Health Information modelling language - overview: Difference between revisions

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N.B Not to be confused with the [[Information model meta model|Information model meta model.]] which specifies the classes that hold the information model data, those classes described using the languages defined below.


<span style="color:#FF0000">Please note. The information in this section represents a specification of intent and work in progress. Actual implementations using the language have partial implementation of the grammars and syntaxes described here.</span>
This article describes the languages used in the information model meta model. In other words, the underlying grammar and syntax used as the building bricks for the classes that make up the model, instances of those classes being objects that conform to the class properties.  


== Purpose background and rationale ==
Details on the W3C standard languages that make up the grammar are described below.
Question: Yet another language? Surely not.


Answer: No, or at least, not quite.
In addtion,  


The following sections first describe the purpose of a modelling language, the background to the Discovery approach and the rationale behind the approach adopted.
If a system can consume RDF in its two main syntaxes (turtle and JSON-LD) then the model can be easily exchanged.


Subsequently the sections break down the various aspects of the language at ever increasing granularity, emphasising the relationship between the language fragments and the languages from which they are derived, resulting in the definition of the grammar of the language. The relationship between the language and a model store is also described.  
The main advantage of RDF and the W3C standards is that types and properties are given internationally unique identifiers which are both humanly readable and can be resolved via the world wide web protocols.


=== Purpose of a language. ===
Thus, in the information model, all classes,  properties and value types (subjects and predicates and objects) are IRIs which are defined by ontological techniques.
[[File:IM classes.png|thumb|Top level classes in information model]]
The main purpose of a modelling language is to exchange data and information about information models in a way that both machines and humans can understand. A language must be able to describe the types of structures that make up an information model as can be seen on the right.  


It is necessary to support both human and machine readability so that a model can be validated both by humans and computers.  Humans can read diagrams or text. Machines can read data bits. The two forms can be brought together as a stream of characters.
== Contributory languages ==
Health data can be conceptualised as a graph, and thus the model is a graph model.


A purely human based language would be ambiguous, as all human languages are. A language that is both can be used to promote a shared understanding of often complex structures whilst enabling machines to process data in a consistent way.
As the information model is a graph, and both classes and properties are uniquely identified, [[wikipedia:Resource_Description_Framework|RDF]] is the language used. As the technical community use Json as the main stream syntax for exchanging objects, the preferred syntax for the model classes and properties is [[wikipedia:JSON-LD|JSON-LD,]] with instances in plain [[wikipedia:JSON|JSON]]


It is almost always the case that a very precise machine readable language is hard for humans to follow and that a human understandable language is hard to compute consistently. As a compromise, many languages are presented in a variety of grammars and syntaxes, each targeted at different readers. The languages in this article all adopt a multi-grammar approach in line with this dual purpose.
RDF itself has limited grammar the modelling language uses the main stream semantic web grammars and vocabularies, these being RDFS, OWL and SHACL. Additional vocabularies are added to the IM to accommodate the shortfalls in vocabularies,


=== Background ===
In addition the IM accommodates some languages required to use the main health ontology i,e Expression Constraint language and Snomed compositional grammar. Within the IM ECL is modelled as query and Snomed-CT compositional grammar is modelled as a Concept class.
Information modelling covers three main business purposes:  '''Inference, validation''' and '''enquiry.''' Health information modelling is no different.


'''Inference''' is pivotal to decision making. For example, if you are about to prescribe a drug containing methicillin to  a patient, and the patient has previously stated that they are allergic to penicillin, it is reasonable to infer that if they take the drug, an allergic reaction might ensue, and thus another drug is prescribed.  
Finally, as a means of bridging the gap between user visualisation of query definitions and the underlying query languages such as SPARQL and SQL, the IM uses a set of classes to model query definitions, using a form that maps directly to SPARQL, SQL, GRAPHQL.


Furthermore, the ability to classify concepts enables business decision making at individual and population level. Thus a modelling language must include the ability to infer things and produce classifications.
When exchanging models using the language grammar both Json-LD and turtle are supported as well as the more specialised syntaxes such as owl functional syntax or expression constraint language.  


'''Data Validation''' is essential for consistent business operations.  Data models, user input forms, and data set specifications are designed to enable data collections to be validated. Maintaining a standard for data collection is essential. For example, if  a date of birth was not recorded in a patient record, the age of the patient could not be determined,  and that would massively affect the probability of a disease or the outcome of a treatment.  Also, if ''more than one'' date of birth was recorded for the same patient, it would be nearly as useless. Thus a modelling language must include the ability to '''constrain''' data models to suit particular business needs.
The modelling language is an amalgam of the following languages:


'''Enquiry (or  query''') is necessary to generate information from data. There is little point in recording data unless it can be interrogated and the results of the interrogation acted upon. Thus a modelling language must include the ability to query the data as defined or described, including the use of inference rules to find data that was recorded in one context for use in another.[[File:Language components.png|thumb|Venn diagram of language components]]In order to meet these requirements a modelling language will contain the 3 aspects:
* [https://www.w3.org/TR/REC-rdf-syntax/ RDF.] An information model can be modelled as a Graph i.e. a set of nodes and edges (nodes and relationships, nodes and properties). Likewise, health data can be modelled as a graph conforming to the information model graph. RDF Forms the statements describing the data. RDF in itself holds no semantics whatsoever. i.e. it is not practical to infer or validate or query based purely on an RDF structure. To use RDF it is necessary to provide semantic definitions for certain predicates and adopt certain conventions. In providing those semantic definitions, the predicates themselves can then be used to semantically define many other things. RDF can be represented using either TURTLE syntax or JSON-LD.
* [https://www.w3.org/TR/rdf-schema/ RDFS]. This is the first of the semantic languages. It is used for the purposes of some of the ontology axioms such as subclasses, domains and ranges as well as the standard annotation properties such as 'label


* To provide inference, a modelling language must support an ontology. The ontology defines the rules used in inference.
*[https://www.w3.org/TR/shacl/ SHACL]. For the data models of types.  Used for everything that defines the shape of data  or logical entities and attributes. Although SHACL is designed for validation of RDF, as SHACL describes what  things 'should be' it can be used as a data modelling language


* To enable validation, a modelling language must be able define structures with specific properties. Properties defined in this way are constraints on what otherwise be infinite possibilitiesThese constraints result in schemas or business classes,  which are used to hold actual data in objects. These constraints are referred to in this article as '''shapes.'''
*[https://www.w3.org/TR/owl2-primer/ OWL2 DL.]  This is supported in the authoring phase, but is simplified within the model. This brings with it more sophisticated description logic such as equivalent classes and existential quantifications ,and is used in the ontology and for defining things when an open world assumption is required. This has contributed to the design of the IM languages but OWL is removed in the run time models with class expressions being replaced by RDFS subclass, and role groups.
*[https://confluence.ihtsdotools.org/display/DOCECL#:~:text=The%20Expression%20Constraint%20Language%20is,either%20precoordinated%20or%20postcoordinated%20expressions. ECL.] This is a specialised query language created for Snomed-CT, used for simple concepts modelled as subtypes, role groups and roles, and is of great value in defining sets of concepts for the myriad of business purposes used in health.
*[https://confluence.ihtsdotools.org/display/DOCSCG/Compositional+Grammar+-+Specification+and+Guide SCG]. Snomed compositional grammar, created for Snomed-CT, which is a concise syntax for representing simple concepts modelled  as subtypes. role groups and roles and is a way of displaying concept definitions.


* To enable query, a modelling language must include a query language of sufficient sophistication to retrieve the necessary information from the information model as well as real data that is modelled by the model.


There is overlap between these 3 aspects. Ideally, a language would cover these three aspects in an integrated manner and that is the case with the Health information Discovery modelling language.<br />
=== Contributory languages ===
An information model can be modelled as a Graph i.e. a set of nodes and edges (nodes and relationships, nodes and properties). Likewise, health data can be modelled as a graph conforming to the information model graph.


The world standard approach to a language that models graphs is RDF, which considers a graph to be a series of interconnected triples, a triple consisting of the language grammar of subject, predicate and object. Thus the Discovery modelling language uses RDF as its fundamental basis, and can therefore be presented in the RDF grammars. The common grammars used in this article include TURTLE (terse RDF Triple language) and the more machine friendly JSON-LD (json linked data) which enables simple JSON identifiers to be contextualised in a way that one set of terms can map directly to internationally defined terms or IRIs.
'''Example  multiple syntaxes and grammars'''


RDF in itself holds no semantics whatsoever i.e. no one can infer or validate or query based purely on an RDF structure. To use it It is necessary to provide semantic definitions for certain predicates and adopt certain conventions to imply usage of the constructs. In providing those semantic definitions, the predicates themselves can then be used to semantically define many other things.
Consider a definition of chest pain in several syntaxes. Note that the OWL definition is in a form prior to classification whereas the others use the post classified structure (so called inferred)
<div class="toccolours mw-collapsible mw-collapsed">
Chest pain in Manchester syntax, SCG, ECL, OWL FS, IM Json-LD:
<div class="mw-collapsible-content">
<syntaxhighlight lang="turtle" style="border:3px solid grey">
# Definition of Chest pain in owl Manchester Syntax
equivalentTo  sn:298705000 and sn:301366005 and (sn:363698007 sn:51185008)


The three aspects alluded to above are covered by the logical inclusion of fragments, or profiles of a set of W3C semantic based languages, which are:
#In RDF turtle
sn:29857009
  rdfs:subClassOf
        sn:301366005 ,  
        sn:298705000;
  im:roleGroup [im:groupNumber "1"^^xsd:integer;
  sn:363698007 sn:51185008];
  rdfs:label "Chest pain (finding)" .


* [https://www.w3.org/TR/owl2-primer/ OWL2], which is used for semantic definition and inference. In line with convention, only OWL2 EL is used and thus existential quantification and object intersection can be assumed in its treating of class expressions and axioms.  The open world assumption inherent in OWL means it is very powerful for [[Subsumption test|subsumption]] testing but cannot be used for constraints without abuse of the grammar.


* [https://www.w3.org/TR/shacl/ SHACL,] which is used for data modelling constraint definitions. SHACL can also include OWL constructs but its main emphasis is on cardinality and value constraints. It is an ideal approach for defining logical schemas, and because SHACL uses IRIs and shares conventions with other W3C recommended languages it can be integrated with the other two aspects. Furthermore, as some validation rules require quite advanced processing SHACL can also include query fragments.
# In Snomed compositional grammar
=== 298705000 |Finding of region of thorax (finding)| +
    301366005 |Pain of truncal structure (finding)| :
            { 363698007 |Finding site (attribute)| = 51185008 |Thoracic structure (body structure)| }


* [https://www.w3.org/TR/sparql11-query/ SPARQ]L, [https://graphql.org/ GRAPHQL] are both used for query. GRAPH QL, when presented in JSON-LD is a pragmatic approach to extracting graph results via APIs and its type and directive systems enables  properties to operating as functions or methods.  SPARQL is a more standard W3C query language for graphs but can suffer from its own in built flexibility making it hard to produce consistent results. SPARQL is included to the extent that it can be easily interpreted into SQL or other query languages. SPARQL with entailment regimes are in effect SPARQL query with OWL support.
# When using ECL to retrieve chest pain
*[https://www.w3.org/TR/REC-rdf-syntax/ RDF] itself. RDF triples can be used to hold objects themselves and an information model will hold many objects which are instances of the classes as defined above (e.g. value sets and other instances)  
<<298705000 |Finding of region of thorax (finding)| and  
    (<<301366005 |Pain of truncal structure (finding)| :
            { 363698007 |Finding site (attribute)| = 51185008 |Thoracic structure (body structure)| })


The information modelling services used by Discovery can interoperate using the above sub-languages, but Discovery also includes a language superset making it easy to integrate. For example it is easy to mix OWL axioms with data model shape constraints as well as value sets  without forcing a misinterpretation of axioms. 


== Language and the information model APIs ==
#When used in OL functional syntax
The language (or languages) are a means to an end i.e. a human and machine readable means of exchanging information models and use of the language to interact with implementations of health records.
EquivalentClasses(
[[File:IM logical object model.png|thumb]]
:29857009 |Chest pain (finding)|
An information model is an abstract representation of data, but an information model must have content and that content must be stored.
ObjectIntersectionOf(
:22253000 |Pain (finding)|
ObjectSomeValuesFrom(
:609096000 |Role group (attribute)|
ObjectSomeValuesFrom(
:363698007 |Finding site (attribute)|
:51185008 |Thoracic structure (body structure)|
)
)
)
)
# In Json-LD


Data cannot be stored conceptually, only physically, and thus there must be a relationship between the abstract model and a physical store.
{
 
  "@id" : "sct:29857009",
In the information model services, the abstract model is instantiated as a set of objects of classes, the data element of those classes holding the subject, predicate and object structures. In reality those objects together with translation and data access methods are instantiated in some form of language. e.g. Java.
  "rdfs:label" : "Chest pain (finding)",
 
  "im:definitionalStatus" : {"@id" : "im:1251000252106","name" : "Concept definition is sufficient (equivalent status)"},
The physical store is currently held in a triple like relational database accessed by a relational database engine but could be easily stored as a native graph.
  "rdfs:subClassOf" : [ {
 
    "@id" : "sct:301366005",
The model can then be used as the source and target of the exchange of data, the latter using a language interoperating via a set of APIs
    "name" : "Pain of truncal structure (finding)"
 
  }, {
This can be visualised as in the diagram on the right. It can be seen that the inner physical store, is accessed by an object model layer, which is itself accessed by APIs using modelling language grammar and syntax. The diagram shows the main grammars supported by the Discovery information model, including the Discovery information modelling language grammar itself.
    "@id" : "sct:298705000",
 
    "name" : "Finding of region of thorax (finding)"
Support for the main languages means that a Discovery information model instance has 2 levels of  separation of concerns from the languages used to exchange data, and the underlying model store. There is thus no reason to buy into Discovery language to use the information model.
  } ],
 
  "im:roleGroup" : [ {
Likewise, an implementation of objects that hold data in a form that is compatible with a particular data model and ontology module, can be accessed using the same language.
    "im:groupNumber" : 1,
 
    "sct:363698007" : [ {
This makes the language just as useful for exchanging query definitions, value sets as well as useful for actual query of health record stores via interpreters.
      "@id" : "sct:51185008",
 
      "name" : "Thoracic structure (body structure)"
The remainder of this article describes the language itself, starting with some high level sections on the components, and eventually providing a specification of the language and links to technical implementations, all of which are open source.
    } ]
== The language building blocks ==
  } ]
This section describes the approach to the design of the grammars of the Discovery super set language, including how the sublanguages are incorporated into a single whole, without loss of meaning.
}
 
</syntaxhighlight>
The description is divided into paragraphs and subsections which follow a set of decisions which start from the basic fundamentals , and end with the final grammar specification referenced in a separate article. The decisions made are as follows:
</div>
 
</div> <div class="mw-collapsible-content">&nbsp;</div>
'''Data as a Graph'''
 
Health data is conceptualised as a graph and thus the model of health data is a graph model.  Consequently the language used must support graph concepts.
 
A graph is considered as a set of nodes and edges. For a graph to be valid, a node must have at least one edge, and an edge must be connected to at least two nodes. Thus the smallest graph must have at least 3 entities.
 
'''Human and machine readable'''
 
The model must be both human and machine readable. A graph can be represented using the recognisable plain language characters in UTF-8. For human readability the characters read from left to right and for machine readability a graph is a character stream from beginning to end.
 
'''Optimised human legibility and optimised machine readability'''


These two are impossible to reconcile in a single grammar. Consequently two grammars are developed, one for human legibility and the other for optimised machine processing. However, both must be human and machine readable and translators are a pre-requisite.
== Internal IM languages for IMAPI usage ==
An implementation of the IM as a terminology server or query library exists.


'''Semantic translatability'''
This implementation uses the following mainstream languages


A model presented in the human legible grammar must be translatable directly to the machine representation without loss of semantics. In the ensuing paragraphs the human optimised grammar is illustrated but in the final language specification both are presented side by side to illustrate semantic translatability.
* Java, used as the main logical business end, server side and services the REST APIs used to exchange information with the IM server
* Javscript / TypeScript extension used for business logic that provides UI specific APIs the web applications


=== Human oriented grammar ===
*[https://www.w3.org/TR/sparql11-query/ SPARQL] Used as the logical means of querying model conformant data (not to be confused with the actual query language used which may be SQL). Used as the query language for the IM and mapped from IM Query Health queries would generally use SQL
A language based grammatical approach is taken, with the English language sentence being the basis,  namely the modelling of data via sentences consisting of s''ubject, predicate and object'' in that order. Legibility (and machine parsing) is assisted by ''punctuation.''
*[https://opensearch.org/docs/latest/opensearch/query-dsl/index/ OpenSearch / Elastic.] Used for complex free text query for fining concepts using the AWS OpenSearch DSL (derivative of Lucene Query). Note that simple free text Lucene indexing is supported by the IM database engines and is used in combined graph/text query.
*[[Meta model class specification#Query .2FSet definition|IM Query.]] Not strictly a language but a class definition representing a scheme independent  way of defining sets (query results) including all the main health queries used by clinicians and analysts.


A terse approach is taken to grammar i.e. avoiding ambiguous flowery language. Thus RDF triples form the basis of the model.
== Grammars and syntaxes ==


'''Semantic triples'''
=== Foundation syntaxes - RDF, TURTLE and JSON-LD ===
Discovery language has its own Grammars built on the foundations of the W3C RDF grammars:


Predicates form the basis of semantic interpretation and predicates are used as atomic entities that have identifiers. Predicate identifiers  are recognisably related to their meaning but are given further definition via prose for background. For example a predicate <<nowiki>http://...../dateOfBirth</nowiki>>" is a property that holds a value that is a data of birth. Subjects and objects may also have identifiers which may or may not be meaningful. As subjects and objects operate as nodes, and nodes require edges,  predicates thus assume the role of edges in a graph.
* A terse abbreviated language, TURTLE


To make sense of the language, subjects require constructs that include predicate object lists, object lists, and objects which can themselves subjects defined by predicates. Put together with the terse language requirement, the grammar used in the human oriented language is TURTLE. The following snip illustrates the main TURTLE structures together with the punctuation:
* JSON-LD representation, which can used by systems that prefer JSON (the majority) , and are able to resolve identifiers via the JSON-LD context structure.
<pre style="background-color:#fcfaee">
Subject1
  Predicate1 Object1;
  Predicate2 Object2;                # predicate object list separated by ';'
  Predicate3 (Object3,
              Object4,
              Object5);              #object list enclosed by '()'
  Predicate4 [                        #anonymous object with predicates enclosed []
                Predicate5 Object6;
                Predicate6 Object7
              ]
.                                       # end of sentence


Subject2 Predicate1 Object1.            #Simple triple                   
'''Identifiers, aliasing  prefixes and context'''
</pre>'''Identifiers'''


Nodes and edges (subjects, predicates and objects) may be identified and the identifiers used as references elsewhere.
Concepts are identified and referenced by the use of International resource identifiers (IRIs).  


Identifiers are universal and presented in one of the following forms:
Identifiers are universal and presented in one of the following forms:


# Full IRI (International resource identifier) which is the fully resolved identifier encompassed by <>
# Full IRI (International resource identifier) which is the fully resolved identifier encompassed by <>
# Abbreviated IRI  a Prefix which is resolved to an IRI  followed by the local name which whan appended to the prefix becomes an full IRI
# Abbreviated IRI  a Prefix followed by a ":" followed by  the local name which is resolved  to a full IRI
# Alias. Used by applications that have a close affinity to a particular information model instance, the aliases being mapped to the full IRIs
#Aliases. The core language tokens (that are themselves concepts) have aliases for ease of use. For example rdfs:subClassOf is aliased to subClassOf,
 
UUIDs are not used within the model but of course may be used in instances of data.
 
'''Semantic context'''
 
The interpretation of a structure is often dependent on the preceding predicate. Because the language is semantically constrained to the profiles of the sublanguages, certain punctuations can be semantically interpreted in context. For example, as the language incorporates OWL EL but not OWL DL, Object Intersection (and) is supported but not Object union. In other words, in certain contexts there are ANDS but not ORS.
 
This allows for the use of a collection construct, for example in the following equivalent definitions of a grandfather, in the first example the grandfather is an equivalent to an intersection of a person and someone who is male and has children, and the second one is an intersection of a person, something that is male, and someone that has children. Both interpretations assume AND as the operator because OR is not supported at this point in  OWL EL.
<syntaxhighlight lang="turtle" style="border:3px solid grey">
Grandfather
  isEquivalentTo (                                    #ObjectIntersection
                    Person,                            class 1
                    [                                    #Anonymous class 2
                    hasGender Male;             
                    hasChild (                          #ObjectIntersection
                                Person,                    class 2.1
                              hasChild Person)            class 2.2 
                    ].
 
or Grandfather
  isEquivalentTo (                                    #ObjectIntersection
                    Person,                            class 1
                  hasGender Male,                     #Anonymous class  2
                  hasChild (                          #Object Intersection
                              Person,                    class 3
                              hasChild Person)          #Anonymous class 4
                    ].
</syntaxhighlight>


=== Machine oriented grammar ===
There is of course nothing to stop applications using their own aliases and when used with JSON-LD @context may be used to enable the use of aliases.
JSON is a popular syntax currently and thus this is used as an alternative.


JSON represents subjects , predicates and objects as object names and values with values being either literals or or objects.
JSON itself has no inherent mechanism of differentiating between different types of entities and therefor JSON-LD is used. In JSON-LD identifiers resolve initially to @id and the use of @context enables prefixed IRIs and aliases.
The above  Grandfather can be represented in JSON as follows:<syntaxhighlight lang="json-ld" style="border:3px solid grey">
{"@id" : "Grandfather",
"EquivalentTo" :[{ "@id":"Person"},
                  {"hasGender": {"@id":"Male"}},
                  {"hasChild": [{"@id":"Person"},
                                {"hasChild" : {"@id":"Person"}}]]}}
</syntaxhighlight>Which is equivalent to the version 2 syntax<syntaxhighlight lang="json" line="1" style="border:3px solid grey">
{"iri" : "Grandfather",
"EquivalentTo" :[
    {"Intersection":[
      { "Class": {"iri":"Person"}},
      {"ObjectPropertyValue": {
          "Property": {"iri":"hasGender"},
            "ValueType": {"iri":"Male"}
            }},
      {"ObjectPropertyValue": {
          "Property":{"iri":"hasChild",
            "Expression":{"Intersection":[
              {"Class":{"iri:"Person"}},
              {"ObjectPropertyValue":{
                    "Property":{"iri": hasChild},
                    "ValueType": {"iri":"Person"} } ] } } ]
</syntaxhighlight><br />
== High level aspects of the language ==
=== Concepts ===
Common to all of the language is the modelling abstraction "'''concept",''' which is an ''idea''  that can be defined, or at least described. All classes,  and properties and data types in a model are represented as concrete classes which are subtypes of a concept. In line with semantic web standards a concept is represented in two forms:
When modelled as triples Concepts are used are used as subjects predicates and objects and both atomic and complex concepts called  class expressions are made up of other concepts.
The purpose of modelling concepts as distinct from the various entity types is to group an identifier together a set of annotations which indicate the name, description, status, version and attribution to the authors of the concept. That is all a concept does at this point. Once a concept is defined it can be referenced by a universal identifier if necessary and then the job is done.
The rest of the information model is then about what can be done with a concept and that is where the value comes in.
=== Context ===
Data is considered to be linked across the world, which means that IRIs are the main identifiers. However, IRIs can be unwieldy to use and some of the languages such as GRAPH-QL do not use them. Furthermore, when used in JSON, (the main exchange syntax via APIs) they can cause significant bloat. Also, identifiers  such as codes or terms have often been created for local use in local single systems and in isolation are ambiguous.
Data is considered to be linked across the world, which means that IRIs are the main identifiers. However, IRIs can be unwieldy to use and some of the languages such as GRAPH-QL do not use them. Furthermore, when used in JSON, (the main exchange syntax via APIs) they can cause significant bloat. Also, identifiers  such as codes or terms have often been created for local use in local single systems and in isolation are ambiguous.


Line 215: Line 150:
# MAPPING CONTEXT definitions for system level vocabularies. This provides sufficient context to uniquely identify a local code or term by including details such as the health care provider, the system and the table within a system. In essence a specialised class with the various property values making up the context.
# MAPPING CONTEXT definitions for system level vocabularies. This provides sufficient context to uniquely identify a local code or term by including details such as the health care provider, the system and the table within a system. In essence a specialised class with the various property values making up the context.


=== Sub languages ===
=== OWL2 and RDFS ===
The Discovery language, as a mixed language, has its own grammars as below, but in addition the language sub components can be used in their respective grammars and syntaxes. This enables multiple levels of interoperability, including between specialised community based languages and more general languages.
 
For example, the Snomed-CT community has a specialised language "Expression constraint language" (ECL), which can also be directly mapped to OWL2 and Discovery. Discovery language itself maps to the 4-6 main OWL2  syntaxes as well as ECL.  Each language has it's own nuances ,usually designed to simplify representations of complex structures. 
 
Many sublanguages overlap with others in a way that makes them difficult to translate. For example, in ECL, the reserved word MINUS (used to exclude certain subclasses from a superclass) , maps to the much more obscure OWL2 syntax that requires the modelling of class IRIs "punned" as individual IRIs, in order to properly exclude instances when generating lists of concepts. Very few people can understand the tortuous translation, and in any event the translation is unnecessary as this part of ECL is in effect a query using closed world concepts.
 
In order to eliminate the overlaps, an inclusive language is required.
 
Discovery language has its own Grammars which include:
 
* A terse abbreviated language, similar to Turtle
 
* Proprietary JSON based object serializable grammar. This directly maps to the internal class structures used in Discovery and used by client applications that have a strong contract with a server.
 
* An open standard JSON-LD representation, which can  used by systems that prefer JSON, wish to use standard approaches,  and are able to resolve identifiers via the JSON-LD context structure.
 
Because the information models are accessible via APIs, this means that systems can use any of the above, or exchange information in the specialised standard sublanguages which are:
 
* Expression constraint language (ECL) with its single string syntax
 
* OWL2 EL presented as functional syntax, RDF/XML, Manchester, JSON-LD
 
* SHACL presented as JSON-LD
 
* GRAPHQL presented as JSON-LD (GraphQL-LD)  or GraphQL natively
 
=== Semantic Ontology ===
 
''Supporting article''  [[Discovery semantic ontology language]]
 
The semantic ontology subsumes OWL2 EL.
 
OWL2, like Snomed-CT, forms the log'''ical basis''' for semantic definition and axioms for inferencing .OWL2 subsets of Discovery are available in the Discovery syntaxes or the OWL 2 syntaxes.
 
In its usual use, OWL2 EL is used for reasoning and classification via the use of the [[wikipedia:Open-world_assumption|Open world assumption]]. In effect this means that OWL2 can be used to infer X from Y which forms the basis of most [[Subsumption test|subsumption]] or entailment queries in healthcare.
 
Note. In theory, OWL2 DL can also used to model property domains and ranges so that then may be used as editorial policies.  Where classic OWL2 DL normally models domains of a property in order to infer the class of a certain entity, one can use the same grammar for use in editorial policies i.e. only certain properties are allowed for certain classes. However, this represents a misuse of the OWL grammar i.e. use of the syntax to mean something else. Therefore SHACL is used for editorial policies. 
 
For example, where OWL2 may say that one of the  domains of a causative agent is an allergy (i.e.an unknown class with a property of causative agent is likely to be an allergy), in the modelling the editorial policy states that an allergy ''can only'' have properties that are allowed via the property domain. Thus the Snomed MRCM could be modelled in OWL2 DL. However, the SHACL construct of targetObjectOf and targetSubject Of are used as a constraint.
 
Thus only existential quantification and object Object intersections are use for reasoning. Cardinality is likewise not required. 
 
The ontology in theory supports the OWL2 syntaxes such as the Functional syntax and Manchester syntax, but can be represented by JSON-LD or the Discovery JSON based syntax, as part of the full information modelling language. Of particular value is the Inverse property of axiom as this can then be used when examining data model properties.
 
Together with the query language, OWL2  makes the language compatible also with [https://confluence.ihtsdotools.org/display/DOCECL/Expression+Constraint+Language+-+Specification+and+Guide Expression constraint language] which is used as the standard for specifying Snomed-CT expression query. 
 
The ontologies that are modelled are considered as modular ontologies. it is not expected that one "mega ontology" would be authored but that there would be maximum sharing of concept definitions (known as axioms)  which results in a super ontology of modular ontologies.


=== Data modelling as shapes ===
For the purposes of authoring and reasoning the semantic ontology axiom and class expression vocabulary uses the tokens and structure from the OWL2 profile [https://www.w3.org/TR/owl2-profiles/#OWL_2_EL OWL EL] , which itself is a sublanguage of the [https://www.w3.org/TR/owl2-syntax/ OWL2 language]


Data models , model classes and properties according to business purposes. This is a different approach to the open world assumption of semantic ontologies.
In addition to the open world assumption of OWL, RDFS constructs of domain and ranges (OWL DL) but are are used in a closed word manner as RDFS.


To illustrate the difference, take the modelling of a human being or person.
Within an information model instance itself the data relationships are held on their post inferred closed form i.e. inferred properties and relationships are explicitly stated using a normalisation process to eliminate duplications from super types.  In other words, whereas an ontology may be authored using the open world assumption, prior to population of the live IM, classifications and inheritance are resolved. This uses the same approach as followed by Snomed-CT, whereby the inferred relationship containing the inherited properties and the "isa" relationship are included explicitly.


From a semantic perspective a person being could be said to be an equivalent to an animal with a certain set of DNA (nuclear or mitochondrial) and perhaps including the means of growth or perhaps being defined at some point before, at the start of, or sometime after the embryonic phase. One would normally just state that a person  is an instance of a homo sapiens and that homo sapiens is a species of.... etc. 
In the live IM OWL Axioms are replaced with the RDFS standard terms and simplified. For example OWL existential quantifications are mapped to "role groups" in line with Snomed-CT.


From a data model perspective we may wish to model a record of a person. We could say that a certain shape is "a record of" a person. In SHACL this is referred to as "targetClass". The shape will have one date of birth, one current gender, and perhaps a main residence. Cardinality is expected. 
'''Use of Annotation properties'''


SCHACL is used inherently, although consideration is given to its community cousin Shex.
Annotation properties are the properties that provide information beyond that needed for reasoning.&nbsp; They form no part in the ontological reasoning, but without them, the information model would be impossible for most people to understand.&nbsp;


The difference is between the open and close world and the model of the person is a constraint on the possible (unlimited) properties of a person.  
Typical annotation properties are names and descriptions.
{| class="wikitable"
|+
!Owl construct
!usage examples
!'''IM live conversion'''
|-
|Class
|An entity that is a class concept e.g. A snomed-ct concept or a general concept
|rdfs:Class
|-
|ObjectProperty
|'hasSubject' (an observation '''has a subject''' that is a patient)
|rdf:Property
|-
|DataProperty
|'dateOfBirth'  (a patient record has a date of birth attribute
|owl:dataTypeProperty
|-
|annotationProperty
|'description'  (a concept has a description)
|
|-
|SubClassOf
|Patient is a subclass of a Person
|rdfs:subClassOf
|-
|Equivalent To
|Adverse reaction to Atenolol is equivalent to An adverse reaction to a drug AND has causative agent of Atenolol (substance)
|rdfs:subClassOf
<br />
|-
|Sub property of
|has responsible practitioner is a subproperty of has responsible agent
|rdfs:subPropertyOf
|-
|Property chain
|is sibling of'/ 'is parent of' / 'has parent' is a sub property chain of 'is first cousin of'
|owl:Property chain
|-
|Existential quantification ( ObjectSomeValuesFrom)
|Chest pain and
Finding site of - {some} thoracic structure
|im:roleGroup
|-
|Object Intersection
|Chest pain is equivalent to pain of truncal structure AND finding in region of thorax AND finding site of thoracic structure
|rdfs:Subclass


A particular data model is a particular business oriented perspective on a set of concepts. As there are potentially thousands of different perspectives (e.g. a GP versus a geneticist) there are potentially unlimited number of data models. All the data models modelled in Discovery share the same atomic concepts and same semantic ontological definitions across ontologies where possible, but where not, mapping relationships are used. 
+


The binding of a data model to its property values is based on a business specific model. For example a standard FHIR resource will map directly to the equivalent data model class, property and value set, whose meaning is defined in the semantic ontology, but the same data may be carried in a non FHIR resource without loss of interoperability.
role groups
|-
|DataType definition
|Date time  is a restriction on a string with a regex that allows approximate dates
|
|-
|Property domain
|a property domain of has causative agent is allergic reaction
|rdfs:domain
|-
|Property range
|A property range of has causative agent is a substance
|rdfs:range
|}
{| class="wikitable"
|+
!Annotation
!Meaning
|-
|rdfs:label
|The name or term for an entity
|-
|rdfs:comment
|the description of an entity
|-
|
|
|}


A common approach to modelling and use of a standard approach to ontology, together with modularisation, means that any sending or receiving machine which uses concepts from the semantic ontology can adopt full semantic interoperability. If both machines use the same data model for the same business, the data may presented in the same relationship, but if the two machines use different data models for different businesses they may present the data in different ways, but without any loss of meaning or query capability.  
=== SHACL shapes ===
SHACL is used as a means of specifying the "data model types" of health record entities and also the IM itself as described directly in the [[Information model meta model#Meta model class specification|meta model article]].


'''''The integration between data model shapes and ontological concepts makes the information model very powerful and is the singe most important contributor to semantic interoperability,'''''
SHACL is used in its standard form and is not extended.


=== Data mapping ===
=== OWL extension : data property expressions ===
Within health care, (and in common parlance), data properties are often used as syntactical short cuts to objects with qualifiers  and a literal value element.


This part of the language is used to define mappings between the data model and an actual schema to enable query and filers to automatically cope with the ever extending ontology and data properties.&nbsp;
For example, the data property "Home telephone number" would be expected to simply contain a number. But a home telephone number also has a number of properties by implication, such as the fact that its usage is "home", and has a country and area code.


This is part of the semantic ontology but uses the idea of context (described later on).
OWL 2 has a known limitation (as described in the OWL specification itself) in respect of data property expressions. OWL2 can only define data property expressions as data property IRIs with annotations.  


=== Query ===
In many health care standards such as HL7 FHIR, these data properties are object properties with the objects having the "value" as one of its properties..
It is fair to say that data modelling and semantic ontology is useless without the means of query.


The current approach to the specification of query uses the GRAPHQL approach with type extensions and directive extensions.
For example, in FHIR  the patients home telephone number is carried explicitly as the property contact {property= telecom -> value =  {property use= Home, /property System= coding system,/ value = the actual number } } i.e. 3 ;levels of nesting.


Graph QL , (despite its name) is not in itself a query language but a way of representing the graph like structure of a underlying model that has been built using OWL. GRAPH QL has a very simple class property representation, is ideal for REST APIs and results are JSON objects in line with the approach taken by the above Discovery syntax.  
Whilst explicit modelling is vital for information exchanged between systems with different data models, if stored in this way, queries would underperform, so the actual systems usually store the home telephone number perhaps in  a field "home telephone"  in the patient table or a simple triple.


Nevertheless, GRAPHQL considers properties to be functions (high order logic) and therefore properties can accept parameters. For example, a patient's average systolic blood pressure reading could be considered a property with a single parameter being a list of the last 3 blood pressure readings. Parameters are types and types can be created and extended.
To resolve the bridge between a complex object definition and simple data property the information model supports data property expressions (but without introducing a new language construct() as follows:


In addition GRAPHQL supports the idea of extensions of directives which further extend the grammar.
# Simple data property against the class e.g. a "contact"
# Patient's home telephone number modelled as a ''sub property'' "homeTelephoneNumber with is a sub property of "telephone number", which is itself a sub property of "contact".
# A standard RDFS  property of the homeTelephone property entity - > "isDefinedBy" which points to a class expression which defines a home telephone number, (itself a subclass of a class expression TelephoneNumber) thus allowing all properties values to be "implicit but defined" as part of the ontology.


Thus GRAPHQL capability is extended by enabling property parameters as types to support such things as filtering, sorting and limiting in the same way as an.y other query language by modelling types passed as parameters. Subqueries are then supported in the same way.  
By this technique subsumption queries that look for home contacts or home telephone numbers or find numbers with US country codes will find the relevant field and the relevant sub pattern of a data property..


GRAPHQL itself is used when the enquirer is familiar with the local logical schema i.e. understands the available types and fields. In order to support semantic web concepts an extension to GRAPHQL, GRAPHQL-LD is used, which is essentially GRAPH-QL with JSON-LD context.  
Implementations would still need to parse numbers to properties if they stored numbers as simple numbers but these would be part of a data model map against the IM models definition.


GRAPH QL-LD  has been chosen over SPARQL for reasons of simplicity and many now consider GRAPHQL to be a de-facto standard. However, this is an ongoing consideration.
== Information model meta classes ==
See main article [[Information model meta model|Information model meta classes]]


=== ABAC language ===
Using the above languages this defines the classes used to model all health data.
''Main article : [[Attribute based access control|ABAC Language]]''


The Discovery attribute based access control language is presented as a pragmatic JSON based profile of the XACML language, modified to use the information model query language (SPARQL) to define policy rules. ABAC attributes are defined in the semantic ontology in the same way as all other classes and properties.


The language is used to support some of the data access authorisation processes as described in the specification - [[Identity Authentication Authorisation|Identity, authentication and authorisation]] .


This article specifies the scope of the language , the grammar and the syntax, together with examples. Whilst presented as a JSON syntax, in line with other components of the information modelling language, the syntax can also be accessed via the ABAC xml schema which includes the baseline Information model XSD schema on the Endeavour GitHub, and example content viewed in the information manager data files folder<br />
<br />

Latest revision as of 14:53, 5 January 2023

N.B Not to be confused with the Information model meta model. which specifies the classes that hold the information model data, those classes described using the languages defined below.

This article describes the languages used in the information model meta model. In other words, the underlying grammar and syntax used as the building bricks for the classes that make up the model, instances of those classes being objects that conform to the class properties.

Details on the W3C standard languages that make up the grammar are described below.

In addtion,

If a system can consume RDF in its two main syntaxes (turtle and JSON-LD) then the model can be easily exchanged.

The main advantage of RDF and the W3C standards is that types and properties are given internationally unique identifiers which are both humanly readable and can be resolved via the world wide web protocols.

Thus, in the information model, all classes, properties and value types (subjects and predicates and objects) are IRIs which are defined by ontological techniques.

Contributory languages

Health data can be conceptualised as a graph, and thus the model is a graph model.

As the information model is a graph, and both classes and properties are uniquely identified, RDF is the language used. As the technical community use Json as the main stream syntax for exchanging objects, the preferred syntax for the model classes and properties is JSON-LD, with instances in plain JSON

RDF itself has limited grammar the modelling language uses the main stream semantic web grammars and vocabularies, these being RDFS, OWL and SHACL. Additional vocabularies are added to the IM to accommodate the shortfalls in vocabularies,

In addition the IM accommodates some languages required to use the main health ontology i,e Expression Constraint language and Snomed compositional grammar. Within the IM ECL is modelled as query and Snomed-CT compositional grammar is modelled as a Concept class.

Finally, as a means of bridging the gap between user visualisation of query definitions and the underlying query languages such as SPARQL and SQL, the IM uses a set of classes to model query definitions, using a form that maps directly to SPARQL, SQL, GRAPHQL.

When exchanging models using the language grammar both Json-LD and turtle are supported as well as the more specialised syntaxes such as owl functional syntax or expression constraint language.

The modelling language is an amalgam of the following languages:

  • RDF. An information model can be modelled as a Graph i.e. a set of nodes and edges (nodes and relationships, nodes and properties). Likewise, health data can be modelled as a graph conforming to the information model graph. RDF Forms the statements describing the data. RDF in itself holds no semantics whatsoever. i.e. it is not practical to infer or validate or query based purely on an RDF structure. To use RDF it is necessary to provide semantic definitions for certain predicates and adopt certain conventions. In providing those semantic definitions, the predicates themselves can then be used to semantically define many other things. RDF can be represented using either TURTLE syntax or JSON-LD.
  • RDFS. This is the first of the semantic languages. It is used for the purposes of some of the ontology axioms such as subclasses, domains and ranges as well as the standard annotation properties such as 'label
  • SHACL. For the data models of types. Used for everything that defines the shape of data or logical entities and attributes. Although SHACL is designed for validation of RDF, as SHACL describes what things 'should be' it can be used as a data modelling language
  • OWL2 DL. This is supported in the authoring phase, but is simplified within the model. This brings with it more sophisticated description logic such as equivalent classes and existential quantifications ,and is used in the ontology and for defining things when an open world assumption is required. This has contributed to the design of the IM languages but OWL is removed in the run time models with class expressions being replaced by RDFS subclass, and role groups.
  • ECL. This is a specialised query language created for Snomed-CT, used for simple concepts modelled as subtypes, role groups and roles, and is of great value in defining sets of concepts for the myriad of business purposes used in health.
  • SCG. Snomed compositional grammar, created for Snomed-CT, which is a concise syntax for representing simple concepts modelled as subtypes. role groups and roles and is a way of displaying concept definitions.


Example multiple syntaxes and grammars

Consider a definition of chest pain in several syntaxes. Note that the OWL definition is in a form prior to classification whereas the others use the post classified structure (so called inferred)

Chest pain in Manchester syntax, SCG, ECL, OWL FS, IM Json-LD: 

# Definition of Chest pain in owl Manchester Syntax
 equivalentTo  sn:298705000 and sn:301366005 and (sn:363698007 sn:51185008)

#In RDF turtle
sn:29857009
   rdfs:subClassOf 
         sn:301366005 , 
         sn:298705000;
   im:roleGroup [im:groupNumber "1"^^xsd:integer;
   sn:363698007 sn:51185008];
   rdfs:label "Chest pain (finding)" .


# In Snomed compositional grammar
=== 298705000 |Finding of region of thorax (finding)| + 
    301366005 |Pain of truncal structure (finding)| :
            { 363698007 |Finding site (attribute)| = 51185008 |Thoracic structure (body structure)| }

# When using ECL to retrieve chest pain
<<298705000 |Finding of region of thorax (finding)| and 
    (<<301366005 |Pain of truncal structure (finding)| :
            { 363698007 |Finding site (attribute)| = 51185008 |Thoracic structure (body structure)| })


#When used in OL functional syntax
EquivalentClasses(
	:29857009 |Chest pain (finding)|
	ObjectIntersectionOf(
		:22253000 |Pain (finding)|
		ObjectSomeValuesFrom(
			:609096000 |Role group (attribute)|
			ObjectSomeValuesFrom(
				:363698007 |Finding site (attribute)|
				:51185008 |Thoracic structure (body structure)|
			)
		)
	)
)
# In Json-LD

{
  "@id" : "sct:29857009",
  "rdfs:label" : "Chest pain (finding)",
  "im:definitionalStatus" : {"@id" : "im:1251000252106","name" : "Concept definition is sufficient (equivalent status)"},
  "rdfs:subClassOf" : [ {
    "@id" : "sct:301366005",
    "name" : "Pain of truncal structure (finding)"
  }, {
    "@id" : "sct:298705000",
    "name" : "Finding of region of thorax (finding)"
  } ],
  "im:roleGroup" : [ {
    "im:groupNumber" : 1,
    "sct:363698007" : [ {
      "@id" : "sct:51185008",
      "name" : "Thoracic structure (body structure)"
    } ]
  } ]
}
 

Internal IM languages for IMAPI usage

An implementation of the IM as a terminology server or query library exists.

This implementation uses the following mainstream languages

  • Java, used as the main logical business end, server side and services the REST APIs used to exchange information with the IM server
  • Javscript / TypeScript extension used for business logic that provides UI specific APIs the web applications
  • SPARQL Used as the logical means of querying model conformant data (not to be confused with the actual query language used which may be SQL). Used as the query language for the IM and mapped from IM Query Health queries would generally use SQL
  • OpenSearch / Elastic. Used for complex free text query for fining concepts using the AWS OpenSearch DSL (derivative of Lucene Query). Note that simple free text Lucene indexing is supported by the IM database engines and is used in combined graph/text query.
  • IM Query. Not strictly a language but a class definition representing a scheme independent way of defining sets (query results) including all the main health queries used by clinicians and analysts.

Grammars and syntaxes

Foundation syntaxes - RDF, TURTLE and JSON-LD

Discovery language has its own Grammars built on the foundations of the W3C RDF grammars:

  • A terse abbreviated language, TURTLE
  • JSON-LD representation, which can used by systems that prefer JSON (the majority) , and are able to resolve identifiers via the JSON-LD context structure.

Identifiers, aliasing prefixes and context

Concepts are identified and referenced by the use of International resource identifiers (IRIs).

Identifiers are universal and presented in one of the following forms:

  1. Full IRI (International resource identifier) which is the fully resolved identifier encompassed by <>
  2. Abbreviated IRI a Prefix followed by a ":" followed by the local name which is resolved to a full IRI
  3. Aliases. The core language tokens (that are themselves concepts) have aliases for ease of use. For example rdfs:subClassOf is aliased to subClassOf,

There is of course nothing to stop applications using their own aliases and when used with JSON-LD @context may be used to enable the use of aliases.

Data is considered to be linked across the world, which means that IRIs are the main identifiers. However, IRIs can be unwieldy to use and some of the languages such as GRAPH-QL do not use them. Furthermore, when used in JSON, (the main exchange syntax via APIs) they can cause significant bloat. Also, identifiers such as codes or terms have often been created for local use in local single systems and in isolation are ambiguous.

To create linked data from local identifiers or vocabulary, the concept of Context is applied. The main form of context in use are:

  1. PREFIX declaration for IRIs, which enable the use of abbreviated IRIs. This approach is used in OWL, RDF turtle, SHACL and Discovery itself.
  2. VOCABULAR CONTEXT declaration for both IRIs and other tokens. This approach is used in JSON-LD which converts local JSON properties and objects into linked data identifiers via the @context keyword. This enables applications that know their context to use simple identifiers such as aliases.
  3. MAPPING CONTEXT definitions for system level vocabularies. This provides sufficient context to uniquely identify a local code or term by including details such as the health care provider, the system and the table within a system. In essence a specialised class with the various property values making up the context.

OWL2 and RDFS

For the purposes of authoring and reasoning the semantic ontology axiom and class expression vocabulary uses the tokens and structure from the OWL2 profile OWL EL , which itself is a sublanguage of the OWL2 language

In addition to the open world assumption of OWL, RDFS constructs of domain and ranges (OWL DL) but are are used in a closed word manner as RDFS.

Within an information model instance itself the data relationships are held on their post inferred closed form i.e. inferred properties and relationships are explicitly stated using a normalisation process to eliminate duplications from super types. In other words, whereas an ontology may be authored using the open world assumption, prior to population of the live IM, classifications and inheritance are resolved. This uses the same approach as followed by Snomed-CT, whereby the inferred relationship containing the inherited properties and the "isa" relationship are included explicitly.

In the live IM OWL Axioms are replaced with the RDFS standard terms and simplified. For example OWL existential quantifications are mapped to "role groups" in line with Snomed-CT.

Use of Annotation properties

Annotation properties are the properties that provide information beyond that needed for reasoning.  They form no part in the ontological reasoning, but without them, the information model would be impossible for most people to understand. 

Typical annotation properties are names and descriptions.

Owl construct usage examples IM live conversion
Class An entity that is a class concept e.g. A snomed-ct concept or a general concept rdfs:Class
ObjectProperty 'hasSubject' (an observation has a subject that is a patient) rdf:Property
DataProperty 'dateOfBirth' (a patient record has a date of birth attribute owl:dataTypeProperty
annotationProperty 'description' (a concept has a description)
SubClassOf Patient is a subclass of a Person rdfs:subClassOf
Equivalent To Adverse reaction to Atenolol is equivalent to An adverse reaction to a drug AND has causative agent of Atenolol (substance) rdfs:subClassOf


Sub property of has responsible practitioner is a subproperty of has responsible agent rdfs:subPropertyOf
Property chain is sibling of'/ 'is parent of' / 'has parent' is a sub property chain of 'is first cousin of' owl:Property chain
Existential quantification ( ObjectSomeValuesFrom) Chest pain and

Finding site of - {some} thoracic structure

im:roleGroup
Object Intersection Chest pain is equivalent to pain of truncal structure AND finding in region of thorax AND finding site of thoracic structure rdfs:Subclass

+

role groups

DataType definition Date time is a restriction on a string with a regex that allows approximate dates
Property domain a property domain of has causative agent is allergic reaction rdfs:domain
Property range A property range of has causative agent is a substance rdfs:range
Annotation Meaning
rdfs:label The name or term for an entity
rdfs:comment the description of an entity

SHACL shapes

SHACL is used as a means of specifying the "data model types" of health record entities and also the IM itself as described directly in the meta model article.

SHACL is used in its standard form and is not extended.

OWL extension : data property expressions

Within health care, (and in common parlance), data properties are often used as syntactical short cuts to objects with qualifiers and a literal value element.

For example, the data property "Home telephone number" would be expected to simply contain a number. But a home telephone number also has a number of properties by implication, such as the fact that its usage is "home", and has a country and area code.

OWL 2 has a known limitation (as described in the OWL specification itself) in respect of data property expressions. OWL2 can only define data property expressions as data property IRIs with annotations.

In many health care standards such as HL7 FHIR, these data properties are object properties with the objects having the "value" as one of its properties..

For example, in FHIR the patients home telephone number is carried explicitly as the property contact {property= telecom -> value = {property use= Home, /property System= coding system,/ value = the actual number } } i.e. 3 ;levels of nesting.

Whilst explicit modelling is vital for information exchanged between systems with different data models, if stored in this way, queries would underperform, so the actual systems usually store the home telephone number perhaps in a field "home telephone" in the patient table or a simple triple.

To resolve the bridge between a complex object definition and simple data property the information model supports data property expressions (but without introducing a new language construct() as follows:

  1. Simple data property against the class e.g. a "contact"
  2. Patient's home telephone number modelled as a sub property "homeTelephoneNumber with is a sub property of "telephone number", which is itself a sub property of "contact".
  3. A standard RDFS property of the homeTelephone property entity - > "isDefinedBy" which points to a class expression which defines a home telephone number, (itself a subclass of a class expression TelephoneNumber) thus allowing all properties values to be "implicit but defined" as part of the ontology.

By this technique subsumption queries that look for home contacts or home telephone numbers or find numbers with US country codes will find the relevant field and the relevant sub pattern of a data property..

Implementations would still need to parse numbers to properties if they stored numbers as simple numbers but these would be part of a data model map against the IM models definition.

Information model meta classes

See main article Information model meta classes

Using the above languages this defines the classes used to model all health data.



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