A Generalized Cramer’s Rule for Tri- Component Interval-valued Neutrosophic Linear Systems

Authors

  • Khadija Basher Sola Author

Keywords:

Neutrosophic, Linear Systems, Determinants, Cramer's Rule, Libya

Abstract

This paper introduces a novel method for solving tri- component interval-valued Neutrosophic linear systems. Building upon fundamental concepts of Neutrosophic sets, including tri-component interval numbers and their algebraic operations, we first derive a generalized matrix representation for systems with n linear equations with m unknowns in this uncertain environment. The core contribution of this work is the development of a generalized Cramer’s rule tailored for these Neutrosophic systems, providing an analytical framework for obtaining solutions under conditions of incompleteness, inconsistency, and indeterminacy. The efficacy and robustness of the proposed method are demonstrated through compassing numerical examples, encompassing binary and generalized system cases. These examples illustrate all possible types of solution: unique solution, no solution, and infinitely many solutions. This research focuses on the theoretical and analytical aspects of solving Neutrosophic systems, relying on Cramer’s rule to find abstract mathematical solutions.

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References

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Published

2026-06-30

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Research Articles

How to Cite

A Generalized Cramer’s Rule for Tri- Component Interval-valued Neutrosophic Linear Systems. (2026). Journal of Basic and Applied Sciences, 25(1), 1-26. https://lafsrj.lafsrj.ly/index.php/JBAS/article/view/2

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