SCIENTIA SINICA Informationis, Volume 48 , Issue 3 : 274-292(2018) https://doi.org/10.1360/N112017-00240

Mobile web-based lightweight and real-time roaming algorithm for large-scale WebBIM scenes

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  • ReceivedNov 14, 2017
  • AcceptedDec 27, 2017
  • PublishedFeb 13, 2018


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[1] Donkers S, Ledoux H, Zhao J. Automatic conversion of IFC datasets to geometrically and semantically correct CityGML LOD3 buildings. Trans GIS, 2016, 20: 547-569 CrossRef Google Scholar

[2] Thomas L. IFC Office Release 4. Model Support Group (MSG) of BuildingSMART, 2013. http://www.buildingsmart-tech.org/specifications/ifc-releases/ifc4-release. Google Scholar

[3] Johansson M, Roupé M, Bosch-Sijtsema P. Real-time visualization of building information models (BIM). Automation Construction, 2015, 54: 69-82 CrossRef Google Scholar

[4] Pasewaldt S, Trapp M, Döllner J. Multi-perspective detail overview visualization for 3D building exploration. In: Proceedings of the 11th Theory and Practice of Computer Graphics (TPCG), 2013. 57--64. Google Scholar

[5] Karsch K, Golparvar-Fard M, Forsyth D. ConstructAide: analyzing and visualizing construction sites through photographs and building models. ACM Trans Graph, 2014, 33: 176. Google Scholar

[6] Sun J, Liu Y S, Gao G. IFCCompressor: A content-based compression algorithm for optimizing Industry Foundation Classes files. Automation Construction, 2015, 50: 1-15 CrossRef Google Scholar

[7] Arthaud G, Lombardo J C. Automatic semantic comparison of STEP product models. In: Innovations in Design & Decision Support Systems in Architecture and Urban Planning. Berlin: Springer, 2006. 447--463. Google Scholar

[8] Lee G, Won J, Ham S. Metrics for Quantifying the Similarities and Differences between IFC Files. J Comput Civ Eng, 2011, 25: 172-181 CrossRef Google Scholar

[9] Zhang L, Issa R R A. Development of IFC-based construction industry ontology for information retrieval from IFC models. In: Proceedings of the EG-ICE Workshop. The Netherlands: University of Twente, 2011. 6--8. Google Scholar

[10] Gao G, Liu Y S, Wang M. A query expansion method for retrieving online BIM resources based on Industry Foundation Classes. Automation Construction, 2015, 56: 14-25 CrossRef Google Scholar

[11] Liu H, Liu Y S, Pauwels P. Enhanced Explicit Semantic Analysis for Product Model Retrieval in Construction Industry. IEEE Trans Ind Inf, 2017, 13: 3361-3369 CrossRef Google Scholar

[12] Gao G, Liu Y S, Lin P. BIMTag: Concept-based automatic semantic annotation of online BIM product resources. Adv Eng Inf, 2017, 31: 48-61 CrossRef Google Scholar

[13] Shi X, Liu Y S, Gao G. IFCdiff : A content-based automatic comparison approach for IFC files. Automation Construction, 2018, 86: 53-68 CrossRef Google Scholar

[14] Guo J, Yan D M, Li E. Illustrating the disassembly of 3D models. Comput Graphics, 2013, 37: 574-581 CrossRef Google Scholar

[15] Laga H, Mortara M, Spagnuolo M. Geometry and context for semantic correspondences and functionality recognition in man-made 3d shapes. ACM Trans Graph, 2013, 32: 150. Google Scholar

[16] Zheng Y, Cohen-Or D, Averkiou M. Recurring part arrangements in shape collections. Comput Graphics Forum, 2014, 33: 115-124 CrossRef Google Scholar

[17] Cohen-Or D, Chrysanthou Y L, Silva C T. A survey of visibility for walkthrough applications. IEEE Trans Visual Comput Graphics, 2003, 9: 412-431 CrossRef Google Scholar

[18] Mattausch O, Bittner J, Wimmer M. CHC+: Coherent Hierarchical Culling Revisited. Comput Graphics Forum, 2008, 27: 221-230 CrossRef Google Scholar

[19] Jia J Y, Wang W, Wang M F, et al. Multi-layered incremental & scalable sector of interest (MISSOI) based efficient progressive transmission of large-scale DVE scenes. Chinese J Comput, 2014, 37: 1324--1334. Google Scholar

[20] Gu W, Wang J, Shi H, et al. Research on a hybrid spatial index structure. J Comput Inf Syst, 2011, 7: 3972--3978. Google Scholar

[21] Terry J, Stantic B. Indexing method for multidimensional vector data. ComSIS, 2013, 10: 1077-1104 CrossRef Google Scholar

[22] Varduhn V, Mundani R P, Rank E. Real time processing of large data sets from built infrastructure. J Syst Cybernet Inf, 2011, 9: 63--67. Google Scholar

[23] Kang H, Lee G. Development of an object-relational IFC server. In: Proceedings of ICCEM/ICCPM, Jeju, 2009. Google Scholar

[24] Liu X, Xie N, Tang K. Lightweighting for Web3D visualization of large-scale BIM scenes in real-time. Graphical Model, 2016, 88: 40-56 CrossRef Google Scholar

[25] Volk R, Stengel J, Schultmann F. Building Information Modeling (BIM) for existing buildings - Literature review and future needs. Automation Construction, 2014, 38: 109-127 CrossRef Google Scholar

[26] van Kaick O, Zhang H, Hamarneh G. A Survey on Shape Correspondence. Comput Graphics Forum, 2011, 30: 1681-1707 CrossRef Google Scholar

[27] Kong Y, Dong W, Mei X, et al. SimLocator: robust locator of similar objects in images. Visual Comput. 2013, 29: 861--870. Google Scholar

[28] Zhu C, Yi R, Lira W, et al. Deformation-driven shape correspondence via shape recognition. ACM Trans Graph, 2017, 36: 51. Google Scholar

[29] Bouaziz S, Tagliasacchi A, Pauly M. Sparse iterative closest point. Comput Graph Forum, 2013, 32: 113--123. Google Scholar

[30] Lin Y H, Liu Y S, Gao G. The IFC-based path planning for 3D indoor spaces. Adv Eng Inf, 2013, 27: 189-205 CrossRef Google Scholar

[31] Amor R, Dimyadi J. An open repository of IFC data models and analyses to support interoperability deployment. In: Proceedings of the 27th Annual International CIB W78 Conference, Cairo, 2010. Google Scholar