Abstract
Inequality theory provides a significant mechanism for managing symmetrical aspects in real-life circumstances. The renowned distinguishing feature of integral inequalities and fractional calculus has a solid possibility to regulate continuous issues with high proficiency. This manuscript contributes to a captivating association of fractional calculus, special functions and convex functions. The authors develop a novel approach for investigating a new class of convex functions which is known as an n-polynomial mathcal{P}-convex function. Meanwhile, considering two identities via generalized fractional integrals, provide several generalizations of the Hermite–Hadamard and Ostrowski type inequalities by employing the better approaches of Hölder and power-mean inequalities. By this new strategy, using the concept of n-polynomial mathcal{P}-convexity we can evaluate several other classes of n-polynomial harmonically convex, n-polynomial convex, classical harmonically convex and classical convex functions as particular cases. In order to investigate the efficiency and supremacy of the suggested scheme regarding the fractional calculus, special functions and n-polynomial mathcal{P}-convexity, we present two applications for the modified Bessel function and mathfrak{q}-digamma function. Finally, these outcomes can evaluate the possible symmetric roles of the criterion that express the real phenomena of the problem.
Highlights
Over the most recent couple of decades, fractional calculus [1,2,3,4,5,6,7,8,9,10,11,12,13,14] has been effectively utilized in modeling for a wide range of processes and systems in the field of engineering and applied sciences
By considering two identities for the generalized fractional integral operators, we proposed several novel generalizations for n-polynomial P-convex functions
We emphasized that all computed outcomes in the present investigation endured preserving for n-polynomial harmonically convex, n-polynomial convex, classical harmonically convex and classical convex functions that can be obtained by choosing P = –1 or 1 and θ = 1
Summary
Over the most recent couple of decades, fractional calculus [1,2,3,4,5,6,7,8,9,10,11,12,13,14] has been effectively utilized in modeling for a wide range of processes and systems in the field of engineering and applied sciences. We recall the Hermite–Hadamard inequality as follows: Let : I → R be a convex function.
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