1. Introduction
Zadeh [
1] introduced the subject of a fuzzy set (FS) in 1995. Rosenfeld [
2] proposed the subject of FGs. The definition of FGs was presented by Kaufmann [
3]. Akram et al. [
4,
5,
6] explained several concepts in FGs. Gau and Buehrer [
7] introduced the notion of a vague set (VS) in 1993. The concept of VGs was defined by Ramakrishna [
8]. VGs belong to the FG family, such that have several applications in real-life systems. The system varies with time and has different accuracy levels. Rashmanlou et al. [
9,
10,
11] investigated different subjects of VGs. Moreover, Akram et al. [
12,
13,
14] developed several results on VGs. Kosari et al. [
15] defined vague graph structure and studied its properties. Borzooei [
16] proposed the degree of vertices in VGs. Haynes et al. [
17] expressed the fundamentals of domination in graphs.
Symmetry is a kind of invariant or a feature that a mathematical object remains the same under some operations or transformations. However, symmetry is a significant feature in FG theory, especially in fuzzy DSs. Symmetric graphs have been the subject of much research. For instance, there are known and famous connections between symmetric configurations and regular bipartite graphs. The concept of DSs in VGs, both theoretically and practically, is very valuable. DSs in VGs are used for solving problems of different branches in applied sciences such as location problems. In this way, the study of new concepts such as the DS is essential in VGs. The domination in VGs has applications in several fields. The domination emerges in the facility location problems, where the number of facilities is fixed, and one endeavors to minimize the distance that a person needs to travel to get to the closest facility. Nagoor Gani and Prasanna Devi [
18] suggested the reduction in the domination number of an FG and the notion of 2-domination in FGs [
19] as the extension of 2-domination in crisp graphs. In another study, Somasundram [
20] proposed the domination notion in FGs. The domination in product FGs and intuitionistic FGs were studied by Mahioub [
21,
22]. Karunambigai et al. and Rao et al. [
23,
24,
25] expressed certain domination properties in vague incidence graphs. Kosari et al. [
26,
27,
28] studied the domination of product VGs. The DS concept in FGs, both theoretically and practically, is very valuable. A DS in FGs is used for solving problems of different branches in applied sciences such as location problems. In this way, the study of new concepts, such as DSs, seems essential in FGs. The domination in VGs has numerous applications in several fields. Qiang et al. [
29] introduced new domination concepts in VGs.
The DDS and double domination number (DDN) were first defined and introduced by Harary and Haynes in [
30] as cited in [
31]. Rashmanlou [
32] expressed a new concept of Ring sum in product intuitionistic FGs. Gutman [
33] introduced the graph energy concept. New results on energy are proposed in [
34,
35,
36]. Anjali and Sunil Mathew [
37] extended the energy of the graph to the energy of FGs. Gutman et al. [
38] introduced that the Laplacian energy of a graph is the sum of the absolute deviations (i.e., the distance from the mean) of the eigenvalues of its Laplacian Matrix. Although VGs are better at expressing uncertain variables than FGs, they do not perform well in many real-world situations, such as IT management. Therefore, when the data come from several factors, it is necessary to use VGs. Zeng et al. presented new results in [
39,
40].
In this paper, we introduced a new notion of DSs in VGs. Finally, an application was proposed.
2. Preliminaries
In this section, we present some preliminary results which will be used throughout the paper. In
Table 1, we show the essential notations.
Definition 1. A graph is a pair where X is called the vertex set and is called the edge set.
Definition 2. A pair is an FG on a graph where ζ is an FS on X and η is an FS on E, such thatfor all Definition 3 ([
7])
. A vague set (VS) is a pair on set X, where and are real-valued functions that can be defined on so that, Definition 4 ([
8])
. A pair is called a VG on graph , where is a VS on X and is a VS on E such that for all . is called VS on . A VG is named strong if for all Definition 5. A quadruple form is named DVG, where denotes a degree of membership and denotes a degree of non-membership, defined asfor Note: The DS means a subset is named DS in if for each , there exists one vertex r in so that r dominates s, i.e., Definition 6. Suppose is a DVG. Suppose , we say that r dominates s in if there exists strong edge from r to s. A subset is named DS in if for each , there exists r in such that r dominates s.
A DS of is called to be a minimal DS if no proper subset of is a DS of .
The minimum cardinality of a minimal DS in is named the domination number (DN) of and is denoted by and the corresponding minimal DS is named the minimum DS of .
Definition 7. Suppose is a DVG. The adjacency matrix (AM) of a DVG is defined as , in which where and represent the strength of relationship between and , respectively. This AM of a DVG can be written in two different matrices as , where
Definition 8. The spectrum of AM of a DVG is defined as , where and are the sets of eigenvalues of and , respectively.
Definition 9. The energy of a DVG is defined aswhere and . Example 1. Consider a DVG on and are defined by and , as shown in Figure 1.Similarly,Moreover,Similarly,Here, dominates and dominates becauseTherefore, is a DS because every vertex in is dominated by at least one vertex in The AM of DVG is given below =
We can write in two different matrices as
=
and
=
We obtain
Therefore,
.
Theorem 1. Suppose is a DVG with p vertices and m edges. Suppose is a DS. If are the eigenvalues of AM , thenand if are the eigenvalues of AM , thenwhere Proof. (i) By the trace property of matrices, we have
(ii) Equivalently, the sum of square of eigenvalues of
Similarity, we can show that
□
Theorem 2. Suppose is a DVG with p vertices and m edges. If is the DS, thenwhere and where and Proof. (i) By Cauchy Schwarz inequality, we have
Upper bound
If
and
then
Lower bound
However,
Therefore,
Combining upper bound and lower bound, we have
Similarity, we can show that
For example, the equality is satisfied for the family of graphs in the form of union . □
Theorem 3. Suppose is a VG and is the AM of Suppose is the DVG of and is the DVG AM of . Then Proof. Now
Similarity, we can show that
□
3. Energy of Double Dominating Vague Graphs
In this section, we defined the notion of energy of double dominating vague graphs.
Definition 10. A graph is named DDVG, where denotes a degree of membership and denotes a degree of non-membership, defined as and
Note: The double dominating set (DDS) means a subset is named DDS in if for each , there exists two vertices r in such that r dominates s, i.e., Definition 11. Suppose is a DDVG. Suppose , we say that r dominates s in if there exists strong edge from r to s. A subset is named DDS in if for each , there exists r in such that r dominates s.
A DDS of X is said to be a minimal DDS if no proper subset of is a DDS of . The minimum cardinality of a minimal DDS in is called the DDN of and is denoted by and the corresponding minimal DDS is called the minimum DDS of .
Example 2. The DS of is .
The DN of is
The DDS of .
The DDN of is
Theorem 4. For any VG, then .
Proof. Suppose is a VG. Suppose is a DS and is a DDS of . If , then . If , then has at least one vertices more than and hence, . Therefore, . □
Theorem 5. Suppose is a VG with DDS. Then .
Proof. Suppose is a VG. Suppose is the DDS. Then, . Therefore, . □
Theorem 6. Suppose is a VG, then .
Proof. Suppose is a VG. Then, by Theorem 5, . Therefore, . □
Definition 12. Suppose is a DDVG. The adjacency matrix (AM) of is defined as , where This AM of can be written in two different matrices as , whereand Definition 13. The spectrum of AM of a DDVG is defined as , where and are the sets of eigenvalues of and , respectively.
Definition 14. The energy of a DDVG is defined aswhere and . Example 3. Consider a DVG on and are defined by and , as shown in Figure 3.Similarly,Moreover,Similarly,Here, dominates and dominates and dominates because, Therefore, is a DDS because every vertex in , is dominated by atleast two vertices in The AM of DVG is given below
=
We can write in two different matrices as
=
and
=
We obtain
Therefore,
.
Theorem 7. Suppose is a DDVG with p vertices and m edges. Suppose is a DDS. If are the eigenvalues of AM , thenand if are the eigenvalues of AM , thenwhere Proof. By using similar information as used in Theorem 1. □
Theorem 8. Suppose is a DDVG with p vertices and m edges. If is the DDS, thenwhere and where and Proof. By using similar information as used in Theorem 2. □
Theorem 9. Suppose is a VFG and is the AM of Suppose is the DDVG of and is the AM of . Then Proof. By using similar information as used in Theorem 3. □
4. Application to Select the Best Medical Laboratories
Assume that there are six different medical labs working in a city for conducting tests. The vertices show the laboratories and the edges show the contract conditions among the laboratories to share the facilities or test kits. To make a domination collection among these labs, a collection of labs that have higher quality and have good communication with other laboratories is assumed. It is necessary to find the minimal dominant set to obtain a dominance number. Furthermore, to construct a minimal dominant set with a lab that has higher features (fuzzy vertex value), the maximum neighborhood with the value of the effective edge should be preferred.
Consider a city with 6 labs framed as a VG
with 6 vertices
as shown in
Figure 4. The labs are considered vertex sets of VG, as shown in
Table 2. The relationship between the labs is considered an edge set of VG, as shown in
Table 3. Here, we have to choose the labs that have the quality level and available facilities from the rest of the labs, which are the DSs.
Consider DVG
on
X and
are, therefore, defined by
and
. The quality level of labs is shown in
Table 4.
Here, lab
dominates labs
and lab
dominates labs
and lab
dominates labs
, because
It means that labs have a quality level and available facilities from the rest of the labs, thus, is a DS because every lab is dominated by at least two labs. After selecting the minimum labs that have access to the rest of the labs and are at a high level in terms of facilities and diagnosis of diseases, we will examine the performance of the labs of this city, so by calculating a new concept of energy on the DVG, we presented the quality of the labs. First, we obtain the AM of DVG , which is given below
=
Then we can write the two different matrices as
=
and
=
We obtain
In this part, we conclude that by choosing three laboratories and equipping them and raising their quality level, the level of diagnosis performance in the labs will increase.