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Glacier outlines during the ‘Little Ice Age’ maximum in Jotunheimen were mapped by using remote sensing techniques (vertical aerial photos and satellite imagery), glacier outlines from the 1980s and 2003, a digital terrain model (DTM), geomorphological maps of individual glaciers, and field-GPS measurements. The related inventory data (surface area, minimum and maximum altitude) and several other variables (e.g. slope, range) were calculated automatically by using a geographical information system. The length of the glacier flowline was mapped manually based on the glacier outlines at the maximum of the ‘Little Ice Age’ and the DTM. The glacier data during the maximum of the ‘Little Ice Age’ were compared with the Norwegian glacier inventory of 2003. Based on the glacier inventories during the maximum of the ‘Little Ice Age’, the 1980s and 2003, a simple parameterization after HAEBERLI & HOELZLE (1995) was performed to estimate unmeasured glacier variables, as e.g. surface velocity or mean net mass balance. Input data were composed of surface glacier area, minimum and maximum elevation, and glacier length. The results of the parameterization were compared with the results of previous parameterizations in the European Alps and the Southern Alps of New Zealand (HAEBERLI & HOELZLE 1995; HOELZLE et al. 2007). A relationship between these results of the inventories and of the parameterization and climate and climate changes was made.
Processes of the Earth’s surface occur at different scales of time and intensity. Climate in particular determines the activity and seasonal development of vegetation. These dynamics are predominantly driven by temperature in the humid mid-latitudes and by the availability of water in semi-arid regions. Human activities are a modifying parameter for many ecosystems and can become the prime force in well-developed regions with an intensively managed environment. Accounting for these dynamics, i.e. seasonal dynamics of ecosystems and short- to long-term changes in land-cover composition, requires multiple measurements in time. With respect to the characterization of the Earth surface and its transformation due to global warming and human-induced global change, there is a need for appropriate data and methods to determine the activity of vegetation and the change of land cover. Space-borne remote sensing is capable of monitoring the activity and development of vegetation as well as changes of the land surface. In many instances, satellite images are the only means to comprehensively assess the surface characteristics of large areas. A high temporal frequency of image acquisition, forming a time series of satellite data, can be employed for mapping the development of vegetation in space and time. Time series allow for detecting and assessing changes and multi-year transformation processes of high and low intensity, or even abrupt events such as fire and flooding. The operational processing of satellite data and automated information-extraction techniques are the basis for consistent and continuous long-term product generation. This provides the potential for directly using remote-sensing data and products for analyzing the land surface in relation to global warming and global change, including deforestation and land transformation. This study aims at the development of an advanced approach to time-series generation using data-quality indicators. A second goal focuses on the application of time series for automated land-cover classification and update, using fractional cover estimates to accommodate for the comparatively coarse spatial resolution. Requirements of this study are the robustness and high accuracy of the approaches as well as the full transferability to other regions and datasets. In this respect, the developments of this study form a methodological framework, which can be filled with appropriate modules for a specific sensor and application. In order to attain the first goal, time-series compilation, a stand-alone software application called TiSeG (Time Series Generator) has been developed. TiSeG evaluates the pixel-level quality indicators provided with each MODIS land product. It computes two important data-availability indicators, the number of invalid pixels and the maximum gap length. Both indices are visualized in time and space, indicating the feasibility of temporal interpolation. The level of desired data quality can be modified spatially and temporally to account for distinct environments in a larger study area and for seasonal differences. Pixels regarded as invalid are either masked or interpolated with spatial or temporal techniques.
Die Bewässerungslandwirtschaft in Mittelasien ist geprägt von schwerwiegenden ökologischen und ökonomischen Problemen. Zur Verbesserung der Situation auf dem hydrologischen Sektor wird daher seitens der mittelasiatischen Interstate Commission for Water Coordination (ICWC) die Einführung des Integrated Water Resource Management (IWRM) gefordert. Wichtige Herausforderungen zur Optimierung der Wassernutzung im Aralsee-Becken sind dabei die Schaffung von Transparenz sowie von Möglichkeiten zur Überwachung der Landnutzung und der Wasserentnahme in den Bewässerungssystemen. Im Detail fokussierte diese Arbeit auf das Bewässerungssystem der Region Khorezm im Unterlauf des Amu Darya südlich des Aralsees. Die Arbeit zielte darauf ab, (1) objektive und konsistente Datengrundlagen zum Monitoring der Landnutzung und des Wasserverbrauchs innerhalb des Bewässerungslandes zu schaffen und (2) auf Basis dieser Ergebnisse die Funktionsweise des Bewässerungssystems zu verstehen sowie die Land- und Wassernutzung der Region zu bewerten. Um diese Ziele zu erreichen, wurden Methoden der Fernerkundung und der Hydrologie miteinander kombiniert. Fernerkundliche Schlüsselgrößen der Arbeit waren die Kartierung der agrarischen Landnutzung und die Modellierung der saisonalen tatsächlichen Evapotranspiration. Es wurde eine Methode vorgestellt, die eine Unterscheidung verschiedener Landnutzungen und Fruchtfolgen der Region durch die temporale Segmentierung von Zeitserien aus 8-tägigen Kompositen von 250 m-Daten des MODIS-Sensors ermöglicht. Durch die mehrfache Anwendung von Recursive Partitioning And Regression Trees auf deskriptive Statistiken von Zeitseriensegmenten konnte eine hohe Stabilität erzielt werden (overall accuracy: 91 %, Kappa-Koeffizient: 0,9). Täglich von MODIS aufgezeichnete Landoberflächentemperaturen (LST) bildeten die Basis zur fernerkundungsbasierten Modellierung der saisonalen tatsächlichen Evapotranspiration (ETact) für die sommerliche Vegetationsperiode. Aufgrund der hohen zeitlichen und groben räumlichen Auflösung der verwendeten MODIS-Daten von 1 km waren leichte Modifikationen des zur Modellierung eingesetzten Surface Energy Balance Algortihm for Land (SEBAL) erforderlich. Zur Modellierung von ETact wurden MODIS-Produkte (LST, Emissionsgrad, Albedo, NDVI und Blattflächenindex) und meteorologische Stationsdaten aus Khorezm verwendet. Die Modellierung des fühlbaren Wärmeflusses, einer Komponente der Energiebilanzgleichung an der Erdoberfläche, erfolgte mittels METRIC (High Resolution and Internalized Calibration), einer Variante des SEBAL. Die Landnutzungsklassifikation fungierte als zentraler Eingangsparameter, um eine automatisierte Auswahl der Ankerpunkte des Models sicherzustellen. Da innerhalb der MODIS-Auflösung aufgrund der Mischpixelproblematik keine homogen feuchten oder trockenen Bedingungen im Bewässerungsgebiet gefunden werden konnten, wurden die Landnutzungsklassifikation, der NDVI und die ASCE-Referenz-Evapotranspiration zur Abschätzung des tatsächlichen Zustands an den Ankerpunkten herangezogen. Weiterhin wurden umfassende Geländemessungen durchgeführt, um in der Vegetationsperiode 2005 die Zu- und Abflussmengen des Wasser von und nach Khorezm zu bestimmen. Die abschließende Bewertung der Land- und Wassernutzung basierte letztendlich auf der Bildung von Wasserbilanzen und der Berechnung anerkannter Performanceindikatoren wie der Ratio aus Drainage und Wasserentnahme oder der depleted fraction. Für die landwirtschaftliche Nutzung im Rayon Khorezm wurde für die Sommersaison 2005 eine Wasserentnahme von 5,38 km3 ermittelt. Damit übertrafen die Messergebnisse die offiziell verfügbaren Daten der ICWC um durchschnittlich 37 %. Auf die landwirtschaftliche Fläche bezogen ergab sich für Khorezm im Jahr 2005 eine mittlere Wasserentnahme von 22.782 m3/ha. In den Subsystemen schwankten diese Werte zwischen 17.000 m3/ha und 30.000 m3/ha. Allerdings konnte an den Systemgrenzen, an denen die Messungen durchgeführt werden, der aus den fernerkundungsbasierten Modellierungen auf WUA-Level erwartete abnehmende Gradient der Wasserentnahme zwischen Oberlauf und Unterlauf nicht nachvollzogen werden. Als Ursache für diese Diskrepanz sind vor allem die Versickerungsverluste im Kanalsystem zu nennen, die den Grundwasserkörper großräumig auffüllen und auf Feldebene nicht zur oberflächlichen Bewässerung zur Verfügung stehen. Monatliche Bilanzierungen und die Analyse der Performanceindikatoren führten zu denselben Ergebnissen. In dieser Arbeit konnte gezeigt werden, dass sich mit Methoden der Fernerkundung objektive und konsistente Daten der agrarischen Landnutzung und des Wasserverbrauchs für ein regionales Monitoring erstellen lassen. Da in den benachbarten Regionen gleiche atmosphärische Bedingungen und ähnliche Anbausorten anzutreffen sind, ist anzunehmen, dass beide Verfahren auch auf der Planungsebene in einem IWRM für die übrigen Mittel- und Unterläufe von Amu Darya und Syr Darya ein hohes Anwendungspotenzial besitzen.
Current changes of biodiversity result almost exclusively from human activities. This anthropogenic conversion of natural ecosystems during the last decades has led to the so-called ‘biodiversity crisis’, which comprises the loss of species as well as changes in the global distribution patterns of organisms. Species richness is unevenly distributed worldwide. Altogether, 17 so-called ‘megadiverse’ nations cover less than 10% of the earth’s land surface but support nearly 70% of global species richness. Mexico, the study area of this thesis, is one of those countries. However, due to Mexico’s large extent and geographical complexity, it is impossible to conduct reliable and spatially explicit assessments of species distribution ranges based on these collection data and field work alone. In the last two decades, Species distribution models (SDMs) have been established as important tools for extrapolating such in situ observations. SDMs analyze empirical correlations between geo-referenced species occurrence data and environmental variables to obtain spatially explicit surfaces indicating the probability of species occurrence. Remote sensing can provide such variables which describe biophysical land surface characteristics with high effective spatial resolutions. Especially during the last three to five years, the number of studies making use of remote sensing data for modeling species distributions has therefore multiplied. Due to the novelty of this field of research, the published literature consists mostly of selective case studies. A systematic framework for modeling species distributions by means of remote sensing is still missing. This research gap was taken up by this thesis and specific studies were designed which addressed the combination of climate and remote sensing data in SDMs, the suitability of continuous remote sensing variables in comparison with categorical land cover classification data, the criteria for selecting appropriate remote sensing data depending on species characteristics, and the effects of inter-annual variability in remotely sensed time series on the performance of species distribution models. The corresponding novel analyses were conducted with the Maximum Entropy algorithm developed by Phillips et al. (2004). In this thesis, a more comprehensive set of remote sensing predictors than in the existing literature was utilized for species distribution modeling. The products were selected based on their ecological relevance for characterizing species distributions. Two 1 km Terra-MODIS Land 16-day composite standard products including the Enhanced Vegetation Index (EVI), Reflectance Data, and Land Surface Temperature (LST) were assembled into enhanced time series for the time period of 2001 to 2009. These high-dimensional time series data were then transformed into 18 phenological and 35 statistical metrics that were selected based on an extensive literature review. Spatial distributions of twelve tree species were modeled in a hierarchical framework which integrated climate (WorldClim) and MODIS remote sensing data. The species are representative of the major Mexican forest types and cover a variety of ecological traits, such as range size and biotope specificity. Trees were selected because they have a high probability of detection in the field and since mapping vegetation has a long tradition in remote sensing. The result of this thesis showed that the integration of remote sensing data into species distribution models has a significant potential for improving and both spatial detail and accuracy of the model predictions.
With accelerating global climate change, the Antarctic Ice Sheet is exposed to increasing ice dynamic change. During 1992 and 2017, Antarctica contributed ~7.6 mm to global sea-level-rise mainly due to ocean thermal forcing along West Antarctica and atmospheric warming along the Antarctic Peninsula (API). Together, these processes caused the progressive retreat of glaciers and ice shelves and weakened their efficient buttressing force causing widespread ice flow accelerations. Holding ~91% of the global ice mass and 57.3 m of sea-level-equivalent, the Antarctic Ice Sheet is by far the largest potential contributor to future sea-level-rise.
Despite the improved understanding of Antarctic ice dynamics, the future of Antarctica remains difficult to predict with its contribution to global sea-level-rise representing the largest uncertainty in current projections. Given that recent studies point towards atmospheric warming and melt intensification to become a dominant driver for future Antarctic ice mass loss, the monitoring of supraglacial lakes and their impacts on ice dynamics is of utmost importance. In this regard, recent progress in Earth Observation provides an abundance of high-resolution optical and Synthetic Aperture Radar (SAR) satellite data at unprecedented spatial and temporal coverage and greatly supports the monitoring of the Antarctic continent where ground-based mapping efforts are difficult to perform. As an automated mapping technique for supraglacial lake extent delineation in optical and SAR satellite imagery as well as a pan-Antarctic inventory of Antarctic supraglacial lakes at high spatial and temporal resolution is entirely missing, this thesis aims to advance the understanding of Antarctic surface hydrology through exploitation of spaceborne remote sensing.
In particular, a detailed literature review on spaceborne remote sensing of Antarctic supraglacial lakes identified several research gaps including the lack of (1) an automated mapping technique for optical or SAR satellite data that is transferable in space and time, (2) high-resolution supraglacial lake extent mappings at intra-annual and inter-annual temporal resolution and (3) large-scale mapping efforts across the entire Antarctic continent. In addition, past method developments were found to be restricted to purely visual, manual or semi-automated mapping techniques hindering their application to multi-temporal satellite imagery at large-scale. In this context, the development of automated mapping techniques was mainly limited by sensor-specific characteristics including the similar appearance of supraglacial lakes and other ice sheet surface features in optical or SAR data, the varying temporal signature of supraglacial lakes throughout the year as well as effects such as speckle noise and wind roughening in SAR data or cloud coverage in optical data. To overcome these limitations, this thesis exploits methods from artificial intelligence and big data processing for development of an automated processing chain for supraglacial lake extent delineation in Sentinel-1 SAR and optical Sentinel-2 satellite imagery. The combination of both sensor types enabled to capture both surface and subsurface lakes as well as to acquire data during cloud cover or wind roughening of lakes. For Sentinel-1, a deep convolutional neural network based on residual U-Net was trained on the basis of 21,200 labeled Sentinel-1 SAR image patches covering 13 Antarctic regions. Similarly, optical Sentinel-2 data were collected over 14 Antarctic regions and used for training of a Random Forest classifier. Optical and SAR classification products were combined through decision-level fusion at bi-weekly temporal scale and unprecedented 10 m spatial resolution. Finally, the method was implemented as part of DLR’s High-Performance Computing infrastructure allowing for an automated processing of large amounts of data including all required pre- and postprocessing steps. The results of an accuracy assessment over independent test scenes highlighted the functionality of the classifiers returning accuracies of 93% and 95% for supraglacial lakes in Sentinel-1 and Sentinel-2 satellite imagery, respectively.
Exploiting the full archive of Sentinel-1 and Sentinel-2, the developed framework for the first time enabled the monitoring of seasonal characteristics of Antarctic supraglacial lakes over six major ice shelves in 2015-2021. In particular, the results for API ice shelves revealed low lake coverage during 2015-2018 and particularly high lake coverage during the 2019-2020 and 2020-2021 melting seasons. On the contrary, East Antarctic ice shelves were characterized by high lake coverage during 2016-2019 and
extremely low lake coverage during the 2020-2021 melting season. Over all six investigated ice shelves, the development of drainage systems was revealed highlighting an increased risk for ice shelf instability. Through statistical correlation analysis with climate data at varying time lags as well as annual data on Southern Hemisphere atmospheric modes, environmental drivers for meltwater ponding were revealed. In addition, the influence of the local glaciological setting was investigated through computation of annual recurrence times of lakes. Over both ice sheet regions, the complex interplay between local, regional and large-scale environmental drivers was found to control supraglacial lake formation despite local to regional discrepancies, as revealed through pixel-based correlation analysis. Local control factors included the ice surface topography, the ice shelf geometry, the presence of low-albedo features as well as a reduced firn air content and were found to exert strong control on lake distribution. On the other hand, regional controls on lake evolution were revealed to be the amount of incoming solar radiation, air temperature and wind occurrence. While foehn winds were found to dictate lake evolution over the API, katabatic winds influenced lake ponding in East Antarctica. Furthermore, the regional near-surface climate was shown to be driven by large-scale atmospheric modes and teleconnections with the tropics. Overall, the results highlight that similar driving factors control supraglacial lake formation on the API and EAIS pointing towards their transferability to other Antarctic regions.
Interactions between different formative processes are reflected in the internal structure of rock glaciers. Therefore, the detection of subsurface conditions can help to enhance our understanding of landform development. For an assessment of subsurface conditions, we present an analysis of the spatial variability of active layer thickness, ground ice content and frost table topography for two different rock glaciers in the Eastern Swiss Alps by means of quasi-3-D electrical resistivity imaging (ERI). This approach enables an extensive mapping of subsurface structures and a spatial overlay between site-specific surface and subsurface characteristics. At Nair rock glacier, we discovered a gradual descent of the frost table in a downslope direction and a constant decrease of ice content which follows the observed surface topography. This is attributed to ice formation by refreezing meltwater from an embedded snow bank or from a subsurface ice patch which reshapes the permafrost layer. The heterogeneous ground ice distribution at Uertsch rock glacier indicates that multiple processes on different time domains were involved in the development. Resistivity values which represent frozen conditions vary within a wide range and indicate a successive formation which includes several advances, past glacial overrides and creep processes on the rock glacier surface. In combination with the observed topography, quasi-3-D ERI enables us to delimit areas of extensive and compressive flow in close proximity. Excellent data quality was provided by a good coupling of electrodes to the ground in the pebbly material of the investigated rock glaciers. Results show the value of the quasi-3-D ERI approach but advise the application of complementary geophysical methods for interpreting the results.
Städtische Agglomerationen zeichnen sich durch eine zunehmende Dynamik ökologischer, ökonomischer und sozialer Veränderungen aus. Um eine nachhaltige Entwicklung urbaner Räume zu gewährleisten, bedarf es verstärkt innovativer Methoden zur Erfassung der raumwirksamen Veränderungen. Diesbezüglich hat sich die satellitengestützte Erdbeobachtung als kostengünstiges Instrumentarium zur Erhebung planungsrelevanter Informationen erwiesen. Dabei wird in naher Zukunft eine neue Generation von Radarsatelliten zur Verfügung stehen, deren Leistungsvermögen erstmals die operationelle Analyse von Siedlungsflächen auf Grundlage von Radardaten ermöglicht. Vor diesem Hintergrund ist es das Ziel der Dissertation, auf der Basis einer nutzerorientierten Methodik das Potential hochauflösender SAR-Daten zur automatisierten Erfassung und Analyse von Siedlungsflächen zu untersuchen. Die Methodik setzt auf dem objektorientierten Bildanalysekonzept der Software eCognition auf. Dabei haben sich der SAR-Speckle sowie Schwächen hinsichtlich der Güte der Bildsegmentierung bzw. der Bestimmung geeigneter Segmentierungseinstellungen als Limitierungen erwiesen. Folglich liegt ein erster Schwerpunkt auf der Optimierung und Stabilisierung einer segmentbasierten Auswertung von Radardaten. Hier hat sich gezeigt, dass mit Blick auf Siedlungsareale weiterhin Optimierungsbedarf hinsichtlich einer strukturerhaltenden Bildglättung besteht. Daher wird zunächst ein neuer Filteransatz entwickelt, der gegenüber den etablierten Techniken eine konsequentere Reduzierung des Speckle in homogenen Bildarealen gewährleistet und dabei gleichsam die hochfrequente Information in stark strukturierten Aufnahmebereichen bewahrt. Die Schwierigkeiten im Zusammenhang mit der Güte und Übertragbarkeit der Bildsegmentierung werden ebenso wie die Schwächen im Hinblick auf die zielgerichtete Definition der optimalen Segmentierungsparameter durch die Entwicklung eines klassenbasierten Ansatzes zur Segmentoptimierung in der Software-Umgebung von eCognition reduziert. Der zweite Schwerpunkt dieser Dissertation widmet sich der Entwicklung von Konzepten zur automatisierten Analyse der regionalen und lokalen Siedlungsstruktur. Im regionalen Kontext liegen die Identifizierung von Siedlungsflächen und die Erfassung einfacher Landnutzungsklassen im Fokus der Arbeiten. Dazu wird ein Regelwerk zur Auswertung einfach-polarisierter SAR-Aufnahmen erstellt, das sich maßgeblich auf räumlich und zeitlich robuste textur-, kontext- und hierarchiebezogene Merkmale stützt. Diese Wissensbasis wird anschließend so erweitert, dass sie die Analyse dual-polarisierter, bifrequenter oder kombinierter optischer und SAR-basierter Bilddaten ermöglicht. Wie die Ergebnisse zeigen, können Siedlungsflächen und Landnutzungsklassen bereits über einfach-polarisierte SAR-Aufnahmen mit Genauigkeiten von rund 90 Prozent erfasst werden. Durch die Einbindung einer weiteren Polarisation, Frequenz oder optischer Daten lässt sich diese Güte auf Werte von bis zu 95 Prozent steigern. Die lokalen Analysen zielen auf die thematisch und räumlich differenzierte Erfassung der Landnutzung innerhalb bebauter Areale ab. Die Untersuchung basiert auf der synergetischen Auswertung einer hochauflösenden Radaraufnahme und eines bedeutend geringer aufgelösten optischen Datensatzes. Die isolierte Analyse von SAR-Aufnahmen reichte hingegen selbst bei der Kombination verschiedener Frequenzen oder Polarisationen nicht zur Charakterisierung der kleinteiligen, heterogenen Stadtlandschaft aus. Im Kontext der synergetischen Auswertung dient die SAR-Aufnahme vornehmlich zur Extraktion der urbanen Topografie, während der optische Datensatz wichtige Merkmale zur Differenzierung der erfassten Struktureinheiten in die Kategorien Gebäude, versiegelte Freifläche, unversiegelte Freifläche und Baumbestand beisteuert. Das Resultat zeigt, dass sich trotz des synergetischen Ansatzes lediglich eine Genauigkeit von 65 Prozent erzielen lässt. Dennoch können Gebäude dabei mit einer Güte von 72 Prozent vergleichsweise akkurat erfasst werden. Im Hinblick auf die Demonstration des siedlungsbezogenen Anwendungspotentials höchstauflösender SAR-Daten lässt sich resümieren, dass eine automatische Ableitung siedlungsstruktureller Merkmale im komplexen städtischen Umfeld aufgrund der eingeschränkten spektralen Aussagekraft und der starken Geometrieabhängigkeit des Signals mit signifikanten Schwierigkeiten verbunden ist. Dennoch hat sich gezeigt, dass diese Limitierungen in gewissem Umfang über den Ansatz der multiskaligen, objektorientierten Klassifizierung kompensiert werden können. Dabei lassen sich die regionalen Siedlungs- und Landnutzungsmuster mit überzeugenden Genauigkeiten erfassen, während die Betrachtung der lokalen Siedlungsstruktur eindeutig die Grenzen der Radartechnik im Hinblick auf die Analyse komplex strukturierter Stadtlandschaften aufzeigt.
Rapid population growth in West Africa has led to expansion in croplands due to the need to grow more food to meet the rising food demand of the burgeoning population. These expansions negatively impact the sub-region's ecosystem, with implications for water and soil quality, biodiversity and climate. In order to appropriately monitor the changes in croplands and assess its impact on the ecosystem and other environmental processes, accurate and up-to-date information on agricultural land use is required. But agricultural land use mapping (i.e. mapping the spatial distribution of crops and croplands) in West Africa has been challenging due to the unavailability of adequate satellite images (as a result of excessive cloud cover), small agricultural fields and a heterogeneous landscape. This study, therefore, investigated the possibilities of improving agricultural land use mapping by utilizing optical satellite images with higher spatial and temporal resolution as well as images from Synthetic Aperture Radar (SAR) systems which are near-independent of weather conditions. The study was conducted at both watershed and regional scales.
At watershed scale, classification of different crop types in three watersheds in Ghana, Burkina Faso and Benin was conducted using multi-temporal: (1) only optical images (RapidEye) and (2) optical plus dual polarimetric (VV/VH) SAR images (TerraSAR-X). In addition, inter-annual or short term (2-3 years) changes in cropland area in the past ten years were investigated using historical Landsat images. Results obtained indicate that the use of only optical images to map different crop types in West Africa can achieve moderate classification accuracies (57% to 71%). Overlaps between the cropping calendars of most crops types and certain inter-croppings pose a challenge to optical images in achieving an adequate separation between those crop classes. Integration of SAR images, however, can improve classification accuracies by between 8 and 15%, depending on the number of available images and their acquisition dates. The sensitivity of SAR systems to different crop canopy architectures and land surface characteristics improved the separation between certain crop types. The VV polarization of TerraSAR-X was found to better discrimination between crop types than the VH. Images acquired between August and October were found to be very useful for crop mapping in the sub-region due to structural differences in some crop types during this period.
At the regional scale, inter-annual or short term changes in cropland area in the Sudanian Savanna agro-ecological zone in West Africa were assessed by upscaling historical cropland information derived at the watershed scale (using Landsat imagery) unto a coarse spatial resolution, but geographically large, satellite imagery (MODIS) using regression based modeling. The possibility of using such regional scale cropland information to improve government-derived agricultural statistics was investigated by comparing extracted cropland area from the fractional cover maps with district-level agricultural statistics from Ghana The accuracy of the fractional cover maps (MAE between 14.2% and 19.1%) indicate that the heterogeneous agricultural landscape of West Africa can be suitably represented at the regional or continental scales by estimating fractional cropland cover on low resolution Analysis of the results revealed that cropland area in the Sudanian Savanna zone has experienced inter-annual or short term fluctuations in the past ten years due to a variety of factors including climate factors (e.g. floods and droughts), declining soil fertility, population increases and agricultural policies such as fertilizer subsidies. Comparison of extracted cropland area from the fractional cover maps with government's agricultural statistics (MoFA) for seventeen districts (second administrative units) in Ghana revealed high inconsistencies in the government statistics, and highlighted the potential of satellite derived cropland information at regional scales to improve national/sub-national agricultural statistics in West Africa.
The results obtained in this study is promising for West Africa, considering the recent launch of optical (Landsat 8) and SAR sensors (Sentinel-1) that will provide free data for crop mapping in the sub-region. This will improve chances of obtaining adequate satellite images acquired during the cropping season for agricultural land use mapping and bolster opportunities of operationalizing agricultural land use mapping in West Africa. This can benefit a wide range of biophysical and economic models and improve decision making based on their results.
Irrigated agriculture in the Khorezm region in the arid inner Aral Sea Basin faces enormous challenges due to a legacy of cotton monoculture and non-sustainable water use. Regional crop growth monitoring and yield estimation continuously gain in importance, especially with regard to climate change and food security issues. Remote sensing is the ideal tool for regional-scale analysis, especially in regions where ground-truth data collection is difficult and data availability is scarce. New satellite systems promise higher spatial and temporal resolutions. So-called light use efficiency (LUE) models are based on the fraction of photosynthetic active radiation absorbed by vegetation (FPAR), a biophysical parameter that can be derived from satellite measurements. The general objective of this thesis was to use satellite data, in conjunction with an adapted LUE model, for inferring crop yield of cotton and rice at field (6.5 m) and regional (250 m) scale for multiple years (2003-2009), in order to assess crop yield variations in the study area. Intensive field measurements of FPAR were conducted in the Khorezm region during the growing season 2009. RapidEye imagery was acquired approximately bi-weekly during this time. The normalized difference vegetation index (NDVI) was calculated for all images. Linear regression between image-based NDVI and field-based FPAR was conducted. The analyses resulted in high correlations, and the resulting regression equations were used to generate time series of FPAR at the RapidEye level. RapidEye-based FPAR was subsequently aggregated to the MODIS scale and used to validate the existing MODIS FPAR product. This step was carried out to evaluate the applicability of MODIS FPAR for regional vegetation monitoring. The validation revealed that the MODIS product generally overestimates RapidEye FPAR by about 6 to 15 %. Mixture of crop types was found to be a problem at the 1 km scale, but less severe at the 250 m scale. Consequently, high resolution FPAR was used to calibrate 8-day, 250 m MODIS NDVI data, this time by linear regression of RapidEye-based FPAR against MODIS-based NDVI. The established FPAR datasets, for both RapidEye and MODIS, were subsequently assimilated into a LUE model as the driving variable. This model operated at both satellite scales, and both required an estimation of further parameters like the photosynthetic active radiation (PAR) or the actual light use efficiency (LUEact). The latter is influenced by crop stress factors like temperature or water stress, which were taken account of in the model. Water stress was especially important, and calculated via the ratio of the actual (ETact) to the potential, crop-specific evapotranspiration (ETc). Results showed that water stress typically occurred between the beginning of May and mid-September and beginning of May and end of July for cotton and rice crops, respectively. The mean water stress showed only minor differences between years. Exceptions occurred in 2008 and 2009, where the mean water stress was higher and lower, respectively. In 2008, this was likely caused by generally reduced water availability in the whole region. Model estimations were evaluated using field-based harvest information (RapidEye) and statistical information at district level (MODIS). The results showed that the model at both the RapidEye and the MODIS scale can estimate regional crop yield with acceptable accuracy. The RMSE for the RapidEye scale amounted to 29.1 % for cotton and 30.4 % for rice, respectively. At the MODIS scale, depending on the year and evaluated at Oblast level, the RMSE ranged from 10.5 % to 23.8 % for cotton and from -0.4 % to -19.4 % for rice. Altogether, the RapidEye scale model slightly underestimated cotton (bias = 0.22) and rice yield (bias = 0.11). The MODIS-scale model, on the other hand, also underestimated official rice yield (bias from 0.01 to 0.87), but overestimated official cotton yield (bias from -0.28 to -0.6). Evaluation of the MODIS scale revealed that predictions were very accurate for some districts, but less for others. The produced crop yield maps indicated that crop yield generally decreases with distance to the river. The lowest yields can be found in the southern districts, close to the desert. From a temporal point of view, there were areas characterized by low crop yields over the span of the seven years investigated. The study at hand showed that light use efficiency-based modeling, based on remote sensing data, is a viable way for regional crop yield prediction. The found accuracies were good within the boundaries of related research. From a methodological viewpoint, the work carried out made several improvements to the existing LUE models reported in the literature, e.g. the calibration of FPAR for the study region using in situ and high resolution RapidEye imagery and the incorporation of crop-specific water stress in the calculation.
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.