基于地球遥感数据利用深度学习和云服务绘制农田地图

IF 0.9 4区 地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES
N. R. Ermolaev, S. A. Yudin, V. P. Belobrov, L. A. Vedeshin, D. A. Shapovalov
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引用次数: 0

摘要

摘 要 近年来,俄罗斯联邦农业部和俄罗斯科学院的科研机构就引入新技术在农业中使用航空航天信息开展了研究。本文以斯塔夫罗波尔边疆区为例,探讨了利用谷歌地球引擎(GEE)和 Kaggle 机器学习系统等云服务,使用基于遥感数据的深度学习方法绘制农田地图的可能性。哨兵 2 号空间系统 2022 年生长季节的中值图像被用作选择训练样本和验证样本的数据。准备的训练样本总量为 3998 幅图像。农业领域的研究人员和制造商面临的一个问题是缺乏集中且经过验证的地理空间数据来源。深度学习方法可以解决这一问题,它可以根据遥感数据自动完成农田几何形状的数字化任务。深度学习广泛应用的限制之一是其对计算资源的高要求,而农业领域的研究人员或制造商并非总能获得这些资源。本文介绍了为神经网络工作准备必要数据的过程,包括使用 GEE 修正和获取卫星图像、在 Kaggle 中标准化训练神经网络以及在本地进一步使用。研究中使用了 U-net 架构的神经网络。最终的分类质量为 97%。根据分类结果划分类别的阈值是根据经验确定的,为 0.62。所提出的方法可以显著降低对本地 PC 计算能力的要求。所有与处理卫星图像相关的资源密集型流程都在 GEE 系统中执行,而学习流程则转移到 Kaggle 系统的资源中。拟议的云服务与深度学习方法的结合有助于在农业生产和科学研究中更广泛地推广使用现代技术。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Using Deep Learning and Cloud Services for Mapping Agricultural Fields on the Basis of Remote Sensing Data of the Earth

Using Deep Learning and Cloud Services for Mapping Agricultural Fields on the Basis of Remote Sensing Data of the Earth

Abstract

In recent years, research has been conducted in scientific institutions of the Ministry of Agriculture of the Russian Federation and the Russian Academy of Sciences on introducing new technologies for the use of aerospace information in agriculture. This article, using the example of Stavropol krai, considers the possibility of using cloud services such as Google Earth Engine (GEE) and Kaggle machine learning systems for mapping agricultural fields using deep learning methods based on remote sensing data. Median images of the Sentinel 2 space system for the 2022 growing season are used as data for the selection of training and validation samples. The total volume of the prepared training samples is 3998 images. One problem for researchers and manufacturers in the field of agriculture is a lack of centralized and verified sources of geospatial data. Deep learning methods are able to solve this problem by automating the task of digitizing the geometries of agricultural fields based on remote sensing data. One of the limitations in the widespread use of deep learning is its high demand for computing resources, which are not always available to a researcher or manufacturer in the field of agriculture. This paper describes the process of preparing the necessary data for working with a neural network, including correcting and obtaining satellite images using GEE, their standardization for training a neural network in Kaggle, and further use locally. A neural network of the U-net architecture is used as part of the study. The final classification quality is 97%. The threshold of division into classes according to the classification results is established empirically and amounts to 0.62. The proposed approach makes it possible to significantly reduce the requirements for the local use of PC computing power. All the most resource-intensive processes related to the processing of satellite images are performed in the GEE system, and the learning process is transferred to the resources of the Kaggle system. The proposed combination of cloud services and deep learning methods can contribute to a wider spread of the use of modern technologies in agricultural production and scientific research.

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来源期刊
CiteScore
1.40
自引率
28.60%
发文量
56
审稿时长
6-12 weeks
期刊介绍: Izvestiya, Atmospheric and Oceanic Physics is a journal that publishes original scientific research and review articles on vital issues in the physics of the Earth’s atmosphere and hydrosphere and climate theory. The journal presents results of recent studies of physical processes in the atmosphere and ocean that control climate, weather, and their changes. These studies have possible practical applications. The journal also gives room to the discussion of results obtained in theoretical and experimental studies in various fields of oceanic and atmospheric physics, such as the dynamics of gas and water media, interaction of the atmosphere with the ocean and land surfaces, turbulence theory, heat balance and radiation processes, remote sensing and optics of both media, natural and man-induced climate changes, and the state of the atmosphere and ocean. The journal publishes papers on research techniques used in both media, current scientific information on domestic and foreign events in the physics of the atmosphere and ocean.
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