The KIPS Transactions:PartB (정보처리학회논문지B)

Korea Information Processing Society (한국정보처리학회)
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Ontology-based Semantic Assembly Modeling for Collaborative Product Design

협업적 제픔 설계를 위한 온톨로지 기반 시맨틱 조립체 모델링

  • Published : 2006.04.01
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Abstract

In the collaborative product design environment, the communication between designers is important to capture design intents and to share a common view among the different but semantically similar terms. The Semantic Web supports integrated and uniform access to information sources and services as well as intelligent applications by the explicit representation of the semantics buried in ontology. Ontologies provide a source of shared and precisely defined terms that can be used to describe web resources and improve their accessibility to automated processes. Therefore, employing ontologies on assembly modeling makes assembly knowledge accurate and machine interpretable. In this paper, we propose a framework of semantic assembly modeling using ontologies to share design information. An assembly modeling ontology plays as a formal, explicit specification of a shared conceptualization of assembly design modeling. In this paper, implicit assembly constraints are explicitly represented using OWL (Web Ontology Language) and SWRL (Semantic Web Rule Language). The assembly ontology also captures design rationale including joint intent and spatial relationships.

협업적 제품 설계 환경에서는 여러 설계자가 작업에 참여하기 때문에 설계자간의 원활한 의사 소통이 필수적인 요소이다. 즉, 제품 설계에 내재되어 있는 다른 설계자의 설계의도를 파악할 수 있어야 하고, 각 설계자마다 사용하고 있는 상이한 모델링 용어에 대한 의미적 처리가 필요하다. 시맨틱 웹에서 온톨로지는 의미 정보를 명시적으로 표현할 수 있기 때문에 데이터와 서비스에 대한 통합되고 일관된 접근을 가능하게 한다. 따라서 제품을 여러 설계자가 설계하는 협업적 환경에서 온톨로지를 사용한다면 조립체내의 내포된 공학적 관계들, 공간적 관계들, 그리고 접합 관계들이 명확하게 표현되고, 추론을 통해 설계자의 의도가 파악되어 설계자간의 의사소통이 원활하게 이루어질 수 있다. 본 논문에서 는 조립체를 온톨로지를 이용하여 표현함으로써 협업적 환경에서 조립체 설계정보를 공유할 수 있는 시맨틱 조립체 모델링 프레임워크를 제안한다. 시맨틱 조립체 모델링 프레임워크에서는 조립체 관계 모델(Assembly Relationship Model, ARM)을 OWL(Web Ontology Language)와 SWRL(Semantic Web Rule Language)로 표현한다. 이를 통해 조립체 내에 내포된 공학적 관계들, 공간적 관계들, 그리고 접합 관계들이 명확하게 표현되고, 추론되어 설계 의도가 파악된다.

Keywords

References

  1. AP. Ambler, RJ. Popplestone, 'Inferring the positions of bodies from specified spatial relationships,' Artificial Intelligence 1975, 6(2) https://doi.org/10.1016/0004-3702(75)90007-7
  2. American Welding Society, Vision for Welding Industry, 2003, http://www.aws.org/research/vision.pdf
  3. R. Beeson, 'Pipeline welding goes mechanized,' Welding Journal 1999; 78(11):47-50
  4. Cycorp, Inc. 2004; http://www.cyc.com/cyc
  5. 2005 Engineous International Symposium & Workshop, Novi, MI. USA, October, 10-12, 2005
  6. Z. Fu, A. De Pennington, S. Saia, 'A graph grammar approach to feature representation and transformation,' Int. J. Computer Integrated Manufacturing 1993, 6(1&2):137-51 https://doi.org/10.1080/09511929308944564
  7. T. Graf, H. Staufer, 'Laser-hybrid welding drives VW improvements,' . Welding Journal 2003, 82(1):42-8
  8. M. Groninger, RD. Sriram, J. Cheng, K. Law, 'Process specification language for project information exchange,' Int. J. ?IT in Architecture, Engineering and Construction 2003, 1:307-28
  9. I. Horvath, JPW. Fulles, AP. Bremer, JSM. Vergeest, 'Towards an ontology-based definition of design features,'SIAM Workshop on Mathematical Foundations for Features in Computer Aided Design, Engineering, and Manufacturing, 1998
  10. KY. Kim, DG. Manley, BO. Nnaji, 'Lean virtual product model sharing for collaborative virtual prototyping,' IIE Annual Conference (IERC), May, 15-19, 2004
  11. K. Y. Kim, Y. Wang, OS. Muogboh, BO. Nnaji, 'Design formalism for collaborative assembly design environment,' Computer Aided Design on Distributed CAD 2004; 36(9):849-71 https://doi.org/10.1016/j.cad.2003.09.003
  12. Y. Kitamura, T. Sano, K. Narnba, R. Mizoguchi, 'A functional concept ontology and its application to automatic identification of functional structures,' Advanced Engineering Informatics 16(2):145-63, 2002 https://doi.org/10.1016/S1474-0346(02)00006-X
  13. Y. Kitamura, R. Mizoguchi, 'Ontology-based description of functional design knowledge and its use in a functional way server,' Expert Systems with Application 24(2):153-66 https://doi.org/10.1016/S0957-4174(02)00138-0
  14. Y. Kitamura, R Mizoguchi, 'Ontology-based systematization of functional knowledge,' In press for J. Engineering Design 2004 https://doi.org/10.1080/09544820410001697163
  15. Y. Kitamura, M. Kashiwase, F. Masayoshi, R. Mizoguchi, 'Deployment of an ontological framework of function design knowledge,' In press for Advanced Engineering Informatics 2004
  16. R. Kurland, 'NX systems engineering powers the product Iifecycle,' TechniCom Inc technical article, 2003
  17. J. Lin, MS. Fox, T. Bilgic, 'A requirement ontology for engineering design,' Concurrent Engineering Research and Applications, 4(3):279-91, 1996 https://doi.org/10.1177/1063293X9600400307
  18. HC. Liu, BO. Nnaji, 'Design with spatial relationships,' J Manufacturing Systems, 10(6), 1991
  19. TL. Liu, 'A coordinated constraint-based modeling and design advisory system for mechanical components and assemblies,' Ph. D. dissertation, University of Massachusetts Amherst, 1997
  20. D. Lutters, AH. Streppel, HJJ. Kals, 'The role of information structures in design and engineering processes,' 3rd Workshop on Product Structuring, 1997
  21. RW. Messler, 'Joining of Advanced Materials,' Boston: Butterworth- Heinemann, 1993
  22. Pegasus, 'NSF I/UCRC for e-Design: Strategic Planning Meeting,' Pittsburgh, PA, USA, Dec., 9 to 10, 2003, www.e-designcenter.info
  23. L. Rernondini, JC. Leon, P. Trompette, 'High-level operations dedicated to the integration of mechanical analysis within a design process,' Engineering with Computers. 1998, 14:81-92 https://doi.org/10.1007/BF01198977
  24. C. Schlenoff, R. Ivester, D. Libes, P. Denno, S. Szykman, 'An analysis of existing ontological systems for applications in manufacturing and healthcare,' NISTIR 6301 National Institute of Standards and Technology 1999
  25. World Wide Web Consortium, 'World wide web-summary,' 1992, http://www.w3.org/Surnmary.html
  26. World Wide Web Consortium, 'OWL web ontology language guide,' 2004, http://www.w3c.org/TRlowl-guide
  27. World Wide Web Consortium, 'SWRL: A Semantic Web Rule Language,' 2004, ?http://www.w3.org/Submission/2004/SUBM-SWRL-20040521/
  28. DE. Whitney, R Mantripragada, JE. Adams, SJ. Rhee, 'Toward a theory for design of kinematically constrained mechanical assemblies,' Int J Robotics Research, 18(12):1235-48, 1999 https://doi.org/10.1177/02783649922067834
  29. DE. Whitney, 'A design procedure applicable to different classes of assemblies,' Proceedings of the ASME 2001 Design Technical Conferences, September, 9-12, 2001
  30. Minsu Jang., Joe-chan Sohn., 'Bossam: an extended rule engine for the web,' Proceedings of RuleML 2004 (LNCS Vol. 3323), Nov., 8, 2004
  31. Jena Tutorial, 'A Programmer's Introduction to RDQL,' http://jena.sourceforge.net/tutorial/RDQL/
  32. S. Szykman, RD. Sriram, WC. Regli, 'The role of knowledge in next-generation product development systems,' J. Computing and Information Sc. in Engr., 2001, 1:3-11 https://doi.org/10.1115/1.1344238
  33. D. Deneux, 'Introduction to assembly features: an illustrated synthesis methodology,' J. Intelligent Manufacturing, 10:29-39, 1999 https://doi.org/10.1023/A:1008912429442
  34. W. van Holland, WF. Bronsvoort, 'Assembly features in modeling and planning,' Robotics and Computer Integrated Manufacturing, 16:277-94, 2000 https://doi.org/10.1016/S0736-5845(00)00014-4