MODELS OF PARTICIPANTS INTERACTION OF THE EDUCATIONAL ENVIRONMENT USING THE TOOLS OF AUGMENTED AND VIRTUAL REALITY IN AN INSTITUTION OF GENERAL EDUCATION
DOI:
https://doi.org/10.31110/2413-1571-2023-038-3-009Keywords:
virtual reality, augmented reality, participants interaction in the educational environment, model of participants interaction in the educational environmentAbstract
The development of information and communication technologies have caused to serious changes in traditional educational concepts, educational models and even education systems.
Problem formulation Gradually, attention is drawn to education that is not subject to the traditional concept and frees the participants of the educational process from limitations in time and space, providing a wealth of teaching and learning resources. Virtual and augmented reality technologies are of particular importance. It is necessary to analyze the interaction of participants in the educational process using virtual and augmented reality, when introducing these technologies into educational programs that have a distance equivalent.
Materials and methods. We used the following methods to achieve the goal of the study: systematic and comparative analysis of pedagogical, psychological, philosophical, sociological works, methodological and specialized literature; analysis of pedagogical experience of use . virtual and augmented reality technologies of the educational in general secondary education institutions; questioning teachers about their experience of using virtual and augmented reality technologies in the educational process, identifying problems for the creation of special webinars and courses in order to develop digital competence of teacher; interpretation of research results. The research was carried out within the framework of the research work “Designing the learning environment using augmented and virtual reality tools in general secondary education institutions” (DR № 0121U107689) of the Institute for Digitalisation of Education of NAES.
Results. It has been established that the interaction of participants in the educational process using virtual reality technology requires improvement, methodological recommendations, and research on the organization of this environment for various purposes. For example, students' exploration of new educational material, conducting laboratory work, collaborative student research, providing instructional guidance for teachers working with students in virtual learning environments, etc. The interaction of participants in the educational process using augmented reality is better understood by teachers and students. They utilize both ready-made augmented reality technologies and personally created ones.
Conclusions. It has been determined that the model of interaction among participants in the educational process of a general education institution, using virtual and augmented reality, generally includes the following blocks: the teacher's activity in organizing the interaction of participants in the educational process using virtual and augmented reality; the organization of interaction between students and the teacher using virtual and augmented reality; the main types of interaction among participants in this process using virtual and augmented reality; the assessment of the effectiveness of interaction in an educational project with virtual and augmented reality. Moreover, the model of interaction among participants in the educational process using virtual reality should take into account the characteristics of the space designated for the use of virtual reality and aim for maximum coverage relative to the center of the classroom.
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References
Bannister, N.A. (2019). Computer Vision Syndrome in Head-Mounted Displays: Spontaneous Eye Blink Rate and Saccades. figshare. URL: https://hammer.figshare.com/articles/Computer_Vision_Syndrome_in_HeadMounted_Displays_Spontaneous_Eye_Blink_Rate_and_Saccades/11309177/1.
Díaz, J.E.M. (2020). Virtual world as a complement to hybrid and mobile learning. International Journal of Emerging Technologies in Learning (iJET), 15(22), 267–274. https://doi.org/10.3991/ijet.v15i22.14393.
Doak, D.G., Denyer, G.S., Gerrard, J.A., Mackay, J.P., & Allison, J.R. (2020). Peppy: A virtual reality environment for exploring the principles of polypeptide structure. Protein Science, 29(1), 157-168. https://doi.org/10.1002/pro.3752.
Dużmańska, N., Strojny, P., & Strojny, A. (2018). Can Simulator Sickness Be Avoided? A Review on Temporal Aspects of Simulator Sickness. Frontiers in psychology, 9, 2132. https://doi.org/10.3389/fpsyg.2018.02132.
Hirota, M., Kanda, H., Endo, T., Miyoshi, T., Miyagawa, S., Hirohara, Y., Yamaguchi, T., Saika, M., Morimoto, T., & Fujikado, T. (2019). Comparison of visual fatigue caused by head-mounted display for virtual reality and two-dimensional display using objective and subjective evaluation. Ergonomics, 62(6), 759–766. https://doi.org/10.1080/00140139.2019.1582805.
Kuhail, M.A., ElSayary, A., Farooq, S., & Alghamdi, A. (2022). Exploring Immersive Learning Experiences: A Survey. Informatics, 9(4), 75. https://doi.org/10.3390/informatics9040075.
Lee, S. H., Kim, M., Kim, H., & Park, C. Y. (2021). Visual fatigue induced by watching virtual reality device and the effect of anisometropia. Ergonomics, 64(12), 1522–1531. https://doi.org/10.1080/00140139.2021.1957158.
Mukasheva, M., Kornilov, Iu., Beisembayev, G., Soroko, N., Sarsimbayeva, S., & Omirzakova, A. (2023). Contextual structure as an approach to the study of virtual reality learning environment, Cogent Education, 10(1). https://doi.org/10.1080/2331186X.2023.2165788.
Oh, H., & Lee, G. (2021). Feasibility of full immersive virtual reality video game on balance and cybersickness of healthy adolescents. Neuroscience letters, 760, 136063. https://doi.org/10.1016/j.neulet.2021.136063
Perkins Coie LLP and the XR Association (2021). URL: https://www.perkinscoie.com/content/designinteractive/xr2021/
Potane, Joel & Bayeta, Rodolfo (2018). Virtual Learning Through PhET Interactive Simulation: A Proactive Approach in Improving Studentss Academic Achievement in Science. SSRN Electronic Journal. https://doi.org/10.2139/ssrn.3166565.
Scavarelli, A., Arya, A., & Teather, R.J. (2021). Virtual reality and augmented reality in social learning spaces: a literature review. Virtual Reality, 25, 257–277. https://doi.org/10.1007/s10055-020-00444-8.
Soroko, N.V., & Lytvynova, S.H. (2021). The Benefits of Using Immersive Technologies at General School. In: , et al. ICTERI 2021 Workshops. ICTERI 2021. Communications in Computer and Information Science, 1635. Springer, Cham. https://doi.org/10.1007/978-3-031-14841-5_16.
Turnbull, P. R. K., & Phillips, J. R. (2017). Ocular effects of virtual reality headset wear in young adults. Scientific reports, 7(1), 16172. https://doi.org/10.1038/s41598-017-16320-6.
Xiao, X., & Wang, J. (2017). Undertanding and detecting divided attention in mobile mooc learning. In Proceedings of the 2017 CHI Conference on Human Factors in Computing Systems, Denver, CO, USA, 6–11 May 2017, 2411–2415. https://doi.org/10.1145/3025453.3025552.
Yuen, S., Yaoyuneyong, G., & Johnson, E. (2011). Augmented Reality: An Overview and Five Directions for AR in Education. Journal of Educational Technology Development and Exchange, 4, 119-140.
Bykov, V. Yu. & Zhuk, Yu. O. (2003). Teoretyko-metodolohichni zasady modeliuvannia navchalnoho seredovyshcha suchasnykh pedahohichnykh system [Theoretical and methodological principles of modeling the educational environment of modern pedagogical systems]. Problemy ta perspektyvy formuvannia natsionalnoi humanitarno-tekhnichnoi elity – Problems and prospects of the formation of the national humanitarian and technical elite, 1(5), 64–76.
Velytchenko L.K. (2006). Psykholohichni osnovy pedahohichnoi vzaiemodii [Psychological foundations of pedagogical interaction]. Dysertatsiia na zdobuttia naukovoho stupenia doktora psykholohichnykh nauk za spetsialnistiu 19.00.07 – pedahohichna ta vikova psykholohiia. – Natsionalnyi pedahohichnyi universytet imeni M.P.Drahomanova, Kyiv.
Hrybiuk, O.O. (2022). Pedahohichne proektuvannia komponentiv virtualnoi i dopovnenoi realnosti KOMSDN u protsesi doslidnytskoho navchannia uchniv predmetiv pryrodnycho-matematychnoho tsyklu u zakladakh zahalnoi serednoi osvity [Pedagogical design of components of virtual and augmented reality of KOMSDN in the process of research training of students in subjects of the natural and mathematical cycle in institutions of general secondary education]. Pedahohika formuvannia tvorchoi osobystosti u vyshchii i zahalnoosvitnii shkolakh – Pedagogy of creative personality formation in higher and secondary schools, 83, 78-94.
Kovalchuk, L.O. (2005). Pedahohichna vzaiemodiia vykladachiv i studentiv pid chas vykorystannia novykh informatsiinykh tekhnolohii navchannia u protsesi vyvchennia pedahohichnykh dystsyplin [Pedagogical interaction of teachers and students during the use of new educational information technologies in the process of studying pedagogical disciplines]. Visnyk Lvivskoho universytetu. Seriia pedahohichna – Bulletin of Lviv University. Pedagogical series, 19, 17–25.
Lytvynova, S.H. (2022). Hotovnist uchniv zakladiv zahalnoi serednoi osvity do vykorystannia virtualnoi realnosti v osvitnomu protsesi. Perspektyvy ta innovatsii nauky [Readiness of students of general secondary education institutions to use virtual reality in the educational process]. Pedahohika, psykholohiia, medytsyna – Perspectives and innovations of science. Pedagogy, psychology, medicine, 4(9), 218-230. https://doi.org/10.52058/2786-4952-2022-4(9).
Lytvynova, S. H., Burov, O. Yu., & Semerikov, S. O. (2021). Kontseptualni pidkhody do vykorystannia zasobiv dopovnenoi realnosti v osvitnomu protsesi [Conceptual approaches to the use of augmented reality in the educational process], Modern Information Technologies and Innovation Methodologies of Education in Professional Training Methodology Theory Experience Problems, 55, 46-62. https://doi.org/10.31652/2412-1142-2020-55-46-62.
Slobodianyk, O. (2023). Osoblyvosti roboty hurtka «Stvorennia dopovnenoi realnosti» u dystantsiinomu formati [Peculiarities of the work of the group "Creating augmented reality" in a remote format]. Fizyko-matematychna osvita – Physical and Mathematical Education, 38(1), 60-65. https://doi.org/10.31110/2413-1571-2023-038-1-009.
Sokoliuk O.M., Slobodianyk O.V. (2022). Zastosuvannia tekhnolohii dopovnenoi realnosti u protsesi navchannia fizyky [Application of augmented reality technology in the process of teaching physics]. Materialy vseukrainskoi vebkonferentsii “Teoriia i praktyka tsyfrovoho navchannia v suchasnykh zakladakh osvity” – Materials of the all-Ukrainian web conference "Theory and practice of digital learning in modern educational institutions". Vinnytskyi derzhavnyi pedahohichnyi universytet imeni Mykhaila Kotsiubynskoho, m. Vinnytsia, Ukraina. URL: https://ito.vspu.net/konferenc/konf_digital_education/2022/digital_education-2022.htm.
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