1. Introduction
We consider a simple graph
on the vertex set
with
and the edge set
E consisting of unordered pairs of vertices. The adjacency matrix of
G is a
-matrix denoted by
, where
when
i and
j are adjacent, and
otherwise. The degree of vertex
i is
, i.e., the number of its incident edges. The Laplacian matrix of
G is defined to be
, where the diagonal matrix
is called the degree matrix of
G. Since
G is undirected, both
and
are symmetric. Moreover, it follows from algebraic graph theory (e.g., [
1]) that
has
n real eigenvalues arranged in the non-increasing order
, and
has
n real and nonnegative eigenvalues ordered non-increasingly as
.
The Estrada index of
G, given by
is a graph spectral invariant introduced by Estrada [
2] in the year 2000. It has notable applications in biochemistry and complex networks including quantifying the degree of folding of long-chain molecules [
3,
4,
5] and network resilience [
6,
7]. An important variant of Estrada index is the Laplacian Estrada index [
8], which is defined by invoking Laplacian eigenvalues as
A variety of mathematical properties, including upper and lower bounds, of these metric have been investigated; see e.g., [
9,
10,
11,
12,
13] and references therein.
In addition to fixed graphs, Estrada and Laplacian Estrada indices have been recently investigated for classical Erdös-Rényi random graph model as well as random multipartite graphs [
14,
15,
16,
17]. These results are noteworthy in the sense that they not only contribute to the understanding of spectral theory of random networks but also presenting estimates to
and
for almost all graphs (as the number of vertices goes to infinity), which are typically much sharper than previous bounds for fixed graphs. Important ramifications for distance Estrada index [
18] and Gaussian Estrada index [
19,
20] have also been explored lately.
In this paper, we study the Estrada index and Laplacian Estrada index for the class of random interdependent graphs, which consist of m subgraphs with edges between different subgraphs appearing independently with probability p, where is a constant. Formally, an interdependent graph with is defined by a family of subgraphs for with , , and an m-partite graph with E containing edges of unordered pairs between and with . Here, G and are deterministic. A random interdependent graph, denoted by , is a graph from the probability space with containing all possible interdependent graphs , -algebra being the power set of , and probability measure defining the probability of each graph in by assigning probability p for each possible edge of G independently.
Note that the random interdependent graph
is very general in that the random
m-partite graph
is independent of
(
) and no assumption is made on the topologies inside these fixed subgraphs
. It is easy to see that Erdös-Rényi random graph
is a special case with each subgraph
being a single vertex, and random multipartite graph is also a special case of
with each
being an empty graph. Moreover, the stochastic block model extensively utilized in statistics and machine learning literature (see e.g., [
21,
22]) can also be viewed as a special case by setting different edge probabilities in each subgraph.
The rest of the paper is organized as follows. In
Section 2, we examine Estrada index and derive some upper and lower bounds for random interdependent graphs. In
Section 3, we investigate the upper and lower bounds of Laplacian Estrada index for random interdependent graphs. Under certain conditions, the exact estimates for both
and
are obtained. We conclude the paper in
Section 4.
2. Estrada Index of Random Interdependent Graphs
In this section, we estimate the Estrada index of random interdependent graphs. Recall that are the orders of subgraphs . We re-label these subgraphs by so that . Standard Landau asymptotic notations will be used here. For example, for two functions and , implies that ; means that for some constant C for sufficiently large n. A property for a random graph model holds asymptotically almost surely (a.a.s.) if its probability tends to 1, namely, as , where is a flow of algebras, and for each .
Lemma 1 (Weyl’s inequality [
23])
. Consider symmetric matrices and satisfying . Assume that , , and are their eigenvalues, respectively. We havefor all . In many applications of Weyl’s inequality, it suffices to use a special result . We will resort to the full power of this lemma in the following sections.
Theorem 1. Let be a random interdependent graph in . We have Proof. By the construction of random interdependent graph, the adjacency matrix
satisfies the following relations:
and
where
and
are two
n-dimensional block diagonal matrices.
We will first estimate
and the eigenvalues of
. By using (
2) and Lemma 1, we have
For Erdös-Rényi random graph
, it is known that [
14]
and
for
a.a.s. Therefore, we derive
For
,
, it follows from Lemma 1 that
Similarly, we have
a.a.s. for
. A further application of Lemma 1 and decomposition (
2) yields
for
. Hence,
a.a.s. for
. Combining the above discussion, we arrive at
It is well known that Estrada index
can be interpreted as weighted sum of closed walks of all lengths in
G, and hence it changes increasingly with respect to edge addition. More results on the perturbation of Estrada index have been reported in [
24]. In light of (
1) and (
3), we obtain
On the other hand, if
(
) are complete graphs, the Estrada index
will attain its maximum. In this case, the eigenvalues of
satisfy
and
. Therefore, using (
1) and Lemma 1, we have
For
,
, similarly,
and for
,
, we have
It follows from the above comments and the definition of Estrada index that
where the last equality holds since
The theorem thus follows from (
4) and (
5). ☐
Corollary 1. Let be a random interdependent graph in . If , we have Proof. Recall that
p is a constant. If
, then
a.a.s. by using (
4) and (
5). ☐
Corollary 1 gives an exact estimate for Estrada index of random interdependent graphs. This result reveals that only depends on the inter-subgraph edge probability p and is independent of the intra-subgraph architectures. This highlights that the inter-network connections in such graph models have an essential role.
In
Table 1 we show the theoretical and experimental values for
with
subgraphs,
and
.
3. Laplacian Estrada Index of Random Interdependent Graphs
In this section, we consider Laplacian Estrada index
for random interdependent graphs. The following result in regard to the Laplacian eigenvalues of random multipartite graphs has been essentially proved in [
16]. We rephrase it as follows.
Lemma 2. For ,and Theorem 2. Let be a random interdependent graph in . We have Proof. By the definition of random interdependent graphs, we observe that
where
is a block diagonal matrix with component blocks representing the Laplacian matrices of subgraphs.
To estimate
, we need to bound the eigenvalues of
. Note that the Laplacian eigenvalues vary monotonically with respect to edge addition or removal; see e.g., the interlacing theorem ([
1] Theorem 7.1.5). Therefore, in view of Lemma 2, we have the following lower bounds
for
, and
We obtained (
7) and (
8) by thinking all subgraphs
as empty. On the other hand, if all these subgraphs are complete graphs, then
, and
. Here, we used the multiset representation
, meaning the multiplicity of element
is
, etc. Therefore, by using Lemmas 1 and 2, and (
6), we have
for
.
Recall that
. We define
,
, ⋯,
. For
,
, it follows from Lemmas 1 and 2 that
By the definition of Laplacian Estrada index and the estimates (
7)–(
10),
With a further look into the above lower and upper bounds, we have
and
The proof is complete. ☐
Corollary 2. Let be a random interdependent graph in . If , we have Proof. If
, by Theorem 2 we have
Since , we obtain a.a.s. The proof is complete. ☐
Similar to Corollary 1, the Laplacian Estrada index only relies on the inter-subgraph edge probability p and is independent of the intra-subgraph topologies. If more information is available for the structure of subgraphs , we may be able to derive sharper bounds for the (Laplacian) Estrada index of these interdependent graphs.
In
Table 2 we show the theoretical and experimental values for
with
subgraphs,
and
.