Application module: Physical unit 3D shape ISO/TS 10303-1727:2018-11(E)
© ISO

Cover page
Table of contents
Copyright
Foreword
Introduction
1 Scope
2 Normative references
3 Terms, definitions and abbreviated terms
    3.1 Terms and definitions
    3.2 Abbreviated terms

4 Information requirements
   4.1 Required AM ARMs
   4.2 ARM type definitions
   4.3 ARM entity definitions
5 Module interpreted model
   5.1 Mapping specification
   5.2 MIM EXPRESS short listing
     5.2.1 MIM type definition

A MIM short names
B Information object registration
C ARM EXPRESS-G   EXPRESS-G
D MIM EXPRESS-G   EXPRESS-G
E Computer interpretable listings
F Change history
Bibliography
Index

5.1 Mapping specification

In the following, "Application element" designates any entity data type defined in Clause 4, any of its explicit attributes and any subtype constraint. "MIM element" designates any entity data type defined in Clause 5.2 or imported with a USE FROM statement, from another EXPRESS schema, any of its attributes and any subtype constraint defined in Clause 5.2 or imported with a USE FROM statement.

This clause contains the mapping specification that defines how each application element of this part of ISO 10303 (see Clause 4) maps to one or more MIM elements (see Clause 5.2).

The mapping for each application element is specified in a separate subclause below. The mapping specification of an attribute of an ARM entity is a subclause of the clause that contains the mapping specification of this entity. Each mapping specification subclause contains up to five elements.

Title: The clause title contains:

MIM element: This section contains, depending on the considered application element:

When the mapping of an application element involves more than one MIM element, each of these MIM elements is presented on a separate line in the mapping specification, enclosed between parentheses or brackets.

Source: This section contains:

This section is omitted when the keywords PATH or IDENTICAL MAPPING or NO MAPPING EXTENSION PROVIDED are used in the MIM element section.

Rules: This section contains the name of one or more global rules that apply to the population of the MIM entity data types listed in the MIM element section or in the reference path. When no rule applies, this section is omitted.

A reference to a global rule may be followed by a reference to the subclause in which the rule is defined.

Constraint: This section contains the name of one or more subtype constraints that apply to the population of the MIM entity data types listed in the MIM element section or in the reference path. When no subtype constraint applies, this section is omitted.

A reference to a subtype constraint may be followed by a reference to the subclause in which the subtype constraint is defined.

Reference path: This section contains:

For the expression of reference paths and of the constraints between MIM elements, the following notational conventions apply:

[] enclosed section constrains multiple MIM elements or sections of the reference path are required to satisfy an information requirement;
() enclosed section constrains multiple MIM elements or sections of the reference path are identified as alternatives within the mapping to satisfy an information requirement;
{} enclosed section constrains the reference path to satisfy an information requirement;
<> enclosed section constrains at one or more required reference path;
|| enclosed section constrains the supertype entity;
-> the attribute, whose name precedes the -> symbol, references the entity or select type whose name follows the -> symbol;
<- the entity or select type, whose name precedes the <- symbol, is referenced by the entity attribute whose name follows the <- symbol;
[i] the attribute, whose name precedes the [i] symbol, is an aggregate; any element of that aggregate is referred to;
[n] the attribute, whose name precedes the [n] symbol, is an ordered aggregate; member n of that aggregate is referred to;
=> the entity, whose name precedes the => symbol, is a supertype of the entity whose name follows the => symbol;
<= the entity, whose name precedes the <= symbol, is a subtype of the entity whose name follows the <= symbol;
= the string, select, or enumeration type is constrained to a choice or value;
\ the reference path expression continues on the next line;
* one or more instances of the relationship entity data type may be assembled in a relationship tree structure. The path between the relationship entity and the related entities, is enclosed with braces;
-- the text following is a comment or introduces a clause reference;
*> the select or enumeration type, whose name precedes the *> symbol, is extended into the select or enumeration type whose name follows the *> symbol;
<* the select or enumeration type, whose name precedes the <* symbol, is an extension of the select or enumeration type whose name follows the <* symbol;
!{} section enclosed by {} indicates a negative constraint placed on the mapping.
The definition and use of mapping templates is not supported in the present version of the application modules. However, use of predefined templates /SUBTYPE/ and /SUPERTYPE/ is supported.

5.1.1 External_source_identification

This application object, External_source_identification, is defined in the module external_item_identification_assignment. This mapping section extends the mapping of External_source_identification, to include assertions defined in this module.

5.1.1.1 External_source_identification to Physical_unit_3d_shape_model (as item)

Reference path:   applied_external_identification_assignment.items[i]-> external_identification_item
external_identification_item *> pu3ds_external_identification_item
pu3ds_external_identification_item = shape_representation

5.1.2 Footprint_definition_shape_model

This application object, Footprint_definition_shape_model, is defined in the module footprint_definition. This mapping section extends the mapping of Footprint_definition_shape_model, to include assertions defined in this module.

5.1.2.1 Footprint_definition_shape_model to Physical_unit_3d_shape_model (as reference_shape)

MIM element: PATH
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_2
representation_relationship
{representation_relationship
representation_relationship.name = 'reference shape'}
representation_relationship.rep_1 ->
representation =>
shape_representation
shape_representation

5.1.3 Physical_unit_3d_keepout_shape_model

MIM element: shape_representation
Source: ISO 10303-41
Reference path:   shape_representation <=
representation
{[representation.id ='uvlnfsm']
[representation.name = '3d bound volume shape']
[(representation.description = 'pu3dksm')]
[representation.context_of_items ->
representation_context =>
geometric_representation_context
geometric_representation_context.coordinate_space_dimension = 3]
[representation <-
property_definition_representation.used_representation
property_definition_representation
{property_definition_representation =>
shape_definition_representation}
property_definition_representation.definition ->
property_definition =>
product_definition_shape =>
physical_unit]}

5.1.3.1 component_application

MIM element: descriptive_representation_item
Source: ISO 10303-45
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'component application'}
representation.items[i] ->
representation_item
{(representation_item.name = 'compliant components permitted')
(representation_item.name = 'no components permitted')}
representation_item =>
descriptive_representation_item

5.1.3.2 shape_classification

MIM element: descriptive_representation_item
Source: ISO 10303-45
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'shape class'}
representation.items[i] ->
representation_item
{(representation_item.name = 'extrusion')
(representation_item.name = 'manhattan block')
(representation_item.name = 'other')
(representation_item.name = 'is unknown')}
representation_item =>
descriptive_representation_item

5.1.3.3 shape_location_with_respect_to_seating_plane

MIM element: descriptive_representation_item
Source: ISO 10303-45
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'shape location'}
representation.items[i] ->
representation_item
{(representation_item.name = 'above')
(representation_item.name = 'below')}
representation_item =>
descriptive_representation_item

5.1.3.4 side

MIM element: descriptive_representation_item
Source: ISO 10303-45
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'side'}
representation.items[i] ->
representation_item
{(representation_item.name = 'same side')
(representation_item.name = 'opposite side')
(representation_item.name = 'both sides')}
representation_item =>
descriptive_representation_item

5.1.3.5 Physical_unit_3d_keepout_shape_model to Length_tolerance_characteristic (as shape_distance_from_seating_plane)

MIM element: PATH
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
{representation_relationship
representation_relationship.name = 'shape distance from seating plane'}
representation_relationship.rep_2 ->
representation

5.1.3.6 Physical_unit_3d_keepout_shape_model to Physical_unit_3d_shape_model (as model_shape)

MIM element: PATH
Reference path:   shape_representation <=
representation
{representation.id = 'uvlnfsm'}
representation <-
representation_relationship.rep_2
representation_relationship
{representation_relationship
representation_relationship.name = 'model shape'}
representation_relationship.rep_1 ->
representation =>
shape_representation

5.1.4 Physical_unit_3d_shape_model

MIM element: shape_representation
Source: ISO 10303-41
Reference path:   shape_representation <=
representation
{[representation.name = '3d bound volume shape']
[representation.description = 'pu3dsm']
[representation.context_of_items ->
representation_context =>
geometric_representation_context
geometric_representation_context.coordinate_space_dimension = 3]
[representation <-
property_definition_representation.used_representation
property_definition_representation
{property_definition_representation =>
shape_definition_representation}
property_definition_representation.definition ->
property_definition =>
product_definition_shape =>
physical_unit]}

5.1.4.1 shape_classification

MIM element: descriptive_representation_item
Source: ISO 10303-45
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'shape class'}
representation.items[i] ->
representation_item
{(representation_item.name = 'extrusion')
(representation_item.name = 'manhattan block')
(representation_item.name = 'other')
(representation_item.name = 'is unknown')}
representation_item =>
descriptive_representation_item

5.1.4.2 Physical_unit_3d_shape_model to predefined_3d_purpose (as shape_purpose)

MIM element: PATH
Reference path:   shape_representation <=
representation <-
representation_relationship.rep_1
representation_relationship
representation_relationship.rep_2 ->
representation
{representation.name = 'predefined shape purpose'}
representation.items[i] ->
representation_item
{(representation_item.name = 'analysis input')
(representation_item.name = 'analysis output')
(representation_item.name = 'shock analysis input')
(representation_item.name = 'shock analysis output')
(representation_item.name = 'design')
(representation_item.name = 'vibration analysis input')
(representation_item.name = 'vibration analysis output')
(representation_item.name = 'electromagnetic compatibility analysis input')
(representation_item.name = 'electromagnetic compatibility analysis output')
(representation_item.name = 'thermal analysis input')
(representation_item.name = 'thermal analysis output')}
representation_item =>
descriptive_representation_item

5.1.5 Requirement_assignment

This application object, Requirement_assignment, is defined in the module requirement_assignment. This mapping section extends the mapping of Requirement_assignment, to include assertions defined in this module.

5.1.5.1 Requirement_assignment to * (as assigned_to)

Reference path:   requirement_assignment <-
requirement_assigned_object.assigned_group
requirement_assigned_object
requirement_assigned_object.items ->
requirement_assigned_item
requirement_assigned_item =
(/MAPPING_OF(Physical_unit_3d_keepout_shape_model)/)
(/MAPPING_OF(Physical_unit_3d_shape_model)/)

5.1.6 Usage_view_level_non_feature_shape_model

This application object, Usage_view_level_non_feature_shape_model, is defined in the module non_feature_shape_element. This mapping section extends the mapping of Usage_view_level_non_feature_shape_model, to include assertions defined in this module.

5.1.6.1 Usage_view_level_non_feature_shape_model to Physical_unit_shape_model (as model_shape)

Reference path:   shape_representation <=
representation
{representation.id = 'uvlnfsm'}
representation <-
representation_relationship.rep_2
representation_relationship
{representation_relationship
representation_relationship.name = 'model shape'}
representation_relationship.rep_1 ->
representation =>
shape_representation
shape_representation


© ISO 2018 — All rights reserved