Strong convergence theorems for a common point of solution of variational inequality, solutions of equilibrium and fixed point problems

Abstract

We introduce an iterative process which converges strongly to a common point of solution of variational inequality problem for continuous monotone mapping, solution of equilibrium problem and a common fixed point of finite family of asymptotically regular uniformly continuous relatively asymptotically nonexpansive mappings in Banach spaces. Our scheme does not involve computation of C_n+1from C _n for each n ≥ 1. Our theorems improve and unify most of the results that have been proved for this important class of nonlinear operators.

Mathematics Subject Classification (2000): 47H05, 47H09, 47H10, 47J05, 47J25

Introduction

Let E be a real Banach space with dual E*. A normalized duality mapping J: E → 2^E*is defined by

$$Jx:=\left\{f^{*}\in E^{*}:⟨x,f^{*}⟩=||x|{|}^2=||f^{*}||2\right\},$$

where 〈., .〉 denotes the generalized duality pairing. It is well known that E is smooth if and only if J is single-valued and if E is uniformly smooth then J is uniformly continuous on bounded subsets of E. Moreover, if E is a reflexive and strictly convex Banach space with a strictly convex dual, then J^-1 is single-valued, one-to-one, surjective, and it is the duality mapping from E* into E and thus JJ^-1 = I_E*and J^-1J = I _E (see [1]).

Throughout this article, we denote by ϕ: E × E → ℝ the function defined by

$$\varphi \left(y,x\right)=||y|{|}^2-2⟨y,Jx⟩+||x|{|}^2,\mathsf{\text{for}}x,y\in E,$$

(1.1)

which was studied by Alber [2], Kamimula and Takahashi [3], and Reich [4]. It is obvious from the definition of the function ϕ that

$${\left(||x||-||y||\right)}^2\le \varphi \left(x,y\right)\le {\left(||x||+||y||\right)}^2,\mathsf{\text{for}}x,y\in E.$$

(1.2)

where J is the normalized duality mapping. We remark that in a Hilbert space H, (1.1) reduces to ϕ(x, y) = ||x - y||², for any x, y ∈ H.

Let C be a nonempty closed and convex subset of a reflexive, strictly convex and smooth Banach space E. The generalized projection mapping, introduced by Alber [2], is a mapping Π_C: E → C that assigns to an arbitrary point x ∈ E the minimum point of the functional ϕ(y, x), i.e., ${\prod }_{C}x=\bar{x}$, where $\bar{x}$ is the solution to the minimization problem

$$\varphi \left(\bar{x},x\right)=\mathsf{\text{min}}\left\{\varphi \left(y,x\right),y\in C\right\}.$$

(1.3)

A mapping A: D(A) ⊂ E → E^∗ is said to be monotone if for each x, y ∈ D(A), the following inequality holds:

$$⟨x-y,Ax-Ay⟩\ge 0.$$

(1.4)

A is said to be γ-inverse strongly monotone if there exists positive real number γ such that

$$⟨x-y,Ax-Ay⟩\ge \gamma ||Ax-Ay|{|}^2,\mathsf{\text{for}}\mathsf{\text{all}}x,y\in D\left(A\right).$$

(1.5)

Suppose that A is monotone mapping from C ⊆ E into E*. The variational inequality problem is formulated as finding

$$\mathsf{\text{a}}\mathsf{\text{point }}u\in C\mathsf{\text{such}}\mathsf{\text{that}}⟨v-u,Au⟩\ge 0,\mathsf{\text{for}}\mathsf{\text{all}}v\in C.$$

(1.6)

The set of solutions of the variational inequality problem is denoted by VI(C, A).

Variational inequalities were initially studied by Stampacchia [5] and ever since have been widely studied. Such a problem is connected with the convex minimization problem, the complementarity problem, the problem of finding a point u ∈ C satisfying 0 ∈ Au. If E = H, a Hilbert space, one method of solving a point u ∈ VI(C, A) is the projection algorithm which starts with any point x₀ = x ∈ C and updates iteratively as x_n+1according to the formula

$$x_{n+1}=P_C\left(x_n-{\alpha }_{n}A{x}_n\right),\mathsf{\text{for}}\mathsf{\text{any}}n\ge 0,$$

(1.7)

where P _C is the metric projection from H onto C and {α _n } is a sequence of positive real numbers. In the case that A is γ-inverse strongly monotone, Iiduka, Takahashi and Toyoda [6] proved that the sequence {x _n } generated by (1.7) converges weakly to some element of VI(C, A).

When the space E is more general than a Hilbert spaces, Iduka and Takahashi [7] introduced the following iteration scheme for finding a solution of the variational inequality problem for an γ-inverse strongly monotone operator A in 2-uniformly convex and uniformly smooth spaces

$$x_{n+1}={\prod }_C{J}^{-1}\left(J{x}_n-{\alpha }_{n}A{x}_n\right),\mathsf{\text{for}}\mathsf{\text{any}}n\ge \mathsf{\text{0}},$$

(1.8)

where Π _C is the generalized projection from E onto C, J is the normalized duality mapping from E into E* and {α _n } is a sequence of positive real numbers. They proved that the sequence {x _n } generated by (1.8) converges weakly to some element of VI(C, A).

Our concern now is the following: Is it possible to construct a sequence {x _n } which converges strongly to some point of VI(C, A)?

In this connection, when E = H, a Hilbert space and A is γ-inverse strongly monotone, Iiduka, Takahashi and Toyoda [6] studied the following iterative scheme:

$$\left\{\begin{array}{c}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary,}}\hfill \\ y_n=P_C\left(x_n-{\alpha }_{n}A{x}_n\right),\hfill \\ C_n=\left\{z\in C:||y_n-z||\le ||x_n-z||\right\},\hfill \\ Q_n=\left\{z\in C:⟨x_n-z,x_0-x_n⟩\ge 0\right\},\hfill \\ x_{n+1}=P_{C_n\cap Q_n}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.9)

where {α _n } is a sequence in [0, 2γ]. They proved that the sequence {x _n } generated by (1.9) converges strongly to P_{VI(C, A)}(x₀), where P_{VI(C, A)}is the metric projection from H onto VI(C, A).

In the case that E is 2-uniformly convex and uniformly smooth Banach space, Iiduka and Takahashi [8] studied the following iterative scheme for a variational inequality problem for γ-inverse strongly monotone mapping A:

$$\left\{\begin{array}{c}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary}},\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left(J{x}_n-{\alpha }_{n}A{x}_n\right),\hfill \\ C_n=\left\{z\in E:\varphi \left(z,y_n\right)\le \varphi \left(z,x_n\right)\right\},\hfill \\ Q_n=\left\{z\in E:⟨x_n-z,J{x}_0-J{x}_n⟩\ge 0\right\},\hfill \\ x_{n+1}={\text{Π}}_{C_n\cap Q_n}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.10)

where ${\text{Π}}_{C_n\cap Q_n}$ is the generalized projection from E onto C _n ∩ Q _n , J is the duality mapping from E into E^∗ and {α _n } is a positive real sequence satisfying certain condition. Then, they proved that the sequence {x _n } converges strongly to an element of VI(C, A) provided that VI(C, A) ≠ ∅ and A satisfies ||A _y || ≤ ||A _y - A _u ||, for all y ∈ C, = and u ∈ VI(C, A).

Remark 1.1. We remark that the computation of x_n+1in their algorithms is not simple because of the involvement of computation of C_n+1from C _n and Q _n , for each n ≥ 0.

Let C be a nonempty, closed and convex subset of a real Banach space E with dual E*. Let T be a mapping from C into itself. An element p ∈ C is called a fixed point of T if T (p) = p. The set of fixed points of T is denoted by F(T). A point p in C is said to be an asymptotic fixed point of T (see [4]) if C contains a sequence {x _n } which converges weakly to p such that $\underset{n\to \infty }{\mathsf{\text{lim}}}||x_n-T{x}_n||=0$. The set of asymptotic fixed points of T will be denoted by $\stackrel{⌢}{F}\left(T\right)$. A mapping T from C into itself is said to be nonexpansive if ||Tx - Ty|| ≤ ||x - y||, for each x, y ∈ C, and is called relatively nonexpansive if (R1) F (T) ≠ ∅ (R2) ϕ(p, Tx) ≤ ϕ(p, x), for x ∈ C and (R3) $F\left(T\right)=\stackrel{⌢}{F}\left(T\right)$. T is called relatively quasi-nonxpansive if F(T) = ∅ and ϕ(p, T _x ) ≤ ϕ(p, x), for all x ∈ C, and p ∈ F(T).

A mapping T from C into itself is said to be asymptotically nonexpansive if there exists {k _n }⊂ [1, ∞) such that k _n → 1 and ||Tⁿx-Tⁿy|| ≤ k _n ||x - y||, for each x, y ∈ C, and is called relatively asymptotically nonexpansive if there exists {k _n } ⊂ [1, ∞) such that (N1) F (T) ≠ ∅ (N2) ϕ(p, Tⁿx) ≤ k _n ϕ(p, x), for x ∈ C, and (N3) $F\left(T\right)=\stackrel{⌢}{F}\left(T\right)$, where k _n → 1, as n → ∞. T is called relatively asymptotically quasinonxpansive if there exist {k _n } ⊂ [1, ∞) and F(T) = ∅ such that ϕ(p, Tⁿx) ≤ k _n ϕ(p, x), for x ∈ C, and p ∈ F(T), where k _n → 1, as n → ∞. A mapping T from C into itself is said to be ϕ-nonexpansive (nonextensive [9]) if ϕ(Tx, Ty) ≤ ϕ(x, y) for all x, y ∈ C and it is called ϕ-asymptotically nonexpansive if there exists {k _n } ⊂ [1, ∞) such that ϕ(Tⁿx, Tⁿy) ≤ k _n ϕ(x, y), for all x, y ∈ C, where k _n → 1, as →∞. A self-mapping on C is called asymptotically regular on C, if for any bounded subset $\bar{C}$ of C, there holds the following equality:

$$\underset{n\to \infty }{\mathsf{\text{lim }}\mathsf{\text{sup}}}\left\{||T^{n+1}x-T^{n}x||:x\in \bar{C}\right\}=0.$$

T is called closed if x _n → x and Tx _n → y, then Tx = y.

Clearly, the class of relatively asymptotically nonexpansive mappings contains the class of relatively nonexpansive mappings.

It is well known that, in an infinite-dimensional Hilbert space, the normal Mann's iterative [10] algorithm has only weak convergence, in general, even for nonexpansive mappings. Consequently, to obtain strong convergence, some modifications of the normal Mann's iteration algorithm has been introduced. The so-called hybrid projection iteration algorithm (HPIA) is one of such modifications, which was introduced by Haugazeau [11] in 1968. Since then, there has been a lot of activity in this area and several modifications appeared. For details, the readers are referred to papers [12–18] and the references therein.

In 2003, Nakajo and Takahashi [17] proposed the following modification of the Mann iteration method for a nonexpansive mapping T in a Hilbert space H:

$$\left\{\begin{array}{c}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary}},\hfill \\ y_n={\alpha }_n{x}_n+\left(1-{\alpha }_n\right)T{x}_n,\hfill \\ C_n=\left\{z\in C:||y_n-z||\le ||x_n-z||\right\},\hfill \\ Q_n=\left\{z\in C:⟨x_n-z,x_0-x_n⟩\ge 0\right\},\hfill \\ x_{n+1}={\text{Π}}_{C_n\cap Q_n}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.11)

where C is a closed convex subset of H, Π _C is the generalized metric projection from E onto C. They proved that if the sequence {α _n } is bounded above from one then the sequence {x _n } generated by (1.11) converges strongly to P_F(T)(x₀), where F(T) denote the fixed points set of T.

In spaces more general than Hilbert spaces, Matsushita and Takahashi [16] proposed the following hybrid iteration method with generalized projection for relatively nonexpansive mapping T in a Banach space E:

$$\left\{\begin{array}{c}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary,}}\hfill \\ y_n=J^{-1}\left({\alpha }_{n}J{x}_n+\left(1-{\alpha }_n\right)JT{x}_n\right),\hfill \\ C_n=\left\{z\in C:\varphi \left(z,y_n\right)<\varphi \left(z,x_n\right)\right\},\hfill \\ Q_n=\left\{z\in C:⟨x_n-z,J{x}_0-J{x}_n⟩\ge 0\right\},\hfill \\ x_{n+1}={\text{Π}}_{C_n\cap Q_n}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.12)

They proved the following convergence theorem.

Theorem MT. Let E be a uniformly convex and uniformly smooth Banach space, let C be a nonempty closed convex subset of E, let T be a relatively nonexpansive mapping from C into itself, and let {α _n } be a sequence of real numbers such that 0 ≤ α _n < 1 and lim sup _n α _n < 1. Suppose that {x _n } is given by (1.12), where J is the duality mapping on E. If F(T) is nonempty, then {x _n } converges strongly to Π_F(T)x₀, where Π_F(T)(.) is the generalized projection from E onto F(T).

Let f: C × C → ℝ be a bifunction, where ℝ is the set of real numbers. The equilibrium problem for f is

$$\mathsf{\text{finding}}{x}^{*}\in C\mathsf{\text{such}}\mathsf{\text{that}}f\left(x^{*},y\right)\ge 0,\forall y\in C.$$

(1.13)

The solution set of (1.13) is denoted by EP(f).

Numerous problems in physics, optimization and economics reduce to find a solution of (1.13) (see, e.g., [19, 20]). For studying the equilibrium problem (1.13), we assume that f satisfies the following conditions:

(A1) f(x, x) = 0, for all x ∈ C,

(A2) f is monotone, i.e., f(x, y)+ f(y, x) ≤ 0, for all x, y ∈ C,

(A3) for each x, y, z ∈ C, $\underset{t\to 0}{\mathsf{\text{lim}}}f\left(tz+\left(1-t\right)x,y\right)\le f\left(x,y\right)$,

(A4) for each x ∈ C, y → f(x, y) is convex and lower semicontinuous.

Recently, many authors have considered the problem of finding a common element of the fixed points set of relatively nonexpansive mapping, the solution set of equilibrium problem and solution set of variational inequality problem for γ-inverse monotone mapping (see, e.g., [21–26]). If E is uniformly convex and smooth Banach space, then Aoyama, Kohsaka and Takahashi [27] constructed a sequence which converges strongly to a common solution of variational inequality problems for two monotone mappings.

Recently, Qin et al. [22] proved the following result:

Theorem QCK. Let E be a uniformly convex and uniformly smooth Banach space and C be a nonempty closed and convex subset of E.

Let f: C × C → R be a bifunction satisfying (A1)-(A4) and let T, S: C → C be two closed relatively quasi- nonexpansive mappings such that F = F(T) ∩ F(S) ∩ EP(f) ≠ ∅. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{C}_1=C,\mathsf{\text{and}}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary,}}\hfill \\ y_n=J^{-1}\left({\alpha }_{n}J{x}_n+{\beta }_{n}JT{x}_n+{\gamma }_{n}JS{x}_n\right),\hfill \\ u_n\in C:f\left(u_n,y\right)+\frac{1}{r_n}⟨y-u_n,J{u}_n-J{y}_n⟩\ge 0,\forall y\in C,\hfill \\ C_{n+1}=\left\{z\in C_n:\varphi \left(z,u_n\right)\le \varphi \left(z,x_n\right)\right\},\hfill \\ x_{n+1}={\text{Π}}_{C_{n+1}}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.14)

where Π _C is the generalized metric projection from E onto C, J is the normalized duality mapping on E, {r _n } is a positive sequence and {α _n }, {β _n } and {γ _n } are sequences in 0[1] satisfying certain conditions. Then {x _n } converges strongly to Π_F(x₀).

Furthermore, Zegeye and Shahzad [28] studied the following iterative scheme for common point of solution of a variational inequality problem for γ-inverse strongly monotone mapping A and fixed point of a continuous ϕ-asymptotically nonexpansive mapping S in a 2-uniformly convex and uniformly smooth Banach space E

$$\left\{\begin{array}{c}\begin{array}{c}{C}_0=C,\mathsf{\text{and}}{x}_0\in C,\mathsf{\text{chosen}}\mathsf{\text{arbitrary,}}\\ z_n={\text{Π}}_C{J}^{-1}\left(J{x}_n-{\lambda }_{n}A{x}_n\right),\hfill \end{array}\hfill \\ y_n=J^{-1}\left({\alpha }_{n}J{x}_n+\left(1-{\alpha }_n\right)J{S}^n{z}_n\right),\hfill \\ u_n\in C:f\left(u_n,y\right)+\frac{1}{r_n}⟨y-u_n,J{u}_n-J{y}_n⟩\ge 0,\forall y\in C,\hfill \\ C_{n+1}=\left\{z\in C_n:\varphi \left(z,u_n\right)\le \varphi \left(z,x_n\right)+{\theta }_n\right\},\hfill \\ x_{n+1}={\text{Π}}_{C_{n+1}}\left(x_0\right),n\ge 0,\hfill \end{array}\right.$$

(1.15)

where C is closed, convex and bounded subset of E, ${\theta }_n=\left(1-{\alpha }_n\right)\left(k_n^2-1\right){\left(\mathsf{\text{diam}}\left(C\right)\right)}^2$ and {α _n }, {λ _n } are sequences satisfying certain condition. Then, they proved that the sequence {x _n } converges strongly to an element of F: = F(S) ∩ VI(C, A) provided that F ≠ Ø and A satisfies ||Ay|| ≤ ||Ay - Ap||, for all y ∈ C and p ∈ F. As it is mentioned in [29], we remark that the computation of x_n+1in Algorithms (1.11), (1.12), (1.14) and (1.15) is not simple because of the involvement of computation of C_n+1from C _n , for each n ≥ 0.

It is our purpose in this article to introduce an iterative scheme {x _n } which converges strongly to a common point of solution of variational inequality problem for continuous monotone mapping, solution of equilibrium problem and a common fixed point of finite family of asymptotically regular uniformly continuous relatively asymptotically nonexpansive mappings in Banach spaces. Our scheme does not involve computation of C_n+1from C _n for each n ≥1. Our theorems improve and unify most of the results that have been proved for this important class of nonlinear operators.

Preliminaries

In the sequel, we shall use of the following lemmas.

Lemma 2.1. [2]Let C be a nonempty closed and convex subset of a real reflexive, strictly convex, and smooth Banach space E and let x ∈ E. Then ∀y ∈ C,

$$\varphi \left(y,{\text{Π}}_{C}x\right)+\varphi ({\text{Π}}_{C}x,x)\le \varphi \left(y,x\right).$$

Lemma 2.2. [3]Let E be a real smooth and uniformly convex Banach space and let {x _n } and {y _n } be two sequences of E. If either {x _n } or {y _n } is bounded and ϕ(x _n , y _n ) → 0, as n → ∞, then x _n - y _n → 0, as n → ∞.

Lemma 2.3. [2]Let C be a convex subset of a real smooth Banach space E. Let x ∈ E. Then x₀ = Π_Cx if and only if

$$⟨z-x_0,Jx-J{x}_0⟩\le 0,\forall z\in C.$$

We make use of the function V: E × E* → ℝ defined by

$$V\left(x,x^{*}\right)=||x|{|}^2-2⟨x,x^{*}⟩+||x^{*}|{|}^2,\mathsf{\text{for}}\mathsf{\text{all }}x\in E\mathsf{\text{and}}{x}^{*}\in E^{*},$$

studied by Alber [2], i.e., V(x, x*) = ϕ(x, J^-1x*), for all x ∈ E and x* ∈ E*.

We know the following lemma related to the function V.

Lemma 2.4. [2]Let E be reflexive strictly convex and smooth Banach space with E* as its dual. Then

$$V\left(x,x^{*}\right)+2⟨{J^{-}}^1{x}^{*}-x,y^{*}⟩\le V\left(x,x^{*}+y^{*}\right),$$

for all x ∈ E and x*, y* ∈ E*.

Lemma 2.5. [24]Let E be a uniformly convex Banach space and B _R (0) be a closed ball of E. Then, there exists a continuous strictly increasing convex function g: [0, ∞) → [0, ∞) with g(0) = 0 such that$||{\alpha }_0{x}_0+{\alpha }_1{x}_1+{\alpha }_2{x}_2+\dots +{\alpha }_k{x}_k|{|}^2\le \sum _{i=0}^k{\alpha }_i||x_i|{|}^2-{\alpha }_i{\alpha }_{j}g\left(||x_i-x_j||\right)$, for 0 ≤ i ≤ j ≤ k, and each α _i ∈ (0, 1), where x _i ∈ B _R (0): = {x ∈ E: ||x|| ≤ R}, i = 0, 1, 2, . . . , k with$\sum _{i=0}^k{\alpha }_i=1$.

Proposition 2.6. [30]Let E be uniformly convex and uniformly smooth Banach space, let C be closed convex subset of E, and let S be closed relatively asymptotically nonexpansive mapping from C into itself. Then F(S) is closed and convex.

Lemma 2.7. [23]Let C be a nonempty, closed and convex subset of a uniformly smooth, strictly convex and reflexive real Banach space E. Let f be a bifunction from C × C to ℝ which satisfies conditions (A ₁ )-(A ₄ ). For r > 0 and x ∈ E, define the mapping T _r : E → C as follows:

$$T_{r}x:=\left\{z\in C:f\left(z,y\right)+\frac{1}{r}⟨y-z,Jz-Jx⟩\ge 0,\forall y\in C\right\}.$$

Then the following statements hold:

1. (1)

   T _r is single-valued;

2. (2)

   F(T _r ) = EP(f);

3. (3)

   ϕ(q, T _r x) + ϕ(T _r x, x) ≤ ϕ(q, x), for q ∈ F(T _r ).

4. (4)

   EP(f) is closed and convex;

Lemma 2.8. [29]Let C be a nonempty, closed and convex subset of a smooth, strictly convex and reflexive real Banach space E. Let A: C → E* be a continuous monotone mapping. For r > 0 and x ∈ E, define the mapping F _r : E → C as follows:

$$F_{r}x=\left\{z\in C:⟨y-z,Az⟩+\frac{1}{r}⟨y-z,Jz-Jx⟩\ge 0,\forall y\in C\right\}.$$

Then conclusions (1)-(4) of Lemma 2.7 hold.

Lemma 2.9[31]. Let {a _n } be a sequence of nonnegative real numbers satisfying the following relation:

$$a_{n+1}\le \left(1-{\beta }_n\right)a_n+{\beta }_n{\delta }_n,n\ge n_0,forsome{n}_0\in \mathbb{N},$$

where {β _n } ⊂ (0,1) and {δ _n } ⊂ R satisfying the following conditions:

$$\underset{n\to \infty }{\mathsf{\text{lim}}}{\beta }_n=0,\sum _{n=1}^{\infty }{\beta }_n=\infty ,and\underset{n\to \infty }{\mathsf{\text{lim}}\mathsf{\text{ sup}}}{\delta }_n\le 0.Then,\underset{n\to \infty }{\mathsf{\text{lim}}}{a}_n=0.$$

Lemma 2.10[32]. Let {a _n } be sequences 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 ∈ ℕ. Then there exists a nondecreasing sequence {m _k } ⊂ ℕ such that m _k → ∞ and the following properties are satisfied by all (sufficiently large) numbers k ∈ ℕ:

$$a_{m_k}\le a_{m_k+1}and{a}_k\le a_{m_k+1}.$$

In fact, m _k = max{j ≤ k: a _j < a_j+1}.

Main result

Let C be a nonempty, closed and convex subset of a smooth, strictly convex and reflexive real Banach space E with dual E*. Let f: C × C → ℝ be a bifunction and A: C →E* be a continuous monotone mapping. For the rest of this article, $T_{r_n}x$ and $F_{r_n}x$ are mappings defined as follows: For x ∈ E, let $F_{r_n}$, $T_{r_n}:E\to C$ be given by

$$F_{r_n}x:=\left\{z\in C:⟨y-z,Az⟩+\frac{1}{r_n}⟨y-z,Jz-Jx⟩\ge 0,\forall y\in C\right\},$$

and

$$T_{r_n}x:\left\{z\in C:f\left(z,y\right)+\frac{1}{r_n}⟨y-z,Jz-Jx⟩\ge 0,\forall y\in C\right\},$$

where {r _n }_n∈ℕ⊂ [c₁,∞) for some c₁ > 0.

Theorem 3.1. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let f: C × C → ℝ be a bifunction which satisfies conditions (A1)-(A4). Let A: C →E* be a continuously monotone mapping. Let T _i : C → C be a asymptotically regular uniformly continuous relatively asymptotically nonexpansive mapping with sequence {k_{n, i}} for i = 1, 2, . . . , N. Assume that$F:={\cap }_{i=1}^{N}F\left(T_i\right)\cap VI\left(C,A\right)\cap EP\left(f\right)$is nonempty. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{x}_0=w\in C,chosenarbitrarity,\hfill \\ u_n=F_{r_n}{x}_n,\hfill \\ w_n=T_{r_n}{u}_n,\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1\mathsf{\text{-}}{\alpha }_n\right)J{w}_n\right),\hfill \\ x_{n+1}=J^{-1}\left({\beta }_{n,0}J{w}_n+{\sum }_{i=1}^N{\beta }_{n,i}J{T}_i^n{y}_n\right),n\ge 0,\hfill \end{array}\right.$$

(3.1)

where α _n ∈ (0,1) such that lim_n→∞α_n = 0, ${\mathsf{\text{lim}}}_{n\to \infty }\frac{\left(k_{n,i}-1\right)}{{\alpha }_n}=0$, ${\sum }_{n=1}^{\infty }{\alpha }_n=\infty$, {β_{n, i}} ⊂ [a, b] ⊂ (0, 1), for i = 1, 2, . . . , N, satisfying β_n,0+ β_n,1+ · · · + β_{n, N}= 1, for each n ≥ 0. Then {x _n } converges strongly to an element of F.

Proof. Since F is nonempty closed and convex, put x*: = Π _F w. Now, from (3.1), Lemmas 2.1, 2.7(3), 2.8(3) and property of ϕ we get that

$$\begin{array}{cc}\hfill \varphi \left(x^{*},y_n\right)& =\varphi (x^{*},{\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right)\hfill \\ \le \varphi (x^{*},J^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right)\hfill \\ =||x^{*}|{|}^2-2⟨x^{*},{\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n⟩\hfill \\ +||{\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n|{|}^2\hfill \\ \le ||x^{*}|{|}^2-2{\alpha }_n⟨x^{*},Jw⟩-2\left(1-{\alpha }_n\right)⟨x^{*},J{w}_n⟩\hfill \\ +{\alpha }_n||Jw|{|}^2+\left(1-{\alpha }_n\right)||J{W}_n|{|}^2,\hfill \\ ={\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},w_n\right)\hfill \\ ={\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},T_{r_n}{u}_n\right)\hfill \\ \le {\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},u_n\right)\hfill \\ ={\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},F_{r_n}{x}_n\right)\hfill \\ \le {\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},x_n\right).\hfill \end{array}$$

(3.2)

Let k _n : = max{k_{n, i}: i = 1, 2, . . . , N}. Then, from (3.1), Lemma 2.7(3), Lemma 2.8(3), relatively asymptotic nonexpansiveness of T _i , property of ϕ and (3.2) we have that

$$\begin{array}{cc}\hfill \varphi \left(x^{*},x_{n+1}\right)& =\varphi \left(x^{*},J^{-1}\left({\beta }_{n,0}J{w}_n+\sum _{i=1}^N{\beta }_{n,i}J{T}_i^n{y}_n\right.\right)\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},w_n\right)+\left.\sum _{i=1}^N{\beta }_{n,i}\varphi \left(x^{*},T_i^n{y}_n\right)\right)\hfill \\ ={\beta }_{n,0}\varphi \left(x^{*},T_{r_n}{u}_n\right)+\sum _{i=1}^N{\beta }_{n,i}\varphi \left(x^{*},T_i^n{y}_n\right)\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},u_n\right)+\left(1-{\beta }_{n,0}\right)k_n\varphi \left(x^{*},y_n\right)\hfill \\ ={\beta }_{n,0}\varphi \left(x^{*},F_{r_n}{x}_n\right)+\left(1-{\beta }_{n,0}\right)k_n\varphi \left(x^{*},y_n\right)\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},x_n\right)+\left(1-{\beta }_{n,0}\right)\varphi \left(x^{*},y_n\right)\hfill \\ +\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\varphi \left(x^{*},y_n\right),\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},x_n\right)+\left(1-{\beta }_{n,0}\right)\left[{\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},x_n\right)\right]\hfill \\ +\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\left[{\alpha }_n\varphi \left(x^{*},w\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},x_n\right)\right]\hfill \\ \le \left[{\alpha }_n\left(1-{\beta }_{n,0}\right)+\left(1-{\beta }_{n,0}\right)\left(k_n-1\right){\alpha }_n\right]\varphi \left(x^{*},w\right)\hfill \\ +\left[\left(1-{\alpha }_n\left(1-{\beta }_{n,0}\right)\right)+\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\left(1-{\alpha }_n\right)\right]\hfill \\ \times \varphi \left(x^{*},x_n\right)\hfill \\ \le {\delta }_n\varphi \left(x^{*},w\right)+\left[1-\left(1-\epsilon \right){\delta }_n\right]\varphi \left(x^{*},x_n\right),\hfill \end{array}$$

(3.3)

where δ _n = (1 - β_n,0)k _n α _n , since for some ϵ > 0, there exists N₀ > 0 such that $\frac{\left(k_n-1\right)}{{\alpha }_n}\le ϵk_n$ and (1 - ϵ)δ _n ≤ 1, for all n ≥ N₀. Thus, by induction

$$\varphi \left(x^{*},x_{n+1}\right)\le \mathsf{\text{max}}\left\{\varphi \left(x^{*},x_{N_0}\right),{\left(1-ϵ\right)}^{-1}\varphi \left(x^{*},w\right)\right\},\forall n\ge N_0.$$

which implies that {x _n } is bounded and hence {y _n }, {u _n } and {w _n } are bounded. Now let z _n = J^-1(α _n Jw + (1 - α _n )Jw _n ). Then we have that y _n = Π_Cz_n. Using Lemmas 2.1, 2.4, and property of ϕ we obtain that

$$\begin{array}{cc}\hfill \varphi \left(x^{*},y_n\right)& \le \varphi \left(x^{*},z_n\right)=V\left(x^{*},J{z}_n\right)\hfill \\ \le V\left(x^{*},J{z}_n-{\alpha }_n\left(Jw-J{x}^{*}\right)\right)-2⟨z_n-x^{*},{\alpha }_n\left(Jw-J{x}^{*}\right)⟩\hfill \\ =\varphi \left(x^{*},J^{-1}\left({\alpha }_{n}J{x}^{*}+\left(1-{\alpha }_n\right)J{w}_n\right)\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩\hfill \\ \le {\alpha }_n\varphi \left(x^{*},x^{*}\right)+\left(1-{\alpha }_n\right)\varphi \left(x^{*},w_n\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩\hfill \\ =\left(1-{\alpha }_n\right)\varphi \left(x^{*},w_n\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩\hfill \\ \le \left(1-{\alpha }_n\right)\varphi \left(x^{*},u_n\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩\hfill \\ \le \left(1-{\alpha }_n\right)\varphi \left(x^{*},x_n\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩.\hfill \end{array}$$

(3.4)

Furthermore, from (3.1), Lemma 2.5, relatively asymptotic nonexpansiveness of T _i , for each i = 1, 2, . . . , N, Lemmas 2.7(3), (3.4), and 2.8(3) we have that

$$\begin{array}{cc}\hfill \varphi \left(x^{*},x_{n+1}\right)& =\varphi \left(x^{*},J^{-1}\left({\beta }_{n,0}J{w}_n+\sum _{k=1}^N{\beta }_{n,i}J{T}_i^n{y}_n\right)\right)\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},w_n\right)+\sum _{i=1}^N{\beta }_{n,i}\varphi \left(x^{*},T_i^n{y}_n\right)\hfill \\ -{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_{n}J{T}_i^n{y}_n||\right),\hfill \end{array}$$

for each i = 1, 2, . . . , N. This implies that

$$\begin{array}{c}\varphi \left(x^{*},x_{n+1}\right)\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},w_n\right)+\left(1-{\beta }_{n,0}\right)k_n\varphi \left(x^{*},y_n\right)\hfill \\ -{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_n-J{T}_i^n{y}_n||\right)\hfill \\ \le {\beta }_{n,0}\left(\varphi \left(x^{*},u_n\right)-\varphi \left(w_n,u_n\right)\right)+\left(1+{\beta }_{n,0}\right)\varphi \left(x^{*},y_n\right)\hfill \\ +\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\varphi \left(x^{*},y_n\right)-{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_n-J{T}_i^n{y}_n||\right)\hfill \\ \le {\beta }_{n,0}\left(\varphi \left(x^{*},x_n\right)-\varphi \left(u_n,x_n\right)\right)-{\beta }_{n,0}\varphi \left(w_n,u_n\right)+\left(1-{\beta }_{n,0}\right)\varphi \left(x^{*},y_n\right)\hfill \\ +\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\varphi \left(x^{*},y_n\right)-{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_n-J{T}_i^n{y}_n||\right),\hfill \\ \le {\beta }_{n,0}\varphi \left(x^{*},x_n\right)-{\beta }_{n,0}\left(\varphi \left(u_n,x_n\right)+\varphi \left(w_n,u_n\right)\right)\hfill \\ +\left(1-{\beta }_{n,0}\right)\left[\left(1-{\alpha }_n\right)\varphi \left(x^{*},x_n\right)+2{\alpha }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩\right]\hfill \\ +\left(1-{\beta }_{n,0}\right)\left(k_n-1\right)\varphi \left(x^{*},y_n\right)-{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_n-J{T}_i^n{y}_n||\right),\hfill \end{array}$$

and hence

$$\begin{array}{c}\varphi \left(x^{*},x_{n+1}\right)\\ \le \left(1-{\theta }_n\right)\varphi \left(x^{*},x_n\right)+2{\theta }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩+\left(k_n-1\right)M\\ -{\beta }_{n,0}\left(\varphi \left(u_n,x_n\right)+\varphi \left(w_n,u_n\right)\right)-{\beta }_{n,0}{\beta }_{n,i}g\left(||J{w}_n-J{T}_i^n{y}_n||\right)\end{array}$$

(3.5)

$$\le \left(1-{\theta }_n\right)\varphi \left(x^{*},x_n\right)+2{\theta }_n⟨z_n-x^{*},Jw-J{x}^{*}⟩+\left(k_n-1\right)M,$$

(3.6)

for some M > 0, where θ _n : = α _n (1 - β_n,0), for all n ∈ ℕ. Note that θ _n satisfies $\underset{n}{\mathsf{\text{lim}}}{\theta }_n=0$ and ${\sum }_{n=1}^{\infty }{\theta }_n=\infty$.

Now, the rest of the proof is divided into two parts:

Case 1. Suppose that there exists n₀ ∈ ℕ such that {ϕ(x*, x _n )} is nonincreasing for all n ≥ n₀. In this situation, {{ϕ(x*, x _n )} is then convergent. Then from (3.5) we have that ϕ(u _n , x _n ), ϕ(w _n , u _n ) → 0 and hence Lemma 2.2 implies that

$$u_n-x_n\to 0,u_n-w_n\to 0,\mathsf{\text{as }}n\to \infty .$$

(3.7)

Moreover, from (3.5) we have that ${{\beta }_n}_{,0}{{\beta }_n}_{,i}g(||J{w}_n-J{T}_i^n{y}_n||\to 0$, for i = 1, 2, . . . , N, which implies by the property of g that $J{w}_n-J{T}_i^n{y}_n\to 0$, as n → ∞, and hence, since J^-1 uniformly continuous on bounded sets, we obtain that

$$w_n-T_i^n{y}_n\to 0,\mathsf{\text{as }}n\to \infty ,\mathsf{\text{for each }}i\in \left\{1,2,\dots ,N\right\}.$$

(3.8)

Furthermore, Lemma 2.1, property of ϕ and the fact that α _n → 0, as n → ∞, imply that

$$\begin{array}{cc}\hfill \varphi \left(w_n,y_n\right)& =\varphi \left(w_n,{\text{Π}}_C{z}_n\right)\le \varphi \left(w_n,z_n\right)\hfill \\ =\varphi (w_n,J^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right)\hfill \\ \le {\alpha }_n\varphi \left(w_n,w\right)+\left(1-{\alpha }_n\right)\varphi (w_n,w_n\mathsf{\text{)}}\hfill \\ ={\alpha }_n\varphi \left(w_n,w\right)\to 0,\mathsf{\text{as }}n\to \infty ,\hfill \end{array}$$

(3.9)

and that

$$w_n-y_n\to 0\mathsf{\text{and}}{w}_n-z_n\to 0,\mathsf{\text{as }}n\to \infty .$$

(3.10)

Therefore, from (3.7), (3.8), and (3.10) we obtain that

$$x_n-z_n\to 0,y_n-x_n\to 0\mathsf{\text{and}}{y}_n-T_i^n{y}_n\to 0,\mathsf{\text{as }}n\to \infty ,$$

(3.11)

for each i ∈ {1, 2, . . . , N}. Therefore, since

$$\begin{array}{cc}\hfill ||y_n-T_i{y}_n||& \le ||y_n-T_i^n{y}_n||+||T_i^n{y}_n-T_i^{n+1}{y}_n||+||T_i^{n+1}{y}_n-T_i{y}_n||,\hfill \\ =||y_n-T_i^n{y}_n||+||T_i^n{y}_n-T_i^{n+1}{y}_n||+||T_i\left(T_i^n{y}_n\right)-T_i{y}_n||,\hfill \end{array}$$

(3.12)

we have from (3.11), asymptotic regularity and uniform continuity of T _i that

$$||y_n-T_i{y}_n||\to 0,\mathsf{\text{as }}n\to \infty ,\mathsf{\text{for each }}i=1,2,\dots ,N.$$

(3.13)

Since {z _n } is bounded and E is reflexive, we choose a subsequence $\left\{z_{n_i}\right\}$ of {z _n } such that $z_{n_i}\rightharpoonup z$ and $\underset{n\to \infty }{\mathsf{\text{lim}}\mathsf{\text{sup}}}⟨z_n-x^{*},Jw-J{x}^{*}⟩=\underset{i\to \infty }{\mathsf{\text{lim}}}⟨z_{n_i}-x^{*},Jw-J{x}^{*}⟩$. Then, from (3.7), (3.11) and the uniform continuity of J we get that

$$u_{n_i}{w}_{n_i}\rightharpoonup z\mathsf{\text{and }}J{u}_n-J{x}_n,J{u}_n-J{w}_n\to 0,\mathsf{\text{as }}n\to \infty .$$

(3.14)

Now, we show that z ∈ VI(C, A). But from the definition of u _n we have that

$$⟨y-u_n,A{u}_n⟩+⟨y-u_n,\frac{J{u}_n-J{x}_n}{r_n}⟩\ge 0,\forall y\in C.$$

(3.15)

and hence

$$⟨y-u_{n_i},A{u}_{n_i}⟩+⟨y-u_{n_i},\frac{J{u}_{n_i}-J{x}_{n_i}}{r_{n_i}}⟩\ge 0,\forall y\in C.$$

(3.16)

Set v _t = ty + (1 - t)z for all t ∈ (0, 1] and y ∈ C. Consequently, we get that v _t ∈ C. Now, from (3.16) it follows that

$$\begin{array}{cc}\hfill ⟨v_t-u_{n_i},A{v}_t⟩& \ge ⟨v_t-u_{n_i},A{v}_t⟩-⟨v_t-u_{n_i},A{u}_{n_i}⟩\hfill \\ -⟨v_t-u_{n_i},\frac{J{u}_{n_i}-J{x}_{n_i}}{r_{n_i}}⟩\hfill \\ =⟨v_t-u_{n_i},A{v}_t-A{u}_{n_i}⟩-⟨v_t-u_{n_i},\frac{J{u}_{n_i}-J{x}_{n_i}}{r_{n_i}}⟩.\hfill \end{array}$$

But, from (3.14) we have that $\frac{J{u}_{n_i}-J{x}_{n_i}}{r_{n_i}}\to 0$, as i → ∞ and the monotonicity of A implies that $\left(v_t-u_{n_i},A{v}_t-A{u}_{n_i}\right)\ge 0$. Thus, it follows that

$$0\le \underset{i\to \infty }{\mathsf{\text{lim}}}⟨v_t-u_{n_i},A{v}_t⟩=⟨v_t-z,A{v}_t⟩,$$

and hence

$$⟨y-z,A{v}_t⟩\ge 0,\forall y\in C.$$

If t → 0, the continuity of A implies that

$$⟨y-z,Az⟩\ge 0,\forall y\in C.$$

This implies that z ∈ VI(C, A).

Next, we show that z ∈ EP(f). From the definition of w _n and (A2) we note that

$$\frac{1}{r_{n_i}}⟨y-w_{n_i},J{w}_{n_i}-J{u}_{n_i}⟩\ge -f\left(w_{n_i},y\right)\ge f\left(y,w_{n_i}\right),\forall y\in C.$$

(3.17)

Letting i → ∞, we have from (3.14) and (A4) that f(y, z) ≤ 0, for all y ∈ C. Now, for 0 < t ≤ 1 and y ∈ C, let y _t = ty + (1 - t)z. Since y ∈ C and z ∈ C, we have y _t ∈ C and hence f(y _t , z) ≤ 0. So, from the convexity of the equilibrium bifunction f(x, y) on the second variable y, we have

$$0=f\left(y_t,y_t\right)\le tf\left(y_t,y\right)+\left(1-t\right)f\left(y_t,z\right)\le tf\left(y_t,y\right),$$

and hence f(y _t , y) ≥ 0. Now, letting t → 0, and condition (A3), we obtain that f(z, y) ≥ 0, for all y ∈ C, and hence z ∈ EP(f).

Finally, we show that $z\in {\cap }_{i=1}^{N}F\left(T_i\right)$. But, since each T _i satisfies condition (N3) we obtain from (3.13) that z ∈ F(T _i ) for each i = 1, 2, . . . , N and hence $z\in {\cap }_{i=1}^{N}F\left(T_i\right)$. Thus, from the above discussions we obtain that $z\in F:={\cap }_{i=1}^{N}F\left(T_i\right)\cap \mathsf{\text{VI}}\left(C,A\right)\cap \mathsf{\text{EP}}\left(f\right)$. Therefore, by Lemma 2.3, we immediately obtain that $\underset{n\to \infty }{\mathsf{\text{lim}}\mathsf{\text{sup}}}⟨z_n-x^{*},Jw-J{x}^{*}⟩=\underset{i\to \infty }{\mathsf{\text{lim}}}⟨z_{n_i}-x^{*},Jw-J{x}^{*}⟩=⟨z-x^{*},Jw-J{x}^{*}⟩\le 0$. It follows from Lemma 2.9 and (3.6) that ϕ(x*, x _n ) → 0, as n → ∞. Consequently, x _n → x* by Lemma 2.2.

Case 2. Suppose that there exists a subsequence {n _i } of {n} such that $\varphi \left(x^{*},x_{n_i}\right)<\varphi \left(x^{*},x_{n_i+1}\right)$, for all i ∈ ℕ. Then, by Lemma 2.10, there exist a nondecreasing sequence {m _k } ⊂ ℕ such that m _k → ∞, $\varphi \left(x^{*},x_{m_k}\right)\le \varphi \left(x^{*},x_{m_k+1}\right)$ and $\varphi \left(x^{*},x_k\right)\le \varphi \left(x^{*},x_{m_k+1}\right)$, for all k ∈ ℕ. Then from (3.5) and the fact that θ _n → 0 we have that

$$\begin{array}{c}{\beta }_{m_k,0}\left(\varphi \left(u_{m_k},x_{m_k}\right)+\varphi \left(w_{m_k},u_{m_k}\right)\right)+{\beta }_{m_k,0}{\beta }_{m_k,i}g\left(||J{w}_{m_k}-J{T}_i^{m_k}{y}_{m_k}||\right)\hfill \\ \le \left(\varphi \left(x^{*},x_{m_k}\right)-\varphi \left(x^{*},x_{m_k+1}\right)\right)-{\theta }_{m_k}\varphi \left(x^{*},x_{m_k}\right)\hfill \\ +2{\theta }_{m_k}⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩+\left(k_{m_k}-1\right)M\to 0,\mathsf{\text{as }}k\to \infty .\hfill \end{array}$$

Thus, using the same proof of Case 1, we obtain that $u_{m_k}-x_{m_k}\to 0$, $u_{m_k}-w_{m_k}\to 0$ and $y_{m_k}-T_i{y}_{m_k}\to 0$, as k → ∞, for each i = 1, 2, . . . , N and hence

$$\underset{n\to \infty }{\mathsf{\text{lim}}\mathsf{\text{ sup}}}⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩\le 0.$$

(3.18)

Then from (3.6) we have that

$$\begin{array}{cc}\hfill \varphi (x^{*}{x}_{m_k+1})& \le \left(1-{\theta }_{m_k}\right)\varphi \left(x^{*},x_{m_k}\right)+2{\theta }_{m_k}⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩\hfill \\ +\left(k_{m_k}-1\right)M.\hfill \end{array}$$

(3.19)

Since $\varphi \left(x^{*},x_{m_k}\right)\le \varphi \left(x^{*},x_{m_k+1}\right)$, (3.19) implies that

$$\begin{array}{cc}\hfill {\theta }_{m_k}\varphi \left(x^{*},x_{m_k}\right)& \le \varphi \left(x^{*},x_{m_k}\right)-\varphi \left(x^{*},x_{m_k+1}\right)\hfill \\ +2{\theta }_{m_k}⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩+\left(k_{m_k}-1\right)M\hfill \\ \le 2{\theta }_{m_k}⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩+\left(k_{m_k}-1\right)M.\hfill \end{array}$$

In particular, since ${\theta }_{m_k}>0$, we get

$$\varphi \left(x^{*},x_{m_k}\right)\le 2⟨z_{m_k}-x^{*},Jw-J{x}^{*}⟩+\frac{\left(k_{m_k}-1\right)}{{\theta }_{m_k}}M.$$

Then, from (3.18) and the fact that $\frac{\left(k_{m_k}-1\right)}{{\theta }_{m_k}}\to 0$, we obtain that $\varphi \left(x^{*},x_{m_k}\right)\to 0$, as k → ∞. This together with (3.19) gives $\varphi \left(x^{*},x_{m_k+1}\right)\to 0$, as k → ∞. But $\varphi \left(x^{*},x_k\right)\le \varphi \left(x^{*},x_{m_k+1}\right)$, for all k ∈ ℕ, thus we obtain that x _k → x*. Therefore, from the above two cases, we can conclude that {x _n } converges strongly to x* and the proof is complete. □

Now, we give an example of asymptotically regular uniformly continuous relatively asymptotically nonexpansive mapping which is not uniformly Lipschitzian.

Example 3.2. Let $C:=\left[\frac{-1}{\pi },\frac{1}{\pi }\right]$ and define T: C → C by

$$T\left(x\right)=\left\{\begin{array}{cc}\frac{x}{2}\mathsf{\text{sin}}\left(\frac{1}{x}\right),\hfill & x\ne 0,\hfill \\ x,\hfill & x=0.\hfill \end{array}\right.$$

Then clearly, T is continuous and F(T) = {0}. Moreover, following the method in [33] we obtain that Tⁿx → 0, uniformly, for each x ∈ C, but T is not a Lipschitz function. We now show that it is relatively asymptotically nonexpansive, asymptotically regular and uniformly continuous mapping. But for any x ∈ C we have that $|T^{n}x-T^{n}0|\le |{\left(\frac{1}{2}\right)}^{n}x|=|{\left(\frac{1}{2}\right)}^{n}x-0|\le k_n|x-0|$, for $k_n:=\mathsf{\text{max}}\left\{{\left(\frac{1}{2}\right)}^n,1\right\}=1$, for each n ≥ 1 and |Tⁿ⁺¹x - Tⁿx| ≤ |Tⁿ⁺¹x| + |Tⁿx| → 0, as n → ∞. Moreover, since T: C → C is continuous, it follows that it is uniformly continuous. Therefore, T is relatively asymptotically nonexpansive, asymptotically regular and uniformly continuous mapping.

Next, we give an example of uniformly Lipschitzian relatively asymptotically nonexpansive mapping which is not relatively nonexpansive.

Example 3.3[34]. Let X = l^p , where 1 < p < ∞, and C = {x = (x₁, x₂, . . .) ∈ X; x _n ≥ 0}. Then C is closed and convex subset of X. Note that C is not bounded. Obviously, X is uniformly convex and uniformly smooth. Let {λ _n } and $\left\{{\bar{\lambda }}_n\right\}$ be sequences of real numbers satisfying the following properties:

1. (i)

   0 < λ _n < 1, ${\bar{\lambda }}_n>1$, λ _n ↑ 1 and ${\bar{\lambda }}_n\downarrow 1$,

2. (ii)

   ${\lambda }_{n+1}{\bar{\lambda }}_n=1$ and ${\lambda }_{j+1}{\bar{\lambda }}_{n+j}<1$, for all n and j (for example: ${\lambda }_n=1-\frac{1}{n+1}$, ${\bar{\lambda }}_n=1-\frac{1}{n+1}$).

Then the map T: C → C defined by

$$Tx:=\left(0,{\bar{\lambda }}_1|\mathsf{\text{sin}}{x}_1|,{\lambda }_2{x}_2,{\bar{\lambda }}_2{x}_3,{\lambda }_3{x}_4,{\bar{\lambda }}_3{x}_5,\dots \right),$$

for all x = (x₁, x₂, . . .) ∈ C is uniformly Lipschitzian which is relatively asymptotically nonexpansive but not relatively nonexpansive (see [34] for the details). Note also that F(T) = {0}.

Remark 3.4. We note that the asymptotic regularity assumption on T _i in Theorem 3.1 can be weakened to the assumption that$T_i^{n+1}{y}_n-T_i^n{y}_n\to 0$, as n → ∞, for i = 1, 2, . . . , N.

Recall that T is uniformly L-Lipschitzian if there exists some L > 0 such that

$$||T^{n}x-T^{n}y||\le L||x-y||,\mathsf{\text{for all }}n\ge 1\mathsf{\text{and }}x,y\in C.$$

(3.20)

We also note that the assumption $T_i^{n+1}{y}_n-T_i^n{y}_n\to 0$, as n → ∞ and uniform continuity of T _i can be replaced by the unform Lipschitz continuity of T _i .

With the above observation we have the following convergence result.

Corollary 3.5. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let f: C × C → ℝ, be a bifunction which satisfies conditions (A1)-(A4). Let A: C → E* be a continuously monotone mapping. Let T _i : C → C be uniformly Li-Lipschtzian relatively asymptotically nonexpansive mapping with sequence {k_{n, i}}, for i = 1, 2, . . . , N. Assume that$F:={\cap }_{i=1}^{N}F\left(T_i\right)\cap VI\left(C,A\right)\cap EP\left(f\right)$is nonempty. Then the sequence {x _n } generated by (3.1) converges strongly to an element of F.

Proof. Clearly, T _i for each i = 1, 2, . . . , N is uniformly continuous. Now we show that $T_i^{n+1}{y}_n-T_i^n{y}_n\to 0$, as n → ∞. But observe that from (3.1) and (3.8) we have

$$\begin{array}{cc}\hfill ||J{x}_{n+1}-J{w}_n||& \le {\beta }_{n,1}||T_1^n{y}_n-w_n||+{\beta }_{n,2}||T_2^n{y}_n-w_n||\hfill \\ +\cdots +{\beta }_{n,N}||T_2^n{y}_n-w_n||\to 0,\hfill \end{array}$$

(3.21)

as n → ∞. Thus, as J^-1 is uniformly continuous on bounded sets we have that x_n+1- w _n → 0 which implies from (3.10) that x_n+1- y _n → 0, as n → ∞. Thus, this with (3.11) implies that

$$||y_{n+1}-y_n||\le ||y_{n+1}-x_{n+1}||+||x_{n+1}-y_n||\to 0,\mathsf{\text{as }}n\to \infty .$$

(3.22)

and hence (3.22) and (3.11) imply that

$$\begin{array}{cc}\hfill ||T_i^n{y}_n-T_i^{n+1}{y}_n||& \le ||T_i^{n+1}{y}_n-T_i^{n+1}{y}_{n+1}||+||T_i^{n+1}{y}_{n+1}-y_{n+1}||\hfill \\ +||y_{n+1}-y_n||+||y_n-T_i^n{y}_n||\hfill \\ \le \left(1+L\right)||y_{n+1}-y_n||+||T_i^{n+1}{y}_{n+1}-y_{n+1}||\hfill \\ +||T_i^n{y}_n-y_n||\to 0,\mathsf{\text{as }}n\to \infty ,\hfill \end{array}$$

(3.23)

for each i = 1, 2, . . . , N, where $L:=\underset{1\le i\le N}{\mathsf{\text{max}}}\left\{L_i\right\}$. Therefore, Remark 3.4 with Theorem 3.1 imply the desired conclusion. □

If in Theorem 3.1 we have N = 1 we get the following corollary.

Corollary 3.6. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let f: C × C → ℝ, be a bifunction which satisfies conditions (A1)-(A4). Let A: C → E* be a continuously monotone mapping. Let T: C → C be a asymptotically regular uniformly continuous relatively asymptotically nonexpansive mapping with sequence {k _n }. Assume that F: = F(T) ∩ VI(C, A) ∩ EP(f) is nonempty. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{x}_0=w\in C,chosenarbitrary\mathsf{\text{,}}\hfill \\ u_n=F_{r_n}{x}_n,\hfill \\ w_n=T_{r_n}{u}_n,\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right),\hfill \\ x_{n+1}=J^{-1}\left({\beta }_{n}J{w}_n+\left(1-{\beta }_n\right)J{T}^n{y}_n\right),n\ge 0,\hfill \end{array}\right.$$

(3.24)

where α _n ∈ (0, 1) such that lim_n→∞α_n = 0, ${\mathsf{\text{lim}}}_{n\to \infty }\frac{\left(k_n-1\right)}{{\alpha }_n}=0$, ${\sum }_{n=1}^{\infty }{\alpha }_n=\infty$, {β _n } ⊂ [a, b] ⊂ (0, 1), for each n ≥ 0. Then {x _n } converges strongly to an element of F.

If in Theorem 3.1 we assume that each T _i is relatively nonexpansive we get the following theorem.

Theorem 3.7. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let f: C × C → ℝ, be a bifunction which satisfies conditions (A1)-(A4). Let A: C → E* be a continuously monotone mapping. Let T _i : C → C be a relatively nonexpansive mapping for each i = 1, 2, . . . , N. Assume that$F:={\cap }_{i=1}^{N}F\left(T_i\right)\cap VI\left(C,A\right)\cap EP\left(f\right)$is nonempty. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{x}_0=w\in C,chosenarbitrarily\mathsf{\text{,}}\hfill \\ u_n=F_{r_n}{x}_n,\hfill \\ w_n=T_{r_n}{u}_n,\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right),\hfill \\ x_{n+1}=J^{-1}\left({\beta }_{n,0}J{w}_n+{\sum }_{i=1}^N{\beta }_{n,i}J{T}_i{y}_n\right),n\ge 0,\hfill \end{array}\right.$$

(3.25)

where α _n ∈ (0,1) such that lim_n→∞α _n = 0, ${\sum }_{n=1}^{\infty }{\alpha }_n=\infty$, {β_{n, i}} ⊂ [a, b] ⊂ (0, 1), for i = 1, 2, . . . , N satisfying β_n,0+ β_n,1+ · · · + β_{n, N}= 1, for each n ≥ 0. Then {x _n } converges strongly to an element of F.

Proof. Following the methods of proof of Theorem 3.1 we obtain the required assertion. □

If in Theorem 3.1 we assume that f ≡ 0 and A ≡ 0 we get the following corollary.

Corollary 3.8. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let T _i : C → C be a asymptotically regular uniformly continuous relatively asymptotically nonexpansive mapping with sequence {k_{n, i}}, for i = 1, 2, . . . , N. Assume that$F:={\cap }_{i=1}^{N}F\left(T_i\right)$is nonempty. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{x}_0=w\in C,chosenarbitrarily\mathsf{\text{,}}\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right),\hfill \\ x_{n+1}=J^{-1}\left({\beta }_{n,0}J{x}_n+{\sum }_{i=1}^N{\beta }_{n,i}J{T}_i^n{y}_n\right),n\ge 0,\hfill \end{array}\right.$$

(3.26)

where α _n ∈ (0, 1) such that lim_n→∞α _n = 0, ${\mathsf{\text{lim}}}_{n\to \infty }\frac{\left(k_{n,i}-1\right)}{{\alpha }_n}=0$, ${\sum }_{n=1}^{\infty }{\alpha }_n=\infty$, {β_{n, i}} ⊂ [a, b] ⊂ (0, 1), for i = 1, 2, . . . , N satisfying β_n,0+ β_n,1+ · · · + β_{n, N}= 1, for each n ≥ 0. Then {x _n } converges strongly to an element of F.

If in Theorem 3.1 we assume that f ≡ 0 and T ≡ I we get the following corollary.

Corollary 3.9. Let C be a nonempty, closed and convex subset of a uniformly smooth and uniformly convex real Banach space E. Let A: C → E* be a continuously monotone mapping. Assume that F: = VI(C, A) is nonempty. Let {x _n } be a sequence generated by

$$\left\{\begin{array}{c}{x}_0=w\in C,chosenarbitrarily\mathsf{\text{,}}\hfill \\ w_n=F_{r_n}{x}_n,\hfill \\ y_n={\text{Π}}_C{J}^{-1}\left({\alpha }_{n}Jw+\left(1-{\alpha }_n\right)J{w}_n\right),\hfill \\ x_{n+1}=J^{-1}\left({\beta }_{n,}J{w}_n+\left(1-{\beta }_n\right)J{y}_n\right),n\ge 0,\hfill \end{array}\right.$$

(3.27)

where α _n ∈ (0, 1) such that lim_n→∞α _n = 0, ${\sum }_{n=1}^{\infty }{\alpha }_n=\infty$, {β _n } ⊂ [a, b] ⊂ (0, 1), for each n ≥ 0. Then {x _n } converges strongly to an element of F.

Remark 3.10. Theorem 3.1 improves and extends the corresponding results of Nakajo and Takahashi [17], Kim and Xu [35] in the sense that the space is extended from Hilbert spaces to uniformly smooth and uniformly convex Banach spaces. Moreover, Corollary 3.8 improves and extends Theorem MT of Matsushita and Takahashi [16] and Theorem 3.4 of Nilsrakoo and Saejung [36] from a relatively nonexpansive mappings to a finite family of asymptotically regular uniformly continuous relatively asymptotically nonexpansive mappings. Corollary 3.9 extends the corresponding results of Iiduka, Takahashi and Toyoda [6] and Iiduka and Takahashi [8] in the sense that either the space is extended from Hilbert space to uniformly smooth and uniformly convex Banach space or our scheme is used for approximating solutions of variational problems for a more general class of monotone mappings. Moreover, our scheme does not involve computation of C_n+1from sets C _n and Q _n for each n ≥ 1.