International Research Journal of Innovations in Engineering and Technology - IRJIET International Open Access, Monthly, Peer Reviewed, Reputed Journal ISSN (online): 2581-3048

Impact Factor (2025): 6.9

DOI Prefix: 10.47001/IRJIET

Generating Symmetric Group Representations for Network Dynamics and Groupoid Formalism

Abstract

Understanding the concept of group theory and to apply it in other field of sciences has been a problem among undergraduate students. Although there are some attempt by Dubinsky et al, [1], where some finite groups were discussed among students, the paper was limited to theoretical aspect of the topic. This research is therefore designed to explore clearly the procedure for constructing finite groups for better understanding of the subject area in the given domain. The research is channeled towards the use of group theory in Network Dynamics, which serves as concrete application of finite groups to the students. Some minor open problems with regards to algebraic graph theory was discussed which lead to network dynamics and groupoid formalism.

Country : Nigeria

1 D. Samaila2 M. P. Agah

  1. Department of Mathematics, Adamawa State University, Mubi, Nigeria
  2. Science Education Department, Adamawa State University, Mubi, Nigeria

IRJIET, Volume 8, Issue 9, September 2024 pp. 8-26

doi.org/10.47001/IRJIET/2024.809002

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References

  1. E. Dubinsky, J. Dautermann, U. Leron and R. Zazkis, “On Learning Fundamental Concepts of Group Theory”, Educational Studies in Mathematics, pp. 1 – 38, 1994. DOI: 10.1007/BF01273732
  2. S. Alabiad& Y. Alkhamees, “Recapturing the structure of group of units of any finite commutative chain ring”, Symmetry13(2), 307, 2021.
  3. A.W. Knapp, “Lie groups beyond an introduction”, (Vol. 140), Boston: Birkhäuser 1996
  4. D. S. Hamermesh, “Why do individual-effects models perform so poorly? The case of academic salaries”, Southern Economic Journal, 39-45, 1989.
  5. M. G. Samaila, C. Lopes, E. Aires, J. B. Sequeiros, T. Simoes, M. M. Freire, & P. R. Inácio, “Performance evaluation of the SRE and SBPG components of the IoT hardware platform security advisor framework”, Computer Networks199, 108496, 2021.
  6. W. William, “Synthesis of monodisperse iron oxide nanocrystals by thermal decomposition of iron carboxylate salts”, Chemical Communications, (20), 2306-2307, 2004.
  7. N. C. Carter, “Visual group Theory”; Classroom Resource Materials Series, Mathematical Association of America.
  8. M. Cremonesi, A. Franci, S. Idelsohn & E. Oñate, “A state of the art review of the particle finite element method (PFEM)”, Archives of Computational Methods in Engineering, 27, 1709-1735, 2020.
  9. G. W. Don, K.K. Muir, G. B. Volk&J. S. Walker, “Music: Broken symmetry, geometry, and complexity”, Notices of the AMS57(1), 2010.
  10. I.Hawthorn, & G. Yue, “Arbitrary Functions in Group Theory”, New Zealand Journal of Mathematics, v.45, pp.1 – 9, 2015.
  11. A.L. Lenz, M. A.Strobel, A. M. Anderson, A. V.Fial, B. A. MacWilliams, J. J. Krzak&K. M. Kruger, “Assignment of local coordinate systems and methods to calculate tibiotalar and subtalar kinematics: a systematic review”, Journal of biomechanics120, 110344, 2021.
  12. Z. Huang & M. Golubitsky, “Classification of infinitesimal homeostasis in four-node input–output networks”, Journal of Mathematical Biology84(4), 25, 2022.
  13. S. Benjamin, “Representation theory of Finite Groups”, Carleton University, Carleton, 2009.
  14. P. André, J. Di Francesco, D. Ward-Thompson, S. I.Inutsuka, R. E. Pudritz & J. E. Pineda, “From filamentary networks to dense cores in molecular clouds: toward a new paradigm for star formation”, Protostars and Planets VI, 27, 2014.

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