基于叶绿素荧光光谱分析的黄瓜霜霉病害预测模型

doi:10.3964/j.issn.1000-0593(2011)11-2987-04

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摘要：为了实现对黄瓜病害的快速无损准确预测，基于激光诱导叶绿素荧光光谱分析技术，建立了温室黄瓜霜霉病害的预测模型。通过测定健康叶片、病菌接种3 d叶片和接种6 d叶片的光谱曲线，采用一阶导数光谱预处理方法，结合主成分分析数据降维方法对三组光谱数据进行特征信息提取后，建立主成分得分散点图，依据累积贡献率选取10个主成分代替导数光谱曲线，再利用最小二乘支持向量机技术进行分类和预测。通过对三组光谱数据105个样本的训练，对44个样本进行分类预测，并对比了四种核函数的支持向量机的分类能力，结果表明，径向基核函数对黄瓜霜霉病害的分类预测能力达到了97.73%，具有很好的分类和鉴别效果。

关键词：荧光光谱;主成分分析;支持向量机;黄瓜霜霉病

Abstract：In order to achieve quick and nondestructive prediction of cucumber disease, a prediction model of greenhouse cucumber downy mildew has been established and it is based on analysis technology of laser-induced chlorophyll fluorescence spectrum. By assaying the spectrum curve of healthy leaves, leaves inoculated with bacteria for three days and six days and after feature information extraction of those three groups of spectrum data using first-order derivative spectrum preprocessing with principal components and data reduction, principal components score scatter diagram has been built, and according to accumulation contribution rate, ten principal components have been selected to replace derivative spectrum curve, and then classification and prediction has been done by support vector machine. According to the training of 105 samples from the three groups, classification and prediction of 44 samples and comparing the classification capacities of four kernel function support vector machines, the consequence is that RBF has high quality in classification and identification and the accuracy rate in classification and prediction of cucumber downy mildew reaches 97.73%.

Key words：Fluorescence spectrum;Principal components analysis;Support vector machine;Cucumber downy mildew

收稿日期: 2011-02-11 修订日期: 2011-06-20

中图分类号:

S123

通讯作者: 于海业 E-mail: haiye@jlu.edu.cn

引用本文:

隋媛媛¹，于海业^1*，张蕾¹，曲剑巍¹，武海巍^1，2，罗瀚¹ . 基于叶绿素荧光光谱分析的黄瓜霜霉病害预测模型[J]. 光谱学与光谱分析, 2011, 31(11): 2987-2990.
SUI Yuan-yuan¹, YU Hai-ye^1*, ZHANG Lei¹, QU Jian-wei1, WU Hai-wei^1，2, LUO Han¹ . Cucumber Downy Mildew Prediction Model Based on Analysis of Chlorophyll Fluorescence Spectrum. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2011, 31(11): 2987-2990.

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[1] Ming L, Chunjiang Z, Daoliang L, et al. Computer and Computing Technologies in Agriculture, 2008, 2(259): 1375.
[2] HE Yan-hong, GUO Liang-sheng, TIAN You-liang(何炎红，郭连生，田有亮). Acta Botanica Boreali-Occidentalia Sinica(西北植物学报), 2005, 25(11): 2226.
[3] Chatzistathis T A, Papadakis I E, Therios I N, et al. Journal of Plant Nutrition, 2010, 34(1): 98.
[4] Kim J, Moon Y R, Lee M H, et al. International Journal of Low Radiation, 2010, 7(4): 1477.
[5] Floerl S, Druebert C, Aroud H I, et al. Journal of Plant Pathology, 2010, 92(3): 693.
[6] LI Jing-ping, XIE Bang-chang(李静萍，谢邦昌). Multivariate Analysis: Methods and Applications(多元统计分析：方法与应用). Beijing： China Renmin University Press(北京：中国人民大学出版社), 2008.
[7] YUE Tian-li, PENG Bang-zhu, YUAN Ya-hong, et al(岳田利，彭邦柱，袁亚宏，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2007, 23(6): 223.
[8] ZENG Jie, SUN Jun-liang, LI Guang-lei, et al(曾洁，孙俊良，李光磊). Journal of Shenyang Agricultural University(沈阳农业大学学报), 2009, 40(1): 53.
[9] Cortes C, Vapnik V. Machine Learning, 1995, 20(3): 273.
[10] Vapnik V N. The Natuse of Statistical Learning Theory. New York: Springer-Verlag, 1955.
[11] Cristianini N, Shawe-Taylor J. An Introduction to Support Vector Machines and Other Kerner-based Learning Methods(支持向量机导论). Beijing: Publishing House of Electronics Industry(北京：电子工业出版社), 2004.
[12] DENG Nai-yang, TIAN Ying-jie(邓乃扬，田英杰). New Method of Data Minning Support Vector Machine(数据挖掘中的新方法——支持向量机). Beijing: Science Press(北京：科学出版社), 2004.
[13] WANG Xing-ling, LI Zhan-bin(王兴玲，李占斌). Periodical of Ocean University of China(中国海洋大学), 2005, 35(5): 859.