Social Semantic Web

The concept of the Social Semantic Web subsumes developments in which social interactions on the Web lead to the creation of explicit and semantically rich knowledge representations. The Social Semantic Web can be seen as a Web of collective knowledge systems, which are able to provide useful information based on human contributions and which get better as more people participate.[1] The Social Semantic Web combines technologies, strategies and methodologies from the Semantic Web, social software and the Web 2.0.[2]

Overview

The social-semantic web (s2w) aims to complement the formal Semantic Web vision by adding a pragmatic approach relying on description languages for semantic browsing using heuristic classification and semiotic ontologies. A socio-semantic system has a continuous process of eliciting crucial knowledge of a domain through semi-formal ontologies, taxonomies or folksonomies. S2w emphasize the importance of humanly created loose semantics as means to fulfil the vision of the semantic web. Instead of relying entirely on automated semantics with formal ontology processing and inferencing, humans are collaboratively building semantics aided by socio-semantic information systems. While the semantic web enables integration of business processing with precise automatic logic inference computing across domains, the socio-semantic web opens up for a more social interface to the semantics of businesses, allowing interoperability between business objects, actions and their users.

Socio-semantic web was coined by Manuel Zacklad and Jean-Pierre Cahier in 2003 and used in the field of Computer Supported Cooperative Work (CSCW). It was then discussed in Peter Morville's 2005 book Ambient Findability.[3] In Chapter 6, he defines the socio-semantic web as relying on "the pace-layering of ontologies, taxonomies, and folksonomies to learn and adapt as well as teach and remember." Morville writes, “I’ll take the ancient tree of knowledge over the transient leaves of popularity any day”.[4] There is undoubtedly scepticism towards the adoption of folksonomies. The socio-semantic web may be seen as a middle way between the top-down monolithic taxonomy approach like the Yahoo! Directory and collaborative tagging (folksonomy) approaches.

The socio-semantic web differs from the semantic web in that the semantic web often is regarded as a system that will solve the epistemic interoperability issues we have to day. While the semantic web will provide ways for businesses to interoperate across domains the socio-semantic web will enable users to share knowledge.

There are various possible social approaches for solving the problems of user driven ontology evolution for the semantic web. First, users could create a folksonomy (flat taxonomy). With Social Network Analysis (SNA) in conjunction with automated parsers, the ontology could be extracted from the tags and this ontology could be entered into a Topic Map/TMCL[5] or RDF/OWL ontology store. Secondly a set of ontology engineers or ontologists could manually analyze the tags created by the users and by using this data, create a more sound ontology. The third approach is to create a system for self governance where the users themselves create the ontology over time in an organic fashion. All of these approaches could start out with an empty ontology or be seeded manually or with an existing ontology, for example the WordNet ontology.[6] Social Networks Ontology is the most important concept in social web.

Examples

References

  1. Tom Gruber (2006). "Where the Social Web Meets the Semantic Web". Keynote presentation at ISWC, The 5th International Semantic Web Conference, November 7, 2006
  2. Katrin Weller (2010), Knowledge Representation in the Social Semantic Web. Berlin: De Gruyter Saur.
  3. Peter Morville (26 September 2005). Ambient Findability. O'Reilly Media. ISBN 978-0-596-00765-2.
  4. (Morville 2005, p. 139)
  5. "The Topic Map Constraint Language".
  6. "Wordnet in RDFS and OWL".
  7. Almeida JS, Deus HF, Maass W (2010). "S3DB core: a framework for RDF generation and management in bioinformatics infrastructures". BMC Bioinformatics. 11: 387. doi:10.1186/1471-2105-11-387. PMC 2918582Freely accessible. PMID 20646315.

External links

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