Abstract
The Kuhn-Tucker theorem in nondifferential form is a well-known classical optimality criterion for a convex programming problems which is true for a convex problem in the case when a Kuhn-Tucker vector exists. It is natural to extract two features connected with the classical theorem. The first of them consists in its possible “impracticability” (the Kuhn-Tucker vector does not exist). The second feature is connected with possible “instability” of the classical theorem with respect to the errors in the initial data. The article deals with the so-called regularized Kuhn-Tucker theorem in nondifferential sequential form which contains its classical analogue. A proof of the regularized theorem is based on the dual regularization method. This theorem is an assertion without regularity assumptions in terms of minimizing sequences about possibility of approximation of the solution of the convex programming problem by minimizers of its regular Lagrangian, that are constructively generated by means of the dual regularization method. The major distinctive property of the regularized Kuhn-Tucker theorem consists that it is free from two lacks of its classical analogue specified above. The last circumstance opens possibilities of its application for solving various ill-posed problems of optimization, optimal control, inverse problems.
Highlights
We consider the convex programming problem (P)Note two fundamental features of the classicalKuhn-Tucker theorem in nondifferential form
The Kuhn-Tucker theorem in nondifferential form is a well-known classical optimality criterion for a convex programming problems which is true for a convex problem in the case when a Kuhn-Tucker vector exists
The second feature is connected with possible “instability” of the classical theorem with respect to the errors in the initial data
Summary
[4,5,6,7]). The first feature is that this theorem is far from being always “correct”. -called regularized Kuhn-Tucker theorem in nondifferential sequential form was proved for Problem (P) with strongly convex objective functional and with parameters in constraints in [7] This theorem is an assertion in terms of minimizing sequences A crucially important advantage of these approximations compared to classical optimal Kuhn-Tucker points (see Example 1.1.) is that the former are stable with respect to the errors in the initial data This stability makes it possible to effectively use the regularized Kuhn-Tucker theorem for practically solving a broad class of ill-posed problems in optimization and optimal control, operator equations of the first kind, and various inverse problems.
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