Abstract
Using spectral reflectance to estimate crop status is a method suitable for developing sensors for site-specific agricultural applications. When developing spectral analysis methods, it is important to know the influence of different crop parameters on the spectral reflectance profile. The objective of this report was to present and evaluate a multivariate method for objective hyperspectral analysis in the examination of how different parts of the reflectance spectrum are affected by disease severity and above ground plant density. Data from two field experiments were used; fungal disease severity assessments in wheat 1998 and above ground plant density measurements 2003. The analysis method consisted of two steps: a pre-processing step where the data was normalized and a classification step for estimating the crop variable. Using only 12% of the data as training data, the method resulted in coefficients of determination (R 2) of 94.3% for the disease severity data and 96.9% for the plant density data. The hyperspectral analysis method presented could also be used to extract spectral signatures of disease severity and plant density using the experimental data. In general, two types of spectral signatures for both data sets, with respect to increasing disease severity and decreasing plant density, were observed (1) a flattening of the green reflectance peak together with a general decrease in reflectance in the near infrared region and, (2) a decrease of the shoulder of the near infrared reflectance plateau together with a general increase in the visible region between 550 and 750 nm.
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References
Carter GA, Knapp AK (2001) Leaf optical properties in higher plants: linking spectral characteristics to stress and chlorophyll concentration. Am J Bot 88(4):677–684
Deering DW (1989) Field measurements of bidirectional reflectance. In: Asrar G (ed) Theory and applications of optical remote sensing. John Wiley & Sons, New York, pp 14–65
Hamid Muhammed H (2001) Feature vector based analysis: a unified concept for multivariate image analysis. Proceedings of IMVIP 2001 (Irish Machine Vision & Image Processing Conference, Maynooth, Ireland), pp 219–226
Hamid Muhammed H, Ammenberg P, Bengtsson E (2001) Using feature-vector based analysis, based on principal component analysis and independent component analysis, for analyzing hyperspectral images. Proceedings of ICIAP 2001 (11th International Conference on Image Analysis and Processing, Palermo, Italy), pp 309–315
Hamid Muhammed H, Larsolle A (2003) Feature vector based analysis of hyperspectral crop reflectance data for discrimination and quantification of fungal disease severity in wheat. Biosyst Eng 86:125–134
Hamid Muhammed H (2004) Characterizing and estimating fungal disease severity in wheat. In: Proceedings of Swedish society for automated image analysis symposium-SSBA (2004). Uppsala University, Sweden, 194–198
Hamid Muhammed H (2005) Hyperspectral crop reflectance data for characterising and estimating fungal disease severity in wheat. Biosyst Eng 91:9-20
Knipling EB (1970) Physical and physiological basis for the reflectance of visible and near-infrared radiation from vegetation. Rem Sens Environ 1:155–159
Kobayashi T, Kanda E, Kitada K, Ishiguro K, Torigoe Y (2001) Detection of rice panicle blast with multispectral radiometer and the potential of using airborne multispectral scanners. Phytopathology 91:316–323
Korobov RM, Railyan VYa (1993) Canonical correlation relationships among spectral and phytometric variables for twenty winter wheat fields. Rem Sens Environ 43:1–10
Kumar L, Schmidt KS, Dury S, Skidmore AK (2001) Review of hyperspectral remote sensing and vegetation science. In: Van der Meer FD, De Jong SM (eds) Imaging spectrometry: basic principles and prospective applications. Kluwer Academic Press, Dordrecht, The Netherlands, pp 111–155
Larsolle A (2003) A method for instantaneous measurement of reflectance spectra in open fields using diode array spectrometers. Biosyst Eng 86(1):1–8
Lelong CCD, Pinet PC, Poilve H (1998) Hyperspectral imaging and stress mapping in agriculture: a case study on wheat in Beauce (France). Rem Sens Environ 66:179–181
Malthus TJ, Madeira AC (1993) High resolution spectroradiometry: spectral reflectance of field bean leaves infected by Botrytis fabae. Rem Sens Environ 45:107–116
Nilsson HE (1985a) Remote sensing of oil seed rape infected by Sclerotinia stem rot and Verticillium wilt. Växtskyddsrapporter - jordbruk, 33, Uppsala, Sweden
Nilsson HE (1985b) Remote sensing of 2-row barley infected by net blotch disease. Växtskyddsrapporter - jordbruk, 34. Uppsala, Sweden
Nilsson HE (1985c) Remote sensing of 6-row barley infected by barley stripe disease. Växtskyddsrapporter - jordbruk, 36. Uppsala, Sweden
Steven MD, Malthus TJ, Demetriades-Shah TH, Danson FM, Clark JA. (1990) High resolution spectral indices for crop stress. In: Steven MD, Clark JA (eds) Applications of remote sensing in agriculture. Butterworth, London, UK, pp 209–227
Acknowledgements
The authors would like to thank Prof. Ewert Bengtsson, Prof. Gunilla Borgefors and Prof. Girma Gebresenbet for their scientific support and aid. This work was financially supported by the Swedish National Space Board (SNSB), the Swedish Farmers’ Foundation for Agricultural Research (SLF) and the Swedish board of agriculture (SJV).
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Larsolle, A., Hamid Muhammed, H. Measuring crop status using multivariate analysis of hyperspectral field reflectance with application to disease severity and plant density. Precision Agric 8, 37–47 (2007). https://doi.org/10.1007/s11119-006-9027-4
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DOI: https://doi.org/10.1007/s11119-006-9027-4