in urban flood modeling remains challenges, such as insufficient feature representation, high memory demands, and limited transferability. To address these challenges, this study introduces a deep neural operator (DNO) and a transfer learning-based DNO for fast, accurate, resolution-invariant, and cross-scenario urban flood forecasting. The DNO features an enhanced Fourier layer with skip connections for improved memory efficiency, alongside a deep encoder-decoder framework and an urban-embedded residual loss to enhance modeling effectiveness. The transfer learning-based DNO further integrates a fine-tuning-based approach for efficient cross-scenario forecasting in the target domain and a domain adaptation-based strategy for continuous learning across diverse domains. The fine-tuning-based DNO enables rapid adaptation to target domains, while the domain adaptation-based DNO mitigates knowledge forgetting from the source domain. Experimental results demonstrate that the proposed DNO significantly outperforms existing neural solvers using a comprehensive urban flood benchmark dataset, particularly in predicting high water depths and exhibiting exceptional zero-shot downscaling performance for high-resolution forecasting. Moreover, the fine-tuning-based DNO enhances transferability for cross-scenario urban flood forecasting, while the domain adaptation-based DNO achieves accurate flood predictions in both source and target domains, even with limited labeled target data. Through the combination of these ML methods and the benchmark dataset, a practical tool is established for effective, cross-scenario, and downscaled spatiotemporal urban flood forecasting.
科研通智能强力驱动
Strongly Powered by AbleSci AI