An Improved Spatiotemporal Fusion Framework for Land-Cover Temporal Harmonization of High-Resolution Remote Sensing Images

IF 4.7 2区地球科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing Pub Date : 2025-04-16 DOI:10.1109/JSTARS.2025.3561514

Kangning Li;Zilin Xie;Xiaojun Qiao;Jinzhong Yang;Jinbao Jiang

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Abstract

High-resolution remote sensing images, with fine spatial detail but limited coverage and infrequent revisits, often exhibit temporal discrepancies that hinder large-scale Earth observations. While spatiotemporal fusion (STF) methods offer a solution, they often lead to reduced spatial resolution and struggle with multisource and multitemporal image processing. To address this issue, an improved STF framework for temporal harmonization (STF-TH) was proposed. Specifically, STF-TH first applies an existing STF method for initial temporal transformation. Second, spatial resolution is recovered through spatial texture correction, referencing the fine texture of the original image. Finally, temporal color correction leverages the consistency of coarse images to further reduce temporal discrepancies among results. STF-TH was evaluated across datasets collected from different satellites, regions, and times, and validated via both qualitative and quantitative analyses at global, local, and line profile levels. Compared with five STF methods, STF-TH demonstrated significant improvements, ranging from 12% to 261.28% across six image quality evaluation metrics. In addition, STF-TH achieved superior spatial texture preservation and temporal color transformation, with improvements of 51.85% and 59.07%, respectively. Furthermore, STF-TH significantly improved the subsequent classification accuracy, with the F1-score and the overall accuracy improved to 89.88% and 93.87%, respectively. Notably, these STF-based improvements in STF-TH incurred negligible additional time consumption. Experimental results confirm that STF-TH is an efficient and effective model for temporal harmonization, considering potential problems of noise, patch effects, and spatial resolution degradation in traditional STF processing. STF-TH is expected to be applied to large-scale high-resolution annual land-cover monitoring.

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一种改进的高分辨率遥感影像土地覆盖时间协调时空融合框架

高分辨率遥感图像具有精细的空间细节，但覆盖范围有限，而且不经常重访，往往表现出时间差异，阻碍了大规模的地球观测。虽然时空融合（STF）方法提供了一种解决方案，但它们往往导致空间分辨率降低，并且难以处理多源和多时间图像。为了解决这个问题，提出了一个改进的时间协调的STF框架（STF- th）。具体来说，STF- th首先应用已有的STF方法进行初始时间变换。其次，参考原始图像的精细纹理，通过空间纹理校正恢复空间分辨率。最后，时间颜色校正利用粗糙图像的一致性，进一步减少结果之间的时间差异。通过从不同卫星、地区和时间收集的数据集对STF-TH进行评估，并通过全球、局部和线路剖面水平的定性和定量分析进行验证。与5种STF方法相比，STF- th在6个图像质量评价指标上表现出显著的改进，改进幅度从12%到261.28%不等。此外，STF-TH在空间纹理保存和时间颜色转换方面均取得了较好的效果，分别提高了51.85%和59.07%。此外，STF-TH显著提高了后续分类准确率，f1得分和总体准确率分别提高到89.88%和93.87%。值得注意的是，这些基于stf的改进在STF-TH中产生的额外时间消耗可以忽略不计。实验结果证实，考虑到传统STF处理中可能存在的噪声、斑块效应和空间分辨率下降等问题，STF- th是一种高效的时间协调模型。STF-TH有望应用于大规模高分辨率年度土地覆盖监测。

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来源期刊

IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 地学-成像科学与照相技术

CiteScore

9.30

自引率

10.90%

发文量

563

审稿时长

4.7 months

期刊介绍： The IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing addresses the growing field of applications in Earth observations and remote sensing, and also provides a venue for the rapidly expanding special issues that are being sponsored by the IEEE Geosciences and Remote Sensing Society. The journal draws upon the experience of the highly successful “IEEE Transactions on Geoscience and Remote Sensing” and provide a complementary medium for the wide range of topics in applied earth observations. The ‘Applications’ areas encompasses the societal benefit areas of the Global Earth Observations Systems of Systems (GEOSS) program. Through deliberations over two years, ministers from 50 countries agreed to identify nine areas where Earth observation could positively impact the quality of life and health of their respective countries. Some of these are areas not traditionally addressed in the IEEE context. These include biodiversity, health and climate. Yet it is the skill sets of IEEE members, in areas such as observations, communications, computers, signal processing, standards and ocean engineering, that form the technical underpinnings of GEOSS. Thus, the Journal attracts a broad range of interests that serves both present members in new ways and expands the IEEE visibility into new areas.