Welcome to Acta Agronomica Sinica,

Acta Agron Sin ›› 2013, Vol. 39 ›› Issue (08): 1469-1477.doi: 10.3724/SP.J.1006.2013.01469

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Estimation of Severity Level of Wheat Powdery Mildew Based on Canopy Spectral Reflectance

FENG Wei,WANG Xiao-Yu,SONG Xiao,HE Li,WANG Yong-Hua,GUO Tian-Cai*   

  1. Henan Agricultural University / National Engineering Research Center for Wheat, Zhengzhou 450002, China
  • Received:2012-12-13 Revised:2013-04-22 Online:2013-08-12 Published:2013-05-20
  • Contact: 郭天财, E-mail: tcguo888@sina.com

RichHTML

PDF

1037

Cited

6

Abstract:

Understanding spectrum characteristics and sensitive bands of wheat infected by Blumeria graminis f. sp. tritici (Bgt) and estimatiing the disease severity will provide a basis for monitoring and subsequently accurately controlling powdery mildew in wheat planted in large scales using aerial remote sensing. Canopy reflectance of winter wheat infected by artificial inoculationof Bgt with different severity levels was measured in disease nursery, field, and pot experiments, and the severity levels in different growth phases were also investigated at the same time. The results indicated that spectrum reflectance increased significantly in visible light region (350–710 nm) with the increase of disease severity level, and the light region between 580 nm to 710 nm was the sensitive bands to wheat powdery mildew, which varied greatly in near-infrared region (710–1100 nm) across treatments with different disease severity levels. However, the correlation between spectrum reflectance and traditional disease index (DI) was low. When the conventionalDI was replaced by modified DI, the correlation was improved significantly. An integrated linear regression equation of  disease severity level to red edge width (Lwidth) described the dynamic pattern of disease severity level in wheat, with R2 of 0.811 and relative error (RE) of 17.7%. Besides, correlation coefficients between spectral parameters (mND705, SIPI, CTR2, and TSAVI) and modified DI were higher than 0.6. No common integrated regression equation could be establishhed due to poor compatibility among experiments. The relative spectral indices (ΔMSAVI and ΔmND705) exhibited high correlations (R2 > 0.76) with the disease sensitive level, with RE values of 18.4% and 19.4%, respectively. The results suggested that the models with sensitive spectral indices could retrieve and forecast the disease severity level accurately in a large area.

Key words: Wheat powdery mildew, Hyperspectral remote sensing, Severity level, Retrieval model

[1]Maxwell J J, Lyerly J H, Cowger C, Marshall D, Brown-Guedira G, Paul Murphy J. MlAG12: a Triticum timopheevii-derived powdery mildew resistance gene in common wheat on chromosome 7AL. Theor Appl Genet, 2009, 119: 1489–1495



[2]Lin J-Y(刘金元), Tao W-J(陶文静), Duan X-Y(段霞瑜), Xiang Q-J(向齐君), Liu D-J(刘大钧), Chen P-D(陈佩度). Molecular marker assisted identification of Pm genes involved in the powdery mildew resistant wheat cultivars (1ines). Acta Phytopathol Sin (植物病理学报), 2000, 30(2): 133–139 (in Chinese with English abstract)



[3]Wu D(吴迪), Zhu D-S(朱登胜), He Y(何勇), Zhang C-Q(张传清), Feng L(冯雷). Nondestructive detection of grey mold of eggplant based on ground multi-spectral imaging sensor. Spectroscopy Spectral Anal (光谱学与光谱分析), 2008, 28(7): 1496–1500 (in Chinese with English abstract)



[4]Bawden F C. Infra-red photography and plant virus diseases. Nature, 1933, 132: 168



[5]Taubenhaus J J, Ezekiel W N, Neblette C B. Airplane photography in the study of cotton root rot. Phytopathology, 1929, 19: 1025–1029



[6]Raikes C, Burpee L L. Use of multispectral radiometry for assessment of rhizoctonia blight in creeping bentgrass. Phytopathology, 1998, 88: 446–449



[7]Wang D, Dowell F E, Lan Y, Pasikatan M, Maghirang E. Determining pecky rice kernels using visible and near-infrared spectroscopy. Int J Food Properties, 2002, 5: 629–639



[8]Cheng T, Rivard B, Sánchez-Azofeifa G A, Feng J, Calvo-Polanco M. Continuous wavelet analysis for the detection of green attack damage due to mountain pine beetle infestation. Remote Sens Environ, 2010, 114: 899–910



[9]Zhang J-C(张竞成), Yuan L(袁琳), Wang J-H(王纪华), Luo J-H(罗菊花), Du S-Z(杜世州), Huang W-J(黄文江). Research progress of crop diseases and pests monitoring based on remote sensing. Trans CSAE (农业工程学报), 2012, 28(20): 1–11 (in Chinese with English abstract)



[10]Zhang M H, Qin Z H, Liu X, Ustin S L. Detection of stress in tomatoes induced by late blight disease in California, USA, using hyperspectral remote sensing. Int J Appl Earth Observ Geoinf, 2003, 4: 295–310



[11]Huang M-Y(黄木易), Wang J-H(王纪华), Huang W-J(黄文江), Huang Y-D(黄义德), Zhao C-J(赵春江), Wan A-M(万安民). Hyperspectral character of stripe rust on winter wheat and monitoring by remote sensing. Trans CSAE (农业工程学报), 2003, 19(6): 154–158 (in Chinese with English abstract)



[12]Jiang J B(蒋金豹), Chen Y H(陈云浩), Huang W J(黄文江). Using the Distance between hyperspectral red edge position and yellow edge position to identify wheat yellow rust disease. Spectroscopy Spectral Anal (光谱学与光谱分析), 2010, 30(6): 1614–1618 (in Chinese with English abstract)



[13]Guo J-B(郭洁滨), Huang C(黄冲), Wang H-G(王海光), Sun Z-Y(孙振宇), Ma Z-H(马占鸿). Disease index inversion of wheat stripe rust on different wheat varieties with hyperspectral remote sensing. Spectroscopy Spectral Anal (光谱学与光谱分析), 2009, 29(12): 3353–3357 (in Chinese with English abstract) 



[14]Riedell W E, Blackmer T M. Leaf reflectance spectra of cereal aphid-damaged wheat. Crop Sci, 1999, 39: 1835–1840



[15]Yang Z, Rao M N, Elliott N C, Kindler S D, Popham T W. Differentiating stress induced by greenbugs and Russian wheat aphids in wheat using remote sensing. Comput Electron Agric, 2009, 67: 64–70



[16]Qiao H-B(乔红波), Cheng D-F(程登发), Sun J-R(孙京瑞), Tian Z(田喆), Chen L(陈林), Lin F-R(林芙蓉). Effects of wheat aphid on spectrum reflectance of the wheat canopy. Plant Prot (植物保护), 2005, 31(2): 21–26 (in Chinese with English abstract)



[17]Kobayashi T, Kanda E, Kitada K, Ishiguro K, Torigoe Y. Detection of rice panicle blast with multi-spectral radiometer and the potential of using airborne multi-spectral scanner. Phytopathology, 2001, 91: 316–323



[18]Cheng S-X(程术希), Shao Y-N(邵咏妮), Wu D(吴迪), He Y(何勇). Determination of rice leaf blast disease level based on visible near infrared spectroscopy. J Zhejiang Univ (Agric & Life Sci) (浙江大学学报?农业与生命科学版), 2011, 37(3): 307–311 (in Chinese with English abstract)



[19]Chen B(陈兵), Wang K-R(王克如), Li S-K(李少昆), Jin X-L(金秀良), Chen J-L(陈江鲁), Zhang D-S(张东升). The effects of disease stress on spectra reflectance and chlorophyll fluorescence characteristics of cotton leaves. Trans CSAE (农业工程学报), 2011, 27(9): 86–92 (in Chinese with English abstract)



[20]Jing X(竞霞), Huang W-J(黄文江), Wang J-H(王纪华), Wang J-D(王锦地), Wang K-R(王克如). Hyperspectral inversion models on verticillium wilt severity of cotton leaf. Spectroscopy Spectral Anal (光谱学与光谱分析), 2009, 29(12): 3348–3352 (in Chinese with English abstract)



[21]Zhang J C, Pu R L, Wang J H, Huang W J, Yuan L, Luo J H. Detecting powdery mildew of winter wheat using leaf level hyperspectral measurements. Comput Electron Agric, 2012, 85: 13–23



[22]Franke J, Menz G. Multi-temporal wheat disease detection by multi-spectral remote sensing. Precision Agric, 2007, 8: 161–172



[23]Peñuelas J, Baret F, Filella I. Semi-empirical indices to assess carotenoids/chlorophyll a ratio from leaf spectral reflectance. Photosynthetica, 1995, 31: 221–230



[24]Baret F, Guyot G, Major D J. TSAVI: a vegetation index which minimizes soil brightness effects on LAI and APAR estimation. In: Proc. IGARRS’89. 12th Canadian Symposium on Remote Sensing, Vol. 3, Vancouver, Canada, 1989, pp 1355–1358



[25]Qi J, Chehbouni A, Huete A R, Kerr Y H. Modified soil adjusted vegetation index (MSAVI). Remote Sens Environ, 1994, 48: 119–126



[26]Merzlyak M N, Gitelson A A, Chivkunova O B, Rakitin V Y. Non-destructive optical detection of pigment changes during leaf senescence and fruit ripening. Physiol Plant, 1999, 106: 135–141



[27]Carter G A, Miller R L. Early detection of plant stress by digital imaging within narrow stress sensitive wavebands. Remote Sens Environ, 1994, 50: 295–302



[28]Sims D A, Gamon J A. Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages. Remote Sensing Environ, 2002, 81: 337–354



[29]Haboudane D, Miller J R, Pattey E, Zarco-Tejada P J, Strachan I. Hyperspectral vegetation indices and novel algorithms for predicting green LAI of crop canopies: modeling and validation in the context of precision agriculture. Remote Sensing Environ, 2004, 90: 337–352



[30]Kokaly R F, Clark R N. Spectroscopic determination of leaf biochemistry using band-depth analysis of absorption features and stepwise multiple linear regression. Remote Sensing Environ, 1999, 67: 267–287



[31]Miller J R, Hare E W, Wu J. Quantitative characterization of the vegetation red edge reflectance: 1. An inverted-Gaussian reflectance model. Int J Remote Sensing, 1990, 11: 1755–1773



[32]Wang X Z(王秀珍), Huang J F(黄敬峰), Li Y M(李云梅), Wang R C(王人潮). Correlation between chemical contents of leaves and characteristic variables of hyperspectra on rice field. Trans CSAE (农业工程学报), 2003, 19(2): 144–148 (in Chinese with English abstract)



[33]Liu L-Y(刘良云), Song X-Y(宋晓宇), Li C-J(李存军), Qi L(齐腊), Huang W-J(黄文江), Wang J-H(王纪华). Monitoring and evaluation of the diseases of and yield winter wheat from multi-temporal remotely-sensed data. Trans CSAE (农业工程学报), 2009, 25: 137–143 (in Chinese with English abstract)



[34]Zhang D-Y(张东彦), Zhang J-C(张竞成), Zhu D-Z(朱大洲), Wang J-H(王纪华), Luo J-H(罗菊花), Zhao J-L(赵晋陵), Huang W-J(黄文江). Investigation of the hyperspectral image characteristics of wheat leaves under different stress. Spectroscopy Spectral Anal (光谱学与光谱分析), 2011, 31(4): 1101–1105 (in Chinese with English abstract)
[1] LI Jin-Min, CHEN Xiu-Qing, YANG Qi, SHI Liang-Sheng. Deep learning models for estimation of paddy rice leaf nitrogen concentration based on canopy hyperspectral data [J]. Acta Agronomica Sinica, 2021, 47(7): 1342-1350.
[2] WU Ya-Peng,HE Li,WANG Yang-Yang,LIU Bei-Cheng,WANG Yong-Hua,GUO Tian-Cai,FENG Wei. Dynamic model of vegetation indices for biomass and nitrogen accumulation in winter wheat [J]. Acta Agronomica Sinica, 2019, 45(8): 1238-1249.
[3] GAO Lin,YANG Gui-Jun,LI Chang-Chun,FENG Hai-Kuan,XU Bo,WANG Lei,DONG Jin-Hui,FU Kui. Application of an Improved Method in Retrieving Leaf Area Index Combined Spectral Index with PLSR in Hyperspectral Data Generated by Unmanned Aerial Vehicle Snapshot Camera [J]. Acta Agron Sin, 2017, 43(04): 549-557.
[4] ZOU Jing-Wei,QIU Dan,SUN Yan-Ling,ZHENG Chao-Xing,LI Jing-Ting,WU Pei-Pei,WU Xiao-Fei,WANG Xiao-Ming,ZHOU Yang,LI Hong-Jie . Pm52: Effectiveness of the Gene Conferring Resistance to Powdery Mildew in Wheat Cultivar Liangxing 99 [J]. Acta Agron Sin, 2017, 43(03): 332-342.
[5] JIANG Yan-Tao,XU Tao,DUAN Xia-Yu*,ZHOU Yi-Lin. Effect of Variety Mixure Planting on Powdery Mildew Controlling as Well as Yield and Protein Contents in Common Wheat [J]. Acta Agron Sin, 2015, 41(02): 276-285.
[6] XING Li-Ping,QIAN Chen,LI Ming-Hao,CAO Ai-Zhong,WANG Xiu-E,CHEN Pei-Du. Transformation of Antisense Wheat Mlo (Ta-Mlo) Gene and Wheat Powdery Mildew Resistance Analysis of Transgenic Plants [J]. Acta Agron Sin, 2013, 39(03): 431-439.
[7] WU Qiong,QI Bo,ZHAO Tuan-Jie,YAO Xin-Feng,ZHU Yan,GAI Jun-Yi. A Tentative Study on Utilization of Canopy Hyperspectral Reflectance to Esti-mate Canopy Growth and Seed Yield in Soybean [J]. Acta Agron Sin, 2013, 39(02): 309-318.
[8] LIU Zi-Ji, ZHU Jie, HUA Wei, YANG Zuo-Min, SUN Ji-Shen, LIU Zhi-Yong. Comparative Genomics Analysis and Constructing EST Markers Linkage Map of Powdery Mildew Resistance Gene pm42 in Wheat [J]. Acta Agron Sin, 2011, 37(09): 1569-1576.
[9] WANG Hua-Zhong, ZHANG Zhen, HE Xiang, YUE Ji-Yu. Dissecting and QTL Mapping of Component Traits of Resistance to Wheat Powdery Mildew at Early Infection Stage [J]. Acta Agron Sin, 2011, 37(07): 1219-1228.
[10] ZHANG Zhen, LIU Xin-Hong, CUI Hong-Cui, WANG Hua-Zhong. Primary Infection Suppression of Blumeria graminis f. sp. Tritici and Host Cell Responses Regulated by Pm21 Gene in Wheat [J]. Acta Agron Sin, 2011, 37(01): 67-73.
[11] CAO Shi-Qi,LUO Hui-Sheng,WU Cui-Peng,JIN he-Lin, ANG Xiao-Ming,ZHU Zhen-Dong,JIA Qiu-Zhen,HUANG Jin,ZHANG Bo,CHANG Xun-Wu. Postulation of Powder Mildew Resistance Genes in 64 Wheat Cultivars (Lines) in Gansu Province, China [J]. Acta Agron Sin, 2010, 36(12): 2107-2115.
[12] ZHANG Kun-Pu;ZHAO Liang;HAI Yan;CHEN Guang-Feng;TIAN Ji-Chun. QTL Mapping for Adult-Plant Resistance to Powdery Mildew, Lodging Resistance and Internode Length below Spike in Wheat [J]. Acta Agron Sin, 2008, 34(08): 1350-1357.
[13] WANG Zhen-Ying;ZHAO Hong-Mei;HONG Jing-Xin;CHEN Li-Yuan;ZHU Jie;LI Gang;PENG Yong-Kang;XIE Chao-Jie;LIU Zhi-Yong;SUN Qi-Xin;YANG Zuo-Min. Identification and Analysis of Four Novel Molecular Markers Linked to Powdery Mildew Resistance Gene Pm21 in 6VS Chromosome Short Arm of Haynaldia villosa [J]. Acta Agron Sin, 2007, 33(04): 605-611.
[14] BAI Jun-Hua;LI Shao-Kun;WANG Ke-Ru;SHUI Xue-Yan;CHEN Bing. Estimation Models of Cotton Aboveground Fresh Biomass Based on Field Hyperspectral Remote Sensing [J]. Acta Agron Sin, 2007, 33(02): 311-316.
[15] GAO An-Li;HE Hua-Gang;CHEN Quan-Zhan;ZHANG Shou-Zhong;CHEN Pei-Du. Pyramiding Wheat Powdery Mildew Resistance Genes Pm2, Pm4a and Pm21 by Molecular Marker-assisted Selection [J]. Acta Agron Sin, 2005, 31(11): 1400-1405.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Add: No.12 Zhongguancun South Street, Beijing 100081,China Email:xbzw@chinajournal.net.cn
Supported by Beijing Magtech Co.Ltd