EN 17632-2 Building Information Modelling (BIM) - Semantic Modelling and Linking (SML), Part 2: Domain-specific modelling patterns

This document, EN 17632-2, provides semantic modelling patterns for (at least) the following asset aspects:
•   Support for distinction between spatial regions and real (“tangible”) objects; the latter being discrete or continuous (“bulk matter”);
•   Support for the materialization of physical objects, adding generic chemistry aspects directly relevant for the built environment dealing with concrete, steel and asphalt;
•   Support for the interaction between objects including connections, interfaces and ports (parts of objects where such interaction can take place). Interaction being defined as activities where material, information, energy/forces are transferred;
•   Support for the definition of requirements, unstructured and structured, coming from client needs, laws and regulations or sector recommendations;
•   Support for implicit groups having no explicit members (to model situations like “all main girders of some steel bridge”);
•   Support for the explicit modelling of measurements reusing the existing W3C Semantic Sensor Network (SSN)/Sensor, Observation, Sample, and Actuator (SOSA) ontology, incl. extended QUDT support.
•   Support for geospatial geometry (GeoSPARQL/wgs84)
These patterns are currently inspired by NEN 2660-2 (that is itself finalized and tested in practice in parallel). These modelling patterns can all be positioned in the global modelling framework already provided in the form of the top level taxonomy by Part 1.
Some of the information needs might be resolved by extending existing language level constructs. Finally there is a lot of ‘pattern potential’ under ‘Discrete Object’  and ‘Spatial Region’ in the built environment (road network, tunnel, bridge, road, building, installations). Care will be taken not to cross existing standards boundaries (like for open BIM and GIS).

Gebäudeinformationsmodellierung - Semantische Modellierung und Verknüpfungs, Teil 2: domänenspezifische Modellierungsmuster

Dieser Teil2 stellt erweiterte semantische Modellierungsmuster für (mindestens) die folgenden domänenspe
zifischen Asset-Aspekte bereit:

Unterstützung der Unterscheidung zwischen zwei Subtypen von physischen Objekten: räumliche Regionen und reale („greifbare“) Objekte; letztere können diskret oder dauerhaft sein („Masse“);

Unterstützung bei der Materialisierung von physischen Objekten durch Hinzufügen von generischen che
mischen Aspekten, die für die gebaute Umwelt direkt relevant sind und Materialien wie Beton, Stahl, Holz und Asphalt betreffen;

Unterstützung für die Interaktion zwischen Objekten, einschließlich Verbindungen, Schnittstellen und Anschlüssen. Interaktionen werden als Aktivitäten definiert, bei denen Material, Informationen, Energie oder Kräfte übertragen werden;

Unterstützung bei der Definition unstrukturierter, von Menschen interpretierbarer Anforderungen, die sich aus den Bedürfnissen der Informationsbesteller, Gesetzen und Vorschriften oder Branchenempfeh
lungen ergeben;

Unterstützung für implizite Gruppen, die keine expliziten Mitglieder haben (zur Modellierung von Situa
tionen wie „alle Hauptträger einer Stahlbrücke“);

Unterstützung für die explizite Modellierung von Messungen unter Wiederverwendung der bestehenden W3C-SOSA-Ontologie (als einfache, aber in sich geschlossene SSN-Kern-Ontologie).

Unterstützung für räumliche Geometrie (Ort/Form) unter Wiederverwendung von OGCGeoSPARQL (GML/WKT) und der Ontologie WGS84_pos (GPS).
Diese Modellierungsmuster (unten fett gedruckt dargestellt) können alle in den globalen Modellierungsrah
men eingeordnet werden, der in Form einer Taxonomie von Teil1 bereitgestellt wird. Diese Blattkonzepte
den das primäre Inhaltsverzeichnis dieses Teils2.

Modélisation des informations du bâtiment (BIM) - Modélisation sémantique et liaison (SML), Partie 2 : modèles de modélisation spécifiques à un domaine

La partie 2 fournit les schémas de modélisation sémantique étendus pour (au moins) les aspects suivants des actifs spécifiques à un domaine :
— prise en charge de la distinction entre deux sous-types d'objets physiques : régions spatiales et objets réels (« tangibles ») ; ces derniers étant discrets ou continus (« matière en vrac ») ;
— prise en charge de la composition des objets physiques, en ajoutant des aspects génériques de chimie qui concernent directement l'environnement bâti et concernent des matériaux tels que le béton, l'acier, le bois et l'asphalte ;
— prise en charge de l'interaction entre les objets, notamment les connexions, les interfaces et les ports ; les interactions étant définies comme des activités au cours desquelles se produit un transfert de matière, d'information, d'énergie ou de forces ;
— prise en charge de la définition d'exigences non structurées interprétables par l'homme, provenant des besoins de la partie désignante, des lois et réglementations ou des recommandations du secteur ;
— prise en charge des groupes implicites n'ayant pas de membres explicites (afin de modéliser des situations telles que « toutes les poutres principales d'un pont d'acier ») ;
— prise en charge de la modélisation explicite des mesures en réutilisant l'ontologie W3C SOSA existante (en tant qu'ontologie centrale SSN légère mais autonome) ;
— prise en charge de la géométrie spatiale (localisation/forme) en réutilisant le schéma GeoSPARQL (GML/WKT) de l'OGC et l'ontologie WGS84_pos (GPS).
Ces schémas de modélisation (en gras ci-dessous) peuvent tous être situés dans le cadre général de modélisation fourni sous la forme d'une taxonomie par la partie 1. Ces concepts « sans descendance » constituent la table des matières principale de la partie 2.

Informacijsko modeliranje gradenj (BIM) - Semantični standard za modeliranje in povezovanje (SML) - 2. del: Domensko specifični vzorci modeliranja

General Information

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Public Enquiry End Date
13-Jul-2023
Current Stage
4020 - Public enquire (PE) (Adopted Project)
Start Date
05-Jun-2023
Due Date
23-Oct-2023

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SLOVENSKI STANDARD
oSIST prEN 17632-2:2023
01-julij-2023
Informacijsko modeliranje gradenj (BIM) - Semantični standard za modeliranje in
povezovanje (SML) - 2. del: Domensko specifični vzorci modeliranja
EN 17632-2 Building Information Modelling (BIM) - Semantic Modelling and Linking
(SML), Part 2: Domain-specific modelling patterns
Gebäudeinformationsmodellierung - Semantische Modellierung und Verknüpfungs, Teil
2: domänenspezifische Modellierungsmuster
Modélisation des informations du bâtiment (BIM) - Modélisation sémantique et liaison
(SML), Partie 2 : modèles de modélisation spécifiques à un domaine
Ta slovenski standard je istoveten z: prEN 17632-2
ICS:
35.240.67 Uporabniške rešitve IT v IT applications in building
gradbeništvu and construction industry
91.010.01 Gradbeništvo na splošno Construction industry in
general
oSIST prEN 17632-2:2023 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 17632-2:2023

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DRAFT
EUROPEAN STANDARD
prEN 17632-2
NORME EUROPÉENNE

EUROPÄISCHE NORM

April 2023
ICS
English Version

EN 17632-2 Building Information Modelling (BIM) -
Semantic Modelling and Linking (SML), Part 2: Domain-
specific modelling patterns
Modélisation des informations du bâtiment (BIM) - Gebäudeinformationsmodellierung - Semantische
Modélisation sémantique et liaison (SML), Partie 2 : Modellierung und Verknüpfungs, Teil 2:
modèles de modélisation spécifiques à un domaine domänenspezifische Modellierungsmuster
This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee
CEN/TC 442.

If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations
which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.

This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other
language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC
Management Centre has the same status as the official versions.

CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,
Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway,
Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Türkiye and
United Kingdom.

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are
aware and to provide supporting documentation.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without
notice and shall not be referred to as a European Standard.


EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2023 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 17632-2:2023 E
worldwide for CEN national Members.

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Contents Page
European foreword . 3
Introduction . 4
1 Scope . 5
2 Normative references . 6
3 Terms and definitions . 7
4 Symbols and abbreviated terms . 8
4.1 Symbols . 8
4.2 Abbreviated terms . 9
5 Semantic extensions for the built environment . 9
5.1 Spatial regions versus real objects . 9
5.2 Materialization of physical objects . 11
5.3 Interaction between objects . 12
5.4 Requirements (unstructured) . 17
5.5 Implicit groups . 18
5.6 Functions . 19
5.7 Extended QUDT reuse . 19
5.8 Observations (SOSA) . 19
5.9 Geospatial geometry (GeoSPARQL) . 20
5.10 Overview of extended modelling constructs . 22
5.10.1 Extended concepts . 22
5.10.2 Extended properties . 23
6 Implementing SML part 2 in code . 24
7 Conformance . 24
7.1 General. 24
7.2 Conformance on language level . 24
7.3 Conformance on semantic level . 25
Annex A (normative) SML part 2 implementation in ‘linked data’ . 27
A.1 Introduction . 27
A.2 SKOS part . 28
A.3 RDFS part . 35
A.4 OWL part . 43
A.5 SHACL part . 48
Annex B (informative) SML part 2 example in SKOS/RDFS/OWL/SHACL (Turtle format) . 52
B.1 Example description . 52
B.2 OWL ontology and information set . 52
Annex C (informative) Extra SOSA information . 62
Annex D (informative) Extra SOSA example. 63
Bibliography . 66

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European foreword
This document (prEN 17632-2:2023) has been prepared by Technical Committee CEN/TC 422 “Building
information modelling (BIM)”, the secretariat of which is held by SN - Norway.
This document is currently submitted to the CEN Enquiry.
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Introduction
The abstract language and generic modelling patterns are already defined by the EN 17632-1:2022.
Early practical industrial application showed that there is a ‘gap’ between these abstract/generic patterns
and the real-world modelling needs in the built environment sector.
This document defines domain-specific extensions of the generic top level information model defined in
EN 17632-1:2022. These extensions are especially relevant for the modelling of assets/products in the
built environment. These extensions will support to close this gap.
This way, stakeholders in the built environment like owners, contractors and suppliers do not have to
‘reinvent the wheel’ for themselves for these new/extended modelling patterns.
By agreeing these patterns, stakeholders-specific data models will become even more pre-integrated
easing future asset/product data exchange/sharing and data integration/innovation in findable,
accessible, interoperable and reusable (FAIR) ways.
The extended standardized modelling patterns introduced in this document may be applicable to other
industry sectors as well.
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1 Scope
This part 2 will provide extended semantic modelling patterns for (at least) the following domain-specific
asset aspects:
— Support for distinction between two subtypes of physical objects: spatial regions and real
(“tangible”) objects; the latter being discrete or continuous (“bulk matter”);
— Support for the materialization of physical objects, adding generic chemistry aspects directly
relevant for the built environment dealing with materials like concrete, steel, wood and asphalt;
— Support for the interaction between objects including connections, interfaces and ports. Interactions
being defined as activities where material, information, energy or forces are transferred;
— Support for the definition of unstructured, human-interpretable, requirements, coming from
appointing party needs, laws & regulations or sector recommendations;
— Support for implicit groups having no explicit members (to model situations like “all main girders of
some steel bridge”);
— Support for the explicit modelling of measurements reusing the existing W3C SOSA ontology (as a
lightweight but self-contained SSN core ontology).
— Support for spatial geometry (location/shape) reusing OGC GeoSPARQL (GML/WKT) and the
WGS84_pos ontology (GPS)
These modelling patterns (in bold below) can all be positioned in the global modelling framework
provided in the form of a taxonomy by Part 1. These leaf concepts form the primary table of content of
this part 2.
• TopConcept
• AbstractConcept
• Type
• EnumerationType
• ConceptType
• Objectification
• QualityValue
• QuantityValue == qudt:QuantityValue (with qudt:numericValue)
• RelationReference
• MatterPortion
• ObservableProperty (SOSA)
• Result (SOSA)
• Sample (SOSA)
o ConcreteConcept
 Entity
• Object == FeatureOfInterest (SOSA) == Feature (GeoSPARQL)
• PhysicalObject
• SpatialRegion
• Interface
• RealObject
• DiscreteObject
• Sensor (SOSA)
• AmountOfBulkMatter
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• Matter
• PureSubstance
• ChemicalElement
• ChemicalCompound
• Mixture
• HomogeneousMixture
• HeterogenousMixture
• Connection
• Port
• InformationObject
• Representation
• GeometricEntity == Geometry (GeoSPARQL)
• TemporalEntity
• Requirement
• Activity
• Interaction
• Observation (SOSA)
• Procedure (SOSA)
• FunctionalEntity
• TechnicalEntity
• PlannedEntity
• RealizedEntity
• State
• Event
NOTE 1 The reused SOSA and GeoSPARQL entities will be kept separate. That means that the actual supertypes
as indicated above will not be modelled. Instead domain-specific concept can be subclasses or individuals can be
multiple typed.
NOTE 2 Some of the information needs might be resolved by extending existing language level constructs (like
in the case of implicit groups just adding some attributes for existing classes or containers or the use of SHACL rules
to represent structured requirements coming from clients, building laws and regulations or from building sector
recommendations). Finally there is a lot of ‘pattern potential’ under ‘DiscreteObject’ and ‘SpatialRegion’ in the built
environment (road networks, tunnels, bridges, buildings, installations). Care is taken not to cross existing standards
boundaries.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements for this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
EN 17632-1:2022, Building information modelling (BIM) - Semantic modelling and linking (SML) - Part 1:
Generic modelling patterns
ISO 6707-1, Buildings and civil engineering works — Vocabulary — Part 1: General terms
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3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 6707-1 and the following apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
• ISO Online browsing platform: available at https://www.iso.org/obp
• IEC Electropedia: available at http://www.electropedia.org/
3.1
amount of bulk matter
real object consisting of a continuous amount of non-formal matter, primarily held together by external
forces (gravity or confinement)
3.2
chemical element
pure substance made up of atoms with the same atomic number
NOTE 1 to entry: A chemical element cannot be decomposed by chemical reactions.
3.3
chemical compound
pure substance that consists of two or more chemical elements that have a chemical bond with each other
NOTE 1 to entry: In a chemical compound, the elements occur in a fixed ratio. A compound can be decomposed into
simpler substances through chemical reactions.
3.4
connection
physical object (real object or spatial region) that connects two other physical objects and over which
interaction takes place, namely the transfer of matter, energy, information or forces
3.5
discrete object
real object consisting of a continuous amount of rigid matter, held together primarily by internal forces
(gravity or electromagnetic force)
3.6
interaction
activity being a combination of sub-activities performed by physical objects between which a transfer of
matter, information, energy, or force occurs, typically over a connection or interface (directly or through
ports)
3.7
interface
spatial object, typically a thin 2D physical space (but also 0D or 1D) that connects two physical objects or
ports of physical objects through which a static or dynamic interaction or interaction between those
elements can take place
3.8
matter
chemical substance
pure substance, chemical compound or mixture from which real objects are made
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3.9
mixture
combination of two or more different pure substances without the molecules losing their identity
NOTE 1 to entry: A mixture is characterized by the molecules participating in it and the ratio of their amounts.
3.10
port
physical or logical point of interaction as part of a physical object where, through a connection or
interface, an interaction can take place
NOTE 1 to entry: In the case of forces, it is mainly a matter of static force transfer such as constructive connections
where the ports of both sides of the connection or the interface can be linked to properties of the port, such as
occurring allowable force, fastening method, shape and standards.
EXAMPLES A cover layer is the port of the asphalt construction in the interaction with vehicles, vice versa in
the same interaction the contact surface of the tire is the port from the vehicle.
3.11
pure substance
chemical substance that has a similar chemical composition and recognizable uniform and isotropic
properties
3.12
real object
amount of matter
physical object (‘retaining shape’ or non-‘retaining shape’) that is (or can be) tangible and visible in
reality, man-made or naturally occurring
NOTE 1 to entry: Examples of man-made physical objects include bridges, tanks, and devices.
NOTE 2 to entry: Examples of physical object that have arisen naturally are terrains, banks, water bottoms and trees.
3.13
spatial region
physical object that encloses a particular area such as a room, roadway, and river, that is bounded by real
objects or other spatial areas (e.g. by usage or convention) and that contains primarily liquid or gaseous
amount of matter
NOTE 1 to entry: Typically in a spatial region there is a gravitational field that differentiates between below, above
and lateral. As a result, the orientation of a spatial area is usually a relevant aspect.
4 Symbols and abbreviated terms
4.1 Symbols
This document does not contain any symbols.
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4.2 Abbreviated terms
For the purposes of this document, the following abbreviated terms apply.
0D/1D/2D/3D 0/1/2/3-dimensional
ALIM asset lifecycle information modelling
bSI building smart international
FAIR findadable, accessible, interoperable and reusable [go-fair.org]
GPS Global positioning system
IFC industry foundation classes [bSI]
OGC open geospatial consortium
OWL web ontology language [W3C]
RDF(S) resource description framework (schema)
SKOS simple knowledge organization schema
SML semantic modelling and linking
SOSA sensor, observation, sample, and actuator ontology [W3C, OGC]
SSN semantic sensor network ontology [W3C, OGC]
W3C world wide web consortium
5 Semantic extensions for the built environment
5.1 Spatial regions versus real objects
First of all, the physical objects (functional or technical, planned or realized) are optionally, disjointly
divided into spatial areas that are not directly tangible and tangible real objects. (Figure 1, 'dashes'
indicate relevant properties (attributes or relations)).

Figure 1 — Division of physical objects into spatial and real
This devision can be regarded as an extra systems engineering dimension orthogonal with
planned/realized and technical/functional introduced EN 17632 Part 1. Its enables the modelling of basic
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“realized/technical/real” entities towards “planned/functional/spatial” entities. In short: from acreage
modelling towards fullscale Asset Lifecycle Information Modelling (ALIM) (Figure 2).

Figure 1 — Extra systems engineering dimension
DiscreteObject (‘shape retaining’) and AmountOfBulkMatter (non-‘shape retaining’) are further
specializations of RealObject.
NOTE 1 A physical object is therefore broader than just 'an embodiment of masse/energy'. Meaningful
('semantic') physical spaces/times (unlike abstract mathematical spaces/times) are also included here under
physical object.
NOTE 2 A (semantic) temporal region would also have been relevant (such as 'The Middle Ages') but is not
included here.
NOTE 3 The 'contains' relation for a spatial region can be used for real objects located in that region and for the
typically gaseous amount of bulk matter present in that region.
NOTE 4 The 'consistsOf' relation towards matter is only relevant for technical objects (not functional objects).
NOTE 5 OGC's GeoSPARQL [2] has a spatial object: 'geo:SpatialObject', defined as: “the class spatial object
represents everything that can have a spatial representation. It is a superclass of feature and geometry”. So this is a
much broader definition than our spatial region. For example, our real object is also a spatial object in this
interpretation.
EXAMPLE 1 (real objects) Examples of real objects are bridge, bridge deck, pavement, wall, floor.
EXAMPLE 2 (spatial regions) IfcSpace is used in ISO 16739-1:2018 to model a spatial area in a building. Other
examples of spatial areas are roadway, lane, tank content, area, funnel, corridor and free space profile.
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EXAMPLE 3 (amount of bulk matter) Examples of amounts of bulk matter are an amount of air in a spatial
region, an amount of liquid in a pipe or river, and an asphalt batch.
5.2 Materialization of physical objects
Matter is seen as a special case of a physical object (also called a 'pseudo-object') and is divided according
to Figure 3 (schematic) and Figure 4 (model-based).

Figure 2 — Devision of matter

Figure 3 — Matter taxonomy
NOTE 1 Exotic states of matter such as ‘Bose–Einstein condensates’ not relevant for construction are left out for
simplicity.
A predefined subtype of RelationReference is MatterPortion. This is an objectification of the consistsOf
relation towards Matter. A predefined metadata attribute is ‘portion’ being a unitless ratio like a
percentage).
NOTE 2 A MatterPortion can indicate a fragment of a certain substance in a mixture or other matter portion.
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EXAMPLE (matter) Examples of chemical elements are oxygen (O ) and hydrogen (H ). An example of a
2 2
chemical compound is water (H2O). Examples of mixtures are cement, an asphalt mixture such as ZOAB-16, steel,
concrete, composite, sand and crushed stone.
NOTE 3 Matter can be transformed (creation, modification, deletion) by an activity. Specifically, matter
represents all the intensive (bulk) properties of a physical object (real object or mixture). This means that all
physical processes that have to do with heat, light, electrical conduction, sound, etc. also take place via (interaction
with) matter. And processes such as evaporation, freezing, melting, boiling also affect the state of matter (as a result
of which in some cases the object suddenly transforms from ‘shape retaining’ to non-‘shape retaining’, for example
the melting of an ice floe/glacier).
NOTE 4 A chemical formula is optional as it is only relevant for technical matter.
NOTE 5 The state of aggregation depends on the initial conditions with regard to atmospheric pressure and
temperature.
5.3 Interaction between objects
In integral design (especially for electrical/hydraulic installations) and demountability in sustainable
recycling (material passports), the correct modelling of interactions over connections and related
transfers between physical objects is becoming increasingly important.
Static models of assets are increasingly moving towards dynamic (simulation) models in which
behavioral aspects (ventilation, drain water, lighting, skid resistance, etc.) are included.
The ambition level of asset management is shifting from factual status information to behaviour,
deviations, causes, effects, risks, measures, etc., and requires more knowledge/data about the
connections between all these topics.
Existing traditional connections such as energy transfer between rooms in buildings and forces transfer
in support systems of civil structures are then no longer sufficient.
Figure 5 describes the theoretical patterns to position these connections in general.

Figure 4 — Interactions over connections
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The ‘Connection 1-2' (between object 1 and object 2) is a derived 'shortcut' for the existing chain of
relations as numbered in Figure 5:
1. executes;
2. transforms;
3. isTransformedBy (the inverse of transforms);
4. isExecutedBy (the inverse of executes).
or using a 'sub-shortcut':
1. executes;
2. 2.+3.: ‘Has interaction with’;
3. isExecutedby.
From this theory there is a connection between objects if there are two activities, respectively executed
by these objects, which are related through a third passive object, being a flow (material, information or
energy) or force, which is transferred from the one to the other. These two activities are both part of an
Interaction, in itself also an activity, in which these two objects participate.
It is precisely this 'Interaction' and 'Connection' between physical objects that is explicitly addressed here
in part 2.
To this end, we first introduce an Interaction as a specialization of an Activity. We also introduce a
participatesIn relation to indicate that physical objects participate in such an interaction.
Interactions have a transfer type that must be the same in an interaction. Options for this type are:
material flow, information flow, energy flow and force transfers from one physical object to another.
This activity modelling is optional. The connection between the objects is also optional, but is more easily
applied. This connection between physical objects can be established in several ways. Five options are
discussed below.
Option 1: Without an explicit 'Connection' physical object, but directly via a relation 'isConnectedTo'
(Figure 6).
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Figure 5 — Direct relation between objects
The direct isConnectedWith relation can also be between ports of physical objects or between ports and
objects. In the latter case, the port is not the port of that connected object.
Option 2: With an explicit Interface (itself a specialization of SpatialRegion), which also establishes a
relation to the connected physical objects via the relation 'connectsObject'. An interface is not a real object
but 'just' a spatial area where two physical objects come together (Figure 7).

Figure 6 — Indirect relation via an interface
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Option 3: With an explicit Connection as physical object, which establishes a relation to the connected
physical objects via the relation 'connectsObject' (Figure 8).

Figure 7 — Indirect relation via a connection
Option 4: As in option 2 but now with a Port, a specific part of one or both physical objects involved, via
the relation 'connectsPort' instead of 'connectsObject' (Figure 9).

Figure 8 — Indirect relation via an interface between ports
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Option 5: As in option 3 but now with a Port, of one or both physical objects involved, via the relation
'connectsPort' instead of 'connectsObject' (Figure 10).

Figure 9 — Indirect relation via a connection between ports
The following modelling constructions are included for this purpose (Figure 11).

Figure 10 — Modelling constructs for interaction
NOTE 1 Connections and ports are defined as specializations of physical objects. The divisions into spatial/real,
functional/technical and planned/realized are therefore also available. For example, a functional connection
between functional objects can be implemented by a technical connection between technical objects that implement
the connected functional objects.
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NOTE 2 With forces, objects do not have to be stuck, for example there may be slip. So it concerns forces on all
kinds of topological connectivity.
5.4 Requirements (unstructured)
For defining unstructured (human-interpreted) requirements, this document specifies the following
modelling constructs (Figure 12):

Figure 11 — Modelling constructs for requirements
The underlying values for requirementSourceType, requirementSeverityType, and
requirementTopicType are sml:EnumerationType instances without predefined allowed values. Those
allowed values may vary by end user ontology.
NOTE 1 A Requirement can b
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