Ruben Verborgh’s data

Matches in Ruben’s data for { <https://peerj.com/articles/cs-110/> ?p ?o }

• cs-110 maker morris_swertz.
• cs-110 maker mark_thompson.
• cs-110 maker mark_d_wilkinson.
• cs-110 maker luiz_olavo_bonino_da_silva_santos.
• cs-110 maker jerven_bolleman.
• cs-110 maker fleur_d_l_kelpin.
• cs-110 maker erik_schultes.
• cs-110 maker erik_m_van_mulligen.
• cs-110 maker arnold_kuzniar.
• cs-110 maker anand_gavai.
• cs-110 maker alasdair_j_g_gray.
• cs-110 maker michel_dumontier.
• cs-110 maker me.
• cs-110 title "Interoperability and FAIRness through a novel combination of Web technologies".
• cs-110 isPartOf peerj_computer_science.
• cs-110 name "Interoperability and FAIRness through a novel combination of Web technologies".
• cs-110 label "Interoperability and FAIRness through a novel combination of Web technologies".
• cs-110 name "Interoperability and FAIRness through a novel combination of Web technologies".
• cs-110 topic FAIR_Data_Principles.
• cs-110 topic interoperability.
• cs-110 topic Representational_state_transfer.
• cs-110 topic Metadata.
• cs-110 topic Linked_Data.
• cs-110 topic data_integration.
• cs-110 topic Semantic_Web.
• cs-110 topic World_Wide_Web.
• cs-110 subject FAIR_Data_Principles.
• cs-110 subject interoperability.
• cs-110 subject Representational_state_transfer.
• cs-110 subject Metadata.
• cs-110 subject Linked_Data.
• cs-110 subject data_integration.
• cs-110 subject Semantic_Web.
• cs-110 subject World_Wide_Web.
• cs-110 authorList b0_b2342.
• cs-110 topic FAIR_Data_Principles.
• cs-110 topic interoperability.
• cs-110 topic Representational_state_transfer.
• cs-110 topic Metadata.
• cs-110 topic Linked_Data.
• cs-110 topic data_integration.
• cs-110 topic Semantic_Web.
• cs-110 topic World_Wide_Web.
• cs-110 abstract "Data in the life sciences are extremely diverse and are stored in a broad spectrum of repositories ranging from those designed for particular data types (such as KEGG for pathway data or UniProt for protein data) to those that are general-purpose (such as FigShare, Zenodo, Dataverse or EUDAT). These data have widely different levels of sensitivity and security considerations. For example, clinical observations about genetic mutations in patients are highly sensitive, while observations of species diversity are generally not. The lack of uniformity in data models from one repository to another, and in the richness and availability of metadata descriptions, makes integration and analysis of these data a manual, time-consuming task with no scalability. Here we explore a set of resource-oriented Web design patterns for data discovery, accessibility, transformation, and integration that can be implemented by any general- or special-purpose repository as a means to assist users in finding and reusing their data holdings. We show that by using off-the-shelf technologies, interoperability can be achieved at the level of an individual spreadsheet cell. We note that the behaviours of this architecture compare favourably to the desiderata defined by the FAIR Data Principles, and can therefore represent an exemplar implementation of those principles. The proposed interoperability design patterns may be used to improve discovery and integration of both new and legacy data, maximizing the utility of all scholarly outputs.".
• cs-110 datePublished "2017".
• cs-110 mainEntityOfPage wilkinson_peerjcs_2017.
• cs-110 sameAs cs-110.
• cs-110 isPrimaryTopicOf wilkinson_peerjcs_2017.
• cs-110 page wilkinson_peerjcs_2017.
• cs-110 number "110".
• cs-110 number "3".
• cs-110 volume "3".
• cs-110 locator "110".
• cs-110 locator "3".
• cs-110 volume "3".
• cs-110 position "3".
• cs-110 volumeNumber "3".
• cs-110 endingPage "110".
• cs-110 pageEnd "110".
• cs-110 pageEnd "110".

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