Water Stress Detection in Pearl Millet Canopy with Selected Wavebands using UAV Based Hyperspectral Imaging and Machine Learning

2022 IEEE Sensors Applications Symposium (SAS) Pub Date : 2022-08-01 DOI:10.1109/SAS54819.2022.9881337

Adduru U. G. Sankararao, P. Rajalakshmi, Sivasakthi Kaliamoorthy, Sunitha Choudhary

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引用次数: 2

Abstract

The major bottleneck in plant phenotyping is the assessment of thousands of genotypes under field conditions, which can be accelerated through Unmanned Aerial Vehicle (UAV) based sensing. Phenotyping for complex traits such as abiotic stress (drought) adaptation can be explored more precisely through the rich spectral information acquired by Hyperspectral Imaging (HSI) sensors. HSI sensors can identify plant water stress early by observing the changes in canopy reflectance due to drought. This study used a UAV-based HSI sensor in the 400-1000 nm range to identify canopy water stress in the pearl millet crop. Five Machine learning-based Feature Selection (FS) methods were used to identify the top-ranked ten wavebands sensitive to canopy water stress. Wavelengths around 692, 714-716, 763-769, 774-882, 870, and 949 nm were repeatedly selected by two or more FS methods. The Recursive feature elimination method with the Support vector machine (SVM) classifier outperformed the other FS methods in selecting the best bands subset. SVM classifier with linear kernel on the selected bands could classify two water stress levels with 95.38% accuracy and early detect stress with 80.76% accuracy in the pearl millet canopy. This study will benefit the agriculture sector by accelerating crop phenotyping using UAV-based HSI.

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基于无人机的高光谱成像与机器学习的珍珠谷子冠层水分胁迫选择波段检测

植物表型分析的主要瓶颈是在田间条件下对数千个基因型进行评估，这可以通过基于无人机(UAV)的传感技术来加速。通过高光谱成像(HSI)传感器获取的丰富光谱信息，可以更精确地探索非生物胁迫(干旱)适应等复杂性状的表型。HSI传感器通过观测干旱引起的冠层反射率变化，可以早期识别植物的水分胁迫。本研究利用无人机在400-1000 nm范围内的HSI传感器对珍珠粟作物冠层水分胁迫进行了识别。利用5种基于机器学习的特征选择(FS)方法，识别出冠层水分胁迫敏感性最高的10个波段。通过两种或多种FS方法反复选择692、714-716、763-769、774-882、870和949 nm附近的波长。基于支持向量机(SVM)分类器的递归特征消除方法在选择最佳频带子集方面优于其他FS方法。在所选波段上采用线性核的SVM分类器对珍珠谷子冠层的两种水分胁迫水平进行分类，准确率为95.38%，早期检测准确率为80.76%。这项研究将通过使用基于无人机的HSI加速作物表型，从而使农业部门受益。

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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2022 IEEE Sensors Applications Symposium (SAS)

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