Immersive Cooperative Work Environments (CWE): Designing Human-Building Interaction in Virtual Reality

Simple item page
dc.contributor.authorBjørn, Pernille
dc.contributor.authorWulff, Mark
dc.contributor.authorPetræus, Mathias Schmidt
dc.contributor.authorMøller, Naja Holten
dc.date.accessioned2022-04-13T08:21:15Z
dc.date.available2022-04-13T08:21:15Z
dc.date.issued2021
dc.date.issued2021
dc.description.abstractWe propose to extend CSCW research to include the design of buildings for cooperative work and to engage in designing Human-Building Interaction supporting cooperative practices. Concretely, we design and implement an immersive Cooperative Work Environment in Virtual Reality using real-life 3D architectural models of a hospital. We then invite healthcare practitioners to cooperatively resuscitate patients experiencing cardiac arrest in an immersive Cooperative Work Environment. This enabled the healthcare practitioners to identify critical functional errors (e.g. how asymmetric door design compromised resurrection practices in certain situations) that were not detected through other available architectural representations. Based upon our research, we identify three design dimensions essential to creating immersive Cooperative Work Environments: 1) the cooperative dimension, structured as the design of interdependence, articulation work, awareness, and grounding; 2) the professional work dimension, structured as the design of work practices, policies, artefacts, and professional language; and 3) the spatiotemporal dimension, structured as the design of loci and mobility. We also identified temporal orientation as a cross-spanning category relevant for all three design dimensions essential to participants’ navigating of the building. Temporal orientation in an immersive Cooperative Work Environment must accommodate the experience of sequential time, clock time, and action time.de
dc.identifier.doi10.1007/s10606-021-09395-3
dc.identifier.pissn1573-7551
dc.identifier.urihttp://dx.doi.org/10.1007/s10606-021-09395-3
dc.identifier.urihttps://dl.eusset.eu/handle/20.500.12015/4288
dc.publisherSpringer
dc.relation.ispartofComputer Supported Cooperative Work (CSCW): Vol. 30, No. 3
dc.relation.ispartofseriesComputer Supported Cooperative Work (CSCW)
dc.subjectAdvanced life support
dc.subjectALS
dc.subjectArchitecture
dc.subjectBIM
dc.subjectBuilding information models
dc.subjectCardiac arrest
dc.subjectCollaborative virtual reality
dc.subjectCooperative virtual environments
dc.subjectCVE
dc.subjectDomain-specific buildings
dc.subjectHealthcare
dc.subjectHospital
dc.subjectImmersive cooperative work environment
dc.subjectTemporal orientation
dc.subjectVR
dc.titleImmersive Cooperative Work Environments (CWE): Designing Human-Building Interaction in Virtual Realityde
dc.typeText/Journal Article
gi.citation.endPage391
gi.citation.startPage351
gi.citations.count9
gi.citations.elementPernille Bjørn, Maja Ling Han, Andrea Parezanovic, Per Larsen (2024): Social fidelity in cooperative virtual reality maritime training, In: Human–Computer Interaction, doi:10.1080/07370024.2024.2372716
gi.citations.elementRongguo Zhao (2023): Seismic Stability Assessment of Civil Building Projects Based on BIM Technology, In: Lecture Notes in Electrical Engineering, doi:10.1007/978-981-99-2092-1_58
gi.citations.elementEléni Economidou, Alina Itzlinger, Christopher Frauenberger (2024): Lived experience in human-building interaction (HBI): an initial framework, In: Frontiers in Computer Science, doi:10.3389/fcomp.2023.1233904
gi.citations.elementJuliana B. S. França, Jacimar F. Tavares, Angélica F. S. Dias, Marcos R. S. Borges (2023): Providing Situational Awareness to Emergency Responders Using Drones, In: IFIP Advances in Information and Communication Technology, doi:10.1007/978-3-031-34207-3_5
gi.citations.elementZiming Li, Yiming Luo, Jialin Wang, Yushan Pan, Lingyun Yu, Hai-Ning Liang (2024): Feasibility and performance enhancement of collaborative control of unmanned ground vehicles via virtual reality, In: Personal and Ubiquitous Computing 3-4(28), doi:10.1007/s00779-024-01799-4
gi.citations.elementSahand Azarby, Arthur Rice (2022): User Performance in Virtual Reality Environments: The Capability of Immersive Virtual Reality Systems in Enhancing User Spatial Awareness and Producing Consistent Design Results, In: Sustainability 21(14), doi:10.3390/su142114129
gi.citations.elementYee Sye Lee, Ali Rashidi, Amin Talei, Huai Jian Beh, Sina Rashidi (2023): A Comparison Study on the Learning Effectiveness of Construction Training Scenarios in a Virtual Reality Environment, In: Virtual Worlds 1(2), doi:10.3390/virtualworlds2010003
gi.citations.elementLiwen Zhang (2023): Future Interactions with Virtual Reality Technology (VR), In: Academic Journal of Science and Technology 3(6), doi:10.54097/ajst.v6i3.10167
gi.citations.elementRoohollah Taherkhani, Mohamadmahdi Aziminezhad (2023): Human-building interaction: A bibliometric review, In: Building and Environment, doi:10.1016/j.buildenv.2023.110493

Files

Collections

JCSCW Vol. 30 (2021)