Identifying the optimal phenological period for discriminating subtropical fruit tree crops using multi-temporal Sentinel-2 data and Google Earth Engine

IF 0.3 Q4 REMOTE SENSING

South African Journal of Geomatics Pub Date : 2023-10-20 DOI:10.4314/sajg.v12i.2.10

Yingisani Chabalala, Elhadi Adam, Khalid Adem Ali

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引用次数: 1

Abstract

The accurate and appropriate monitoring of the spatial distribution of fruit tree crops is crucial for crop management and yield forecasting. Owing to both inter- and intra-farm fragmentation and overlapping phenological cycles, the classification of fruit tree crops in subtropical agriculture using single-date images is challenging. Therefore, this research aimed to identify the optimal temporal window in which the crucial phenological stages can be used to classify fruit tree crops in Levubu, Limpopo province, using a random forest (RF) classifier. Phenological metrics were extracted from 12-month Multispectral Instrument (MSI) images from Sentinel-2 (S2). The RF classification algorithm attained an overall accuracy of 84.89% and a kappa coefficient of 83%. The user accuracy ranged from 62 to 100%, while the producer accuracy ranged from 60 to 100%. An analysis of variance was used to assess whether the overall accuracies among the S2 monthly composites were statistically significant. The results showed distinct spectral differences between fruit trees. In April, there were differences observed during the harvesting and senescence of the mango and macadamia nut crops. In May, there were differences observed during the senescence of the macadamia nut, mango, and guava crops. In June and July, there were distinct spectral differences during the peak flowering stage of the avocado, macadamia nut, and mango crops, as well as in the fruiting stage of the banana crops. Followed by the red-edge bands, the shortwave infrared bands were significant in differentiating between the respective fruit tree crops. The results of this research provide evidence-based information that can assist farm managers and horticulturists in making informed decisions. This is critical in achieving effective agricultural management and in ensuring the sustainability of local horticultural systems.

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利用多时相Sentinel-2数据和Google Earth Engine识别亚热带果树作物的最佳物候期

准确、合理地监测果树作物的空间分布，对果树作物管理和产量预测具有重要意义。由于农场间和农场内的破碎化和物候周期重叠，利用单日期图像对亚热带农业果树作物进行分类具有挑战性。因此，本研究旨在利用随机森林(RF)分类器，确定林波波省Levubu地区关键物候阶段可用于果树作物分类的最佳时间窗口。物候指标提取自Sentinel-2 (S2)的12个月多光谱仪器(MSI)图像。RF分类算法的总体准确率为84.89%，kappa系数为83%。用户的准确度在62%到100%之间，而生产者的准确度在60%到100%之间。方差分析用于评估S2个月综合数据的总体准确性是否具有统计学意义。结果表明，不同果树间光谱差异明显。在4月份，芒果和夏威夷果的收获和衰老过程中观察到差异。5月，在夏威夷果、芒果和番石榴作物的衰老过程中观察到差异。在6月和7月，牛油果、夏威夷果和芒果作物的盛花期和香蕉作物的结果期光谱差异明显。其次是红边波段，短波红外波段对不同果树作物的区分效果显著。这项研究的结果提供了基于证据的信息，可以帮助农场管理者和园艺师做出明智的决定。这对于实现有效的农业管理和确保当地园艺系统的可持续性至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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South African Journal of Geomatics REMOTE SENSING-

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