Abstract
Most designs, especially architecture and product design, involve the collective efforts of multiple disciplinary teams. These kinds of designs encounter many problems because of the need to implement various experimental interactive installations as well as utilize innovative design methods and processes. According to the traditional process, these surfaces also require tailor-made construction processes in fabrication and assembly in order to test a proposed prototype. However, as component-based installation requires many people assisting with the assembly phase, team members require a dynamic process called Design-Fabrication-Assembly (DFA) to understand the method and process of the whole project. However allowing team members to participate in and understand the project is a problem for a novice design fabrication team. We propose a visualization system called Visualization System of DFA (ViDA) and refine the DFA process according to the problem encountered, where a large experimental interactive installation needs to be implemented. We also describe in detail three experiments, two projects, and two design models of communication media for a component-based installation to help the design team fabricate and assemble the prototype. The ViDA is evaluated by reflecting on the initial three experiments and reifying the two projects (i.e., the prototyping process). Results of the ViDA redesign and user analysis show that the visualization system meets the short-term time cost feature of prototyping and provides an effective way to collaborate with team members, including allowing multiple disciplinary groups with different knowledge to work together.
Similar content being viewed by others
References
Arduino (2018) Arduino manual. https://arduino.cc/
Azuma RT (1997) A survey of augmented reality. Presence: Teleoperators & Virtual Environments 6(4):355–385
Billinghurst M, Kato H (1999) Collaborative mixed reality. In: Proceedings of the first international symposium on mixed reality, pp 261–284
Biswas A, Biswas B (2017) Community-based link prediction. Multimed Tools Applic 76(18):18619–18639. https://doi.org/10.1007/s11042-016-4270-9
Chang TW, Datta S, Lai IC (2016) Modeling distributed interaction with dynamic agent role interplay system (daris). Int J Digit Media Des 8 (2):1–14
Chang TW, Huang HY, Datta S (2019) Design and fabrication of a responsive carrier component envelope. Buildings 9(4):84
Chen CY, Chang TW, Hsiao CF, Huang HY (2019) Developing an interactive fabrication process of maker based on “seeing-moving-seeing”model. In: Proceedings of the 2019 DigitalFUTURES. Springer, pp 312–321
Cheng YB, Chang TW, Yang CK (2019) Generation of design ideas using edos-touch. Des J 22(2):169–190
Davidova M, Sevaldson B (2016) 1:1, A Transdisciplinary Prototyping Studio. Warszaw University of Technology Faculty of Architecture
Fologram (2018) Fologram manual. https://fologram.com/
Goldschmidt G (2014) Linkography: unfolding the design process. Mit Press
Guo X, Wang J, Zhao W, Zhang K, Wang C (2016) Study of medical device innovation design strategy based on demand analysis and process case base. Multimed Tools Applic 75(22):14351–14365. https://doi.org/10.1007/s11042-015-3176-2
Hsieh TL, Chang TW (2017) Whether the relationscape of interaction design strategies during design process can be explained by linkography. In: 21st International Conference Information Visualisation (IV), pp. 14–19. https://doi.org/10.1109/iV.2017.79
Hsieh TL, Chang TW (2019) How to collective design-and-fabricating a weaving structure interaction design—six experiments using a design-fabrication-assembly (dfa) approach. In: The 4th RSU national and international research conference on science and technology, social sciences, and humanities 2019.(RSUSSH 2019)
Hsieh TL, Chang TW (2019) Vida: a visual system of dfa process for interactive surface. In: Wyeld TG, Banissi E, Ursyn A, Bannatyne M, Datia N, Sarfraz M (eds) 23 International conference information visualisation, pp 68–73. https://doi.org/10.1109/IV-2.2019.00022
Huang HY, Chang TW (2017) Surfacing repetitive design strategy with visualization tool. In: 21st International conference information visualisation (IV), pp 301–305. https://doi.org/10.1109/iV.2017.76
Huang W, Williams M, Luo D, Wu Y, Lin Y (2018) Rsu x tsinghua x yuntech weaving struc-ture and interactive space workshop. In: 23rd International conference on computer-aided architectural design research in asia (CAADRIA). Hong Kong
Huang W, Wu C, Huang J (2017) A weaving structure for design & construction of organic geometry. In: Proceedings of IASS annual symposia, pp 1–8. https://www.ingentaconnect.com/content/iass/piass/2017/00002017/00000007/art00007
Huang WX, Yan D, Luo P, Li X (2016) Digital design and construction of a weaving structure. In: The 8th international conference on fibre-reinforced polymer (FRP) composites in civil engineering (CICE 2016), Hong Kong. The 8th international conference on fibre-reinforced polymer (FRP) composites in civil engineering (CICE 2016). Hong Kong
Kim M, Park KB, Choi SH, Lee JY (2020) Inside-reachable and see-through augmented reality shell for 3d visualization and tangible interaction. Multimed Tools Applic 79(9):5941–5963
Langacker RW (1999) Virtual reality. Linguistic Sciences 29(2)
Lo CHN, Lai IC, Chang TW (2013) djoe: design jigsaw on site. In: International conference of design, user experience, and usability, pp 402–407
McNeel R (2018) Rhino 3d manual. https://rhino3d.com/
Microsoft (2018) Hololens document. https://www.microsoft.com/en-us/hololens
Nóbrega R, Correia N (2017) Interactive 3d content insertion in images for multimedia applications. Multimed Tools Applic 76(1):163–197. https://doi.org/10.1007/s11042-015-3031-5
Park JS (2011) Ar-room: a rapid prototyping framework for augmented reality applications. Multimed Tools Applic 55(3):725–746
Ryu SH, Kim HJ, Park JS, Kwon Yw, Jeong CS (2007) Collaborative object-oriented visualization environment. Multimed Tools Applic 32 (2):209–234. https://doi.org/10.1007/s11042-006-0066-7
Takahashi M, Yokozawa S, Mitsumine H, Itsuki T, Naoe M, Funaki S (2020) Real-time visualization of sword trajectories in fencing matches. Multimed Tools Appl, 1–15
Wang J, Yan W, Huang C (2020) Surface shape-based clustering for b-rep models. Multimed Tools Appl, 1–15
Weichel C, Lau M, Kim D, Villar N, Gellersen HW (2014) Mixfab: a mixed-reality environment for personal fabrication. In: Proceedings of the SIGCHI conference on human factors in computing systems. ACM, pp 3855–3864
Yan D, Huang WX, Song ZD (2016) Generation of weaving structure on free-form surface using a remeshing algorithm CUMINCAD
Yang M, Tao J, Chao L, Li H, Zhang D, Che H, Gao T, Liu B (2015) User behavior fusion in dialog management with multi-modal history cues. Multimed Tools Applic 74(22):10025–10051. https://doi.org/10.1007/s11042-014-2161-5
Zilles Borba E, Corrêa AG, de Deus Lopes R, Zuffo M (2020) Usability in virtual reality: evaluating user experience with interactive archaeometry tools in digital simulations. Multimed Tools Applic 79(5):3425–3447. https://doi.org/10.1007/s11042-019-07924-3
Acknowledgements
Authors would like to acknowledge Dr Walaiporn Nakapan for her contribution on ViDA system concept development and proof-reading on manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Chang, TW., Chen, CY., Huang, HY. et al. ViDA: developing a visualization system for a Design-Fabrication-Assembly (D-F-A) process. Multimed Tools Appl 81, 14617–14639 (2022). https://doi.org/10.1007/s11042-022-12179-6
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11042-022-12179-6