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5. Geo Engine: Workflow-backed Geo Data Portals

Author

Beilschmidt, Christian, Drönner, Johannes, Mattig, Michael, Schweitzer, Philip, and Seeger, Bernhard

Subjects
Geo processing||Data portals
Abstract

Geo data portals play a key role in the distribution and exploitation of domain-specific geo data.While such portals are highly specialized, they share a number of common requirements that span from data access and processing to UI components.Geo Engine is able to provide all the necessary parts for portal building.We demonstrate this on a real data portal we built for the Dragonfly community.In addition, we show its general architecture and outline future improvements.

Published
2023
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8. Satellite-based high-resolution mapping of rainfall over southern Africa

Author

Meyer, Hanna, Drönner, Johannes, and Nauss, Thomas

Subjects
lcsh:TA715-787, lcsh:Earthwork. Foundations, lcsh:TA170-171, lcsh:Environmental engineering
Abstract

A spatially explicit mapping of rainfall is necessary for southern Africa for eco-climatological studies or nowcasting but accurate estimates are still a challenging task. This study presents a method to estimate hourly rainfall based on data from the Meteosat Second Generation (MSG) Spinning Enhanced Visible and Infrared Imager (SEVIRI). Rainfall measurements from about 350 weather stations from 2010–2014 served as ground truth for calibration and validation. SEVIRI and weather station data were used to train neural networks that allowed the estimation of rainfall area and rainfall quantities over all times of the day. The results revealed that 60 % of recorded rainfall events were correctly classified by the model (probability of detection, POD). However, the false alarm ratio (FAR) was high (0.80), leading to a Heidke skill score (HSS) of 0.18. Estimated hourly rainfall quantities were estimated with an average hourly correlation of ρ = 0. 33 and a root mean square error (RMSE) of 0.72. The correlation increased with temporal aggregation to 0.52 (daily), 0.67 (weekly) and 0.71 (monthly). The main weakness was the overestimation of rainfall events. The model results were compared to the Integrated Multi-satellitE Retrievals for GPM (IMERG) of the Global Precipitation Measurement (GPM) mission. Despite being a comparably simple approach, the presented MSG-based rainfall retrieval outperformed GPM IMERG in terms of rainfall area detection: GPM IMERG had a considerably lower POD. The HSS was not significantly different compared to the MSG-based retrieval due to a lower FAR of GPM IMERG. There were no further significant differences between the MSG-based retrieval and GPM IMERG in terms of correlation with the observed rainfall quantities. The MSG-based retrieval, however, provides rainfall in a higher spatial resolution. Though estimating rainfall from satellite data remains challenging, especially at high temporal resolutions, this study showed promising results towards improved spatio-temporal estimates of rainfall over southern Africa.

Published
2017

9. Raster Time Series: Learning and Processing

Author

Drönner, Johannes and Seeger, Bernhard (Prof. Dr.)

Subjects
Rasterdata, Spatio-Temporal Data, Meteosat Second Generation, Convolutional Neural Networks, Rasterdaten, Informatik, Tiefe neuronale Netze, Raum-zeitliche Daten, Data processing, Computer science, ddc:004
Abstract

Da die Menge der Fernerkundungsdaten stark zunimmt, sind effiziente Verarbeitungsmöglichkeiten von größter Bedeutung. Fernerkundungsdaten von Satelliten sind in vielen wissenschaftlichen Bereichen, wie Biodiversität und Klimaforschung, von entscheidender Bedeutung. Wetter und Klima für fast alle lebenden Organismen auf der Erde von besonderem Interesse. Daher ist die effiziente Klassifizierung von Wolken eines der wichtigsten Probleme. Geostationäre Satelliten, wie Meteosat Second Generation (MSG), bieten die einzige Möglichkeit, langfristige Wolkendatensätze mit hoher räumlicher und zeitlicher Auflösung zu erzeugen. Diese Arbeit befasst sich daher mit der effizienten und parallelen Verarbeitung von MSG-Daten, um neue Anwendungen und Erkenntnisse zu ermöglichen. Zuerst wird das Fehlen einer geeigneten Verarbeitungskette zur Erzeugung einer langfristigen Nebel- und niedrgem Stratus- (FLS) Zeitreihe aufgegriffen. Wir präsentieren eine effiziente MSG-Datenverarbeitungskette, die mehrere Aufgaben gleichzeitig, sowie Rasterdaten parallel, mit der Open Computing Language, verarbeitet. Die Verarbeitungskette ermöglicht eine einheitliche Klassifizierung von FLS, die Tag- und Nachtansätze kombiniert. Infolgedessen ist es möglich, die FLS-Raster für ein Jahr in kurzer Zeit zu berechnen. Das zweite Thema präsentiert die Anwendung von Convolutional Neural Networks (CNN) zur Wolkenklassifikation. Gängige Ansätze zur Wolkenerkennung klassifizieren oft nur einzelne Pixel und ignorieren die Tatsache, dass Wolken hochdynamische und räumlich kontinuierliche Einheiten sind. Daher schlagen wir eine neue Methode vor, die auf Deep Learning basiert. Basierend auf einer CNN-Architektur zur Bildsegmentierung klassifiziert das vorgestellte Cloud Segmentation CNN (CS-CNN) alle Pixel einer Szene gleichzeitig. Wir zeigen, dass CS-CNN multispektrale Satellitendaten verarbeiten kann, um kontinuierliche Phänomene, wie Wolken zu identifizieren. Unser Ansatz liefert ausgezeichnete Ergebnisse auf MSG-Satellitendaten in Bezug auf Qualität, Robustheit und Laufzeit im Vergleich zu Random Forest, einer oft verwendeten maschinellen Lernmethode. Schließlich stellen wir die Verarbeitung von Rasterzeitreihen mit einem System zur Visualisierung, Transformation und Analyse (VAT) von raumzeitlichen Daten vor. Es ermöglicht daten-getriebene Forschung mit explorativen Workflows und verwendet Zeit als integralen Bestandteil. Die Kombination aus heterogenen Raster- und Vektordaten-Zeitreihen ermöglicht neue Anwendungen und Erkenntnisse. Wir stellen einen Anwendungsfall vor, der Wetterinformationen und Flugzeugtrajektorien kombiniert, um Muster in Schlechtwettersituationen zu identifizieren., As the amount of remote sensing data is increasing at a high rate, due to great improvements in sensor technology, efficient processing capabilities are of utmost importance. Remote sensing data from satellites is crucial in many scientific domains, like biodiversity and climate research. Because weather and climate are of particular interest for almost all living organisms on earth, the efficient classification of clouds is one of the most important problems. Geostationary satellites such as Meteosat Second Generation (MSG) offer the only possibility to generate long-term cloud data sets with high spatial and temporal resolution. This work, therefore, addresses research problems on efficient and parallel processing of MSG data to enable new applications and insights. First, we address the lack of a suitable processing chain to generate a long-term Fog and Low Stratus (FLS) time series. We present an efficient MSG data processing chain that processes multiple tasks simultaneously, and raster data in parallel using the Open Computing Language (OpenCL). The processing chain delivers a uniform FLS classification that combines day and night approaches in a single method. As a result, it is possible to calculate a year of FLS rasters quite easy. The second topic presents the application of Convolutional Neural Networks (CNN) for cloud classification. Conventional approaches to cloud detection often only classify single pixels and ignore the fact that clouds are highly dynamic and spatially continuous entities. Therefore, we propose a new method based on deep learning. Using a CNN image segmentation architecture, the presented Cloud Segmentation CNN (CS-CNN) classifies all pixels of a scene simultaneously. We show that CS-CNN is capable of processing multispectral satellite data to identify continuous phenomena such as highly dynamic clouds. The proposed approach provides excellent results on MSG satellite data in terms of quality, robustness, and runtime, in comparison to Random Forest (RF), another widely used machine learning method. Finally, we present the processing of raster time series with a system for Visualization, Transformation, and Analysis (VAT) of spatio-temporal data. It enables data-driven research with explorative workflows and uses time as an integral dimension. The combination of various raster and vector data time series enables new applications and insights. We present an application that combines weather information and aircraft trajectories to identify patterns in bad weather situations.

Published
2019

10. Towards an EBV Analyzer based on VAT

Author

Beilschmidt, Christian, Drönner, Johannes, Fernández, Néstor, Langer, Christian, Mattig, Michael, and Seeger, Bernhard

Subjects
Interactive Data Exploration, GIS, Spatio-temporal processing, Essential Biodiversity Variables
Abstract

The Essential Biodiversity Variables (EBVs) proposed by GEO BON offer great benefits for decision makers and scientists if they are made readily available. Currently, the usage of EBVs is, however, still a challenge. The required data sets are very large, heterogeneous and temporal. This makes the usage in common tools like GIS very cumbersome. We propose the VAT system, a web-based processing engine for spatio-temporal data, as an ideal tool for EBV visualization and analysis. VAT is being developed as part of GFBio, but was designed to work independently from the start. Here, users can access a rich set of environmental layers and combine them with their own, private data. So-called exploratory workflows allow users to process data in an interactive fashion while guaranteeing reproducibility of the result. In cooperation with GEO BON we are working towards using VAT as the future EBV Browser & Analyzer. In our first use case we considered the global forest change EBV that measures the yearly global loss and gain of tree cover. In particular we wanted to investigate the change over time for a given region of interest. This information is highly relevant for decision makers as well as scientists. In our application users can choose between forest loss and forest gain and then specify their region of interest. This is either done by selecting a country from a list, or by drawing a custom polygon on the map. The relevant part of the EBV data set is added to the map as a new layer. In addition, a plot visualizes the aggregated changes over time. On the technical side this requires intersecting the raster data from the EBV with the user-defined polygon. The size of the raster makes it necessary to work with overviews in order to achieve a low-latency computation. For plotting the temporal development, we make use of our interface to R which allows us exploiting its powerful plotting functionality. In our ongoing work we will implement a public EBV catalogue that allows users to search and submit EBVs. Quality indicators will assist users to decide on the suitability of the data for their given use case. The data from the EBV catalogue will be available in the VAT system for scientists. In addition, VAT also offers simplified report views that hide the complexity of the actual computations and are thus suitable for decision makers and even the general public.

Published
2018
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11. Pretty Fly for a VAT GUI

Author

Beilschmidt, Christian, primary, Drönner, Johannes, additional, Glombiewski, Nikolaus, additional, Heigele, Christian, additional, Holznigenkemper, Jana, additional, Isenberg, Anna, additional, Körber, Michael, additional, Mattig, Michael, additional, Morgen, Andreas, additional, and Seeger, Bernhard, additional

Published
2019
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