OWL ontology evolution: understanding and unifying the complex changes

Silva, Viviane Torres da; Santos, Jéssica Soares dos; Thiago, Raphael Melo; Soares, Elton; Azevedo, Leonardo Guerreiro

doi:10.1017/s0269888922000066

Cited by 2 publications

(1 citation statement)

References 47 publications

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“…The matcher is an optional feature to map the changes and establish potential semantic links between them. In a more recent work [ 21 ], the authors provide a unified list of complex changes together with a classification for those complex changes. In [ 22 ], the method introduced focuses on RDF data (not on ontologies) to detect and express elementary and complex changes.…”

Section: Introductionmentioning

confidence: 99%

Analysis and implementation of the DynDiff tool when comparing versions of ontology

Diaz Benavides,

Cardoso,

Da Silveira

et al. 2023

J Biomed Semant

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Background Ontologies play a key role in the management of medical knowledge because they have the properties to support a wide range of knowledge-intensive tasks. The dynamic nature of knowledge requires frequent changes to the ontologies to keep them up-to-date. The challenge is to understand and manage these changes and their impact on depending systems well in order to handle the growing volume of data annotated with ontologies and the limited documentation describing the changes. Methods We present a method to detect and characterize the changes occurring between different versions of an ontology together with an ontology of changes entitled DynDiffOnto, designed according to Semantic Web best practices and FAIR principles. We further describe the implementation of the method and the evaluation of the tool with different ontologies from the biomedical domain (i.e. ICD9-CM, MeSH, NCIt, SNOMEDCT, GO, IOBC and CIDO), showing its performance in terms of time execution and capacity to classify ontological changes, compared with other state-of-the-art approaches. Results The experiments show a top-level performance of DynDiff for large ontologies and a good performance for smaller ones, with respect to execution time and capability to identify complex changes. In this paper, we further highlight the impact of ontology matchers on the diff computation and the possibility to parameterize the matcher in DynDiff, enabling the possibility of benefits from state-of-the-art matchers. Conclusion DynDiff is an efficient tool to compute differences between ontology versions and classify these differences according to DynDiffOnto concepts. This work also contributes to a better understanding of ontological changes through DynDiffOnto, which was designed to express the semantics of the changes between versions of an ontology and can be used to document the evolution of an ontology.

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Section: Introductionmentioning

confidence: 99%