Journal of the Korean Association of Geographic Information Studies (한국지리정보학회지)

The Korean Association of Geographic Information Studies (한국지리정보학회)
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Development of 3D Underground Utilities Processing and Partial Update Automation Technology - Focused on 3D Underground Geospatial Map -

3차원 지하시설물 가공 및 부분갱신 자동화 기술개발 - 지하공간통합지도 중심으로 -

  • Received : 2020.09.11
  • Accepted : 2020.10.28
  • Published : 2020.12.31
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Abstract

As cities expand and underground utilities construction projects increase, there is an urgent need for a technology capable of analyzing the underground utilities network in 3D. Since 2015, 3D Underground Geospatial Map project, that has been integrating 15 types of underground information such as underground utilities, underground structures, and ground information, is in progress in S. Korea. However, the construction of 3D underground facilities is currently based on manual work and the logic for building a 3D model is very complicated. And it takes a lot of time and cost to process millions of large amounts of data per local governments. By presenting a framework on the processing and partial updating of the 3D underground utilities model, this paper aims to establish a plan to quickly build a 3D underground utility model at a minimum cost. The underground utilities processing and partial update automation technologies developed in this study are expected to be immediately applied to the 3D Underground Geospatial Map project.

도시가 확장되고 지하시설물 관련 공사가 늘어남에 따라 지하시설물 관로 네트워크를 3차원으로 분석할 수 있는 기술이 절실히 요구되고 있다. 국내에서는 2015년부터 15종의 지하정보(지하시설물, 지하구조물, 지반)를 3차원 기반 지하공간통합지도로 구축하는 사업을 진행하고 있다. 하지만 현재 3차원 지하시설물 구축은 수작업 기반으로서 구축 방법이 매우 복잡하고 지자체별 수백만 건이 넘는 대용량 데이터를 처리하기에는 시간과 비용이 많이 발생한다. 본 논문은 3차원 지하시설물 모델의 가공 및 갱신 자동화 구축 프레임워크를 제시함으로써 3차원 지하시설물 모델을 최소비용으로 신속하게 구축하는 방안을 수립하였다. 본 연구에서 개발된 지하시설물 가공 및 부분갱신 자동화 기술들은 지하공간통합지도 구축사업에 즉시 현장적용이 가능할 것으로 기대한다.

Keywords

Acknowledgement

본 연구는 국토교통부/국토교통과학기술진흥원의 지원으로 수행되었음(과제번호 20DCRU-B158151-01).

References

  1. Ahn, H.S. 1997. The Development of the Object-Oriented Data Structure and 3-D Visualization System for the Management of Underground Utilities. Master Thesis of Hanyang University, Seoul, Korea. 51pp.
  2. Balogun, A., Matori, A. and Lawal D. 2011. Developing a framework for the 3D visualization of underground petroleum pipelines. International Journal of Chemical and Environmental Engineering. 2(2):135-139.
  3. Becker, T., Nagel, C. and Kolbe, T.G. 2011 Integrated 3D modeling of multi-utility networks and their interdependencies for critical infrastructure analysis. Advances in 3D Geo-Information Sciences, Lectures in Goinformation and Cartography, Kolbe, T.H., Koning, G. & Nagel, C.(eds), Springer, Berlin Heidelberg, pp.1-20.
  4. Carlo P. and James H.A. 2014, Advances in 3D modeling of existing subsurface utilities. T&DI Congress, ASCE, Orlando, Florida, pp.574-583.
  5. Du, Y. and Zlatanova, S. 2006. An approach for 3D visualization of pipelines. In: Abdul-Rahman A, Zlatanova S, Coors V (eds) Innovation in 3D-Geo Information System, Springer, Berlin, Heidelberg. pp.395-404.
  6. Du, Y., Zlatanova, S. and Liu, X. 2006. Management and 3D visualisation of pipeline networks using DBMS and AEC software. Proceedings of the ISPRS Commission IV Symposium on 'Geospatial Databases for Sustainable Development'. 27-30 September2006. Edited by: Nayak, S., Pathan, S.K. and Garg, J.K. pp.395-400. Goa, India Archives of ISPRS 36, (4A).
  7. El-Hakim, s. 2008 3-D Data modelling and visualization. ISPRS Congress Book, pp.311-322
  8. Fenais, A., Ariaratnam, S.T., Ayer, S. K. and Smilovsky, N. 2019. Integrating Geographic Information Systems and Augmented Reality for Mapping Underground Utilities. Infrastructures 4(4):60. https://doi.org/10.3390/infrastructures4040060
  9. Guerrero, J., Zlatanova, S. and Meijers M. 2013. 3D visulisation of underground pipelines: Best strategy for 3D scene creation", ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, II-2/W1, pp.139-145. https://doi.org/10.5194/isprsannals-II-2-W1-139-2013
  10. Kim, K.H., Cho, H.B., Kang, B.J., Kim, M.S. and Kim I.H. 2008. Study on a 3D Visualization of Underground Facilities. Proceedings of the 2008 Fall Conference of Geographic Information System Association of Korea. pp.232-237.
  11. Lee, H.J., Kim, J.S., Seo, H.S. and Cho, Y.S. 2018. Development of location based augmented reality system for public underground facility management. Journal of Digital Contents Society. (18)2:237-243.
  12. Lee, Y.K., Kim, M.S., Kim, K.H., Cho, H.B. and Kim. I.H. 2008. Study on a web services for the 3D information about a feature of underground facilities on open standards. Proceedings of the 2008 Joint Spring Conference of Geographic Information System Association of Korea. pp.327-331.
  13. Li, S., Cai, H. and Kamat, V.R. 2015. Uncertanity-aware geospatial system for mapping and visualizing underground utilities. Autom. Constr. (53):105-119. https://doi.org/10.1016/j.autcon.2015.03.011
  14. Lyle, S.k. 2017. Damage information reporting tool; Common Ground Alliance: San Diego, CA, USA. (13):3.
  15. Ministry of Land, Infrastructure and Transport. 2012. Development of urban spatial information platform for urban public facility management based on sensing data. Land Transport and Maritime R&D Report pp.1-2647.
  16. Ministry of Land, Infrastructure and Transport. 2014. http://www.molit.go.kr/USR/NEWS/m_71/dtl.jsp?lcmspage=1&id=95074554. (Accessed August 26, 2020).
  17. National IT Industry Promotion Agency. 2011. https://www.itfind.or.kr/WZIN/jugidong/1497/file25672-149701.pdf. (Accessed August 26, 2020).
  18. National Law Information Center. 2018. http://www.law.go.kr/LSW/admRulLsInfoP.do?admRulSeq=2100000165613. (Accessed August 26, 2020).
  19. Oh, S., Kang, B.I. and Chong, J.W. 1996. The object-oriented design and implementation of spatial data transformation system for the 3-D representation of underground utilities. Brief report of the 1996 Spring Conference of Geographic Information System Association of Korea. pp.79-109.
  20. Oh, S., Lee, Y. and Kim, I.H. 2000. Design and implementation of web-based 3-D management system for underground utilities. Proceedings of the 2000 Conference of Korea Spatial Information System Society.
  21. Olde Scholtenhuis, L.L., den Duijn, X. and Zlatanova, S., 2018, Representing Geographical Uncertainties of Utility Location Data in 3D, Autom. Constr. 96:483-493. https://doi.org/10.1016/j.autcon.2018.09.012
  22. Shin, S.H., Ahn, K.W., Ji, H.S. and Lee, H.S. 2002. The application of web three dimensional GIS for efficient management of underground facilities. Proceedings of the 2002 Fall Conference of Korean Society of Surveying, Geodesy, Photogrammetry and Cartography. pp.305-309.
  23. Talmaki, S., Kamat, V.R. and Cai, H., 2013, Geometric modeling of geospatial data for visualization-assisted excavation. Adv. Eng. Inform 27:283-298. https://doi.org/10.1016/j.aei.2013.01.004
  24. Yan J., Jaw S.W., Soon K.H., Wieser A. and Schrotter, G. 2019 Towards an underground utilities 3D data model for land administration. Remote Sens. (11):1957.