A vehicle imaging approach to acquire ground truth data for upscaling to satellite data: A case study for estimating harvesting dates

IF 11.1 1区地球科学 Q1 ENVIRONMENTAL SCIENCES

Remote Sensing of Environment Pub Date : 2023-11-06 DOI:10.1016/j.rse.2023.113894

Chongya Jiang , Kaiyu Guan , Yizhi Huang , Maxwell Jong

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引用次数: 0

Abstract

Crop harvesting date is critical information for crop yield prediction, financial and logistic planning of grain market and downstream supply chain. Remote sensing has the potential to map harvesting date at regional scale. However, existing studies generally lack ground truth data, and have not fully utilized spectral and temporal information of satellite data. To address these gaps, we present a new approach named Field Rover to acquire large volumes of binary harvesting status (harvested VS. unharvested) ground truth data at regional scale on a weekly basis, by repeatedly using vehicle-mounted cameras to collect time series images for sampled fields and interpreting them with a deep learning approach. With these vehicle-derived ground truth data, we present a machine learning approach to upscale harvesting status and subsequently estimate harvesting date to each field in a study area based on a new satellite platform Planet SuperDove which provides daily 8-band surface reflectance at 3 m resolution. We acquired >200,000 vehicle images from September to November for two years (2021 and 2022), and the deep learning model was able to generate harvesting status for each image with an accuracy of 0.998, which can be treated as ground truth. From a time series of harvesting status derived from revisiting vehicle images, harvesting dates for >500 fields were obtained by a change detection approach. We then trained a remote sensing classification model using harvesting status ground truth, and applied it to generate a harvesting status map for each Planet SuperDove overpass day. The classification model achieved an accuracy of 0.96 and subsequently accurate harvesting date maps were obtained by a curve fitting approach. We found that the Planet SuperDove harvesting date agreed well with the Field Rover harvesting date ground truth (R² = 0.84, RMSE ≈ 5.5 days) at the field level in two years. When focusing on 2022 when more Planet SuperDove satellites were launched, the remote sensing of the harvest date achieved an accuracy of R² = 0.91, and RMSE ≈ 3.3 days. This study demonstrated the efficacy of using repeated vehicle images to acquire time-related agricultural ground truth data, as well as the efficacy of using vehicle-satellite integrative sensing to upscale ground truth data to the regional scale. We envision this new method can be applied to monitor other agricultural management practices and therefore effectively advance the monitoring and modeling of smart farming and sustainable agriculture.

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获取地面真值数据以升级为卫星数据的车辆成像方法:用于估计收获日期的案例研究

作物收获日期是作物产量预测、粮食市场和下游供应链财务和物流规划的关键信息。遥感有可能绘制区域范围内的收获日期图。然而，现有的研究普遍缺乏地面实况数据，并且没有充分利用卫星数据的光谱和时间信息。为了解决这些差距，我们提出了一种名为Field Rover的新方法，通过反复使用车载摄像头收集采样田地的时间序列图像，并用深度学习方法对其进行解释，每周在区域范围内获取大量的二元采集状态（采集状态与未采集状态）地面实况数据。利用这些来自车辆的地面实况数据，我们提出了一种机器学习方法来提升收割状态，并随后基于新的卫星平台Planet SuperDove估计研究区域内每个田地的收割日期，该平台每天提供3米分辨率的8波段表面反射率。我们收购了>；在两年（2021年和2022年）的9月至11月期间，共有200000张车辆图像，深度学习模型能够以0.998的精度为每张图像生成采集状态，这可以被视为基本事实。根据从重新访问车辆图像得到的收获状态的时间序列；通过变化检测方法获得500个场。然后，我们使用收割状态地面实况训练了一个遥感分类模型，并将其应用于生成每个Planet SuperDove立交桥日的收割状态图。分类模型的精度达到0.96，随后通过曲线拟合方法获得了准确的收获日期图。我们发现，Planet SuperDove的收获日期与两年内实地的Field Rover收获日期地面实况（R2=0.84，RMSE≈5.5天）非常一致。当关注2022年更多的Planet SuperDove卫星发射时，收获日期的遥感精度达到R2=0.91，RMSE≈3.3天。这项研究证明了使用重复的车辆图像来获取与时间相关的农业地面实况数据的有效性，以及使用车载卫星综合传感将地面实况数据提升到区域尺度的效果。我们设想这种新方法可以应用于监测其他农业管理实践，从而有效地推进智能农业和可持续农业的监测和建模。

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来源期刊

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.