Home Common fixed point results under w-distance with applications to nonlinear integral equations and nonlinear fractional Differential Equations
Article
Licensed
Unlicensed Requires Authentication

Common fixed point results under w-distance with applications to nonlinear integral equations and nonlinear fractional Differential Equations

  • D. Ramesh Kumar
Published/Copyright: December 10, 2021
Become an author with De Gruyter Brill
Author Information Explore this Subject
Mathematica Slovaca
From the journal Mathematica Slovaca Volume 71 Issue 6

Abstract

In this article, we prove some new common fixed point results under the generalized contraction condition using w-distance and weak altering distance functions. Also, the validity of the results is demonstrated by an example along with numerical experiment for approximating the common fixed point. Later, as applications, the unique common solutions for the system of nonlinear Fredholm integral equations, nonlinear Volterra integral equations and nonlinear fractional differential equations of Caputo type are derived.

Keywords: common fixed point; w-distance; altering distance function; integral equation; fractional differential equation
MSC 2010: Primary 47H10; 54H25; Secondary 45B05; 34A08

  1. (Communicated by Alberto Lastra)

Acknowledgement

The author is thankful to the anonymous referees and the area editor for giving valuable comments and suggestions, which helped to improve the final version of this paper.

References

[1] Abd-Elhameed, W. M.—Youssri, Y. H.: Numerical solutions for Volterra FredholmHammerstein integral equations via second kind Chebyshev quadrature collocation algorithm, Adv. Math. Sci. Appl. 24 (2014), 129–141.Search in Google Scholar

[2] Alegre, C.—Marín, J.—Romaguera, S.: A fixed point theorem for generalized contractions involving w-distances on complete quasi-metric spaces, Fixed Point Theory Appl. 2014:40 (2014).10.1186/1687-1812-2014-40Search in Google Scholar

[3] Aydi, H.—Wongyat, T.—Sintunavarat, W.: On new evolution of Ri's result via w-distances and the study on the solution for nonlinear integral equations and fractional differential equations, Adv. Differ. Equ. 2018:132 (2018).10.1186/s13662-018-1590-2Search in Google Scholar

[4] Baleanu, D.—Rezapour, S.—Mohammadi, M.: Some existence results on nonlinear fractional differential equations, Philos. Trans. R. Soc. Lond. A 371 (2013), Art. 20120144.10.1098/rsta.2012.0144Search in Google Scholar PubMed

[5] Banach, S.: Sur les opérations dans les ensembles abstraits et leur application aux équations intégrales, Fund Math. 3 (1922), 133–181. 10.4064/fm-3-1-133-181Search in Google Scholar

[6] Choudhury, B. S.—Dutta, P. N.: A unified fixed point result in metric spaces involving a two variable function, Filomat 14 (2000), 43–48.Search in Google Scholar

[7] Choudhury, B. S.: A common unique fixed point result in metric spaces involving generalised altering distances, Math. Commun. 10(2) (2005), 105–110.Search in Google Scholar

[8] Choudhury, B. S.—Upadhyay, A.: On unique common fixed point for a sequence of multi-valued mappings on metric spaces, Bull. Pure Appl. Sci. Sect. E Math. Stat. 19(2) (2000), 529–533.Search in Google Scholar

[9] Doha, E. H.—Youssri, Y. H.—Zaky, M. A.: Spectral Solutions for Differential and Integral Equations with Varying Coefficients Using Classical Orthogonal Polynomials, Bull. Iran. Math. Soc. 45 (2019), 527–555.10.1007/s41980-018-0147-1Search in Google Scholar

[10] Dutta, P. N.—Choudhury, B. S.: A generalisation of contraction principle in metric spaces, Fixed Point Theory Appl. 2008:406368 (2008).10.1155/2008/406368Search in Google Scholar

[11] Kada, O.—Suzuki, T—Takahashi, W.: Nonconvex minimization theorems and fixed point theorems in complete metric spaces, Math. Jpn. 44 (1996) 381–391.Search in Google Scholar

[12] Khan, M. S.—Swaleh, M.—Sessa, S.: Fixed point theorems by altering distances between the points, Bull. Aust. Math. Soc. 30(1) (1984), 1–9.10.1017/S0004972700001659Search in Google Scholar

[13] Lakzian, H.—Aydi, H.—Rhoades, B. E.: Fixed points for (ψ, ϕ, p)-weakly contractive mappings in metric spaces with w-distance, Appl. Math. Comput. 219(12) (2013), 6777–6782.10.1016/j.amc.2012.11.025Search in Google Scholar

[14] Nadler Jr. N. B.: Multi-valued contraction mappings, Pacific J. Math. 30 (1969), 475–488.10.2140/pjm.1969.30.475Search in Google Scholar

[15] Salazar, L. A.—Reich, S.: A remark on weakly contractive mappings, J. Nonlinear Convex Anal. 16 (2015), 767–773.Search in Google Scholar

[16] Sang, Y.—Meng, Q.: Fixed point theorems with generalized altering distance functions in partially ordered metric spaces via w-distances and applications, Fixed Point Theory Appl. 2015:168 (2015).10.1186/s13663-015-0408-0Search in Google Scholar

[17] Sastry, K. P. R.—Naidu, S. V. R.—Babu, G. V. R.—Naidu, G. A.: Generalization of common fixed point theorems for weakly commuting map by altering distances, Tamkang J. Math. 31(3) (2000), 243–250.10.5556/j.tkjm.31.2000.399Search in Google Scholar

[18] Su, Y. F.: Contraction mapping principle with generalized altering distance function in ordered metric spaces and applications to ordinary differential equations, Fixed Point Theory Appl. 2014:227 (2014).10.1186/1687-1812-2014-227Search in Google Scholar

[19] Suzuki, T.—Takahashi, W.: Fixed point theorems and characterizations of metric completeness, Topol. Methods Nonlinear Anal. 8(2) (1996, 371–382.10.12775/TMNA.1996.040Search in Google Scholar

[20] Wongyat, T.—Sintunavarat, W.; The existence and uniqueness of the solution for nonlinear Fredholm and Volterra integral equations together with nonlinear fractional differential equations via w-distances, Adv. Difference Equ. 2017:211 (2017).10.1186/s13662-017-1267-2Search in Google Scholar

[21] Wongyat, T.—Sintunavarat, W.: On new existence and uniqueness results concerning solutions to nonlinear Fredholm integral equations via w-distances and weak altering distance functions, J. Fixed Point Theory Appl. 21:7 (2019).10.1007/s11784-018-0646-ySearch in Google Scholar

[22] Youssri, Y. H.—Hafez, R. M.: Chebyshev collocation treatment of VolterraFredholm integral equation with error analysis, Arab. J. Math. 9(2) (2020), 471–480.10.1007/s40065-019-0243-ySearch in Google Scholar

[23] Youssri, Y. H.—Hafez, R. M.: Spectral Legendre-Chebyshev Treatment of 2D Linear and Nonlinear Mixed Volterra-Fredholm Integral Equation, Math. Sci. Lett. 9(2) (2020), 37–47.10.1007/s40065-019-0243-ySearch in Google Scholar
Received: 2020-07-08
Accepted: 2021-02-17
Published Online: 2021-12-10
Published in Print: 2021-12-20

© 2021 Mathematical Institute Slovak Academy of Sciences

Articles in the same Issue

  1. Regular Papers
  2. Semidistributivity and Whitman Property in implication zroupoids
  3. Composition of binary quadratic forms over number fields
  4. On Z-Symmetric Rings
  5. On the factorable spaces of absolutely p-summable, null, convergent, and bounded sequences
  6. Coefficient estimates for Libera type bi-close-to-convex functions
  7. Oscillation of nonlinear third-order differential equations with several sublinear neutral terms
  8. On rapidly oscillating solutions of a nonlinear elliptic equation
  9. Multiplicity of solutions for a class of fourth-order elliptic equations of p(x)-Kirchhoff type
  10. Existence of traveling wave solutions in nonlocal delayed higher-dimensional lattice systems with quasi-monotone nonlinearities
  11. On absolute double summability methods with high indices
  12. On the continuity of lattice isomorphisms on C(X, I)
  13. New fixed point theorems for countably condensing maps with an application to functional integral inclusions
  14. Common fixed point results under w-distance with applications to nonlinear integral equations and nonlinear fractional Differential Equations
  15. The form of locally defined operators in waterman spaces
  16. Conformal vector fields on almost co-Kähler manifolds
  17. A certain η-parallelism on real hypersurfaces in a nonflat complex space form
  18. On log-bimodal alpha-power distributions with application to nickel contents and erosion data
  19. Univariate and bivariate extensions of the generalized exponential distributions
  20. Pellian equations of special type
https://doi.org/10.1515/ms-2021-0068
Keywords for this article
common fixed point; w-distance; altering distance function; integral equation; fractional differential equation

Articles in the same Issue

  1. Regular Papers
  2. Semidistributivity and Whitman Property in implication zroupoids
  3. Composition of binary quadratic forms over number fields
  4. On Z-Symmetric Rings
  5. On the factorable spaces of absolutely p-summable, null, convergent, and bounded sequences
  6. Coefficient estimates for Libera type bi-close-to-convex functions
  7. Oscillation of nonlinear third-order differential equations with several sublinear neutral terms
  8. On rapidly oscillating solutions of a nonlinear elliptic equation
  9. Multiplicity of solutions for a class of fourth-order elliptic equations of p(x)-Kirchhoff type
  10. Existence of traveling wave solutions in nonlocal delayed higher-dimensional lattice systems with quasi-monotone nonlinearities
  11. On absolute double summability methods with high indices
  12. On the continuity of lattice isomorphisms on C(X, I)
  13. New fixed point theorems for countably condensing maps with an application to functional integral inclusions
  14. Common fixed point results under w-distance with applications to nonlinear integral equations and nonlinear fractional Differential Equations
  15. The form of locally defined operators in waterman spaces
  16. Conformal vector fields on almost co-Kähler manifolds
  17. A certain η-parallelism on real hypersurfaces in a nonflat complex space form
  18. On log-bimodal alpha-power distributions with application to nickel contents and erosion data
  19. Univariate and bivariate extensions of the generalized exponential distributions
  20. Pellian equations of special type
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 29.10.2025 from https://www.degruyterbrill.com/document/doi/10.1515/ms-2021-0068/html
Scroll to top button