The article presents the development of a model for generating and adapting an individual educational plan for distance learning based on the requirements of the Federal State Educational Standard (FSES) and the student model. A systematic approach with a multi-agent structure is used, including subsystems for initializing the student's model, planning the educational process, and evaluating the assimilation of material. The student's model takes into account preferences, goals, and progress, which makes it possible to adapt the educational plan based on the competencies being formed and the requirements of the standard. The quantitative characteristics of the educational process are formalized, such as the time to study, the form of final control, as well as the coefficients of similarity and discrepancy between student preferences and the requirements of the Federal State Educational Standard. The author applied an optimization model to minimize time and maximize the effectiveness of the plan, taking into account the connectivity of courses represented by an oriented graph. Special attention is paid to the consideration of conflicts of interest between the individual preferences of the student and the mandatory requirements of the Federal State Educational Standard. The results of the conducted research show the possibility of effectively creating an adaptive educational plan that meets the regulatory requirements and individual characteristics of students, which contributes to improving the quality of distance education. In conclusion, the author draws a conclusion about the criteria for effective modeling of the educational plan.
1. Savkina A.V., Savkina A.V., Fedosin S.A. Virtual'nye laboratorii v distantsionnom obuchenii. Educational Technologies and Society. 2014;17(4):507–517. (In Russ.).
2. Bannikov S.A. Problems and Prospects of Quality Management System of Higher Education in the Russian Federation. Bulletin of Chelyabinsk State University. 2016;(2):190–196. (In Russ.).
3. Sharamazanov R., Savkina A., Nushtaeva A. A Multi-Agent System Architecture for E-Learning Systems Using a MOODLE LMS. Natsional'naya assotsiatsiya uchenykh. 2015;(7–2):78–82. (In Russ.).
4. Volyanskaya T.A. Adaptive Courseware Generation Issues in Intelligent Tutoring Systems. System Informatics. 2025;(26). (In Russ.). https://doi.org/10.31144/si.2307-6410.2025.n26.p1-40
5. Pham Q.D., Florea A.M. Adaptation to Learners' Learning Styles in a Multi-Agent E-Learning System. Internet Learning. 2013;2(1):11–20.
6. Barinova N.A., Karunas E.V. Design Individual Training Programs as a Condition of Implementation of the GEF. Kazan Pedagogical Journal. 2015;(3):70–75. (In Russ.).
7. Ninul A.S. Optimizatsiya tselevykh funktsii: Analitika. Chislennye metody. Planirovanie eksperimenta. Moscow: Izdatel'stvo Fiziko-matematicheskoi literatury; 2009. 336 p. (In Russ.).
8. Evstigneev V.A., Kas'yanov V.N. Teoriya grafov: Algoritmy obrabotki beskonturnykh grafov. Novosibirsk: Nauka; 1998. 385 p. (In Russ.).
9. Gaidai A.A., Russman I.B. Nepreryvnyi kontrol' protsessa dostizheniya tseli. Large-Scale Systems Control. 2004;(7):106–113. (In Russ.).
10. Abanina K.A., Krukovskaya O.A., Nikolaeva V.V., Puzyreva E.Ju., Ryabinina M.V. The Modern Problems, Conditions and Factors Considered When Modeling the Process of the Activization of Students' Cognitive Activity. Sotsial'nye otnosheniya. 2016;(4):8–17. (In Russ.).
11. Chernyakova N.V. Features of the Design and Implementation of Substantive Training in College Based on System Approach. Modeling, Optimization and Information Technology. 2013;1(1). (In Russ.). URL: https://moit.vivt.ru/wp-content/uploads/2013/04/chernyakova_1_13_1.pdf
Savkina Anastasia Vasilievna
Candidate of Engineering Sciences, Docent
Ogarev Mordovian State University
Saransk, Russian Federation
