Extended existence results for FDEs with nonlocal conditions

Saleh Fahad Aljurbua; Saleh Fahad Aljurbua

doi:10.3934/math.2024440

AIMS Mathematics

2024, Volume 9, Issue 4: 9049-9058. doi: 10.3934/math.2024440

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Extended existence results for FDEs with nonlocal conditions

Saleh Fahad Aljurbua ^,

Department of Mathematics, College of Science, Qassim University, P.O. Box 6644, Buraydah, 51452, Saudi Arabia

Received: 02 January 2024 Revised: 20 February 2024 Accepted: 20 February 2024 Published: 05 March 2024
MSC : 26A33, 34A08

This paper discusses the existence of solutions for fractional differential equations with nonlocal boundary conditions (NFDEs) under essential assumptions. The boundary conditions incorporate a point $ 0\leq c < d $ and fixed points at the end of the interval $ [0, d] $. For $ i = 0, 1 $, the boundary conditions are as follows: $ a_{i}, b_{i} > 0 $, $ a_{0} p(c) = -b_{0} p(d), \ a_{1} p^{'}(c) = -b_{1} p^{'}(d) $. Furthermore, the research aims to expand the usability and comprehension of these results to encompass not just NFDEs but also classical fractional differential equations (FDEs) by using the Krasnoselskii fixed-point theorem and the contraction principle to improve the completeness and usefulness of the results in a wider context of fractional differential equations. We offer examples to demonstrate the results we have achieved.
- fractional derivatives,
- differential equations,
- fractional differential equations,
- existence of solutions,
- fixed-point theorem
Citation: Saleh Fahad Aljurbua. Extended existence results for FDEs with nonlocal conditions[J]. AIMS Mathematics, 2024, 9(4): 9049-9058. doi: 10.3934/math.2024440

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Abstract

This paper discusses the existence of solutions for fractional differential equations with nonlocal boundary conditions (NFDEs) under essential assumptions. The boundary conditions incorporate a point $ 0\leq c < d $ and fixed points at the end of the interval $ [0, d] $. For $ i = 0, 1 $, the boundary conditions are as follows: $ a_{i}, b_{i} > 0 $, $ a_{0} p(c) = -b_{0} p(d), \ a_{1} p^{'}(c) = -b_{1} p^{'}(d) $. Furthermore, the research aims to expand the usability and comprehension of these results to encompass not just NFDEs but also classical fractional differential equations (FDEs) by using the Krasnoselskii fixed-point theorem and the contraction principle to improve the completeness and usefulness of the results in a wider context of fractional differential equations. We offer examples to demonstrate the results we have achieved.

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