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Controlled Vocabularies and SKOS

About this module

This learning resource is presented in two formats: a video screencast, which you can view below; or the full text module which continues below the video. Both the video and the module cover the basics of controlled vocabularies and the SKOS Standard, and can be used alongside one another, or each used independently. The full text module, though, contains an additional section about SKOS-XL, and a quiz for testing your SKOS knowledge.

Watch the video

This screencast was recorded for the Spring School LiSeH 2021, and presents much of the same material as in the full module below, with some omissions.

Introduction

What are Controlled Vocabularies?

Controlled vocabularies are knowledge organization systems that contain (optionally) structured set of concepts/terms for organizing and classifying data in order to ensure its future access and retrieval. The concepts/terms are data descriptors related to each other via explicit relationships (hierarchical or associative). These data descriptors are used to distinguish and define the characteristics of knowledge resources in a specific domain. Using controlled vocabularies the resources can be queried, retrieved, analysed and linked to other relevant information objects.

Patricia Harpring 1 introduced the following definition of controlled vocabulary (CV):

“A controlled vocabulary is an organized arrangement of words and phrases used to index content and/or to retrieve content through browsing or searching. It typically includes preferred and variant terms and has a defined scope or describes a specific domain.” (Harpring, P., 2010)

There are many different types of controlled vocabularies, the most common among them are:

  • Thesaurus - a type of controlled vocabulary used in information systems that organizes concepts in hierarchical and/or associative relationships and provides their semantic definitions
  • Classification schema - a system that based primarily on classifying things or concepts into groups or classes with a detailed explanation of those classification methods
  • Subject heading list - a list of terms describing subjects in information system
  • Taxonomy - a system that organizes things and concepts in groups based on their common characteristics and/or differences
  • Terminology - a list of terms used to describe concepts in a certain domain
  • Glossary - an alphabetical list of terms with their explanation used in a specific context

Diagram 1. below shows how controlled vocabularies are embedded in architecture of an information system (the example is derived from DEFC controlled vocabulary). In this example, the Archeological site is a Universal abstract class, whereas Athens is an instance of Archaeological site class and a Particular that represents the exact and real archaeological site studied and described in the system. Athens can be of one or many types that are defined in a controlled vocabulary, for example, it can be a type of ‘Hillside’.

Diagram 1. Controlled vocabularies in data architecture

Controlled vocabularies (CVs) are prominently used in many domains of research and industry:

  • On the Web, vocabularies are often used in building the information architecture for websites, data repositories, information systems, thereby providing terms for indexing and retrieval of information objects.
  • CVs are widely used in biology for classification of living organisms (e.g. taxonomies of living organisms, classifications of cross-species anatomical entities).
  • Public health and medicine have CVs in various forms (terminologies, thesauri, ontologies) for defining categorizations and classifications for biomedical investigations, diseases, symptoms, medical errors, etc.
  • International organizations actively use CVs to standardize terms and translations in international affairs. The most notable examples are the United Nations terminologies that are translated into six main languages of the UN to eliminate ambiguity in terms used in international communication.
  • GLAM (Galleries/Libraries/Archives/Museums) have used CVs for a very long time to describe their objects and resources, build catalogues and information systems.
  • The fields of Computer Science as data mining, knowledge extraction, or conversation AI use CVs to classify entities and objects in text or speech recognition (Named Entity Recognition and Named Entity Disambiguation, e.g. CVs used to categorize intent in conversation with a robot).

Thereby the CVs are used :

  • to organize large volumes of data (group, categorize)
  • to ensure future retrieval/search functionality
  • to simplify user experience and navigation on the website
  • to have a common understanding of used terms (reduce the ambiguity of words)
  • for data interoperability and dataset integration (contributing to Open Data and Open Science)
  • to facilitate an exploration process in information systems
  • as a base for recommendation systems
  • in question-answering systems

Role of CVs in Semantic web

The main idea of Semantic Web is to enrich data with its semantics/meaning that not only humans but also machines could use, interpret and infer new knowledge from. CVs provide and document data semantics.

Tim Berners-Lee in his fundamental paper “The Semantic Web” (2001) says that on the Semantic Web “information is given well-defined meaning” 2. CVs are one of the tools used for this mission.

W3C developed specifications and standards to support the usage of CVs in the context of the Semantic Web in order to express knowledge in a machine-readable format that can be used by computer applications to interpret it. SKOS (Simple Knowledge Organization System) is a standard schema to represent CVs using Resource Description Framework (RDF), which is a standard model for data exchange on the Web. Usage of RDF for CVs representation allows metadata to be shared and retrieved across different applications.

CVs in a Digital Humanities context

The field of Digital Humanities (DH) deals with the production of digital objects which could be data resources (e.g. 3D models, TEI 3 documents, data visualizations) as well as with the production of metadata for real-world objects (e.g. archaeological finds, historical manuscripts). In both cases, it involves the creation of digital assets. CVs are used to describe, group and distinguish these resources.

Why CVs are important in DH projects?

DH data is highly interpretational and often observational. To a certain extent and in certain DH disciplines (e.g. literary studies) it is shaped by a researcher’s worldview and opinion. This makes it more difficult to standardize and develop a common understanding of the used terminology. Nevertheless, CVs are an attempt to make the conceptualizations explicit and thus understandable to recipients.

Moreover, Digital Humanities is one of the domains that has adopted Open Data and Open Science initiatives actively in recent years. This makes it even more crucial to design and publish CVs and link them to external authoritative reference resource to allow data interoperability and linking with data from other DH projects.

Approaches to CVs interoperability

There are different approaches to how CVs can be reused or made interoperable with each other in order to facilitate data integration.

Diagram 2. below shows how different projects use one controlled vocabulary to describe their data. Both projects’ data can be queried with terms from this vocabulary. This is probably the best-case scenario that can happen because it ensures full data interoperability.

Diagram 2. Usage of a common controlled vocabulary for data description in different projects

Another approach on Diagram 3. shows how different projects use their own project-specific controlled vocabularies. The vocabularies are linked to each other through established relationships among concepts in both of them. Therefore we can refer to data in Project 1 using matching concepts from the controlled vocabulary of Project 2. The linking happens on a level of a concept description when the statement is encoded that the concept is exact/related/close match (etc.) to a concept from another CV or from a large semantic network, e.g. Dbpedia.

Diagram 3. Interoperable controlled vocabularies

There are also meta-vocabularies developed with a primary goal to be a high-level overarching vocabulary for more domain-specific CVs. Therefore making it easier to connect local CVs and establish relationships among them through common meta-level concepts. Backbone Thesaurus 4 is one of the examples in the DH domain that has as its purpose to allow interdisciplinary CVs development and integration.

BBT - Backbone Thesaurus in Vocabs repository

SKOS Standard

About SKOS

SKOS is a Simple Knowledge Organization System, a common data model for sharing and linking knowledge organization systems via the Web 5.

SKOS is based on RDF and is a machine-readable format and can be exchanged between software applications and published on the Web.

Informative guide SKOS Primer .

Normative guide SKOS Reference intended for users who have a good understanding of Semantic Web technology, especially RDF and OWL SKOS Reference .

SKOS Basics

Concept

The central element of SKOS is a Concept.

“Concepts exist in the mind as abstract entities which are independent of the terms used to label them.” SKOS Primer

To create a Concept one needs to create a Uniform Resource Identifier (URI) and assign this URI with rdf:type skos:Concept. This is how it is done in RDF syntax:

@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:cat rdf:type skos:Concept.

Labels

The Concept is defined by a label in natural language. SKOS provides three properties to attach labels to a concept:

  • skos:prefLabel - preferred label for a concept, only one unique preferred label per language is allowed;
  • skos:altLabel - alternative labels for a concept, e.g. synonyms, abbreviations and acronyms (can be many);
  • skos:hiddenLabel - misspellings and other variants, this label is accessible for text indexing by applications but not visible for the user.
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:cat rdf:type skos:Concept;
    skos:prefLabel "cat"@en;
    skos:prefLabel "Katze"@de;
    skos:altLabel "kitten"@en;
    skos:hiddenLabel "katze"@de.

Semantic relationships

There are two types of relationships between concepts that can be established in a vocabulary:

  • Hierarchical via properties skos:broader, skos:narrower
    • SKOS model doesn’t state that broader & narrower are transitive, but it also doesn’t imply that these properties are intransitive (Note on transitivity: the relationship is transitive if concept A is related to concept B. Concept B is related to concept C. That implies that concept A is related to concept C.)
    • For explicit transitivity use skos:broaderTransitive and skos:narrowerTransitive
  • Associative via property skos:related
    • is not defined as a transitive property

Important to not mix hierarchical and associative relationships: if two concepts are in broader/narrower relationships between each other then they are explicitly in hierarchical relationships, therefore, don’t need to be related via skos:related property. Similarly, if two concepts are related via skos:related property we can infer that they are related in some other distinct hierarchical relationships (e.g. a concept representing a tangible object is related to a concept describing a method that uses that object).

@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:cat rdf:type skos:Concept;
  skos:prefLabel "cat"@en;
  skos:prefLabel "Katze"@de;
  skos:altLabel "kitten"@en;
  skos:narrower ex:wildcat.

ex:wildcat rdf:type skos:Concept;
  skos:prefLabel "wildcat"@en;
  skos:broader ex:cat.

Documenting concepts

SKOS defines properties to add human-readable documentation about concept. It is strongly recommended to add documentation properties for each concept.

The following properties can be used:

  • skos:note - general documentation purposes
  • skos:scopeNote - partial information about the intended meaning of a concept
  • skos:definition - complete explanation of the intended meaning of a concept
  • skos:example - example of the use of a concept
  • skos:historyNote - significant changes to the meaning or the form of a concept
  • skos:editorialNote - administrative information for editors
  • skos:changeNote - changes for the purposes of administration and maintenance
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:cat rdf:type skos:Concept;
  skos:prefLabel "cat"@en;
  skos:prefLabel "Katze"@de;
  skos:altLabel "kitten"@en;
  skos:hiddenLabel "katze"@de;
  skos:definition "A small carnivorous mammal with soft fur, a short snout, and retractable claws."@en;
  skos:editorialNote "Review this term after merge."@en;
  skos:changeNote "Added hidden label."@en.

Concept Scheme

As mentioned above, CV forms a schema of data descriptors. Therefore SKOS introduces a Concept Scheme class to express the notion of CV itself. Concepts are compiled in one Concept Scheme with an explicitly defined scope.

The following statements define the purpose and usage of Concept Scheme class:

  • skos:ConceptScheme is a class for representing a controlled vocabulary.
  • Concepts have to be linked to ConceptScheme via skos:inScheme property.
  • skos:hasTopConcept is used to define entry points of a hierarchy.
  • Metadata about Concept Scheme can be expressed using Dublin Core properties such as dct:creator, dct:contributor, dct: title, dct:rightHolder …
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .
@prefix dct: <http://purl.org/dc/terms/> .


ex:animalsVocabulary rdf:type skos:ConceptScheme;
  dct:title "Animals Vocabulary"@en;
  skos:hasTopConcept ex:animals.

ex:animals rdf:type skos:Concept;
  skos:prefLabel "animals"@en;
  skos:prefLabel "Tiere"@de;
  skos:inScheme ex:animalsVocabulary;
  skos:topConceptOf ex:animalsVocabulary.

Grouping concepts within one vocabulary

  • SKOS provides a class of Collection for the purposes of grouping concepts based on their shared characteristics.
  • Class skos:Collection/skos:OrderedCollection is used to group concepts into meaningful collections within Concept Scheme.
  • Concepts are added to Collection via skos:member or skos:memberList property.
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:wildCatsInEurope rdf:type skos:Collection;
  skos:prefLabel "Wild cats in Europe"@en;
  skos:member ex:europeanWildcat;
  skos:member ex:eurasianLynx;
  skos:member ex:iberianLynx.

ex:europeanWildcat rdf:type skos:Concept;
  skos:prefLabel "European wildcat"@en.

ex:eurasianLynx rdf:type skos:Concept;
  skos:prefLabel "Eurasian lynx"@en.

ex:iberianLynx rdf:type skos:Concept;
  skos:prefLabel "Iberian lynx"@en.

Advanced SKOS

Mapping concepts to external vocabularies and Linked Open Data (LOD) resources

Concepts can be semantically reconciled to concepts in different Concept Schemes (=vocabularies) or LOD resources on the Web for the purposes of data interoperability and integration.

SKOS provides the following properties to link concepts with external resources:

  • skos:exactMatch - the local term is an exact match to a term in an external vocabulary
  • skos:closeMatch - not exact but close match to a term in an external vocabulary
  • skos:broadMatch - the local term has a broader match in an external vocabulary
  • skos:narrowMatch - the local term has a narrower term in an external vocabulary
  • skos:relatedMatch - the related term in an external vocabulary
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .

ex:europeanWildcat rdf:type skos:Concept;
    skos:prefLabel "European wildcat"@en;
    skos:exactMatch <https://www.wikidata.org/wiki/Q148833>;
    skos:broadMatch <https://www.wikidata.org/wiki/Q43576>.

SKOS-XL

Sometimes it is required to describe relationships among lexical labels representing concepts. For this SKOS provides an extension SKOS-XL - SKOS eXtension for Labels - to identify, describe and link lexical labels.

  • Each label is defined as skosxl:Label class and assigned a URI
  • The lexical form is stored via skosxl:literalForm property
  • Labels relations are expressed via skosxl:labelRelation
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix rdf: <http://www.w3.org/1999/02/22-rdf-syntax-ns#> .
@prefix ex: <http://www.example.com/> .
@prefix skosxl: <http://www.w3.org/2008/05/skos-xl#> .

ex:europeanWildcat rdf:type skos:Concept;
  skosxl:prefLabel ex:europeanWildcatLabel1;
  skosxl:altLabel ex:europeanWildcatLabel2.

ex:europeanWildcatLabel1 rdf:type skosxl:Label;
  skosxl:literalForm "European wildcat"@en.

ex:europeanWildcatLabel2 rdf:type skosxl:Label;
  skosxl:literalForm "Felis silvestris"@la.

ex:europeanWildcatLabel1 skosxl:labelRelation ex:europeanWildcatLabel2.

SKOS Quiz

Test your knowledge of the SKOS standard with the quiz. The correct answers are at the end of the learning resource.

SKOS vocabulary quality

SKOS checklist

The future retrieval and search functionality will directly depend on the quality of CV, therefore, it is important to follow W3C recommendations for SKOS and check a vocabulary against the most common errors before using it in an application or publishing on the Web. The most common reasons for errors and bad practices are the following:

  1. Omitted or invalid language tags (e.g.: skos:prefLabel “stone”@english)
  2. Label conflicts (e.g. two concepts have the same preferred lexical label in a given language when they belong to the same concept scheme)
  3. Orphan concepts (e.g. concepts without any associative or hierarchical relationships)
  4. Undocumented concepts (concept should have one of the documentary notes)
  5. Valueless associative relations
  6. Omitted top concepts => no starting points of the concept hierarchy
  7. Top concept having broader concepts
  8. Creating a new concept for each synonym
  9. Ambiguous label for a concept
  10. Flat data (no hierarchy and associative relationships among concepts)

The above material is derived from the following work: Mader, Christian, Bernhard Haslhofer, and Antoine Isaac. “Finding quality issues in SKOS vocabularies.” In International Conference on Theory and Practice of Digital Libraries, pp. 222-233. Springer, Berlin, Heidelberg, 2012.

Task: Model Music styles vocabulary

There are many styles used to categorize music. Consider the following styles: pop music, alternative rock, electronic music, punk rock, techno, rock, heavy metal.

  1. Structure/draw your own vocabulary called “Music styles”
  2. Model this vocabulary in a SKOS record:
    • model in RDF turtle format
    • add at least one documentary note for each concept
    • add labels in other languages
    • feel free to add more music styles
    • establish relationships to external LOD resources (dbpedia, wikidata)
    • save file in .ttl format
  3. Visualize “Music styles” using web tool SKOS play. Try out different visualization types.

Controlled vocabulary as a backbone of information architecture

CV in data management web application

Controlled vocabularies provide data descriptors for future data retrieval. This directly impacts search and data discovery. A CV is a building block in database design and is a part of information architecture in the user interface. The following examples show how one CV is used in different parts of the web application. The following examples are taken from Iron-Age-Danube project’s data management system.

Picture 1. Visualization of IAD Thesaurus 6

Picture 1. Visualization of IAD thesaurus

  • Database values: CVs are closed lists in the user interface represented as dropdown lists when creating or annotating a record.

Picture 2. CV in data curation interface

Picture 2. Controlled vocabularies in IAD curation interface

  • Context information: when exploring data it is important to provide a user with an explanation of used terms in the interface.

Picture 3. CV in user interface

Picture 3. Pop up with a vocabulary term definition and traslations in user interface

  • Faceted search is based on CVs: dropdowns and autocompletes

Picture 4. CV in faceted search interface

Picture 4. Controlled vocabularies in IAD search interface

Picture 5. CV in faceted search interface

Picture 5. Controlled vocabularies in IAD search interface

  • CVs are building blocks of Linked Open Data and used for connecting distributed datasets via concepts persistent URIs. Each concept has a unique stable and resolvable URI that can be reused by other projects to refer to this concept. The reference can be done by using directly URI or by retrieving a URI using the API of a vocabulary repository.

Picture 6. IAD Thesaurus in Vocabs repository

Picture 6. IAD - Iron-Age-Danube Thesaurus in Vocabs repository

Open source tools for vocabulary management

Creating a vocabulary is a lengthy and time-consuming process. Usually, it involves the conceptual thinking stage. In addition, the vocabulary refinement stage can last until the end of the project.

Vocabulary can be integrated into a project’s software at a database architecture level or retrieved via API from the third-party applications. There are different open source tools available for managing controlled vocabularies.

Editing and browsing

SKOS editors are tools for creating SKOS vocabulary in a user-friendly interface:

Most of the tools allow SKOS data import and export.

SKOSMOS is a vocabulary repository and browser which queries data via a SPARQL endpoint and provides a REST API to allow for linked data.

Validation

Validation tools are very important to detect any inconsistencies in SKOS structure and syntax.

  • Skosify - corrects errors and adds missing symmetric statements; it can be used as a command line tool or python library.

  • SKOS Testing tool - provides a validation report on the quality of submitted SKOS file; based on qSKOS.

Visualization

SKOS Play - renders and visualizes SKOS vocabularies (alphabetical index, hierarchical tree, interactive tree/square/circle visualization, autocomplete form).

ACDH-CH Vocabs services

The Austrian Centre for Digital Humanities and Cultural Heritage (ACDH-CH) provides a suite of services for collaborative creation, maintenance and sharing of vocabularies of any kind. Some services adapt existing open source tools to the needs of users and some are developed at the ACDH-CH.

ACDH-CH vocabs contains four major services covering different aspects of vocabulary usage:

  1. Vocabs repository is a service based on the open source tool SKOSMOS to allow publication, reuse and retrieval of controlled vocabularies. It provides an API endpoint in order to integrate vocabulary terms in web applications.
  2. Vocabs editor is a web-based tool for collaborative development of small and medium-sized controlled vocabularies. The editor follows the SKOS data model for the main elements of vocabulary. The Dublin core schema is used to capture the metadata (such as date created, date modified, creator, contributor, source and other) about each element. Each concept scheme, as well as each individual concept, can be downloaded in RDF/XML and Turtle format. The user management system allows a user to share a concept scheme that she/he created with other users (called ‘curators’) to create new concepts, edit and delete concepts and collections within this concept scheme. Each user can find a summary of their latest activity on the user’s page. The tool also provides an API to retrieve the data.
  3. Vocabs SPARQL is an interface for querying vocabularies triple store with SPARQL queries. It is developed on top of Jena Fuseki triple store and uses a YASGUI interface to access the endpoint.
  4. Vocabs Visualize is a data visualization service developed to show the relationships between concepts in multiple vocabularies and see how the represented topics are connected.

Controlled Vocabularies in Digital Humanities domain

Various domains controlled vocabularies registry - BARTOC

Category: General

Category: Meta-thesauri

Category: Resource type

Category: Digital Humanities

Category: Geosciences

Category: Cultural Heritage

Category: Archaeology

Acknowledgement

The creation of this learning material was supported by the Visegrad Fund Project “Training Digital Scholars: Knowledge Exchange between V4 and Austria” under the International Visegrad Fund’s Grant No. 21820079.

Footnotes

  1. Harpring, Patricia. Introduction to controlled vocabularies: terminology for art, architecture, and other cultural works. Getty Publications, 2010.

  2. Berners-Lee, Tim, James Hendler, and Ora Lassila. “The semantic web.” Scientific american 284, no. 5 (2001): 28-37.

  3. DariahTeach: Text encoding and the Text Encoding Initiative

  4. Backbone Thesaurus

  5. Alistair Miles, Sean Bechhofer. SKOS Reference, W3C Recommendation 18 August 2009

  6. IAD Thesaurus

Cite as

Ksenia Zaytseva and Matej Ďurčo (2020). Controlled Vocabularies and SKOS. Version 1.1.0. Edited by Matej Ďurčo and Tanja Wissik. DARIAH-Campus. [Training module]. https://elexis.humanistika.org/id/D8d6OrLdpLlGRqBSQDVN0

Reuse conditions

Resources hosted on DARIAH-Campus are subjects to the DARIAH-Campus Training Materials Reuse Charter

Full metadata

Title:
Controlled Vocabularies and SKOS
Authors:
Ksenia Zaytseva
Domain:
Social Sciences and Humanities
Language:
en
Published to DARIAH-Campus:
3/23/2020
Content type:
Training module
Licence:
CCBY 4.0
Sources:
DARIAH
Topics:
SKOS, Controlled Vocabularies, Semantic Web, Information Architecture, Metadata
Version:
1.1.0