A new approximation scheme for solving various split inverse problems

“…This class of monotone mapping have been widely studied in literature (see [44,45]) for more details. If A is a monotone operator, then we can define, for each r > 0, a nonexpansive single-valued mapping J A r : R(I + rA) → D(A) by J A r := (I + rA) −1 which is generally known as the resolvent of A, (see [46,47]). It is also known that A −1 (0) = F(J A r ), where A −1 (0) = {x ∈ H : 0 ∈ Ax} and F(J A r ) = {x ∈ H :…”

A Strong Convergence Theorem for Split Null Point Problem and Generalized Mixed Equilibrium Problem in Real Hilbert Spaces

“…This class of monotone mapping have been widely studied in literature (see [44,45]) for more details. If A is a monotone operator, then we can define, for each r > 0, a nonexpansive single-valued mapping J A r : R(I + rA) → D(A) by J A r := (I + rA) −1 which is generally known as the resolvent of A, (see [46,47]). It is also known that A −1 (0) = F(J A r ), where A −1 (0) = {x ∈ H : 0 ∈ Ax} and F(J A r ) = {x ∈ H :…”

A Strong Convergence Theorem for Split Null Point Problem and Generalized Mixed Equilibrium Problem in Real Hilbert Spaces

“…Motivated and inspired by the works of Moudafi, 9 Taiwo et al, 10,24 Izuchukwu et al, 12 and Sunthrayuth et al, 26 we introduce and study an inertial algorithm, which converges strongly to a solution of split equality of monotone inclusion and $$$ f,g $$$‐fixed point of Bregman relatively $$$ f,g $$$‐nonexpansive mapping problems () in reflexive real Banach spaces. In addition, we provide several applications of our method and provide a numerical example to demonstrate the behavior of the convergence of the algorithm to a solution of the indicated problems.…”

“…The split monotone inclusion and fixed point problem (SMIFPP) 10 is the generalization of SMIP, which is defined as finding a point $$$ \left(p,q\right)\in {H}_1\times {H}_2 $$$ such that $$$$ p\in F(T)\cap {\left(A+B\right)}^{-1}0,q\in F(G)\cap {\left(C+D\right)}^{-1}0\kern0.3em \mathrm{and}\kern0.3em S(p)=K(q), $$$$ where $$$ A:{H}_1\to {H}_1 $$$ and $$$ C:{H}_2\to {H}_2 $$$ are inverse strongly monotone mappings, $$$ B:{H}_1\to {2}^{H_1} $$$ and $$$ D:{H}_2\to {2}^{H_2} $$$ are maximal monotone mappings, $$$ T:{H}_1\to {H}_1 $$$ and $$$ G:{H}_2\to {H}_2 $$$ are demi‐contractive mappings, …”

An inertial method for a solution of split equality of monotone inclusion and the f$$ f $$‐fixed point problems in Banach spaces

“…authors have studied and proposed many iterative algorithms for approximating the solution of variational inequality problem and related optimization problems, (see [10,20,26,25,29,44,46,49]) and the references therein. The variational inequality problem is widely known to be equivalent to the following fixed point equation:…”

A new inertial-projection algorithm for approximating common solution of variational inequality and fixed point problems of multivalued mappings