Let $H^n$ denote the set of $n\times n$ Hermitian matrices, $K^n$ denote the set of $n\times n$ Hermitian positive semidefinite matrices, and $P^n$ denote the set of $n\times n$ Hermitian positive definite matrices. The notation $\parallel A\parallel$ represents the Frobenius norm of matrix A. For the matrices B and C, $B\ge C$ means $B-C\in K^n$, $B>C$ means $B-C\in P^n$, $X\in [B,C]$ means $B\le X\le C$. ${\lambda }_1\left(B\right)$, and ${\lambda }_n\left(B\right)$ indicate the maximum and minimum eigenvalues of the $n\times n$ Hermitian matrix respectively, and I indicates the $n\times n$ identity matrix.

Definition 2.1

[18] Let $A,B\in P^n$, the Thompson distance between the Hermitian positive definite matrices A and B is defined as follows: $d(A,B)=max\{logM(A/B),logM(B/A)\},$ where $M(A/B)=inf\{\delta >0:A\le \delta B\}={\lambda }_1\left(B^{-\frac{1}{2}}A{B}^{-\frac{1}{2}}\right).$

A space with a defined Thompson distance is a called Thompson metric space. For a Thompson metric space, the following Lemma 2.1, Lemma 2.2, and Lemma 2.3 hold.

Lemma 2.1

[19, 20] For any nonsingular matricesW, the following equalities and inequalities hold: $\begin{array}{c}d(X,Y)=d(X^{-1},Y^{-1})=d(W^{\ast }XW,W^{\ast }YW),\mathrm{\forall }X,Y\in P^n,\hfill \\ d(W^{\ast }{X}^{r}W,W^{\ast }{Y}^{r}W)\le |r|d(X,Y),r\in [-1,1].\hfill \end{array}$

Lemma 2.2

[19, 20] For any$A,B,C,D\in P^n$, the following equalities hold: $d(A+B,C+D)\le max\{d(A,C),d(B,D)\}.$

Lemma 2.3

[19, 20] For any$A\in K^n$, $X,Y\in P^n$, the following inequality holds$d(A+X,A+Y)\le \frac{\alpha }{\alpha +\beta }d(X,Y),$where$\alpha =max\{{\lambda }_1\left(X\right),{\lambda }_1\left(Y\right)\}$, $\beta ={\lambda }_n\left(A\right)$.

In addition, the following Lemma 2.4 can be obtained by direct calculation according to the Thompson metric space definition.

Lemma 2.4

For the constant$\alpha \ne 0$, $A,B\in P^n$, we have$d(\alpha A,\alpha B)=d(A,B)$.

Lemma 2.5

[21] If$0<X\le Y$, then$0<X^a\le Y^a$for any$a\in (0,1]$, $X,Y\in P^n$. Similarly, if$0<X\le Y$, then$0<Y^a\le X^a$for any$a\in [-1,0)$, $X,Y\in P^n$.

Lemma 2.6

Assume thatXis a positive definite solution of the nonlinear matrix equation (1), then the following inequality holds: $A^{1/p}<X<{(A+\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{A}_i)}^{1/p}.$

Proof

Since X is a positive definite solution of the nonlinear matrix equation (1), that is $X={(A+\sum _{i=1}^m{M}_i^{\ast }{(B+X^{-1})}^{-1}{M}_i)}^{1/p}.$ Hence, $X>A^{1/p}$. Furthermore, we have by Lemma 2.5 that $X^{-1}<A^{-1/p},{(B+A^{-1/p})}^{-1}<{(B+X^{-1})}^{-1}<B^{-1}.$ Hence, we have $X={(A+\sum _{i=1}^m{M}_i^{\ast }{(B+X^{-1})}^{-1}{M}_i)}^{1/p}<{(A+\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)}^{1/p}.$ Hence, the result holds. □

Lemma 2.7

Assume thatXis a positive definite solution of the nonlinear matrix equation (1), then the inequality$d(M^{\ast }{(B+X^{-1})}^{-1}M,M^{\ast }{(B+Y^{-1})}^{-1}M)\le \frac{{\lambda }_1(A^{-1/p})}{{\lambda }_1(A^{-1/p})+{\lambda }_n(B)}d(X,Y)$holds for any nonsingular matrixAand any positive definite matrixB.

Proof

It is known from Lemma 2.1, Lemma 2.3, Lemma 2.5, and Lemma 2.6 that $\begin{array}{rcl}d(M^{\ast }{(B+X^{-1})}^{-1}M,M^{\ast }{(B+Y^{-1})}^{-1}M)& =& d({(B+X^{-1})}^{-1},{(B+Y^{-1})}^{-1})\\ & =& d(B+X^{-1},B+Y^{-1})\\ & \le & \frac{{\lambda }_1(A^{-1/p})}{{\lambda }_1(A^{-1/p})+{\lambda }_n(B)}d(X^{-1},Y^{-1})\\ & =& \frac{{\lambda }_1(A^{-1/p})}{{\lambda }_1(A^{-1/p})+{\lambda }_n(B)}d(X,Y).\end{array}$ Hence, the result holds. □

Let

4

Lemma 2.8

The matrix function$G\left(X\right)$satisfies the Lipschitz condition on Ω, that is, for any$X,Y\in \mathrm{\Omega }$, we have$d(G(X),G(Y))<Ld(X,Y),$where

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Proof

It is known from Lemma 2.1, Lemma 2.2, Lemma 2.3, and Lemma 2.7 that $\begin{array}{rl}& d(G(X),G(Y))\\ & =d({(A+\sum _{i=1}^m{M}_i^{\ast }{(B+X^{-1})}^{-1}{M}_i)}^{1/p},{(A+\sum _{i=1}^m{M}_i^{\ast }{(B+Y^{-1})}^{-1}{M}_i)}^{1/p})\\ & \le \frac{1}{p}d(A+\sum _{i=1}^m{M}_i^{\ast }{(B+X^{-1})}^{-1}{M}_i,A+\sum _{i=1}^m{M}_i^{\ast }{(B+Y^{-1})}^{-1}{M}_i)\\ & \le \frac{1}{p}.\frac{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)}{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)+{\lambda }_n(A)}d(\sum _{i=1}^m{M}_i^{\ast }{(B+X^{-1})}^{-1}{M}_i,\sum _{i=1}^m{M}_i^{\ast }{(B+Y^{-1})}^{-1}{M}_i)\\ & \le \frac{1}{p}.\frac{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)}{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)+{\lambda }_n(A)}max\{d(M_1^{\ast }{(B+X^{-1})}^{-1}{M}_1,M_1^{\ast }{(B+Y^{-1})}^{-1}{M}_1),\\ & d(\sum _{i=2}^m.M_i^{\ast }{(B+X^{-1})}^{-1}{M}_i,\sum _{i=2}^m{M}_i^{\ast }{(B+Y^{-1})}^{-1}{M}_i)\}\\ & \le \frac{1}{p}.\frac{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)}{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)+{\lambda }_n(A)}max\{d(M_1^{\ast }{(B+X^{-1})}^{-1}{M}_1,M_1^{\ast }{(B+Y^{-1})}^{-1}{M}_1),\\ & ...,d(M_m^{\ast }{(B+X^{-1})}^{-1}{M}_m,M_m^{\ast }{(B+Y^{-1})}^{-1}{M}_m)\}\\ & \le \frac{1}{p}.\frac{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)}{{\lambda }_1(\sum _{i=1}^m{M}_i^{\ast }{B}^{-1}{M}_i)+{\lambda }_n(A)}.\frac{{\lambda }_1(A^{-1/p})}{{\lambda }_1(A^{-1/p})+{\lambda }_n(B)}d(X,Y).\end{array}$ Hence, the result holds. □

Lemma 2.9

[22] Ifϕis a compression mapping on the distance space Ω and the compression coefficient$\alpha \in (0,1)$, then the mappingϕhas a unique fixed point on Ω.

According to Lemma 2.8 and Lemma 2.9, the following lemma can be immediately obtained.

Lemma 2.10

The nonlinear matrix equation (1) has a unique positive definite solution, and, furthermore, its unique positive definite solution$X^{\ast }$satisfies$X^{\ast }\in \mathrm{\Omega }$given as (4).

In this section we first propose a fixed-point accelerated iterative algorithm for solving the nonlinear matrix equation (1), and then, based on the basic characteristics of the Thompson distance, prove the convergence of the proposed algorithm and the error estimation formula of the iterative solution. Let $F\left(X\right)=G\left(X\right)-X$. we propose a fixed-point acceleration iterative algorithm to solve the nonlinear matrix equation (1), as in Algorithm 1.

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Algorithm 1

Fixed-point accelerated algorithm to solve (1)

Theorem 3.1

The nonlinear matrix equation (1) has a unique positive definite solution$X^{\ast }$in Ω given as (4), and for any initial matrix$X_0\in \mathrm{\Omega }$, the matrix sequence$\left\{X_k\right\}$generated by Algorithm 1 converges to the unique positive definite solution$X^{\ast }$. Furthermore, the error-estimation formula of the iteration solution with the true solution of the nonlinear equation (1) can be expressed as

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Proof

The result that the nonlinear matrix equation (1) has a unique positive definite solution $X^{\ast }$ in Ω given as (4) can be obtained directly by Lemma 2.10, and hence we do not prove it here. We prove the conclusion (6) by induction. For $1\le k\le m_k+1$, we have by Lemma 2.4 and Lemma 2.8 that $\begin{array}{rl}& d(X_1,X^{\ast })=d(G(X_0),G(X^{\ast }))\le Ld(X_0,X^{\ast }),\\ d(X_2,X^{\ast })& =d({\alpha }_0^{1}G(X_0)+{\alpha }_1^{1}G(X_1),{\alpha }_0^{1}G(X^{\ast })+{\alpha }_1^{1}G(X^{\ast }))\\ & \le max\{d({\alpha }_0^{1}G(X_0),{\alpha }_0^{1}G(X^{\ast })),d({\alpha }_1^{1}G(X_1),{\alpha }_1^{1}G(X^{\ast }))\}\\ & =max\{d(G(X_0),G(X^{\ast })),d(G(X_1),G(X^{\ast }))\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),d(X_1,X^{\ast })\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),Ld(X_0,X^{\ast })\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),d(X_0,X^{\ast })\}\\ & \le Ld(X_0,X^{\ast }),\\ d(X_3,X^{\ast })& =d({\alpha }_0^{2}G(X_0)+{\alpha }_1^{2}G(X_1)+{\alpha }_2^{2}G(X_2),{\alpha }_0^{2}G(X^{\ast })+{\alpha }_1^{2}G(X^{\ast })+{\alpha }_2^{2}G(X^{\ast }))\\ & \le max\{d({\alpha }_0^{2}G(X_0),{\alpha }_0^{2}G(X^{\ast })),d({\alpha }_1^{2}G(X_1)+{\alpha }_2^{2}G(X_2),\\ & {\alpha }_1^{2}G(X^{\ast })+{\alpha }_2^{2}G(X^{\ast }))\}\\ & \le max\{d(G(X_0),G(X^{\ast })),max\{d(G(X_1),G(X^{\ast })),d(G(X_2),G(X^{\ast }))\}\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),d(X_1,X^{\ast }),d(X_2,X^{\ast })\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),Ld(X_0,X^{\ast }),Ld(X_0,X^{\ast })\}\\ & \le Ld(X_0,X^{\ast }),\\ & .........................\\ d(X_{m_k+1},X^{\ast })& =d({\alpha }_0^{m_k}G(X_0)+{\alpha }_1^{m_k}G(X_1)+\cdots +{\alpha }_{m_k}^{m_k}G(X_{m_k}),\\ & {\alpha }_0^{m_k}G(X^{\ast })+{\alpha }_1^{m_k}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{m_k}G(X^{\ast }))\\ & \le max\{d(G(X_0),G(X^{\ast })),d({\alpha }_1^{m_k}G(X_1)+\cdots +{\alpha }_{m_k}^{m_k}G(X_{m_k}),\\ & {\alpha }_1^{m_k}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{m_k}G(X^{\ast }))\}\\ & \le max\{d(G(X_0),G(X^{\ast })),d(G(X_1),G(X^{\ast })),\dots ,d(G(X_{m_k}),G(X^{\ast }))\}\\ & \le max\{Ld(X_0,X^{\ast }),Ld(X_1,X^{\ast }),\dots ,Ld(X_{m_k},X^{\ast })\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),Ld(X_0,X^{\ast }),\dots ,Ld(X_0,X^{\ast })\}\\ & \le L\cdot max\{d(X_0,X^{\ast }),d(X_0,X^{\ast }),\dots ,d(X_0,X^{\ast })\}\\ & \le Ld(X_0,X^{\ast }),\\ d(X_{m_k+2},X^{\ast })& =d({\alpha }_0^{m_k+1}G(X_1)+{\alpha }_1^{m_k+1}G(X_2)+\cdots +{\alpha }_{m_k}^{m_k+1}G(X_{m_k+1}),\\ & {\alpha }_0^{m_k+1}G(X^{\ast })+{\alpha }_1^{m_k+1}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{m_k+1}G(X^{\ast }))\\ & \le max\{d(G(X_1),G(X^{\ast })),d({\alpha }_1^{m_k+1}G(X_2)+\cdots +{\alpha }_{m_k}^{m_k+1}G(X_{m_k+1}),\\ & {\alpha }_1^{m_k+1}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{m_k+1}G(X^{\ast }))\}\\ & \le max\{d(G(X_1),G(X^{\ast })),d(G(X_2),G(X^{\ast })),\dots ,d(G(X_{m_k}),G(X^{\ast }))\}\\ & \le max\{Ld(X_1,X^{\ast }),Ld(X_2,X^{\ast }),\dots ,Ld(X_{m_k},X^{\ast })\}\\ & \le L\cdot max\{Ld(X_0,X^{\ast }),Ld(X_0,X^{\ast }),\dots ,Ld(X_0,X^{\ast })\}\\ & \le L^2\cdot max\{d(X_0,X^{\ast }),d(X_0,X^{\ast }),\dots ,d(X_0,X^{\ast })\}\\ & \le L^{2}d(X_0,X^{\ast }).\end{array}$ Assume that the inequality $d(X_k,X^{\ast })\le L^{\lfloor \frac{k}{m_k+2}\rfloor +1}d(X_0,X^{\ast })=L^{l+1}d(X_0,X^{\ast })$ holds for $k=l(m_k+2)+q,l>1,0<q<m_k+2$. Then, we have again by Lemma 2.4 and Lemma 2.8 that, when $k=(l+1)(m_k+2)$, $\begin{array}{rl}d(X_k,X^{\ast })& =d({\alpha }_0^{k-1}G(X_{k-m_k-1})+\cdots +{\alpha }_{m_k}^{k-1}G(X_{k-1}),{\alpha }_0^{k-1}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{k-1}G(X^{\ast }))\\ & \le max\{d(G(X_{k-m_k-1}),G(X^{\ast })),d(G(X_{k-m_k}),G(X^{\ast })),\dots ,d(G(X_{k-1}),G(X^{\ast }))\}\\ & \le max\{Ld(X_{k-m_k-1},X^{\ast }),Ld(X_{k-m_k},X^{\ast }),\dots ,Ld(X_{k-1},X^{\ast })\}\\ & \le max\{L^{l+2}d(X_0,X^{\ast }),\dots ,L^{l+2}d(X_0,X^{\ast }),L^{l+2}d(X_0,X^{\ast })\}\\ & \le L^{l+2}d(X_0,X^{\ast })\end{array}$ and when $k=(l+1)(m_k+2)+q,0<q<m_k+2$, $\begin{array}{rl}d(X_k,X^{\ast })& =d({\alpha }_0^{k-1}G(X_{k-m_k+1})+\cdots +{\alpha }_{m_k}^{k-1}G(X_{k+1}),{\alpha }_0^{k-1}G(X^{\ast })+\cdots +{\alpha }_{m_k}^{k-1}G(X^{\ast }))\\ & \le max\{d(G(X_{k-m_k-1}),G(X^{\ast })),\dots ,d(G(X_{k-1}),G(X^{\ast }))\}\\ & \le max\{Ld(X_{k-m_k-1},X^{\ast }),\dots ,Ld(X_{k-1},X^{\ast })\}\\ & \le max\{\underset{m_k+1-q}{\underbrace{L^{l+2}d(X_0,X^{\ast }),\dots ,L^{l+2}d(X_0,X^{\ast })}},\underset{q}{\underbrace{L^{l+3}d(X_0,X^{\ast }),\dots ,L^{l+3}(X_0,X^{\ast })}}\}\\ & \le L^{l+2}d(X_0,X^{\ast }).\end{array}$ Hence, by the principle of induction, the inequality $d(X_k,X^{\ast })\le L^{\lfloor \frac{k}{m_k+2}\rfloor +1}d(X_0,X^{\ast })=L^{l+1}d(X_0,X^{\ast })$ holds for k.

Note that for the compression coefficient $L\in (0,1)$, we have $\underset{k\to \mathrm{\infty }}{lim}d(X_k,X^{\ast })=0.$ This means that the matrix sequence $\left\{X_k\right\}$ generated by Algorithm 1 converges to the unique positive definite solution $X^{\ast }$ of the nonlinear matrix equation (1), and the error estimation formula can be expressed as (6). □

Selection of the backtracking step $m_k$

Backtracking steps $m_k$ are closely related to the convergence speed of the algorithm 1. Consider the nonlinear matrix equation

7

It can be seen from Fig. 1 that the convergence speed of Algorithm 1 is directly affected by the backtracking step $m_k$. In general, when $m_k$ is chosen as 2 through 10, Algorithm 1 is relatively more efficient than other cases. However, how to select the best backtracking steps $m_k$ is an important problem that should be studied in future.

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Figure 1

Backtracking steps $m_k$ and calculation time curve with different matrix sizes

Comparison of convergence with existing algorithms

Competing interests

The authors declare that they have no competing interests.