A method for solving the initial-boundary value problem for hyperbolic integro-differential systems with functional term

Anar T. Assanova; Sailaubay S. Zhumatov; Anar T. Assanova; Sailaubay S. Zhumatov

doi:10.3934/math.20251178

AIMS Mathematics

2025, Volume 10, Issue 11: 26803-26822. doi: 10.3934/math.20251178

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A method for solving the initial-boundary value problem for hyperbolic integro-differential systems with functional term

Institute of Mathematics and Mathematical Modeling, 28 Shevchenko Str., Almaty 050000/A26G7T5, Kazakhstan

Received: 18 September 2025 Revised: 04 November 2025 Accepted: 12 November 2025 Published: 19 November 2025
MSC : 35G16, 35L53, 35R10, 34B08

In this paper, we propose a method for solving initial-boundary value problems (IBVPs) for hyperbolic integro-differential systems (HIDSs) with functional terms. The equations under consideration involve derivatives with respect to a spatial variable with a generalized piecewise constant argument (GPCA), as well as integral operators acting on the time variable. For a qualitative analysis of such problems, we construct auxiliary problems for first-order integro-differential systems with distributed parameters and additional integral constraints. Using the parameterization of the Dzhumabaev method, the auxiliary problem is reduced to a family of parameterized integral problems. Under explicit invertibility conditions for certain matrices, we establish theorems on the existence and uniqueness of solutions for this family of problems. Furthermore, we develop a constructive iterative algorithm to obtain solutions to the auxiliary problem and prove its convergence. The results extend the theory of HIDEs and open up prospects for applications in models with discontinuities, impulse effects, and integral memory terms.
- hyperbolic integro-differential systems,
- initial-integral condition,
- parametrized integral-problems,
- distributed functions
Citation: Anar T. Assanova, Sailaubay S. Zhumatov. A method for solving the initial-boundary value problem for hyperbolic integro-differential systems with functional term[J]. AIMS Mathematics, 2025, 10(11): 26803-26822. doi: 10.3934/math.20251178

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Abstract

In this paper, we propose a method for solving initial-boundary value problems (IBVPs) for hyperbolic integro-differential systems (HIDSs) with functional terms. The equations under consideration involve derivatives with respect to a spatial variable with a generalized piecewise constant argument (GPCA), as well as integral operators acting on the time variable. For a qualitative analysis of such problems, we construct auxiliary problems for first-order integro-differential systems with distributed parameters and additional integral constraints. Using the parameterization of the Dzhumabaev method, the auxiliary problem is reduced to a family of parameterized integral problems. Under explicit invertibility conditions for certain matrices, we establish theorems on the existence and uniqueness of solutions for this family of problems. Furthermore, we develop a constructive iterative algorithm to obtain solutions to the auxiliary problem and prove its convergence. The results extend the theory of HIDEs and open up prospects for applications in models with discontinuities, impulse effects, and integral memory terms.

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