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Hadoop is a Java-based open source programming framework, which supports the processing and storage of large volumes of data sets in a distributed computing environment. On the other hand, an overwhelming majority of organizations are moving their big data processing and storing to the cloud to take advantage of cost reduction – the cloud eliminates the need for investing heavily in infrastructures, which may or may not be used by organizations. This paper shows how organizations can alleviate some of the obstacles faced when trying to make Hadoop run in the cloud.
Big-Data-Datenplattformen werden immer beliebter, um große Datenmengen bei Bedarf analysieren zu können. Zu den fünf gängigsten Big-Data-Verarbeitungsframeworks gehören Apache Hadoop, Apache Storm, Apache Samza, Apache Spark, und Apache Flink. Zwar unterstützen alle fünf Plattformen die Verarbeitung großer Datenmengen, doch unterscheiden sich diese Frameworks in ihren Anwendungsbereichen und der zugrunde liegenden Architektur. Eine Reihe von Studien hat sich bereits mit dem Vergleich dieser Big-Data-Frameworks befasst, indem sie sie anhand eines bestimmten Leistungsindikators bewertet haben. Die IT-Sicherheit dieser Frameworks wurde dabei jedoch nicht betrachtet. In diesem Beitrag werden zunächst allgemeine Anforderungen und Anforderungen an die IT-Sicherheit der Datenplattformen definiert. Anschließend werden die Datenplattform-Konzepte unter Berücksichtigung der aufgestellten Anforderungen analysiert und gegenübergestellt.
In the context of modern mobility, topics such as smart-cities, Car2Car-Communication, extensive vehicle sensor-data, e-mobility and charging point management systems have to be considered. These topics of modern mobility often have in common that they are characterized by complex and extensive data situations. Vehicle position data, sensor data or vehicle communication data must be preprocessed, aggregated and analyzed. In many cases, the data is interdependent. For example, the vehicle position data of electric vehicles and surrounding charging points have a dependence on one another and characterize a competition situation between the vehicles. In the case of Car2Car-Communication, the positions of the vehicles must also be viewed in relation to each other. The data are dependent on each other and will influence the ability to establish a communication. This dependency can provoke very complex and large data situations, which can no longer be treated efficiently. With this work, a model is presented in order to be able to map such typical data situations with a strong dependency of the data among each other. Microservices can help reduce complexity.