Strong convergence theorems for the general split variational inclusion problem in Hilbert spaces

The purpose of this paper is to introduce and study a general split variational inclusion problem in the setting of infinite-dimensional Hilbert spaces. Under suitable conditions, we prove that the sequence generated by the proposed new algorithm converges strongly to a solution of the general split variational inclusion problem. As a particular case, we consider the algorithms for a split feasibility problem and a split optimization problem and give some strong convergence theorems for these problems in Hilbert spaces.

Let C and Q be nonempty closed convex subsets of real Hilbert spaces $H_1$ and $H_2$, respectively. The split feasibility problem $(SFP)$ is formulated as

where $A:H_1\to H_2$ is a bounded linear operator. In 1994, Censor and Elfving [1] first introduced the $SFP$ in finite-dimensional Hilbert spaces for modeling inverse problems which arise from phase retrievals and in medical image reconstruction [2]. It has been found that the $SFP$ can also be used in various disciplines such as image restoration, computer tomography and radiation therapy treatment planning [3–5]. The $SFP$ in an infinite-dimensional real Hilbert space can be found in [2, 4, 6–10]. For comprehensive literature, bibliography and a survey on SFP, we refer to [11].

Assuming that the $SFP$ is consistent, it is not hard to see that $x^{\ast }\in C$ solves $SFP$ if and only if it solves the fixed point equation

where $P_C$ and $P_Q$ are the metric projection from $H_1$ onto C and from $H_2$ onto Q, respectively, $\gamma >0$ is a positive constant, and $A^{\ast }$ is the adjoint of A.

A popular algorithm to be used to solves the $SFP$ (1.1) is due to Byrne’s CQ-algorithm [2]:

where ${\gamma }_k\in (0,2/\lambda )$ with λ being the spectral radius of the operator $A^{\ast }A$.

On the other hand, let H be a real Hilbert space, and B be a set-valued mapping with domain $D(B):=\{x\in H:B(x)\ne \mathrm{\varnothing }\}$. Recall that B is called monotone, if $〈u-v,x,x-y〉\ge 0$ for any $u\in Bx$ and $v\in By$; B is maximal monotone, if its graph $\{(x,y):x\in D(B),y\in Bx\}$ is not properly contained in the graph of any other monotone mapping. An important problem for set-valued monotone mappings is to find $x^{\ast }\in H$ such that $0\in B(x^{\ast })$. Here, $x^{\ast }$ is called a zero point of B. A well-known method for approximating a zero point of a maximal monotone mapping defined in a real Hilbert space H is the proximal point algorithm first introduced by Martinet [12] and generated by Rockafellar [13]. This is an iterative procedure, which generates $\{x_n\}$ by $x_1=x\in H$ and

where $\{{\beta }_n\}\subset (0,\mathrm{\infty })$, B is a maximal monotone mapping in a real Hilbert space, and $J_r^B$ is the resolvent mapping of B defined by $J_r^B={(I+rB)}^{-1}$ for each $r>0$. Rockafellar [13] proved that if the solution set $B^{-1}(0)$ is nonempty and ${lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}{\beta }_n>0$, then the sequence $\{x_n\}$ in (1.2) converges weakly to an element of $B^{-1}(0)$. In particular, if B is the sub-differential ∂f of a proper convex and lower semicontinuous function $f:H\to \mathbb{R}$, then (1.2) is reduced to

In this case, $\{x_n\}$ converges weakly to a minimizer of f. Later, many researchers have studied the convergence problems of the proximal point algorithm in Hilbert spaces (see [14–21] and the references therein).

Motivated by the works in [14–17] and related literature, the purpose of this paper is to introduce and consider the following general split variational inclusion problem.

Let $H_1$ and $H_2$ be two real Hilbert spaces, $B_i:H_1\to H_1$ and $K_i:H_2\to H_2$, $i=1,2,\dots$ be two families of set-valued maximal monotone mappings, $A:H_1\to H_2$ be a linear and bounded operator, and $A^{\ast }$ be the adjoint of A. The so-called general split variational inclusion problem is

The following examples are special cases of (GSVIP) (1.4).

Classical split variational inclusion problem. Let $B:H_1\to H_1$ and $K:H_2\to H_2$ be set-valued maximal monotone mappings. The so-called classical split variational inclusion problem (CSVIP) is

which was introduced by Moudafi [17]. It is obvious that problem (1.5) is a special case of (GSVIP) (1.4). In [17], Moudafi proved that the iteration process

converges weakly to a solution of problem (1.5), where λ and γ are given positive numbers.

Split optimization problem. Let $f:H_1\to \mathbb{R}$, $g:H_2\to \mathbb{R}$ be two proper convex and lower semicontinuous functions. The so-called split optimization problem (SOP) is

Denote by $B=\partial (f)$ and $K=\partial (g)$, then B and K both are maximal monotone mappings, and problem (1.6) is equivalent to the following classical split variational inclusion problem, i.e.:

Split feasibility problem. As in (1.1), let C and Q be two nonempty closed convex subsets of real Hilbert spaces $H_1$ and $H_2$, respectively and A be the same as above. The split feasibility problem is

It is well known that this kind of problems was first introduced by Censor and Elfving [1] for modeling inverse problems arising from phase retrievals and in medical image reconstruction [2]. Also it can be used in various disciplines such as image restoration, computer tomography and radiation therapy treatment planning.

Let $i_C$ ($i_Q$) be the indicator function of C (Q), i.e.,

Then $i_C$ and $i_Q$ both are proper convex and lower semicontinuous functions, and its subdifferentials $\partial i_C$ and $\partial i_Q$ are maximal monotone operators. Consequently problem (1.8) is equivalent to the following ‘split optimization problem’ and ‘Moudafi’s classical split variational inclusion problem’, i.e.,

For solving (GSVIP) (1.4), in our paper we propose the following iterative algorithms:

where $f:H_1\to H_1$ is a contraction mapping with a contractive constant $k\in (0,1)$, $\{{\alpha }_n\}$, $\{{\xi }_n\}$ and $\{{\gamma }_{n,i}\}$ are sequence in $[0,1]$ satisfying some conditions. Under suitable conditions, some strong convergence theorems for the sequence proposed by (1.11) to a solution for (GSVIP) (1.4) in Hilbert spaces are proved. As a particular case, we consider the algorithms for a split feasibility problem and a split optimization problem and give some strong convergence theorems for these problems in Hilbert spaces. Our results extend and improve the related results of Censor and Elfving [1], Byrne [2], Censor et al. [3–5], Rockafellar [13], Moudafi [14, 17], Eslamian and Latif [15], Eslamian [21], and Chuang [22].

Throughout the paper, we denote by H a real Hilbert space, C be a nonempty closed and convex subset of H. $F(T)$ denote by the set of fixed points of a mapping T. Let $\{x_n\}$ be a sequence in H and $x\in H$. Strong convergence of $\{x_n\}$ to x is denoted by $x_n\to x$, and weak convergence of $\{x_n\}$ to x is denoted by $x_n\rightharpoonup x$. For every point $x\in H$, there exists a unique nearest point in C, denoted by $P_{C}x$. This point satisfies.

The operator $P_C$ is called the metric projection. The metric projection $P_C$ is characterized by the fact that $P_{C}x\in C$ and

Recall that a mapping $T:C\to H$ is said to be nonexpansive, if $\parallel Tx-Ty\parallel \le \parallel x-y\parallel$ for every $x,y\in C$. T is said to be quasi-nonexpansive, if $F(T)\ne \mathrm{\varnothing }$ and $\parallel Tx-p\parallel \le \parallel x-p\parallel$ for every $x\in C$ and $p\in F(T)$. It is easy to see that $F(T)$ is a closed convex subset of C if T is a quasi-nonexpansive mapping. Besides, T is said to be a firmly nonexpansive, if

Lemma 2.1 (demi-closed principle)

Let C be a nonempty closed convex subset of a real Hilbert space H. Let $T:C\to H$ be a nonexpansive mapping, and let $\{x_n\}$ be a sequence in C. If $x_n\rightharpoonup w$ and ${lim}_{n\to \mathrm{\infty }}\parallel x_n-T{x}_n\parallel =0$, then $Tw=w$.

Lemma 2.2 [23]

Let H be a (real) Hilbert space. Then for all $x,y\in H$,

Lemma 2.3 [24]

Let H be a Hilbert space and let $\{x_n\}$ be a sequence in H. Then, for any given sequence $\{{\lambda }_n\}\subset (0,1)$ with ${\sum }_{n=1}^{\mathrm{\infty }}{\lambda }_n=1$ and for any positive integers i, j with $i<j$,

Lemma 2.4 Let $\{a_n\}$ be a sequence of nonnegative real numbers, $\{b_n\}$ be a sequence of real numbers in $(0,1)$ with ${\sum }_{n=1}^{\mathrm{\infty }}{b}_n=\mathrm{\infty }$, $\{u_n\}$ be a sequence of nonnegative real numbers with ${\sum }_{n=1}^{\mathrm{\infty }}{u}_n<\mathrm{\infty }$, $\{t_n\}$ be a real numbers with ${lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}{t}_n\le 0$. If

then ${lim}_{n\to \mathrm{\infty }}{a}_n=0$.

Lemma 2.5 [25]

Let $\{a_n\}$ be a sequence of real numbers such that there exists a subsequence $\{n_i\}$ of $\{n\}$ such that $a_{n_i}<a_{n_i+1}$ for all $i\in \mathbb{N}$. Then there exists a nondecreasing sequence $\{m_k\}\subset \mathbb{N}$ such that $m_k\to \mathrm{\infty }$, $a_{m_k}\le a_{m_k+1}$ and $a_k\le a_{m_k+1}$ are satisfied by all (sufficiently large) numbers $k\in \mathbb{N}$. In fact, $m_k=max\{j\le k:a_j<a_{j+1}\}$.

Lemma 2.6 [22]

Let H be a real Hilbert space, $B:H\to 2^H$ be a set-valued maximal monotone mapping, $\beta >0$, and let $J_{\beta }^B$ be the resolvent mapping of B.

1. (i)

   For each $\beta >0$, $J_{\beta }^B$ is a single-valued and firmly nonexpansive mapping;

2. (ii)

   $D(J_{\beta }^B)=H$ and $F(J_{\beta }^B)=B^{-1}(0):=\{x\in D(B):0\in Bx\}$;

3. (iii)

   $(I-J_{\beta }^B)$ is a firmly nonexpansive mapping for each $\beta >0$;

4. (iv)

   suppose that $B^{-1}(0)\ne \mathrm{\varnothing }$, then for each $x\in H$, each $x^{\ast }\in B^{-1}(0)$ and each $\beta >0$

   $${\parallel x-J_{\beta }^{B}x\parallel }^2+\parallel J_{\beta }^{B}x-x^{\ast }\parallel \le {\parallel x-x^{\ast }\parallel }^2;$$
5. (v)

   suppose that $B^{-1}(0)\ne \mathrm{\varnothing }$. Then $〈x-J_{\beta }^{B}x,J_{\beta }^{B}x-w〉\ge 0$ for each $x\in H$ and each $w\in B^{-1}(0)$, and each $\beta >0$.

Lemma 2.7 Let $H_1$, $H_2$ be two real Hilbert spaces, $A:H_1\to H_2$ be a linear bounded operator and $A^{\ast }$ be the adjoint of A. Let $B:H_2\to 2_2^H$ be a set-valued maximal monotone mapping, $\beta >0$, and let $J_{\beta }^B$ be the resolvent mapping of B, then

1. (i)

   ${\parallel (I-J_{\beta }^B)Ax-(I-J_{\beta }^B)Ay\parallel }^2\le 〈(I-J_{\beta }^B)Ax-(I-J_{\beta }^B)Ay,Ax-Ay〉$;

2. (ii)

   ${\parallel A^{\ast }(I-J_{\beta }^B)Ax-A^{\ast }(I-J_{\beta }^B)Ay\parallel }^2\le {\parallel A\parallel }^2〈(I-J_{\beta }^B)Ax-(I-J_{\beta }^B)Ay,Ax-Ay〉$;

3. (iii)

   if $\rho \in (0,\frac{2}{{\parallel A\parallel }^2})$, then $(I-\rho A^{\ast }(I-J_{\beta }^B)A)$ is a nonexpansive mapping.

Proof By Lemma 2.6(iii), the mapping $(I-J_{\beta }^B)$ is firmly nonexpansive, hence the conclusions (i) and (ii) are obvious.

Now we prove the conclusion (iii).

In fact, for any $x,y\in H_1$, it follows from the conclusions (i) and (ii) that

This completes the proof of Lemma 2.7. □

The following lemma will be used in proving our main results.

Lemma 3.1 Let $H_1$ and $H_2$ be two real Hilbert spaces, $A:H_1\to H_2$ be a linear and bounded operator, and $A^{\ast }$ be the adjoint of A. Let $B_i:H_1\to 2^{H_1}$, and $K_i:H_2\to 2^{H_2}$, $i=1,2,\dots$ , be two families of set-valued maximal monotone mappings, and let $\beta >0$ and $\gamma >0$. If $\mathrm{\Omega }\ne \mathrm{\varnothing }$ (the solution set of (GSVIP) (1.4)), then $x^{\ast }\in H_1$ is a solution of (GSVIP) (1.4) if and only if for each $i\ge 1$, for each $\gamma >0$ and for each $\beta >0$

Proof Indeed, if $x^{\ast }$ is a solution of (GSVIP) (1.4), then for each $i\ge 1$, $\gamma >0$ and $\beta >0$,

This implies that $x^{\ast }=J_{\beta }^{B_i}(x^{\ast }-\gamma A{x}^{\ast }(I-J_{\beta }^{K_i})A{x}^{\ast })$.

Conversely, if $x^{\ast }$ solves (3.1), by Lemma 2.6(v), we have

Hence we have

On the other hand, by Lemma 2.6(v) again

Adding up (3.2) and (3.3), we have

Simplifying it, we have

By the assumption that $\mathrm{\Omega }\ne \mathrm{\varnothing }$. Taking $w\in \mathrm{\Omega }$, hence for each $i\ge 1$ $w\in B_i^{-1}(0)$ and $Aw\in K_i^{-1}(0)$. In (3.4), taking $y=w$ and $v=Aw$, then we have

This implies that $A{x}^{\ast }=J_{\beta }^{K_i}A{x}^{\ast }$, and so $A{x}^{\ast }\in K_i^{-1}(0)$ for each $i\ge 1$. Hence from (3.1), $x^{\ast }=J_{\beta }^{B_i}{x}^{\ast }$, i.e., $x^{\ast }\in B_i^{-1}(0)$. Hence $x^{\ast }$ is a solution of (GSVIP)(1.4).

This completes the proof of Lemma 3.1. □

We are now in a position to prove the following main result.

Theorem 3.2 Let $H_1$, $H_2$, A, $A^{\ast }$, $\{B_i\}$, $\{K_i\}$, Ω be the same as in Lemma  3.1. Let $f:H_1\to H_1$ be a contractive mapping with contractive constant $k\in (0,1)$. Let $\{{\alpha }_n\}$, $\{{\xi }_n\}$, $\{{\gamma }_{n,i}\}$ be the sequences in $(0,1)$ with ${\alpha }_n+{\xi }_n+{\sum }_{i=1}^{\mathrm{\infty }}{\gamma }_{n,i}=1$, for each $n\ge 0$. Let $\{{\beta }_i\}$ be a sequence in $(0,\mathrm{\infty })$, and $\{{\lambda }_{n,i}\}$ be a sequence in $(0,\frac{2}{{\parallel A\parallel }^2})$. Let $\{x_n\}$ be the sequence defined by (1.11). If $\mathrm{\Omega }\ne \mathrm{\varnothing }$ and the following conditions are satisfied:

1. (i)

   ${lim}_{n\to \mathrm{\infty }}{\xi }_n=0$, and ${\sum }_{n=0}^{\mathrm{\infty }}{\xi }_n=\mathrm{\infty }$;

2. (ii)

   ${lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}{\alpha }_n{\gamma }_{n,i}>0$ for each $i\ge 1$;

3. (iii)

   $0<{lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}{\lambda }_{n,i}\le {lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}{\lambda }_{n,i}<\frac{2}{{\parallel A\parallel }^2}$,

then $x_n\to x^{\ast }\in \mathrm{\Omega }$ where $x^{\ast }=P_{\mathrm{\Omega }}f(x^{\ast })$, where $P_{\mathrm{\Omega }}$ is the metric projection from $H_1$ onto Ω.

Proof (I) First we prove that $\{x_n\}$ is bounded.

In fact, letting $z\in \mathrm{\Omega }$, by Lemma 3.1, for each $i\ge 1$,

Hence it follows from Lemma 2.7(iii) that for each $i\ge 1$ and each $n\ge 1$ we have

By induction, we can prove that

This implies that $\{x_n\}$ is bounded, so is $\{f(x_n)\}$.

(II) Now we prove that for each $j\ge 1$

Indeed, it follows from Lemma 2.3 that for any positive $j\ge 1$

Simplifying it, (3.6) is proved.

By the assumption that $\mathrm{\Omega }\ne \mathrm{\varnothing }$, and it is easy to prove that Ω is closed and convex. This implies that $P_{\mathrm{\Omega }}$ is well defined. Again since $P_{\mathrm{\Omega }}f:H_1\to \mathrm{\Omega }$ is a contraction mapping with contractive constant $k\in (0,1)$, there exists a unique $x^{\ast }\in \mathrm{\Omega }$ such that $x^{\ast }=P_{\mathrm{\Omega }}f{x}^{\ast }$. Since $x^{\ast }\in \mathrm{\Omega }$, it solves (GSVIP) (1.4). By Lemma 3.1,

1. (III)

   Now we prove that $x_n\to x^{\ast }$.

In order to prove that $x_n\to x^{\ast }$ (as $n\to \mathrm{\infty }$), we consider two cases.

Case 1. Assume that $\{\parallel x_n-x^{\ast }\parallel \}$ is a monotone sequence. In other words, for $n_0$ large enough, ${\{\parallel x_n-x^{\ast }\parallel \}}_{n\ge n_0}$ is either nondecreasing or non-increasing. Since $\{\parallel x_n-x^{\ast }\parallel \}$ is bounded, $\{\parallel x_n-x^{\ast }\parallel \}$ is convergence. Again since ${lim}_{n\to \mathrm{\infty }}{\xi }_n=0$, and $\{f(x_n)\}$ is bounded, from (3.6) we get

By condition (ii), we obtain

Now we prove that

To show this inequality, we choose a subsequence $\{x_{n_k}\}$ of $\{x_n\}$ such that $x_{n_k}\rightharpoonup w$, ${\lambda }_{n_k,i}\to {\lambda }_i\in (0,\frac{2}{{\parallel A\parallel }^2})$ for each $i\ge 1$, and

It follows from (3.8) that

For each $i\ge 1$, $J_{{\beta }_i}^{B_i}[I-{\lambda }_i{A}^{\ast }(I-J_{{\beta }_i}^{K_i})A]$ is a nonexpansive mapping. Thus from Lemma 2.1, $w=J_{{\beta }_i}^{B_i}[I-{\lambda }_i{A}^{\ast }(I-J_{{\beta }_i}^{K_i})A]w$. By Lemma 3.1 $w\in \mathrm{\Omega }$, i.e., w is a solution of (GSVIP) (1.4). Consequently we have

1. (IV)

   Finally, we prove that $x_n\to P_{\mathrm{\Omega }}f(x^{\ast })$.

In fact, from Lemma 2.2 we have

Simplifying it, we have

where ${\delta }_n=\frac{{\xi }_{n}M}{2(1-k)}+\frac{1}{1-k}〈f(x^{\ast })-x^{\ast },x_{n+1}-x^{\ast }〉$, $M={sup}_{n\ge 0}{\parallel x_n-x^{\ast }\parallel }^2$, and ${\eta }_n=\frac{2(1-k){\xi }_n}{1-{\xi }_{n}k}$. It is easy to see that ${\eta }_n\to 0$, ${\sum }_{n=1}^{\mathrm{\infty }}{\eta }_n=\mathrm{\infty }$, and ${lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}{\delta }_n\le 0$. Hence by Lemma 2.4, the sequence $\{x_n\}$ converges strongly to $x^{\ast }=P_{\mathrm{\Omega }}f(x^{\ast })$.

Case 2. Assume that $\{\parallel x_n-x^{\ast }\parallel \}$ is not a monotone sequence. Then, by Lemma 2.3, we can define a sequence of positive integers: $\{\tau (n)\}$, $n\ge n_0$ (where $n_0$ large enough) by

Clearly $\{\tau (n)\}$ is a nondecreasing sequence such that $\tau (n)\to \mathrm{\infty }$ as $n\to \mathrm{\infty }$, and for all $n\ge n_0$

Therefore $\{\parallel x_{\tau (n)}-x^{\ast }\parallel \}$ is a nondecreasing sequence. According to Case (1), ${lim}_{n\to \mathrm{\infty }}\parallel x_{\tau (n)}-x^{\ast }\parallel =0$ and ${lim}_{n\to \mathrm{\infty }}\parallel x_{\tau (n)+1}-x^{\ast }\parallel =0$. Hence we have

This implies that $x_n\to x^{\ast }$ and $x^{\ast }=P_{\mathrm{\Omega }}f(x^{\ast })$ is a solution of (GSVIP) (1.4).

This completes the proof of Theorem 3.2. □

In Theorem 3.2, if $B_i=B$ and $K_i=K$, for each $i\ge 1$, where $B:H_1\to 2^{H_1}$ and $K:H_2\to 2^{H_2}$ are two set-valued maximal monotone mappings, then from Theorem 3.2 we have the following.

Theorem 3.3 Let $H_1$, $H_2$, A, $A^{\ast }$, B, K, Ω, f be the same as in Theorem  3.2. Let $\{{\alpha }_n\}$, $\{{\xi }_n\}$, $\{{\gamma }_n\}$ be the sequence in $(0,1)$ with ${\alpha }_n+{\xi }_n+{\gamma }_n=1$ for each $n\ge 0$. Let $\beta >0$ be any given positive number, and $\{{\lambda }_n\}$ be a sequence in $(0,\frac{2}{{\parallel A\parallel }^2})$. Let $\{x_n\}$ be the sequence defined by

If $\mathrm{\Omega }\ne \mathrm{\varnothing }$ and the following conditions are satisfied:

1. (i)

   ${lim}_{n\to \mathrm{\infty }}{\xi }_n=0$, and ${\sum }_{n=0}^{\mathrm{\infty }}{\xi }_n=\mathrm{\infty }$;

2. (ii)

   ${lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}{\alpha }_n{\gamma }_n>0$;

3. (iii)

   $0<{lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}{\lambda }_n\le {lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}{\lambda }_n<\frac{2}{{\parallel A\parallel }^2}$,

then $x_n\to x^{\ast }\in \mathrm{\Omega }$ where $x^{\ast }=P_{\mathrm{\Omega }}f(x^{\ast })$.

In this section we shall utilize the results presented in Theorem 3.2 and Theorem 3.3 to study some problems.

4.1 Application to split optimization problem

Let $H_1$ and $H_2$ be two real Hilbert spaces. Let $h:H_1\to \mathbb{R}$ and $g:H_2\to \mathbb{R}$ be two proper, convex and lower semicontinuous functions, and $A:H_1\to H_2$ be a linear and bounded operators. The so-called split optimization problem (SOP) is

Denote by $\partial h=B$ and $\partial g=K$. It is know that $B:H_1\to 2^{H_1}$ (resp. $K:H_2\to 2^{H_2}$) is a maximal monotone mapping, so we can define the resolvent $J_{\beta }^B={(I+\beta B)}^{-1}$ and $J_{\beta }^K={(I+\beta K)}^{-1}$, where $\beta >0$. Since $x^{\ast }$ and $A{x}^{\ast }$ is a minimum of h on $H_1$ and g on $H_2$, respectively, for any given $\beta >0$, we have

This implies that the (SOP) (4.1) is equivalent to the split variational inclusion problem (SVIP) (4.2). From Theorem 3.3 we have the following.

Theorem 4.1 Let $H_1$, $H_2$, A, B, K, h, g be the same as above. Let f, $\{{\alpha }_n\}$, $\{{\xi }_n\}$, $\{{\gamma }_n\}$ be the same as in Theorem  3.3. Let $\beta >0$ be any given positive number, and $\{{\lambda }_n\}$ be a sequence in $(0,\frac{2}{{\parallel A\parallel }^2})$. Let $\{x_n\}$ be a sequence generated by $x_0\in H_1$

If ${\mathrm{\Omega }}_1\ne \mathrm{\varnothing }$, the solution set of the split optimization problem (4.1), and the following conditions are satisfied: