gathering lexical linked data and knowledge patterns from framenet
TRANSCRIPT
(2) Dipartimento di Scienze dell’Informazione, Università di Bologna(1) Semantic Technology Laboratory ISTC-CNR
Gathering Lexical Linked Data and Knowledge Patterns from FrameNetAndrea Giovanni Nuzzolese (1,2)
[email protected] Gangemi (1)
[email protected] Presutti (1)
K-CAP 2011Banff, AL, Canada 27 June 2011
Outline
• Motivations
• Semantic issues
• Transformation method
• Ongoing work
• Conclusions
Premise
• Work after request from Berkeley FrameNet group for a Semantic Web version of FrameNet 1.5
• Previous work had various limitations, mainly data incompleteness and implicit semantics– E.g. Scheczyk et al., Narayanan et al.
• Decided to go for a dual transformation– RDF for a complete porting to Linked Open Data,
similarly to W3C WordNet RDF porting– (customizable) OWL for a focused porting to knowledge
patterns reusable for ontology design or for creating views over linked data
Motivations• The web of data is exploding and NLP techniques accompany this
explosion
• Hybridizing natural language processing and semantic web techniques shows to be a promising approach
• Part of the exploitation of LOD data, is carried out by means of lexical resources that are represented directly as linked data
• Bring lexical resource on linked data (favor hybridization)– benefit from linking all lexical resources and have an homogenous more
powerful one
• Link lexical knowledge to domain knowledge– linked data ground to lexical knowledge and textual documents
DBpedia
Yago
Lexvo
lingvoj
RDFWordNet
2.0
RDFWordNet
3.0
RDFFrameNet
1.5RDF
VerbNet 3.1
RDF Italian
MultiWordNet
WordNetDomains
WordNetSupersenses
WordNetFormal Glosses
OpenCyc
VerbOcean
Several semantic issues in reusable linguistic data
• Semantics induced by the data structure, e.g. RDB, XML, etc.
• Semantics from the linguistic model adopted
• Semantics of the corpus (e.g. sentences)
• Semantics needed for querying
• Semantics needed for reasoning
FrameNet
• A lexical knowledge base – cognitive soundness– grounded in a large corpus
• Consists of a set of frames, which have– frame elements – lexical units, which pair words (lexemes) to frames– relations to corpus elements
• Each frame can be interpreted as a class of situations
An example of frame
FrameNet as LOD
FrameNet as LOD
FrameNet as ontologies
StructuralSchema
LinguisticSchema
LinguisticData
CorpusData
ReferentialData
Linguistic transformation
architecture
Transformation approach
• We pulled out the semantics of FrameNet and its data by using Semion,
• Semion is a tool grounded on a method with two main steps– a syntactic and completely automatic transformation of the data source
to RDF datasets according to an OWL ontology that represents the data source structure
– a semantic rule-based refactoring that allows to express the RDF triples according to specific domain ontologies e.g. SKOS, DOLCE, FOAF, LMM, or anything indicated by the user.
Reengineering
Syntactic transformation to RDF triples
<frame name="Abounding_with" ... ID="262">...
<frameRelation type="Inherits from"><relatedFrame>
Locative_relation</relatedFrame>
</frameRelation>...</frame>
Refactoring
• aims to add semantics to data
• is performed by means of set of rules– i.e. SPARQL CONSTRUCT
ABox Refactoring
The ABox refactoring is the process of gathering RDF data (Abox)
Rule-based
Customizable or based on recipes
ABox Refactoring (data)
TBox Refactoring
• The TBox refactoring is the process of gathering a new ontology schema (a TBox) from data (ABox)
TBox Refactoring
Ongoing work
• Linking – WordNet, WN Domains, MultiWordNet, VerbNet,
FrameNet, VerbOcean (P. Pantel)
• Basic linking uses SKOS– exactMatch, closeMatch– links partly present in Colorado bank, partly in
WordNet mappings, part are newly created
• More reasoning requires some expressivity– semiotics.owl knowledge pattern, D&S– property chains
Conclusion
• issues related to the conversion of lexical resources – more specifically to semantic issued of FrameNet
conversion
• a method to solve those issues (supported by a tool)
• a conversion of FrameNet to RDF published as a dataset in the LOD
• a method to convert FrameNet data into knowledge patterns
Thank youAndrea Nuzzolese
-STLab, ISTC-CNR
&Dipartimento di Scienze dell’Informazione
University of BolognaItaly
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Semantic issues: objects• Semantic frames/verb classes as twofold creatures
– intensional polymorphic relations (aka descriptions) + situation types– Desiring(?experiencer, ?theme, ?time, ?loc, ?...)
• Frame elements/VN arguments as complex creatures– (semantic) roles + concepts
• Semantic types are a mixture– concepts, grammatical types, etc.
• Lexical units/VN class members as hybrid creatures– lexically-oriented semantic frames– bridges between semantic frames and word senses– FN lex units belong to diverse parts of speech
• Annotated sentences contain syntactical realizations of semantic frames (“exemplifications”)
– syntactic frames in VN, valences in FN
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Semantic issues: relations• Inheritance in FN and VN is classic, can hold for situation types safely
– needs to be treated jointly with semantic role representation– subFe also classic
• Subframes in FN are conceptual compositions (“parts of descriptions” in D&S), intensional in nature
– similarly for “excludes” and “requires” holding for FE• Frame “usage” in FN is partial inheritance, hard to digest for situation
types• Selectional restrictions in VN maybe too tough for situation types• Selectional preferences absent in resources, but probability would be
an added value• Core vs. peripheral vs. unexpressed are interesting but tough:
“characteristic”, hidden optionality, etc.
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Why a KP?
– a multidimensional context model able to capture descriptive, informational, situational, social, and formal characters of knowledge.