IMPRECISE EMPIRICAL ONTOLOGY REFINEMENT - Application to Taxonomy Acquisition
Vít Novácěk
2007
Abstract
The significance of uncertainty representation has become obvious in the Semantic Web community recently. This paper presents new results of our research on uncertainty incorporation into ontologies created automatically by means of Human Language Technologies. The research is related to OLE (Ontology LEarning) – a project aimed at bottom-up generation and merging of ontologies. It utilises a proposal of expressive fuzzy knowledge representation framework called ANUIC (Adaptive Net of Universally Interrelated Concepts). We discuss our recent achievements in taxonomy acquisition and show how even simple application of the principles of ANUIC can improve the results of initial knowledge extraction methods.
References
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- 1: process the resources by the pattern-based method and produce a set of ontologies Sp
- 2: merge the ontologies in Sp into one ontology R
- 3: process the resources by the clustering-based method (Alg. 1 and Alg. 2) using R as a reference ontology in Alg. 2 and produce set of ontologies
- Require: r - number of optimisation repeats, value 5 was found to be sufficient
- Require: pickBal(di,V ) - abstract (due to simplicity of the description) function, which pops a subset S from set V ; S is characterised by these conditions: (1) all v ? S all the closest possible vectors to di, and (2) all the sets picked from V are balanced in size after a sequence of pickBal() applications that makes V empty
- 1: Minit ? random v ? V {* initial means *}
- 2: Vtmp ? V
- 3: repeat
- 4: c ? centroid(Minit )
- 5: v ? u such that dist(u, c) is maximal for u ? Vtmp
- 6: Minit ? Minit ? {v}
- 7: Vtmp ? Vtmp - {v}
- 8: until |Minit | < k
- 9: FACT ? {} {* empty map *}
- 10: Vtmp ? V
- 11: j ? 0
- 12: for di ? Minit do
- 13: Sbalanced ? pickBal(di,Vtmp)
- 14: j ? j + 1
- 15: FACT [ j] ? Sbalanced
- 16: end for
- 17: C ? 0/
- 18: for j ? FACT.keys() do
- 19: C ? C ? centroid(FACT [ j])
- 20: end for
- 21: V ECT 2SCORE ? {} {* empty map *}
- 22: for v ? V do
- 23: V ECT 2SCORE[v] ? {(c0, 0), . . . , (ck-1, k - 1)} such that {c0, . . . , ck-1} is a sequence of centroids from C ordered by the increasing distance from v
- 24: end for
- 25: CLUST ? 0/ {* clustering structure *}
- 26: S ? {} {* empty map *}
- 27: for j ? {1, . . . , r} do
- 28: Stmp ? random shuffle of V
- 29: initialize clustering c j with clusters given by pivotal centroids from C
- 30: sequentially process Stmp and assign each vector to the nearest available cluster from c j, keeping the clusters as balanced in size as possible
- 31: compute the score S[ j] for the obtained clustering by summing up the numbers pointed by respective centroids in V ECT 2SCORE for each vector in each cluster in c j
- 32: CLUST ? CLUST ? c j
- 33: end for
- 34: return cx ? CLUST with lowest score S[ j], s ? {1, . . . , r} associated
Paper Citation
in Harvard Style
Novácěk V. (2007). IMPRECISE EMPIRICAL ONTOLOGY REFINEMENT - Application to Taxonomy Acquisition . In Proceedings of the Ninth International Conference on Enterprise Information Systems - Volume 2: ICEIS, ISBN 978-972-8865-89-4, pages 31-38. DOI: 10.5220/0002391800310038
in Bibtex Style
@conference{iceis07,
author={Vít Novácěk},
title={IMPRECISE EMPIRICAL ONTOLOGY REFINEMENT - Application to Taxonomy Acquisition},
booktitle={Proceedings of the Ninth International Conference on Enterprise Information Systems - Volume 2: ICEIS,},
year={2007},
pages={31-38},
publisher={SciTePress},
organization={INSTICC},
doi={10.5220/0002391800310038},
isbn={978-972-8865-89-4},
}
in EndNote Style
TY - CONF
JO - Proceedings of the Ninth International Conference on Enterprise Information Systems - Volume 2: ICEIS,
TI - IMPRECISE EMPIRICAL ONTOLOGY REFINEMENT - Application to Taxonomy Acquisition
SN - 978-972-8865-89-4
AU - Novácěk V.
PY - 2007
SP - 31
EP - 38
DO - 10.5220/0002391800310038