Leveraging Game-Based Learning in Mathematics Education: Enhancing Engagement and Efficiency Through Management Information Systems

Authors

  • Besjana Mema Department of Information Technology, Faculty of Informatics, Mediterranean University of Albania, Tirana, 1001, Albania.
  • Albina Basholli Department of Mathematics, Faculty of Mathematics Engineering and Physics Engineering, Polytechnic University of Tirana, 1001, Albania.
  • Zahra Sheikhaleslami Department of Mathematics, University of Tabriz, Bahman 29th Boulevard, 51666- 16471, Tabriz, Iran.

DOI:

https://doi.org/10.22105/kmisj.v1i2.62

Keywords:

Game-Based learning, Information systems, Education, Technology, Optimization

Abstract

The integration of game-based learning (GBL) into mathematics education has emerged as a promising approach to enhance student engagement and understanding of complex concepts. Simultaneously, the use of management information systems (MIS) offers an innovative framework for monitoring and optimizing the implementation of such educational methods. This study explores the intersection of GBL and MIS, focusing on their combined potential to improve teaching and learning outcomes in mathematics. By leveraging MIS, educators can collect and analyze data on student performance, customize learning experiences, and address individual needs effectively. The article also discusses challenges in integrating these technologies and provides recommendations for further development. This research highlights the transformative potential of combining GBL and MIS in fostering a more interactive and data-driven approach to mathematics education.

References

G.S. Boolos, J.P. Burgess, R.C. Jeffrey, Computability and Logic, Cambridge University Press, (5th ed.), ISBN: 9780521701464 (2007).

S.N. Burris, N. Stanley, H.P. Sankappanavar, Course in Universal Algebra, Springer-Verlag, ISBN 3-540-90578-2 Free online edition (1981).

B. Poizat. A Course in Model Theory, Springer, (2000).

P. Cégielski, Théorie Elémentair de La Multiplication des Entiers Naturals. Model Theory and Arithmetic, Proc., 890, 44–89 (1981).

P. Cégielski, The Elementary Theory of the Natural Lattice is Finitely Axiomatizable. Notre Dame Journal of Formal Logic, 30:11, 138–150 (1989).

C.T. Ortiz, Complete Theories of Boolean Algebras, Departament de Matemàtiques Informàtica, June 27, (2018).

Ch. C. Leary, L. Kristiansen, A Friendly Introduction to Mathematical Logic, Milne Library, (2019).

D. Prawitz, D. Westerståhl, Logic and Philosophy of Science in Uppsala, Springer Science and Business Media, Tir 8, 1392 AP–Philosophy - 614 pages.

C.D. Novaes, Formal Languages in Logic, November, (2012), ISBN: 9781107020917.

H.B. Enderton, A Mathematical Introduction to Logic, Academic Press (2nd ed.) (2001), ISBN:9780122384523.

G. Steven, H. Paul, Introduction to Boolean algebras, Undergraduate Texts in Mathematics. Springer,(2009).

S. Salehi, On axiomatizability of the multiplicative theory of numbers. Fundamenta Informaticae, 159:3,279–296 (2018).

S. Salehi, Axiomatizing Mathematical Theories: Multiplication, in: A.Kamali-Nejad (ed). Proceedings of Frontiers in Mathematical Sciences, Sharif University of Technology. Tehran, Iran, 165–176 (2012).

C. Smorynski, Logical Number Theory I Springer-Verlag, (1991).

M.E. Habiˇc, J.D. Hamkins, L.D. Klausner, J. Verner, K.J. Williams, Set-theoretic blockchains. Archive for Mathematical Logic, (2019).

https://www.researchsquare.com/article/rs-2050628/v1.

Downloads

Published

2024-12-20

Issue

Vol. 1 No. 2 (2024): kmisj

Section

Articles

How to Cite

Mema, B. ., Basholli, A. ., & Sheikhaleslami, Z. . (2024). Leveraging Game-Based Learning in Mathematics Education: Enhancing Engagement and Efficiency Through Management Information Systems. Karshi Multidisciplinary International Scientific Journal, 1(2), 258–266 . https://doi.org/10.22105/kmisj.v1i2.62

Similar Articles

1-10 of 11

You may also start an advanced similarity search for this article.

Most read articles by the same author(s)