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TMF - a tutorial

TMF - a tutorial. TMF - Terminological Markup Framework Laurent Romary - Laboratoire Loria. Three parts. Part 1: Basic concepts Part 2: Representing data categories Part 3: Designing (schemas and) filters. TMF - a tutorial Part 1: Basic concepts. TMF - Terminological Markup Framework

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TMF - a tutorial

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  1. TMF - a tutorial TMF - Terminological Markup Framework Laurent Romary - Laboratoire Loria

  2. Three parts • Part 1: Basic concepts • Part 2: Representing data categories • Part 3: Designing (schemas and) filters

  3. TMF - a tutorialPart 1: Basic concepts TMF - Terminological Markup Framework Laurent Romary - Laboratoire Loria

  4. Background - ISO etc. • The need for abstraction • Structure and content of terminological data - picture virtual-actual • The meta-model (structural skeleton) • Describing data categories • Styles and vocabularies • XTMF as a mapping tool - examples • Further work: extending the model to a wider scope (language engineering)

  5. Overview

  6. General principles • Expressing constraints on the representation of computerized terminologies • What is the underlying structure of computerized terminologies? • Which data-category is used and under which conditions? • Maintaining interoperability between representations • Providing a conceptual tool to compare two given formats

  7. Definitions • TMF: Terminological Mark-up Framework • Definition of underlying structures and mechanisms needed for the computer representation of terminological data • Independence with regards any specific format • GMT: Generic Mapping Tool • Abstract XML format equivalent to the underlying model of TMF

  8. Definitions - cont. • TML: Terminological Mark-up Language • One specific representation format generated within TMF • E.g.: DXLT is a possible TML

  9. A family of formats TMF … TML1 TML2 TML3 TMLi (Geneter) (DXLT) GMT

  10. Meta-model Representing the underlying structure of terminological data

  11. Terminological Data Collection 0:1 * * 1 1 1 Global Information Terminological Entry Complementary Information * * Terminology- related Information 1 * Language Section 1 * * 1 Term Section * * 1 Term Component Section

  12. Meta-model description • Terminological Data Collection (TDC) • A collection of data containing information on concepts of specific concept fields. • Terminological Entry (TE) • An entry containing information on terminological units (i.e., subject-specific concepts, terms, etc.). • Example: Domain description, Conceptual relations etc.

  13. Meta-model description - cont. • Language Section (LS) • The part of a terminological entry containing information related to one language. • Note: One terminological entry may contain information on one, two or more languages. • Term Section (TS) • The part of a language section giving information about a term. • Example: Term status (e.g. abbreviation), Usage information (temporal, geographical etc.)

  14. Meta-model description - cont. • Term Component Section (TCS) • The section of a term section giving information about components of a term. • Example: Component grammatical information (Part of speech)

  15. Meta-model description - cont. • Global Information (GI) • Technical and administrative information applying to the entire data collection . • Example: title of the data collection, revision history • Complementary Information (CI) • Information supplementary to terminology-related information. • Example: bibliographical source, documentary language or description thereof.

  16. The structural skeleton Terminological Data Collection (TDC) Global Information (GI) Complementary Information (CI) * Terminological Entry (TE) * Language Section (LS) * Term Level (TL) * Term Component Level (TCL)

  17. How does this work? Walking through an example…

  18. DXLT example <termEntryid='ID67'> <descrip type='subjectField‘>manufacturing</descrip> <descrip type='definition'>A value between 0 and 1 used in ...</descrip> <langSetlang='en'> <tig> <term>alpha smoothing factor</term> <termNote type='termType'>fullForm</termNote> </tig> </langSet> <langSetlang='hu'> <tig> <term>Alfa ...</term> </tig> </langSet> </termEntry>

  19. id=‘ID67’ [attribute] subjectField=‘ manufacturing ’ [typedElement] definition=‘A value…’ [typedElement] TE lang=‘ en ’ [attribute] LS lang=‘ hu ’ [attribute] TS term=‘…’ [element] term=‘alpha smoothing factor’ [element] termType=‘fullForm’ [typedElement] Identifying the structural skeleton TE: Terminological Entry LS: Language Section TS: Term Section

  20. TMF information model id=‘ID67’ subjectField=‘ manufacturing ’ definition=‘A value…’ TE LS LS lang=‘ hu ’ lang=‘ en ’ term=‘alpha smoothing factor’ termType=‘fullForm’ TS term=‘…’ TS

  21. GMT representation <struct type=“TE”> <feat type=“id”>ID67</feat> <feat type=“subjectField”>manufacturing</feat> <feat type=“definition”>A value between 0 and 1 used in ...</feat> <struct type=“LS”> <feat type=“lang”>en</feat> <struct type=“TS”> <feat type=“term”>alpha smoothing factor</feat> <feat type=“termType”>fullForm</feat> </struct> </struct> <struct type=“LS”> <feat type=“lang”>hu</feat> <struct type=“TS”> <feat type=“term”>Alfa ...</feat> </struct> </struct> </struct>

  22. TML à la mode ISO • Ingredients • A structural skeleton • (take the TMF Metamodel) • A reference Data Category Registry • ISO 12620 is a good place to find one • Recette • Choose some data categories from the registry • You can even constrain the values of your datcats • Associate a style and vocabulary to each datcat • You can inspire yourself from others (DXLT) • Serve it hot to your software guy with a piece of SALT software

  23. GMT Generic Mapping Tool

  24. Background • Interoperability principle • If any two TMLs have exactly the same DCS, even though they differ radically in style and vocabulary, they are equivalent. • Consequence • It is always possible to define a filter from one TML to another when they are interoperable • GMT is the intermediate representation to do so

  25. From one TML to another • GMT - Generic mapping tool • an abstract XML representation • identification of levels • <struct type=“LS”>…</struct> • a recursive element • representation of data-categories • <feat type=“definition”>…</feat>

  26. The tmf element • Description: • The tmf element is the root element for any valid XTMF document. It contains both the global information that corresponds to a terminological data collection, the collection itself, and the complementary information comprising external resources in particular, which are needed for describing the various terminological entries. • Content model: <!ELEMENT tmf (struct*)>

  27. The struct element • Description • The struct element should be used to represent a locus in a given structural skeleton. The struct element is recursive and may also contain feat and/or brack elements to express attributes belonging to the corresponding level of the meta model. • Attributes: • type: level in the meta model (TDC, TE, LS, TS or TCS) • Content model: <!ELEMENT struct ((feat|brack)*, struct*)> <!ATTLIST struct type (TDC|TE|LS|TS|TCS) #REQUIRED>

  28. The feat element • Description • The feat element represents any feature that is either directly attached to a locus in the structural skeleton (represented by a struct element). • The feat element accepts the following attributes: • type: categorises the feat element through the reference to the name of the corresponding data category. • Content model (DTD) • <!ELEMENT feat (#PCDATA | annot)*> • <!ATTLIST feat type CDATA #REQUIRED>

  29. Bracketing information

  30. Rationale • Describing the context of use of a given data category • Example 1: • Classification Code: AG1 • Classification System: Lenoc • Example 2: • Transaction type: modification • Responsible person: Mr. X • Date: 23 avril 1988

  31. Formal model • Hierarchical feature structure • Constraint: Type given by ‘ main ’ (first) data category

  32. GMT description • Bracketing features <brack> <feat type=“classificationCode“>xxx</feat> <feat type=“classificationSystem“>Lenoc</feat> </brack> Rem: no type for ‘ brack ’

  33. Annotating content

  34. Rationale • Why should we annotate specific content? • To identify components which are not explicitly expressed as a specific part of a terminological entry • E.g.: Characteristics of a concept • To relate a component to another entry or an external resource • E.g.: bibliographical reference

  35. Formal model ?

  36. XML model • Mixed content • <!element feat (#PCDATA|annot)*> • Attributes • type: categorises the annot element through the reference to the name of the corresponding data category. • Rem.: Problems with mixed content in XML schemas

  37. GMT description • Annotating information <feat type=“definition”> pencil whose <annot type=“characteristic”> casing </annot> is fixed around a cental graphite medium which is used for writing or making marks </feat>

  38. Representation of relations

  39. XML links • Transparency as to the actual location of a resource (internal vs. external) • Maybe useful to identify ontologies • External links between concepts entry i entry i entry j entry j

  40. Representation in GMT • Two attributes • Target - a pointer to a ‘ struct ’ element in the case the feature expresses a relation between the current locus and another locus in the structural skeleton; • Source - a pointer to a ‘ struct ’ element in cases where the feature is described external to the locus to which it is supposed to be attached.

  41. Some examples • Simple atomic feature attached directly to a locus: <feat type="conceptIdentifier">ID67</feat> • Basic feature whose value is a reference to a locus in the structural skeleton: <feat type="partWhole" target="TE24"/> • Basic feature anchored at the locus in the structural skeleton whose id attribute value is “TE24”: <feat type="conceptIdentifier" source="TE24">ID67</feat> • Compound feature anchored at “TE 23” and which makes reference to “TE 24”: <feat type="partWhole" source="TE23" target=“TE24”/>

  42. Styles and vocabularies

  43. Implementating a DatCat • Definitions: • ‘ style ’ — The way a given DatCat is implemented as an XML object… • ‘ vocabulary ’ — symbols needed to express the implementation of a given DatCat in its associated style ; • E.g.: • DatCat: /definition/ • Vocabulary = [def] • Style = Element • <def>pencil whose casing …</def> DatCat value

  44. Implementating a DatCat (Cont.) • Definition: • ‘ anchor ’ — the XML element(s) to which the implementation of a given DatCat can be attached • E.g.: <tig> <term>alpha smoothing factor</term> </tig>

  45. Styles - element • Element • Def.: The Datcat is implemented as an element, child of its anchor • Vocabularies : the name of the corresponding element • E.g.: <def>pencil whose casing …</def> <term>alpha smoothing factor</term> DatCat value

  46. Styles - typedElement • typedElement • Def.: The Datcat is implemented as a generic XML element, which is a child of the anchor, and which is further specified by means of a type attribute. Its content is the value of the feature in the structural skeleton. • Vocabularies : the element name and the value of the type attribute • E.g.: <termNote type=‘definition’>Bla, bla, bla…</termNote> DatCat value

  47. Styles - attribute • Attribute • Def.: The Datcat is implemented as an attribute of its anchor • Vocabularies : the name of the corresponding attribute • E.g.: <termEntry id='ID67'> … </termEntry> <ldl language ='en'> … </ldl> DatCat value

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