Let G be a simple undirected graph with vertex and edge sets. A total labeling that assigns integers from 1 to k to the union of the vertex and edge sets is called a k-total labeling. The weight of an edge uv, denoted by w(uv), is defined as the sum of the labels of the two vertices u, v, and the label of edge uv itself. A k-total labeling is called an edge irregular total k-labeling of G if the weights of all distinct edges are different. The minimum k for which every edge of G has a distinct weight is called the total edge irregularity strength of G, denoted by tes(G). A cycle snake graph CS_m,n is obtained from the path graph P_n with n + 1 vertices and n edges by replacing each edge with a cycle graph C_m, where m ≥ 3 and n ≥ 2. In this paper, we study the graphs CS_3,n and CS_m,n and determine their total edge irregularity strength. The case m = 3 is considered separately because the structure of CS_3,n gives a different representation of the vertex and edge sets than for m ≥ 4, requiring a different labeling construction.

cycle snake graph; edge irregular total $k$-labeling; total edge irregularity strength

[1] W. D. Wallis. Magic Graphs. Birkhäuser, 2001. doi: 10.1007/978-1-4612-0123-6.

[2] Ruslan Sadykov, Artur Pessoa, and Eduardo Uchoa. “A Bucket Graph Based Labelling Algorithm for Vehicle Routing Pricing”. In: POC Autumn School on Advanced BCP Tools. Paris, France, Nov. 2019. https://hal.science/hal-02378624/.

[3] Ghaffar Raeisi and Mohammad Gholami. “Edge coloring of graphs with applications in coding theory”. In: China Communications 18.1 (2021), pp. 181–195. doi: 10.23919/JCC.2021.01.016.

[4] P. Mariaraja, Hussein Z. Almngoshi, C. M. Hilda Jerlin, S. Muthuperumal, K. Amarendra, Sudhakar Sengan, and Pankaj Dadheech. “Lucky edge geometric mean labeling of graphs and applications in electrical networks”. In: Journal of Discrete Mathematical Sciences and Cryptography 27.7 (2024), pp. 2133–2141. doi: 10.47974/JDMSC-2086.

[5] C. Yogalakshmi and B. J. Balamurugan. “Graph coloring–driven topological indices for QSPR modeling and MCDM prioritization of brain tumor drugs”. In: Results in Engineering 29 (2026), p. 109470. doi: 10.1016/j.rineng.2026.109470.

[6] Martin Bača, Stanislav Jendrol’, Mirka Miller, and Joseph Ryan. “On irregular total labellings”. In: Discrete Mathematics 307.11–12 (2007), pp. 1378–1388. doi: 10.1016/j.disc.2005.11.075.

[7] Nurdin, E. T. Baskoro, A. N. M. Salman, and N. N. Gaos. “On the total vertex irregularity strength of trees”. In: Discrete Mathematics 310.21 (2010), pp. 3043–3048. doi: 10.1016/j.disc.2010.06.041.

[8] Ali Ahmad, E. T. Baskoro, and M. Imran. “Total vertex irregularity strength of disjoint union of helm graphs”. In: Discussiones Mathematicae Graph Theory 32.3 (2012), pp. 427–434. doi: 10.7151/dmgt.1619.

[9] Nurdin Hinding, Hye Kyung Kim, Nurtiti Sunusi, and Riskawati Mise. “On Total Vertex Irregularity Strength of Hexagonal Cluster Graphs”. In: International Journal of Mathematics and Mathematical Sciences 2021 (2021), p. 2743858. doi: 10.1155/2021/2743858.

[10] Stanislav Jendrol’, Jozef Miškuf, and Roman Soták. “Total edge irregularity strength of complete graphs and complete bipartite graphs”. In: Discrete Mathematics 310.3 (2010), pp. 400–407. doi: 10.1016/j.disc.2009.03.006.

[11] Martin Bača and Muhammad Kamran Siddiqui. “Total edge irregularity strength of generalized prism”. In: Applied Mathematics and Computation 235 (2014), pp. 168–173. doi: 10.1016/j.amc.2014.03.001.

[12] Riyan Wicaksana Putra and Yeni Susanti. “On total edge irregularity strength of centralized uniform theta graphs”. In: AKCE International Journal of Graphs and Combinatorics 15.1 (2018), pp. 7–13. doi: 10.1016/j.akcej.2018.02.002.

[13] F. Salama. “Computing the total edge irregularity strength for quintet snake graph and related graphs”. In: Journal of Discrete Mathematical Sciences and Cryptography 25.8 (2022), pp. 2491–2504. doi: 10.1080/09720529.2021.1878627.

[14] Fatma Salama and Randa M. Abo Elanin. “On total edge irregularity strength for some special types of uniform theta snake graphs”. In: AIMS Mathematics 6.8 (2021), pp. 8127–8148. doi: 10.3934/math.2021471.

[15] F. Salama. “Computing total edge irregularity strength for heptagonal snake graph and related graphs”. In: Soft Computing 26.1 (2022), pp. 155–164. doi: 10.1007/s00500-021-06364-2.

[16] Hala Attiya, Nasr Ahmed, and Fatema Salama. “Total Edge Irregularity Strength of Star Snake Graphs”. In: European Journal of Pure and Applied Mathematics 18.2 (2025), p. 5673. doi: 10.29020/nybg.ejpam.v18i2.5673.