Abstract
The edge -labeling of is defined by a mapping from to a set of integers , where the integer weight assigned to the vertex is given as , such that the sum is taken over every vertex of that is adjacent to and the integer weights of adjacent vertices must be distinct for all vertices with . An irregular assignment of using atmost labels which is considered to be a minimum is defined as irregularity strength of a graph and can be denoted as . There are also further works on familiar irregular assignments, such as edge irregular labelings, vertex irregular total labelings, edge irregular total labelings, and face irregular entire -labelings of plane graphs. A plane graph can be defined as a graph that is embedded in the plane in which no two lines will be intersected. In a plane graph the number of regions present are called faces and we denote it as . The concept of total face irregularity strength is defined by the motivation of irregular networks and entire irregular face -labeling. In our paper, we have obtained a minimum bound for the total face irregularity strength of two-connected plane graphs like cycle-of-ladder, -necklace graph, -necklace graph, sibling tree, and triangular graph.
1. Introduction
Graph theory is an interesting topic of research in combinatorics. Graph-based models are a powerful and indispensable tool for solving practical issues. In general, new algorithms that are appropriate for graph structures have been explored as a result of the development of contemporary theoretical issues such as labeling in graph theory. At present the utilization of computers is increasing in human life and our future is entirely becoming computer oriented. Most of the applications use graphs as their underlying structures, say for example, Google search engines are primarily based on the concept of shortest paths in the graph theory. As a result, graph theory has grown to be an enormous field of study in mathematics.
The concept of graph labeling was established in the middle of 1960’s. Graph labeling can be defined as the assignment of integer labels (values) to the links and/or nodes of a graph. One important motive in graph labeling is to fulfill some conditions that are imposed on the graph. In general, a lot of graph labeling problems started off in connection with some real-time applications such as the exam scheduling and tournament scheduling problems in sports. In recent times, graphs with a defined set of labels (integers) allocated to the vertices, edges, or both based on certain given conditions are being explored. These graphs are termed as labeled graphs. Labeled graphs are studied as an important concept in graph theory because of their innumerable applications. These labeled graphs are also of interest in their own way because of their theoretical mathematical properties of the underlying graphs. Research works on the labeling of graphs are being encouraged in several domains such as human inquiry, including resolution of conflicts in psychology, cybernetic systems, and energy shortages. Mathematical labeling of various graphs has resulted in rather complex domains of application, such as the theory of coding problems, such as the development of excellent radar position codes, missile navigation codes, and convolution signals. There are numerous theoretical applications for labeled graphs in combinatorial number theory, group theory, and in linear algebra [1]. In general, the graph labeling problem can be described as follows: for a given graph, find the optimal way of labeling the vertices/edges or both with distinct integers or -tuples of integers subject to certain objectives. Many fascinating applications for graph labeling are found in Bloom and Golomb’s [2, 3] papers.
We consider the vertex set and edge set of a finite, simple, and undirected graph . An irregular assignment of maybe defined as the labeling of edges of with a set of positive integer such that the total (sum) of the labels that are incident with some vertex is distinct for every vertex. Chartrand et al. [4] introduced this concept. They discovered that for any graph, the irregularity strength , which is the lowest possible value for which constitutes an irregular assignment with label at most , is extremely difficult to find. In recent times, motivated by this particular concept, many researchers are having specific interest for these types of irregular labeling and have found the irregularity strength for some graphs [5–10]. Shabbir et al. [11] have proved their exact values of the strength of total vertex (edge) irregularities of a randomly convex unions of (3,6)-fullerene graphs. In 2022, Bača et al. [12] investigated the irregular labelings with respect to face of plane graphs and have found a new graph characteristic which can be termed as face irregularity strength of a few types . Also, Tilukay et al. [13] have estimated the bounds of total face irregularity strength and have proved that the lower bound is sharp for isomorphic to a cycle, a book with polygonal pages, or a wheel. Further, Jamil and Mughal [14] have studied of generalized plane grid graphs and wheel graphs under a graph -labeling of type where . Since a total labeling is defined for both edges and vertices, it is difficult to find the lower bounds for certain higher dimensions of graphs.
In our paper, we have obtained a lower bound for the of two-connected plane graphs like cycle-of-ladder, -necklace graph , -necklace graph , sibling tree, as well as a lower bound for is obtained for triangular graph.
2. Preliminaries
The concept of irregularity strengths and a recent publication on entire coloring of plane graphs [15] served as the inspiration for Bača’s et al. [16] study of face irregular entire -labeling of plane graphs in 2015. In the sections below, for a graph we denote the number of cycles of length as .
In the year 2016, Packiam [17] has defined the concept of total face irregularity strength. The following theorems give the lower bound for total face irregularity strength of a plane graph.
Theorem 1 [17]. Let be a plane graph with -sided faces where and . Then .
Theorem 2 [17]. Let be a two-connected plane graph with -sided faces where and . Then
We now propose the following theorem:
Theorem 3. Let be a two-connected plane graph and be the girth in . Then .
Proof. Let . Clearly, . Therefore,
Remark 1. Theorem 3 implies that it is not always necessary to consider all the cycles induced by the plane graph faces.
3. Main Results
3.1. Cycle-of-Ladder
In this section, the is obtained for cycle-of-ladder (Figure 1) where its graph theoretical definition given in [18, 19].
Lemma 1. Let be the , where are considered as the rungs of equal length and be a girth in . Then .
Proof. In , the shortest cycle length is 4. Hence, . By Theorem 3, . Therefore, .
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Remark 2. Algorithm 1 holds good for , .
3.2. C-Necklace Graph,
In this section, we obtain the of -necklace graph, , .
Definition 1 [20]. Let us consider to be a cycle with vertices which is called the inner cycle and for ; let be a cycle on vertices called the outer cycle. The resulting graph is called -necklace graph that is obtained by attaching any one vertex of to the corresponding vertex of the cycle , and we denote it by . It has vertices and edges.
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Proof of correctness: Let be a -necklace graph, , . Let and be the vertices and edges of the inner cycle. Then by our labeling Algorithm 2, the weight of that face is . Further, if and are the vertices and edges of the outer cycles, respectively, then the weights of , , varies from to , thereby , for every two distinct faces and of . Further,
3.3. -Necklace Graph,
In this section, a lower bound for the total face irregularity strength is obtained for -necklace graph, , . The definition of is given in [20].
Definition 2 [20]. Let us consider to be a path with vertices and is a cycle with vertices, . The resulting graph is called -necklace graph that is obtained by attaching any one vertex of to the corresponding vertex of , and we denote it by .
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Proof of correctness: Let be a -necklace graph, , . Let and be the vertices and edges in , respectively. Then by our labeling Algorithm 3, the weight of this face is . The weights of all the faces vary between and . Therefore, for every two distinct faces and of , .
3.4. Sibling Tree
In this section, the total face irregularity strength is obtained for sibling tree. The formal definition of sibling tree can be seen in [21, 22].
Lemma 2. Let be a sibling tree. The total face irregularity strength of is given by for .
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Proof of correctness: Let be a sibling tree, , for . Let and be the vertices and edges in each cycle , respectively. Then by our labeling Algorithm 4, the weight of the face of the first cycle of length is . The weights of all the faces of the cycles of length vary between and . Therefore, for every two different faces and of , as illustrated in Figure 4.
3.5. Triangular Graph
In this section, a lower bound for the is obtained for triangular graph. Figure 5 shows the diagrammatic representation of triangular graph.
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Lemma 3. Let be the number of cycles of length 6 in . The total face irregularity strength of triangular graph is given by:
Proof. With minimum label , the weight of a face is . If is the number of cycles of length 6, then the weights vary between and . Hence .
Remark 3. Label the vertices and edges in Levels , and of as shown in Figure 5(b) as 1 and the vertices and edges in Level as and the perpendicular edges between Levels and as , between Levels and as and between Levels and as . The graph has six faces. It is easy to see that the weights of the faces are all distinct and sequential. Hence .
Open problem: Let be the number of cycles of length 6 in , . Then .
4. Conclusion
We have found the total face irregularity strength of plane graphs like cycle-of-ladder, necklace graph, necklace graph, and sibling tree. For triangular graphs, we have established a lower bound on their total face irregularity strength. Our labeling approach on the vertices and edges of graphs is focused on estimating face weights of graphs in order to prove the sharpness of -labeling. Excitingly, we are now exploring the total face irregularity strength of plane graphs like Sierpinski-like graphs, Schreier graphs, and WK-recursive networks, all of which find numerous practical applications in network theory. In general, it would be really challenging to improve the lower bound of total face irregularity strength for both plane graphs and their dual counterparts.
Data Availability
No underlying data were collected or produced in this study.
Conflicts of Interest
The authors declare that they have no conflicts of interest.