Nabla Fractional Derivative and Fractional Integral on Time Scales
Abstract
:1. Introduction
2. Motivation of the Article
3. Preliminaries and Auxiliary Results
- (i)
- If h is continuous at a left-scattered t, then h is nabla differentiable at t with
- (ii)
- If t is left dense, then h is nabla differentiable at t if and only if the limit
4. Nabla Fractional Derivative and Nabla Fractional Integral
- (i)
- If t is left dense and h is nabla differentiable of order μ at t, then h is continuous at t;
- (ii)
- If h is continuous at t and t is left scattered, then h is nabla differentiable at t of order μ with
- (iii)
- If t is left dense, then h is differentiable at t if and only if the limit
- (iv)
- If h is nabla differentiable of order μ at t, then
- (i)
- The sum is nabla differentiable at t of order μ,
- (ii)
- The product is nabla differentiable of order μ at t,
- (iii)
- If then is nabla differentiable at t of order μ,
- (iv)
- If , then is nabla differentiable at t of order μ,
- (i)
- If , then
- (ii)
- If , then
- (i)
- If , then from Theorem 5, we obtainBy using Theorem 5, we obtain the following results:
- (ii)
- If , then .
- (iii)
- If , then .
- (iv)
- If , then .
- (i)
- If we consider the real time scale , then all the elements of are dense. So, by using Theorem 3 (iii), we have that
- (ii)
- If , for one has and then . Now, by using Theorem 3 (ii), we obtainIf we have that , which is similar as the usual backward operator;
- (iii)
- Let , where . Then we obtainFor , we have from Theorem 1 thatFrom Definition 3, the second order nabla derivative isIn general, the derivative for and ,Since the binomial coefficient vanish when , so no contribution in the summation is given from the presence of terms with , the upper limit of the formula can be raised to any value greater than m and hence, the finite summation in this formula can be replaced with the infinite series, i.e.,Letting h tend to zero, then all points of the time scale become dense, and the time scale becomes the continuous time scale. If the value of m is replaced by an arbitrary real number , , and changing the factorial function with a Euler gamma function using the recurrence relation , then without losing the generality, if we replace m by any arbitrary real number , then the nabla fractional derivative, from Definition 3 and Theorem 3, isMoreover, once a starting point a assign as for , such thatSince for any continuous function Grünwald–Letnikov derivative and Riemann–Liouville derivative coincide with positive non integer order derivative, so we haveIf , then we haveLet us takeNow,Here, we obtain a condition (see [28]) that, if
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
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Gogoi, B.; Saha, U.K.; Hazarika, B.; Torres, D.F.M.; Ahmad, H. Nabla Fractional Derivative and Fractional Integral on Time Scales. Axioms 2021, 10, 317. https://doi.org/10.3390/axioms10040317
Gogoi B, Saha UK, Hazarika B, Torres DFM, Ahmad H. Nabla Fractional Derivative and Fractional Integral on Time Scales. Axioms. 2021; 10(4):317. https://doi.org/10.3390/axioms10040317
Chicago/Turabian StyleGogoi, Bikash, Utpal Kumar Saha, Bipan Hazarika, Delfim F. M. Torres, and Hijaz Ahmad. 2021. "Nabla Fractional Derivative and Fractional Integral on Time Scales" Axioms 10, no. 4: 317. https://doi.org/10.3390/axioms10040317
APA StyleGogoi, B., Saha, U. K., Hazarika, B., Torres, D. F. M., & Ahmad, H. (2021). Nabla Fractional Derivative and Fractional Integral on Time Scales. Axioms, 10(4), 317. https://doi.org/10.3390/axioms10040317