Enhancing Deep Learning Soil Moisture Forecasting Models by Integrating Physics-based Models

IF 6.5 2区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES
Lu Li, Yongjiu Dai, Zhongwang Wei, Wei Shangguan, Nan Wei, Yonggen Zhang, Qingliang Li, Xian-Xiang Li
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引用次数: 0

Abstract

Accurate soil moisture (SM) prediction is critical for understanding hydrological processes. Physics-based (PB) models exhibit large uncertainties in SM predictions arising from uncertain parameterizations and insufficient representation of land-surface processes. In addition to PB models, deep learning (DL) models have been widely used in SM predictions recently. However, few pure DL models have notably high success rates due to lacking physical information. Thus, we developed hybrid models to effectively integrate the outputs of PB models into DL models to improve SM predictions. To this end, we first developed a hybrid model based on the attention mechanism to take advantage of PB models at each forecast time scale (attention model). We further built an ensemble model that combined the advantages of different hybrid schemes (ensemble model). We utilized SM forecasts from the Global Forecast System to enhance the convolutional long short-term memory (ConvLSTM) model for 1–16 days of SM predictions. The performances of the proposed hybrid models were investigated and compared with two existing hybrid models. The results showed that the attention model could leverage benefits of PB models and achieved the best predictability of drought events among the different hybrid models. Moreover, the ensemble model performed best among all hybrid models at all forecast time scales and different soil conditions. It is highlighted that the ensemble model outperformed the pure DL model over 79.5% of in situ stations for 16-day predictions. These findings suggest that our proposed hybrid models can adequately exploit the benefits of PB model outputs to aid DL models in making SM predictions.

通过整合物理模型加强深度学习土壤水分预报模型
准确的土壤水分(SM)预测对于了解水文过程至关重要。基于物理(PB)的模型在土壤水分预测中表现出很大的不确定性,原因是参数不确定和对地表过程的表征不足。除了 PB 模型,深度学习(DL)模型最近也被广泛应用于 SM 预测。然而,由于缺乏物理信息,很少有纯 DL 模型具有显著的高成功率。因此,我们开发了混合模型,以有效地将 PB 模型的输出集成到 DL 模型中,从而改进 SM 预测。为此,我们首先开发了一种基于注意力机制的混合模型(注意力模型),以便在每个预测时间尺度上利用预报模型的优势。我们进一步建立了一个集合模型,结合了不同混合方案的优势(集合模型)。我们利用全球预报系统的 SM 预测来增强卷积长短期记忆模型(ConvLSTM),以进行 1-16 天的 SM 预测。我们对所提出的混合模型的性能进行了研究,并与现有的两个混合模型进行了比较。结果表明,注意力模型可以充分利用 PB 模型的优势,在不同的混合模型中对干旱事件的预测能力最强。此外,在所有预报时间尺度和不同土壤条件下,集合模型在所有混合模型中表现最佳。值得强调的是,在 79.5% 的原地站点中,集合模型的 16 天预测结果优于纯 DL 模型。这些研究结果表明,我们提出的混合模式可以充分发挥 PB 模式输出的优势,帮助 DL 模式进行 SM 预测。
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来源期刊
Advances in Atmospheric Sciences
Advances in Atmospheric Sciences 地学-气象与大气科学
CiteScore
9.30
自引率
5.20%
发文量
154
审稿时长
6 months
期刊介绍: Advances in Atmospheric Sciences, launched in 1984, aims to rapidly publish original scientific papers on the dynamics, physics and chemistry of the atmosphere and ocean. It covers the latest achievements and developments in the atmospheric sciences, including marine meteorology and meteorology-associated geophysics, as well as the theoretical and practical aspects of these disciplines. Papers on weather systems, numerical weather prediction, climate dynamics and variability, satellite meteorology, remote sensing, air chemistry and the boundary layer, clouds and weather modification, can be found in the journal. Papers describing the application of new mathematics or new instruments are also collected here.
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