Augmented Reality System Specification for Placemaking
الموضوعات :
Hossein Amin Pour Pirjel
1
(PhD Candidate, Department of Civil Engineering, Architecture and Art, Science and Research Branch, Islamic Azad University, Tehran, Iran)
Farah Habib
2
(Professor; Department of Architecture,, Science and Research Branch, Islamic Azad University, Tehran, Iran.)
Zahra Sadat Saeideh Zarabadi
3
(Assistant professor, Department of Art and Architecture, Science and Research, Islamic Azad University, Tehran , Iran.)
Vahdaneh Fooladi
4
(Assistant Professor, Dept. of Civil Engineering, Architecture and Art, Science and Research Branch, Islamic Azad University, Tehran, Iran)
الکلمات المفتاحية: Augmented Reality, design, construction, procurement, system specification, stakeholders management, placemaking,
ملخص المقالة :
Augmented reality (AR) builds better participation for placemaking by focusing on real time features, communication, and direct information flow between project stakeholders. This study attempts to access to specification of the Augmented Reality System for Placemaking (ARSP) model and make the research a basis for a profitable e-business model. By investigating AR and placemaking, this research seeks to build an augmented reality system specification of the information flow and communication for project stakeholders' management. This paper explores the potential for using AR technology in interior design by three-dimensional (3D) and two-dimensional (2D) and façade placemaking by 2D textures of brick material. The system consists of a qualitative proof of concept (POC) model, a prototype model, and a minimum vital product (MVP) model to study to compel quantitative research. The ARSP POC model, prototype model, and MVP model are programmed by building an information modeling (BIM) system, Revit and Unity software, and different software development kits (SDKs) as an application for Android devices. Seventy-four experts tested the MVP model in the Delphi method and observed, interviewed, and filled out a questionnaire. The research shows that the contributions of this study to the body of knowledge are twofold. First, this study extends the understanding of AR applications in placemaking. Second, this study identifies possible improvements using AR systems in design, procurement, and construction.
Amin, D., & Govilkar, S. (2015). Comparative study of augmented reality SDKs. International Journal on Computational Science & Applications, 5(1), 11-26.
Arefi, M. (2014). Deconstructing placemaking: Needs, opportunities, and assets. Routledge.
Azuma, R. (1997), “A survey of augmented reality.” Teleoperators and Virtual Environments, 16(4), 355-385.
Bacon, E. N., & Walduck, K. (1967). Design of Cities. New York: Penguin Books
Bae, H., Golparvar-Fard, M., & White, J. (2013). High-precision vision-based mobile augmented reality system for context-aware architectural, engineering, construction, and facility management (AEC/FM) applications. Visualization in Engineering, 1(1), 1-13.
Balali, V., Zalavadia, A., & Heydarian, A. (2020). Real-time interaction and cost estimating within immersive virtual environments. Journal of Construction Engineering and Management, 146(2), 04019098.
Bourhim, E. M., & Akhiate, A. (2022). Augmented Reality SDK’s: A Comparative Study. In International Conference on Intelligent Systems Design and Applications (pp. 559-566). Springer, Cham.
Brown, R., & Barros, A. (2011). Towards a service framework for remote sales support via augmented reality. In Web Information Systems Engineering–WISE 2011 and 2012 Workshops (pp. 335-347). Springer, Berlin, Heidelberg.
Bu, S., Shen, G., Anumba, C., Wong, A. and Liang, X. (2015), “Literature review of green retrofit design for commercial buildings with BIM implication,” Smart and Sustainable Built Environment, 4(2), 188-214.
Cohen, L., Manion, L., & Morrison, K. (2007). Research Methods in Education (6th ed.). London and New York, NY: Routledge Falmer.
Cullen, G. (2012). Concise townscape. London: Routledge.
Chen, K., Lu, W., Peng, Y., Rowlinson, S. and Huang, G.Q. (2015), “Bridging BIM and building: from a literature review to an integrated conceptual framework,” International Journal of Project Management, 33(6), 1405-1416.
Chen, K. & Xue, F. (2020), "The renaissance of augmented reality in construction: history, present status, and future directions," Smart and Sustainable Built Environment, Vol. ahead-of-print No. ahead-of-print.
Cheng, J. C., Chen, K., & Chen, W. (2020). State-of-the-art review on mixed reality applications in the AECO industry. Journal of Construction Engineering and Management, 146(2), 03119009.
Chu, M., Matthews, J., & Love, P. E. (2018). Integrating mobile building information modelling and augmented reality systems: an experimental study. Automation in Construction, 85, 305-316.
Dacko, S. G. (2017). Enabling smart retail settings via mobile augmented reality shopping apps. Technological forecasting and social change, 124, 243-256.
Dayaratne, R. (1992). Supporting people's placemaking theory and practice: the case of support housing in Sri Lanka (Doctoral dissertation, the University of Newcastle upon Tyne).
Delgado, J. M. D., Oyedele, L., Beach, T., & Demian, P. (2020). Augmented and virtual reality in construction: drivers and limitations for industry adoption. Journal of Construction Engineering and Management, 146(7).
Egger, J., Masood, T., (2019), Augmented Reality in Support of Intelligent Manufacturing – A Systematic Literature Review, Computers & Industrial Engineering, 140.
Ernstsen, S. N., Whyte, J., Thuesen, C., & Maier, A. (2021). How innovation champions frame the future: Three visions for digital transformation of construction. Journal of Construction Engineering and Management, 147(1).
Govindarajan, U. H., Trappey, A. J., & Trappey, C. V. (2018). Immersive technology for human-centric cyberphysical systems in complex manufacturing processes: a comprehensive overview of the global patent profile using collective intelligence. Complexity, 2018.
Hewett, T. T., Baecker, R., Card, S., Carey, T., Gasen, J., Mantei, M., ... & Verplank, W. (1992). ACM SIGCHI curricula for human-computer interaction. ACM.
Joshi, A., Kale, S., Chandel, S., & Pal, D. K. (2015). Likert scale: Explored and explained. British journal of applied science & technology, 7(4), 396.
Kalkofen, D., Mendez, E. and Schmalstieg, D. (2009), “Comprehensible visualization for augmented reality.” Visualization and Computer Graphics, IEEE Transactions, 15(2), 193-204.
Kamat, V. R., Martinez, J. C., Fischer, M., Golparvar-Fard, M., Peña-Mora, F., & Savarese, S. (2011). Research in visualization techniques for field construction. Journal of construction engineering and management, 137(10), 853-862.
Kim, S. L., Suk, H. J., Kang, J. H., Jung, J. M., Laine, T. H., & Westlin, J. (2014). Using Unity 3D to facilitate mobile augmented reality game development. In 2014 IEEE World Forum on Internet of Things (WF-IoT) (pp. 21-26). IEEE.
Li, X., Yi, W., Chi, H. L., Wang, X., & Chan, A. P. (2018). A critical review of virtual and augmented reality (VR/AR) applications in construction safety. Automation in Construction, 86, 150-162.
Milgram, P., Takemura, H., Utsumi, A., & Kishino, F. (1995, December). Augmented reality: A class of displays on the reality-virtuality continuum. In Telemanipulator and telepresence technologies (Vol. 2351, pp. 282-292). International Society for Optics and Photonics.
Newman, C., Edwards, D., Martek, I., Lai, J., Thwala, W.D. and Rillie, I. (2020), "Industry 4.0 deployment in the construction industry: a bibliometric literature review and UK-based case study", Smart and Sustainable Built Environment, 10(4), 557-580.
Norman, D. (1993). Things That Make Us Smart. Reading, MA: Addison-Wesley.
Noghabaei, M., Heydarian, A., Balali, V., & Han, K. (2020). Trend analysis on adoption of virtual and augmented reality in the architecture, engineering, and construction industry. Data, 5(1), 26.
Pallasmaa, J. (2012). The eyes of the skin: Architecture and the senses. John Wiley & Sons.
