Competence-based approach to the topic «Area» in geometric origami modeling

Introduction. The article is devoted to the assertion of the need to develop and include in the educational process of growing personalities competence-oriented tasks provided by the technology of geometric origami modeling. Relevance. In modern mathematical education, there is an active search for improving the quality of education using competence- based approach.
Purpose setting. In the scientific literature, as it turned out, no studies have been found indicating effective means of asserting a competence-based approach to the study of the topic «Area», which led to the need to develop and include in the educational process competence-oriented tasks designed within the framework of technology associated with the recognition, modification and evaluation of the area ratios of geometric shapes.
Methodology and methods of the study. In theoretical studies, competence-based, environmental and synergetic, cognitive-visual approaches are considered. The method of conducting experimental work using visual and graphic means aimed at revealing the category of area as an additive scalar quantity is recreated from the analysis of geometric shapes arising during the geometric modeling of origami, which the child explores and sets their boundaries.
Results. The effectiveness of the considered approach to the topic «Area» is proved.
Conclusions. The scope of implementation of the research results is presented.

1. Decree of the Government of the Russian Federation of December 24, 2013 No. 2506‑р «On the Concept of development of mathematical education in the Russian Federation» (with amendments and additions). URL: https:// base.garant.ru/70552506 / (accessed 07.06. 2022). (In Russ.).

2. Pavlova L. V. Subject competence tasks in mathematics. Bulletin of the Pskov State University. Natural and Physical-Mathematical Sciences, 2013, no. 3, pp. 127 – 134. (In Russ.).

3. Testov V. A. Strategy of teaching mathematics. Moscow, Technological School of Business, 1999, 304 p. (In Russ.).

4. Testov V. A. Features of the formation of basic mathematical concepts in schoolchildren in modern conditions. Scientific and methodological electronic journal « Koncept», 2014, no. 12, art. 14333. URL: https://e-koncept.ru/2014/14333.htm (accessed 07.06. 2022). (In Russ.).

5. Testov V. A. Step-by-step formation of the concept of scalar quantity. Scientific and methodological electronic journal « Koncept», 2016, vol. 9, pp. 11 – 15. URL: http://e-koncept.ru/2016/46106.htm (accessed 07.06.2022). (In Russ.).

6. Boganovskaya N. D. Additive scalar quantities in the mathematics course of a special (correctional) educational institution of the VIII type. Special Education, 2008, no. 1, pp. 9 – 13. (In Russ.).

7. Vinogradov I. M. (ed.) Mathematical encyclopedia. 1977 – 1985. URL: http://es.niv.ru/doc/encyclopedia/mathematics/index-207.htm#207 (accessed 07.06. 2022). (In Russ.).

8. Gasanova A. M. Analysis of historical and pedagogical research on the problems of education visualization. The World of Science, Culture, Education, 2019, no. 3, pp. 28 – 29. (In Russ.).

9. Dalinger V. A. Teaching mathematics based on a cognitive-visual approach. Bulletin of the Bryansk State University, 2011, no. 1, pp. 299 – 305. (In Russ.).

10. Dalinger V. A. Cognitive-visual approach, its essence and methodological features in teaching mathematics. Wschodnioeuropejskie Czasopismo Naukowe, 2015, vol.3, no. 2, pp. 28 – 32. (In Russ.).

11. Dalinger V. A. Teaching mathematics based on cognitive-visual technology. Scientific Review. Pedagogical Sciences, 2020, no. 1, pp. 22 – 26. (In Russ.).

12. Balashov Yu. V. Cognitive-visual approach to teaching mathematics as an effective means of mathematical development of students. Pedagogical mastership: materials of the V Intern. sci. conf. (Moscow, November 2014). Moscow, 2014, pp. 62 – 65. URL: https://moluch.ru/conf/ped/archive/144/6562/ (accessed 07.06.2022). (In Russ.).

13. Mozgovaya M. A. Formation of graphic images of geometric concepts as the basis for the development of spatial thinking in the study of geometry in secondary school. Problems of Modern Pedagogical Education, 2018, no. 60 – 1, pp. 190 – 193. (In Russ.).

14. Sokolova G. A. Guidelines for designing the content of the preparatory course of geometry by means of origami: (educational and methodological manual). Novosibirsk, NIPKiPRO, 2004, 60 p. (In Russ.).

15. Demina E. S. The role of visual and schematic tools in the development of general mental and mathematical abilities of preschool children. The world of Science, Culture, Education, 2012, no. 3, pp. 12 – 13. (In Russ.).

16. Korepanova M. V. Visual modeling as a method of mathematical development of preschoolers. Izvestia of the Volgograd State Pedagogical University, 2020, no. 6, pp. 51 – 56. (In Russ.).

17. Sokolova G. A. Integrative tendencies of mathematical education. Integration of Education, 2004, no. 1, pp. 165 – 168. (In Russ.).

18. Sokolova G. A. Implementation of classical principles of education by о

19. Sokolova G. A. Geometric modeling of origami in the environmental approach to self-organization in childhood. Bulletin of Kemerovo State University. Series: Humanities and Social Sciences, 2021, no. 3, pp. 229 – 237. (In Russ.).

20. Orlov A. I. System-synergetic approach in the formation of professional competence. Herald of Vyatka State University, 2011, vol. 4 – 3, pp. 62 – 64. (In Russ.).