METHODOLOGY FOR DEVELOPING THE COMPETENCE OF FUTURE PHYSICS TEACHERS THROUGH THEORETICAL TRAINING SESSIONS

Kahhorov Siddik; Tursunov Adizjon

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Published

2026-04-01

Issue

Vol. 6 No. 3 (2026): Multidisciplinary Journal of Science and Technology

Section

Articles

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METHODOLOGY FOR DEVELOPING THE COMPETENCE OF FUTURE PHYSICS TEACHERS THROUGH THEORETICAL TRAINING SESSIONS. (2026). Multidisciplinary Journal of Science and Technology, 6(3), 577-587. https://www.mjstjournal.universalpublishings.com/index.php/mjst/article/view/7127

How to Cite

METHODOLOGY FOR DEVELOPING THE COMPETENCE OF FUTURE PHYSICS TEACHERS THROUGH THEORETICAL TRAINING SESSIONS. (2026). Multidisciplinary Journal of Science and Technology, 6(3), 577-587. https://www.mjstjournal.universalpublishings.com/index.php/mjst/article/view/7127

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METHODOLOGY FOR DEVELOPING THE COMPETENCE OF FUTURE PHYSICS TEACHERS THROUGH THEORETICAL TRAINING SESSIONS

Kahhorov Siddik

Professor of the Department of Heliophysics, Renewable Energy Sources and Electronics, Bukhara State University

Tursunov Adizjon

Doctoral Student of the Department of Heliophysics, Renewable Energy Sources and Electronics, Bukhara State University

Keywords: competence, theoretical training, physics teacher, methodology, innovative educational technologies, reflection, active learning, pedagogical approach, mentoring, assessment system

Abstract

This article analyzes the issue of developing the competence of future physics teachers in the process of theoretical training from a scientific and methodological perspective. Within the framework of the study, the essence of the concept of competence, its main types, and the theoretical foundations for their formation in the system of physics education are elucidated. Furthermore, innovative approaches aimed at developing the methodological, scientific, information-communication, and reflective competences of future teachers during theoretical training sessions are proposed.

The article scientifically substantiates the stages of competence formation based on active learning technologies, interactive methods, problem-based learning, and an integrated approach. It also pays special attention to assessment and self-development mechanisms aimed at increasing the effectiveness of organizing theoretical training sessions.

The research findings contribute to aligning the professional training of future physics teachers with modern educational requirements, enhancing their creative and analytical potential, and ensuring their thorough preparation for practical training.

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