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The existence of solutions of Hadamard fractional differential equations with integral and discrete boundary conditions on infinite interval

  • Received: 13 January 2024 Revised: 19 February 2024 Accepted: 11 March 2024 Published: 21 March 2024
  • In this article, the properties of solutions of Hadamard fractional differential equations are investigated on an infinite interval. The equations are subject to integral and discrete boundary conditions. A new proper compactness criterion is introduced in a unique space. By applying the monotone iterative technique, we have obtained two positive solutions. And, an error estimate is also shown at the end. This study innovatively uses a monotonic iterative approach to study Hadamard fractional boundary-value problems containing multiple fractional derivative terms on infinite intervals, and it enriches some of the existing conclusions. Meanwhile, it is potentially of practical significance in the research field of computational fluid dynamics related to blood flow problems and in the direction of the development of viscoelastic fluids.

    Citation: Jinheng Liu, Kemei Zhang, Xue-Jun Xie. The existence of solutions of Hadamard fractional differential equations with integral and discrete boundary conditions on infinite interval[J]. Electronic Research Archive, 2024, 32(4): 2286-2309. doi: 10.3934/era.2024104

    Related Papers:

  • In this article, the properties of solutions of Hadamard fractional differential equations are investigated on an infinite interval. The equations are subject to integral and discrete boundary conditions. A new proper compactness criterion is introduced in a unique space. By applying the monotone iterative technique, we have obtained two positive solutions. And, an error estimate is also shown at the end. This study innovatively uses a monotonic iterative approach to study Hadamard fractional boundary-value problems containing multiple fractional derivative terms on infinite intervals, and it enriches some of the existing conclusions. Meanwhile, it is potentially of practical significance in the research field of computational fluid dynamics related to blood flow problems and in the direction of the development of viscoelastic fluids.



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