基于近红外超连续光谱的水稻种子活力无损分级检测研究 -

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基于近红外超连续光谱的水稻种子活力无损分级检测研究

doi:10.37188/CO.2020-0027

金文玲^{1, 2,},
曹乃亮¹,
朱明东³,
陈伟¹,
张佩光¹,
赵庆磊¹,
梁静秋¹,
余应弘⁴,
吕金光^1,,,
阚瑞峰^1,,

1.
中国科学院长春光学精密机械与物理研究所应用光学国家重点实验室，吉林长春 130033
2.
中国科学院大学，北京 100049
3.
湖南省水稻研究所，湖南长沙 410125
4.
湖南省农业科学院，湖南长沙 410125

基金项目:湖南省农业科技创新资金项目（No. 2018NK1020）；国家自然科学基金（No. 61627819，No. 61805239，No. 61727818）；吉林省科技发展计划（No. 20190303063SF，No. 20180201024GX，No. 20150520101JH）；中国科学院青年创新促进会基金（No. 2018254）

详细信息

作者简介:
金文玲（1994—），女，辽宁大连人，硕士研究生，2017年于沈阳理工大学获得学士学位，主要从事光学与光谱学检测系统设计及方法研究。E-mail：jinwenling17@mails.ucas.ac.cn
吕金光（1984—）男，吉林蛟河人，博士，副研究员，硕士生导师，2008年于吉林大学物理学院获得学士学位，2013年于中国科学院长春光学精密机械与物理研究所获得博士学位，主要从事微小光学系统设计与光学信息处理方面的研究。E-mail：jinguanglv@163.com
阚瑞峰（1977—），男，辽宁锦州人，研究员，博士生导师，主要从事光谱检测方法及其在环境污染、生产安全、航空航天流场诊断、深海溶解气体检测等方面应用的研究。E-mail：rfkan@ciomp.ac.cn

通讯作者:
吕金光，jinguanglv@163.com
阚瑞峰，rfkan@ciomp.ac.cn

中图分类号:O433.1
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出版历程
- 收稿日期:2020-02-24
- 修回日期:2020-03-25
- 网络出版日期:2020-08-03
- 刊出日期:2020-10-01

Nondestructive grading test of rice seed activity using near infrared super-continuum laser spectrum

1.
State Key Laboratory of Applied Optics, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China
2.
University of Chinese Academy of Sciences, Beijing 100049, China
3.
Hunan Rice Research Institute, Changsha 410125, China
4.
Hunan Academy of Agricultural Science, Changsha 410125, China

Funds:Supported by Hunan Agricultural Science and Technology Innovation Fund Project (No. 2018NK1020); National Natural Science Foundation of China (No. 61627819, No.61805239, No. 61727818); Jilin Province Science and Technology Development Plan (No. 20190303063SF, No. 20180201024GX, No.20150520101JH); Foundation of Youth Innovation Promotion Association of Chinese Academy of Sciences (No. 2018254)

More Information

Corresponding author:jinguanglv@163.com;rfkan@ciomp.ac.cn

摘要

摘要:针对目前农业种植选种应用对于带稃壳水稻种子活力分级检测的迫切需求，以及现有通用的糙米检测技术存在的问题，本文提出一种基于近红外超连续光谱的水稻种子活力透射光谱检测方法。首先，设计了种子活力近红外吸收光谱检测系统，测量了3种不同年份的带稃壳的水稻种子的近红外吸收光谱，结果显示，水稻种子的活力梯度与近红外吸收光谱的特征吸收峰值相关。然后，采用归一化、二阶导数校正法和正交信号校正相结合优化了种子光谱的预处理算法。最后，建立主成分分析(PCA)模型，对光谱进行降维，确定最佳主成分数目，应用偏最小二乘判别分析(PLS-DA)建立了水稻种子活力分析鉴别模型。分析结果表明，本文设计的透射式吸收光谱检测系统结合PLS-DA判别模型可对不同活力的水稻种子进行分类，校正集和验证集的准确率分别为94.44%和95.92%，筛选后水稻种子的发芽率可达97.17%。研究结果表明，本文提出的基于近红外光谱信息实现水稻种子活力无损分级的方法可行，且具有较高的预测精度。
- 近红外光谱/
- 种子活力/
- 偏最小二乘判别分析/
- 主成分分析
Abstract:In view of the urgent need for seed selection technology in agriculture and for grading detection of the vigor of three different years of unpeeled rice seeds, we proposed a new method of detecting the vigor of rice seeds based on near-infrared super-continuous laser spectrum to overcome the significant issues in pre-existing universal brown rice detection technology. Firstly, we design a near-infrared absorption spectroscopy system with which we detect seed viability and measure the NIR spectra of three different years of unpeeled rice seeds. The results show that the activity gradient of the rice seeds is correlated with the characteristic absorption peak of their NIR absorption spectrum. Then, the spectrum of seed is optimized with a pretreatment algorithm of normalization, second derivative correction and orthogonal signal correction. Finally, a Principal Component Analysis (PCA) model is established to reduce the dimension of the spectrum and determine the optimal number of principal components. A Partial Least Squares Discriminant Analysis (PLS-DA) model is established. The analysis results show that the transmission absorption spectrum detection system designed in this paper combined with the PLS-DA discrimination model can classify rice seeds of different vigor with an accuracy of 94.44% and 95.92%. After screening, the germination rate of rice seeds can reach 97.17%. The results show that it is feasible to achieve non-destructive classification of rice seed activity using near-infrared spectroscopy with high accuracy.
- near-infrared spectroscopy/
- seed vigor/
- partial least-squares discriminant analysis/
- principal component analysis

HTML全文

图 1(a)反射式光谱检测方法与(b)透射式光谱检测方法测量原理示意图

Figure 1.Schematic diagram of (a) reflection type spectral detection method, and (b) transmission type spectral detection method

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图 2水稻种子活力的透射光谱检测系统

Figure 2.Transmission spectrum detection system for rice seed vigor

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图 3水稻种子的近红外吸收光谱图。（a）不同活力的水稻种子近红外光谱平均曲线；（b）高活力水稻种子近红外吸收光谱

Figure 3.Near-infrared absorption spectrum of rice seeds. (a) The average curves of transmission spectra of rice seeds with different vigors. (b) Near-infrared absorption spectrum of high vigor seeds

下载: 全尺寸图片幻灯片

图 4二阶导数处理后的光谱信息

Figure 4.The absorption spectrum of rice seed after second derivative processing

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图 5两种预处理方法结果对比。（a）正交信号校正处理后的光谱；（b）标准正态变量校正后的光谱

Figure 5.Comparison of absorption spectrum of rice seed processed by two pretreatment methods. (a) Orthogonal signal correction; (b) standard normal variate correction

下载: 全尺寸图片幻灯片

图 6PLS-DA模型对2018年（a）、2017年（b）、2016年（c）及随机混合（d）的水稻种子活力判别结果

Figure 6.Evaluation results of vigor of the rice seed in 2018 (a)、2017 (b)、2016 (c) and random mixing (d) determined by PLS-DA model

下载: 全尺寸图片幻灯片

表 1筛选前水稻种子的活力情况

Table 1.The seed vigor parameters of rice seeds before selecting

年份	活力高	活力低	不发芽	发芽率
2018	192	52	44	84.72%
2017	154	71	63	78.13%
2016	106	93	89	69.09%
随机混合	133	84	71	75.351%
总计	585	300	267	——

下载: 导出CSV

表 2不同预处理方法对样品的活力鉴别情况

Table 2.The vitality identification results of samples by different pretreatment methods

预处理方法	光谱范围/nm	主成分数	准确率/%
未处理	1100～2100	5	68.19
MSC	1100～2100	3	75.63
SNV	1100～2100	3	71.78
OSC	1100～2100	3	77.05
归一化+MSC	1100～2100	3	70.33
SD+MSC	1100～2100	3	77.91
SD+SNV	1100～2100	3	79.85
SD+OSC	1100～2100	3	78.57
归一化+SD+MSC	1100～2100	3	83.97
归一化+SD+SNV	1100～2100	3	88.06
归一化+SD+OSC	1100～2100	3	94.13
归一化+SD+OSC	1100～2100	2	82.85
归一化+FD+OSC	1100～2100	3	89.39

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表 3主成分数与模型贡献率

Table 3.Number of principal components and model contribution rate

主成分数	1	2	3	4	5	6
模型准确率/%	55.3	82.9	95.9	94.2	94.1	92.7
累积贡献率/%	62.4	85.7	93.5	96.1	98.2	99.6

下载: 导出CSV

表 4PLS-DA模型判别准确率及筛选后种子发芽率

Table 4.Total accuracy of PLS-DA model and seed germination of rice seeds after screening

年份	校正集准确率/%	验证集准确率/%	筛选后发芽率/%
2018	94.44	95.92	97.17
2017	93.98	94.69	96.52
2016	91.53	92.37	95.06
随机混合	92.74	93.16	96.07

下载: 导出CSV

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