Machine Learning-Based Crop Drought Mapping System by UAV Remote Sensing RGB Imagery

Unmanned Syst. Pub Date : 2020-01-08 DOI:10.1142/s2301385020500053

Jinya Su, M. Coombes, Cunjia Liu, Yongchao Zhu, Xingyang Song, S. Fang, Lei Guo, Wen‐Hua Chen

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引用次数: 26

Abstract

Water stress has adverse effects on crop growth and yield, where its monitoring plays a vital role in precision crop management. This paper aims at initially exploiting the potentials of UAV aerial RGB image in crop water stress assessment by developing a simple but effective supervised learning system. Various techniques are seamlessly integrated into the system including vegetation segmentation, feature engineering, Bayesian optimization and Support Vector Machine (SVM) classifier. In particular, wheat pixels are first segmented from soil background by using the classical vegetation index thresholding. Rather than performing pixel-wise classification, pixel squares of appropriate dimension are defined as samples, from which various features for pure vegetation pixels are extracted including spectral and colour index features. SVM with Bayesian optimization is adopted as the classifier. To validate the developed system, a UAV survey is performed to collect high-resolution atop canopy RGB imageries by using DJI S1000 for the experimental wheat fields of Gucheng town, Heibei Province, China. Two levels of soil moisture were designed after seedling establishment for wheat plots by using intelligent irrigation and rain shelter, where field measurements were to obtain ground soil water ratio for each wheat plot. Comparative experiments by three-fold cross-validation demonstrate that pixel-wise classification, with a high computation load, can only achieve an accuracy of 82.8% with poor F1 score of 71.7%; however, the developed system can achieve an accuracy of 89.9% with F1 score of 87.7% by using only spectral intensities, and the accuracy can be further improved to 92.8% with F1 score of 91.5% by fusing both spectral intensities and colour index features. Future work is focused on incorporating more spectral information and advanced feature extraction algorithms to further improve the performance.

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基于机器学习的无人机RGB遥感作物干旱制图系统

水分胁迫对作物生长和产量有不利影响，其监测在作物精准管理中起着至关重要的作用。本文旨在通过开发简单有效的监督学习系统，初步挖掘无人机航拍RGB图像在作物水分胁迫评估中的潜力。各种技术无缝集成到系统中，包括植被分割，特征工程，贝叶斯优化和支持向量机(SVM)分类器。其中，首先利用经典植被指数阈值法从土壤背景中分割出小麦像素。不是进行像素分类，而是将适当尺寸的像素正方形定义为样本，从中提取纯植被像素的各种特征，包括光谱和颜色指数特征。采用贝叶斯优化支持向量机作为分类器。为了验证所开发的系统，利用大疆S1000对中国河北省谷城实验麦田进行了无人机调查，收集了高分辨率的冠层RGB图像。采用智能灌溉和智能遮雨的方法，设计了小麦地块播种后的两个土壤水分水平，并通过田间测量获得了每个小麦地块的土壤水分比。通过三次交叉验证的对比实验表明，在计算量较大的情况下，逐像素分类的准确率仅为82.8%，F1分数较差，为71.7%;然而，仅使用光谱强度时，系统的准确率可达到89.9%，F1评分为87.7%;同时融合光谱强度和显色指数特征，系统的准确率可进一步提高到92.8%，F1评分为91.5%。未来的工作重点是结合更多的光谱信息和先进的特征提取算法，以进一步提高性能。

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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Unmanned Syst.

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