Novosibirsk State Pedagogical University Bulletin, 2016, vol. 6, no. 4, pp. 92–107
© Shaikhyzada Z. G., Kostina E. A., Zatyneyko A. M., Kubeyeva A. E., Zhetpisbayeva B. A., 2016
UDC: 
372.881.1

The model of technology of university engineering students’ foreign language training in conditions of multilingual education in Kazakhstan [In English]

Shaikhyzada Z. G. 1 (Karaganda, Republic of Kazakhstan), Kostina E. A. 2 (Novosibirsk, Russian Federation), Zatyneyko A. M. 1 (Karaganda, Republic of Kazakhstan), Kubeyeva A. E. 1 (Karaganda, Republic of Kazakhstan), Zhetpisbayeva B. A. 1 (Karaganda, Republic of Kazakhstan)
1 Academician E. A. Buketov Karaganda State University, Karaganda, Republic of Kazakhstan
2 Novosibirsk State Pedagogical University, Novosibirsk, Russian Federation
Full text (Open Access) — Downloaded 7613
Abstract: 

Nowadays foreign language education is considered to be an essential component of higher vocational education since during the introduction of Kazakhstan’s higher educational establishments in the Bologna process, which implies the academic and professional recognition of the country’s diplomas in European countries, a high level of foreign language proficiency is necessary for experts of any profile. In particular, this statement is of great importance in the field of training engineering specialists in Kazakhstan connected with the necessity of international accreditation of educational programs in the field of engineering and technologies and the possibility for engineering professionals to receive the rank of "Euro engineer". The demand to train engineers in compliance with the European standards of engineering education foregrounds for Kazakhstan’s universities issues concerning purposeful and continuous foreign languages teaching which has to be aimed at the formation of students’ foreign language communicative competency. The solution of these issues calls for a new conceptual approach to engineering students’ foreign language training within higher vocational education which would provide with the most optimal way of achieving the stated goal. In this regard, the article authors address to the question of using pedagogical technologies in the process of foreign languages teaching and learning which enable to set up precise goals, plan the expected outcome and focus the whole activity on its achievement. In the article the authors introduce the new concept "technology of university engineering students’ foreign language training" and provide insight into it. They also present the model of this technology which includes such interrelated components as the goal and outcomes of foreign languages teaching, content-related, organizational-procedural and monitoring-assessment components. The presented model suggests the modernization of the process of foreign language teaching, the selection of the language learning content and the putting of the national assessment system in conformity with the European Credit Transfer and Accumulation System (ECTS). Thus, through the relative determination and organization of each structural component of its model, the technology of university engineering students’ foreign language training condition facilitates the achievement of the main goal of teaching foreign languages in higher schools - the formation of students’ foreign language communicative competency.

Keywords: 

Ttechnology, higher engineering education, Euroengineer, foreign language education, foreign language training, foreign language communicative competency, pedagogical technology, model, content of foreign language learning

https://www.scopus.com/record/display.uri?eid=2-s2.0-85015952101&origin=...

The model of technology of university engineering students' foreign language training in conditions of multilingual education in Kazakhstan

For citation:
Shaikhyzada Z. G., Kostina E. A., Zatyneyko A. M., Kubeyeva A. E., Zhetpisbayeva B. A. The model of technology of university engineering students’ foreign language training in conditions of multilingual education in Kazakhstan [In English]. Novosibirsk State Pedagogical University Bulletin, 2016, vol. 6, no. 4, pp. 92–107. DOI: http://dx.doi.org/10.15293/2226-3365.1604.09
References: 

1. Smirnov S. V. Technologies in education. Higher Education in Russia. 1999, no. 1, pp. 109–112.

2. Dooley K. E. Towards a holistic model for the discussion of education technologies. Journal of Educational Technology and Society. 1996, vol. 2, no. 4, pp. 35–45.

3. Bloom B. S., Engelhart M. D., Furst E. J., Hill W. H., Krathwohl D. R. Taxonomy of educational objectives: The classification of educational goals. Handbook I: Cognitive domain. New York, Longmans and Green Publ., 1956, 111 p.

4. Luppicini R. A Systems Definition of Educational Technology in Society. Educational Technology & Society. 2005, vol. 8, no. 3, pp. 103–109.

5. Sakamoto Т. The Roles of Educational Technology in Curriculum Development. Curriculum Development by Means of Educational Technology. Paris, Centre for Educational Research and Innovation Publ., OECD, 1974, 218 p.

6. Lefevre D., Cox B. Feedback in technology-based instruction: Learner preferences.British Journal of Educational Technology. 2016, vol. 47, no 2, pp. 248–256.

7. Hlynka D., Jacobsen M. What is educational technology, anyway? A commentary on the new AECT definition of the field. Canadian Journal of Learning and Technology. 2010, vol. 35, no. 2. Available at: http://www.cjlt.ca/index.php/cjlt/article/view/527/260 (accessed 15.06.2016) (In Russian)

8. Yau H. K., Cheng Lai Fong A., Ho W. M. Identify the Motivational Factors to Affect the Higher Education Students to Learn Using Technology.The Turkish Online Journal of Educational Technology. 2015, vol. 14, no. 2, pp. 89–100.

9. Jang S.-J., Chang Y. Exploring the technological pedagogical and content knowledge (TPACK) of Taiwanese university physics instructors. Australasian Journal of Educational Technology. 2016, vol. 32, no. 1, pp. 107–122.

10. Hsin C. T., Li M. C., Tsai C. C. The Influence of Young Children’s Use of Technology on Their Learning: A Review. Educational Technology & Society. 2014, vol. 17, no. 4, pp. 85–99.

11. Selevko G. K. Modern educational technologies. Moscow, Education Publ., 1998, 256 p.  (In Russian)

12. Bespalko V. P. Components of pedagogical technology. Moscow, Pedagogy Publ., 1989, 192 p. (In Russian)

13. Lavrentyev G. V., Lavrentyeva N. B. Innovative educational technologies in vocational education of specialists. Barnaul, Altay State University Publ., 2012, 146 p. (In Russian)

14. Clarin M. V. Pedagogical technology in the educational process. Moscow, Knowledge Publ., 1989, 80 p. (In Russian)

15. Monakhov V. M. Technological card – passport of the designed educational process. Novokuznetsk, RPK Publ., 1996, 208 p. (In Russian)

16. Kuznetsova N. Е. Pedagogical technologies in subject-matter teaching. St. Petersburg, Education Publ., 1995, 68 p. (In Russian)

17. Bulanova-Toporkova M. V. Pedagogy and higher school psychology: the manual. Rostov-on-Don, Feniks Publ., 2002, 544 p. (In Russian)

18. Anderson L. W., Krathwohl D. R. A taxonomy for learning, teaching and assessing. New York, Longman Publ., 2001, 208 p.

19. Zyagvyazinsky V. I. Methodology and methods of psychological-and-pedagogical research. Moscow, Academy Publ., 2001, 190 p. (In Russian)

20. Vvedensky B. N. The modeling of teachers’ professional competences. Pedagogy. 2003, no. 10, pp. 51–58. (In Russian)

21. Zhetpisbayeva B. A., Shaikhyzada Zh. G., Syrymbetova L. S. The conceptual model of continuous multilingual education. Middle-East Journal of Scientific Research. 2012, vol. 17, no. 10, pp. 1503–1507.

Date of the publication 17.08.2016