Discontinuity, Nonlinearity, and Complexity
Application of the Six Functionals Fixed Point Theorem: Positivity for RL-type
Nonlinear FBVPs with $p$-Laplacian
Discontinuity, Nonlinearity, and Complexity 13(1) (2024) 83--94 | DOI:10.5890/DNC.2024.03.007
Boddu Muralee Bala Krushna$^{1}$, Kapula Rajendra Prasad$^{2}$
$^1$ Department of Mathematics, MVGR College of Engineering (Autonomous), Vizianagaram,
535 005, India
$^2$ Department of Applied Mathematics, Andhra University, Visakhapatnam, 530 003, India
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Abstract
We study a coupled system of RL--type nonlinear fractional-order boundary value problems with a $p$-Laplacian operator in this paper. Using two Kernels, the considered coupled system can be transformed into an integral system. Due to the increased applicability of SFFPT to non-linear problems, sufficient conditions for the existence of positive solutions to the proposed problem are derived. Our technique for accomplishing these results is straightforward, but its application in the current context problem is new.
References
-
[1]  |
Samko, S.G., Kilbas, A.A., and Marichev, O.I. (1993),
Fractional Integral and Derivatives: Theory and Applications,
Gordon and Breach, Longhorne, PA.
|
-
[2]  |
Podulbny, I. (1999),
Fractional Diffrential Equations, Academic Press, San Diego.
|
-
[3]  |
Kilbas, A.A., Srivasthava, H.M., and Trujillo, J.J. (2006),
Theory and Applications of Fractional Differential Equations,
North-Holland Mathematics Studies, 204, Elsevier Science, Amsterdam.
|
-
[4]  |
Sabatier, J., Agrawal, O.P., and Machado, J.A.T. (2007),
Advances in Fractional Calculus: Theoretical Developments and Applications in Physics and Engineering,
Springer, Dordrecht.
|
-
[5]  |
Goodrich, C. (2010),
Existence of a positive solution to a class of fractional differential equations,
Computers and Mathematics with Applications, 59, 3489-3499.
|
-
[6]  |
Prasad, K.R. and Krushna, B.M.B. (2013),
Multiple positive solutions for a coupled system of Riemann-Liouville fractional order two-point boundary value problems,
Nonlinear Studies, 20, 501-511.
|
-
[7]  |
Prasad, K.R. and Krushna, B.M.B. (2015),
Positive solutions to iterative systems of fractional order three-point boundary value problems
with Riemann-Liouville derivative,
Fractional Differential Calculus, 5, 137-150.
|
-
[8]  |
Baleanu, D., Ghassabzade, F.A., Nieto, J.J., and Jajarmi, A. (2022),
On a new and generalized fractional model for a real cholera outbreak,
Alexandria Engineering Journal, 61, 9175-9186.
|
-
[9]  |
Jajarmi, A., Baleanu, D., Zarghami, V.K., and Mobayen, S. (2022),
A general fractional formulation and tracking control for immunogenic tumor dynamics,
Mathematical Models and Methods in Applied Sciences, 45, 667-680.
|
-
[10]  |
Naik, P.A., Yavuz, M., Qureshi, S., Zu, J., and Townley, S. (2020),
Modeling and analysis of COVID-19 epidemics with treatment in fractional derivatives using real data from Pakistan,
The European Physical Journal Plus, 135, 1-42.
|
-
[11]  |
Yusuf, A., Qureshi, S., Mustapha, U.T., Musa, S.S., and Sulaiman, T.A. (2022),
Fractional modeling for improving scholastic performance of students with optimal control,
International Journal of Computational and Applied Mathematics, 8, 1-20.
|
-
[12]  |
Dineshkumar, C., Udhayakumar, R., Vijayakumar, V., Nisar, K.S., and Shukla, A. (2021),
A note on the approximate controllability of Sobolev type fractional stochastic
integro-differential delay inclusions with order $1< r< 2$,
Mathematics and Computers in Simulation, 190, 1003-1026.
|
-
[13]  |
Kavitha Williams, W., Vijayakumar, V., Udhayakumar, R., Panda, S.K., and Nisar, K.S. (2020),
Existence and controllability of nonlocal mixed Volterra-Fredholm type fractional delay integro-differential
equations of order $1< r< 2$,
Numerical Methods for Partial Differential Equations, 1-21.
|
-
[14]  |
Kavitha, K., Vijayakumar, V., Udhayakumar, R., and Ravichandran, C. (2021),
Results on controllability of Hilfer fractional differential equations with infinite delay via measures of noncompactness, Asian Journal of Control, 24(3), 1-10.
|
-
[15]  |
Nisar, K.S. and Vijayakumar, V. (2021),
Results concerning to approximate controllability of non-densely defined Sobolev-type Hilfer fractional neutral delay differential system,
Mathematical Methods in the Applied Sciences, 44(17), 13615-13632.
|
-
[16]  |
Vijayakumar, V., Panda, S.K., Nisar, K.S., and Baskonus, H.M. (2021),
Results on approximate controllability results for second-order Sobolev-type impulsive neutral differential evolution inclusions with infinite delay,
Numerical Methods for Partial Differential Equations, 37(2), 1200-1221.
|
-
[17]  |
Diening, L., Lindqvist, P., and Kawohl, B. (2013),
Mini-Workshop: The $p$-Laplacian Operator and Applications,
Oberwolfach Reports, 10, 433-482.
|
-
[18]  |
Henderson, J. and Luca, R. (2016),
Boundary Value Problems for Systems of Differential,
Difference and Fractional Equations, Positive solutions, Elsevier, Amsterdam.
|
-
[19]  |
Agarwal, R.P., O'Regan, D., and Wong, P.J.Y. (1999),
Positive Solutions of Differential,
Difference and Integral Equations, Kluwer Academic Publishers, Dordrecht, The Netherlands.
|
-
[20]  |
Bai, Z. and L\"u, H. (2005),
Positive solutions for boundary value problems of nonlinear fractional differential equations,
Journal of Mathematical Analysis and Applications, 311, 495-505.
|
-
[21]  |
Benchohra, M., Henderson, J., Ntoyuas, S.K., and Ouahab, A. (2008),
Existence results for fractional order functional differential equations with infinite delay,
Journal of Mathematical Analysis and Applications, 338, 1340-1350.
|
-
[22]  |
Bai, C. (2010),
Existence of positive solutions for boundary value problems of fractional functional differential equations,
Electronic Journal of Qualitative Theory of Differential Equations, 30, 1-14.
|
-
[23]  |
Kong, L. and Wang, J. (2000),
Multiple positive solutions for the one-dimensional $p$-Laplacian,
Nonlinear Analysis, 42, 1327-1333.
|
-
[24]  |
Avery, R.I. and Henderson, J. (2003),
Existence of three positive pseudo-symmetric solutions for a one-dimensional $p$-Laplacian,
Journal of Mathematical Analysis and Applications, 277, 395-404.
|
-
[25]  |
Yang, C. and Yan, J. (2010),
Positive solutions for third order Sturm-Liouville boundary value problems with $p$-Laplacian,
Computers and Mathematics with Applications, 59, 2059-2066.
|
-
[26]  |
Chai, G. (2012),
Positive solutions for boundary value problem of fractional differential equation with $p$-Laplacian operator,
Boundary Value Problems, 2012, 1-18.
|
-
[27]  |
Chen, T. and Liu, W. (2012),
An anti-periodic boundary value problem for the fractional differential equation with a $p$-Laplacian operator,
Applied Mathematics Letters, 25, 1671-1675.
|
-
[28]  |
Prasad, K.R. and Krushna, B.M.B. (2014),
Multiple positive solutions for a coupled system of $p$-Laplacian fractional order two-point boundary value problems,
International Journal of Difference Equations, 2014, 1-10.
|
-
[29]  |
Prasad, K.R. and Krushna, B.M.B. (2015),
Solvability of $p$-Laplacian fractional higher order two-point boundary value problems,
Communications in Applied Analysis, 19, 659-678.
|
-
[30]  |
Prasad, K.R. and Krushna, B.M.B. (2014),
Eigenvalues for iterative systems of Sturm-Liouville fractional order two-point boundary value problems,
Fractional Calculus and Applied Analysis, 17, 638-653.
|
-
[31]  |
Avery, R.I., Henderson, J. and O'Regan, D. (2008),
Six functionals fixed point theorem,
Journal of Mathematical Analysis and Applications, 12, 69-82.
|
-
[32]  |
Prasad, K.R., Murali, P. and Devi, K.L.S. (2011),
Multiple positive solutions for the Sturm-Liouville fractional order boundary value problem,
Panamerican Mathematical Journal, 21(1), 99-109.
|
-
[33]  |
Prasad, K.R. and Krushna, B.M.B. (2015),
Existence of multiple positive solutions for a coupled system of iterative type fractional order boundary value problems,
Journal of Nonlinear Functional Analysis, 2015, Article ID 11, 1-15.
|
-
[34]  |
Krushna, B.M.B. (2020),
Eigenvalues for iterative systems of Riemann-Liouville type $p$-Laplacian fractional-order
boundary-value problems in Banach spaces,
Computational and Applied Mathematics, 39, 1-15.
|