基于光谱技术的水稻稻纵卷叶螟受害区域检测

doi:10.3964/j.issn.1000-0593(2010)04-1080-04

摘要
参考文献
相关文章 (15)

全文: PDF (1336 KB)
输出: BibTeX | EndNote (RIS)

摘要：利用光谱技术探索了水稻稻纵卷叶螟虫害的检测。通过分析田间水稻稻纵卷叶螟受害区和对照区冠层反射光谱和一阶微分光谱特征差异发现，可见光区(400～700 nm)，550 nm附近中度受害水稻冠层反射率明显低于对照冠层反射率值，重度受害水稻冠层反射率则高于对照区冠层反射率;水稻受害时，叶片受损及干枯导致叶绿素含量降低，对红光波段(600～700 nm)的吸收减小。近红外区(750～770 nm)范围内，受害水稻冠层反射光谱曲线均不同程度出现“尖峰”波动，且光谱曲线红边拐点发生“蓝移”。通过构建样本总体修正曲线，提供了直观判别广域水稻是否受稻纵卷叶螟虫害侵扰的依据。进一步探讨稻纵卷叶螟受害区定性检测参数发现，利用NIR-NDVI特征可以有效地区分对照区和受害区区域，经验证，准确率达70%。

关键词：病虫害检测;光谱分析;稻纵卷叶螟;水稻

Abstract：The canopy reflectance of rice was measured in the filed in order to monitor the damaged region caused by Cnaphalocrocis medinalis Guenee. The characteristics of canopy spectral reflectance were analyzed in contrast region and damaged regions. When rice plant was damaged by Cnaphalocrocis medinalis Guenee, the chlorophyll absorption was decreased in the band of 600-700 nm. The canopy reflectance of moderate damage region was lower than that of the contrast region, while the reflectance of severe damage region rice was higher near 550 nm. The canopy reflectance of Cnaphalocrocis medinalis Guenee damaged rice was fluctuant and exhibited the significant peak in the NIR band of 750-770nm. Meanwhile, red edge inflection point as one of the most important spectral parameters was analyzed at different damage levels based on the first derivative of reflectance spectra. The analysis results indicated that red edge inflection position moved to direction of blue light (short wavelength) with the affection severity increasing. Then the modified reflectance of rice canopy was calculated based on zero-mean calculation and standard deviation. It was easy to find the degree of deviation from the average of samples and distinguish the damaged region from experiment plots. The canopy modified reflectance was gently in the contrast region, but changed violently in the affected regions in the band of 750-950 nm. The analysis of Cnaphalocrocis medinalis Guenee affected regions illustrated that the Cnaphalocrocis medinalis Guenee was increased with the increase in severity. The vegetation index was applied in detection of Cnaphalocrocis medinalis Guenee damaged regions because of the composition of multi-wavelength information. The wavelengths 762 and 774 nm were chosen to build detection parameters of Cnaphalocrocis medinalis Guenee such as NIR-RVI, NIR-DVI, NIR-NDVI and KI. The results indicated that the NIR-NDVI could be used to identify the damaged region with contrast region efficiently. The accurate rate of 25 verification samples selected randomly reached 70%. The preliminary studies on rice Cnaphalocrocis medinalis Guenee damaged regions provided a new method to detect the affected regions in the wide area.

Key words：Crop diseases and pests;Spectral technology;Cnaphalocrocis medinalis Guenee;Rice

收稿日期: 2009-04-18 修订日期: 2009-07-22

中图分类号:	O657.3
	S431.9

通讯作者: 李民赞 E-mail: limz@cau.edu.cn

引用本文:

孙红¹，李民赞^1*，周志艳²，刘刚¹，罗锡文² . 基于光谱技术的水稻稻纵卷叶螟受害区域检测[J]. 光谱学与光谱分析, 2010, 30(04): 1080-1083.
SUN Hong¹, LI Min-zan^1*, ZHOU Zhi-yan², LIU Gang¹, LUO Xi-wen² . Monitoring of Cnaphalocrocis Medinalis Guenee Based on Canopy Reflectance . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2010, 30(04): 1080-1083.

链接本文:

http://www.gpxygpfx.com/CN/10.3964/j.issn.1000-0593(2010)04-1080-04 或 http://www.gpxygpfx.com/CN/Y2010/V30/I04/1080

[1] LIU Zhan-yu, HUANG Jing-feng, TAO Rong-xiang, et al(刘占宇, 黄敬峰, 陶荣祥, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2008, 28(9): 2157.
[2] WU Shu-wen, WANG Chao-ren, CHEN Xiao-bin, et al(吴曙雯, 王潮人, 陈晓斌, 等). Journal of Shanghai Jiaotong University·Agricultural Science(上海交通大学学报·农业科学版), 2002, 20(1): 73.
[3] PENG Wang-lu(彭望琭). Introduction of Remote Sensing(遥感概论). Beijing: Higher Education Press(北京：高等教育出版社)，2002. 307.
[4] WANG Ji-hua, ZHAO Chun-jiang, HUANG Wen-jiang(王纪华，赵春江，黄文江). Semote Sensing Quantitative Theory and Application in Agriculture(农业定量遥感基础与应用). Beijing: Science Press(北京：科学出版社), 2008. 373.
[5] YAN Yan-lu, ZHAO Long-lian, HAN Dong-hai(严衍禄，赵龙莲，韩东海). Near-Infrared Spectrum Analysis and Application(近红外光谱分析基础与应用). Beijing: China Light Industry Press(北京：中国轻工业出版社), 2005. 523.
[6] Beverly S Ausmus, James W Hilty. Remote Sensing of Environment, 1971, 2: 77.
[7] Hamed Hamid Muhammed, Anders Larsolle. Biosystems Engineering, 2003, 86(2): 125.
[8] Hamed Hamid Muhammed. Biosystems Engineering, 2005, 91(1): 9.
[9] Moshou D, Bravo C, Oberti R, et al. Real-Time Imaging, 2005, 11(2): 75.
[10] LIU Xing-ku, LI Zhao-hua(刘兴库，李兆华). Journal of Northeast Forestry University(东北林业大学学报), 1993, 21(2): 106.
[11] WU Ji-you, NI Jian(吴继友, 倪健). Remote Sensing of Environment(环境遥感), 1995, 10(4): 250.
[12] HUANG Mu-yi, WANG Ji-hua, HUANG Wen-jiang, et al(黄木易, 王纪华, 黄文江, 等). Transaction of the Chinese Society of Agricultural Engineering(农业工程学报), 2003, 19(6): 154.
[13] LIU Liang-yun, HUANG Mu-yi, HUANG Wen-jiang, et al(刘良云, 黄木易, 黄文江, 等). Journal of Remote Sensing(遥感学报). 2004, 8(3): 275.
[14] YANG Ke-ming，GUO Da-zhi(杨可明, 郭达志). Geography and Geo-Information Science(地理与地理信息科学), 2006, 22(4): 31.
[15] WANG Yuan-yuan, CHEN Yun-hao, LI Jing, et al(王圆圆, 陈云浩, 李京, 等). Remote Sensing for Land & Resources(国土资源遥感), 2007, 1: 57.
[16] QIU Bai-jing, CHEN Guo-ping, CHENG Qi-wen(邱白晶, 陈国平, 程麒文). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2008, 39(9): 92.
[17] Xu H R，Ying Y B，Fu X P, et al. Biosystems Engineering , 2007, 96(4): 447.
[18] CHEN Bing, LI Shao-kun, WANG Ke-ru, et al(陈兵, 李少昆, 王克如, 等). Scientia Agricultura Sinica(中国农业科学), 2007, 40(12): 2709.
[19] CHEN Bing, LI Shao-kun, WANG Ke-ru, et al. Agricultural Sciences in China，2008，(7): 561.
[20] TIAN You-wen, ZHANG Chang-shui, LI Cheng-hua(田有文, 张长水, 李成华). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2004, 35(3): 95.
[21] GE Jing, SHAO Lu-shou, DING Ke-jian, et al(葛婧，邵陆寿，丁克坚，等). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2008, 39(1): 114.
[22] LI Min-zan(李民赞). Spectral Analysis Technology and Application(光谱分析技术及其应用). Beijing: Science Press(北京: 科学出版社), 2006. 122.