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A DECISION SUPPORT SYSTEM PROPOSAL ON THE USAGE OF EXTENDED REALITY SDKS IN AEC DISCIPLINES

Year 2022, - Vol.23 - 16th DDAS (MSTAS) Special Issue -2022, 17 - 30, 23.12.2022
https://doi.org/10.18038/estubtda.1165368

Abstract

Technology is employed in the fields of architecture, engineering, and construction (AEC) for characteristics like producing visual representations and offering assistance during the building phase. Both users and creators of these tools are able to immediately take advantage of the technology's potential as well as create a variety of workarounds for its drawbacks. Both viewpoints will be looked at in this study with regard to mobile extended reality SDKs (software development kit). By excluding the articles that did not provide the relevant information, this research concentrates solely on the papers that discuss the technological aspects of the SDK that were used, the opportunities the SDK offers, and/or the flaws of the SDK. The study's main objective is to compare the technological contributions made by the SDKs employed in the scope of the examined literature to the AEC disciplines and to the contexts in which such contributions are made. Through applications in literature research, the study aims to highlight the contributions of mobile extended reality SDKs to the fields of architecture, engineering, and construction. An entry-level developer can use the SDKs in accordance with his work by using the comparison diagrams, produced in this study, to see the relationships and comparisons between them, as well as to build a framework for what uses should be made in which domains. The technological capabilities and constraints of SDKs have an impact on how research is designed. Making relationality diagrams on the SDK to use and the effects it will have throughout the research phase is also crucial. As a result of the research, SDKs permit flexible uses in a variety of sectors, and their use also financially and logistically supports literature studies.

Supporting Institution

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Project Number

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Thanks

We appreciate the advice, lectures, and regular supervision provided by Prof. Leman Figen Gül and Assoc. Prof. Sema Alaçam of Istanbul Technical University for this study.

References

  • [1] Yao J, Lin Y, Zhao, Yan C, Chang-lin L, Yuan P. Augmented reality technology based wind environment visualisation. CAADRIA, 2018. pp. 369-377.
  • [2] Abe U, Hotta K, Hotta A., Takami Y, Ikeda H, Ikeda Y. Digital construction: Demonstration of interactive assembly using smart discrete papers with RFID and AR codes. CAADRIA, 2017. pp. 75-85.
  • [3] Silcock D, Schnabel MA, Moleta T, Brown A. Participatory AR: A parametric design instrument. Hong Kong: CAADRIA, 2021.
  • [4] Yao J, Lin Y, Zhao Y, Yan C, Li C, Yuan PF. Augmented reality in the design process: Using visual effects (VFX) motion tracking techniques to conduct quantification research on the performance of augmented reality. eCAADe 36, 2018.
  • [5] Gül LF. Studying architectural massing strategies in co-design mobile augmented reality tool versus 3d virtual world. eCAADe 35, 2017.
  • [6] Sun M, Sun P, Dong Y, Lopez JLGDC. Mass production: Towards multidimensional, real-time feedback in early stages of urban design processes. Hong Kong: CAADRIA, 2021.
  • [7] Goepel G. Augmented construction: Impact and opportunity of mixed reality integration in architectural design implementation. ACADIA, 2019.
  • [8] Jahn G, Newnham C, Berg N, Beanland M. Making in mixed reality: Holographic design, fabrication, assembly, and analysis of woven steel structures. ACADIA, 2018.
  • [9] Chaltiel S, Bravo M, Chronis A. Digital fabrication with virtual and augmented reality for monolithic shells. eCAADe 35, 2017.
  • [10] Kontovourkis O, Georgiou C, Stroumpoulis A, Kounnis C, Dionyses C, S. Bagdati. Implementing augmented reality for the holographic assembly of a modular shading device. eCAADe 37/SIGraDi 23, 2019.
  • [11] Song Y, Koeck R, Luo S. AR Digi-Component: AR-assisted, real-time, immersive design and robotic fabrication workflow for parametric architectural structures. CAADRIA, 2021.
  • [12] Hashimoto J, Park HJ. Dance with Shadows: Capturing tacit knowledge with smart device augmented reality (SDAR). eCAADe 38, 2020.
  • [13] Song Y. BloomShell: Augmented reality for the assembly and real-time modification of complex curved structure. eCAADe, 2020. pp 345-354.
  • [14] Goepel G, Crolla K. Augmented reality-based collaboration: ARgan, a bamboo art installation case study. Hong Kong: CAADRIA, 2020. pp. 313-322.
  • [15] Betti G, Aziz S, Ron G. Pop up factory : Collaborative design in mixed reality interactive live installation for the makecity festival. eCAADe 37/SIGraDi 23, 2019. pp. 115-124.
  • [16] Syahputra MF, Hardywantara F, Andayani U. Augmented reality virtual house model using ARCore technology based on android. journal of physics: Conference Series, 2018.
  • [17] Grasser A. Towards an architecture of collaborative objects. eCAADe 37 / SIGraDi 23, 2019. pp. 325-332.
  • [18] Ashour Z, Yan W. BIM-powered augmented reality for advancing human-building interaction. eCAADe, 2020. pp. 169-178.
  • [19] Narazani M, Eghtebas C, Klinker G, Jenney SL, Mühlhaus M, Petzold F. Extending AR interaction through 3D printed tangible interfaces in an urban planning context. New Orleans:UIST'19, 2019. pp. 116-118.
  • [20] Fazel A, Izadi A. An interactive augmented reality tool for constructing free-form modular surfaces. Automation in Construction, 2018. pp. 135-145.
  • [21] Zhang Y, Kwok TH. Design and interaction interface using augmented reality for smart manufacturing. Texas: 46th SME North American Manufacturing Research Conference, 2018. pp. 1278-1286.
  • [22] Koch V, Ritterbusch S, Kopmann A, Müller M, Habel T, Both P. Flying augmented reality: Supporting planning and simulation analysis by combining mixed reality methods using multicopter and pattern recognition. eCAADe 29, 2011. pp. 843-849.
  • [23] Mirshokraei M, Gaetani CI, Migliaccio F. A Web-Based BIM–AR Quality Management System for Structural Elements. MDPI, Applied Sciences, 2019.
  • [24] Yan L, Fukuda T, Yabuki N. Integrating UAV development technology with augmented reality toward landscape. Hong Kong: CAADRIA, 2019. pp. 423-432.
  • [25] Carozza L, Valero E, Bosché F, Banfill G, Mall R, Nguyen M. Urbanplanar: BIM mobile visualisation in urban environments with occlusion-aware augmented reality. Heraklion: Proceedings of the Joint Conference in Computing in Construction, 2017.

A DECISION SUPPORT SYSTEM PROPOSAL ON THE USAGE OF EXTENDED REALITY SDKS IN AEC DISCIPLINES

Year 2022, - Vol.23 - 16th DDAS (MSTAS) Special Issue -2022, 17 - 30, 23.12.2022
https://doi.org/10.18038/estubtda.1165368

Abstract

Project Number

-

References

  • [1] Yao J, Lin Y, Zhao, Yan C, Chang-lin L, Yuan P. Augmented reality technology based wind environment visualisation. CAADRIA, 2018. pp. 369-377.
  • [2] Abe U, Hotta K, Hotta A., Takami Y, Ikeda H, Ikeda Y. Digital construction: Demonstration of interactive assembly using smart discrete papers with RFID and AR codes. CAADRIA, 2017. pp. 75-85.
  • [3] Silcock D, Schnabel MA, Moleta T, Brown A. Participatory AR: A parametric design instrument. Hong Kong: CAADRIA, 2021.
  • [4] Yao J, Lin Y, Zhao Y, Yan C, Li C, Yuan PF. Augmented reality in the design process: Using visual effects (VFX) motion tracking techniques to conduct quantification research on the performance of augmented reality. eCAADe 36, 2018.
  • [5] Gül LF. Studying architectural massing strategies in co-design mobile augmented reality tool versus 3d virtual world. eCAADe 35, 2017.
  • [6] Sun M, Sun P, Dong Y, Lopez JLGDC. Mass production: Towards multidimensional, real-time feedback in early stages of urban design processes. Hong Kong: CAADRIA, 2021.
  • [7] Goepel G. Augmented construction: Impact and opportunity of mixed reality integration in architectural design implementation. ACADIA, 2019.
  • [8] Jahn G, Newnham C, Berg N, Beanland M. Making in mixed reality: Holographic design, fabrication, assembly, and analysis of woven steel structures. ACADIA, 2018.
  • [9] Chaltiel S, Bravo M, Chronis A. Digital fabrication with virtual and augmented reality for monolithic shells. eCAADe 35, 2017.
  • [10] Kontovourkis O, Georgiou C, Stroumpoulis A, Kounnis C, Dionyses C, S. Bagdati. Implementing augmented reality for the holographic assembly of a modular shading device. eCAADe 37/SIGraDi 23, 2019.
  • [11] Song Y, Koeck R, Luo S. AR Digi-Component: AR-assisted, real-time, immersive design and robotic fabrication workflow for parametric architectural structures. CAADRIA, 2021.
  • [12] Hashimoto J, Park HJ. Dance with Shadows: Capturing tacit knowledge with smart device augmented reality (SDAR). eCAADe 38, 2020.
  • [13] Song Y. BloomShell: Augmented reality for the assembly and real-time modification of complex curved structure. eCAADe, 2020. pp 345-354.
  • [14] Goepel G, Crolla K. Augmented reality-based collaboration: ARgan, a bamboo art installation case study. Hong Kong: CAADRIA, 2020. pp. 313-322.
  • [15] Betti G, Aziz S, Ron G. Pop up factory : Collaborative design in mixed reality interactive live installation for the makecity festival. eCAADe 37/SIGraDi 23, 2019. pp. 115-124.
  • [16] Syahputra MF, Hardywantara F, Andayani U. Augmented reality virtual house model using ARCore technology based on android. journal of physics: Conference Series, 2018.
  • [17] Grasser A. Towards an architecture of collaborative objects. eCAADe 37 / SIGraDi 23, 2019. pp. 325-332.
  • [18] Ashour Z, Yan W. BIM-powered augmented reality for advancing human-building interaction. eCAADe, 2020. pp. 169-178.
  • [19] Narazani M, Eghtebas C, Klinker G, Jenney SL, Mühlhaus M, Petzold F. Extending AR interaction through 3D printed tangible interfaces in an urban planning context. New Orleans:UIST'19, 2019. pp. 116-118.
  • [20] Fazel A, Izadi A. An interactive augmented reality tool for constructing free-form modular surfaces. Automation in Construction, 2018. pp. 135-145.
  • [21] Zhang Y, Kwok TH. Design and interaction interface using augmented reality for smart manufacturing. Texas: 46th SME North American Manufacturing Research Conference, 2018. pp. 1278-1286.
  • [22] Koch V, Ritterbusch S, Kopmann A, Müller M, Habel T, Both P. Flying augmented reality: Supporting planning and simulation analysis by combining mixed reality methods using multicopter and pattern recognition. eCAADe 29, 2011. pp. 843-849.
  • [23] Mirshokraei M, Gaetani CI, Migliaccio F. A Web-Based BIM–AR Quality Management System for Structural Elements. MDPI, Applied Sciences, 2019.
  • [24] Yan L, Fukuda T, Yabuki N. Integrating UAV development technology with augmented reality toward landscape. Hong Kong: CAADRIA, 2019. pp. 423-432.
  • [25] Carozza L, Valero E, Bosché F, Banfill G, Mall R, Nguyen M. Urbanplanar: BIM mobile visualisation in urban environments with occlusion-aware augmented reality. Heraklion: Proceedings of the Joint Conference in Computing in Construction, 2017.
There are 25 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Esranur Karacif 0000-0002-3173-8687

Ethem Gürer 0000-0002-3482-2526

Project Number -
Publication Date December 23, 2022
Published in Issue Year 2022 - Vol.23 - 16th DDAS (MSTAS) Special Issue -2022

Cite

AMA Karacif E, Gürer E. A DECISION SUPPORT SYSTEM PROPOSAL ON THE USAGE OF EXTENDED REALITY SDKS IN AEC DISCIPLINES. Eskişehir Technical University Journal of Science and Technology A - Applied Sciences and Engineering. December 2022;23:17-30. doi:10.18038/estubtda.1165368