Novel results of Milne-type inequalities involving tempered fractional integrals

In this current research, we focus on the domain of tempered fractional integrals, establishing a novel identity that serves as the cornerstone of our study. This identity paves the way for the Milne-type inequalities, which are explored through the framework of diﬀerentiable convex mappings inclusive of tempered fractional integrals. The signiﬁcance of these mappings in the realm of fractional calculus is underscored by their ability to extend classical concepts into more complex, fractional dimensions. In addition, by using the Hölder inequality and power-mean inequality, we acquire some new Milne-type inequalities. Moreover, the practicality and theoretical relevance of our ﬁndings are further demonstrated through the application of speciﬁc cases derived from the theorems


Introduction and preliminaries
Nowadays many scientists are focusing on fractional calculus and studying the theory of inequalities.The studies of fractional calculus have become the most popular field of research in physics, engineering, and mathematics.Most of the well-known mathematicians like Euler, Fourier, Laplace, Lacroix, Leibnitz, Abel, etc., were attracted to fractional calculus.Recently, tremendous research has been done on fractional calculus.The researchers who have contributed directly and indirectly to the development of fractional calculus are N. H. Abel (1823-1826), J. Liouville (1832-1873), G. F. B. Riemann (1847), H. Holmgren (1865-1867), A. K. Grunwald (1867-1872), A. V. Letnikov (1868-1872), H. Laurent (1884), P. A. Nekrassov (1888), A. Kurg (1889), J. Hadamard (1892), O. Heaviside , G. H. Hardy and J. E. Littlewood (1917Littlewood ( -1928)), H. Weyl (1917), Buss (1929), P. Levy (1923), A. Marchaud (1927), H.T. Davis (1924Davis ( -1927)), Goldman (1949), K. Oldham and J. Spanier (1974), L. Debnath (1992), K. S. Miller and B. Ross (1993), R. Gorenflo and F. Mainardi (2000), I. Podlubny (2003), and many more.While integer orders provide models that are suitable for nature in classical analysis, fractional computation in which arbitrary orders are examined enables us to obtain more realistic approaches.Moreover, the application of arithmetic carried out in classical analysis is very important in fractional analysis in terms of obtaining more realistic results in the solution of many problems.More general results are obtained with different approaches and operators in fractional calculus.Fractional integral operators have provided solutions to integrals in many studies.In the literature, many integral operators such as Riemann-Liouville, Hadamard, Katugompola, and tempered differential integral operators are considered.The most widely used of them is the Riemann-Liouville integral.There is a lot of research on these integrals.Tempered fractional integral operators generalizing Riemann-Liouville integrals are given in papers [12,16].In the literature, the theory of inequalities is an important area of mathematics.There are a lot of studies on the well-known Hermite-Hadamard inequality.Many researchers have studied the Hermite-Hadamard-type and related inequalities such as trapezoid and midpoint type.Also, a lot of researchers focused on Simpson-, Newton-, and Milne-type inequalities and contributed to science.Many researchers have contributed to the refinement and generalization of these integral inequalities.Sarikaya et al. [19] established Hermite-Hadamard-type inequalities via Riemann-Liouville fractional integrals.Sarikaya and Yildirim acquired some new inequalities of Hermite-Hadamard and midpoint type with the help of the Riemann-Liouville fractional integrals via differentiable convex functions in [18].Khan et al. [1] established some new versions of Hermite-Hadamard-type inequalities for Riemann-Liouville and conformable fractional integrals.The authors of [15] proved several Simpson-type inequalities involving Riemann-Liouville fractional integrals and in the case of general convex functions.See references [5,21], and the references therein, for further information concerning Simpson-type inequalities and several properties of Riemann-Liouville fractional integrals as well as those of various fractional integral operators.In the paper [9], Djenaoui and Meftah proved several new estimates of Milne's quadrature rule for functions whose first derivative is s-convex.Budak et al. [6] acquired fractional versions of Milne-type inequalities by utilizing differentiable convex functions.Ali et al. [2] gave error bounds via one of the open Newton-Cotes formulas, namely Milne's formula for differentiable convex functions in fractional and classical calculus.Alomari and Liu [3] established error estimates for Milne's rule for mappings of bounded variation and for absolutely continuous mappings.
Before giving Milne-type inequalities, let us give the following preliminary information.Simpson-type inequalities are inequalities that are created from Simpson's rules: i. Simpson's quadrature formula (Simpson's 1/3 rule) is formulated as follows: ii. Simpson's second formula or Newton-Cotes quadrature formula (Simpson's 3/8 rule (cf.[8])) is formulated as follows: Formulae (1.1) and (1.2) are satisfied for any function F with a continuous fourth derivative on [η, μ].
The most popular Newton-Cotes quadrature involving three points is Simpson-type inequality and formulated as follows: Theorem 1 Let F : [η, μ] → R be a four times continuously differentiable function on (η, μ), and let F (4) ∞ = sup κ∈(η,μ) |F (4) (κ)| < ∞.Then, one has the following inequality: One of the classical closed-type quadrature rules is the Simpson 3/8 rule based on the Simpson 3/8 inequality as follows: |F (4) (κ)| < ∞, then one has the inequality In terms of Newton-Cotes formulas, Milne's formula, which is of open type, is parallel to Simpson's formula, which is of closed type, since they hold under the same conditions.Theorem 3 ([4]) Suppose that F : [η, μ] → R is a four times continuously differentiable mapping on (η, μ), and let Then, one has the inequality In this research, we will establish a fractional version of the left-hand side of (1.3) and will consider several new bounds by using various mapping classes.Recall that the gamma function, incomplete gamma function, λ-incomplete gamma function are respectively defined by Here, 0 < α < ∞ and λ ≥ 0.
We list some properties of the λ-incomplete gamma function as follows: Remark 1 ( [14]) For the real numbers α > 0, κ, λ ≥ 0, and η < μ, we readily have Recall also that the Riemann-Liouville integrals of order α > 0 are given by and . See [10,11] for details and unexplained subjects.Note that the Riemann-Liouville integrals become classical integrals when α = 1.
We shall now present the fundamental definitions and new notations of tempered fractional operators.
It can be said that the inequalities obtained with the help of tempered fractional integral operators generalize the inequalities established through the Riemann-Liouville integral operators.The descriptions of fractional integration with weak singular and exponential kernels were firstly reported in Buschman's earlier work [7].For more research on the different cases of tempered fractional integrals, see the books [13,17,20].In the paper [14], Mohammed et al. acquired several Hermite-Hadamard-type inequalities with the help of the tempered fractional integrals by employing convex functions, which cover the previously published results such as Riemann and Riemann-Liouville fractional integrals.
Inspired by the ongoing studies, we acquire the tempered fractional version of Milne's formula-type inequalities via differentiable convex mappings.The main advantage of these inequalities is that they can be converted into Riemann-Liouville fractional Milne-type inequalities for λ = 0.If we choose α = 1 in the inequalities, the result is reduced to classical Milne-type inequalities.The basic definitions of fractional calculus and other relevant research in this discipline are given in the above-mentioned references.We will prove an integral equality in Sect. 2 that is critical in establishing the primary results of the present paper.Furthermore, it will prove some Milne-type inequalities for the case of differentiable convex mappings, including tempered fractional integrals.By using the special cases of the established results, we will then present several important inequalities.In Sect.3, we will suggest several ideas about the inequalities of Milne via further directions of research.

Main results
In this section, we first obtain an identity by using tempered fractional integrals.Then, using this identity, we obtain new Milne-type inequalities with the help of tempered fractional integrals.

Theorem 4 If the assumptions of Lemma 1 hold and the function |F | is convex on [η, μ],
then we have the following corrected Euler-Maclaurin-type inequality: Here, Proof Let us take the modulus in Lemma 1.Then, we reality have It is assumed that |F | is convex.Thus, This finishes the proof of Theorem 4.
Remark 2 Let us consider λ = 0 in Theorem 4.Then, the following Milne-type inequality holds: which is given by Ali et al. [2,Theorem 1].
Remark 3 If we assign λ = 0 and α = 1 in Theorem 4, then we get the Milne-type inequality which is given by Ali et al. [2,Corollary 1].This inequality helps us find an error bound of Milne's rule.
Theorem 5 Suppose that the assumptions of Lemma 1 hold and the function Then, the following Milne-type inequality holds: , where 1 p + 1 q = 1 and Proof If we apply Hölder inequality in (2.9), then .
By using the convexity of |F | q , we readily get , which completes the proof of Theorem 5.
Remark 5 If we choose λ = 0 and α = 1 in Theorem 5, then we obtain the following Milnetype inequality: , which is presented by Ali et al. [2,Corollary 2].This inequality helps us find an error bound of Milne's rule.
This inequality helps us find an error bound of Milne's rule.

Summary and concluding remarks
In the current investigation, several new versions of Milne-type inequalities were presented with the help of the differentiable convex mappings by utilizing tempered fractional integrals.What is more, Milne-type inequalities were established by taking advantage of the convexity, as well as Hölder and the power mean inequalities.Also, previous and new results were presented by using special cases of the obtained theorems.
In future work, the ideas and techniques via our results related to Milne-type inequalities by tempered fractional integrals may open new ways for researchers in this field.Moreover, readers can generalize our results by utilizing a different convex function classes or another type of fractional integral operator.Moreover, one can obtain Milne-type inequalities by tempered fractional integrals for convex functions by utilizing quantum integrals.

Funding
There is no funding.