Oscillation Behaviour of Solutions for a Class of a Discrete Nonlinear Fractional-Order Derivatives

Chatzarakis, George. E.; George Maria Selvam, A.; Janagaraj, Rajendran; Miliaras, George. N.

doi:10.2478/tmmp-2021-0022

Abstract

Based on the generalized Riccati transformation technique and some inequality, we study some oscillation behaviour of solutions for a class of a discrete nonlinear fractional-order derivative equation $Δ [γ (ℓ) {[α (ℓ) + β (ℓ) Δ^{μ} u (ℓ)]}^{η}] + ϕ (ℓ) f [G (ℓ)] = 0, ℓ \in N_{ℓ_{0} + 1 - μ},$ \[\Delta [\gamma (\ell ){[\alpha (\ell ) + \beta (\ell ){\Delta ^\mu }u(\ell )]^\eta }] + \phi (\ell )f[G(\ell )] = 0,\ell \in {N_{{\ell _0} + 1 - \mu }},\] where $ℓ_{0} > 0, G (ℓ) = \sum_{j = ℓ_{0}}^{ℓ - 1 + μ} {(ℓ - j - 1)}^{(- μ)} u (j)$ \[{\ell _0} > 0,\quad G(\ell ) = \sum\limits_{j = {\ell _0}}^{\ell - 1 + \mu } {{{(\ell - j - 1)}^{( - \mu )}}u(j)} \] and Δ^μ is the Riemann-Liouville (R-L) difference operator of the derivative of order μ, 0 < μ ≤ 1 and η is a quotient of odd positive integers. Illustrative examples are given to show the validity of the theoretical results.

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Oscillation Behaviour of Solutions for a Class of a Discrete Nonlinear Fractional-Order Derivatives

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