On the Convergence of the Approximate Solution to the Optimization Problem for Oscillatory Processes

• Published in: Қарағанды университетінің хабаршысы. Математика сериясы Vol. 119; no. 3; pp. 22 - 33
• Main Authors: Abdyldaeva, E.F., Kerimbekov, A., Yuldashev, T.K., Kamali, M.
• Format: Journal Article
• Language: English
• Published: Academician Ye.A. Buketov Karaganda University 30.09.2025
• Subjects: approximations of complete solution; minimal value of functional; non-linear optimization problem; optimal control; optimal process; resolvent approximation
• ISSN: 2518-7929; 2663-5011; 2663-5011
• DOI: 10.31489/2025m3/22-33

This article addresses the non-linear optimization problem of oscillatory processes governed by partial integro-differential equations involving a Fredholm integral operator. A distinctive feature of the problem is that both the objective functional and the functions describing external and boundary influences are non-linear with respect to the vector controls. The integro-differential equation describing the state of the oscillatory process includes Fredholm integral operator, which has a significant impact on the structure and properties of the solutions. The algorithm for constructing the complete solution to this problem, as well as the effect of the Fredholm integral operator on the solution of the corresponding boundary value problem, has been published in previous studies. This article is dedicated to the investigation of the convergence of approximate solutions to the exact solution of the considered non-linear optimization problem. The influence of the Fredholm integral operator on the convergence behavior of the approximations is examined. It is demonstrated that the presence of the integral operator necessitates the construction of three distinct types of approximations of the optimal process: “Resolvent” approximations, based on the resolvent of the kernel of the integral operator; Approximations by optimal controls, constructed through the approximation of control functions; Finite-dimensional approximations.