Combined approach based on principal component analysis and canonical discriminant analysis for investigating hyperspectral plant response

Hyperspectral (HS) data represents an extremely powerful means for rapidly detecting crop stress and then aiding in the rational management of natural resources in agriculture. However, large volume of data poses a challenge for data processing and extracting crucial information. Multivariate statistical techniques can play a key role in the analysis of HS data, as they may allow to both eliminate redundant information and identify synthetic indices which maximize differences among levels of stress. In this paper we propose an integrated approach, based on the combined use of Principal Component Analysis (PCA) and Canonical Discriminant Analysis (CDA), to investigate HS plant response and discriminate plant status. The approach was preliminary evaluated on a data set collected on durum wheat plants grown under different nitrogen (N) stress levels. Hyperspectral measurements were performed at anthesis through a high resolution field spectroradiometer, ASD FieldSpec HandHeld, covering the 325-1075 nm region. Reflectance data were first restricted to the interval 510-1000 nm and then divided into five bands of the electromagnetic spectrum [green: 510-580 nm; yellow: 581-630 nm; red: 631-690 nm; red-edge: 705-770 nm; near-infrared (NIR): 771-1000 nm]. PCA was applied to each spectral interval. CDA was performed on the extracted components to identify the factors maximizing the differences among plants fertilised with increasing N rates. Within the intervals of green, yellow and red only the first principal component (PC) had an eigenvalue greater than 1 and explained more than 95% of total variance; within the ranges of red-edge and NIR, the first two PCs had an eigenvalue higher than 1. Two canonical variables explained cumulatively more than 81% of total variance and the first was able to discriminate wheat plants differently fertilised, as confirmed also by the significant correlation with aboveground biomass and grain yield parameters. The combined approach proved to be effective, being able to synthesise the redundant radiometric information in a reduced number of indicators of plant nutritional status, which could be utilized to delineate homogeneous within-field areas to be submitted to site-specific fertilization.

[1]  Alexander F. H. Goetz,et al.  Three decades of hyperspectral remote sensing of the Earth: a personal view. , 2009 .

[2]  A. Huete,et al.  Development of a two-band enhanced vegetation index without a blue band , 2008 .

[3]  D. F. Morrison,et al.  Multivariate Statistical Methods , 1968 .

[4]  K. Schmidt,et al.  Hyperspectral remote sensing of vegetation species distribution in a saltmarsh , 2003 .

[5]  M. Ashton,et al.  Accuracy assessments of hyperspectral waveband performance for vegetation analysis applications , 2004 .

[6]  Prasad S. Thenkabail,et al.  Evaluation of Narrowband and Broadband Vegetation Indices for Determining Optimal Hyperspectral Wavebands for Agricultural Crop Characterization , 2002 .

[7]  Hogervorst,et al.  Hyperspectral Data Analysis and Visualisation , 2011 .

[8]  C. O'Connor An introduction to multivariate statistical analysis: 2nd edn. by T. W. Anderson. 675 pp. Wiley, New York (1984) , 1987 .

[9]  Sushma Panigrahy,et al.  Use of hyperspectral data to assess the effects of different nitrogen applications on a potato crop , 2007, Precision Agriculture.

[10]  Gregory A. Carter,et al.  Responses of leaf spectral reflectance to plant stress. , 1993 .

[11]  Anand K. Asundi,et al.  Signature Optical Cues: Emerging Technologies for Monitoring Plant Health , 2008, Sensors.

[12]  E. Hunt,et al.  Combined Spectral Index to Improve Ground‐Based Estimates of Nitrogen Status in Dryland Wheat , 2008 .

[13]  G. Carter,et al.  Leaf optical properties in higher plants: linking spectral characteristics to stress and chlorophyll concentration. , 2001, American journal of botany.

[14]  Weixing Cao,et al.  Monitoring leaf nitrogen in wheat using canopy reflectance spectra , 2006 .

[15]  N. Broge,et al.  Comparing prediction power and stability of broadband and hyperspectral vegetation indices for estimation of green leaf area index and canopy chlorophyll density , 2001 .

[16]  Georg Bareth,et al.  Evaluating red edge vegetation indices for estimating winter wheat N status under high canopy coverage condition , 2009 .

[17]  D. Sims,et al.  Relationships between leaf pigment content and spectral reflectance across a wide range of species, leaf structures and developmental stages , 2002 .

[18]  Qi Hongbo,et al.  A study on hyperspectral estimating models of Tobacco Leaf Area Index , 2011 .

[19]  Bruno Basso,et al.  Cultivar discrimination at different site elevations with remotely sensed vegetation indices , 2010 .

[20]  Georg Bareth,et al.  Evaluating hyperspectral vegetation indices for estimating nitrogen concentration of winter wheat at different growth stages , 2010, Precision Agriculture.

[21]  T. W. Anderson An Introduction to Multivariate Statistical Analysis , 1959 .

[22]  J. Liebler,et al.  Diurnal Variation in Hyperspectral Vegetation Indices Related to Winter Wheat Biomass Formation , 2004, Precision Agriculture.

[23]  Prasad S. Thenkabail,et al.  Optimal hyperspectral narrowbands for discriminating agricultural crops , 2001 .

[24]  Armando Apan,et al.  Detecting sugarcane ‘orange rust’ disease using EO-1 Hyperion hyperspectral imagery , 2004 .

[25]  G. Guyot,et al.  Utilisation de la Haute Resolution Spectrale pour Suivre L'etat des Couverts Vegetaux , 1988 .

[26]  Pol Coppin,et al.  Detection of biotic stress (Venturia inaequalis) in apple trees using hyperspectral data: Non-parametric statistical approaches and physiological implications , 2007 .

[27]  Josep Peñuelas,et al.  Evaluating Wheat Nitrogen Status with Canopy Reflectance Indices and Discriminant Analysis , 1995 .