光学和SAR植被指数在意大利波谷葡萄园监测中的联合分析：生物量动态和物候阶段评估

IF 3.6 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-09-01 DOI:10.1109/ACCESS.2025.3604663

Andrea Bergamaschi;Abhinav Verma;Avik Bhattacharya;Fabio Dell’Acqua

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引用次数: 0

摘要

多极化合成孔径雷达（SAR）技术在农业上的应用越来越受到重视。由于全天候、昼夜运行和高回访频率，它提供了独特的监测植被动态的能力。本研究首次将双偏振雷达植被指数（DpRVI）与光学指数相结合，对葡萄园作物进行了综合分析。葡萄园由于其明显的行向而表现出明显的非各向同性散射行为，使其成为遥感的特别具有挑战性和有趣的目标。本研究进一步探讨了DpRVI与光学植被指数之间的关系，揭示了两者信息的互补性。DpRVI与光学指数（$r \leq 0.24$）之间的低相关性表明，它们捕捉到了不同的植被结构和健康方面。值得注意的是，DpRVI在整个生长季节呈现抛物线趋势，这可能反映了从Winkler指数推断的生物量动态。与反映植被绿度的光学指数不同，DpRVI似乎与生物量生长更直接相关，与特定物候相一致。这项研究与PNRR-NODES项目的目标一致，该项目旨在促进基于自然的解决方案（NbS），以实现可持续的葡萄园管理。应用DpRVI监测葡萄园是将遥感技术纳入更广泛的适应气候变化和减少风险战略领域的一部分，强调基于sar的创新型监测在可持续农业中的作用。

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Joint Analysis of Optical and SAR Vegetation Indices for Vineyard Monitoring: Assessing Biomass Dynamics and Phenological Stages Over Po Valley, Italy

Multi-polarized Synthetic Aperture Radar (SAR) technology has gained increasing attention in agricultural applications. It offers unique capabilities for monitoring vegetation dynamics thanks to its all-weather, day-and-night operation and high revisit frequency. This study presents, for the first time, a comprehensive analysis combining dual-polarimetric radar vegetation index (DpRVI) with optical indices to characterize vineyard crops. Vineyards exhibit distinct non-isotropic scattering behavior due to their pronounced row orientation, making them particularly challenging and interesting targets for remote sensing. The study further explores the relationship between DpRVI and optical vegetation indices, revealing the complementary nature of their information. The low correlation between DpRVI and optical indices (

$r \leq 0.24$

) suggests they capture distinct vegetation structure and health aspects. Notably, DpRVI exhibits a parabolic trend across the growing season, which may reflect biomass dynamics as inferred from the Winkler Index. Unlike optical indices reflecting vegetation greenness, DpRVI appears more directly related to biomass growth, aligning with specific phenological phases. This research aligns with the objectives of the PNRR-NODES project, which promotes nature-based solutions (NbS) for sustainable vineyard management. The application of DpRVI for monitoring vineyards is part of integrating remote sensing techniques into the broader field of strategies for climate-related change adaptation and risk reduction, emphasizing the role of innovative SAR-based monitoring in sustainable agriculture.

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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