The further generalization on the inequalities for Hadamard products of any number of invertible Hermitian matrices

Without ‘positive definiteness’ demanded in the present papers, the forward and reverse inequalities for Hadamard products of any number of invertible Hermitian matrices are obtained, and the sufficient and necessary conditions for the equations in these inequalities are given. As Hermitian positive matrices naturally satisfy the added constraints, these results generalize and improve the corresponding results in the present papers. Beyond that, with no demand of ‘positive definiteness’, these forward and backward inequalities are not determined mutually any longer.

Throughout the paper, we assume $C^{m\times n}$ is the set of $m\times n$ complex matrices, I is a identity matrix, $E_{ii}$ is a diagonal matrix with 1 at its $(i,i)$th position and 0 elsewhere, and $Z_n={[E_{11},E_{22},\dots ,E_{nn}]}^{\ast }\in C^{n^2\times n}$ is a selection matrix. $A^{\ast }$ stands for the conjugate transpose of $A\in C^{m\times n}$. The matrix A is Hermitian if $A^{\ast }=A$, denoted by $A\in H(n)$. Furthermore, we denote by $H_0^{+}(n)$ and $H^{+}(n)$ the sets of Hermitian semi-positive matrices and Hermitian positive matrices, respectively. Recall that A, B are said to have the inequality $A\ge B$ or $B\le A$, if $A-B\in H_0^{+}(n)$. In particular, $A\in H_0^{+}(n)$ (resp. $A\in H^{+}(n)$), denoted by $A\ge 0$ (resp. $A>0$), and denoted by $A^{\frac{1}{2}}$ the square root of A. For a positive integer k, we have $\alpha (k)\subseteq 〈n^k〉=\{1,2,\dots ,n^k\}$, ${\alpha }^{\prime }(k)=〈n^k〉-\alpha (k)$. Especially, $\alpha =\alpha (1)\in 〈n〉$. For $A\in C^{n\times n}$, $A(\alpha ,\beta )$ denotes the submatrix of A lying in rows indexed by α and the columns indexed by β and $A(\alpha ,\alpha )=A(\alpha )$. The Hadamard and Kronecker products of $A=(a_{ij})$, $B=(B_{ij})$ are defined as $A\circ B=(a_{ij}{b}_{ij})$ and $A\otimes B=(a_{ij}B)$, respectively. If $AXA=X$, $XAX=X$, ${(AX)}^{\ast }=AX$, and ${(XA)}^{\ast }=XA$, then X is said to be a Moore-Penrose generalized inverse of A, denoted by $X=A^{+}$.

Recall that if every diagonal element of $R\in H_0^{+}(n)$ is 1, then R is said to be a correlation matrix, in symbol $R\in C{H}_0^{+}(n)$ (see [1]). The invertible matrix $A\in H_0^{+}(n)$ implies $A\in H^{+}(n)$, thus the set of invertible matrices $C{H}^{+}(n)\subset H^{+}(n)$.

By multivariate analysis, Styan obtained the inequalities as follows in 1973 (see [[1], Theorem 4.1, Corollary 4.2(4.21) and Corollary 4.3]):

Meanwhile, Styan pointed out ‘A matrix-theoretic proof of Theorem 4.1 would be of interest.’ (see [1]).

Many papers [2–10] focus on the generalization of inequalities (1.1)-(1.4) to Hermitian (semi-)positive matrices by matrix methods. As a generalization of the usual Hadamard product, the Khatri-Rao product [5, 6, 8] has many similar properties to the Hadamard product (see [5]), thus here we only focus on the Hadamard product, a basic product. Referring to [2] and [6], we denote

In 1979, Ando [2] obtained the following.

Proposition 1.1 (see [[2], Theorem 20])

Let $A\in H^{+}(n)$, for any positive integer k (≥2), one has

When $k=2$, the inequality (1.5) implies (1.3). Ando also made clear, by applying the method of Proposition 1.1, that one has the following.

Proposition 1.2 (see [[2], p.239])

Let $A,B\in H^{+}(n)$. Then

In 2000, Zhang showed the following.

Proposition 1.3 (see [[3], Application 4])

Let $A,B\in H^{+}(n)$. Then

As applications, (1.2) and (1.4) were also given by Visick in 2000 (see [[4], Theorem 20]).

Moreover, Al Zhour and Kilicman obtained a matrix inequality as follows in 2006 (see [[6], Theorem 4.4]):

For $A\in H_0^{+}(n)$, by [11], one has $A^{\frac{1}{2}}{A}^{+\frac{1}{2}}=A{A}^{+}$. Because of the commutativity of the Hadamard product, the inequality (1.9) is equivalent to [[7], Proposition 1], [[8], Corollary 1(5)], it could be viewed as a generalization of (1.4) over Hermitian semi-positive matrices.

For $A,B\in H^{+}(n)$, (1.6) and (1.7) are the forward and backward inequalities to each other, and determined mutually as well (Theorem 2.6), [8] has ever called them as companion inequalities. Of course, (1.1) and (1.2), (1.3) and (1.4) are also the companion inequalities determined by each other (Lemma 2.4). In fact, [[9], Theorem 1] shows us the backward inequality which is companied to (1.9).

Papers [1–10] all discuss on Hermitian (semi-)positive matrices. However, the following Example 1.4 illustrates that the condition ‘positive definiteness’ is not necessary for the inequality (1.7) to hold.

Example 1.4 Let $A=\frac{1}{2}\left[\begin{array}{cc}-1& 1\\ 1& 1\end{array}\right],B=\frac{1}{3}\left[\begin{array}{cc}1& 1\\ 1& -2\end{array}\right]\in H(2)$. Then the matrix inequality (1.7) holds, this is because

Example 1.5 Let $A=\left[\begin{array}{cc}-1& 1\\ 1& 1\end{array}\right],B=\left[\begin{array}{cc}-1& 1\\ 1& 2\end{array}\right]\in H(2)$. Then the inequality (1.7) does not hold anymore, this is because

Example 1.5 indicates that, in general, the matrix inequality (1.7) does not hold for all invertible Hermitian matrices. Hence we will add some constraint conditions in our discussion.

In this paper, without the ‘positive definiteness’ demanded in the inequality (1.5), we will show inequalities and their companion forms for any number of invertible Hermitian matrices and get sufficient and necessary conditions for the equations in the related inequalities to hold. In view of [12, 13]etc., we see the discussion of the equation conditions for the inequalities is significant. Further, Hermitian positive matrices satisfy the added constraints naturally, thus these results generalize and improve the corresponding results in the present literature. However, with no demand of ‘positive definiteness’, the new forward and backward companion inequalities are not determined mutually.

For matrices of appropriate sizes, in view of [[14], Proposition 4.2.14] and [[15], Propositions 7.13-7.17], by induction to k, it follows that

Lemma 2.1 Let $A_l\in C^{n\times n}$, $l=1,2,\dots ,k$. Then

Proof In view of [[4], Theorem 1 and Corollary 2] or [[15], Proposition 7.3.1] yields

that is,

which indicates (2.7) and (2.8) hold for $k=2$.

By (2.9), (2.1), (2.3), and (2.4), similar to [[10], Lemma 2.1], it follows that

that is,

As $E_{ii}{E}_{jj}=E_{ii}$ ($i=j$), $E_{ii}{E}_{jj}=0$ ($i\ne j$), and $E_{ii}\in H(n)$, by (2.9) and (2.10), we see

which shows the $\alpha (3)$ determined by $P(n,3)$ satisfies (2.8), then (2.7) holds.

Just as the proof of [[10], Lemma 2.1], similarly, one has

thus the $\alpha (k)$ determined by $P(n,k)$ satisfies (2.8), then (2.7) follows by (2.11). □

The proof method of Lemma 2.1 plays a great role in discussing the matrix inequalities for Khatri-Rao products of any finite number of positive matrices (see [[16], Lemma 2.1], [[6], Lemmas 2.1 and 2.2]). Recently, [[17], Theorem 3] has also discussed a similar problem to Lemma 2.1, but our results (2.7) and (2.8) should be more convenient in applications.

When $A\in C^{n\times n}$, if $\alpha =\alpha (1)\in 〈n〉$ and $A(\alpha )$ is invertible, we call

the Schur complement of $A(\alpha )$ in A (see [8, 18, 19]).

Lemma 2.2 Let $A\in H(n)$ and $A({\alpha }^{\prime })$ be both invertible. Then both of $A/{\alpha }^{\prime }$ and $A^{-1}(\alpha )$ are invertible as well, and ${(A/{\alpha }^{\prime })}^{-1}=A^{-1}(\alpha )$.

Proof By assumption, there exists a permutation matrix U such that

Since both of A and $A({\alpha }^{\prime })$ are invertible, by (2.12), one has a matrix $V=\left[\begin{array}{cc}I& 0\\ -A{({\alpha }^{\prime })}^{-1}A({\alpha }^{\prime },\alpha )& I\end{array}\right]$ such that

thus $A/{\alpha }^{\prime }$ is invertible. By (2.12),

by comparing with (2.12), it follows that $A^{-1}(\alpha )$ is invertible and ${(A/{\alpha }^{\prime })}^{-1}=A^{-1}(\alpha )$. □

When $A\in H^{+}(n)$, it is natural that $A({\alpha }^{\prime })$ is invertible, hence we could obtain [[18], formula (4)] again by Lemma 2.2.

Lemma 2.3 Let $C\in C^{n\times n}$ and $A\in H(n)$ be invertible, $\alpha \subset 〈n〉$, ${\alpha }^{\prime }=〈n〉-\alpha$, if $A^{-1}({\alpha }^{\prime })>0$, then $A(\alpha )$ is invertible and

Moreover, the equation in (2.13) holds if and only if $A^{-1}({\alpha }^{\prime },\alpha )C(\alpha )+A^{-1}({\alpha }^{\prime })C({\alpha }^{\prime },\alpha )=0$.

Proof In this case, there is a permutation matrix U such that (2.12) holds and $U^{\ast }CU=\left[\begin{array}{cc}C(\alpha )& C(\alpha ,{\alpha }^{\prime })\\ C({\alpha }^{\prime },\alpha )& C({\alpha }^{\prime })\end{array}\right]$, then

By assumption, both of $A^{-1}\in H(n)$ and $A^{-1}({\alpha }^{\prime })$ are Hermitian and invertible, then by applying Lemma 2.2, $A(\alpha )$ is invertible and

combining with (2.12), there exists $W=\left[\begin{array}{cc}I& 0\\ -A^{-1}{({\alpha }^{\prime })}^{-1}{A}^{-1}({\alpha }^{\prime },\alpha )& I\end{array}\right]$ such that

By (2.14)-(2.16), as $A^{-1}({\alpha }^{\prime })>0$, then $(C^{\ast }{A}^{-1}C)(\alpha )-C{(\alpha )}^{\ast }A{(\alpha )}^{-1}C(\alpha )=X^{\ast }{A}^{-1}({\alpha }^{\prime })X\ge 0$, that is, (2.13) follows. Meanwhile, the equation in (2.13) holds; therefore $X=0$, it is equivalent to

 □

For a Hermitian positive matrix A, one has $A^{-1}({\alpha }^{\prime })>0$; then we get [[3], Theorem 1(7)] again by Lemma 2.3.

Lemma 2.4 Let $F,G\in H^{+}(n)$. Then

Proof In this case, $M=\left[\begin{array}{cc}F& T\\ T^{\ast }& G\end{array}\right]\in H(2n)$, and there exist invertible matrices $P=\left[\begin{array}{cc}I& 0\\ -G^{-1}{T}^{\ast }& I\end{array}\right]$ and $Q=\left[\begin{array}{cc}I& -F^{-1}T\\ 0& I\end{array}\right]$ such that

which indicates

 □

Lemmas 2.2-2.4 will play an important role in the discussion.

Theorem 2.5 Let $A\in H^{+}(n)$, for any positive integer k (≥2). Then

Moreover, the equation in (1.5) holds if and only if the one in (2.17) holds.

Proof As $A\in H^{+}(n)$, by (2.6), ${\prod }_{l=1}^k\circ A,A^{-1}\circ ({\prod }_{l=1}^{k-1}\circ A)+(k-1){(A\circ I)}^{k-2}\in H^{+}(n)$. Taking $T^{\ast }=T=\sqrt{k}{(A\circ I)}^{k-1}\in H(n)$, in view of Proposition 1.1, yields the inequality (1.5), that is, ${\prod }_{l=1}^k\circ A\ge T^{\ast }{(A^{-1}\circ ({\prod }_{l=1}^{k-1}\circ A)+(k-1){(A\circ I)}^{k-2})}^{-1}T$, then by Lemma 2.4, $A^{-1}\circ ({\prod }_{l=1}^{k-1}\circ A)+(k-1){(A\circ I)}^{k-2}\ge T^{\ast }{({\prod }_{l=1}^k\circ A)}^{-1}T$, which shows (2.17) holds, meanwhile, the equation in (1.5) holds; therefore the one in (2.17) holds. □

Theorem 2.5 not only leads to the backward inequality (2.17) of (1.5) (in this case, the inequalities (1.5) and (2.17) are mutually determined), but it also shows us that the inequalities (1.1) and (1.2), (1.3) and (1.4) given by Styan are companied and determined by each other (the case of $k=2$ in Theorem 2.5).

By applying Lemma 2.4, Propositions 1.2 and 1.3, with a similar discussion as Theorem 2.5, we have the following.

Theorem 2.6 Let $A\in H^{+}(n)$. Then the inequalities (1.6) and (1.7) are companied and determined by each other, and the equation in (1.6) holds; therefore the one in (1.7) holds.

For Hermitian matrices $A_l$ ($l=1,2,\dots ,k$), unless otherwise specified, we always assume

Theorem 3.1 Let $A_l\in H(n)$ be invertible, $l=1,2,\dots ,k$, and $\alpha (k)$ be as in (2.7) and (2.8), if $({\prod }_{l=1}^k\otimes A_l^{-1})({\alpha }^{\prime }(k))>0$, then ${\prod }_{l=1}^k\circ A_l$ is also invertible and

Moreover, the equation in (3.1) holds if and only if

Proof By (2.6), we see $C={\sum }_{t=1}^k[({\prod }_{l=1}^{t-1}\otimes A_l)\otimes I\otimes ({\prod }_{l=t+1}^k\otimes A_l)]\in H(n^k)$, and by (2.5), ${\prod }_{l=1}^k\otimes A_l^{-1}={({\prod }_{l=1}^k\otimes A_l)}^{-1}$ is invertible. From our assumption, $({\prod }_{l=1}^k\otimes A_l^{-1})({\alpha }^{\prime }(k))>0$, then by applying (2.7) and Lemma 2.3, ${\prod }_{l=1}^k\circ A_l=({\prod }_{l=1}^k\otimes A_l)(\alpha (k))$ is invertible. By the commutativity of Hadamard products, combining with (2.1)-(2.6) yields

that is,

By (2.7), (2.13), and (3.3), we have $C(\alpha (k))={\sum }_{t=1}^k[({\prod }_{l\ne t}\circ A_l)\circ I]=N\in H(n)$, and

so (3.1) holds.

From Lemma 2.3, the equation in (3.1) holds; therefore

 □

From Theorems 2.5 and 2.6, we see the inequalities (1.1) and (1.2), (1.3) and (1.4), and the general ones (1.5) and (2.17), (1.6) and (1.7) are companied and determined by each other, hence one of the companion inequalities could be obtained from the other one immediately. However, the following example indicates that the matrix inequality (3.1) is no longer equivalent to its backward inequality, without ‘positive definiteness’.

Example 3.2 Let A, B just as the one in Example 1.4, as $(A^{-1}\otimes B^{-1})({\alpha }^{\prime }(2))=\left[\begin{array}{cc}1& 1\\ 1& 2\end{array}\right]>0$, then (1.7) follows by Theorem 3.1, but the inequality (1.6) does not hold; this is because

Theorem 3.3 Let $A_l\in H(n)$ ($l=1,2,\dots ,k$) be invertible, and $\alpha (k)$ be as in (2.7) and (2.8), if C is invertible and $(C^{-1}({\prod }_{l=1}^k\otimes A_l)C^{-1})({\alpha }^{\prime }(k))>0$, then ${\sum }_{t=1}^k(A_t^{-1}\circ ({\prod }_{l\ne t}\circ A_l))+2{\sum }_{1\le t<s\le k}(({\prod }_{l\ne t,s}\circ A_l)\circ I)\in H(n)$ is invertible as well and

Moreover, the equation in (3.4) holds if and only if

Proof By (2.6), $C\in H(n^k)$ is invertible, then ${\prod }_{l=1}^k\otimes A_l=C^{\ast }{(C^{\ast }{({\prod }_{l=1}^k\otimes A_l)}^{-1}C)}^{-1}C\in H(n^k)$ is also invertible. As

in view of (3.3), (2.7), and Lemma 2.3 we find that

is invertible. Then combining with (2.7), (2.13), and Lemma 2.3, it follows that

where $C(\alpha (k))={\sum }_{t=1}^k(({\prod }_{l\ne t}\circ A_l)\circ I)=N$, meanwhile

thus the inequality (3.4) follows by (3.3).

From Lemma 2.3 and the proof course as above, with a similar discussion as Theorem 3.1, we see the condition for the equation in (3.4) is determined by (3.5). □

From above, the case discussed here is without ‘positive definiteness’, which is different from [1–10], and in form, the inequalities (3.1) and (3.4) are the reverses to each other; however, Theorems 3.1 and 3.3, and Example 3.2 indicate that their constraints are different, so (3.1) and (3.4) are not determined by each other any longer.

When $k=2$, we could obtain [[8], Corollaries 2 and 3] from Theorems 3.1 and 3.3 immediately.

Corollary 3.4 Let $A\in H(n)$ be invertible, and $\alpha (k)$ be as in (2.7) and (2.8),

1. (i)

   if C is invertible and $(C^{-1}({\prod }_{l=1}^k\otimes A)C^{-1})({\alpha }^{\prime }(k))>0$, then $A^{-1}\circ ({\prod }_{l=1}^{k-1}\circ A)+(k-1){(A\circ I)}^{k-2}$ is also invertible and the inequality (1.5) holds. Meanwhile, we have the equation in (1.5) if and only if

   $$\begin{array}{c}k\left(C^{-1}(\prod _{l=1}^k\otimes A)C^{-1}\right)({\alpha }^{\prime }(k),\alpha (k)){(A\circ I)}^{k-1}\hfill \\ +\left(C^{-1}(\prod _{l=1}^k\otimes A)C^{-1}\right)({\alpha }^{\prime }(k))C({\alpha }^{\prime }(k),\alpha (k))=0;\hfill \end{array}$$

   (3.6)
2. (ii)

   if $({\prod }_{l=1}^k\otimes A^{-1})({\alpha }^{\prime }(k))>0$, then ${\prod }_{l=1}^k\circ A\in H(n)$ is invertible and the inequality (2.17) holds. Meanwhile, the equation in (2.17) holds if and only if

   $$\begin{array}{c}k(\prod _{l=1}^k\otimes A^{-1})({\alpha }^{\prime }(k),\alpha (k)){(A\circ I)}^{k-1}\hfill \\ +(\prod _{l=1}^k\otimes A^{-1})({\alpha }^{\prime }(k))C({\alpha }^{\prime }(k),\alpha (k))=0.\hfill \end{array}$$

   (3.7)