Mapping a Brazilian deforestation frontier using multi-temporal TerraSAR-X data and supervised machine learning

Satellite remote sensing enables a repeated survey of the earth’s surface. With machine learning it is possible to recognize complex patterns from extensive data sets. Using methods from machine learning, remote sensing images are utilized to derive large scale land use and land cover (LULC) maps, carrying discrete information on the human management of land and intact primary forests, as well as change processes. Such information is particularly relevant in little developed regions, and areas which are undergoing transformation. Therefore, satellite remote sensing is generally the preferred method for generating LULC products within tropical regions, and particularly useful to assist tracking of change processes with regard to deforestation or land management. The Amazon is the largest area of continuous tropical forest in the world, and of substantial importance with regard to biodiversity, its influence on global climate, as well as providing living space for a large number of indigenous tribes. As tropical region, the Amazon is particularly affected by cloudy conditions, which pose a serious challenge to many remote sensing efforts. Utilization of Synthetic Aperture Radar (SAR) hence is promoted, as this warrants data availability at fixed intervals. Performing land cover mapping at the deforestation frontier in the Brazilian states of Pará and Mato Grosso, the aim of this thesis is to evaluate latest concepts from machine learning and SAR remote sensing in the light of real world applicability. As a cumulative effort, this thesis provides a scalable method based on Markov Random Fields, to increase classification performance. This method is especially useful to enhance the outcome of SAR classifications, as it directly addresses inherent SAR properties such as multi-temporality and speckle. Furthermore, ALOS-2, RADARSAT-2, and TerraSAR-X, which are current SAR sensors fulfilling different properties with regard to ground resolution and wavelength, are being investigated concerning their synergetic potentials for the mapping of vegetated LULC classes of the Brazilian Amazon. Here, the additional value of combining multiple frequencies is evaluated using reliable validation techniques based on area adjustment. Additionally, single performance of the three sensors is evaluated and their potentials concerning the task of tropical mapping are estimated. Lastly, different potentials of TanDEM-X for the purpose of tropical mapping are investigated. TanDEM-X is the first continuous spaceborne missionvi to offer a bi-static acquisition of data, enabling the generation of height models and the collection of coherence layers via a single pass

Evaluation of Multi-Frequency SAR Images for Tropical Land Cover Mapping

Earth Observation (EO) data plays a major role in supporting surveying compliance of several multilateral environmental treaties, such as UN-REDD+ (United Nations Reducing Emissions from Deforestation and Degradation). In this context, land cover maps of remote sensing data are the most commonly used EO products and development of adequate classification strategies is an ongoing research topic. However, the availability of meaningful multispectral data sets can be limited due to cloud cover, particularly in the tropics. In such regions, the use of SAR systems (Synthetic Aperture Radar), which are nearly independent form weather conditions, is particularly promising. With an ever-growing number of SAR satellites, as well as the increasing accessibility of SAR data, potentials for multi-frequency remote sensing are becoming numerous. In our study, we evaluate the synergistic contribution of multitemporal L-, C-, and X-band data to tropical land cover mapping. We compare classification outcomes of ALOS-2, RADARSAT-2, and TerraSAR-X datasets for a study site in the Brazilian Amazon using a wrapper approach. After preprocessing and calculation of GLCM texture (Grey Level Co-Occurence), the wrapper utilizes Random Forest classifications to estimate scene importance. Comparing the contribution of different wavelengths, ALOS-2 data perform best in terms of overall classification accuracy, while the classification of TerraSAR-X data yields higher accuracies when compared to the results achieved by RADARSAT-2. Moreover, the wrapper underlines potentials of multi-frequency classification as integration of multi-frequency images is always preferred over multi-temporal, mono-frequent composites. We conclude that, despite distinct advantages of certain sensors, for land cover classification, multi- sensoral integration is beneficial

Evaluation of Multi-Frequency SAR Images for Tropical Land Cover Mapping

Earth Observation (EO) data plays a major role in supporting surveying compliance of several multilateral environmental treaties, such as UN-REDD+ (United Nations Reducing Emissions from Deforestation and Degradation). In this context, land cover maps of remote sensing data are the most commonly used EO products and development of adequate classification strategies is an ongoing research topic. However, the availability of meaningful multispectral data sets can be limited due to cloud cover, particularly in the tropics. In such regions, the use of SAR systems (Synthetic Aperture Radar), which are nearly independent form weather conditions, is particularly promising. With an ever-growing number of SAR satellites, as well as the increasing accessibility of SAR data, potentials for multi-frequency remote sensing are becoming numerous. In our study, we evaluate the synergistic contribution of multitemporal L-, C-, and X-band data to tropical land cover mapping. We compare classification outcomes of ALOS-2, RADARSAT-2, and TerraSAR-X datasets for a study site in the Brazilian Amazon using a wrapper approach. After preprocessing and calculation of GLCM texture (Grey Level Co-Occurence), the wrapper utilizes Random Forest classifications to estimate scene importance. Comparing the contribution of different wavelengths, ALOS-2 data perform best in terms of overall classification accuracy, while the classification of TerraSAR-X data yields higher accuracies when compared to the results achieved by RADARSAT-2. Moreover, the wrapper underlines potentials of multi-frequency classification as integration of multi-frequency images is always preferred over multi-temporal, mono-frequent composites. We conclude that, despite distinct advantages of certain sensors, for land cover classification, multi-sensoral integration is beneficial