THE FUNCTIONAL MODEL OF THE RESOURCE MANAGEMENT SUBSYSTEM OF THE COGNITIVE RADIO SYSTEM OF THE ROBOTIC COMPLEX

Abstract

The study is devoted to improving the efficiency of the functioning of robotic complexes
(RTCs) by increasing the conflict stability of their data transmission radio systems (RS). The presence
of a stable tendency to complicate the operating conditions of the RTK causes stricter requirements
for the characteristics of the RTK RS. Also, these increasing requirements are limited
by the need to function in conditions of a complex electronic conflict, which means the simultaneous
presence of antagonistic, coalition and indifferent conflicting electro-magnetic interactions.
In order to ensure the required conflict stability, it is proposed to endow the RTK RS with cognitive
abilities that will allow the adaptation of the RTK RS resources to dynamically changing conditions
of the functioning environment, including promising ones. The purpose of the work is to
develop a functional model of the resource management subsystem of the cognitive RS RTK, the
formalization of which will allow analyzing the relationship between the structure of the model 
and the properties of the simulated system. The functional model of the proposed subsystem for the management of telecommunication resources of the cognitive RS RTK is given. The proposed decomposition
of the general model allows us to consider the control algorithm of the subsystem
under consideration from a constructivist perspective. The proposed approach to the construction
of this algorithm is based on the theory of finite combinatorial Post processes, equivalent to other
well-known approaches to the formalization of algorithms. The choice of this model is justified and
consistent with the current approaches to the construction of knowledge bases proposed for use in
the developed subsystem. The hypothesis put forward about the potential conflict stability of the
RTK RS is confirmed by the example, as which the conflict with an information technology system
capable of carrying out targeted electromagnetic effects is considered. At the same time, consideration
of the complex concept of conflict stability is limited to the analysis of one of its key components
– electronic security. It is proposed to consider this conflict as an instance of a mass problem.
The unsolvability of the proposed mass prediction problem is proved by reducing to it the
well-known problem of stopping a deterministic Turing machine.