METHODICAL FEATURES OF IMPLEMENTATION OF THE RELATIONSHIP BETWEEN SYMMETRY AND ASYMMETRY BASED ON STEM EDUCATION
DOI:
https://doi.org/10.51707/2618-0529-2022-24-07Keywords:
physics, STEM technologies, symmetry, asymmetry, methodical features of teaching.Abstract
The authors analyze the concept of symmetry and asymmetry in the process of teaching physics in technical institutions of higher education. The relationship between symmetry and asymmetry in the process of teaching physics based on STEM technologies is revealed. The use of fundamental ideas of physics (for example, symmetry and asymmetry) taking into account STEM technologies is highlighted. The interrelation of symmetry and conservation laws about their fundamentality is clarified; the technique of the integrated approach of physics and disciplines of the professionally-oriented profile, on an example of studying cosmetic loadings, is presented. It was found that the formation of independent cognitive-exploratory activities of students should use physics problems with consideration of fundamental concepts, such as symmetry caused by the development of motives, cognitive interest and scientific thinking and the acquisition of professional competencies. The demonstration of engineering and technical component of STEM education and development of methods of studying disciplines taught to students of technical institutions of higher education, taking into account the integrated approach and interdisciplinary links, is relevant. The transition to STEM training requires improving the methodology of teaching physics in terms of integrated, systematic, professionally-oriented approaches, which includes: the use of new methods, techniques, teaching aids that would help solve several methodological problems; application and introduction in the educational process of physics of interesting and important scientific achievements, as well as strengthening those aspects that stimulate and intensify the independent cognitive activity of students of technical institutions of higher education. It is established that to improve the quality of teaching physics in future technical specialists it is necessary to systematically improve the methodology of educational and cognitive activities, and more widely apply STEM-learning technologies, which leads to productive mental and practical activities of students in the process of mastering educational material. In the future, work on the study of this problem can be carried out in the following areas: development of a new approach to changing the structure and content of working curricula, improving the content and system of teaching physics taking into account STEM technologies, strengthening the connection between the teaching of physics course and the professional orientation of students of non-physical specialities of technical universities in the context of STEM education.
References
Xun, Xu, Yuqian, Lua, Birgit, Vogel-Heuserb & Lihui, Wangc (2021). Industry 4.0 and Industry 5.0 — Inception, conception and perception. Journal of Manufacturing Systems. (Vol. 61), (pр. 530–535). DOI: https://doi.org/10.1016/j.jmsy.2021.10.006.
Chernetskyi, I. S., Polikhun, N. I., & Slipukhina, I. A. (2017). Multydystsyplinarnyi pidkhid u formuvanni STEM oriientovanykh navchalnykh zavdan [Multidisciplinary approach to the formation of STEM-oriented learning objectives]. Naukovi zapysky. Problemy metodyky fizyko-mаtemаtychnoi i tekhnolohichnoi osvity — Scientific notes. Problems of methods of physical-mathematical and technological education, 12 (1), 158–168. Kropyvnytskyi. Retrieved from: https://phm.cuspu.edu.ua/ojs/index.php/NZ-PMFMTO/article/view/1355/1328 [in Ukrainian].
Stryzhak, O., Slipukhina, I., Polikhun, N. & Chernetskyi, I. (2017). STEM-osvita: osnovni definitsii [STEM education: basic definitions]. Information Technologies and Learning Tools, 62 (6), 16–33. Kyiv : IITZN NAPN Ukrainy. Retrieved from: https://journal.iitta.gov.ua/index.php/itlt/article/ view/1753/1276 [in Ukrainian].
Gott, V. S. (1965). Simmetriya i asimmetriya [Symmetry and asymmetry]. Moscow : Znaniye [in Russian].
Ganiyev, R. M. (2001). Gruppovaya simmetriya v mnozhestve mirovozzrencheskikh vyskazyvaniy [Group symmetry in the set of worldview statements]. Vladikavkaz : Severo-Osetinskiy gos. un-t im. K. L. Khetagurova [in Russian].
Grin, B. (2007). Elegantnaya Vselennaya. Superstruny, skrytyye razmernosti i poiski okonchatelnoy teorii [Elegant Universe. Superstrings, Hidden Dimensions, and the Quest for the Ultimate Theory]. Moscow : URSS; KomKniga [in Russian].
Kovalev, I. Z. (1976). Ucheniye o simmetrii v kurse fiziki sredney shkoly [The doctrine of symmetry in the course of high school physics]. Candidate’s thesis. Kiev [in Russian].
Multanovskiy, V. V. (1988). Kurs teoreticheskoy fiziki [Theoretical Physics Course]. Moscow : Prosveshcheniye [in Russian].
Murach, M. M. (1978). Heometrychni peretvorennia i symetriia [Geometric transformations and symmetry]. Kyiv : Radianska shkola [in Ukrainian].
Sadovyi, M. I. (2007). Okremi pytannia suchasnoi ta tradytsiinoi fizyky [Some issues of modern and traditional physics]. Kirovohrad : Kalich O. H. [in Ukrainian].
Wang, Lixin, Xu, Zijian, & Yue, Ting (2016). Dynamic characteristics analysis and flight control design for oblique wing aircraft. Chinese Journal of Aeronautics, 29 (6), 1664–1672. DOI: https://doi.org/10.1016/j.cja.2016.10.010.
Ribe, N. M., Brun, P-T., & Audoly, B. (2022). Symmetry and Asymmetry in the Fluid Mechanical Sewing Machine. Symmetry, 14 (4), 772. DOI: https://doi.org/10.3390/sym14040772.
Dardashti, R., Frisch, M. & Valente, G. (2021). Editorial: symmetries and asymmetries in physics. Synthese, 199, 983–989. DOI: https://doi.org/10.1007/s11229-020-02745-6.
Eliot, Dzh., & Dober, P. (1983). Simmetriya v fizike [Symmetry in physics]. Vols. 1. Moscow : Mir [in Russian].
Vigner, E. (1971). Etyudy o simmetrii [Studies on symmetry]. Moscow : Mir [in Russian].
Illarionov, S. V., & Mamchur, E. A. (1994). Printsipy simmetrii v fizike elementarnykh chastits [Symmetry principles in elementary particle physics]. Filosofskiye problemy fiziki elementarnykh chastits (tridtsat let spustya) — Philosophical problems of elementary particle physics (thirty years later). Moscow : RAN [in Russian].
Abraham, A. (2018). Ungar Symmetry Groups of Systems of Entangled Particles. Journal of Geometry and Symmetry in Physics, 48, 47–77. DOI: https://doi.org/10.7546/jgsp-48-2018-47-77.
Targ, S. M. (1967). Kratkiy kurs teoreticheskoy mekhaniki [A short course in theoretical mechanics]. 5th ed. stereotypical. Moscow : Nauka. Gl. red. fiz.-mat. lit. [in Russian].
Yaremenko, M. I. (2019). Einstein-Maxwell theory without symmetry and examples of geodesics in space with torsion. Canadian Journal of Physics, 97, 3. DOI: https://doi.org/10.1139/cjp-2019-0106.
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