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Classifying Scientific Data Objects with Bibliographic Relationship Taxonomies

This study focuses on the classification of scientific data objects using bibliographic relationship taxonomies. The researchers aim to build an open access repository that accurately reflects disciplinary knowledge structures and supports data preservation, sharing, and reuse.

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Classifying Scientific Data Objects with Bibliographic Relationship Taxonomies

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  1. “Classifying Scientific Data Objects with Bibliographic Relationship Taxonomies” ~~~~~~ ASIS&T 2007 Annual Meeting Sunday, October 21, 2007 Jane Greenberg, Frances McColl Professor; Director, SILS/Metadata Research Center School of Information and Library Science Univ. of North Carolina at Chapel Hill janeg@ils.unc.edu

  2. Overview • DRIADE – (Digital Repository of Information and Data for Evolution) • Accomplishments: basic metadata challenges • Functional requirements, underlying metadata • Instantiation • Motivation • Research design • Preliminary results • Conclusions http://www.caffedriade.com/ -adaptation -natural selection

  3. Small science, open access • Small science repositories (SSR) • Knowledge Network for Biocomplexity (KNB), Marine Metadata Initiative (MMI) • Evolutionary biology • Publication process • Supplementary data (Molecular Biology and Evolution, American Naturalists) “Author,” “deposition date,” not“subject” “species,” ”geo. locator” • Data deposition (Genbank, TreeBase, Morphbank) • NESCent and SILS/Metadata Research Center ecology, paleontology, population genetics, physiology, systematics + genomics

  4. One-stop deposition and shopping for data objects Support the acquisition, preservation, resource discovery, and reuse of heterogeneous digital datasets Balance a need for low barriers, with higher-level … data synthesis DRIADE Team NESCent PI: Todd Vision, Director of Informatics and Associate Professor, Biology, UNC Hilmar Lapp, Assistant Director of Informatics Ryan Scherle, Data Repository Architect UNC/SILS/MRC PI: Jane Greenberg, Associate Professor, SILS and MRC Sarah Carrier, Research Assistant Abbey Thompson, DRIADE R.A./SILS Masters Student Hollie White, Doctoral Fellow Amy Bouck, Biology, Ph.d.student DRIADE’s Goals

  5. DRIADE(Dryad) Depositor/s One stop deposition • Specialized • Repositories • Genbank • TreeBase • Morphbank • PaleoDB DRIADE -Data objects supporting published research Journals & journal repositories One stop shopping—an option Researcher/s

  6. Accomplishments: basic metadata challenges

  7. Accomplishments: addressing basic metadata challenges • Functional requirements • Consensus building (Dec. 06) + SSR workshops (May ‘07) • First class object, **SHARING & REUSE** • Analysis metadata functions in existing repositories (JCDL, 2007) • Functional model • OAIS (Open Archival Information System), DSpace • Level one application profile

  8. Functional requirements

  9. Bibliographic Citation Module dcterms:bibliographicCitation/Citation information DOI Data Object Module dc:creator/Name* dc:title/Data Set # dc:identifier/Data Set Identifier PREMIS:fixity/(hidden) dc:relation/DOI of Published Article* DDI:<depositr>/Depositor DDI:<contact>/Contact Information dc:rights/Rights Statement dc:description/Description # dc:subject/Keywords dc:coverage / Locality Required* dc:coverage/Date Range Required* dc:software/Software* dc:format/File Format dc:format/File Size dc:date/(Hidden) Required dc:date/Date Modified* Darwin Core: species/ Species, or Scientific* Key * = semi-automatic # = manual Everything else is automatic <DRIADE application profile>

  10. DRIADE metadata application profile….organic… • Level 1 – initial repository implementation • Application profile: Preservation, access/resource discovery, (limited use of CVs) • Level 2 – full repository implementation • Level 1++ expanded usage, interoperability, preservation; administration; greater use of CV and authority control; data sharing and reuse • Level 3 – “next generation” implementation • Considering Web 2.0 functionalities, Semantic Web

  11. Instantiation (Classifying Scientific Data Objects with Bibliographic Relationships Taxonomies)

  12. Motivation • DRIADE goals: • Data preservation, sharing, use/re-use, validation, repeatability • Is it important to know history of a data object? • How can we support accurate and effective tracking of the life-cycle of data object? • Data objects = first class objects • Data structures as works (Coleman, 2002) • Units of analysis, intellectual products of activity • Work = “propositions expressed (ideational content)”, and “expressions of the propositions” (Smiraglia, 2001) • Data objects are content carriers (Greenberg, 2007)

  13. Motivation • Research and…to explain a“work”; bibliographic families; and instantiation • Metadata and Bibliographic Control Models • FRBR (Functional Requirements for Bibliographic Records) • DCAM (Dublin Core Abstract Model) • RDF (Resource Description Framework)

  14. Research design • Objective: Build an open access repository that accurately reflects the “disciplinary knowledge structures” (relationship among data objects”) • Research questions • Do scientists (developing scientists) view data objects as works? • Do they understand different “instantiations”? • Do they think instantiation tracking is important? • Method • Instantiation identification test and survey • Participants: Scientists, research and publication

  15. Procedures, etc. • Verify participant suitability, contextual introduction • Read instantiation definitions and view instantiation diagram (next slide) • Example Instantiation scenario Scenario: Sherry collects data on the survival and growth of the plant Borrichia frutescens (the bushy seaside tansy)… Question: What is the relationship between Sherry’s paper data sheet and her excel spreadsheet? Answer: Equivalent | Derivative | Whole-part | Sequential (circle one) • 8 scenarios (randomized); survey

  16. Data object relationships B (=data set A annotated) A (=data set) A (=data set in Excel) A (=same data set in SAS) A (=same data set on paper) C (=data set A revised) A1 (=part 1 of a data set) A2 (=part 2 of a data set) A (=data set) A1 (=a subset of A) Smiraglia, Tillet

  17. Results • 7 participants (Biochemistry, Biology, Botany/Plant Ecology) • 3 Faculty/research associates; 21+ yrs. research/pub. • 4 Research assistants; 3 (1-3 yrs.), 1 (5 yrs.)

  18. Results • ht=halftime; s=seldom; na=no answer

  19. Results (participant comments) • Validity: “Whenever anything changes, there’s the ability to make mistakes” • Sheer quantity of data: “We have 30 years worth of data, tracking changes is important” • The impact of changes in scientific nomenclature: • “As time goes on, datasets must be maintained to reflect current understanding of taxonomy and nomenclature, to allow connection of old data and attributes of that data to be associated correctly with new data and attributes of that data. This is a giant problem.”

  20. Conclusions and next steps • Conclusions • Use of data created by others increases over time • In general, more seasoned scientists better grasp • Sequential data presented the most difficulty (less seasoned sci.) • Unanimous support, “very  extremely important” • Bibliographic control relationship are applicable to describing the relationships between data objects • Next steps: • Continue to collect data (30-50) • Study additional types of instantiations • Develop applications that effectively track data object life-cycle • How do we encode these relationships? Manually/automatically? • Who should create them? Curator, scientists, collaboratively? • Should we maintain a vocabulary? • Consider implications for other disciplines

  21. Jane Greenberg, Associate Professor, and Director, SILS Metadata Research Center janeg@ils.unc.edu Thank you!!

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