Research article

Tripled fixed point techniques for solving system of tripled-fractional differential equations

  • Received: 18 October 2020 Accepted: 11 December 2020 Published: 16 December 2020
  • MSC : 26A33, 34A08, 34B24, 39A70, 47H10, 54H25

  • The intended goal of this manuscript is to discuss the existence of the solution to the below system of tripled-fractional differential equations (TFDEs, for short):

    $ \left\{ \begin{array}{c} \Theta ^{\mu }\left[ k(\alpha )-\gimel (\alpha ,k(\alpha ))\right] = \Game \left( \alpha ,r(\alpha ),I^{\tau }(r(\alpha ))\right) +\Game \left( \alpha ,l(\alpha ),I^{\tau }(l(\alpha ))\right) , \\ \Theta ^{\mu }\left[ l(\alpha )-\gimel (\alpha ,l(\alpha ))\right] = \Game \left( \alpha ,k(\alpha ),I^{\tau }(k(\alpha )\right) )+\Game \left( \alpha ,r(\alpha ),I^{\tau }(r(\alpha )\right) ), \\ \Theta ^{\mu }\left[ r(\alpha )-\gimel (\alpha ,r(\alpha ))\right] = \Game \left( \alpha ,l(\alpha ),I^{\tau }(l(\alpha )\right) )+\Game \left( \alpha ,k(\alpha ),I^{\tau }(k(\alpha )\right) ), \\ k(0) = 0,\text{ }l(0) = 0,\text{ }r(0) = 0, \end{array} \right. a.e.\text{ }\alpha \in \Omega ,\text{ }\tau >0,\text{ }\mu \in (0,1), $

    where $ \Theta ^{\mu } $ is RL-fractional derivative of order $ \tau, \; \Omega = [0, \Lambda ], \; \Lambda > 0, $ and $ \gimel :\Omega \times \mathbb{R} \rightarrow \mathbb{R}, $ with $ \gimel (0, 0) = 0, \; \Game :\Omega \times \mathbb{R} \times \mathbb{R} \rightarrow \mathbb{R} $ are functions taken under appropriate hypotheses. The method of the proof depends on a manner of a tripled fixed point (TFP), which generalize a fixed point theorem of Burton [1]. At last, a non-trivial example to strong our results is illustrated.

    Citation: Hasanen A. Hammad, Manuel De la Sen. Tripled fixed point techniques for solving system of tripled-fractional differential equations[J]. AIMS Mathematics, 2021, 6(3): 2330-2343. doi: 10.3934/math.2021141

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  • The intended goal of this manuscript is to discuss the existence of the solution to the below system of tripled-fractional differential equations (TFDEs, for short):

    $ \left\{ \begin{array}{c} \Theta ^{\mu }\left[ k(\alpha )-\gimel (\alpha ,k(\alpha ))\right] = \Game \left( \alpha ,r(\alpha ),I^{\tau }(r(\alpha ))\right) +\Game \left( \alpha ,l(\alpha ),I^{\tau }(l(\alpha ))\right) , \\ \Theta ^{\mu }\left[ l(\alpha )-\gimel (\alpha ,l(\alpha ))\right] = \Game \left( \alpha ,k(\alpha ),I^{\tau }(k(\alpha )\right) )+\Game \left( \alpha ,r(\alpha ),I^{\tau }(r(\alpha )\right) ), \\ \Theta ^{\mu }\left[ r(\alpha )-\gimel (\alpha ,r(\alpha ))\right] = \Game \left( \alpha ,l(\alpha ),I^{\tau }(l(\alpha )\right) )+\Game \left( \alpha ,k(\alpha ),I^{\tau }(k(\alpha )\right) ), \\ k(0) = 0,\text{ }l(0) = 0,\text{ }r(0) = 0, \end{array} \right. a.e.\text{ }\alpha \in \Omega ,\text{ }\tau >0,\text{ }\mu \in (0,1), $

    where $ \Theta ^{\mu } $ is RL-fractional derivative of order $ \tau, \; \Omega = [0, \Lambda ], \; \Lambda > 0, $ and $ \gimel :\Omega \times \mathbb{R} \rightarrow \mathbb{R}, $ with $ \gimel (0, 0) = 0, \; \Game :\Omega \times \mathbb{R} \times \mathbb{R} \rightarrow \mathbb{R} $ are functions taken under appropriate hypotheses. The method of the proof depends on a manner of a tripled fixed point (TFP), which generalize a fixed point theorem of Burton [1]. At last, a non-trivial example to strong our results is illustrated.



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