Submissions:View Inheritance

From Odp

Jump to: navigation, search


This pattern has been certified.

Related submission, with evaluation history, can be found here

If you are a member of quality committee please visit the

evaluation section

If you are author of this proposal or you want to contribute to this pattern's review, you can:

In general, it could be useful to visit the evaluation section to have information about the evaluation process of this proposal

Current revision ID: 9979

Graphical representation

Diagram

Image:Fig_view_inheritance_structure.png

General information

Name View Inheritance
Also known as
Author(s) Benedicto Rodriguez-Castro, Hugh Glaser
Domain (if applicable) General
Submitted by BenedictoRodriguezCastro, HughGlaser


Description

Problem description There are ontology domain concepts that are difficult to represent due to the complexities in their definition and the presence of multiple alternative criteria to classify their abstractions.
Solution description Introduce the following types of classes:
  • Criterion_i: These classes represent each one of the alternative abstraction criteria of the TargetDomainConcept (Criterion1, Criterion2, Criterion_i in the Figure above). The list of classes may not be exhaustive or pairwise disjoint.
  • Ci_Class_x: These classes refine each abstraction criteria class (C1_Class1, ..., C2_Class1, ..., Ci_Class_i in the Figure above). The list of classes may not be exhaustive or pairwise disjoint.
  • CiClass_xCjClass_y, Ci_Class_xClass_y: These classes participate in multiple inheritance relationships combining different refinements from the alternative abstraction criteria classes (C1Class3_C2Class2 and C1_Class1Class2 in the Figure above).
Implementation workflow
Reusable component


Example

Problem example
Solution example Figure above in particular, shows a matrix representation of all types of faults which may affect a system during its life. Implicitly, the figure reveals several alternative criteria for the classification of faults:
  • A first criterion can be derived from the left column of the matrix (listing the basic view points from Figure 2: Development/Operational Faults, Internal/External Faults and so on). This column represents the values of the eight basic viewpoints which lead to the elementary fault classes.
  • A second criterion can be abstracted from the bottom row (listing numbers 1 to 31). This row represents the 31 likely combinations of fault classes out of the 256 possible.
  • A third criterion is implicit at the top row, representing the three major partially overlapping groupings of faults: Development, Physical and Interaction.
  • A fourth criterion can be seen at the bottom row, labeled Examples, containing nine illustrative examples of fault classes.
Consequences Inter- and Intra-criterion Multiple Inheritance.

There is an interesting feature regarding the types of multiple inheritance relations that can take place in the context of a View Inheritance pattern. These types of multiple inheritance relationships can be characterized as:

  • Inter-criterion, when the parent classes involved in the multiple inheritance relation are subclasses of different abstraction criteria. The class C1Class3_C2Class2 in Figure 1 is an example of this type of inheritance because one of its parent classes, C1_Class3, is a refining concept of Criterion1 and the other parent class, C2_Class2, is a refining concept of Criterion2.
  • Intra-criterion, when the parent classes involved in the multiple inheritance relation are subclasses of the same abstraction criterion. The class C1_Class1Class2 is an example of this type of inheritance because all of its parents classes, C1_Class1 and C1_Class2, are refining concepts of the same criterion, Criterion1.
  • Intra- and inter-criterion, when there are at least two parents involved in the relation that are subclasses of the same abstraction criterion and there is at least one more different parent that is a subclass of a different abstraction criterion. An example of this type of inheritance is trivial to extrapolate from the composition of the previous two.


Pattern reference

Origin Object Oriented:
  • Meyer, B.: Object-Oriented Software Construction (Book/CD-ROM) (2nd Edition). Prentice Hall PTR (March 2000)

Ontology:

  • Rector, A.L.: Modularisation of domain ontologies implemented in description logics and related formalisms including owl. In: K-CAP '03: Proceedings of the 2nd international conference on Knowledge capture, New York, NY, USA, ACM (2003) 121--128
Known use
Reference
Related ODP Submissions:Normalization, Submissions:Partition, Submissions:ClassAsPropertyValue, Submission:MultipleInheritance

Additional information

Image:Fig_avizienis_fault_4.jpg


Image:Fig_avizienis_fault_5a.jpg


Image:Fig_avizienis_fault_5b.jpg


Image:Fig_fault_f1_f2_asserted_prot4x.png

Scenarios

Scenarios about View Inheritance

No scenario is added to this Content OP.

Reviews

Reviews about View Inheritance

There is no review about this proposal. This revision (revision ID 9979) takes in account the reviews: none

Other info at evaluation tab


Modeling issues

Modeling issues about View Inheritance

There is no Modeling issue related to this proposal.


References

Add a reference


Personal tools
Quality Committee
Content OP publishers