MODELS OF TRAINING PROCEDURES

Authors

  • V. Ye. Khodakov Kherson National Technical University, Kherson, Ukraine, Ukraine
  • A. Ye. Sokolov Kherson National Technical University, Kherson, Ukraine, Ukraine
  • G. V. Veselovskaya Kherson National Technical University, Kherson, Ukraine, Ukraine

DOI:

https://doi.org/10.15588/1607-3274-2018-4-5

Keywords:

training, formalization of training procedures, teacher, student, information flow, optimization procedures

Abstract

Context. The problem of justifying methods for constructing models of optimization procedures as dynamic objects, taking into account the features of the training procedures, is considered. The object of the study were models of the dynamics of training procedures.
Objective. The goal of the work is to solve the tasks of formalizing the training procedures, developing methods for constructing mathematical models of the learning processes, the processes of searching for the optimum of the learning tasks, and for evaluating dynamic training procedures.
Method. The learning process is a totality of sequential and interrelated actions of a teacher and learners, aimed at providing a conscious and durable assimilation of knowledge, abilities, and skills. As a result of systematic analysis, main, basic patterns of training procedures are defined. The notion of “information flow” is justified as the sequence of messages carrying information for building models of interactions in information systems. The important property of the information flow is determined – the direction
from the source to the receiver. Two possible variants of information interaction of objects are singled out – information transfer and information compensation. The use of optimality principle for information processes of learning is offered. It is shown that the dynamics of learning processes is determined by the characteristics of the used optimization procedure. The gradient procedure for finding the extremum of the goal function is described by the autonomous motion of the dynamic system. For a strictly convex goal
function, according to sufficient optimality conditions, the optimization procedure is described by the dynamics of the autonomous motion of a stationary linear unbound dynamic object. The choice of the multiplier for the gradient significantly affects the dynamics of the process, and for a strictly convex goal function the multiplier is equal to the increment vector. The use of a dynamic model determines the number of steps required to achieve the given accuracy.
Results. The created models received software implementation and were investigated in practice when solving the tasks of modeling the dynamics of training procedures in the teaching process of the Information Technologies Department of Kherson National Technical University.
Conclusions. The carried out experimental researches have allowed to confirm practically operability of the created mathematical apparatus and to consider it expedient for application with the purpose of increase of efficiency of modeling and realization of training procedures. Further perspectives of the research are seen in the coverage of more types of dynamic training procedures, optimizing approaches to their software implementations, and increasing the scale of their coverage with confirmatory experiments.

References

Mitrofanov K. G., Zaytseva O. V. Primeneniya innovatsionnyih kompyuternyih tehnologiy v sfere obrazovaniya: osnovnyie aspektyi i tendentsii, Vestnik TGPU, 2009, Vyip. 10 (88), pp. 64–68.

Alsied S. M., Pathan M. M. The use of computer technology in EFL classroom: Advantages and implications, International Journal of English Language and Translation Studies, 2013, Vol. 1, Issue 1, April-June, pp. 61–71.

Blurton C. New Directions of ICT – Use in Education. United National Education Science and Culture Organization (UNESCO),

Viner N. Per. s angl. I. V. Soloveva i G. N. Povarova; Pod red. G. N. Povarova. Kibernetika, ili Upravlenie i svyaz v zhivotnom i mashine. 2-e izdanie. Moscow, Nauka, Glavnaya redaktsiya izdaniy dlya zarubezhnyih stran, 1983, 344 p.

Atanov G. A. Deyatelnostnyiy podhod v obuchenii. Donetsk, EAI press, 2001, 160 p.

Chaplin J. P. Dictionary of Psychology. N.J., 1985, 528 p.

Kolmogorov A. N. Teoriya informatsii i teoriya algoritmov. Moscow, Nauka, 1987, 304 p.

Znanie [Elektronnyiy resurs]. Rezhim dostupa: dic.academic.ru.

Esipov B. A. Metodyi optimizatsii i issledovaniya operatsiy : Uchebnoe posobie. Samara, Izd-vo. Samar. aerokosm. un-ta, 2007, 180 p.

Chernorutskiy I. G. Metodyi optimizatsii v teorii upravleniya: Uchebnoe posobie. SPB, Piter, 2004, 256 p.

LarIonov Yu. I. DoslIzhdennya operatsIy: Navchalniy posyibnik. Harkiv, V.D. «INZhEK», 2005, 288 p.

Panteleev A. V., Letova T. A. Metodyi optimizatsii v primerah i

zadachah: Uchebnoe posobie. 2-e izdanie, ispravl. A. V. Panteleev. Moscow, Vyissh. shkola, 2005, 544 p.

Kim D. P. Teoriya avtomaticheskogo upravleniya. Tom 1. Lineynyie sistemyi. Moscow, Fizmatlit, 2003, 288 p.

Vasilev F. P. Chislennyie metodyi resheniya ekstremalnyih zadach: Uchebnoe posobie dlya VUZov. – 2-e izdanie, pererab. i dop. Moscow, Nauka, Gl. red. fiz.-mat. lit., 1988, 552 s.

Moskaleva S. S. Programmnaya podderzhka ekspertnoy otsenki kriteriev dlya postroeniya kognitivnoy modeli, Obrazovatelnyie resursyi i tehnologii, 2014, pp. 97–101.

Samoylo I. V. Matematicheskie modeli i algoritmyi professionalnoy orientatsii i upravleniya znaniyami: avtoref. dis. na soiskanie uchen. stepeni kand. tehn. nauk : spets. 05.13.10 “Upravlenie v sotsialnyih i ekonomicheskih sistemah”. Moscow, 2010, 25 p.

Oharenko T. Yu. Modeliuvannia dynamiky popytu na posluhy vyshchykh navchalnykh zakladiv : avtoref. dys. na zdobuttia nauk. stupenia kand. ekon. nauk : spets. 08.00.11 “Matematychni metody, modeli ta informatsiini tekhnolohii v ekonomitsi.” Zaporizhzhia,

, 23 p.

Downloads

How to Cite

Khodakov, V. Y., Sokolov, A. Y., & Veselovskaya, G. V. (2019). MODELS OF TRAINING PROCEDURES. Radio Electronics, Computer Science, Control, (4). https://doi.org/10.15588/1607-3274-2018-4-5

Issue

No. 4 (2018): Radio Electronics, Computer Science, Control

Section

Mathematical and computer modelling

License

Copyright (c) 2019 V. Ye. Khodakov, A. Ye. Sokolov, G. V. Veselovskaya

Creative Commons License

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Creative Commons Licensing Notifications in the Copyright Notices

The journal allows the authors to hold the copyright without restrictions and to retain publishing rights without restrictions.

The journal allows readers to read, download, copy, distribute, print, search, or link to the full texts of its articles.

The journal allows to reuse and remixing of its content, in accordance with a Creative Commons license СС BY -SA.

Authors who publish with this journal agree to the following terms:

  • Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License CC BY-SA that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.

  • Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.

  • Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work.