A Convolution Type Nonlinear Integro-Differential Equation with a Variable Coefficient and an Inhomogeneity in the Linear Part

		ISSN 1683-3414 (Print) • ISSN 1814-0807 (Online)

		Log in

Home Editorial board Publication ethics Peer review guidelines Latest issue All issues Rules for authors Online submission system’s guidelines Submit manuscript Contacts Address: Vatutina st. 53, Vladikavkaz, 362025, RNO-A, Russia Phone: (8672)23-00-54 E-mail: rio@smath.ru	Dear authors! Submission of all materials is carried out only electronically through Online Submission System in personal account. DOI: 10.46698/e6476-5914-8893-f A Convolution Type Nonlinear Integro-Differential Equation with a Variable Coefficient and an Inhomogeneity in the Linear Part Askhabov, S. N. Vladikavkaz Mathematical Journal 2020. Vol. 22. Issue 4. Abstract: We study a Volterra integro-differential equation of convolution type with a power nonlinearity, variable coefficient \(a(x)\) and an inhomogeneity \(f(x)\) in the linear part, which is closely related to the corresponding nonlinear integral equation, arising in the study of fluid infiltration from a cylindrical reservoir into an isotropic homogeneous porous medium, when describing the process of propagation of shock waves in gas-filled pipes, when solving the problem about heating a half-infinite body in a nonlinear heat-transfer process, in models of population genetics, and others. It is important to note that in relation to the above-mentioned and other applications, of special interest are continuous positive (for \(x > 0\)) solutions of the integral equation. Based on the obtained exact lower and upper a priori estimates for the solution of the integral equation, we construct a weighted complete metric space \(P_b\), invariant with respect to the nonlinear integral convolution operator generated by this equation, and, using the method of weighted metrics (an analogue of Belitsky's method), we prove the global existence theorem and the uniqueness of the solution of the nonlinear integro-differential equation under study both in the space \(P_b\) and in the whole class \(Q_0^1\) of continuously differentiable functions positive for \(x>0\). It is shown that the solution can be found in the \(P_b\) space by a successive approximation method of the Picard type. Estimates for the rate of convergence of the successive approximations to the exact solution in terms of the weight metric of the space \(P_b\) are derived. In particular, for \(f(x)=0\), this theorem implies that the corresponding homogeneous nonlinear integro-differential equation, in contrast to the linear case, has a nontrivial solution. Examples are also given to illustrate the results obtained. Keywords: integro-differential equation, power nonlinearity, variable coefficient, a priori estimates, successive approximation, weight metrics method Language: Russian Download the full text For citation: Askhabov, S. N. A Convolution Type Nonlinear Integro-Differential Equation with a Variable Coefficient and an Inhomogeneity in the Linear Part, Vladikavkaz Math. J., 2020, vol. 22, no. 4, pp.16-27 (in Russian). DOI 10.46698/e6476-5914-8893-f + References 1. Gakhov, F. D. and Cherskii, Yu. I. Uravneniya tipa svertki [Equations of Convolution Type], Moscow, Nauka, 1978, 296 p. (in Russian). 2. Prossdorf, S. Einige Klassen Singularer Gleichungen, Berlin, Akademie-Verlag, 1974, 369 p. 3. Askhabov, S. N. Nelineinye uravneniya tipa svertki [Nonlinear Equations of Convolution Type], Moscow, Fizmatlit, 2009, 304 p. (in Russian). 4. Brunner, H. Volterra Integral Equations: an Introduction to the Theory and Applications, Cambridge, Cambridge University Press, 2017, 387 p. DOI: 10.1017/9781316162491. 5. Askhabov, S. N., Karapetyants, N. K. and Yakubov, A. Ya. Integral Equations of Convolution Type with a Power Nonlinearity and their Systems, Soviet Mathematics Doklady, 1990, vol. 41, no. 2, pp. 323-327. 6. Askhabov, S. N. and Betilgiriev, M. A. A-Priori Estimates for the Solutions of a Class of Nonlinear Convolution Equations, Zeitschrift fur Analysis und ihre Anwendungen, 1991, vol. 10, no. 2, pp. 201-204. DOI: 10.4171/ZAA/442. 7. Kilbas, A. A. and Saigo, M. On Solution of Nonlinear Abel-Volterra Integral Equations, Journal of Mathematical Analysis and Applications, 1999, vol. 229, no. 1, pp. 41-60. DOI: 10.1006/jmaa.1998.6139. 8. Karapetiants, N. K., Kilbas, A. A., Saigo, M. and Samko, S. G. Upper and Lower Bounds for Solutions of Nonlinear Volterra Convolution Integral Equations with Power Nonlinearity, Journal of Integral Equations and Applications, 2001, vol. 12, no. 4, pp. 421-448. DOI: 10.1216/jiea/1020282237. 9. Okrasinski, W. Nonlinear Volterra Equations and Physical Applications, Extracta Mathematicae, 1989, vol. 4, no. 2, pp. 51-74. 10. Edwards, R. E. Functional Analysis: Theory and Applications, New York, Holt, Rinehart, and Winston, 1965, 1072 p. 11. Askhabov, S. N. Integro-Differential Equation of the Convolution Type with a Power Nonlinearity and Inhomogeneity in the Linear Part, Differential Equations, 2020, vol. 56, no. 6, pp. 775-784. DOI: 10.1134/S0012266120060105. 12. Okrasinski, W. On the Existence and Uniqueness of Nonnegative Solutions of a Certain Nonlinear Convolution Equation, Annales Polonici Mathematici, 1979, vol. 36, no. 1, pp. 61-72. ← Contents of issue


	\| Home \| Editorial board \| Publication ethics \| Peer review guidelines \| Latest issue \| All issues \| Rules for authors \| Online submission system’s guidelines \| Submit manuscript \|
	© 1999-2024 Южный математический институт