Abstract
In this article, the investigation is centered around the quantum estimates by utilizing quantum Hahn integral operator via the quantum shift operator {}_{eta}psi_{mathfrak{q}}(zeta)=mathfrak{q}zeta+(1-mathfrak{q})eta, zetain[mu,nu], eta=mu+frac{omega}{(1-mathfrak{q})}, 0<mathfrak{q}<1, omegageq0. Our strategy includes fractional calculus, Jackson’s mathfrak{q}-integral, the main ideas of quantum calculus, and a generalization used in the frame of convex functions. We presented, in general, three types of fractional quantum integral inequalities that can be utilized to explain orthogonal polynomials, and exploring some estimation problems with shifting estimations of fractional order varrho_{1} and the mathfrak{q}-numbers have yielded fascinating outcomes. As an application viewpoint, an illustrative example shows the effectiveness of mathfrak{q}, ω-derivative for boundary value problem.
Highlights
Quantum difference operators have played a crucial role in the development of quantum calculus due to their fertile application, see [1,2,3,4,5]
A quantum calculus substitutes the classical derivative by a difference operator, which allows dealing with sets of nondifferentiable functions
3 New estimates for reverse Minkowski inequality by fractional quantum Hahn integral operator. This segment comprises our principal involvement of establishing the proof of the reverse Minkowski inequalities via fractional quantum Hahn integral operator defined in (1.11)
Summary
Quantum difference operators have played a crucial role in the development of quantum calculus due to their fertile application, see [1,2,3,4,5]. We consider the concept of Riemann–Liouville type of fractional derivative and integral of quantum Hahn calculus on an interval [μ, ν] which is proposed by [16]. Definition 1.4 ([16]) Suppose that a function h1 : [μ, ν] → R is said to be fractional quantum Hahn integral of Riemann–Liouville type of order 1 ≥ 0 if μ Iq,1ω h1. From (2.28), (2.30), and (2.31), we get our desired result This segment comprises our principal involvement of establishing the proof of the reverse Minkowski inequalities via fractional quantum Hahn integral operator defined in (1.11). This section is dedicated to deriving bounds for reverse Hölder inequalities regarding fractional quantum Hahn integral operator.
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