Research on the application of virtual reality technology in contemporary environmental design

被引：0

作者：

Su B. ^{[1
]}

Ren Q. ^{[2
]}

机构：

[1] College of Creative Design, Shanghai Industry & Commerce Foreign Language College, Shanghai

[2] Hefei Zhucaojian Culture and Art Communication Co., Ltd., Anhui, Hefei

来源：

Applied Mathematics and Nonlinear Sciences | 2024年 / 9卷 / 01期

关键词：

3D reconstruction technology; LOD technology; Para-polar geometry; Single response matrix; Virtual reality technology;

D O I：

10.2478/amns.2023.2.00622

中图分类号：

学科分类号：

摘要：

The development and application of virtual reality technology can help the innovative application of environmental design. This paper first focuses on the application of virtual reality technology in the natural environment based on the development of environmental design and the integration of natural geographical conditions. In fact, the focus is on the analysis of virtual reality technology. Selected 3D reconstruction technology algorithms, including camera calibration profile, pair of polar geometry and single response matrix, matching cost and quality assessment index. Finally, the natural environment simulation experiment is constructed based on virtual reality technology. The average real-time rendering FPS of the unoptimized vegetation distribution interval decreases continuously with the increase in the number of vegetation models. When the average vegetation number is around 54,672, the average FPS decreases to around per 53. When the average vegetation count is at 97,713, the average FPS drops to about 28 frames per second. The average real-time dye FPS stabilizes at around 50 after using the LOD multi-detail hierarchical model. © 2023 Bingjie Su and Qing Ren, published by Sciendo.

引用

共 20 条

[1]

Ikl S., Baran Z., Aslan S., Developing an auxiliary tool for treatment of specific phobias via virtual reality technology applications: an effectiveness study, Journal of Clinical Psychiatry, 22, 3, (2019)

[2]

Yap H.J., Tan C.H., Phoon S.Y., Kan E.L., Sekaran S.C., Process planning and scheduling for loop layout robotic workcell using virtual reality technology, Advances in Mechanical Engineering, 11, 9, pp. 899-919, (2019)

[3]

Gs A., Virtual reality technology for experiential learning in global health training curricula: a prototype for testing, The Lancet Global Health, 7, (2019)

[4]

Alashram A.R., Annino G., Padua E., Romagnoli C., Mercuri N.B., Cognitive rehabilitation post traumatic brain injury: a systematic review for emerging use of virtual reality technology, Journal of Clinical Neuroscience, 65, pp. 209-219, (2019)

[5]

Shaw C., Washington E., Alavi C.C., Ray A., Carden K.D., Duncan A.C., Et al., Enhancing dementia care and building empathy through the integration of virtual reality technology and art therapy, Alzheimer’s and Dementia, 14, 7, pp. P934-P935, (2018)

[6]

Speight L., Prosser A., O'Leary C., Edwards V., Bridges C., Hapgood G., Et al., Ws12.1 pioneering virtual reality technology for distraction therapy at the all wales adult cf centre, Journal of Cystic Fibrosis, 17, (2018)

[7]

Zhalechian M., Tavakkoli-Moghaddam R., Rahimi Y., Jolai F., An interactive possibilistic programming approach for a multi-objective hub location problem: economic and environmental design, Applied Soft Computing, 52, 100, pp. 699-713, (2017)

[8]

Chiari A., Pistoresi B., Galli C., Tondelli M., Zamboni G., Determinants of caregiver burden in early onset dementia: psychosocial factors and environmental design / social networks, Alzheimer’s and Dementia, 16, S7, (2020)

[9]

Mackrill J., Marshall P., Payne S.R., Dimitrokali E., Cain R., Using a bespoke situated digital kiosk to encourage user participation in healthcare environment design, Applied Ergonomics, 59, pp. 342-356, (2017)

[10]

Tedeschi A., Calcaterra S., Benedetto F., Ultrasonic radar system (uras): arduino and virtual reality for a light-free mapping of indoor environments, IEEE Sensors Journal, pp. 4595-4604, (2017)

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