Large-scale mapping of boreal forest in SIBERIA using ERS tandem coherence and JERS backscatter data

Wagner, Wolfgang; Luckman, Adrian; Vietmeier, J.; Tansey, Kevin; Balzter, Heiko; Schmullius, Christiane; Davidson, Malcolm; Gaveau, David; Gluck, M.; Toan, Thuy Le; Quegan, S.; Shvidenko, А.; Wiesmann, Andreas; Yu, Jihong

doi:10.1016/s0034-4257(02)00198-0

Cited by 127 publications

(91 citation statements)

References 42 publications

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“…Vegetation observed in remote-sensing data is usually described in terms of derived variables such as vegetation indices (normalized difference vegetation index (NDVI), soil-adjusted vegetation index (SAVI), enhanced vegetation index (EVI), etc.) (Tucker 1979;Tarpley 1991;Jackson and Huete 1991;Baret and Guyot 1991;Gupta 1993;Huete et al 1997), leaf area index (LAI) (Gupta, Prasad, and Vijayan 2000;Fensholt, Sandholt, and Rasmussen 2004;Casa and Jones 2005), tree cover density (Bai et al 2005;Yang, Weisberg, and Bristow 2012;Leinenkugel et al 2014, forthcoming), net primary productivity (NPP) and biomass (gC m −2 ) (Wagner et al 2003;Hese et al 2005;Lu 2006;Eisfelder, Kuenzer, and Dech 2011), canopy moisture (Brakke et al 1981), canopy height, expected crop yield (Birnie, Robertson, and Stove 1982;Hatfield 1983;Horie, Yajima, and Nakagawa 1992), measures of fragmentation and connectivity (Stenhouse 2004;Pueyo and Alados 2007;Briant, Gond, and Laurance 2010), or as detailed classification-derived map products breaking down vegetation distribution to the species level (Foody and Cutler 2006;Kutser and Jupp 2006;Pu and Landry 2012;Engler et al 2013). Vegetation height can also be derived from digital elevation model (DEM) data (Walker et al 2007).…”

Section: Spaceborne Remote Sensing Of Vegetation Biodiversitymentioning

confidence: 99%

Earth observation satellite sensors for biodiversity monitoring: potentials and bottlenecks

Kuenzer

Ottinger²,

Wegmann³

et al. 2014

International Journal of Remote Sensing

157

112

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Many biologists, ecologists, and conservationists are interested in the possibilities that remote sensing offers for their daily work and study site analyses as well as for the assessment of biodiversity. However, due to differing technical backgrounds and languages, cross-sectorial communication between this group and remote-sensing scientists is often hampered. Hardly any really comprehensive studies exist that are directed towards the conservation community and provide a solid overview of available Earth observation sensors and their different characteristics. This article presents, categorizes, and discusses what spaceborne remote sensing has contributed to the study of animal and vegetation biodiversity, which different types of variables of value for the biodiversity community can be derived from remote-sensing data, and which types of spaceborne sensor data are available for which time spans, and at which spatial and temporal resolution. We categorize all current and important past sensors with respect to application fields relevant for biologists, ecologists, and conservationists. Furthermore, sensor gaps and current challenges for Earth observation with respect to data access and provision are presented.

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Section: Spaceborne Remote Sensing Of Vegetation Biodiversitymentioning

confidence: 99%

Earth observation satellite sensors for biodiversity monitoring: potentials and bottlenecks

Kuenzer

Ottinger²,

Wegmann³

et al. 2014

International Journal of Remote Sensing

157

112

View full text Add to dashboard Cite

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“…Although such datasets can only be considered for comparison purposes as they do not qualify as reference sets for validation, they were of interest to benchmark the ASAR GSV and assess its overall reliability towards quantifying forest resources and carbon stocks in the boreal zone and to pinpoint areas of discrepancy. Table 2 provides an overview of the three different types of GSV datasets for the three study regions ( [6,7,10,29,39,[55][56][57]). If necessary, datasets were re-projected and resampled into the geographic projection used for the ASAR data.…”

Section: Gsv Datasetsmentioning

confidence: 99%

“…A polygon corresponds to an area with similar forest properties in terms of tree species, age, productivity, GSV and local homogeneity. Such data were available from ten forest enterprises located in Irkutsk Oblast [29] (Tables 2 and 3) and originated from forest surveys carried out according to the Russian Forest Inventory Manual [58]. Forest stand boundaries were based on manual interpretation of aerial photographs.…”

Section: Forest Field Inventory Datasetsmentioning

confidence: 99%

“…LiDAR (Light Detection And Ranging) point-wise measurements have been implemented in combination with either in situ or two-dimensional data from optical imagery to provide spatially explicit estimates of forest canopy height [16,17], above-ground biomass [18][19][20][21][22], and above-ground carbon [23] at regional and global scales. Mapping efforts based on spaceborne synthetic aperture radar (SAR) are instead limited to investigations based on images acquired between 1994 and 2000 to obtain estimates of above-ground biomass in the boreal zone of Canada [24] and the Amazon basin [25], canopy height for the conterminous US [26], growing stock volume in Central Siberia [27][28][29] and Northeast China [30], and forest age for UK [31].…”

Section: Introductionmentioning

confidence: 99%

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Estimates of Forest Growing Stock Volume for Sweden, Central Siberia, and Québec Using Envisat Advanced Synthetic Aperture Radar Backscatter Data

et al. 2013

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A study was undertaken to assess Envisat Advanced Synthetic Aperture Radar (ASAR) ScanSAR data for quantifying forest growing stock volume (GSV) across three boreal regions with varying forest types, composition, and structure (Sweden, Central Siberia, and Québec). Estimates of GSV were obtained using hyper-temporal observations of the radar backscatter acquired by Envisat ASAR with the BIOMASAR algorithm. In total, 5.3×106 km2 were mapped with a 0.01° pixel size to obtain estimates representative for the year of 2005. Comparing the SAR-based estimates to spatially explicit datasets of GSV, generated from forest field inventory and/or Earth Observation data, revealed similar spatial distributions of GSV. Nonetheless, the weak sensitivity of C-band backscatter to forest structural parameters introduced significant uncertainty to the estimated GSV at full resolution. Further discrepancies were observed in the case of different scales of the ASAR and the reference GSV and in areas of fragmented landscapes. Aggregation to 0.1° and 0.5° was then undertaken to generate coarse scale estimates of GSV. The agreement between ASAR and the reference GSV datasets improved; the relative difference at 0.5° was consistently within a magnitude of 20–30%. The results indicate an improvement of the characterization of forest GSV in the boreal zone with respect to currently available information

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“…In general, non-forest areas (e.g., urban areas, bare soil), typically stable over time, have high coherence value. Since coherence is typically lower over forests (through an increase of volume and corresponding temporal decorrelation), interferometric coherence can be used for the mapping of forest/non-forest areas [11] as well as for AGB assessment [12,13]. Limitations of radar data for AGB estimation are saturation as well as strong dependence on environmental conditions (e.g., rain fall, and soil moisture conditions).…”

Section: Introductionmentioning

confidence: 99%

Improved Multi-Sensor Satellite-Based Aboveground Biomass Estimation by Selecting Temporally Stable Forest Inventory Plots Using NDVI Time Series

Urbazaev

Thiel

Migliavacca

et al. 2016

Forests

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Accurate estimates of aboveground biomass (AGB) are crucial to assess terrestrial C-stocks and C-emissions as well as to develop sustainable forest management strategies. In this study we used Synthetic Aperture Radar (SAR) data acquired at L-band and the Landsat tree cover product together with Moderate Resolution Image Spectroradiometer (MODIS) normalized difference vegetation index (NDVI) time series data to improve AGB estimations over two study areas in southern Mexico. We used Mexican National Forest Inventory (INFyS) data collected between 2005 and 2011 to calibrate AGB models as well as to validate the derived AGB products. We applied MODIS NDVI time series data analysis to exclude field plots in which abrupt changes were detected. For this, we used Breaks For Additive Seasonal and Trend analysis (BFAST). We modelled AGB using an original field dataset and BFAST-filtered data. The results show higher accuracies of AGB estimations using BFAST-filtered data than using original field data in terms of R 2 and root mean square error (RMSE) for both dry and humid tropical forests of southern Mexico. The best results were found in areas with high deforestation rates where the AGB models based on the BFAST-filtered data substantially outperformed those based on original field data (R 2 BFAST = 0.62 vs. R 2 orig = 0.45; RMSE BFAST = 28.4 t/ha vs. RMSE orig = 33.8 t/ha). We conclude that the presented method shows great potential to improve AGB estimations and can be easily and automatically implemented over large areas.

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Large-scale mapping of boreal forest in SIBERIA using ERS tandem coherence and JERS backscatter data

Cited by 127 publications

References 42 publications

Earth observation satellite sensors for biodiversity monitoring: potentials and bottlenecks

Earth observation satellite sensors for biodiversity monitoring: potentials and bottlenecks

Estimates of Forest Growing Stock Volume for Sweden, Central Siberia, and Québec Using Envisat Advanced Synthetic Aperture Radar Backscatter Data

Improved Multi-Sensor Satellite-Based Aboveground Biomass Estimation by Selecting Temporally Stable Forest Inventory Plots Using NDVI Time Series

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