On the Controllability of Coupled Nonlocal Partial Integrodifferential Equations Using Fractional Power Operators
Abstract
:1. Introduction
2. Basic Concepts and Preliminaries
- ()
- for all ; if , then ;
- ()
- for all , and ;
- ()
- for all .
- (a)
- and for some constants and .
- (b)
- For each and , the function is continuous.
- (c)
- for . For any , such that for each , we have
- An analytic semigroup on is generated by the operator A. Let be a closed operator on , with a domain at least for almost every , with is strongly measurable for every and for with absolutely convergent for .
- There exists a bounded operator on , which is analytic for in the region defined as
- for , and is analytic from to . Furthermore, for belongs to , and Given there is so that and with and as in Additionally, for some and with Moreover, there is that is dense in such that and are contained in and is bounded for every and with
3. Controllability Results
- The operator resolvent is continuous in the uniform topology.
- The functions for satisfy the following:
- The functions are continuous for every , and the functions are measurable for every .
- There exist and functions , for such that for every and , we have
- For , there are functions such that, for any bounded set and every , we have
- The nonlocal functions and the function are both continuous and satisfy the following:
- For each there are positive constants and such that
- There exist such that for any bounded , , we have
- (i) The linear operators , are defined as follows
- There are positive constants and , satisfying
- There exist and such that for any bounded sets and ,
- Let us consider a subset such that
4. An Example
- The functions are continuous for ; there exists and functions such that for any
- The functions and satisfies for ; there exists some positive constant such that .
- The functions for and satisfy that, there exist such that, for and ,
- satisfies with , for , and moreover, if as .
- ()
- If then
- ()
- If and . Particularly, and
- ()
- The operator is defined as
- First, assumption ensures that the functions meet the hypothesis . In fact, by applying Lemma 7 and the Cauchy-Schwarz inequality, for , and we have
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Litimein, H.; Huang, Z.-Y.; Ouahab, A.; Stamova, I.; Souid, M.S. On the Controllability of Coupled Nonlocal Partial Integrodifferential Equations Using Fractional Power Operators. Fractal Fract. 2024, 8, 270. https://doi.org/10.3390/fractalfract8050270
Litimein H, Huang Z-Y, Ouahab A, Stamova I, Souid MS. On the Controllability of Coupled Nonlocal Partial Integrodifferential Equations Using Fractional Power Operators. Fractal and Fractional. 2024; 8(5):270. https://doi.org/10.3390/fractalfract8050270
Chicago/Turabian StyleLitimein, Hamida, Zhen-You Huang, Abdelghani Ouahab, Ivanka Stamova, and Mohammed Said Souid. 2024. "On the Controllability of Coupled Nonlocal Partial Integrodifferential Equations Using Fractional Power Operators" Fractal and Fractional 8, no. 5: 270. https://doi.org/10.3390/fractalfract8050270
APA StyleLitimein, H., Huang, Z. -Y., Ouahab, A., Stamova, I., & Souid, M. S. (2024). On the Controllability of Coupled Nonlocal Partial Integrodifferential Equations Using Fractional Power Operators. Fractal and Fractional, 8(5), 270. https://doi.org/10.3390/fractalfract8050270