ارایه چارچوب نظری طراحی فضای غیرماده معماری بر مبنای TRUSTدر موج چهارم تعامل انسان و کامپیوتر(HCI)
سیده مستوره موسوی
1
(
پژوهشگر دوره دکتری، دانشکده معماری و شهرسازی، دانشگاه آزاد اسلامی واحد تهران مرکزی، تهران، ایران.
)
وحید شالی امینی
2
(
استادیار، گروه معماری و شهرسازی، دانشگاه آزاد اسلامی واحد تهران مرکزی، تهران، ایران.
)
مهدی خاکزند
3
(
دانشیار، گروه معماری، دانشگاه علم و صنعت ایران، تهران، ایران.
)
مرتضی رهبر
4
(
استادیار، گروه معماری، دانشگاه علم و صنعت ایران، تهران، ایران.
)
پریسا علیمحمدی
5
(
استادیار، گروه معماری و شهرسازی، دانشگاه آزاد اسلامی واحد تهران مرکزی، تهران، ایران.
)
کلید واژه: HCI, تعامل انسان و تکنولوژی, اعتماد, واقعیت مجازی (VR), فضای غیرماده معماری, طراحی انسان شناسانه ,
چکیده مقاله :
مواجه انسان و تکنولوژی در موج چهارم خود، به معنای درهمتنیدگی روند تعاملی، بین انسان با تکنولوژی های نوظهور در زندگی انسان امروزه می باشد که روند تعاملی تازه ای را بین انسان و تکنولوژی آغاز نموده است. پژوهش حاضر با مرور و تحلیل منابع موجود و ارائة آن در قالب یک چارچوب نظری به ایجاد ارتباط مابین دسپلین های درگیر و شناسایی حفره ادبیات موجود در معماری می پردازد، و براین اساس با هدف رفع سوگیری نسبت به تکنولوژی های نوظهور چارچوب نظری طراحی فضای غیرماده معماری برمبنای TRUST را مطرح می نماید. بر اساس مرور سیستماتیک، 242 تعداد مقاله در زمینههای تعامل انسان و رایانه، اخلاق رایانه، هوشمصنوعی، تاثیرات پساپاندمی، روانشناسی محیط، معماری هوشمند، فضای معماری، تکنولوژیهای واقعیت افزوده و مجازی و متاورس در خلال سالهای 2017-2022 مورد بررسی قرار گرفت و پس از غربالگری نهایی و تحلیل در نرم افزار MAXQDA به توسعه و شکل دادن نتیجه گیری منجرشد؛ در ...
چکیده انگلیسی :
The 4th wave of the human-technology interaction (HTI) refers to the entanglement of a new form of interactive process between humans and emerging technologies and their presence in today’s human life. With an emphasis on the emergence of artificial intelligence (AI), social robotics, virtual reality (VR), neural implants, cyber-physical systems, smart spaces, and autonomous vehicles (AVs), recent scientific literature has recognized the necessity of the human-computer interaction (HCI) 4th wave to show how human-machine interaction has turned into an ambiguous subject given human-technology boundaries. By reviewing, analyzing, and conceptually framing the literature, this study aimed to find possible relationships between the involved disciplines and architectural literature gaps. The obtained results can be used to (1) determine research gaps in the field of HTI from an architectural perspective to eliminate bias against emerging technologies, (2) theoretically explain how to design a virtual architectural space while considering those gaps, and (3) recommend a path for future studies....
Ahmad, I., & Mikinski, M. S. (2021). Trust in Smart Homes: The Power of Social Influences and Perceived Risks. In International Conference on Information Systems (pp. 1-13).
Banaei, M., Ahmadi, A., Gramann, K., & Hatami, J. (2020). Emotional evaluation of architectural interior forms based on personality differences using virtual reality. Frontiers of Architectural Research, 9(1), 138-147.
Cervantes, S., López, S., & Cervantes, J. A. (2020). Toward ethical cognitive architectures for the development of artificial moral agents. Cognitive systems research, 64, 117-125.
Ćetković, A. (2020). Architectural paradox in the smart home. Ubiquity: The Journal of Pervasive Media, 7(1), 3-16.
Chan, K. T. (2022). Emergence of the ‘Digitalized Self’in the Age of Digitalization. Computers in Human Behavior Reports, 6, 100191.
Chubarov, A. A., Tikhomirova, D. V., Shirshova, A. V., Veselov, N. O., & Samsonovich, A. V. (2020). Virtual Listener: A Turing-like test for behavioral believability. Procedia Computer Science, 169, 892-899.
Damiano, L., & Dumouchel, P. (2018). Anthropomorphism in human–robot co-evolution. Frontiers in psychology, 9, 363437.
De, R., Neena Pandey, N., Pal, A. (2021). Impact of digital surge during COVID-19 pandemic: A viewpoint on research and practice. International Journal of Information Management, 55.
Duan, H., Li, J., Fan, S., Lin, Z., Wu, X., & Cai, W. (2021, October). Metaverse for social good: A university campus prototype. In Proceedings of the 29th ACM international conference on multimedia (pp. 153-161).
Ekman, F., Johansson, M., Bligård, L. O., Karlsson, M., & Strömberg, H. (2019). Exploring automated vehicle driving styles as a source of trust information. Transportation research part F: traffic psychology and behaviour, 65, 268-279.
Ekman, F., Johansson, M., Karlsson, M., Strömberg, H., & Bligård, L. O. (2021). Trust in what? Exploring the interdependency between an automated vehicle’s driving style and traffic situations. Transportation research part F: traffic psychology and behaviour, 76, 59-71.
Fox, J., & Gambino, A. (2021). Relationship development with humanoid social robots: Applying interpersonal theories to human–robot interaction. Cyberpsychology, Behavior, and Social Networking, 24(5), 294-299.
Frauenberger, C. (2019). Entanglement HCI The Next Wave?. ACM Transactions on Computer-Human Interaction, 27, 1-27. http://dx.doi.org/10.1145/3364998
Frison, A. K., Wintersberger, P., & Riener, A. (2019). Resurrecting the ghost in the shell: A need-centered development approach for optimizing user experience in highly automated vehicles. Transportation research part F: traffic psychology and behaviour, 65, 439-456.
Gram-Hanssen, K., & Darby, S. J. (2018). “Home is where the smart is”? Evaluating smart home research and approaches against the concept of home. Energy Research & Social Science, 37, 94-101.
Guerrero, E., Lu, M. H., Yueh, H. P., & Lindgren, H. (2019). Designing and evaluating an intelligent augmented reality system for assisting older adults’ medication management. Cognitive Systems Research, 58, 278-291.
Han, M. J. N., Kim, M. J., & Kim, I. H. (2021). Exploring the user performance of Korean women in smart homes with a focus on user adoption. Journal of Building Engineering, 39, 102303.
Hassani, H., Huang, X., & Silva, E. (2021). The human digitalisation journey: Technology first at the expense of humans?. Information, 12(7), 267.
Hengstler, M., Enkel, E., & Duelli, S. (2016). Applied artificial intelligence and trustdthe case of autonomous vehicles and medical assistance devices. Technological Forecasting and Social Change, 105.
Hengstler, M., Enkel, E., & Duelli, S. (2016). Applied artificial intelligence and trust—The case of autonomous vehicles and medical assistance devices. Technological Forecasting and Social Change, 105, 105-120.
Hengstler, M., Enkel, E., & Duelli, S. (2016). Applied artificial intelligence and trust—The case of autonomous vehicles and medical assistance devices. Technological Forecasting and Social Change, 105, 105-120.
Hoff, K.A., & Bashir, M. (2015). Trust in automation: integrating empirical evidence on factors that influence trust. Hum. Factors, 57, 407–434. http://refhub.elsevier.com/S2590-1982(20)30112-3/rf0100
Horner, D. S. (2010). Moral luck and computer ethics: Gauguin in cyberspace. Ethics and information technology, 12(4), 299-312.
Irfan, B. (2019, August). Multi-modal Personalisation in Long-Term Human-Robot Interaction. 9th Joint IEEE International Conference on Development and Learning and on Epigenetic Robotics (ICDL-EpiRob 2019), Workshop on Personal Robotics and Secure Human-Robot Collaboration.
Jeon, M., Fiebrink, R., Edmonds, E. A., & Herath, D. (2019). From rituals to magic: Interactive art and HCI of the past, present, and future. International Journal of Human-Computer Studies, 131, 108-119.
Jin, Q., et al. (2018). Research roadmap intelligent and responsive buildings.
Kim, J., Shin, S., Bae, K., Oh, S., Park, E., & del Pobil, A. P. (2020). Can AI be a content generator? Effects of content generators and information delivery methods on the psychology of content consumers. Telematics and Informatics, 55, 101452.
Lachini, T.& Pagliaro, S. & Ruggiero, G. (2015). Near or far? It depends on my impression: Moral information and spatial behavior in virtual interactions. Acta Psychologica, 161, 131-136. 10.1016/j.actpsy.2015.09.003.http://dx.doi.org/10.1016/j.actpsy.2015.09.003
Lee, J.D., & See, K.A., (2004). Trust in automation: designing for appropriate reliance. Hum. Factors 46 (1), 50–80. http://refhub.elsevier.com/S0040-1625(15)00418-7/rf0145
Lee, J.-G., Kim, K. J., Lee, S., & Shin, D.-H. (2015). Can autonomous vehicles Be safe and trustworthy? Effects of appearance and autonomy of unmanned driving systems. International Journal of Human-Computer Interaction, 31(10), 682e691. http://refhub.elsevier.com/S0142-694X(20)30024-7/sref29-
Lee, L. H., Braud, T., Zhou, P., Wang, L., Xu, D., Lin, Z., ... & Hui, P. (2021). All one needs to know about metaverse: A complete survey on technological singularity, virtual ecosystem, and research agenda. arXiv preprint arXiv:2110.05352.
Leichtmann, B., & Nitsch, V. (2020). How much distance do humans keep toward robots? Literature review, meta-analysis, and theoretical considerations on personal space in human-robot interaction. Journal of environmental Psychology, 68, 101386.
Liu, B., & Sundar, S. S. (2018). Should machines express sympathy and empathy? Experiments with a health advice chatbot. Cyberpsychology, Behavior, and Social Networking, 21(10), 625-636.
Luders, M., Andreassen, T. W., Clatworthy, S., & Hillestad, T. (2017). Innovating € for trust. In M. Luders, T. W. Andreassen, S. Clatworthy, & T. Hillestad € (Eds.), Innovating for trust (pp. 1e14). Eward Elgar: Cheltenham. http://refhub.elsevier.com/S0142-694X(20)30024-7/opts1GSSFkxru
Mannino, A., Dejaco, M. C., & Re Cecconi, F. (2021). Building information modelling and internet of things integration for facility management—Literature review and future needs. Applied Sciences, 11(7), 3062.
Mashal, I., & Shuhaiber, A. (2018). What makes Jordanian residents buy smart home devices? A factorial investigation using PLS-SEM. Kybernetes, 48(8), 1681-1698.
Massimiliano, P. (2018). A developmental model of trust in humanoid robot. Univ. Plymouth, Plymouth, UK, Tech. Rep.
McKnight, D.H., Choudhury, V., Kacmar, C., 2002. The impact of initial consumer trust on intentions to transact with a web site: a trust building model. J. Strateg. Inf. Syst, 11(3), 297–323. http://refhub.elsevier.com/S0040-1625(15)00418-7/rf0175
Mele, C., Spena, T. R., Kaartemo, V., & Marzullo, M. L. (2021). Smart nudging: How cognitive technologies enable choice architectures for value co-creation. Journal of Business Research, 129, 949-960.
Namazian, A., & Mehdipour, A. (2013). Psychological demands of the built environment, privacy, personal space and territory in architecture. International Journal of Psychology and Behavioral Sciences, 3(4), 109-113.
Netanyahu, A., Shu, T., Katz, B., Barbu, A., & Tenenbaum, J. B. (2021, May). Phase: Physically-grounded abstract social events for machine social perception. In Proceedings of the aaai conference on artificial intelligence (Vol. 35, No. 1, pp. 845-853).
Nevelsteen, K. J. (2018). Virtual world, defined from a technological perspective and applied to video games, mixed reality, and the Metaverse. Computer animation and virtual worlds, 29(1), e1752.
Norman, D.A. (2007). The design of everyday things. Basic Books.
Oliveira, L., Burns, C., Luton, J., Iyer, S., & Birrell, S. (2020). The influence of system transparency on trust: Evaluating interfaces in a highly automated vehicle. Transportation research part F: traffic psychology and behaviour, 72, 280-296.
Park, E., Kim, S., Kim, Y., & Kwon, S. J. (2018). Smart home services as the next mainstream of the ICT industry: determinants of the adoption of smart home services. Universal Access in the Information Society, 17, 175-190.
Pessoa, L. (2019). Intelligent architectures for robotics: The merging of cognition and emotion. Physics of Life Reviews, 31, 157-170.
Pink, S., Osz, K., Raats, K., Lindgren, T., & Fors, V. (2020). Design anthropology for emerging technologies: Trust and sharing in autonomous driving futures. Design Studies, 69, 100942. https://doi.org/10.1016/j.destud.2020.04.002
Puig, X., Shu, T., Li, S., Wang, Z., Liao, Y. H., Tenenbaum, J. B., ... & Torralba, A. (2020). Watch-and-help: A challenge for social perception and human-ai collaboration. arXiv preprint arXiv:2010.09890.
Raats, K., Fors, V. & Pink, S. (2020). Trusting autonomous vehicles: An interdisciplinary approach. Transportation Research Interdisciplinary Perspectives. http://dx.doi.org/10.1016/j.trip.2020.100201
Raats, K., Fors, V., & Pink, S. (2020). Trusting autonomous vehicles: An interdisciplinary approach. Transportation Research Interdisciplinary Perspectives, 7, 100201.
Rogers, E.M. (2003). Diffusion of Innovations. , New York: Free Press
Russell, S.J., & Norvig, P. (2010). Artificial Intelligence: A Modern Approach. Prentice Hall, third ed. Englewood Cliffs, New Jersey. http://refhub.elsevier.com/S0040-1625(15)00418-7/rf0250
Shuhaiber, A., & Mashal, I. (2019). Understanding users’ acceptance of smart homes. Technology in society, 58, 101110. https://doi.org/10.1016/j.techsoc.2019.01.003
Shuhaiber, A., & Mashal, I. (2019). Understanding users’ acceptance of smart homes. Technology in society, 58, 101110.
Slovic, P. (1993). Perceived risk, trust, and democracy. Risk Anal, 13(6), 675–682.
Strauch, C., Mühl, K., Patro, K., Grabmaier, C., Reithinger, S., Baumann, M., & Huckauf, A. (2019). Real autonomous driving from a passenger’s perspective: Two experimental investigations using gaze behaviour and trust ratings in field and simulator. Transportation research part F: traffic psychology and behaviour, 66, 15-28.
Tejwani, R., Kuo, Y. L., Shu, T., Katz, B., & Barbu, A. (2022, January). Social interactions as recursive mdps. In Conference on Robot Learning (pp. 949-958). PMLR.
Vial, G. (2021). Understanding digital transformation: A review and a research agenda. Managing digital transformation, 13-66.
Yang, H., Lee, H., & Zo, H. (2017). User acceptance of smart home services: an extension of the theory of planned behavior. Industrial Management & Data Systems, 117(1), 68-89.
Zhao, Y., Jiang, J., Chen, Y., Liu, R., Yang, Y., Xue, X., & Chen, S. (2022). Metaverse: Perspectives from graphics, interactions and visualization. Visual Informatics, 6(1), 56-67.