Spectral Discrimination of Vegetation Classes in Ice-Free Areas of Antarctica

Detailed monitoring of vegetation changes in ice-free areas of Antarctica is crucial to determine the effects of climate warming and increasing human presence in this vulnerable ecosystem. Remote sensing techniques are especially suitable in this distant and rough environment, with high spectral and spatial resolutions needed owing to the patchiness and similarity between vegetation elements. We analyze the reflectance spectra of the most representative vegetation elements in ice-free areas of Antarctica to assess the potential for discrimination. This research is aimed as a basis for future aircraft/satellite research for long-term vegetation monitoring. The study was conducted in the Barton Peninsula, King George Island. The reflectance of ground patches of different types of vegetation or bare ground (c. 0.25 m 2 , n = 30 patches per class) was recorded with a spectrophotometer measuring between 340 nm to 1025 nm at a resolution of 0.38 n m . We used Linear Discriminant Analysis (LDA) to classify the cover classes according to reflectance spectra, after reduction of the number of bands using Principal Component Analysis (PCA). The first five principal components explained an accumulated 99.4% of the total variance and were added to the discriminant function. The LDA classification resulted in c. 92% of cases correctly classified (a hit ratio 11.9 times greater than chance). The most important region for discrimination was the visible and near ultraviolet (UV), with the relative importance of spectral bands steeply decreasing in the Near Infra-Red (NIR) region. Our study shows the feasibility of discriminating among representative taxa of Antarctic vegetation using their spectral patterns in the near UV, visible and NIR. The results are encouraging for hyperspectral vegetation mapping in Antarctica, which could greatly facilitate monitoring vegetation changes in response to a changing environment, reducing the costs and environmental impacts of field surveys.

[1]  Tomas Ayala-Silva,et al.  Changes in spectral reflectance of wheat leaves in response to specific macronutrient deficiency. , 2005, Advances in space research : the official journal of the Committee on Space Research.

[2]  J. R. Landis,et al.  The measurement of observer agreement for categorical data. , 1977, Biometrics.

[3]  Teuvo Kohonen,et al.  Self-organized formation of topologically correct feature maps , 2004, Biological Cybernetics.

[4]  Ross A. Virginia,et al.  LOW‐DIVERSITY ANTARCTIC SOIL NEMATODE COMMUNITIES: DISTRIBUTION AND RESPONSE TO DISTURBANCE , 1997 .

[5]  J. H. Kim,et al.  Lichen flora around the Korean Antarctic Scientific Station, King George Island, Antarctic. , 2006, Journal of microbiology.

[6]  P. Convey,et al.  Determining the native/non-native status of newly discovered terrestrial and freshwater species in Antarctica - current knowledge, methodology and management action. , 2012, Journal of environmental management.

[7]  S. Jacobs,et al.  Antarctic climate change and the environment: an update , 2013, Polar Record.

[8]  H. Lim,et al.  Geochemistry of soils of King George Island, South Shetland Islands, West Antarctica: Implications for pedogenesis in cold polar regions , 2004 .

[9]  Teuvo Kohonen,et al.  The self-organizing map , 1990 .

[10]  T. Callaghan,et al.  Arctic terrestrial ecosystems and environmental change , 1995, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

[11]  R. G. Oderwald,et al.  Assessing Landsat classification accuracy using discrete multivariate analysis statistical techniques. , 1983 .

[12]  Vegetation abundance on the Barton Peninsula, Antarctica: estimation from high-resolution satellite images , 2014, Polar Biology.

[13]  P. Convey,et al.  Biological invasions in terrestrial Antarctica: what is the current status and can we respond? , 2015, Biodiversity and Conservation.

[14]  S. Tarantola,et al.  Detecting vegetation leaf water content using reflectance in the optical domain , 2001 .

[15]  J. H. Kim,et al.  Vegetation of Barton Peninsula in the neighbourhood of King Sejong Station (King George Island, maritime Antarctic) , 2007, Polar Biology.

[16]  R. Smith,et al.  Lichens of Antarctica and South Georgia: A Guide to their Identification and Ecology , 2001 .

[17]  Laurent Tits,et al.  Spectral Unmixing of Forest Crown Components at Close Range, Airborne and Simulated Sentinel-2 and EnMAP Spectral Imaging Scale , 2015, Remote. Sens..

[18]  José Luis Alba-Castro,et al.  Grading Textured Surfaces with Automated Soft Clustering in a Supervised SOM , 2004, ICIAR.

[19]  김지희,et al.  Ice cliff retreat and sea-ice formation observed around King Sejong Station in King George Island, West Antarctica , 2004 .

[20]  P. Convey,et al.  Primary succession of lichen and bryophyte communities following glacial recession on Signy Island, South Orkney Islands, Maritime Antarctic , 2012, Antarctic Science.

[21]  Benoit Rivard,et al.  Spectral properties of foliose and crustose lichens based on laboratory experiments , 2002 .

[22]  John Turner,et al.  Antarctic climate change and the environment , 2009, Antarctic Science.

[23]  Peter Convey,et al.  Biological invasions in the Antarctic: extent, impacts and implications , 2005, Biological reviews of the Cambridge Philosophical Society.

[24]  Jacob Cohen A Coefficient of Agreement for Nominal Scales , 1960 .

[25]  Roi Méndez-Rial,et al.  Accurate Implementation of Anisotropic Diffusion in the Hypercube , 2010, IEEE Geoscience and Remote Sensing Letters.

[26]  Jean-Pierre Da Costa,et al.  Hyperspectral Image Analysis for Precision Viticulture , 2006, ICIAR.

[27]  Marcel Schwieder,et al.  Ground-Based Hyperspectral Characterization of Alaska Tundra Vegetation along Environmental Gradients , 2013, Remote. Sens..

[28]  Peter Convey,et al.  Spatial and temporal variability across life's hierarchies in the terrestrial Antarctic , 2007, Philosophical Transactions of the Royal Society B: Biological Sciences.

[29]  Roi Méndez-Rial,et al.  Anisotropic Inpainting of the Hypercube , 2012, IEEE Geoscience and Remote Sensing Letters.

[30]  C. Schaefer,et al.  A proxy for snow cover and winter ground surface cooling: Mapping Usnea sp. communities using high resolution remote sensing imagery (Maritime Antarctica) , 2014 .

[31]  I. F. Aymerich,et al.  Detection of Tephra Layers in Antarctic Sediment Cores with Hyperspectral Imaging , 2016, PloS one.

[32]  A. Skidmore,et al.  Spectral discrimination of vegetation types in a coastal wetland , 2003 .

[33]  R. Smith Vascular plants as bioindicators of regional warming in Antarctica , 1994, Oecologia.

[34]  J. Michalsky,et al.  Column water vapor from diffuse irradiance , 2003 .

[35]  Xin Huang,et al.  Wavelength selection and spectral discrimination for paddy rice, with laboratory measurements of hyperspectral leaf reflectance , 2011 .

[36]  P. Convey Maritime Antarctic Climate Change: Signals from Terrestrial Biology , 2013 .

[37]  A. D. Kennedy Antarctic Terrestrial Ecosystem Response to Global Environmental Change , 1995 .

[38]  P. Convey,et al.  Changes in lichen diversity and community structure with fur seal population increase on Signy Island, South Orkney Islands , 2010, Antarctic Science.

[39]  Roi Méndez-Rial,et al.  Alien Plant Monitoring with Ultralight Airborne Imaging Spectroscopy , 2014, PloS one.

[40]  C. Tucker Red and photographic infrared linear combinations for monitoring vegetation , 1979 .

[41]  P. Convey,et al.  Detecting and mapping vegetation distribution on the Antarctic Peninsula from remote sensing data , 2011, Polar Biology.

[42]  Samuel N. Goward,et al.  Reflectance spectra of subarctic lichens , 1988 .

[43]  W. Verhoef,et al.  Simulation of hyperspectral and directional radiance images using coupled biophysical and atmospheric radiative transfer models , 2003 .

[44]  W. G. Rees,et al.  Reflectance spectra of subarctic lichens between 400 and 2400 nm , 2004 .

[45]  M. Guglielmin,et al.  Permafrost and periglacial research in Antarctica: New results and perspectives , 2014 .

[46]  Successional patterns along soil development gradients formed by glacier retreat in the Maritime Antarctic, King George Island , 2016, Revista Chilena de Historia Natural.

[47]  Roberta E. Martin,et al.  Sources of Canopy Chemical and Spectral Diversity in Lowland Bornean Forest , 2012, Ecosystems.

[48]  S. Sarkar,et al.  Systematic conservation planning , 2000, Nature.

[49]  P. Convey,et al.  Global southern limit of flowering plants and moss peat accumulation , 2011 .

[50]  T. Green,et al.  Functional and spatial pressures on terrestrial vegetation in Antarctica forced by global warming , 2011, Polar Biology.

[51]  Wenjiang Huang,et al.  Estimating winter wheat plant water content using red edge parameters , 2004 .

[52]  P. Convey,et al.  Mapping lichen distribution on the Antarctic Peninsula using remote sensing, lichen spectra and photographic documentation by citizen scientists , 2015 .

[53]  F. Valladares,et al.  Lichen colonization of recent moraines on Livingston Island (South Shetland I., Antarctica) , 1993, Polar Biology.

[54]  André Große-Stoltenberg,et al.  Field Spectroscopy in the VNIR-SWIR Region to Discriminate between Mediterranean Native Plants and Exotic-Invasive Shrubs Based on Leaf Tannin Content , 2015, Remote. Sens..

[55]  K. Swadling Antarctic Biology in a Global Context , 2004 .

[56]  P. Convey,et al.  Impacts of local human activities on the Antarctic environment , 2008, Antarctic Science.

[57]  J. Benayas,et al.  Rapid denudation processes in cryptogamic communities from Maritime Antarctica subjected to human trampling , 2013, Antarctic Science.

[58]  Benoit Rivard,et al.  Spectral unmixing of normalized reflectance data for the deconvolution of lichen and rock mixtures , 2005 .