Rice yield prediction using radar vegetation indices from Sentinel-1 data and multiscale one-dimensional convolutional long- and short-term memory network model

IF 1.4 4区 地球科学 Q4 ENVIRONMENTAL SCIENCES
Chunling Sun, Hong Zhang, Lu Xu, Ji Ge, Jingling Jiang, Mingyang Song, Chao Wang
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Abstract

Reliable rice yield information is critical for global food security. Optical vegetation indices (OVIs) are important parameters for rice yield estimation using remote sensing. Studies have shown that radar vegetation indices (RVIs) are correlated with OVIs. However, research on the implementation of RVIs in rice yield prediction is still in its early stages. In addition, existing deep learning yield prediction models ignore the contribution of temporal features at each time step to the predicted yield and lack the extraction of higher-level features. To address the above issues, this study proposed a rice yield prediction workflow using RVIs and a multiscale one-dimensional convolutional long- and short-term memory network (MultiscaleConv1d-LSTM, MC-LSTM). Sentinel-1 vertical emission and horizontal reception of polarization vertical emission and vertical reception of polarization data and county-level rice yield statistics covering Guangdong Province, China, from 2017 to 2021 were used. The experimental results show that the performance of the RVIs is comparable to that of the OVIs. The proposed MC-LSTM model can effectively improve the accuracy of rice yield prediction. For early rice yield prediction based on RVIs, the optimal accuracy of MC-LSTM [coefficient of determination R2 of 0.67, unbiased root mean square error (ubRMSE) of 217.77 kg/ha] was significantly better than that of the LSTM model (R2 of 0.61, ubRMSE of 229.52 kg/ha). For late rice yield prediction based on RVIs, the optimal accuracy of MC-LSTM (R2 of 0.61 and ubRMSE of 456.54 kg/ha) was significantly better than that of the LSTM model (R2 of 0.55 and ubRMSE of 486.76 kg/ha). The above results show that the proposed method has excellent application prospects in crop yield prediction. This work can provide a new feasible scheme for synthetic-aperture radar data to serve agricultural monitoring and improve the efficiency of rice yield monitoring in a large area.
利用哨兵 1 号数据中的雷达植被指数和多尺度一维卷积长短期记忆网络模型预测水稻产量
可靠的水稻产量信息对全球粮食安全至关重要。光学植被指数是利用遥感技术估算水稻产量的重要参数。研究表明,雷达植被指数与光学植被指数相关。然而,将雷达植被指数应用于水稻产量预测的研究仍处于早期阶段。此外,现有的深度学习产量预测模型忽略了每个时间步的时间特征对预测产量的贡献,缺乏对更高层次特征的提取。针对上述问题,本研究提出了利用 RVI 和多尺度一维卷积长短期记忆网络(MultiscaleConv1d-LSTM,MC-LSTM)的水稻产量预测工作流程。实验使用了哨兵-1 垂直发射和水平接收偏振垂直发射和垂直接收偏振数据以及覆盖中国广东省的 2017 年至 2021 年县级水稻产量统计数据。实验结果表明,RVI 的性能与 OVI 相当。所提出的 MC-LSTM 模型能有效提高水稻产量预测的准确性。对于基于 RVIs 的早稻产量预测,MC-LSTM 的最佳精度[判定系数 R2 为 0.67,无偏均方根误差(ubRMSE)为 217.77 千克/公顷]明显优于 LSTM 模型(R2 为 0.61,ubRMSE 为 229.52 千克/公顷)。对于基于 RVI 的晚稻产量预测,MC-LSTM 的最佳精度(R2 为 0.61,ubRMSE 为 456.54 千克/公顷)明显优于 LSTM 模型(R2 为 0.55,ubRMSE 为 486.76 千克/公顷)。以上结果表明,所提出的方法在作物产量预测中具有很好的应用前景。这项工作可以为合成孔径雷达数据服务于农业监测提供一种新的可行方案,提高大面积水稻产量监测的效率。
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来源期刊
Journal of Applied Remote Sensing
Journal of Applied Remote Sensing 环境科学-成像科学与照相技术
CiteScore
3.40
自引率
11.80%
发文量
194
审稿时长
3 months
期刊介绍: The Journal of Applied Remote Sensing is a peer-reviewed journal that optimizes the communication of concepts, information, and progress among the remote sensing community.
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