TY  - JOUR
A1  - Landmann, Tobias
A1  - Schramm, Matthias
A1  - Colditz, Rene R.
A1  - Dietz, Andreas
A1  - Dech, Stefan
T1  - Wide Area Wetland Mapping in Semi-Arid Africa Using 250-Meter MODIS Metrics and Topographic Variables
N2  - Wetlands in West Africa are among the most vulnerable ecosystems to climate change. West African wetlands are often freshwater transfer mechanisms from wetter climate regions to dryer areas, providing an array of ecosystem services and functions. Often wetland-specific data in Africa is only available on a per country basis or as point data. Since wetlands are challenging to map, their accuracies are not well considered in global land cover products. In this paper we describe a methodology to map wetlands using well-corrected 250-meter MODIS time-series data for the year 2002 and over a 360,000 km2 large study area in western Burkina Faso and southern Mali (West Africa). A MODIS-based spectral index table is used to map basic wetland morphology classes. The index uses the wet season near infrared (NIR) metrics as a surrogate for flooding, as a function of the dry season chlorophyll activity metrics (as NDVI). Topographic features such as sinks and streamline areas were used to mask areas where wetlands can potentially occur, and minimize spectral confusion. 30-m Landsat trajectories from the same year, over two reference sites, were used for accuracy assessment, which considered the area-proportion of each class mapped in Landsat for every MODIS cell. We were able to map a total of five wetland categories. Aerial extend of all mapped wetlands (class “Wetland”) is 9,350 km2, corresponding to 4.3% of the total study area size. The classes “No wetland”/“Wetland” could be separated with very high certainty; the overall agreement (KHAT) was 84.2% (0.67) and 97.9% (0.59) for the two reference sites, respectively. The methodology described herein can be employed to render wide area base line information on wetland distributions in semi-arid West Africa, as a data-scarce region. The results can provide (spatially) interoperable information feeds for inter-zonal as well as local scale water assessments.
KW  - Geologie
KW  - wetland mapping
KW  - MODIS time-series
KW  - Landsat
KW  - land cover
KW  - class homogeneity
KW  - West Africa
Y1  - 2010
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-68628
ER  - 
TY  - THES
A1  - Geßner, Ursula
T1  - Räumliche und zeitliche Muster der Vegetationsstruktur in Savannen des südlichen Afrika
T1  - Spatial and temporal patterns of vegetation structure in southern African savannas
N2  - Die Veränderung der terrestrischen Ökosysteme, ist ein grundlegendes Element des Globalen Wandels. In diesem Kontext unterliegt auch eines der größten Biome der Erde, die tropische und subtropische Savanne, immer stärkeren Veränderungen. Dieses Biom in sozioökonomischer und ökologischer Hinsicht von besonderer Bedeutung. Für einen rasch wachsenden Teil der Weltbevölkerung bildet es die Grundlage für das Betreiben von Weidewirtschaft, Ackerbau und Tourismus. In nationalen und internationalen Forschungsprogrammen zum Globalen Wandel hat die Analyse von Landnutzungs- und Landbedeckungsänderungen in den vergangenen Jahrzehnten zunehmend an Bedeutung gewonnen. Die Landbedeckungsdynamik von Savannenökosystemen ist jedoch noch nicht hinreichend verstanden, so dass diese Ökosysteme in globalen Studien nur ansatzweise berücksichtigt werden können. Besondere Herausforderungen bei der Erfassung der Landbedeckung und ihrer Dynamik liegen im Falle der Savannen in der heterogenen räumlichen Verteilung der Wuchsformen, in den graduellen Übergängen zwischen Landbedeckungsklassen und in der hohen inner- und interannuellen Variabilität der Vegetationsdecke. Vor diesem Hintergrund beschäftigt sich diese Dissertation mit der fernerkundungsbasierten Erfassung und Interpretation der Vegetationsstruktur und der Vegetationsdynamik von Savannen am Beispiel ausgewählter afrikanischer Untersuchungsregionen. Die Vegetationsstruktur wird in dieser Dissertation in Form von Bedeckungsgraden holziger Vegetation, krautiger Vegetation und vegetationsloser Fläche erfasst. Es kommt ein mehrskaliges Verfahren zum Einsatz, in dem höchstaufgelöste IKONOS- und QuickBird-Daten, Landsat-Daten und annuelle MODIS-Zeitreihen ausgewertet werden. Der Ansatz basiert auf der Methodik der Ensemble-Regeressionbäume und stellt eine Erweiterung und Optimierung der Herangehensweise des MODIS-Standardproduktes Vegetation Continuous Fields (VCF) nach Hansen et al. (2002) dar. Beim Vergleich mit unabhängigen Validierungsdaten der nächst höheren Auflösungsebene zeigt sich das Potenzial der vorgestellten Methodik. Die räumliche Übertragbarkeit der Regressionsbäume wird am Beispiel von zwei Vegetationstypen innerhalb der Zentralnamibischen Savanne dargestellt. In diesem Zusammenhang zeigt sich der hohe Stellenwert einer optimalen Auswahl an Trainingsdaten mit einer repräsentativen Abdeckung der Wertespanne aller existierenden Bedeckungsgrade. Die erarbeiteten Resultate unterstreichen, die optimale Eignung der Subpixel-Bedeckungsgrade, gerade zur Beschreibung von Savannenlandschaften. In der Kombination von herkömmlichen, diskreten Landbedeckungs- oder Vegetationskarten mit Informationen zu Bedeckungsgraden wird ein besonderer Mehrwert für weiterführende Analysen gesehen. Die Dynamik der Savannenvegetation wird in dieser Arbeit sowohl auf biannueller als auch auf mehrjähriger Skala charakterisiert. Bei der biannuellen Analyse werden die Veränderungen der holzigen Vegetationsbedeckung zwischen den Jahren 2003/04 und 2006/07 erfasst. Hierfür findet eine zeitliche Übertragung des zuvor vorgestellten Verfahrens zur Ableitung von Bedeckungsanteilen statt. Im Rahmen der biannuellen Untersuchungen können Veränderungsflächen identifiziert werden, ohne Einschränkung auf Übergänge zwischen fest definierten Klassengrenzen. In Ergänzung der biannuellen Analysen werden aus MODIS-EVI- und Niederschlagszeitreihen Maßzahlen abgeleitet, die den Zusammenhang zwischen Niederschlag und Vegetationsentwicklung, die Variabilität und die Trends der Vegetation über einen Zeitraum von acht Jahren beschreiben. Hierbei kommen beispielsweise Korrelationsanalysen zwischen Vegetationsindex- und Niederschlagszeitreihen zum Einsatz. Zudem werden Trendanalysen der Vegetationsindex-Zeitreihen durchgeführt. Die Trends werden einerseits allein aus den Zeitreihen der Vegetationsindizes ermittelt, andererseits wird bei der Berechnung von Restrends (Residual Trends) der Einfluss des Niederschlags berücksichtigt. Neben den Korrelations- und Trendanalysen werden unterschiedliche Variabilitätsmaße der Vegetationsindex-Zeitreihen genutzt, um die mehrjährige Vegetationsdynamik zu beschreiben. Durch die Kombination von Fernerkundungsdaten unterschiedlicher räumlicher und zeitlicher Auflösungen wird in dieser Dissertation die heterogene Vegetationsstruktur und die komplexe Vegetationsdynamik ausgewählter afrikanischer Savannenökosysteme beschreiben.
N2  - The change of terrestrial ecosystems is a fundamnental element of Global Change. In this context, also one of the largest terrestrial biomes, the tropical and subtropical savanna, is subject to increasing changes. This biome is of high socioeconomic and ecologic relevance both globally and for the vulnerable African continent. Savannas provide fundamental natural resources for cropping, grazing and tourism for a rapidly growing part of the global population. Furthermore, savannas are characterised by an extraordinary biodiversity. With regard to carbon storage and carbon fluxes they occupy the second rank after the global forest biome. During the last few decades, national and international research programmes have increasingly focused on the analysis of land cover and land use change. However, the land surface dynamics of savanna ecosystems are not yet fully understood. The consequence is, that savanna ecosystems can not yet be adequately included in global studies. When analysing the land surface and land surface dynamics of savannas, the major challenge is to be seen in the heterogeneous spatial patterns of vegetation growth forms, in gradual transitions between land cover classes and in the high innerand interannual variability of vegetation. In this framework, this thesis deals with the remote sensing based assessment and interpretation of vegetation structure and vegetation dynamics in selected African savanna regions. Vegetation structure is delineated as per pixel fractional cover of woody vegetation, herbaceous vegetation and bare surface. A multiscale approach is used which includes the analysis of very high resolution IKONOS and QuickBird data, high resolution Landsat data, and medium resolution MODIS time-series. The approach is based on ensemble regression trees and can be seen as an extension and regional optimisation of the approach of the MODIS standard product Vegetation Continuous Fields (VCF, Hansen et al. 2002). The spatial transferability of the regression tree ensembles is demonstrated for two vegetation types of the central Namibian savanna. In this context, the high relevance of an optimal selection of training data is demonstrated. This means first of all that training data should cover the complete range of existing cover types of the area under investigation. The presented results underline the high potential of analysing sub-pixel fractional cover in savanna landscapes as the typical heterogeneous structure and the gradual transitions of vegetation cover are captured adequately. Added value is seen in the combination of the delineated fractional vegetation cover with conventional discrete classifications. The dynamics of the savanna vegetation of the northern Namibian study region Kalahari Woodland is examined both at biannual and multiannual scale. In the biannual analysis, changes of woody vegetation cover between the years 2003/04 and 2006/07 are delineated. For this purpose, the presented multiscale approach for the delineation of fractional vegetation cover is adapted in order to also analyse the situation of a past year. This temporal transfer is conceived in a way that does not require very high resolution satellite data for the past. Based on the biannual analyses, areas of change can be identified without any constraint to predefined transitions of class boundaries. In addition to the biannual analyses, time-series of MODIS-EVI and rainfall are analysed. Metrics are calculated from these time-series which describe the connection between precipitation and vegetation development as well as gradual changes (trends) and variability of the vegetation for a period of 8 years. Here, correlation analyses between time-series of rainfall and vegetation indices are used. Furthermore, trend analyses of vegetation indices are performed as well as Restrend (Residual trend) analyses accounting for the influence of precipitation on vegetation. In addition to these correlation and trend analyses different measures of variability are calculated. In this thesis, the heterogeneous vegetation structure and the complex vegetation dynamics of selected African savannas are characterised by the combined analysis of remote sensing data of different spatial and temporal resolutions. The presented analyses reveal possibilities to enhance regional studies of the state and dynamics of savanna ecosystems.
KW  - Savanne
KW  - Optische Fernerkundung
KW  - Vegetation
KW  - Südafrika
KW  - Bedeckungsgrade
KW  - Landbedeckung
KW  - Landbedeckungsveränderungen
KW  - Fernerkundung
KW  - fractional cover
KW  - land cover
KW  - land cover change
Y1  - 2010
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-55128
ER  - 
TY  - JOUR
A1  - Ullmann, Tobias
A1  - Schmitt, Andreas
A1  - Roth, Achim
A1  - Duffe, Jason
A1  - Dech, Stefan
A1  - Hubberten, Hans-Wolfgang
A1  - Baumhauer, Roland
T1  - Land Cover  Characterization and Classification of Arctic Tundra Environments by Means of Polarized Synthetic Aperture X- and C-Band Radar (PolSAR) and Landsat 8 Multispectral Imagery — Richards Island, Canada
N2  - In this work the potential of polarimetric Synthetic Aperture Radar (PolSAR) data of dual-polarized TerraSAR-X (HH/VV) and quad-polarized Radarsat-2 was examined in combination with multispectral Landsat 8 data for unsupervised and supervised classification of tundra land cover types of Richards Island, Canada. The classification accuracies as well as the backscatter and reflectance characteristics were analyzed using reference data collected during three field work campaigns and include in situ data and high resolution airborne photography. The optical data offered an acceptable initial accuracy for the land cover classification. The overall accuracy was increased by the combination of PolSAR and optical data and was up to 71% for unsupervised (Landsat 8 and TerraSAR-X) and up to 87% for supervised classification (Landsat 8 and Radarsat-2) for five tundra land cover types. The decomposition features of the dual and quad-polarized data showed a high sensitivity for the non-vegetated substrate (dominant surface scattering) and wetland vegetation (dominant double bounce and volume scattering). These classes had high potential to be automatically detected with unsupervised classification techniques.
KW  - radar
KW  - arctic
KW  - tundra
KW  - land cover
KW  - classification
KW  - polarimetry
KW  - PolSAR
KW  - SAR
KW  - TerraSAR-X
KW  - Radarsat-2
Y1  - 2014
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-113303
ER  - 
TY  - JOUR
A1  - Remelgado, Ruben
A1  - Safi, Kamran
A1  - Wegmann, Martin
T1  - From ecology to remote sensing: using animals to map land cover
JF  - Remote Sensing in Ecology and Conservation
N2  - Land cover is a key variable in monitoring applications and new processing technologies made deriving this information easier. Yet, classification algorithms remain dependent on samples collected on the field and field campaigns are limited by financial, infrastructural and political boundaries. Here, animal tracking data could be an asset. Looking at the land cover dependencies of animal behaviour, we can obtain land cover samples over places that are difficult to access. Following this premise, we evaluated the potential of animal movement data to map land cover. Specifically, we used 13 White Storks (Cicona cicona) individuals of the same population to map agriculture within three test regions distributed along their migratory track. The White Stork has adapted to foraging over agricultural lands, making it an ideal source of samples to map this land use. We applied a presence-absence modelling approach over a Normalized Difference Vegetation Index (NDVI) time series and validated our classifications, with high-resolution land cover information. Our results suggest White Stork movement is useful to map agriculture, however, we identified some limitations. We achieved high accuracies (F1-scores > 0.8) for two test regions, but observed poor results over one region. This can be explained by differences in land management practices. The animals preferred agriculture in every test region, but our data showed a biased distribution of training samples between irrigated and non-irrigated land. When both options occurred, the animals disregarded non-irrigated land leading to its misclassification as non-agriculture. Additionally, we found difference between the GPS observation dates and the harvest times for non-irrigated crops. Given the White Stork takes advantage of managed land to search for prey, the inactivity of these fields was the likely culprit of their underrepresentation. Including more species attracted to agriculture - with other land-use dependencies and observation times - can contribute to better results in similar applications.
KW  - Animal Tracking
KW  - land cover
KW  - land use
KW  - movement ecology
KW  - R
KW  - remote sensing
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-225200
VL  - 6
IS  - 1
ER  - 
TY  - JOUR
A1  - Koehler, Jonas
A1  - Kuenzer, Claudia
T1  - Forecasting spatio-temporal dynamics on the land surface using Earth Observation data — a review
JF  - Remote Sensing
N2  - Reliable forecasts on the impacts of global change on the land surface are vital to inform the actions of policy and decision makers to mitigate consequences and secure livelihoods. Geospatial Earth Observation (EO) data from remote sensing satellites has been collected continuously for 40 years and has the potential to facilitate the spatio-temporal forecasting of land surface dynamics. In this review we compiled 143 papers on EO-based forecasting of all aspects of the land surface published in 16 high-ranking remote sensing journals within the past decade. We analyzed the literature regarding research focus, the spatial scope of the study, the forecasting method applied, as well as the temporal and technical properties of the input data. We categorized the identified forecasting methods according to their temporal forecasting mechanism and the type of input data. Time-lagged regressions which are predominantly used for crop yield forecasting and approaches based on Markov Chains for future land use and land cover simulation are the most established methods. The use of external climate projections allows the forecasting of numerical land surface parameters up to one hundred years into the future, while auto-regressive time series modeling can account for intra-annual variances. Machine learning methods have been increasingly used in all categories and multivariate modeling that integrates multiple data sources appears to be more popular than univariate auto-regressive modeling despite the availability of continuously expanding time series data. Regardless of the method, reliable EO-based forecasting requires high-level remote sensing data products and the resulting computational demand appears to be the main reason that most forecasts are conducted only on a local scale. In the upcoming years, however, we expect this to change with further advances in the field of machine learning, the publication of new global datasets, and the further establishment of cloud computing for data processing.
KW  - forecast
KW  - Earth Observation
KW  - land surface
KW  - land use
KW  - land cover
KW  - time series
KW  - machine learning
KW  - Markov chains
KW  - modeling
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-216285
SN  - 2072-4292
VL  - 12
IS  - 21
ER  -