利用Plantscope时间序列和深度学习绘制巴西综合作物-牲畜系统地图

IF 11.1 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Inacio T. Bueno , João F.G. Antunes , Aliny A. Dos Reis , João P.S. Werner , Ana P.S.G.D.D. Toro , Gleyce K.D.A. Figueiredo , Júlio C.D.M. Esquerdo , Rubens A.C. Lamparelli , Alexandre C. Coutinho , Paulo S.G. Magalhães
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引用次数: 0

摘要

高时空分辨率的作物精确测绘在实现可持续发展目标方面发挥着关键作用,特别是在作物-畜牧业综合系统的背景下。利益相关者可以通过了解这些系统的空间动态,做出明智的决策并实施有针对性的战略,以实现与农业、农村发展和可持续生计相关的多个可持续发展目标。从多时相遥感和深度学习等新兴地图技术中获得的关于ICLS范围的准确信息有助于实施可持续农业实践。然而,人们对ICLS地图准确性的关注太少了,因为与其他农业实践相比,它可能不在研究议程的前沿。本文旨在使用高时空分辨率图像和深度学习神经网络分类器在巴西的两个不同地点绘制ICLS。该管道涉及四种基于ICLS类的解释方法:评估具有不同图像组成间隔的深度神经网络分类器,解释委托和遗漏错误,评估该方法的时间可转移性,以及评估变量的影响。研究区域由巴西圣保罗(研究地点1,SS1)和马托格罗索州(研究地点2,SS2)的两个地点组成。我们从PlanetScope(PS)图像中导出了九个光谱变量,并通过基于对象的图像分析(OBIA)使用两个时间间隔(10天和15天)导出了四个度量,以生成图像组成。这些输入变量被用于三个深度神经网络分类器:一维卷积神经网络(Conv1D)、长短期记忆(LSTM)和具有全卷积网络的LSTM(LSTM-FCN)。我们的研究结果表明,通过使用高时空分辨率图像和深度神经网络分类器,绘制动态土地利用地图(如ICLS)是可能的。为期15天的LSTM-FCN分类器为两个站点返回了最高的地图准确度,具有以下类别级准确度:SS1的生产者准确度(PA)=97.0%和用户准确度(UA)=77.0%,SS2的PA=82.0%和UA=96.5%。同时,我们发现不同的作物日历以及ICLS和其他土地利用之间的光谱-时间相似性导致了地图的不确定性。最佳方法表明,时间泛化适用于映射ICLS,但由于类的固有特性,一些分类器无法泛化。大多数变量被认为是预测ICLS的有效变量,尽管光谱指数显示出更好的函数关系,而PS带对预测的影响较小。用所提出的方法实现的精度为充分准确地绘制ICLS和其他复杂作物活动提供了很好的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mapping integrated crop-livestock systems in Brazil with planetscope time series and deep learning

Accurate mapping of crops with high spatiotemporal resolution plays a critical role in achieving the Sustainable Development Goals (SDGs), especially in the context of integrated crop-livestock systems (ICLS). Stakeholders can make informed decisions and implement targeted strategies to achieve multiple SDGs related to agriculture, rural development, and sustainable livelihoods by understanding the spatial dynamics of these systems. Accurate information on the extent of ICLS derived from multitemporal remote sensing and emerging map techniques such as deep learning can help in the implementation of sustainable agricultural practices. However, far too little attention has been paid to ICLS map accuracy because it may not be at the forefront of research agendas compared to those of other agricultural practices. This paper aims to map ICLS using high spatiotemporal resolution imagery and deep learning neural network classifiers at two different sites located in Brazil. The pipeline involves four interpretation approaches based on the ICLS class: evaluating deep neural network classifiers with different image composition intervals, explaining commission and omission errors, evaluating the temporal transferability of the method, and evaluating the influence of variables. The study area consists of two locations in São Paulo (study site 1, SS1) and Mato Grosso state (study site 2, SS2), Brazil. We derived nine spectral variables from PlanetScope (PS) images and four metrics through object-based image analysis (OBIA) using two time intervals, 10 and 15 days, to generate the image compositions. These input variables were used in three deep neural network classifiers: convolutional neural network in one dimension (Conv1D), long short-term memory (LSTM), and LSTM with a fully convolutional network (LSTM-FCN). Our results showed that mapping dynamic land use such as ICLS is possible by using high-spatiotemporal-resolution imagery and deep neural network classifiers. The 15-day LSTM-FCN classifier returned the highest map accuracies for both sites, with the following class-level accuracies: producer accuracy (PA) = 97.0% and user accuracy (UA) = 97.0% for SS1 and PA = 82.0% and UA = 96.5% for SS2. Meanwhile, we found map uncertainties arising from the diverse crop calendars and spectro-temporal similarities between ICLS and other land use. The best approaches revealed that temporal generalization was suitable for mapping ICLS, but some classifiers could not generalize due to the inherent characteristics of the class. Most variables were considered efficient for predicting ICLS, although spectral indices revealed better functional relationships, while the PS bands had a lower influence on the predictions. The accuracies achieved with the proposed method represent promising opportunities for the sufficiently accurate mapping of ICLS and other complex crop activities.

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来源期刊
Remote Sensing of Environment
Remote Sensing of Environment 环境科学-成像科学与照相技术
CiteScore
25.10
自引率
8.90%
发文量
455
审稿时长
53 days
期刊介绍: Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.
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