Use of field reflectance data for crop mapping using airborne hyperspectral image

Abstract Recent developments in hyperspectral remote sensing technologies enable acquisition of image with high spectral resolution, which is typical to the laboratory or in situ reflectance measurements. There has been an increasing interest in the utilization of in situ reference reflectance spectra for rapid and repeated mapping of various surface features. Here we examined the prospect of classifying airborne hyperspectral image using field reflectance spectra as the training data for crop mapping. Canopy level field reflectance measurements of some important agricultural crops, i.e. alfalfa, winter barley, winter rape, winter rye, and winter wheat collected during four consecutive growing seasons are used for the classification of a HyMAP image acquired for a separate location by (1) mixture tuned matched filtering (MTMF), (2) spectral feature fitting (SFF), and (3) spectral angle mapper (SAM) methods. In order to answer a general research question “what is the prospect of using independent reference reflectance spectra for image classification”, while focussing on the crop classification, the results indicate distinct aspects. On the one hand, field reflectance spectra of winter rape and alfalfa demonstrate excellent crop discrimination and spectral matching with the image across the growing seasons. On the other hand, significant spectral confusion detected among the winter barley, winter rye, and winter wheat rule out the possibility of existence of a meaningful spectral matching between field reflectance spectra and image. While supporting the current notion of “non-existence of characteristic reflectance spectral signatures for vegetation”, results indicate that there exist some crops whose spectral signatures are similar to characteristic spectral signatures with possibility of using them in image classification.

[1]  A. Stein,et al.  Optimal field sampling for targeting minerals using hyperspectral data , 2005 .

[2]  M. Cochrane Using vegetation reflectance variability for species level classification of hyperspectral data , 2000 .

[3]  Antonino Maltese,et al.  The classification of submerged vegetation using hyperspectral MIVIS data , 2006 .

[4]  Fred A. Kruse,et al.  The Spectral Image Processing System (SIPS) - Interactive visualization and analysis of imaging spectrometer data , 1993 .

[5]  David J. Williams,et al.  Preliminary Investigation of Submerged Aquatic Vegetation Mapping using Hyperspectral Remote Sensing , 2003, Environmental monitoring and assessment.

[6]  Margaret E. Gardner,et al.  Spectrometry for urban area remote sensing—Development and analysis of a spectral library from 350 to 2400 nm , 2004 .

[7]  R. Pasterkamp,et al.  Integrating in situ reef-top reflectance spectra with Landsat TM imagery to aid shallow-tropical benthic habitat mapping , 2004, Coral Reefs.

[8]  Gail P. Anderson,et al.  Analysis of Hyperion data with the FLAASH atmospheric correction algorithm , 2003, IGARSS 2003. 2003 IEEE International Geoscience and Remote Sensing Symposium. Proceedings (IEEE Cat. No.03CH37477).

[9]  J. Campbell Introduction to remote sensing , 1987 .

[10]  D. Jupp,et al.  Mapping coral reef benthic substrates using hyperspectral space-borne images and spectral libraries , 2006 .

[11]  E. LeDrew,et al.  Remote sensing of aquatic coastal ecosystem processes , 2006 .

[12]  G. Taylor,et al.  Field-derived spectra of salinized soils and vegetation as indicators of irrigation-induced soil salinization , 2002 .

[13]  Susan L. Ustin,et al.  Spectral and physiological uniqueness of perennial pepperweed (Lepidium latifolium) , 2006, Weed Science.

[14]  Roger N. Clark,et al.  Mapping minerals, amorphous materials, environmental materials, vegetation, water, ice and snow, and other materials: The USGS tricorder algorithm , 1995 .

[15]  Shunlin Liang,et al.  Recent developments in estimating land surface biogeophysical variables from optical remote sensing , 2007 .

[16]  J. C. Price How unique are spectral signatures , 1994 .

[17]  W. Farrand Identification and mapping of ferric oxide and oxyhydroxide minerals in imaging spectrometer data of Summitville, Colorado, U.S.A., and the surrounding San Juan Mountains , 1997 .

[18]  John A. Richards,et al.  Remote Sensing Digital Image Analysis: An Introduction , 1999 .

[19]  S. Hook,et al.  The ASTER spectral library version 2.0 , 2009 .

[20]  T. Kutser,et al.  Spectral library of macroalgae and benthic substrates in Estonian coastal waters , 2006, Proceedings of the Estonian Academy of Sciences. Biology. Ecology.

[21]  S. J. Sutley,et al.  Mapping potentially asbestos-bearing rocks using imaging spectroscopy , 2009 .

[22]  David J. Brown Using a global VNIR soil-spectral library for local soil characterization and landscape modeling in a 2nd-order Uganda watershed , 2007 .

[23]  H. Bleiholder,et al.  Use of the extended BBCH scale—general for the descriptions of the growth stages of mono; and dicotyledonous weed species , 1997 .

[24]  F. Meer Analysis of spectral absorption features in hyperspectral imagery , 2004 .

[25]  S. Ghosh,et al.  Development of an agricultural crops spectral library and classification of crops at cultivar level using hyperspectral data , 2007, Precision Agriculture.

[26]  Pablo Zarco-Tejada,et al.  Hyperspectral mapping of crop and soils for precision agriculture , 2006, SPIE Optics + Photonics.

[27]  S. Ustin,et al.  Building spectral libraries for wetlands land cover classification and hyperspectral remote sensing. , 2009, Journal of Environmental Management.

[28]  Jens Nieke,et al.  The spectral database SPECCHIO for improved long-term usability and data sharing , 2009, Comput. Geosci..