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Ontologies at Ericsson Why and How

Ontologies at Ericsson Why and How. Lars Taxén, PhD Department of Science and Technology, Campus Norrköping, Linköping University lars.taxen@telia.com, +46 73 0977864. Background Lars Taxén. M.Sc. KTH 1968 Ericsson 1968 - 2003 Development methods for hardware and software

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Ontologies at Ericsson Why and How

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  1. Ontologies at EricssonWhy and How Lars Taxén, PhD Department of Science and Technology, Campus Norrköping, Linköping University lars.taxen@telia.com, +46 73 0977864

  2. Background Lars Taxén • M.Sc. KTH 1968 • Ericsson 1968 - 2003 • Development methods for hardware and software • Global information system support for coordination • Doctoral studies Linköping University 1998 - 2003 • “A Framework for the Coordination of Complex Systems’ Development” • Now researcher and consultant “There is nothing so practical as a good theory.” (Kurt Lewin)

  3. Outline • Definitions of ontology • Telecommunication systems • “Pragmatic” ontologies at Ericsson - why and how • “Formal” ontologies in the literature • Comparison • Discussion • Conclusions

  4. Ontology in philosophy “Ontology studies being or existence as well as the basic categories thereof—trying to find out what entities and what types of entities exist. Ontology has strong implications for the conceptions of reality.”

  5. Definition “Ontologies are content theories about the sorts of objects, properties of objects, and relations between objects that are possible in a specified domainof knowledge. ” Chandrasekaran et al. (1999) “What Are Ontologies, and Why Do We Need Them?” IEEE Intelligent Systems, Jan/Feb 1999

  6. Two types of ontologies • “Pragmatic” ontologies • “Context models” at Ericsson • Used to coordinate complex development projects • Social action theories (Activity Theory, Structuration Theory, Actor Network Theory, etc.) • “Formal” ontologies • Origin in the AI community • Currently “hot topic” in the Semantic Web • First-order logic

  7. Telecom background

  8. Network Access Points LAN Wide-band Backbone Service Providers LAN The telecom network Exchange Exchange Router

  9. Issues Development lead-times Coordination and dependencies Progress follow-up Culture - disciplines Geographical distribution Commitments and responsibilities Competence Quality Drivers Market push Shorter time to market More competitors Less margins Shorter product life cycles Technological complexity Standardization Change Developing a node

  10. Development of 3G mobile systems • Development centers • S-domain (Stockholm) • A-domain (Aachen) • L-domain (Linköping) • C-domain (Stockholm)

  11. Coordination • “The management of dependencies btw activities” • Malone & Crowston, 1994 • Communal meaning about how to coordinate • requirements • engineering change orders • products • documents describing products • test cases • integrations • baselines • milestones • deliveries • ... • Information system support

  12. “Pragmatic” ontologies at Ericsson- a historical Odyssey

  13. Plan Integrate Analysis Design Verification “Big Bang” Plan Integrate Integrate Increment From waterfall to integration centric development

  14. Method development 1996 S-domain Incremental Development Method Package

  15. Context model S-domain 1996 Assignment Specification AD plan System Issue Constr. plan Project AD package Project Increment Proj MS def Incr MS def MCI Incr. Task Specification Increment Specification Function Anatomy Customer New Feature Set of req’s Test Object Test Case Function Incr dep. matrix Interface Characte- ristics Design Base Baseline Design Item AXE System Specification MCI Document Project Document Product Document Implementation New categories System Issue

  16. Information system support 1996 1997 S-domain Incremental Development Method Package Information system (IS) introduced

  17. Context model S-domain 1997 System Issue Project Project MS Customer Customer Feature AD Task AD MS Set of Req’s AD Package IS Tech. Feature Inc Spec Feature Increment Increment Task Spec Inc. MS IP Increment Responsible Functional Anatomy Impact Individual FF Resource Function Teaml Design Base Design Item LDC Sub projectl Product Document Project New categories ... ANT CNT CAA FS FD TS ...

  18. IS support for the context model S-domain 1997

  19. First project 1996 1997 1998 1999 S-domain Incremental Development Method Package 1st sharp project prototype 1st sharp project up and running Information system (IS) in pilot projects

  20. Needs, Impacts Includes Consists_Of Context model S-domain 1999 Test Case PROJ. ITEMS Req Issuer TEST ITEM Project MS MILESTONE TestedBy Parent_Child Input Req Increment MS REQUIREMENT Project AllocatedTo Detailed Req DESIGN ITEM Includes DELIVERY IP System Issue AD Package Consists_Of TECH INCR SPEC Function Package Use Case INCREMENT Baseline PRODUCT Design Base Change Request DOCUMENT Role CR Comment PROJECT DOCUMENT CCB Meeting PRODUCT DOCUMENT CCB Decision Requirement Coordinator Designer Configuration Manager Project Manager

  21. Expansion A-domain 1996 1997 1998 1999 2000 2001 S-domain Incremental Development Method Package 1st sharp project prototype 1st sharp project up and running L-domain Information system (IS) in pilot projects Two more domains created

  22. Context model A-domain 2001 ARS, CRS, MRS High-level RS Feature Groups DependsOn Feature Group DescribedIn* Features toAnatomy Has (s)WPG prio Holds Feature DescribedIn RS_IP IP_FF FF_WP RS IP FF WP DependsOn Tagged(H)RS Item RS_SIP IncludedIn SIP_IP Impacts SIP Detailed RS LSV Product

  23. Expansion A-domain 1996 1997 1998 1999 2000 2001 S-domain Incremental Development Method Package 1st sharp project prototype 1st sharp project up and running L-domain Information system (IS) in pilot projects Two more domains created Two more IS applications

  24. Depends_on ! Context model S-domain 2001 TEST_ITEM Tested_by Requirement Issuer has ANATOMY_ITEM INTEGRATION_ITEM Included_In LSV Work Package Directed_To (fulfillment-status) AD-package Feature Increment Impacts (man-hours) DESIGN_ITEM REQUIREMENT PRODUCT PROGRESS_CONTROL_ITEM PROD_DOC Baseline MILESTONE CHANGE_PROPOSAL_ITEM CR TR

  25. Centralization A-domain ? 2003 2004 1996 1997 1998 1999 2000 2001 2002 S-domain X Incremental Development Method Package 1st sharp project prototype 1st sharp project up and running C-domain X L-domain Information system (IS) in pilot projects Two more domains created Ericsson common domain serving the other domains One common Ericsson domain

  26. Context model C-domain 2003

  27. Context model evolution A-domain ? 1996 1997 1998 1999 2000 2001 2002 2003 2004 S-domain X C-domain X L-domain

  28. Construction of context models

  29. A detail in the context model To be defined... • Entities • Relations • Names, icons • Types of requirements • Life cycle of requirements • Attributes on requirements • Attributes on relations • Cardinalities on relations • Revision stepping rules • Actor roles • Access rights for roles • ...

  30. Constructing communal meaning the key issue We also had major discussion about the attributes for each and every object, what do they really mean and how are they to be used. That was also something that caused quite a lot of time. (Project Manager 3G)

  31. Construction process Individual meaning Communal meaning Meaningful artifacts Req. mgr Proj. mgr IS vendor Architect

  32. A comparison- between context models at Ericsson and ontologies in the literature

  33. Example adapted after Edgington et al. (2004) “Adopting Ontology to Facilitate Knowledge Sharing”, Chandrasekaran et al. (1999) “What Are Ontologies, and Why Do We Need Them?” Properties of ontologies from the literature • There are objects in the world • Objects have properties or attributes that can take values • Objects can exist in various relations with each other • Objects can have parts • Properties and relations can change over time • There are events that occur at different time instants • There are processes in which objects participate and that occur over time • The world and its objects can be in different states • Events can cause other events or states as effects

  34. Properties of context models at Ericsson • There are objects in the world • Objects have properties or attributes that can take values • Objects can exist in various relations with each other • Objects can have parts • Properties and relations can change over time • There are events that occur at different time instants • There are processes in which objects participate and that occur over time • The world and its objects can be in different states • Events can cause other events or states as effects

  35. “Formal” Ontologies- related to the Semantic Web

  36. Formally defined “...The only languages [to describe the entities involved and the relationships between them] that are likely to fit the bill are mathematical, and the prime contenders are understandable in terms of first-order logic.”

  37. Conceptions of knowledge “… knowledge is a collection of facts about a domain.” “…encoding knowledge in terms of the concepts and relations.” “Ontological analysis clarifies the structure of knowledge”

  38. Meaning “Ontologies will provide the necessary meaning to web content therefore enabling software agents to understand and retrieve information in relevant contexts.”

  39. Separation of ontology and knowledge “An ontology provides a set of concepts and terms for describing some domain, while a knowledge base uses those terms to represent what is true about some real or hypothetical world.”

  40. Stability “Ontology, ... is supposed to reflect ... the well established knowledge of a given area... It should be stable and throughout used.

  41. Commonality “Communication between distinct groups using different vocabularies creates the need to create common vocabularies, which optimally suit all involved”

  42. Machine processing “We have presented an automated approach to unifying heterogeneous information models based on machine-processable metadata specifications.”

  43. Discussion

  44. Basic tenets “formal” ontologies • Knowledge • A collection of facts that are true • Can be managed • Is discovered • Ontologies separate from knowledge • Ontologies • Give meaning • Describe some part of the “real” world • External to the worlds they describe • Stable • Formally defined • Can be machine processed • Validated according to compliance with facts, truth

  45. Basic tenets “pragmatic” ontologies • Knowledge • Intrinsic to humans, knowledge is what a knower knows • Constructed in action • Not a commodity • Ontologies are inseparable from knowledge • Ontologies • Instruments for constructing communal meaning • Domain specific • Provide a communal language in the domain • In constant evolution • Informally described - easy to interpret for humans • Machine processing not a prerequisite • Validated for usefulness in the domain

  46. Commodity Inherent Description Stable Formal Truth Uniform External Inherently human Constructed Action Evolution Significant Usability Multitude Internal “Formal” versus “pragmatic” ontologies “Formal” “Pragmatic” Knowledge Meaning Usage Change Model Validation Commonality Existence On the surface formal and pragmatic ontologies look the same Fundamentally different conceptions of knowledge

  47. Issues • Ontology for ontologies • Knowledge for description or action? • Is knowledge equal to facts? • Can knowledge be managed? • Are ontologies external to the world it describes? • Meaning • Do ontologies encode meaning? • Unification • Is it possible to define “one size fits all” ontology? • Validation • Usefulness or truth? • Development • Stable or dynamic world?

  48. Activity Domain Theory • Focus on communal meaning • Activity Modalities • Spatialization • Temporalization • Technologization • Stabilization • Contextualization • Transition • Pragmatic communication • Ontology is one modality - spatialization • Other modalities need to be considered in ontology construction

  49. Further reading • Taxén L (2003) A Framework for the Coordination of Complex Systems’ Development. Dissertation No. 800. Linköping University, Dep. of Computer &Information Science, 2003. Retrieved from http://www.ep.liu.se/diss/science_technology/08/00/index.html (Nov 2004) • Taxén L (2004): Articulating Coordination of Human Activity - the Activity Domain Theory. In Proceedings of the 2nd International workshop on Action in Language, Organisations and Information Systems (ALOIS-2004), Linköping University. Retrieved from http://www.vits.org/konferenser/alois2004/proceedings.asp (Dec 2005). • Taxén L (2005) Categorizing Objective Meaning in Activity Systems, in Whymark G, Hasan H (Eds.), Activity as the Focus of Information Systems Research, Eveleigh, Australia: Knowledge Creation Press, pp. 169-192 • Taxén L (2005) An Integrated Approach for the Coordination of Distributed Software Development Projects, Information and Software Technology, (in press).

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