Matrix Inequalities for the Fan Product and the Hadamard Product of Matrices ()
1. Introduction
Let
, and
. We write 
if 
for any
. If
, A is called a nonnegative matrix, and if A > 0, A is called a positive matrix. The spectral radius of a nonnegative matrix A is denoted by
.
We denote by Zn the class of all n × n real matrices, all of whose off-diagonal entries are nonpositive. A matrix 
is called an M-matrix if there exists a nonnegative matrix B and a nonnegative real number s, such that 
with
, where I is the identity matrix. If 
(resp.,
), then the M-matrix A is nonsingular (resp., singular) (see [1] [2] ). Denote by Mn the set of nonsingular M-matrices. We define
, where 
denotes the spectrum of A.
The Fan product of two matrices ![]()
and ![]()
is the matrix![]()
, where
![]()
If![]()
, then so is![]()
. In ([2] , p. 359), a lower bound for ![]()
was given: if![]()
, then![]()
.
If![]()
, and![]()
, we write![]()
, where![]()
. Thus we define![]()
. Obviously, JA is nonnegative. Recently, some authors gave some lower bounds of ![]()
(see [3] -[8] ). In [4] , Huang obtained the following result for![]()
,
![]()
(1)
The bound of (1) is better than the bound ![]()
in ([2] , p. 359).
In [7] , Liu gave a lower bound of![]()
,
![]()
(2)
where![]()
. The bound of (2) is better than the one of (1).
For a nonnegative matrix![]()
, let![]()
, where![]()
. We denote![]()
, where![]()
,
![]()
The Hadamard product of two matrices ![]()
and ![]()
is the matrix ![]()
. For two nonnegative matrices A and B, recently, some authors gave several new upper bounds of ![]()
(see [3] -[7] [9] ). In [4] , Huang obtained the following result for![]()
,
1) If![]()
, then
![]()
(3)
2) If ![]()
or ![]()
for some i0, but![]()
, then
![]()
(4)
3) If ![]()
and![]()
, then
![]()
(5)
4) If ![]()
and ![]()
for some i0, j0, then the upper bound of ![]()
is the maximum value of the upper bounds of the inequalities in (3)-(5).
The bound of ![]()
in [4] is better than that in ([2] , p. 358).
In [7] , Liu gave a new upper bound of![]()
,
1) If![]()
, then
![]()
(6)
where![]()
.
2) If ![]()
and ![]()
or ![]()
and ![]()
for some![]()
, but![]()
, then
![]()
(7)
3) If ![]()
and![]()
, then
![]()
(8)
4) If ![]()
and ![]()
for some i0, j0, then the upper bound of ![]()
is the maximum value of the upper bounds of the inequalities in (6)-(8).
The bound of ![]()
in [7] is better than that in [4] .
The paper is organized as follows. In Section 2, we give a new lower bound of![]()
. In Section 3, we present a new upper bound of![]()
.
2. Inequalities for the Fan Product of Two M-Matrices
In this section, we will give a new lower bound of![]()
.
If ![]()
and![]()
, we write ![]()
for the k-th Hadamard power of A. If ![]()
and![]()
, we write![]()
.
Lemma 1. [7] Let![]()
, and let ![]()
be two positive diagonal matrices. Then
![]()
Lemma 2. [2] If ![]()
is a nonnegative matrix and![]()
, then
![]()
Theorem 1. Let ![]()
and![]()
. Then
![]()
where![]()
.
It is evident that the Theorem holds with equality for n = 1. Next, we assume that![]()
.
(1) First, we assume that ![]()
is irreducible matrix, then A and B are irreducible. Obviously JA and JB are also irreducible and nonnegative, so ![]()
and ![]()
are nonnegative irreducible matrices. Then there exist two
positive vectors ![]()
and ![]()
such that ![]()
and![]()
. Let
![]()
Then we have ![]()
and![]()
, that is
![]()
Let ![]()
and ![]()
in which U and V are the nonsingular diagonal matrices
![]()
and![]()
. Then, we have
![]()
![]()
It is easy to see that![]()
, ![]()
, and VU are nonsingular since V and U are. From Lemma 1, we have
![]()
Thus, we obtain![]()
, and
![]()
We next consider the minimum eigenvalue ![]()
of![]()
. Let![]()
. Then we have that![]()
. By Theorem 1.23 of [10] , there exist![]()
, ![]()
, such that
![]()
By Hölder’s inequality, we have
![]()
Then, we have
![]()
Since![]()
, then
![]()
Hence,
![]()
i.e.,
![]()
(2) Now, assume that ![]()
is reducible. It is well known that a matrix in Zn is a nonsingular M-matrix if and only if all its leading principal minors are positive (see [11] ). If we denote by ![]()
the n × n permutation matrix with![]()
, the remaining tij zero, then both ![]()
and ![]()
are irreducible nonsingular M-matrix for any chosen positive real number![]()
, sufficiently small such that all the leading principal minors of both ![]()
and ![]()
are positive. Now, we substitute ![]()
and ![]()
for A and B, respectively, in the previous case, and then letting![]()
, the result follows by continuity.
Remark 1. By Lemma 2, the bound in Theorem 1 is better than that in Theorem 4 of [8] and Theorem 2 of [7] .
Example 1. Let
![]()
By calculating with Matlab 7.1, it is easy to show that![]()
.
Applying Theorem 4 of [4] , Theorem 3.1 of [5] , Theorem 2 of [7] , and Theorem 3.1 of [8] , we have![]()
, ![]()
, ![]()
, and![]()
, respectively. But, if we apply Theorem 1, we have
![]()
The numerical example shows that the bound in Theorem 1 is better than that in Theorem 4 of [4] , Theorem 3.1 of [5] , Theorem 2 of [7] , and Theorem 3.1 of [8] .
3. Inequalities for the Hadamard Product of Two Nonnegative Matrices
In this section, we will give a new upper bound of ![]()
for nonnegative matrices A and B. Similar to [7] , for![]()
, write Q = A − D, where![]()
. We denote ![]()
with![]()
, where
![]()
Note that ![]()
is nonnegative, and ![]()
if![]()
,![]()
. For![]()
, let![]()
, where
![]()
Similarly, the nonnegative matrix ![]()
is defined.
Lemma 3. [2] Let![]()
, and let ![]()
be diagonal matrices. Then
![]()
Lemma 4. [12] Let ![]()
be a nonnegative matrix. Then
![]()
Theorem 2. Let![]()
, ![]()
and![]()
. Then
1) If![]()
, then
![]()
(9)
where![]()
.
2) If ![]()
and ![]()
or ![]()
and ![]()
for some![]()
, but![]()
, then
![]()
(10)
3) If ![]()
and![]()
, then
![]()
(11)
4) If ![]()
and ![]()
for some i0, j0, then the upper bound of ![]()
is the maximum value of the upper bounds of the inequalities in (9)-(11).
Proof. It is evident that 4) holds with equality for n = 1. Next, we assume that![]()
.
(1) First, we assume that ![]()
is irreducible matrix, then A and B are irreducible. Obviously ![]()
and ![]()
are also irreducible and nonnegative, so ![]()
and ![]()
are nonnegative irreducible matrices. Then there exist two positive vectors ![]()
and ![]()
such that ![]()
and![]()
. Let
![]()
Then we have ![]()
and![]()
, that is
![]()
Let ![]()
and ![]()
in which U and V are the nonsingular diagonal matrices
![]()
and![]()
. Then we have
![]()
![]()
It is easy to see that![]()
, ![]()
, and VU are nonsingular since V and U are. From Lemma 4, we have
![]()
Thus, we obtain![]()
, and
![]()
We next consider the minimum eigenvalue ![]()
of![]()
. For nonnegative irreducible matrices ![]()
and![]()
, by definition of the Hadamard product of ![]()
and![]()
, Hölder’s inequality, and Lemma 5, we have
![]()
Thus, we obtain
1) If![]()
, then
![]()
2) If ![]()
and ![]()
or ![]()
and ![]()
for some i0, j0, but![]()
, then
![]()
3) If ![]()
and![]()
, then
![]()
4) If ![]()
and ![]()
for some i0, j0, then the upper bound of ![]()
is the maximum value of the upper bounds of the inequalities in (9)-(11).
(2) Now, we assume that ![]()
is reducible. If we denote by ![]()
the n × n permutation matrix with![]()
, the remaining tij = 0, then both ![]()
and ![]()
are irreducible nonsingular matrices for any chosen positive real number![]()
. Now, we substitute ![]()
and ![]()
for A and B, respectively, in the previous case, and then letting![]()
, the result follows by continuity.
Remark 2. By Lemma 2, the bound in Theorem 2 is better than that in Theorem 6 of [6] and Theorem 3 of [9] .
Example 2. Let
![]()
By calculation with Matlab 7.1, we have![]()
, ![]()
, ![]()
, ![]()
, and![]()
.
If we apply Theorem 6 of [4] , Theorem 3 of [7] , and Theorem 2.2 of [9] , we have![]()
, ![]()
, and![]()
, respectively. But, if we apply Theorem 2, we have
![]()
The numerical example shows that the bound in Theorem 2 is better than that in Theorem 6 of [4] , Theorem 3 of [7] , and Theorem 2.2 of [9] .