Plant Soil Environ., 2015, 61(4):182-188 | DOI: 10.17221/7/2015-PSE

Application of fluorescence spectrum to precisely inverse paddy rice nitrogen contentOriginal Paper

J. Yang1, S. Shi1,2, W. Gong1,2, L. Du1,3, Y.Y. Ma1,2, B. Zhu1, S.L. Song4
1 StateKey Laboratory of Information Engineering in Surveying, Mapping and Remote Sensing, Wuhan University, Wuhan, P.R. China
2 Collaborative Innovation Center for Geospatial Technology, Wuhan, P.R. China
3 School of Physics and Technology, Wuhan University, Wuhan, P.R. China
4 Wuhan Institute of Physics and Mathematics, Chinese Academy of Sciences,

Paddy rice is important for Chinese agriculture and crop production, which largely depends on the leaf nitrogen (N) levels. The purpose of this study is to discuss the relationship between the fluorescence parameters and leaf N content of paddy rice and to test their performance in inversing N content of crops through back-propagation (B-P) neural network. In the correlative analysis of the fluorescence parameters and the N content, we found that the correlation between fluorescence ratios (F740/F685 and F685/F525 (F740, F685, F525 - intensity of fluorescence at 740, 685 and 525 nm, respectively)) and the N content (R2 are 0.735 and 0.4342, respectively) is weaker than that between the intensity of fluorescence peaks (F685 and F740) and N content (R2 are 0.9743 and 0.9686, respectively). Our studies show that the accuracy and precision of N content inversion which is acquired from the intensity of fluorescence peaks through the B-P neural network model are significantly improved (root mean square error (MSRE) = 0.1702, the residual changes between -0.1-0.1 mg/g) compared with the fluorescence ratio (MSRE = 0.3655, the residual changes from -0.3-0.3 mg/g). Results demonstrate that the intensity of fluorescence peaks can be as a characteristic parameter to estimate N content of crops leaf. The B-P neural network model will be serviceable approach in inversing N content of paddy leaf.

Keywords: remote sensing; N fertilization strategies; nutrient stress; chlorophyll

Published: April 30, 2015  Show citation

ACS AIP APA ASA Harvard Chicago IEEE ISO690 MLA NLM Turabian Vancouver
Yang J, Shi S, Gong W, Du L, Ma YY, Zhu B, Song SL. Application of fluorescence spectrum to precisely inverse paddy rice nitrogen content. CAAS Agricultural Journals. 2015;61(4):182-188. doi: 10.17221/7/2015-PSE.
Share...
Download citation
  • BibTeX (.bib)
  • Bookends (.ris)
  • EasyBib (.ris)
  • EndNote (.enw)
  • EndNote 8 (.xml)
  • ISI WoS (.isi)
  • Medlars (.medlars)
  • Mendeley (.ris)
  • MODS (.xml)
  • Papers (.ris)
  • RefWorks (.txt)
  • RefManager (.ris)
  • RIS (.ris)
  • MS Word (.xml)
  • Zotero (.ris)
    • Open full article

    References

    1. Apostol S., Viau A.A., Tremblay N. (2007): A comparison of multiwavelength laser-induced fluorescence parameters for the remote sensing of nitrogen stress in field-cultivated corn. Canadian Journal of Remote Sensing, 33: 150-161. Go to original source...
    2. Blackburn G.A. (1998): Quantifying chlorophylls and caroteniods at leaf and canopy scales: An evaluation of some hyperspectral approaches. Remote Sensing of Environment, 66: 273-285. Go to original source...
    3. Chappelle E.W., Wood F.M., McMurtrey J.E., Newcomb W.W. (1984): Laser-induced fluorescence of green plants 1: A technique for the remote detection of plant stress and species differentiation. Applied Optics, 23: 134-138. Go to original source... Go to PubMed...
    4. Dobrowski S.Z., Pushnik J.C., Zarco-Tejada P.J., Ustin S.L. (2005): Simple reflectance indices track heat and water stress-induced changes in steady-state chlorophyll fluorescence at the canopy scale. Remote Sensing of Environment, 97: 403-414. Go to original source...
    5. Fox R.H., Piekielek W.P., Macneal K.E. (2001): Comparison of late-season diagnostic tests for predicting nitrogen status of corn. Agronomy Journal, 93: 590-597. Go to original source...
    6. Goltsev V., Zaharieva I., Chernev P., Kouzmanova M., Kalaji H.M., Yordanov I., Krasteva V., Alexandrov V., Stefanov D., Allakhverdiev S.I., Strasser R.J. (2012): Drought-induced modifications of photosynthetic electron transport in intact leaves: Analysis and use of neural networks as a tool for a rapid non-invasive estimation. Biochimica Biophysica Acta, 1817: 1490-1498. Go to original source... Go to PubMed...
    7. Günther K.P., Dahn H.-G., Lüdeker W. (1994): Remote sensing vegetation status by laser-induced fluorescence. Remote Sensing of Environment, 47: 10-17. Go to original source...
    8. Janušauskaite D., Feiziene D. (2012): Chlorophyll fluorescence characteristics throughout spring triticale development stages as affected by fertilization. Acta Agriculturae Scandinavica, Section B - Soil and Plant Science, 62: 7-15. Go to original source...
    9. Janušauskaitė D., Auškalnienė O., Pšibišauskienė G. (2011): Evaluation of chlorophyll fluorescence in different densities of spring barley. Acta Physiologiae Plantarum, 33: 2159-2167. Go to original source...
    10. Li F., Gnyp M.L., Jia L., Miao Y., Yu Z., Koppe W., Bareth G., Chen X.P., Zhang F.S. (2008): Estimating N status of winter wheat using a handheld spectrometer in the North China Plain. Field Crops Research, 106: 77-85. Go to original source...
    11. Nguyen H.T., Lee B.W. (2006): Assessment of rice leaf growth and nitrogen status by hyperspectral canopy reflectance and partial least square regression. European Journal of Agronomy, 24: 349-356. Go to original source...
    12. Oppelt N., Mauser W. (2004): Hyperspectral monitoring of physiological parameters of wheat during a vegetation period using AVIS data. International Journal of Remote Sensing, 25: 145-159. Go to original source...
    13. Samborska I.A., Alexandrov V., Sieczko L., Kornatowska B., Goltsev V., Cetner M.D., Kalaji H.M. (2014): Artificial neural networks and their application in biological and agricultural research. NanoPhotoBioSciences, 2: 14-30.
    14. Sayed O.H. (2003): Chlorophyll fluorescence as a tool in cereal crop research. Photosynthetica, 41: 321-330. Go to original source...
    15. Song S., Gong W., Zhu B., Huang X. (2011): Wavelength selection and spectral discrimination for paddy rice, with laboratory measurements of hyperspectral leaf reflectance. ISPRS Journal of Photogrammetry and Remote Sensing, 66: 672-682. Go to original source...
    16. Stober F., Lichtenthaler H.K. (1993): Characterization of the laser-induced blue, green and red fluorescence signatures of leaves of wheat and soybean grown under different irradiance. Physiologia Plantarum, 88: 696-704. Go to original source... Go to PubMed...
    17. Subhash N., Mohanan C.N. (1994): Laser-induced red chlorophyll fluorescence signatures as nutrient stress indicator in rice plants. Remote Sensing of Environment, 47: 45-50. Go to original source...
    18. Takeuchi A., Saito Y., Kanoh M., Kawahara T.D., Nomura A., Ishizawa H., Matsuzawa T., Komatsu K. (2002): Laser-induced fluorescence detection of plant and optimal harvest time of agricultural products (lettuce). Applied Engineering in Agriculture, 18: 361-366. Go to original source...
    19. Živčák M., Olšovská K., Slamka P., Galambošová J., Rataj V., Shao H.B., Brestič M. (2014): Application of chlorophyll fluorescence performance indices to assess the wheat photosynthetic functions influenced by nitrogen deficiency. Plant, Soil and Environment, 60: 210-215. Go to original source...

    This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International (CC BY NC 4.0), which permits non-comercial use, distribution, and reproduction in any medium, provided the original publication is properly cited. No use, distribution or reproduction is permitted which does not comply with these terms.


    Return to the content