Enhanced forecasting of chlorophyll-a concentration in coastal waters through integration of Fourier analysis and Transformer networks

The accurate prediction of chlorophyll-a (chl-a) concentration in coastal waters is essential to coastal economies and ecosystems as it serves as the key indicator of harmful algal blooms. Although powerful machine learning methods have made strides in forecasting chl-a concentrations, there remains...

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Bibliographic Details
Published in:Water research (Oxford) 2024-10, Vol.263, p.122160, Article 122160
Main Authors: Sun, Xiaoyao, Yan, Danyang, Wu, Sensen, Chen, Yijun, Qi, Jin, Du, Zhenhong
Format: Article
Language:English
Subjects:
Chlorophyll - analysis
Chlorophyll A
Chlorophyll-a concentrations
Deep Learning
Environmental Monitoring - methods
Forecasting
Fourier Analysis
Harmful algal blooms
Seawater - chemistry
Time series prediction
Transformer
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Summary:The accurate prediction of chlorophyll-a (chl-a) concentration in coastal waters is essential to coastal economies and ecosystems as it serves as the key indicator of harmful algal blooms. Although powerful machine learning methods have made strides in forecasting chl-a concentrations, there remains a gap in effectively modeling the dynamic temporal patterns and dealing with data noise and unreliability. To wiggle out of quagmires, we introduce an innovative deep learning prediction model (termed ChloroFormer) by integrating Transformer networks with Fourier analysis within a decomposition architecture, utilizing coastal in-situ data from two distinct study areas. Our proposed model exhibits superior capabilities in capturing both short-term and middle-term dependency patterns in chl-a concentrations, surpassing the performance of six other deep learning models in multistep-ahead predictive accuracy. Particularly in scenarios involving extreme and frequent blooms, our proposed model shows exceptional predictive performance, especially in accurately forecasting peak chl-a concentrations. Further validation through Kolmogorov–Smirnov tests attests that our model not only replicates the actual dynamics of chl-a concentrations but also preserves the distribution of observation data, showcasing its robustness and reliability. The presented deep learning model addresses the critical need for accurate prediction on chl-a concentrations, facilitating the exploration of marine observations with complex dynamic temporal patterns, thereby supporting marine conservation and policy-making in coastal areas. [Display omitted] •A deep learning model (ChloroFormer) is introduced for chlorophyll-a prediction.•ChloroFormer surpasses baselines in both short-term and medium-term horizons.•ChloroFormer excels in predicting peak chlorophyll-a values with high accuracy.•ChloroFormer maintains a high goodness of fit to the observed data distribution.
ISSN:0043-1354
1879-2448
1879-2448
DOI:10.1016/j.watres.2024.122160