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With the Multimedia Metadata Ontology (M3O), we have developed a sophisticated model for representing among others the annotation, decomposition, and provenance of multimedia metadata. The goal of the M3O is to integrate the existing metadata standards and metadata formats rather than replacing them. To this end, the M3O provides a scaffold needed to represent multimedia metadata. Being an abstract model for multimedia metadata, it is not straightforward how to use and specialize the M3O for concrete application requirements and existing metadata formats and metadata standards. In this paper, we present a step-by-step alignment method describing how to integrate and leverage existing multimedia metadata standards and metadata formats in the M3O in order to use them in a concrete application. We demonstrate our approach by integrating three existing metadata models: the Core Ontology on Multimedia (COMM), which is a formalization of the multimedia metadata standard MPEG-7, the Ontology for Media Resource of the W3C, and the widely known industry standard EXIF for image metadata
Existing tools for generating application programming interfaces (APIs) for ontologies lack sophisticated support for mapping the logics-based concepts of the ontology to an appropriate object-oriented implementation of the API. Such a mapping has to overcome the fundamental differences between the semantics described in the ontology and the pragmatics, i.e., structure, functionalities, and behavior implemented in the API. Typically, concepts from the ontology are mapped one-to-one to classes in the targeted programming language. Such a mapping only produces concept representations but not an API at the desired level of granularity expected by an application developer. We present a Model-Driven Engineering (MDE) process to generate customized APIs for ontologies. This API generation is based on the semantics defined in the ontology but also leverages additional information the ontology provides. This can be the inheritance structure of the ontology concepts, the scope of relevance of an ontology concept, or design patterns defined in the ontology.
We propose a new approach for mobile visualization and interaction of temporal information by integrating support for time with today's most prevalent visualization of spatial information, the map. Our approach allows for an easy and precise selection of the time that is of interest and provides immediate feedback to the users when interacting with it. It has been developed in an evolutionary process gaining formative feedback from end users.
Entwicklung eines generischen Sesame-Sails für die Abbildung von SPARQL-Anfragen auf Webservices
(2010)
Diese Arbeit soll eine Möglichkeit aufzeigen, aufbauend auf dem Sesame Framework Datenbestände von nicht-semantischen Web-Diensten im Sinne des Semantic Web auszuwerten. Konkret wird ein Sail (Webservice-Sail) entwickelt, das einen solchen Web-Dienst wie eine RDF-Quelle abfragen kann, indem es SPARQL-Ausdrücke in Methodenaufrufe des Dienstes übersetzt und deren Ergebnisse entsprechend auswertet und zurückgibt. Um eine möglichst große Anzahl von Webservices abdecken zu können, muss die Lösung entsprechend generisch gehalten sein. Das bedeutet aber insbesondere auch, dass das Sail auf die Modalitäten konkreter Services eingestellt werden muss. Es muss also auch eine geeignete Konfigurationsrepräsentation gefunden werden, um eine möglichst gute Unterstützung eines zu verwendenden Web-Dienstes durch das Webservice-Sail zu gewährleisten. Die Entwicklung einer solchen Repräsentation ist damit auch Bestandteil dieser Arbeit.
The novel mobile application csxPOI (short for: collaborative, semantic, and context-aware points-of-interest) enables its users to collaboratively create, share, and modify semantic points of interest (POI). Semantic POIs describe geographic places with explicit semantic properties of a collaboratively created ontology. As the ontology includes multiple subclassiffcations and instantiations and as it links to DBpedia, the richness of annotation goes far beyond mere textual annotations such as tags. With the intuitive interface of csxPOI, users can easily create, delete, and modify their POIs and those shared by others. Thereby, the users adapt the structure of the ontology underlying the semantic annotations of the POIs. Data mining techniques are employed to cluster and thus improve the quality of the collaboratively created POIs. The semantic POIs and collaborative POI ontology are published as Linked Open Data.
In recent development, attempts have been made to integrate UML and OWL into one hybrid modeling language, namely TwoUse. This aims at making use of the benefits of both modeling languages and overcoming the restrictions of each. In order to create a modeling language that will actually be used in software development an integration with OCL is needed. This integration has already been described at the contextual level in, however an implementation is lacking so far. The scope of this paper is the programatical implementation of the integration of TwoUse with OCL. In order to achieve this, two different OCL implementations that already provide parsing and interpretation functionalities for expressions over regular UML. This paper presents two attempts to extend existing OCL implementations, as well as a comparison of the existing approaches.
Unlocking the semantics of multimedia presentations in the web with the multimedia metadata ontology
(2010)
The semantics of rich multimedia presentations in the web such as SMIL, SVG and Flash cannot or only to a very limited extend be understood by search engines today. This hampers the retrieval of such presentations and makes their archival and management a difficult task. Existing metadata models and metadata standards are either conceptually too narrow, focus on a specific media type only, cannot be used and combined together, or are not practically applicable for the semantic description of rich multimedia presentations. In this paper, we propose the Multimedia Metadata Ontology (M3O) for annotating rich, structured multimedia presentations. The M3O provides a generic modeling framework for representing sophisticated multimedia metadata. It allows for integrating the features provided by the existing metadata models and metadata standards. Our approach bases on Semantic Web technologies and can be easily integrated with multimedia formats such as the W3C standards SMIL and SVG. With the M3O, we unlock the semantics of rich multimedia presentations in the web by making the semantics machine-readable and machine-understandable. The M3O is used with our SemanticMM4U framework for the multi-channel generation of semantically-rich multimedia presentations.
Der Idee des Semantic Desktop liegen die gleichen Konzepte zugrunde wie dem Semantic Web mit dem Unterschied, dass sie nun auf die Applikationen und Daten eines durchschnittlichen Desktops angewendet werden. Insbesondere geht es darum, die unterschiedlichen Sichten auf Daten, die durch unterschiedliche Anwendungen erzeugt werden, über eine kontextübergreifende Beschreibung zu integrieren. Z.B. können sich zwei Programme darin unterscheiden, dass eine E-Mail-Adresse in dem einen als aktiver Link dargestellt wird, über den sich direkt eine E-Mail versenden lässt, in dem anderen aber lediglich als Zeichenkette. In der angestrebten idealen Welt des Semantic Desktop würde diese Adresse unabhängig von ihrem Anzeigekontext auch als solche erkannt und behandelt. Ziel der Arbeit ist die Entwicklung einer Integrationsmöglichkeit, die es Applikationen erlaubt, Informationen über ihre Inhalte auszutauschen. Hierzu werden zunächst die Anforderungen an die zu erarbeitende Kommunikationskomponente aufgeführt und daraus das technische Umfeld abgeleitet. Dabei wird vor allem auf die einzusetzenden Technologien eingegangen, und die angewendeten Konzepte werden erläutert. Die Entwicklung und Beschreibung einer Testanwendung schließen den technischen Teil ab. Zuletzt wird die gesamte Entwicklung kritisch diskutiert und ein Ausblick auf mögliche fortführende Entwicklungen geboten.