Description: The article deals with the methodological aspects of conceptually accounting substantiation of construction (configuration) of perspective system of radar intelligence of air space, which is carried out in the interests of ensuring the fulfillment of air defense tasks, as well as the system aspects of the study of the process of managing its functioning and structural dynamics in the conditions of dynamic change of air and signal crossing the situation. As a prospective radar intelligence system, it is proposed to use a multiposition radar system (BPRL), consisting of a network of distributed, territorially remote radar facilities. It is considered that the BSLRS should consist of receiving, transmitting and receiving and transmitting positions, coordinated by the central control point, communication, collection and processing of information on the air and signal-interference situation, which provides detection and tracking of both radiating and non-radiating aircraft. The need for adaptive control of parameters, structure and modes of operation of the SLBM is pointed out, as well as the fact that for the automation of adaptive control it is necessary to enter into the general control loop appropriate special software tools that allow to provide the implementation of adaptation methods at different hierarchical levels. Its main advantages are its high noise immunity and accuracy of tying and tracking of the trajectory of aircraft, as well as great informativeness and increased survivability. It is noted that the construction of interference-proof and territoriallydistributed radar systems requires the implementation of both new constructive technological solutions and the additional development of specific methods of processing the organization of information processing and control of the radar system with a complex consideration of uncertainty, the actions of the enemy and the influence of organized radio interference.
Keywords: radar intelligence system, multi-position radar system, control of structural dynamics, telecommunication and communication facilities, adaptation methods
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