TL-iTransformer:通过 iTransformer 和迁移学习革新海面温度预测

IF 2.7 4区 地球科学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Wanhai Jia, Shaopeng Guan, Yuewei Xue
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引用次数: 0

摘要

海表温度(SST)的动态变化对维持海洋生态系统的平衡至关重要。虽然现有的人工智能方法为 SST 预测提供了强大的工具,但它们在数据稀疏性问题上却举步维艰。为了提高稀疏数据条件下的 SST 预测精度,本研究提出了一种创新的预测模型:TL-iTransformer。该模型基于 iTransformer 架构,并结合了专门针对 SST 预测的迁移学习技术。我们首先利用迁移学习策略从数据丰富的海区(源海区)提取 SST 特征,并将这些特征整合到 iTransformer 模型中进行预训练。这一过程为模型提供了先验知识和基本预测能力,使其能够适应数据稀少的海域(目标海域)。然后使用领域自适应技术对模型进行微调,以准确捕捉目标海域的数据特征和分布模式。我们使用加拿大不列颠哥伦比亚海域的真实 SST 数据集进行了一系列实验。结果表明,在数据稀疏条件下,TL-iTransformer 的平均绝对误差(MAE)和平均平方误差(MSE)分别保持在 0.144 和 0.356 以内。此外,随着预测时间跨度的增加,该模型的性能优于四个主流时间序列预测基线模型。所提出的模型能有效解决数据稀疏情况下的 SST 预测问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

TL-iTransformer: Revolutionizing sea surface temperature prediction through iTransformer and transfer learning

TL-iTransformer: Revolutionizing sea surface temperature prediction through iTransformer and transfer learning

The dynamics of Sea Surface Temperature (SST) are crucial for maintaining the balance of marine ecosystems. While existing artificial intelligence methods offer powerful tools for SST prediction, they struggle with data sparsity issues. To enhance SST prediction accuracy under sparse data conditions, this study proposes an innovative prediction model: TL-iTransformer. This model is based on the iTransformer architecture and incorporates transfer learning techniques specifically tailored for SST prediction. We begin by extracting SST features from data-rich sea areas (source sea areas) using a transfer learning strategy, integrating these features into the iTransformer model for pre-training. This process imparts the model with a priori knowledge and basic prediction capabilities, enabling it to adapt to data-sparse sea areas (target sea areas). The model is then fine-tuned using domain adaptive techniques to accurately capture the data characteristics and distribution patterns of the target sea area. We conducted a series of experiments using a real SST dataset from the sea area of British Columbia, Canada. The results demonstrate that TL-iTransformer maintains the Mean Absolute Error (MAE) and Mean Squared Error (MSE) within 0.144 and 0.356, respectively, under data sparsity conditions. Additionally, it outperforms four mainstream time-series prediction baseline models as the prediction time span increases. The proposed model can effectively address the issue of SST prediction in situations with sparse data.

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来源期刊
Earth Science Informatics
Earth Science Informatics COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
4.60
自引率
3.60%
发文量
157
审稿时长
4.3 months
期刊介绍: The Earth Science Informatics [ESIN] journal aims at rapid publication of high-quality, current, cutting-edge, and provocative scientific work in the area of Earth Science Informatics as it relates to Earth systems science and space science. This includes articles on the application of formal and computational methods, computational Earth science, spatial and temporal analyses, and all aspects of computer applications to the acquisition, storage, processing, interchange, and visualization of data and information about the materials, properties, processes, features, and phenomena that occur at all scales and locations in the Earth system’s five components (atmosphere, hydrosphere, geosphere, biosphere, cryosphere) and in space (see "About this journal" for more detail). The quarterly journal publishes research, methodology, and software articles, as well as editorials, comments, and book and software reviews. Review articles of relevant findings, topics, and methodologies are also considered.
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