FHIR:Vprepub-1.0 FHIR Profiling Guidelines R4: verschil tussen versies
(Added copyright text) |
(→Slicing: Initial addition of Slicing guidelines) |
||
Regel 155: | Regel 155: | ||
=Slicing= | =Slicing= | ||
+ | Elements are sliced to specify different sets of requirements for repeating elements and to allow reusability. | ||
+ | Slicing occurs on the highest level possible, e.g. a {{fhir|CodeableConcept}} versus {{fhir|Coding}}. In general, the slice discriminator is set to {{fhir|discriminator.type}} = 'value' and {{fhir|discriminator.path}} = '$this'. The sliced element gets a {{fhir| pattern[x]}} or a required ValueSet binding on it's root. This applies to the following situations. | ||
+ | * [[#Mapping_semantic_codes_to_profiles|Mapping semantic codes to profiles]] require the presence of the semantic code while leaving the option to provide additional codes. | ||
+ | * A concept has two or more ValueSets. These will be bound with a required binding strength to a slice. An example is the multiple medication ValueSets that are defined for {{fhir|Medication.code}}. | ||
+ | ** For validation performance reasons a {{fhir| pattern[x]}} can be used that fixes the {{fhir| system}} if the ValueSets can be differentiated on a single code system. | ||
+ | * Identifier systems are always defined on a sliced {{fhir| Identifier}}, even if there is only one defined, to allow reuse of the {{fhir| Identifier}}. | ||
+ | * On some occasions, both a semantic code and a concept is mapped to the same element. This is usually a metadata element such as a category element which requires slicing: one slice for the fixed code and one for the concept. | ||
+ | |||
+ | Other forms of slicing that are common,(Forge sets these slicing details by default): | ||
+ | * A concept is mapped to one or multiple types of a polymorphic element, e.g. {{fhir|Observation.value[x]}}. The mapping and functional description are placed on the slice with the matching data type(s). | ||
+ | * Adding an extension slices the {{fhir|extension}} element that is discriminated by the value on {{fhir|extension.url}}. | ||
=Open vs. closed world modeling= | =Open vs. closed world modeling= |
Versie van 14 dec 2020 15:14
Introduction
This page lays out the conventions for creating FHIR profiles and associated conformance resources within Nictiz. These guidelines are specifically aimed at FHIR R4; for the STU3 profiling work, a separate document exists.
This page is titled "profiling guidelines", but actually addresses all conformance resources (profiles, extensions, value sets, CapabilityStatements) and associated examples. We use these terms somewhat interchangeable throughout this document; 'profile' can usually be read as 'the whole set of conformance resources'.
Versioning
Conformance resources are versioned on multiple levels:
- The version of the underlying data model.
- The FHIR Version (
StructureDefinition.fhirVersion
): this document is specifically aimed at FHIR R4, meaning this element will be fixed on 4.x. - The version of the conformance resource (
StructureDefinition.version
): used to indicate the business version to the user, without strict specifications. - The version of the package the conformance resources reside in: versioned according to SemVer 2.0.
For consistency and manageability reasons, the version of the conformance resources are inherited from the version number of the package. This means that all of the conformance resources get a new version number whenever a new package version is released, even if they aren't changed.
The life cycle of the underlying data model is reflected only indirectly in the versioning of conformance resources. The normal SemVer rules determine how a new release of the underlying data model should be handled; if it doesn't affect the conformance resources, nothing should be done, if it affects them in a backwards compatible way, a new patch release should be made, etc. If a new version of the underlying data model reflects a fundamental change, the choice can be made to create a completely new package.
Version updates of conformance resources normally do not affect the canonical URI. Any resource that references another resource normally does so without a version indicator (uri|version
). Instead, this is handled at the package level; reference targets either reside within the same package or in a versioned package that has been added as a dependency.
Functional model as specification
Most, if not all, conformance resources are based on an underlying functional model. The functional model is the specification to which the conformance resources should adhere.
The basis for most other functional models is formed by the 'zibs' ('Zorginformatiebouwstenen'), in English also known as are Clinical Information Models (CIMs), Health and Care Information Models (HCIMs) or Clinical Building Blocks (CBB) -- we will use the Dutch term 'zib' for all profiling work as it has become a recognizable term over the past years. The zibs are defined by the program ‘Registratie aan de bron’ (Data capture at the point of care) and provide a foundation of use case neutral building blocks from which use cases can be built. The formal definition of the zibs can be found on the zibs wiki
Use cases or information standards use and refine those zibs that are relevant to the situation. The formal specification for these information standards can usually be found in Nictiz' instance of ART-DECOR.
Zibs, information standard specific profiles and uniprofiles
The profiles and other conformance resources align to this layering of information standards. We recognize three levels of profiles:
- zib profiles
- profiles that represent the zib as faithful as possible
- uniprofiles
- derived profiles from the zib profiles that form a 'union' of the uses case specific elements for all use cases that use a certain zib.
- information standard specific profiles
- derived profiles from the uniprofiles that further restrict or enhance the unionprofiles for a specific use case.
Identity of artifacts
Canonical URL, id, name and title
Conformance resources can have multiple types of identifying information, which are related at some level:
StructureDefinition.url
- The canonical URL, which is the external identifier for conformance resources. All conformance resources SHALL have a canonical URL. This URL is preferably resolvable but does not have to be processable. Canonical URL's are about the identity of artifacts, not necessarily about retrieval location. Canonical URLs aren't meant to be human recognizable.
StructureDefintion.id
- This should align with the latter part of the canonical URL.
StructureDefintion.name
- A recognizable name that is still computer processable.
StructureDefintion.title
- A recognizable title purely for human consumption.
URIs for the latter (for artifacts living in ART-DECOR) are described in ART-DECOR FHIR_URIs.
Profiles and extensions
- The id will be constructed in the following way:
- For profiles:
- zib profiles:
zib-[English zib name]
- uniprofiles:
uni-[English zib name]
- standard specific:
[project prefix]-[concept name]
- zib profiles:
- For extensions:
- pertaining to 1 profile:
[profile id]-[English concept name]
- pertaining to multiple profiles, or not pertaining to specific profiles and generally applicable:
- if the use context is a single resource:
[resource]-[purpose]
- otherwise:
[purpose]
- if the use context is a single resource:
- pertaining to 1 profile:
- For profiles:
- The canonical URL will then be created as:
http://nictiz.nl/fhir/4.0/StructureDefintion/[id]
- The name will be the
.id
capitalized, with hyphens removed. - The title will generally be the
.id
with hyphens replaced by spaces.
Where:
[project prefix]
is preferably the same as its matching ART-DECOR project prefix[purpose]
is generally a camelCased name starting with a lowercase letter
ValueSets
- For value sets as specified on ART-DECOR, the id will be:
[value set OID]--[effective date as yyyymmddhhmmss]
- The canonical URL will then be created as:
http://decor.nictiz.nl/fhir/4.0/ValueSet/[id]
- Both the name and title will be name of the value set (usually in Dutch).
ConceptMaps
- The id will be constructed as:
[source ValueSet.name]-to-[target ValueSet.name]
- The canonical URL will then be:
http://nictiz.nl/fhir/4.0/ConceptMap/[id]
- The name will be constructed as:
[source ValueSet.name]_to_[target ValueSet.name]
- The title will be constructed as:
[source ValueSet.name] to [target ValueSet.name]
Folder structure and file name
- profiles
resources/[id].xml
- extensions
resources/extension-[id].xml
- valuesets
resources/terminology/[name]-[id].xml
- conceptmaps
resources/terminology/conceptmap-[id].xml
- examples
examples/[profile id]-[serial number, two digits].xml
Metadata of StructureDefinitions
- version: see #Versioning
- status: as applicable (normally draft or active)
- publisher: Nictiz
- contact:
- name: Nictiz
- telecom:
- system: email
- value: info@nictiz.nl
- use: work
- description:
- For profiles:
- For zib profiles: the 'Concept' section from the zib.
- For uniprofiles: TBD
- For standard specific profiles: TBD
- For extensions:
- A description of what the extension is for.
- For profiles:
- purpose:
- For profiles:
- For zib profiles:
This [enter resource type] resource represents the Dutch [zib ('Zorginformatiebouwsteen', i.e. Health and Care Information Model) [English zib name] [version]([release])]([link to the English zib page on zibs.nl]).
- For uniprofiles:
A derived profile from [[id of zib profile]]([canonical of zib profile]) to provide a version better suited for implementation purposes. This profile augments the base profile with common elements found in the various use cases that have adopted the zib.
- For standard specific profiles: A description with a reference to the base profile, with an explanation of why it has been added.
- For zib profiles:
- For extensions:
- For extension representing a specific concept:
This extension represents the [concept name] of ..., followed by a link to the functional description.
- For other extensions this will likely be absent.
- For extension representing a specific concept:
- For profiles:
- copyright: Copyright and related rights waived via CC0, https://creativecommons.org/publicdomain/zero/1.0/. This does not apply to information from third parties, for example a medical terminology system. The implementer alone is responsible for identifying and obtaining any necessary licenses or authorizations to utilize third party IP in connection with the specification or otherwise.
- mapping: see #Associating_functional_definition_to_StructureDefinition)
- abstract: usually false, but may be set to true when this profile is to be used only as a base profile from which other profiles should be derived.
- comment on the root element: when special guidance on the use of this profile is needed, it will be placed here. For example: when this profile has a (non-trivial) relationship to other profiles, when a concept of the functional description is mapped over multiple elements, etc.
Associating the functional definition to StructureDefinitions
Any StructureDefinition that profiles a Resource does so because there is some kind of logical definition dictating how. Profiles SHALL have a traceable relationship with their functional counterpart(s).
The FHIR specification contains several solutions for this problem, ConceptMap (>=STU1), StructureMap (>=STU3), ElementDefinition.mapping. Neither of these solutions are mature and cover our use case.
- ConceptMap: works best for value sets and codes.
- StructureMap: overcomplicated and unclear how to apply and whether or not this has a future.
- ElementDefinition.mapping: is a free text mapping inside the profile. This means we cannot add mappings to profiles from third parties without updating their resource.
Current implementation
We use the mapping elements in profiles to map functional elements to resource elements. Functional elements are referenced based on their id in the functional model. The mapping shall resolve to a description of the functional model. For zibs, this should be the English page on zibs.nl.
When slicing, the mapping is made on the content of the slice, not the slice itself (see also #Placing-Info).
On the root element of the StructureDefinition, the mapping should thus be defined as:
<mapping>
<identity value="zib-medicationagreement-v1.2-2020EN" />
<uri value="https://zibs.nl/wiki/MedicationAgreement-v1.2(2020EN)" />
<name value="zib MedicationAgreement-v1.2(2020EN)" />
</mapping>
A specific element can then be mapped using:
<element id="MedicationRequest.extension:usageDuration">
<path value="MedicationRequest.extension" />
<mapping>
<identity value="zib-medicationagreement-v1.2-2020EN" />
<map value="NL-CM:9.6.19936" />
<comment value="PeriodOfUse" />
</mapping>
</element>
Mapping semantic codes to profiles
Oftentimes a functional concept has an equivalent FHIR element, e.g. a 'comment' in the functional description maps in FHIR to the Resource.comment
element. When this is not the case, a code (usually SNOMED or LOINC) is needed to add the proper definition to the FHIR resource, usually using the Resource.code
element. For example, the root concept of an Observation is unknown unless it is defined by the .code
element, and when components are used in an Observation, each Observation.component
needs to be defined using an individual .code
element.
These codes should be provided by the functional description (for zibs this is the DefinitionCode). These codes are profiled as required elements.
Slicing
Elements are sliced to specify different sets of requirements for repeating elements and to allow reusability.
Slicing occurs on the highest level possible, e.g. a CodeableConcept
versus Coding
. In general, the slice discriminator is set to discriminator.type
= 'value' and discriminator.path
= '$this'. The sliced element gets a pattern[x]
or a required ValueSet binding on it's root. This applies to the following situations.
- Mapping semantic codes to profiles require the presence of the semantic code while leaving the option to provide additional codes.
- A concept has two or more ValueSets. These will be bound with a required binding strength to a slice. An example is the multiple medication ValueSets that are defined for
Medication.code
.- For validation performance reasons a
pattern[x]
can be used that fixes thesystem
if the ValueSets can be differentiated on a single code system.
- For validation performance reasons a
- Identifier systems are always defined on a sliced
Identifier
, even if there is only one defined, to allow reuse of theIdentifier
. - On some occasions, both a semantic code and a concept is mapped to the same element. This is usually a metadata element such as a category element which requires slicing: one slice for the fixed code and one for the concept.
Other forms of slicing that are common,(Forge sets these slicing details by default):
- A concept is mapped to one or multiple types of a polymorphic element, e.g.
Observation.value[x]
. The mapping and functional description are placed on the slice with the matching data type(s). - Adding an extension slices the
extension
element that is discriminated by the value onextension.url
.
Open vs. closed world modeling
When profiling, an "open world" or a "closed world" model can be chosen. The former means that the profile only allows the elements to be used specified by the functional model, with all the restrictions from the functional model. The latter means that the profile can accommodate the elements specified by the functional model, but doesn't impose further restrictions.
We adopt the "open world" modeling approach to aid re-usability beyond the known use cases. When restrictions are deemed necessary for a specific use case, it will be added to the information standard specific profiles.
× | Open | Closed |
---|---|---|
Pros |
|
|
Cons |
|
|
General guidelines for open world modeling
We only profile elements, cardinalities and bindings that require profiling. We leave other elements, cardinalities and bindings as-is.
Cardinality
The functional description will specify the cardinality for each concept as a minimum required and maximum allowed number of times it may occur, which is the same mechanism as in FHIR. However, one needs to be careful as the cardinality can only be restricted in derived profiles, and never widened. Being too strict could thus hinder the re-use of these profiles. This is especially true for cardinalities in zibs, which should be interpreted as 'purely conceptual'; a use case might allow for data that conceptually always should be there to be absent in practice.
- For zib profiles:
- A minimum of 0 or 1 will be profiled as 0.
- A maximum (1, n, *) will be profiled as-is.
For uniprofiles:
- No further restrictions are added, as these profiles only cover the currently known use cases. Adding restrictions here would hinder as yet unknown of undefined use cases.
For information standard specific profiles:
- If the corresponding zib has a minimum of 1 and the use case doesn't contradict this, the minimum will be profiled here as 1.
- Cardinalities may be further restricted if the use case defines this.
Constraining references
Concepts in a functional description oftentimes refer to each other; e.g. most clinical concepts will refer to the concept of a Patient. In FHIR these connections are realized using the reference datatype, which allow to specify the target (base resource of profile) as well. For example, a profile representing the zib Problem could set the target of the .subject
element to the profile representing the zib Patient.
However, setting the target explicitly means a restriction of the allowed targets, which runs counter to the principles of open world modelling. On the other hand, specifying a dedicated profile provides useful guidance on how to handle this profile. To address both concerns, only the targets that are defined explicitly in the functional model are constrained, while other targets are left alone. For example, the Condition resource allows both Patient and Group as target in the .subject
element. When profiling the zib Problem, the Patient target will be restricted to the profile representing the zib Patient, but the Group target is left as-is.
Miscellaneous
- For elements that map to zibs:
- The English name from the zib concept is placed on
(in elements that refer to other zibs, the name is built up like <<ElementName::ReferenceZibName>>, but we only use the part before the double colons)
- The zib concept description is placed on
element.definition
- The Dutch zib concept name is placed on
element.alias
- Note: as a rule of thumb, info is placed 'as close as possible' to the elements that actually represent the data. For example: when slicing, the texts are placed on the slice content, not the slice itself. Similarly, in concept containers like
Observation.component
, this info is placed on the .valueXXX elements. This is also true for the zib mappings.
- The English name from the zib concept is placed on
- Slices get a lowerCamelCased name based on the zib element name.
- New elements defined through extensions get a lowerCamelCased name based on the zib element name.
- When adding invariants we use "zib-[zib-name]-[number]" as a key. Example: zib-alert-1
- For FHIR base resource elements with datatype code and binding required it may be that the functional description uses other/additional codes to specialize the FHIR codes. To conform to FHIR and the functional description:
- The ValueSet from the functional description will be bound extensible using the code-specification extension. The extension slice is named after the full English name of the value set according to the functional description.
- Mapping to the concepts of the functional description is applied both to FHIR element and the extension.
- The mapping will be documented in a ConceptMap, which will be linked using the extension permitted-value-conceptmap extension.
- Inline examples in profiles are added (only) when the usage of an element in the profile is not trivial.
Data type mapping
In most cases, the mapping between ART-DECOR, zib and FHIR datatypes is straightforward, though there are a number of cases which are not as clear-cut. The table below shows how datatypes from the functional models should be mapped to FHIR.
ART-DECOR | zib | FHIR | Remarks |
---|---|---|---|
count | INT | Count or integer | Count in FHIR is derived from Quantity. This is appropriate for observations, such as a count of red blood cells in a specimen. Count in FHIR is a Quantity with system set to http://unitsofmeasure.org and code set to 1 (for units). If this is not appropriate, use integer.
|
boolean | BL | boolean | |
blob | ED | base64Binary | |
code | CD | CodeableConcept or coding or code | In general, CodeableConcept will be the right choice. See Using Codes in Resources for details. |
complex | ANY | BackboneElement | 'complex' is data which is not further defined in DECOR, and thus cannot be translated. |
currency | - | Money | Does not have a zib counterpart currenty. Theoretically this could be MO |
date | - | date | Does not have a zib counterpart currently. Closest counterpart could be TS |
datetime | TS | dateTime | |
decimal | - | decimal | Does not have a zib counterpart currently. Theoeratically this could be REAL |
duration | - | Duration | Does not have a zib counterpart currently. Closest counterpart could be PQ |
identifier | II | Identifier | |
ordinal | CO | CodeableConcept or coding or code | See Using Codes in Resources for details. |
string | ST | string | |
ratio | - | Ratio | Does not have a zib counterpart currently. Closest counterpart could be RTO |
text | - | string | Does not have a zib counterpart currently. |
quantity | PQ | Quantity |