Banaei, S., Ghaemi, M. (2019). A Generalization of the Meir-Keeler Condensing Operators and its Application to Solvability of a System of Nonlinear Functional Integral Equations of Volterra Type. Sahand Communications in Mathematical Analysis, (), -. doi: 10.22130/scma.2018.74869.322

Shahram Banaei; Mohammad Bagher Ghaemi. "A Generalization of the Meir-Keeler Condensing Operators and its Application to Solvability of a System of Nonlinear Functional Integral Equations of Volterra Type". Sahand Communications in Mathematical Analysis, , , 2019, -. doi: 10.22130/scma.2018.74869.322

Banaei, S., Ghaemi, M. (2019). 'A Generalization of the Meir-Keeler Condensing Operators and its Application to Solvability of a System of Nonlinear Functional Integral Equations of Volterra Type', Sahand Communications in Mathematical Analysis, (), pp. -. doi: 10.22130/scma.2018.74869.322

Banaei, S., Ghaemi, M. A Generalization of the Meir-Keeler Condensing Operators and its Application to Solvability of a System of Nonlinear Functional Integral Equations of Volterra Type. Sahand Communications in Mathematical Analysis, 2019; (): -. doi: 10.22130/scma.2018.74869.322

A Generalization of the Meir-Keeler Condensing Operators and its Application to Solvability of a System of Nonlinear Functional Integral Equations of Volterra Type

Articles in Press, Accepted Manuscript , Available Online from 23 April 2019

^{1}Department of Mathematics, Bonab Branch, Islamic Azad University, Bonab, Iran.

^{2}Department of Mathematics, Iran University of Science and Technology, Narmak, Tehran, Iran.

Abstract

In this paper, we generalize the Meir-Keeler condensing operators via a concept of the class of operators $ O (f;.)$, that was given by Altun and Turkoglu [4], and apply this extension to obtain some tripled fixed point theorems. As an application of this extension, we analyze the existence of solution for a system of nonlinear functional integral equations of Volterra type. Finally, we present an example to show the effectiveness of our results. We use the technique of measure of noncompactness to obtain our results.

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