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Jun 21, 2004 - are discovered and ranked ... Discovery & ranking of semantic associations .... M. Rectenwald, K. Lee, Y. Seo, J.A. Giampapa, and K. Sycara.
An Ontological Approach to Assessing IC Need to Know Phillip Burns Prof. Amit Sheth

CTA Inc. LSDIS Lab, University of Georgia

Presented to ARDA PI Meeting, Myrtle Beach, February 16 2005

Contract # NBCHC030083

A thought to begin with … „ You cannot separate two facets of information retrieval (“systematic serendipity)— information recovery and information discovery. ƒ Eugene Garfield … in essays of an Information Scientist

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Objective & Approach „ Determine if (classified) documents reviewed by an IC analyst satisfy his/her “need to know” ‰Characterization of “need to know” w.r.t. ontology ‰Characterizing document content in terms of ontology ‰Discovering weighted semantic relationships between document content and “need to know” characterization

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Characterizing “Need to Know” using a Semantic Approach (using Ontology) „ Requires domain ontology ‰models important concepts & relationships of domain (schema), captures factual knowledge (instances)

„ Relate analyst’s need to know to concepts & relationships in ontology ‰e.g. terrorist organization, funding sources, facilitators, members, methods

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Characterizing document content in terms of ontology: “Semantic Annotation” „ Correlate words/phrases from document with concepts/relationships in ontology „ Meta-data added to document (from associated ontological knowledge) „ Active area of research but practically useful technology now available (e.g., Semagix Freedom)

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Semantic Relationships between Document & “Need to Know” „ Semantic associations: relationships between document concepts & “need to know” concepts are discovered and ranked „ Ranking based on multiple factors ‰no. of links, types of links, location in ontology, …

„ Ranking indicates degree of semantic “closeness” ‰and therefore, how related document is to “need to know”

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Research Content „ Discovery & ranking of semantic associations „ Characterizing “need to know” in terms of ontological concepts & relationships (context of investigation) While applying emerging technologies for „ Ontology design and population „ Meta-data annotation of heterogeneous documents ‰ correlation of document content with concepts in ontology

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Relevance Ranking of Documents Four groups of document-ranking: - Not Related Documents -

unable to determine relation to context

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Ambiguously Related Documents

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Closely Related Documents

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Highly Related Documents

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some relationship exists to the context Entities are closely related to the context Entities are a direct match to the context

Cut-off values determine grouping of documents w.r.t. relevance -

These are customizable cut-off values (more control and more meaningful parameters compared to say automatic classification or statistical approaches)

“Inspection” of a document is possible via (a) original document or (b) original document with highlighted entities

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Relevance Function (w.r.t. Context) “Closely related entities are more relevant than distant entities” E = {e | e ∈ Document } Ek = {f | distance(f, e∈E) = k }

⎛ classes_Re levance ( E k ) ⎞ ⎟ ⎜ + ⎟ ⎜ k =n Document Relevance = ∑ ⎜ relations_ Relevance ( E k ) ⎟ ⎟ ⎜ k =0 ⎟ ⎜ + ⎟ ⎜ ⎝ entities_R elevance ( E k ) ⎠

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IA Context of Investigation (characterization of “Need to Know”) We define the context of investigation as a combination of the following: „ A set of entity classes and relationships, and/or a negation of a set of entity classes and relationships „ A set of entity instance names, and/or a negation of a set of entity instance names „ A set of keyword values that might appear at any attribute of the populated instance data, and/or a negation of a set of keyword values

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Context of Investigation (cont) „ Goal is to capture, at a high level, the types of entities, (or relationships), that are considered important. „ Relationships can be constrained to be associated with specified class types ‰ E.G. It can be specified that a relation ‘affiliated with’ is part of the context only when it is connected with an entity that belongs to a specific class, say, ‘Terror Organization’

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graph-based creation of a context of investigation 26,489 entities 34,513 (explicit) relationships Add relationship to context

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Additional Semantic Constraints

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Components of Document Relevance 2.

lis te in d

n ize cit of

Context of Investigation

Relationships constrains Relationship Æ [Class]

n ize cit of

Entities belong to classes in the Context

(specific entities) Abu Abdallah Turkmenistan Konduz Province …

n ize cit of

lis te in d

• • • •

lives in

type(entity) ∈ Context

lis te in d

lives in

1.

3. lives in

Entities match a list of entities of interest (in the Context) entity ∈ Entities-List

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Some thoughts along the way „ “An object by itself is intensely uninteresting.” Grady Booch, Object Oriented Design with Applications, 1991

„ I might as well join my better known colleagues:

“Relationship is at the heart of semantics. Ontology is at the hear of the Semantic Web.”

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Schematic of Ontological Approach to the Legitimate Access Problem Semagix Freedom

Semagix Freedom

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Show me the stuff …

here you go … demonstration

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Security and Terrorism Part of SWETO Ontology

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Semantic Annotation „ Document searched for entity names (or synonyms) contained in ontology „ Then document entities are annotated with additional information from corresponding entities in ontology including named relationships to other entities „ Following chart is example ‰ Highlighted text are entities found corresponding to concepts in ontology ‰ XML is corresponding meta-data annotation

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Relevance Measures for Documents (relating document content to IA “need to know”

„ Relevance engine input ‰ the set of semantically annotated documents ‰the context of investigation for the assignment ‰the ontology schema represented in RDFS, and the ontology instances represented in RDF

„ Relevance measure function used to verify whether the entity annotations in the annotated document can be fit into the entity classes, entity instances, and/or keywords specified in the context of investigation. 6/21/2004

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Relevance Measures for Documents (relating document content to IA “need to know” (cont) „ Documents classified as: ‰ Highly relevant „ Document entities directly related

‰ Closely related „ Document entities related through strong semantic associations

‰ Ambiguous „ Document entities related through weak semantic associations

‰ Not relevant „ Document entities not related to “need to know”

‰ Undeterminable „ Document entities not found in ontology 6/21/2004

Challenges we have addressed - Discovery of Semantic Associations per entity per document - Input/Visualization/Management of Context of Investigation - Scalability on number of documents & ontology size - Performs well (in terms of time and scalability) with thousands of documents and for scenarios when a IA investigation has involved hundreds of documents - No systematic measure of quality for this specific application/scenario (general evaluation of research is done) 6/21/2004

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Challenges to be addressed - Scalability to a million+ documents (possibly with preprocessing/filtering) - Further development/enrichment of the ontology - Improved measure of the strength of Semantic Associations - Evaluations by human subjects - Visualization and interactive discovery

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References „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „

1. B. Aleman-Meza, C. Halaschek, I.B. Arpinar, A. Sheth, Context-Aware Semantic Association Ranking. Proceedings of Semantic Web and Databases Workshop, Berlin, September 78 2003, pp. 33-50 2. B. Aleman-Meza, C. Halaschek, A. Sheth, I.B. Arpinar, and G. Sannapareddy. SWETO: Large-Scale Semantic Web Test-bed. Proceedings of the 16th International Conference on Software Engineering and Knowledge Engineering (SEKE2004): Workshop on Ontology in Action, Banff, Canada, June 21-24, 2004, pp. 490-493 3. R. Anderson and R. Brackney. Understanding the Insider Threat. Proceedings of a March 2004 Workshop. Prepared for the Advanced Research and Development Activity (ARDA). http://www.rand.org/publications/CF/CF196/ 4. K. Anyanwu and A. Sheth ρ-Queries: Enabling Querying for Semantic Associations on the Semantic Web The Twelfth International World Wide Web Conference, Budapest, Hungary, 2003, pp. 690-699 5. K. Anyanwu, A. Maduko, A. Sheth, SemRank: Ranking Complex Relationship Search Results on the Semantic Web, In Proceedings of the 14th International World Wide Web Conference, Japan 2005 (accepted, to appear) 6. K. Anyanwu, A. Maduko, A. Sheth, J. Miller. Top-k Path Query Evaluation in Semantic Web Databases. (submitted for publication), 2005 7. C. Halaschek, B. Aleman-Meza, I.B. Arpinar, A. Sheth Discovering and Ranking Semantic Associations over a Large RDF Metabase Demonstration Paper, VLDB 2004, 30th International Conference on Very Large Data Bases, Toronto, Canada, 30 August - 3 September, 2004 8. B. Hammond, A. Sheth, and K. Kochut, Semantic Enhancement Engine: A Modular Document Enhancement Platform for Semantic Applications over Heterogeneous Content, in Real World Semantic Web Applications, V. Kashyap and L. Shklar, Eds., IOS Press, December 2002, pp. 29-49

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References (cont) „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „ „

9. M. Rectenwald, K. Lee, Y. Seo, J.A. Giampapa, and K. Sycara. Proof of Concept System for Automatically Determining Need-to-Know Access Privileges: Installation Notes and User Guide. Technical Report CMU-RI-TR-04-56, Robotics Institute, Carnegie Mellon University, October, 2004. http://www.ri.cmu.edu/pub_files/pub4/rectenwald_michael_2004_3/rectenwald_michael_20 04_3.pdf 10. C. Rocha, D. Schwabe, M.P. Aragao. A Hybrid Approach for Searching in the Semantic Web, In Proceedings of the 13th International World Wide Web, Conference, New York, May 2004, pp. 374-383. 11. M.A. Rodriguez, M.J. Egenhofer, Determining Semantic Similarity Among Entity Classes from Different Ontologies, IEEE Transactions on Knowledge and Data Engineering 2003 15(2):442-456 12. A. Sheth, C. Bertram, D. Avant, B. Hammond, K. Kochut, and Y. Warke. Managing Semantic Content for the Web. IEEE Internet Computing, 2002. 6(4):80-87 13. A. Sheth, B. Aleman-Meza, I.B. Arpinar, C. Halaschek, C. Ramakrishnan, C. Bertram, Y. Warke, D. Avant, F.S. Arpinar, K. Anyanwu, and K. Kochut. Semantic Association Identification and Knowledge Discovery for National Security Applications. Journal of Database Management, Jan-Mar 2005, 16 (1):33-53 14. Boanerges Aleman-Meza, Phillip Burns, Matthew Eavenson,Devanand Palaniswami, Amit Sheth. An Ontological Approach to the Document Access Problem of Insider Threat

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Conclusions „ New Semantic Approach to a class of challenging problems: vendor vetting, knowledge discovery, …. „ Viability demonstrated on a small scale (comprehensive demonstration) „ Significant new research that builds upon the latest Semantic Platform

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A parting thought „ “Discovery commences with an awareness of anomaly …” ƒ Thomas S. Kuhn, in The Structure of Scientific Revolutions

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