Poster_IGARSS_4913 [Mode de compatibilité] - i-sea
Transcription
Poster_IGARSS_4913 [Mode de compatibilité] - i-sea
Hyperspectral field database in support to coastal wetland mapping A. Dehouck1,2, V. Lafon1,2, B. Lubac2,3, S. Kervella1,2, D. Bru2,3, M. Schmeltz2,3, A. Roubache1,2 1 GEO-Transfert, ADERA, avenue du Dr Schweitzer, 33600 Pessac, France de Bordeaux, EPOC, UMR 5805, avenue des facultés, 33405 Talence, France 3 CNRS, EPOC, UMR 5805, avenue des facultés, 33405 Talence, France 2 Université Introduction and objectives Coastal areas are very attractive places worldwide that undergo significant changes due to natural variability, climate change and anthropogenic activities. The macrotidal lagoon of Arcachon (SW of France, Figure 1) is characterized by a wide range of natural habitats classified in the Natura 2000 network. The upper tidal levels are occupied by coastal salt-marshes (Figure 2) which constitute valuable habitats with regards to biodiversity and ecosystem functioning. Intertidal mud and sand flats are partially covered by a thin vegetation cover of Zostera noltii aquatic plants (Figure 3). Figure 2. Salt marsh Figure 3. Zostera noltii over intertidal flats Spaceborne remote sensing is an efficient and low-cost tool to ensure long-term monitoring over wide coastal areas and assess their changes over time [1,2,3]. This contribution forms a part of an ongoing research work that aims to derive accurate spatial maps of the Arcachon lagoon from highresolution multispectral optical imagery (Spot, Formosat). This paper investigates the hyperspectral signatures of the main intertidal facies over space and time in order to determine if the vegetation species can be dissociated one from each other using multispectral bands or band associations (e.g. NDVI), and if not, what is the potential of hyperspectral imagery to do so. Figure 1. Arcachon lagoon. Red boxes locate field sites. Data and methods The hyperspectral database consists of about three hundred and twenty-five reflectance spectra. Various sediment grain size, vegetation species, vegetation cover have been sampled (Fig. 4) at a seasonal timescale. In particular, we collected spectra over Zostera noltii seabeds with various sediment backgrounds (sand and muddy sand) and typical Water Framework Directive densities (0-25%, 25-75%, 75-100%), endemic Spartina maritima and invasive Spartina anglica (lower salt-marsh vegetation), green algal deposits as well as bare sediments which were occasionally associated with a microphytobenthos biofilm. Sampled areas are reported on Figure 1. Data presented here are remote sensing reflectance (Rrs in sr-1) measurements performed at nadir. A series of relevant accompanying measurements was also realized consisting in sediment grain size, sediment moisture, microphytobenthos biomass and characterization of vegetation species. Each measurement was geo-positioned using a Trimble GEO XT GPS (0.5 m accuracy). Figure 4. Content of the hyperspectral field data base Results Zostera noltii vs Spartina Effect of sediment background In both summer and winter time, Spartina maritima presents low reflectances from the blue to the red domain in comparison to Z. noltii and Spartina anglica covers (Figure 8). Also, both Spartina sp. winter spectra are clearly discriminable from Zostera spectra. This indicates that coupling winter and summer bands in a classification scheme will increase the discrimination of the lower salt marsh from intertidal seagrass meadows and the discrimination between endemic and invasive Spartina species. Reflectance data indicate a strong dependence of Zostera noltii seabeds to sediment background (Figure 6), particularly for lowly- to moderatelyvegetated covers. As demonstrated in laboratory [1], reflectance is higher over the whole spectra for brighter sediments than for darker ones. Variations in the NDVI are also background-dependent. This suggests that the NDVI cannot be used to retrieve Zostera noltii density, except if it is associated with a detection tool of the underlying substrate. Biofilm detection A set of reflectance spectra acquired over sands and muddy sands shows strong light absorption at 670 nm due to the presence of chlorophyll (Figure 7). Here, tiny reflectance variations in the blue to red range suppose discrimination of the microphytobenthos from bare sediment and Zostera seabed may be possible using multispectral imagery. But in many other cases, the spectra are much more confused. Thus, more data are still needed to assess the capability of either multispectral and hyperspectral sensors to detect microphytobenthic biofilms. Again, the use of NDVI may also bring confusion with similar NDVI values being both associated with biofilms and Zostera noltii covers. Figure 6. Reflectance spectra of low-density Zostera noltii seabeds (0-25 %) over sands (red) and a muddy sand (green) background Figure 7. Reflectance spectra of bare sediment, microphytobenthos biofilms and low Zostera noltii seabeds Zostera noltii vs green algae Several green algae species (Ulva, Enteromorpha, Monostroma, Cladophora) proliferate in the Arcachon lagoon at various seasons. Figure 9 compares algae and Zostera reflectance spectra. Reflectance behaves differently from the blue to red wavelengths depending on the considered algae species: some algae (Enteromorpha, Cladophora) experiment a slightly weakened reflectance while filamentous deposits are quite similar to Zostera seabed. Thus, it appears necessary to consider small differences in narrow bands. More investigations are needed here to clarify the discrimination potential of all algae species from Zostera noltii from the use of both commercial space sensors and airborne hyperspectral imagery. Figure 5. Deployment of TriOS sensors over a patch of Spartina anglica at wintertime Figure 8. Typical reflectance spectra acquired in summer (continuous line) and winter time (dashed) of Zostera noltii seabeds (green), Spartina maritima (red) and Spartina anglica (purple) Figure 9. Comparison between Zostera noltii seabeds (green) and green algae reflectance spectra (blue) Conclusions The hyperspectral field dataset recorded along the Arcachon lagoon is crucial to adapt a mapping strategy based on optical imagery, in particular when space imagery is the only accessible tool. The dataset demonstrates the potential of e.g. SPOT and Formosat imagery to derive biosedimentary maps of the intertidal lagoon. These results demonstrate the potential of selecting carefully multispectral bands or by combining them using a multi-temporal strategy to achieve discrimination of the habitats of interest. In particular, we established that several vegetation species are discriminable using multispectral imagery (intertidal Zostera noltii, endemic Spartina martima and invasive Spartina anglica). However, algae deposits must be treated carefully, since only some species seem discriminable only when using narrow spectral bands. Finally, we must highlight the counterproductive use of associating the NDVI to qualify the vegetation density over intertidal flats in a multispectral classification scheme, since it may confuse biofilms with seagrass covers. References: [1] L. Barillé, J.-L. Mouget, V. Méléder, P. Rosa, and B. Jesus, “Spectral response of benthic diatoms with different sediment backgrounds”, Remote Sensing of Environment, 115, pp. 1034–1042, 2011. [2] L. Barillé, M. Robin, N. Harin, A. Bargain, and P. Launeau, “Increase in seagrass distribution at Bourgneuf Bay (France) detected by spatial remote sensing”, Aquatic Botany, 92, pp. 185–194, 2010. [3] V. Lafon, V. Marieu, R. Butel, A. Dehouck, J.M. Froidefond, and G. Trut “Cartographie des faciès bio-sédimentaires du Bassin d’Arcachon par imagerie Formosat-2”, Proceedings of the 10èmes Journées Nationales Génie Côtier Génie Civil, Sophia-Antipolis, pp. 563-572, in French, 2008. This work has recently been funded by the CNES (French Space Center) in the frame of the ORFEO program (Pleiades preparatory program) in 2010 and TOSCA SYNIHAL in 2011.