Обзор технологии лазерного сканирования для исторического информационного моделирования зданий и сооружений в Санкт-Петербурге

Автор: Баденко Владимир, Зотов Кирилл, Зотов Дмитрий, Гарг Рахул Д, Жан Ли, Болсуновская Марина, Федотов Александр

Журнал: Строительство уникальных зданий и сооружений @unistroy

Статья в выпуске: 1 (52), 2017 года.

Бесплатный доступ

Историческое информационное моделирование зданий (HBIM) - это новая технология, используемая для документирования и управления существующими историческими зданиями. Цель работы - разработать единую технологию для обработки, хранения и визуализации данных лазерного сканирования и фотографий исторических зданий, основанной на алгоритмах декодирования и векторизации в качестве информационной основы, для исторического архитектурного наследия в Санкт-Петербурге. Первый результат применения технологии к историческому зданию (Гидробашни Санкт-Петербургского Политехнического университета Петра Великого) показывает надежность предлагаемой технологии. Баденко В., Зотов К., Зотов Д., Гарг Р. Д., Жан Л., Болсуновская М., Федотов А., Обзор технолоuии лазерного сканирования для исторического информационного моделирования зданий и сооружений

Еще

Архитектура, здания, сканирование лазерных сканеров, историческое здание, информационное моделирование, культурное наследие, моделирование программного обеспечения

Короткий адрес: https://sciup.org/14322367

IDR: 14322367 | DOI: 10.18720/CUBS.52.8

Список литературы Обзор технологии лазерного сканирования для исторического информационного моделирования зданий и сооружений в Санкт-Петербурге

Bond S., Worthing D. Managing Built Heritage: Role of Cultural Significance. Wiley-Blackwell. London, 2016. 280 p.
Khodeir L.M., Aly D., Tarek S. Integrating HBIM (Heritage Building Information Modeling) Tools in the Application of Sustainable Retrofitting of Heritage Buildings in Egypt. Procedia Environmental Sciences. 2016. Vol. 34. Pp. 258 -270.
Lembo F., Marino F.P.R., Ambrosecchia N. Sustainability in civil engineering: integrated mix of some non-invasive sensing techniques for conservation and restoration of historical buildings and frescoes. Procedia Engineering. 2011. Vol. 21. Pp. 446-456.
Tapete D., Casagli N., Luzi G., Fanti R., Gigli G., Leva D. Integrating radar and laser-based remote sensing techniques for monitoring structural deformation of archaeological monuments. Journal of Archaeological Science. 2013. Vol. 40. Pp. 176-189.
Mansir D., Muhammad J.A., Kasim N. Reviewing the need for historical building information modeling (HBIM) in the conservation of heritage buildings in Melaka world heritage city. The Social Sciences. 2016. Vol. 11. No. 11. Pp. 2777-2782.
Biagini C., Capone P., Donato V., Facchini N. Towards the BIM implementation for historical building restoration sites. Automation in Construction. 2016. Vol. 71. Pp. 74-86.
Allen P.K., Troccoli A., Smith B., Murray S., Stamos I., Leordeanu M. New Methods for Digital Modeling of Historic Sites. IEEE Computer Graphics and Applications. 2003. Vol. 23. No. 6. 32-41.
Murphy M., McGovern E., Pavia S. Historic Building Information Modelling -Adding intelligence to laser and image based surveys of European classical architecture. ISPRS Journal of Photogrammetry and Remote Sensing. 2013. Vol. 76. Pp. 89-102.
Volk R., Stengel J., Schultmann F. Building Information Modeling (BIM) for existing buildings -Literature review and future needs. Automation in Construction. 2014. Vol. 38. Pp. 109-127.
Barber D.M., Dallas R.W., Mills J.P. Laser scanning for architectural conservation. Journal of Architectural Conservation. 2006. Vol. 12. Pp. 35-52.
Murphy M., Mcgovern E., Pavia S. Historic building information modelling (HBIM). Structural Survey. 2009. Vol. 27. No.4. Pp. 311-327.
Remondino F. Heritage recording and 3D modeling with photogrammetry and 3D scanning. Remote Sensing. 2011. Vol. 3. No. 6. Pp. 1104-1138.
Barazzetti L., Banfi F., Brumana R., Oreni D., Previtali M., Roncoroni F. HBIM and augmented information: Towards a wider user community of image and range-based reconstructions. International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences -ISPRS Archives. 2015. Vol. 40. No. 5W7. Pp. 35-42. Строительство уникальных зданий и сооружений, 2017 №1(52) Construction of Unique Buildings and Structures, 2017, №1(52)
Баденко В., Зотов К., Зотов Д., Гарг Р. Д., Жан Л., Болсуновская М., Федотов А., Обзор технолоuии лазерного сканирования для исторического информационного моделирования зданий и сооружений в Санкт-Петербурге, Россия/Badenko V., Zotov K., Zotov D., Garg R.D., Zhang L., Bolsunovskaya M., Fedotov A. Laser Scanner Survey Technologies for Historic Building Information Modeling of Heritage Resources in Saint-Petersburg, Russia©
Oreni D., Cuca B., Brumana R. Three-dimensional virtual models for better comprehension of architectural heritage construction techniques and its maintenance over time. Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics). 2012. Vol. 7616. Pp. 533-542.
Pesci A., Bonali E., Galli C., Boschi E. Laser scanning and digital imaging for the investigation of an ancient building: Palazzo d'Accursio study case (Bologna, Italy). Journal of Cultural Heritage. 2012. Vol. 13. No.2. Pp. 215-220.
Rüther H., Chazan M., Schroeder R., Neeser R., Held C., Walker S.J., Matmon A., Horwitz L.K. Laser scanning for conservation and research of African cultural heritage sites: the case study of Wonderwerk Cave, South Africa. Journal of Archaeological Science. 2009. Vol. 36. No. 9. Pp. 1847-1856.
Geymen A. Development of an information and management system for recording, analysis, protection and revitalization of cultural heritage application case study of Istanbul. Lasers in Engineering. 2009. Vol. 19. No. 1-2. Pp. 93-108.
Chen C., Yang B. Dynamic occlusion detection and inpainting of in situ captured terrestrial laser scanning point clouds sequence. ISPRS Journal of Photogrammetry and Remote Sensing. 2016. Vol. 119. Pp. 90-107.
Zlot R., Bosse M., Greenop K., Jarzab Z., Juckes E., Roberts J. Efficiently capturing large, complex cultural heritage sites with a handheld mobile 3D laser mapping system. Journal of Cultural Heritage. 2014. Vol. 15. No. 6. Pp. 670-678.
Styliadis A.D. Digital documentation of historical buildings with 3-d modelling functionality. Automation in Construction, 2007. Vol. 16. No. 4. Pp. 498-510.
Prizeman O.E.C. HBIM and matching techniques: Considerations for late nineteenth-and early twentieth-century buildings. Journal of Architectural Conservation. 2015. Vol. 21. No. 3. Pp. 145-159.
Barazzetti L., Banfi F., Brumana R., Gusmeroli G., Previtali M., Schiantarelli G. Cloud-to-BIM-to-FEM: Structural simulation with accurate historic BIM from laser scans. Simulation Modelling Practice and Theory. 2015. Vol. 57. Pp. 71-87.
Oreni D. From 3D content models to HBIM for conservation and management of built heritage. Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics). 2013. Vol. 7974. No. 4. Pp. 344-357.
Kurtener D., Badenko V. A GIS methodological framework based on fuzzy sets theory for land use management. Journal of the Brazilian Computer Society. 2000. Vol. 6. No. 3. Pp. 26-35.
Arefiev N., Terleev V., Badenko V. GIS-based fuzzy method for urban planning. Procedia Engineering. 2015. Vol. 117. Pp. 39-44.
Singh P.P., Garg R.D. Regional electricity consumption analysis for consumers using data mining techniques and consumer meter reading data. Communications in Computer and Information Science. 2013. Vol. 276. Pp. 262-271.
Kozlova T. On the method of information modeling of monuments of wooden architecture. Proceedings of the Novosibirsk State Architecture and Construction University (Sibstrin). 2011. Vol. 14. № 3 (52). Pp. 6-8.
Melnikova O.G., Oleynikov P.P. Information modeling of buildings: experience of reconstruction of monuments of cultural heritage. City sociology. 2013. № 4. Pp. 72-80.
Kozlova T., Talapov V. On the technique of application of BIM in modeling of architecture monuments. Architecture and Modern Information Technologies. 2010. № 3 (12). Pp. 11-18.
Anikeeva S. Experience using BIM technology for musefication wooden architectural monuments. Bulletin of the Tomsk State University. Cultural and art history. 2014. № 1 (13). Pp. 31-36.
Kozlova T., Kulikova S., Talapov V., Guanying Z. BIM and monuments of wooden architecture. Historical science. Information technology and mathematical methods in historical research and education. 2014. № 2-3 (8-9). Pp. 50-73.
De Luca L., Busayarat C., Stefani C., Véron P., Florenzano M. A semantic-based platform for the digital analysis of architectural heritage. Computers and Graphics. 2011. Vol. 35. No. 2. Pp. 227-241.
Quintana B., Prieto S.A., Adán A., Vázquez A.S., Semantic scan planning for indoor structural elements of buildings. Advanced Engineering Informatics. 2016. Vol. 30. No. 4. Pp. 643-659.
Suchocki C., Katzer J. An example of harnessing Terrestrial Laser Scanner for remote sensing of saturation of chosen building materials. Construction and Building Materials. 2016. Vol. 122. Pp. 400-405.
Wang C., Cho Y.K., Kim C. Automatic BIM component extraction from point clouds of existing buildings for sustainability applications. Automation in Construction. 2015. Vol. 56, Pp. 1-13.
Huang H., Sester, M. A hybrid approach to extraction and refinement of building footprints from airborne LIDAR data. International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences -ISPRS Archives. 2011. Vol. 38. No. 4W25. Pp. 153-158.
Barazzetti L. Parametric as-built model generation of complex shapes from point clouds. Advanced Engineering Informatics. 2016. Vol. 30. No. 3. Pp. 298-311.
Göçer Ö., Hua Y., Göçer K. A BIM-GIS integrated pre-retrofit model for building data mapping. Building Simulation. 2016. Vol. 9. No. 5. Pp. 513-527.
Huang H., Brenner C., Sester M. A generative statistical approach to automatic 3D building roof reconstruction from laser scanning data. ISPRS Journal of Photogrammetry and Remote Sensing. 2013. Vol. 79. Pp 29-43.
Sheng W., Hasegawa K., Okamoto A., Tanaka S. Visualizing the architectural structure of a historical building by clustering its laser-scanned point cloud. Communications in Computer and Information Science. 2016. Vol. 645, Pp. 3-
Kaasalainen S., Jaakkola A., Kaasalainen M., Krooks A., Kukko A. Analysis of incidence angle and distance effects on terrestrial laser scanner intensity: Search for correction methods. Remote Sensing. 2011. Vol. 3. No. 10. Pp. 2207-2221.
Demir N. Use of airborne laser scanning data and image-based three-dimensional. Lasers in Engineering. 2015. Vol.32.No. 3-4. Pp. 173-205.
Druzhkov P.N., Erukhimov V.L., Zolotykh N.Y., Kozinov E.A., Kustikova V.D., Meerov I.B., Polovinkin A.N. New object detection features in the OpenCV library. Pattern Recognition and Image Analysis. 2011. Vol.21. No.3. Pp. 384-386.

Еще

Статья научная