RU2662726C1 - Monitoring and measuring system for monitoring - Google Patents

Abstract

FIELD: radio engineering and communications.SUBSTANCE: invention relates to radio engineering and can be used in test-and-measurement systems to control technical condition of particular parts and the whole test-and-measurement system in general, as well as to analyze downloading of frequency bands, to determine the location of radio-frequency sources (RFS), to measure frequency and time parameters of radio signals and electrical intensity. In addition, control-and-measurement monitoring system has central control room of technical condition of means, included in control-and-measurement monitoring system, notably, central control room of technical condition is connected to the central point of radio monitoring through communication channels of the central control room (CCR), to each stationary monitoring point entering CCR, in the auxiliary command and measuring complex (CMC), and in each mobile monitoring post in addition control points of technical condition are entered, which interact with central control room of technical condition via antenna device of a stationary monitoring station or mobile monitoring station, depending on where they are located, by means of communication channels of CCR or the nearest control point of auxiliary CMCs.EFFECT: increase of reliability of radiomonitoring results due to increase of efficiency of elimination of technical malfunctions in monitoring and measuring monitoring system.10 cl, 15 dwg

Description

The invention relates to radio engineering and can be used in control and measuring systems (CIS) for monitoring the technical condition of individual parts and the entire CIS in general, as well as for analyzing the loading of frequency subbands, determining the location of radio emission sources (IRI), measuring frequency and time parameters radio signals and electric field strength.

A known method and device for determining the coordinates of radio sources, implemented in the patent of Russian Federation No. 2263328, IPC7 G01S 5/04, 10.27.2005.

The device contains N spatially separated receiving points, each of which is a phase interferometer, a control point, remotely controlling the receiving points via data transmission channels and determining the most probable location of IRI. The device provides the location of controlled IRI with a given accuracy.

The disadvantage of the analogue is the low reliability of the monitoring results due to the lack of the ability to control the technical condition of control points and spatially separated points of reception, which entails a decrease in the efficiency of eliminating technical malfunctions in the system, which reduces the accuracy of determining the parameters of objects.

Known control system of radio monitoring of VHF and UHF bands "Marten", implemented in RF patent No. 234014, IPC7 G01S5 / 04, 10.12.2008.

The device provides radio monitoring of the specified IRI in spatially remote areas (determining the location of the IRI and technical analysis of their signals) using a significant number of unattended monitoring posts, which significantly reduces the cost of its operation.

The disadvantage of this device is the reliability of the results of radio monitoring due to the lack of the ability to monitor the technical condition of the central control point, spatially spaced stationary posts of radio monitoring and additional spatially spaced control and measuring complexes of the control and measuring radio monitoring system, as a result of which there is no possibility of prompt elimination of technical malfunctions in system.

Closest to the technical nature of the claimed device is a control and measuring system of radio monitoring, implemented in RF patent No. 2459218 "Control and measuring system of radio monitoring", IPC G01S 5/0, 08/20/2012. The prototype device contains a central control center, including a central radio monitoring control center and K≥2 spatially separated stationary monitoring posts, N≥2 auxiliary spatially separated test and measurement complexes, each of which includes a control point and M≥3 spatially separated stationary monitoring posts, mobile monitoring posts located on mobile ground objects or ships, and radio monitoring posts on flight-lifting facilities (LPS), as well as the totality of controlled sources of radio emission, moreover, spatially separated stationary monitoring posts that are part of the central control center and auxiliary control and measuring complexes interact remotely through communication channels of the central control point, spatially separated stationary monitoring posts that are part of auxiliary control and measuring complexes interact remotely through control points of auxiliary control and measurement of the complexes which these monitoring posts are part of, the mobile monitoring posts and the radio monitoring posts on the LPS are remotely controlled via communication channels of the central control center or via the nearest control centers of auxiliary monitoring and measuring complexes.

This device provides a wide area of radio monitoring and potentially has a sufficiently high efficiency of radio monitoring.

However, the disadvantage of the prototype device is the relatively low reliability of the results of radio monitoring, due to the likely possibility of violations of the technical condition of the control and measuring system of radio monitoring, leading to distortion of the control results.

The purpose of the proposed technical solution is to increase the reliability of the results of radio monitoring by increasing the efficiency of eliminating technical malfunctions in the control and measuring monitoring system.

This goal is achieved by the fact that in the known control and measuring system of radio monitoring containing a central control center (CPU), including a central control center of radio monitoring (CPUR) and K≥2 spatially separated stationary monitoring posts, N≥2 auxiliary spatially separated control and monitoring measuring complexes (CFC), each of which includes a control point and M≥3 spatially separated stationary monitoring posts, mobile monitoring posts located on mobile x ground facilities or ships, and monitoring stations on flight-lifting equipment (LPS), as well as a set of controlled sources of radio emission, and the spatially separated stationary monitoring posts that are part of the CPU and auxiliary KIK interact remotely through the communication channels of the CPU, spatially spaced stationary monitoring posts that are part of the auxiliary CFCs interact remotely through control centers of the auxiliary CFCs, which include these monitoring posts Children, mobile monitoring posts and radio monitoring posts on the LPS are remotely controlled through the communication channels of the CPU or through the nearest control points of the auxiliary KIK, in addition to the central control center, the central technical condition control center (CPPC) of the funds included in the control and measurement monitoring system (KISM) is introduced, moreover, the central control center is connected with the central control center through the communication channels of the central control center, in the composition of each stationary monitoring post included in the central control center, in auxiliary KIK, and in each mobile monitoring post s technical state control points that interact with TSPUTS through antenna device monitoring or stationary mobile monitoring post post, depending on where they are located, by using communication channels CPU or subsidiary CICs nearest control station.

The central control center consists of a cascade-connected control and measuring device, an antenna device, a radio station, a radio modem and a firewall, the second input / output of which is connected to the first input / output of the network switch, the second, third and fourth inputs / outputs of which are connected to the inputs / outputs, respectively a radio monitoring data server, a first and second PC, the fifth input / output of the network switch being connected to the second input / output of the control and measuring device.

CPPCS consists of a cascade-connected communication antenna, radio station, radio modem and firewall, the second input / output of which is connected to the first input / output of the network switch, the second, third, fourth and fifth inputs / outputs of which are connected to the inputs / outputs of the data server technical condition of KISM, the first, second and third PC.

A stationary monitoring station consists of an antenna device, the first, second, third, fourth and fifth outputs of which are connected to the corresponding inputs of the control and measuring device, the first, second, third and fourth outputs of which are connected to the corresponding inputs of the antenna device, and the fifth output of which is connected to the first entrance of the control point is a technical condition. Moreover, the sixth output of the antenna device is connected to the second input of the control point of the technical condition, the first output of which is connected to the sixth input of the control and measuring device, and the second output is connected to the fifth input of the antenna device.

The antenna device of the stationary monitoring station consists of a two-beam direction-finding antenna, consisting of the first and second letters, thirty-two outputs of which are connected to thirty-two inputs of the first antenna switch, the first and second outputs of which are connected to the first and second input of the two-channel digital radio receiving device of the control and measuring device . The thirty-third input of the first antenna switch is connected to the first output of the two-channel digital radio receiving device of the control and measuring device. The antenna device also includes the first and second hearing aids antennas, the outputs of which are connected to the first and second inputs of the second antenna switch, the output of which is connected to the first input of the hearing aid radio receiving device of the control and measuring device. The third input of the second antenna switch is connected to the first output of the radio receiving device for auditory monitoring of the control and measuring device. The antenna device also includes a measuring antenna, the output of which is connected to the first input of a single-channel digital radio receiving device of the control and measuring device. The input of the measuring antenna is connected to the second output of the second PC control and measuring device. Also included is a communication antenna, the output of which is connected to the first input of the third antenna switch, the first output and second input of which are connected to the second input / output of the radio station of the control and measuring device. The second output and the third input of the third antenna switch are connected to the first input / output of the radio station control the technical condition.

The control and measuring device of the stationary monitoring station consists of a two-channel digital radio receiving device, the first and second inputs of which are connected to the first and second outputs of the first antenna switch of the antenna device. The first output of the two-channel digital radio receiver is connected to the third input of the first antenna switch of the antenna device, and the second output of the two-channel digital radio receiver is connected to the first input of the network switch. Moreover, the third input of the two-channel digital radio receiving device is connected to the output of the first adapter, the input of which is connected to the second output of the radio receiving hearing aid, the first input of which is connected to the output of the second antenna switch of the antenna device. The first output of the hearing aid radio receiver is connected to the third input of the second antenna switch of the antenna device. Moreover, the second input of the hearing aid radio receiver is connected to the first output of the second adapter, the second input / output of which is connected to the fourth input / output of the network switch, the second input / output of which is connected to the first PC. The third input / output of the network switch is connected to the fifth input / output of the network switch, the technical state control point. Moreover, the fifth input / output of the network switch is connected to the second input / output of a single-channel digital radio receiving device, the first input of which is connected to the output of the measuring antenna of the antenna device. The third input of a single-channel digital radio receiver is connected to the output of a highly stable reference generator. Moreover, the sixth input / output of the network switch is connected to the first input / output of the second PC, the second output of which is connected to the input of the measuring antenna of the antenna device. Also, the control and measuring device of the stationary monitoring station includes cascading-enabled firewall, radio modem and radio station, the second input / output of which is connected to the second input and the first output of the third antenna switch of the antenna device. Moreover, the first input / output of the firewall is connected to the seventh input / output of the network switch.

A mobile monitoring station consists of an antenna device, the first to ninth outputs of which are connected to the corresponding inputs of the control and measuring device, the first, second, third and fourth outputs of which are connected to the corresponding inputs of the antenna device. The fifth output of the control and measuring device is connected to the first input of the controller, the second input / output of which is connected to the first input / output of the camera. The first output of the controller is connected to the tenth input of the instrumentation. Moreover, the sixth output of the control and measuring device is connected to the first input of the control point of the technical condition, the first output of which is connected to the eleventh input of the control and measuring device. The tenth output of the antenna device is connected to the second input of the technical state control point, the second output of which is connected to the fifth input of the antenna device.

The antenna device of the mobile monitoring station consists of a two-way direction-finding antenna, consisting of the first and second letters, sixteen outputs of which are connected to sixteen inputs of the first antenna switch, the first and second outputs of which are connected to the first and second input of the two-channel digital radio receiving device of the control and measuring device. The seventeenth input of the first antenna switch is connected to the first output of the two-channel digital radio receiving device of the control and measuring device. The structure also includes an auditory monitoring antenna, the output of which is connected to the input of the radio-receiving device for auditory monitoring of the control-measuring device, a first non-directional antenna, the output of which is connected to the first input of a single-channel digital radio receiver of the monitoring and measuring device, and a second non-directional antenna, the output of which is connected to the first input the second antenna switch, the second output of which is connected to the input of the converter, the output of which is connected to the third input of a single-channel digital of radio monitoring and measuring devices. Moreover, the first output of the second antenna switch is connected to the second input of a single-channel digital radio receiver of the control and measuring device. The second input of the second antenna switch is connected to the first output of a single-channel digital radio receiver of the control and measuring device. The antenna device of the mobile monitoring station also includes an antenna of the global satellite positioning system, the output of which is connected to the fourth input of a single-channel digital radio receiver of the control and measuring device, the slewing-rotary device connected to the measuring antenna, the output of which is connected to the fifth input of a single-channel digital radio receiver of the control and measurement devices. Moreover, the input of the slewing ring device is connected to the third output of the second network switch. Also included is a communication antenna, the output of which is connected to the first input of the third antenna switch, the first output and the second input of which are connected to the second input / output of the radio station of the control and measuring device. The second output and the third input of the third antenna switch are connected to the first input / output of the radio station control the technical condition.

The control and measuring device of the mobile monitoring station consists of a two-channel digital radio receiving device, the first and second inputs of which are connected to the first and second outputs of the first antenna switch of the antenna device. The first output of the two-channel digital radio receiver is connected to the seventeenth input of the first antenna switch of the antenna device. Moreover, the third input / output of a two-channel digital radio receiver is connected to the first input / output of the first network switch, the second input / output of which is connected to the fifth input / output of the first PC, the first, second and third inputs of which are connected to the first, second and third output of the radio receiver auditory control, the first input of which is connected to the output of the antenna for auditory monitoring of the antenna device, also includes a mobile phone, the output of which is connected to the fourth input of the first PC, the second A PC, the output of which is connected to the seventh input of the first network switch, the third input / output of which is connected to the third input / output of the network switch, the technical state control point. The fourth input / output of the first network switch is connected to the first input / output of the second network switch. Moreover, the fifth input / output of the first network switch is connected to the input / output of the third PC. The sixth input / output of the first network switch is connected to the sixth input / output of a single-channel digital radio receiver, the first input of which is connected to the output of the first non-directional antenna of the antenna device. The first output of a single-channel digital radio is connected to the second input of the second antenna switch of the antenna device. The second input of a single-channel digital radio is connected to the first output of the second antenna switch antenna device. Moreover, the third, fourth and fifth inputs of a single-channel digital radio are connected to the outputs of the converter, antenna of the global satellite positioning system and measuring antenna of the antenna device, respectively. Also, the control and measuring device of the mobile monitoring station includes cascade-connected firewall, radio modem and radio station, the second input / output of which is connected to the second output and third input of the third antenna switch of the antenna device. Moreover, the first input / output of the firewall is connected to the second input / output of the second network switch, the third output of which is connected to the input of the rotary device of the antenna device. The third input and fourth output of the second network switch are connected to the first input / output of the controller.

The control point for the technical condition of the stationary monitoring post consists of cascade-switched radio stations, a radio modem and a firewall, the second input / output of which is connected to the first input / output of the network switch, the second, third and fourth inputs / outputs of which are connected to the inputs / outputs of the first, second PC and technical data server. Moreover, the first input of the radio station is connected to the second output of the third antenna switch of the antenna device. The first output of the radio station is connected to the third input of the third antenna switch of the antenna device. Moreover, the fifth input / output of the network switch is connected to the third input / output of the network switch of the measuring device.

The control point for the technical condition of the mobile monitoring station consists of cascade-switched radio stations, a radio modem and a firewall, the second input / output of which is connected to the first input / output of the network switch, the second input / output of which is connected to the input / output of the PC. Moreover, the first input of the radio station is connected to the second output of the third antenna switch of the antenna device. The first output of the radio station is connected to the third input of the third antenna switch of the antenna device. Moreover, the third input / output of the network switch is connected to the third input / output of the first network switch of the measuring device.

Thanks to a new set of essential features, the claimed device provides for the prompt elimination of technical malfunctions in the monitoring and control monitoring system, as a result of which the reliability of the results of radio monitoring increases.

The inventive instrumentation monitoring system is illustrated by drawings, which depict the following:

in FIG. 1 - spatial distribution of elements of a control and measuring monitoring system;

in FIG. 2 is a structural diagram of a central monitoring center for radio monitoring;

in FIG. 3 is a block diagram of a central technical condition management center;

in FIG. 4 is a structural diagram of a stationary monitoring post;

in FIG. 5 is a structural diagram of an antenna device of a stationary monitoring post;

in FIG. 6 is a structural diagram of a control and measuring device of a stationary monitoring post;

in FIG. 7 is a structural diagram of a mobile monitoring post;

in FIG. 8 is a structural diagram of an antenna device of a mobile monitoring station;

in FIG. 9 is a structural diagram of a control and measuring device of a mobile monitoring station;

in FIG. 10 is a structural diagram of a control station for a technical condition of a stationary monitoring post;

in FIG. 11 is a structural diagram of a control point for a technical condition of a mobile monitoring post;

in FIG. 12 is a structural diagram of an automated control system for a monitoring and control monitoring system;

in FIG. 13 is an algorithm for the operation of an automated control system for a monitoring and control monitoring system when performing radio monitoring tasks;

in FIG. 14 - the functioning algorithm of an automated control system for a control and measuring monitoring system when performing monitoring tasks for the technical condition of the system;

in FIG. 15 is a graph of the relationship between the uptime indicator and the time that an unwanted incident is detected and the time that an unwanted incident is resolved.

The declared KISM (see Fig. 1) consists of a CPU (1), N≥2 auxiliary spatially separated KIK (3 ₁ , 3 ₂ , ..., 3 _N ), mobile monitoring posts (4) located on mobile ground or ships, LPS radio monitoring posts (5), as well as a set of controlled sources of radio emission (6). CPU (1) consists of CPUR (1.1) and CPPCS (1.2), also CPU (1) has a control zone (7) in which K≥2 spatially separated stationary monitoring posts are located (2 ₁ , 2 ₂ , ..., 2 _K ). Auxiliary spatially separated CFCs (3 ₁ , 3 ₂ , ..., 3 _N ) have control zones (7) and consist of a control point (3a) and M≥3 spatially separated stationary monitoring posts (2 ₁ , 2 ₂ , ..., 2 _M ). Moreover, the TsPUR (1.1) and TsPUTS (1.2) are connected through the communication channels of the CPU (1), and spatially separated stationary monitoring posts located in the control zone (7) of the CPU (1) interact remotely through communication channels with the CPU (1). Spaced-apart stationary monitoring posts that are part of the auxiliary CFCs (3) interact remotely through communication channels with the control centers (3a) of the auxiliary CFCs (3), which these monitoring posts are part of, and the control points (3a) of the auxiliary CFCs ( 3) in turn, interact remotely through communication channels with the CPU (1). Mobile monitoring posts (4) and radio monitoring posts on the LPS (5) are controlled remotely through the communication channels of the CPU (1) or through the nearest control points (3a) of the auxiliary KIK (3). Also, in each stationary monitoring post (2), which is part of the CPU (1), in the auxiliary CFCs (3), and in each mobile monitoring post (4), there are additionally introduced technical state control points that interact with the central control center (1.2) through the antenna the device of a stationary monitoring post (2) or a mobile monitoring post (4), depending on where they are, using the communication channels of the CPU (1) or the nearest control point (3a) of the auxiliary KIK (3).

The connection between the CPU (1), control centers (3a) of the auxiliary KIK (3) and spatially separated stationary monitoring posts can be organized by fiber optics, radio-relay communication channels 400-450. MHz, radio communications 140-170 MHz, GSM, Internet, etc. The most common principle is the organization of radio communications of the "star" type.

DSPC (1.1) is intended for receiving and converting received signals, processing received information and storing the results of radio monitoring, its circuit can be implemented in various ways, in particular, as shown in FIG. 2, and consists of a cascade-connected control and measuring device (1.1.2) and an antenna device (1.1.1) implemented in the Bars-MPI3 product (http://www.stc-spb.ru/produkcia/stacionarnye -kompleksy / bars-mpi-3 / sostav), a radio station (1.1.3), a radio modem (1.1.4) and a firewall (1.1.5), the second input / output of which is connected to the first input / output of the network switch (1.1. 6), the second, third and fourth inputs / outputs of which are connected to the inputs / outputs of the radio monitoring data server (1.1.7), first (1.1.8) and second (1.1.9) PC, respectively. Moreover, the fifth input / output of the network switch (1.1.6) is connected to the second input / output of the control and measuring device (1.1.2). The antenna device (1.1.1) is designed to receive signals, the structure of one of the device variants is shown in FIG. 5. The control and measuring device (1.1.2) is designed to convert the received signals and process the received information, the structure of one of the device variants is shown in FIG. 6.

CPPCS (1.2) is designed to identify, prevent and submit a control command to eliminate violations of the technical state of the KISM, its scheme can be implemented in various ways, in particular, as shown in FIG. 3, and consists of a cascade-connected communication antenna (1.2.1), a radio station (1.2.2), a radio modem (1.2.3) and a firewall (1.2.4), the second input / output of which is connected to the first input / output of the network switch (1.2.5), the second, third, fourth and fifth inputs / outputs of which are connected to the inputs / outputs of the data server on the technical state of the KISM (1.2.6), the first (1.2.7), the second (1.2.8) and third (1.2.9) PC. As the communication antenna (1.2.1), any VHF antenna can be used.

The radio stations (1.1.3, 1.2.2) included in the central control system (1.1) and central control system (1.2), designed to receive / transmit signals, and radio modems (1.1.4, 1.2.3), designed to transmit digital data over the air, are known , developed and manufactured by Scientific Research Institute "NTT", St. Petersburg. Firewalls (1.1.5, 1.2.4) are designed to protect network segments or individual KISM hosts from unauthorized access using vulnerabilities in the OSI network model protocols or in software installed on the KISM PC and are software or hardware-software elements KISM. A Cisco ASA 5506-X appliance can be used (http://www.cisco.com/c/m_en/products/security/asa-firepower-services/index.html?stickynav=1). Network switches (1.1.6, 1.2.5), are designed to connect several nodes of the KISM network. A Cisco Catalyst 3560-CX device can be used (http://www.cisco.com/c/en/us/products/switches/catalyst-3560-cx-series-switches/index.html). The radio monitoring data server (1.1.7) CPMS (1.1) and the KISM technical status data server (1.2.6) CPUTS (1.2) are designed to accumulate and store information about the results of radio monitoring and the KISM technical condition, respectively. A dedicated PC with functional software can be used as a server.

The stationary monitoring post (2) is intended for receiving and converting received signals, processing the received information, monitoring the technical condition of the KISM elements, transmitting the results of radio monitoring and monitoring the technical condition of the KISM elements through communication channels to the CPU (1) directly or through control points (3a ) auxiliary KIK (3), depending on what it belongs to, and elimination of violations in the technical state of KISM, its scheme can be implemented in various ways or similarly to a patent RF №2459218 "Control and measuring radio monitoring system", IPC G01S 5/0, 20.08.2012 with the addition in particular (2.3) of the technical state of the control, as shown in FIG. 4. The stationary monitoring station (2) consists of an antenna device (2.1), the first, second, third, fourth and fifth outputs of which are connected to the corresponding inputs of the control and measuring device (2.2), the first, second, third and fourth outputs of which are connected to corresponding inputs of the antenna device (2.1). The fifth output of the control and measuring device (2.2) is connected to the first input of the technical state control center (2.3). Moreover, the sixth output of the antenna device (2.1) is connected to the second input of the control point of the technical condition (2.3), the first output of which is connected to the sixth input of the control and measuring device (2.2), and the second output is connected to the fifth input of the antenna device (2.1).

The antenna device (2.1) of the stationary monitoring station (2) is designed to receive signals and transmit the results of radio monitoring and monitoring the technical condition of the KISM elements through communication channels, its circuit can be implemented in various ways or similarly to RF patent No. 2459218 "Control and measuring radio monitoring system" , IPC G01S 5/0, 08/20/2012, but with the addition of a third antenna switch (2.1.9) designed to connect a communication antenna (2.1.8) to a monitoring and measuring device (2.2) of a stationary monitoring station Inga (2) and the technical condition control center (2.3) of the stationary monitoring station (2) at the same time, in particular, as shown in FIG. 5. Antenna device (2.1) consists of a two-way direction-finding antenna, consisting of the first (2.1.1) and second (2.1.2) letters, which are placed in two tiers, the antenna elements of which are arranged in a circle, thirty-two outputs of which are connected to thirty two inputs of the first antenna switch (2.1.3), the first and second outputs of which are connected to the first and second input of the two-channel digital radio receiver (2.2.1) of the control and measuring device (2.2). The thirty-third input of the first antenna switch (2.1.3) is connected to the first output of the two-channel digital radio receiver (2.2.1) of the control and measuring device (2.2). Also, the antenna device (2.1) includes the first (2.1.4) and second (2.1.5) auditory control antennas, the outputs of which are connected to the first and second input of the second antenna switch (2.1.6), the output of which is connected to the first input of the radio receiver auditory control devices (2.2.5) of the control and measuring device (2.2). The third input of the second antenna switch (2.1.6) is connected to the first output of the radio-receiving device for auditory control (2.2.5) of the control and measuring device (2.2). The measuring antenna (2.1.7), which is part of the antenna device (2.1), has an output which is connected to the first input of a single-channel digital radio receiver (2.2.7) of the control and measuring device (2.2). The input of the measuring antenna (2.1.7) is connected to the second output of the second PC (2.2.8) of the control and measuring device (2.2). Also, the antenna device (2.1) includes a communication antenna (2.1.8), the output of which is connected to the first input of the third antenna switch (2.1.9), the first output and the second input of which are connected to the second input / output of the radio station (2.2.12) control and measuring device (2.2), and the second output and the third input of the third antenna switch (2.1.9) are connected to the first input / output of the radio station (2.3.1) of the technical state control center (2.3).

The control device (2.2) of the stationary monitoring station (2) is designed to convert the received signals, process the received information about radio monitoring, its circuit can be implemented in various ways, in particular, as shown in FIG. 6 or may be taken from the commercially available stationary product "Bars-MPI2" of various modifications. This product has been examined by the Federal Agency for Technical Regulation and Metrology (RU. P.35.002.A No. 38992) and is registered in the State Register of Measuring Instruments under No. 43662-10 and approved for use in the Russian Federation. The product is manufactured by Special Technological Center LLC, St. Petersburg. The stationary Bars-MPI2 complex is designed to analyze the loading of frequency sub-bands, direction finding of sources of VHF-microwave radiation, measuring the frequency and time parameters of radio signals, as well as the electric field strength of a linearly polarized wave. The control and measuring device (2.2) consists of a two-channel digital radio receiver (2.2.1), the first and second inputs of which are connected to the first and second outputs of the first antenna switch (2.1.3) of the antenna device (2.1). The first output of the two-channel digital radio receiver (2.2.1) is connected to the third input of the first antenna switch (2.1.3) of the antenna device (2.1), and the second output of the two-channel digital radio receiver (2.2.1) is connected to the first input of the network switch (2.2. 3). Moreover, the third input of the two-channel digital radio receiver (2.2.1) is connected to the output of the first adapter (2.2.2), the input of which is connected to the second output of the radio receiver of the auditory control (2.2.5), the first input of which is connected to the output of the second antenna switch (2.1 .6) antenna device (2.1). The first output of the hearing aid radio receiver (2.2.5) is connected to the third input of the second antenna switch (2.1.6) of the antenna device (2.1). Moreover, the second input of the hearing aid radio receiver (2.2.5) is connected to the first output of the second adapter (2.2.6), the second input / output of which is connected to the fourth input / output of the network switch (2.2.3), the second input / output of which is connected to first PC (2.2.4). The third input / output of the network switch (2.2.3) is connected to the fifth input / output of the network switch (2.3.4) the technical state control point (2.3). Moreover, the fifth input / output of the network switch (2.2.3) is connected to the second input / output of a single-channel digital radio receiver (2.2.7), the first input of which is connected to the output of the measuring antenna (2.1.7) of the antenna device (2.1). The third input of a single-channel digital radio receiver (2.2.7) is connected to the output of a highly stable reference oscillator (2.2.9). Moreover, the sixth input / output of the network switch (2.2.3) is connected to the first input / output of the second PC (2.2.8), the second output of which is connected to the input of the measuring antenna (2.1.7) of the antenna device (2.1). The control and measuring device (2.2) also includes a cascade-enabled firewall (2.2.10) designed to protect the segments of the monitoring and measuring device (2.2) from unauthorized access using vulnerabilities in the protocols of the OSI network model or in software, installed on the PC of the control and measuring device (2.2), and is a software or hardware-software element, the Cisco ASA 5506-X device can be used (http://www.cisco.com/c/ru_ru/products/security/asa -firepower-services / index.html? stickynav = 1) , a radio modem (2.2.11) and a radio station (2.2.12), the second input / output of which is connected to the second input and the first output of the third antenna switch (2.1.9) of the antenna device (2.1). Moreover, the first input / output of the firewall (2.2.10) is connected to the seventh input / output of the network switch (2.2.3).

The mobile monitoring post (4) is designed to expand the radio monitoring zone, as well as receiving and converting received signals, processing the received information, monitoring the technical state of the KISM elements, transmitting the results of radio monitoring and monitoring the technical state of the KISM elements through communication channels to the CPU (1) directly or through the control points (3a) of the auxiliary KIK (3), depending on what it belongs to, and elimination of violations in the technical state of the KISM, its scheme can be implemented by personal way or analogously RF patent №2459218 "Control and measuring radio monitoring system", IPC G01S 5/0, 20.08.2012 with the addition of the technical state of the control points (4.3), in particular, as shown in FIG. 7. The mobile monitoring station (4) consists of an antenna device (4.1), the first to ninth outputs of which are connected to the corresponding inputs of the control and measuring device (4.2), the first, second, third and fourth outputs of which are connected to the corresponding inputs of the antenna device (4.1) ) The fifth output of the control device (4.2) is connected to the first input of the controller (4.4), the second input / output of which is connected to the first input / output of the camera (4.5), and the first output of the controller (4.4) is connected to the tenth input of the control device ( 4.2). Moreover, the sixth output of the control and measuring device (4.2) is connected to the first input of the control point of the technical condition (4.3), the first output of which is connected to the eleventh input of the control and measuring device (4.2). The tenth output of the antenna device (4.1) is connected to the second input of the technical state control center (4.3), the second output of which is connected to the fifth input of the antenna device (4.1).

The antenna device (4.1) of the mobile monitoring station (4) is designed to receive signals and transmit the results of radio monitoring and monitoring the technical state of the KISM elements through communication channels, its circuit can be implemented in various ways or similarly to RF patent No. 2459218 "Control and measuring radio monitoring system" , IPC G01S 5/0, 08/20/2012, but with the addition of a third antenna switch (4.1.13), designed to connect a communication antenna (4.1.12) to the control and measuring device (4.2) of the mobile monitoring station ( 4) and the technical condition control center (4.3) of the mobile monitoring station (4) at the same time, in particular, as shown in FIG. 8. The antenna device (4.1) consists of a two-letter direction-finding antenna, consisting of the first (4.1.1) and second (4.1.2) letters, which are placed in two tiers, the antenna elements of which are arranged in a circle, sixteen outputs of which are connected to sixteen inputs the first antenna switch (4.1.3), the first and second outputs of which are connected to the first and second input of the two-channel digital radio receiver (4.2.1) of the control and measuring device (4.2). The seventeenth input of the first antenna switch (4.1.3) is connected to the first output of the two-channel digital radio receiver (4.2.1) of the control and measuring device (4.2). The antenna device (4.1) also includes an auditory monitoring antenna (4.1.4), the output of which is connected to the input of a radio-receiving device for auditory monitoring (4.2.5) of a control and measuring device (4.2), the first non-directional antenna (4.1.5), the output of which is connected to the first input of a single-channel digital radio (4.2.11) of the control and measuring device (4.2), the second non-directional antenna (4.1.6), the output of which is connected to the first input of the second antenna switch (4.1.7), the second output of which is connected to the input of the converter (4.1.8), exit for which it is connected to the third input of a single-channel digital radio (4.2.11) of the control and measuring device (4.2). Moreover, the first output of the second antenna switch (4.1.7) is connected to the second input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2). The second input of the second antenna switch (4.1.7) is connected to the first output of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2). The antenna of the global satellite positioning system (4.1.9), which is part of the antenna device (4.1), has an output connected to the fourth input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2). The antenna device (4.1) also includes a slewing ring device (4.1.11) connected to a measuring antenna (4.1.10), the output of which is connected to the fifth input of a single-channel digital radio receiver (4.2.11) of the measuring and measuring device (4.2) . Moreover, the input of the slewing ring (4.1.11) is connected to the third output of the second network switch (4.2.7), and the communication antenna (4.1.12), the output of which is connected to the first input of the third antenna switch (4.1.13), is the first output and the second input of which is connected to the second input / output of the radio station (4.2.10) of the control and measuring device (4.2). The second output and the third input of the third antenna switch (4.1.13) are connected to the first input / output of the radio station (4.3.1), the technical state control center (4.3).

The control and measuring device (4.2) of the mobile monitoring station (4) is intended for receiving and converting received signals, processing the received information, determining the location and orientation of the vehicle of the mobile monitoring station (4), its circuit can be implemented in various ways, in particular, as shown in FIG. 6 or may be taken from a commercially available stationary product Bars-MPI2 of various modifications, in particular, as shown in FIG. 9. The control and measuring device (4.2) consists of a two-channel digital radio receiver (4.2.1), the first and second inputs of which are connected to the first and second outputs of the first antenna switch (4.1.3) of the antenna device (4.1), the first output of the two-channel digital the radio receiving device (4.2.1) is connected to the seventeenth input of the first antenna switch (4.1.3) of the antenna device (4.1). Moreover, the third input / output of the two-channel digital radio receiver (4.2.1) is connected to the first input / output of the first network switch (4.2.2), the second input / output of which is connected to the fifth input / output of the first PC (4.2.3), the first one the second and third inputs of which are connected to the first, second and third output of the radio-receiving device for auditory control (4.2.5), the first input of which is connected to the output of the antenna for auditory monitoring (4.1.4) of the antenna device (4.1). The control and measuring device (4.2) also includes a mobile phone (4.2.4), the output of which is connected to the fourth input of the first PC (4.2.3), and the second PC (4.2.6), the output of which is connected to the seventh input of the first network switch (4.2.2), the third input / output of which is connected to the third input / output of the network switch (4.3.4), the state control point (4.3). The fourth input / output of the first network switch (4.2.2) is connected to the first input / output of the second network switch (4.2.7). Moreover, the fifth input / output of the first network switch (4.2.2) is connected to the input / output of the third PC (4.2.12). The sixth input / output of the first network switch (4.2.2) is connected to the sixth input / output of a single-channel digital radio receiver (4.2.11), the first input of which is connected to the output of the first non-directional antenna (4.1.5) of the antenna device (4.1). The first output of a single-channel digital radio (4.2.11) is connected to the second input of the second antenna switch (4.1.7) of the antenna device (4.1). The second input of a single-channel digital radio (4.2.11) is connected to the first output of the second antenna switch (4.1.7) of the antenna device (4.1). Moreover, the third, fourth and fifth inputs of a single-channel digital radio receiver (4.2.11) are connected to the outputs of the converter (4.1.8), the antenna of the global satellite positioning system (4.1.9) and the measuring antenna (4.1.10) of the antenna device (4.1), respectively. The control device (4.2) also includes a cascade-connected firewall (4.2.8) designed to protect the segments of the control device (4.2) from unauthorized access using vulnerabilities in the protocols of the OSI network model or in software installed on the PC of the control and measuring device (4.2), and is a software or hardware-software element, the Cisco ASA 5506-X device can be used (http://www.cisco.com/c/ru_ru/products/security/ asa-firepower-services / index.html? stickyna v = 1), a radio modem (4.2.9) and a radio station (4.2.10), the second input / output of which is connected to the second output and the third input of the third antenna switch (4.1.13) of the antenna device (4.1). Moreover, the first input / output of the firewall (4.2.8) is connected to the second input / output of the second network switch (4.2.7), the third output of which is connected to the input of the slewing device (4.1.11) of the antenna device (4.1). The third input and fourth output of the second network switch (4.2.7) are connected to the first input / output of the controller (4.4).

The control point for the technical condition (2.3) of the stationary monitoring post (2) is designed to monitor the technical condition of the radio monitoring means and the information received through the communication channels, and to prevent technical malfunctions of the radio monitoring means and unauthorized influences on the transmitted information through the communication channels, its scheme can be implemented in various ways, in particular as shown in FIG. 10. The control point for the technical condition (2.3) consists of cascading radio stations (2.3.1), a radio modem (2.3.2) and a firewall (2.3.3), the second input / output of which is connected to the first input / output of the network switch ( 2.3.4), the second, third and fourth inputs / outputs of which are connected to the inputs / outputs of the first (2.3.5), second (2.3.6) PC and the technical state data server (2.3.7), intended for accumulation and storing information on the technical condition of a stationary monitoring post (2). A dedicated PC with functional software can be used as a server. Moreover, the first input of the radio station (2.3.1) is connected to the second output of the third antenna switch (2.1.9) of the antenna device (2.1). The first output of the radio station (2.3.1) is connected to the third input of the third antenna switch (2.1.9) of the antenna device (2.1). Moreover, the fifth input / output of the network switch (2.3.4) is connected to the third input / output of the network switch (2.2.3) of the control and measuring device (2.2).

The control point for the technical condition (4.3) of the mobile monitoring post (4) is designed to monitor the technical condition of the radio monitoring means and the information received through the communication channels, and to prevent technical malfunctions of the radio monitoring means and unauthorized influences on the transmitted information through the communication channels, its scheme can be implemented in various ways, in particular as shown in FIG. 11. The control point for the technical condition (4.3) consists of cascading radio stations (4.3.1), a radio modem (4.3.2) and a firewall (4.3.3), the second input / output of which is connected to the first input / output of the network switch ( 4.3.4), the second, the input / output of which is connected to the input / output of the PC (4.3.5). Moreover, the first input of the radio station (4.3.1) is connected to the second output of the third antenna switch (4.1.13) of the antenna device (4.1). The first output of the radio station (4.3.1) is connected to the third input of the third antenna switch (4.1.13) of the antenna device (4.1). Moreover, the third input / output of the network switch (4.3.4) is connected to the third input / output of the first network switch (4.2.2) of the control and measuring device (4.2).

The radio stations (2.3.1, 4.3.1) included in the technical state control center (2.3) of the stationary monitoring station (2) and the technical state control center (4.3) of the mobile monitoring station (4) are designed to receive / transmit signals, radio modems ( 2.3.2, 4.3.2), designed to transmit digital data over the air, developed and manufactured by NPT NTT LLC, St. Petersburg. Firewalls (2.3.3, 4.3.3) are designed to protect network segments or individual KISM hosts from unauthorized access using vulnerabilities in the OSI network model protocols or in software installed on the KISM PC and are software or hardware-software elements KISM. A Cisco ASA 5506-X appliance can be used (http://www.cisco.com/c/en/products/security/asa-firepower-services/mdex.html?stickynav=1). Network switches (2.3.4, 4.3.4), are designed to connect several nodes of the KISM network. A Cisco Catalyst 3560-CX device can be used (http://www.cisco.com/c/en/us/products/switches/catalyst-3560-cx-series-switches/index.html).

The declared KISM works on the principle of an automated control system (ACS), the structural elements of which are placed on the appropriate blocks. The block diagram of the KISM ACS is shown in FIG. 12. The KISM ACS is a modular system, and consists of a task planning module, a KISM ACS database, a KISM control module, a radomonitoring control module, a radio monitoring results processing module, a technical state control module, a technical state monitoring module, an operational technical state control module, and ACS of mobile and stationary monitoring posts, as well as ACS of radio monitoring posts on LPS. Each KISM ACS module performs specific tasks and functions as shown in FIG. 12 links.

The task planning module is deployed on the basis of the CPU (1) and it is designed to receive tasks for radio monitoring from customers, create tasks for radio monitoring and monitoring the technical state of KISM, write tasks to the KISM ACS databases, generate reporting documents on the results of radio monitoring and send them to the customer, as well as generating reports on the technical condition of KISM and taking measures to improve KISM on the basis of these reports.

ACS KISM incorporates three types of databases. The radio monitoring database is deployed on the basis of the CPMS (1.1) and they contain information on the tasks of radio monitoring and the results obtained in the course of these tasks. The database of the technical condition is deployed on the basis of CPPTS (1.2) and it contains information on the tasks for monitoring the technical condition of the KISM and the results of their solution. The database of frequency assignments is deployed on the basis of the Central Control System (1.1) and it contains information on legally operating sources of radio emissions.

The KISM control module is deployed on the basis of the CPU (1) and it is designed to load tasks for radio monitoring and monitoring the technical condition, redistributing tasks between modules, collecting and analyzing the results obtained during the execution of a task.

The radio monitoring control module is deployed on the basis of the CPMS (1.1) and it is designed to redistribute the tasks of radio monitoring between the KSIM resources for more complete collection of information about the monitored radiation sources, as well as clarifying the results of radio monitoring, on the basis of which the final report on radio monitoring is generated.

The module for processing the results of radio monitoring is deployed on the basis of the CPMS (1.1) and it is intended for receiving monitoring, analysis and processing results of radio monitoring from the posts, and generating a report on the completed task.

The technical state management module is deployed on the basis of CPPS (1.2) and it is designed to receive tasks for monitoring the technical condition, redistributing them between the KISM resources, processing and analyzing the results of this monitoring, making decisions on eliminating the problems of the KISM technical state, and developing recommendations for choosing serviceable monitoring posts.

The technical condition monitoring module is deployed on the basis of CPPTS (1.2) and it is intended for sending requests about the technical condition of monitoring posts, receiving answers from them and compiling a report on the technical condition of the KISM elements.

The operational module for managing the technical condition is deployed on the basis of CPUTS (1.2) and it is designed to form a control team in accordance with the decision made to eliminate technical condition problems, send it to a faulty monitoring post, and after receiving a response about the command from the monitoring post report on solving the problem of the technical state of KISM

ACMS KISM operates as shown in FIG. 12 links. The task planning module generates tasks and saves them to the KISM ACS databases, and also uploads the results of completed tasks from these databases. The KISM control module receives tasks from the KISM ACS databases and saves back the results of completed tasks there. In the KISM control module, tasks are redistributed between the radio monitoring control module and the technical state control module in accordance with the specifics of the task. The radio monitoring control module sends tasks for radio monitoring to mobile and stationary monitoring posts and radio monitoring posts on the LPS. Mobile and stationary monitoring posts and radio monitoring posts on the LPS, having completed tasks for radio monitoring, send the results to the radio monitoring results processing module, in which these results are processed and these results processed are sent to the radio monitoring control module. The technical condition management module sends tasks for monitoring the technical condition to the technical condition monitoring module, which sends requests for the technical condition to mobile and stationary monitoring posts. Mobile and stationary monitoring posts, having collected information about the technical condition, send a response to the request to the technical state management module, which, based on these answers, forms tasks for solving problems of the KISM technical state and sends them to the operational technical state management module. This module, based on the tasks received, forms control teams and sends them to the corresponding mobile and stationary monitoring posts, which, after these commands are executed, send a progress report back to the operational technical state management module, which, summarizing the reports, sends the results of solving problems of the KISM technical condition to technical state management module. The technical state control module and the radio monitoring control module, after solving the tasks set by them, send the results to the KISM control module.

ACS of the declared KISM during operation solves two problems simultaneously: the task of radio monitoring and monitoring the technical state of KISM.

The algorithm for the functioning of the ACS KISM when performing tasks of radio monitoring is presented in FIG. 13 and is performed as follows:

1. Task planning module:

1.1. receiving a task for radio monitoring from a customer;

1.2. statement of the problem using the database of frequency assignments;

1.3. setting task parameters;

1.4. saving tasks to the radio monitoring database.

2. KISM control module:

2.1. loading a task from the radio monitoring database;

2.2. making a decision on the formulation of the task for implementation, taking into account the technical condition of the KISM.

3. Radio monitoring control module:

3.1. getting a task;

3.2. checking time limits, equipment availability, etc .;

3.3. sending tasks to monitoring posts.

4. Post monitoring:

4.1. getting a task;

4.2. performance of radio monitoring;

4.3. sending the result.

5. The module for processing the results of radio monitoring:

5.1. receiving results from radio monitoring posts;

5.2. analysis of the results;

5.3. processing results in automatic or manual mode;

5.4. report generation.

6. Radio monitoring control module:

6.1. receipt of a radio monitoring report;

6.2. clarification of the results of radio monitoring;

6.3. formation of the final report.

7. KISM control module:

7.1. making a decision to complete an assignment;

7.2. saving the result to the radio monitoring database.

8. Task planning module:

8.1. downloading the result from the radio monitoring database;

8.2. generation of a report on the results of the completed task for radio monitoring;

8.3. sending the result of radio monitoring to the customer.

The algorithm for the functioning of the ACS KISM when performing monitoring tasks for the technical state of KISM is presented in FIG. 14 and is performed as follows:

1. Task planning module:

1.1. statement of the problem of monitoring the technical condition of the KISM in accordance with the task of radio monitoring using the technical condition database;

1.2. setting task parameters;

1.3. saving the task to the database of the technical condition.

2. KISM control module:

2.1. loading tasks from the database of the technical condition;

2.2. making a decision on setting a task to be completed.

3. Technical state management module:

3.1. getting a task;

3.2. task detail.

4. The module for monitoring the technical condition:

4.1. getting a task;

4.2. sending a request for technical condition to monitoring posts;

4.3. receiving a response from monitoring posts;

4.4. drawing up a report on monitoring the technical condition.

5. Technical state management module:

5.1. receiving a report;

5.2. report analysis;

5.3. verification of the condition “Does the technical condition meet the requirements?”, if “yes”, then clause 7.2. is met, if “no”, then clauses 5.4 are carried out. and 5.5 .;

5.4. making recommendations on the election of monitoring posts for the task of radio monitoring, after completion, paragraph 7.1 is followed .;

5.5. statement of the problem to solve the problems of technical condition, after completion, paragraph 6.1 is executed.

6. Operational module for managing the technical condition:

6.1. getting a task;

6.2. formation of management teams;

6.3. sending control teams to faulty monitoring posts;

6.4. receiving reports from monitoring posts on the implementation of the management team;

6.5. drawing up a report on the results of solving problems of technical condition, after completion, paragraph 5.1 is executed.

7. KISM control module:

7.1. adjustment of the task of radio monitoring taking into account recommendations;

7.2. making decisions on the implementation of the task, taking into account the measures taken to manage the technical condition;

7.3. saving the result to the database of the technical condition.

8. Task planning module:

8.1. loading the result from the technical condition database;

8.2. generating a report on the results of the task of monitoring the technical condition of the KISM;

8.3. taking organizational measures to improve KISM to meet the technical state of KISM requirements.

The feasibility of implementing the formulated technical result was tested by mathematical modeling, reflecting the most characteristic features of the control system. As one of the possible models, we used the representation of KISM as a system with a variable structure, the behavior of which at random time intervals is characterized by various structures and is described by probabilistic laws, for example, an exponential distribution that corresponds to the simplest flow of events and the description of transitions between KISM states by Markov random processes . In this case, the transition of one structure to another occurs at a random moment of time, depending on the value of the phase coordinates of the system. This mathematical apparatus is used in the work [Lipatnikov V.A., Shevchenko A.A., Yatskin A.D., Semenova E.G. Information security management of an integrated structure organization based on a dedicated server with container virtualization // Management Information Systems. 2017. No4 (89). S. 67-76. doi: 10.15217 / issn1684-8853.2017.4.67]. As a result of the simulation, the relationship between the reliability indicator of the monitoring results and the values of the time for identifying technical failures in KISM t _century. when using the claimed device P _D.Z. , and also shows the dependence of the reliability indicator of the monitoring results of the device of the prototype R _D.P.R. (see Fig. 15).

The achievement of the technical result is illustrated as follows. In the prototype device, the elimination of technical malfunctions is carried out for a time t _у.п. according to the results of the analysis of the reliability of information on controlled sources of radio emission. For the proposed method for eliminating technical malfunctions, it is performed according to the results of the monitoring of the technical state of the KISM received from the central control center and technical control points that are part of stationary and mobile monitoring posts, over time _t.s. .

At the same time, having drawn a direct R _Z.D.P. = 0.9 - a given indicator of the reliability of the monitoring results of the KISM, it can be seen that the required time to fix technical malfunctions in the KISM in the prototype device is more time to fix technical malfunctions in the claimed device, that is, t _у.пр. > t _UZ , this shows the achievement of the formulated technical result in the implementation of the claimed device, that is, increasing the reliability of the results of radio monitoring by increasing the efficiency of eliminating technical malfunctions in the KISM.

Claims (10)

1. Monitoring and measuring monitoring system (KISM), containing a central control center (CPU) (1), including a central radio monitoring control center (CPMS) (1.1) and K≥2 spatially separated stationary monitoring posts (2 ₁ , 2 ₂ , ..., 2 _K ), N≥2 auxiliary spatially separated measuring and measuring complexes (KIK) (3 ₁ , 3 ₂ , ..., 3 _N ), each of which includes a control point (3a) and М≥3 spatially separated stationary monitoring posts (2 ₁ , 2 ₂ , ..., 2 _M ), mobile monitoring posts (4) located on mobile Objects: soil, ships or aircraft (LPS) (5), as well as a set of controlled sources of radio emission (6), and spatially separated stationary monitoring posts that are part of the CPU (1) and auxiliary KIK (3), interact remotely through the communication channels of the CPU (1), spatially separated stationary monitoring posts that are part of the auxiliary KIK (3), interact remotely through the control points (3a) of the auxiliary KIK (3), which these monitoring posts are part of, mob The monitoring posts (4) and the radio monitoring posts on the LPS (5) are remotely controlled via the communication channels of the CPU (1) or through the nearest control points (3a) of the auxiliary KIK (3), characterized in that a central control unit is additionally added to the CPU (1) technical condition control center (CPCTS) (1.2) of the facilities included in the CIS; moreover, CPAC (1.2) interacts with the CPMS (1.1) using the communication channels of the CPU (1), and each stationary monitoring post (2) included in the CPU (1), to auxiliary CFCs (3) and to each mobile monitoring post (4) additional technical state control points have been introduced that interact with the central control center (1.2) through the antenna device of the stationary monitoring station (2) or mobile monitoring station (4), depending on where they are located, using the CPU communication channels (1) or the nearest control point (3a) of auxiliary KIK (3). 2. The control and measuring monitoring system according to claim 1, characterized in that the CPU (1.2) consists of a cascade-connected communication antenna (1.2.1), a radio station (1.2.2), a radio modem (1.2.3) and a firewall ( 1.2.4), the second input / output of which is connected to the first input / output of the network switch (1.2.5), the second, third, fourth and fifth inputs / outputs of which are connected to the inputs / outputs of the KISM technical status data server, respectively (1.2. 6), the first (1.2.7), the second (1.2.8) and the third (1.2.9) PC. 3. The monitoring and control monitoring system according to claim 1, characterized in that the stationary monitoring station (2) consists of an antenna device (2.1), the first, second, third, fourth and fifth outputs of which are connected to the corresponding inputs of the monitoring and measuring device ( 2.2), the first, second, third and fourth outputs of which are connected to the corresponding inputs of the antenna device (2.1), and the fifth output of which is connected to the first input of the control point of the technical condition (2.3), and the sixth output of the antenna device (2.1) is connected It is connected to the second input of the technical condition control center (2.3), the first output of which is connected to the sixth input of the control and measuring device (2.2), and the second output is connected to the fifth input of the antenna device (2.1). 4. The monitoring and control monitoring system according to claim 3, characterized in that the antenna device (2.1) of the stationary monitoring station (2) consists of a two-line direction-finding antenna, consisting of the first (2.1.1) and the second (2.1.2) letters, thirty-two outputs of which are connected to thirty-two inputs of the first antenna switch (2.1.3), the first and second outputs of which are connected to the first and second inputs of a two-channel digital radio receiver (2.2.1) of the control and measuring device (2.2), and the thirty-third input first antenna comm The speaker (2.1.3) is connected to the first output of the two-channel digital radio receiver (2.2.1) of the control and measuring device (2.2), the first (2.1.4) and second (2.1.5) auditory monitoring antennas, the outputs of which are connected to the first and the second input of the second antenna switch (2.1.6), the output of which is connected to the first input of the radio receiver of the auditory control device (2.2.5) of the control and measuring device (2.2), and the third input of the second antenna switch (2.1.6) is connected to the first output of the radio receiver auditory control devices (2.2.5) con a measuring and measuring device (2.2), a measuring antenna (2.1.7), the output of which is connected to the first input of a single-channel digital radio receiving device (2.2.7) of the measuring and measuring device (2.2), and the input of the measuring antenna (2.1.7) is connected to the second output of the second PC (2.2.8) of the control and measuring device (2.2), the communication antenna (2.1.8), the output of which is connected to the first input of the third antenna switch (2.1.9), the first output and the second input of which are connected to the second input / output of the radio station (2.2.12) devices (2.2), and the second output and the third input of the third antenna switch (2.1.9) are connected to the first input / output of the radio station (2.3.1) of the technical condition control center (2.3). 5. The control and measuring monitoring system according to claim 3, characterized in that the control and measuring device (2.2) of the stationary monitoring station (2) consists of a two-channel digital radio receiving device (2.2.1), the first and second inputs of which are connected to the first and to the second outputs of the first antenna switch (2.1.3) of the antenna device (2.1), the first output of the two-channel digital radio receiver (2.2.1) is connected to the third input of the first antenna switch (2.1.3) of the antenna device (2.1), and the second output of the two-channel digital the radio receiver (2.2.1) is connected to the first input of the network switch (2.2.3), and the third input of the two-channel digital radio receiver (2.2.1) is connected to the output of the first adapter (2.2.2), the input of which is connected to the second output of the radio auditory control devices (2.2.5), the first input of which is connected to the output of the second antenna switch (2.1.6) of the antenna device (2.1), and the first output of the hearing aid radio receiver (2.2.5) is connected to the third input of the second antenna switch (2.1) .6) antenna devices (2.1), and the second input of the hearing aid radio receiver (2.2.5) is connected to the first output of the second adapter (2.2.6), the second input / output of which is connected to the fourth input / output of the network switch (2.2.3), the second input / the output of which is connected to the first PC (2.2.4), and the third input / output of the network switch (2.2.3) is connected to the fifth input / output of the network switch (2.3.4) the technical state control point (2.3), and the fifth input / the output of the network switch (2.2.3) is connected to the second input / output of a single-channel digital ra a receiving device (2.2.7), the first input of which is connected to the output of the measuring antenna (2.1.7) of the antenna device (2.1), and the third input of a single-channel digital radio receiving device (2.2.7) is connected to the output of the highly stable reference generator (2.2.9) and the sixth input / output of the network switch (2.2.3) is connected to the first input / output of the second PC (2.2.8), the second output of which is connected to the input of the measuring antenna (2.1.7) of the antenna device (2.1), and cascaded firewall (2.2.10), radio modem (2.2.11) and radio stations (2.2.12), second the path / output of which is connected to the second input and the first output of the third antenna switch (2.1.9) of the antenna device (2.1), and the first input / output of the firewall (2.2.10) is connected to the seventh input / output of the network switch (2.2.3) . 6. The monitoring and control monitoring system according to claim 1, characterized in that the mobile monitoring station (4) consists of an antenna device (4.1), the first to ninth outputs of which are connected to the corresponding inputs of the monitoring and measuring device (4.2), first, second , the third and fourth outputs of which are connected to the corresponding inputs of the antenna device (4.1), and the fifth output of the control and measuring device (4.2) is connected to the first input of the controller (4.4), the second input / output of which is connected to the first input / output of the camera (4.5) , and the first output of the controller (4.4) is connected to the tenth input of the control and measuring device (4.2), and the sixth output of the control and measuring device (4.2) is connected to the first input of the control point of the technical state (4.3), the first output of which is connected to the eleventh input of the control and measuring device (4.2), and the tenth output of the antenna device (4.1) is connected to the second input of the control point of the technical condition (4.3), the second output of which is connected to the fifth input of the antenna device (4.1). 7. The monitoring and control monitoring system according to claim 6, characterized in that the antenna device (4.1) of the mobile monitoring station (4) consists of a two-line direction-finding antenna, consisting of the first (4.1.1) and second (4.1.2) letters, sixteen outputs of which are connected to sixteen inputs of the first antenna switch (4.1.3), the first and second outputs of which are connected to the first and second inputs of a two-channel digital radio receiver (4.2.1) of the control and measuring device (4.2), and the seventeenth input of the first antenna switch (four. 1.3) is connected to the first output of the two-channel digital radio receiver (4.2.1) of the control and measuring device (4.2), the auditory control antenna (4.1.4), the output of which is connected to the input of the radio receiver of the auditory control (4.2.5) of the control and measuring device (4.2), the first omnidirectional antenna (4.1.5), the output of which is connected to the first input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2), the second omnidirectional antenna (4.1.6), the output of which is connected to the first input second antenna nth switch (4.1.7), the second output of which is connected to the input of the converter (4.1.8), the output of which is connected to the third input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2), and the first output of the second antenna switch ( 4.1.7) is connected to the second input of a single-channel digital radio (4.2.11) of the control and measuring device (4.2), and the second input of the second antenna switch (4.1.7) is connected to the first output of a single-channel digital radio (4.2.11) of the control and measuring devices ( 4.2), antennas of the global satellite positioning system (4.1.9), the output of which is connected to the fourth input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2), of the slewing ring device (4.1.11) connected to the measuring antenna (4.1.10), the output of which is connected to the fifth input of a single-channel digital radio receiver (4.2.11) of the control and measuring device (4.2), and the input of the slewing ring device (4.1.11) is connected to the third output of the second network switch (4.2.7 ), and communication antennas (4.1.12), out One of which is connected to the first input of the third antenna switch (4.1.13), the first output and second input of which is connected to the second input / output of the radio station (4.2.10) of the control and measuring device (4.2), and the second output and third inputs of the third antenna switch (4.1.13) are connected to the first input / output of the radio station (4.3.1) of the technical state control center (4.3). 8. The control and measuring monitoring system according to claim 6, characterized in that the control and measuring device (4.2) of the mobile monitoring station (4) consists of a two-channel digital radio receiving device (4.2.1), the first and second inputs of which are connected to the first and the second outputs of the first antenna switch (4.1.3) of the antenna device (4.1), and the first output of the two-channel digital radio receiver (4.2.1) is connected to the seventeenth input of the first antenna switch (4.1.3) of the antenna device (4.1), and the third input / output of two channel digital radio receiver (4.2.1) is connected to the first input / output of the first network switch (4.2.2), the second input / output of which is connected to the fifth input / output of the first PC (4.2.3), the first, second and third inputs of which connected to the first, second and third outputs of the hearing aid radio receiver (4.2.5), the first input of which is connected to the output of the hearing aid antenna (4.1.4) of the antenna device (4.1), a mobile phone (4.2.4), the output of which is connected to the fourth input of the first PC (4.2.3), the second PC (4.2.6), output which is connected to the seventh input of the first network switch (4.2.2), the third input / output of which is connected to the third input / output of the network switch (4.3.4), the state control point (4.3), and the fourth input / output of the first network switch (4.2 .2) connected to the first input / output of the second network switch (4.2.7), and the fifth input / output of the first network switch (4.2.2) connected to the input / output of the third PC (4.2.12), and the sixth input / output of the first the network switch (4.2.2) is connected to the sixth input / output of a single-channel digital a diode receiver (4.2.11), the first input of which is connected to the output of the first non-directional antenna (4.1.5) of the antenna device (4.1), the first output of a single-channel digital radio receiver (4.2.11) is connected to the second input of the second antenna switch (4.1.7) of the antenna devices (4.1), the second input of the single-channel digital radio (4.2.11) is connected to the first output of the second antenna switch (4.1.7) of the antenna device (4.1), and the third, fourth and fifth inputs of the single-channel digital radio (4.2.11) are connected to outputs respectively a torus (4.1.8), an antenna of the global satellite positioning system (4.1.9) and a measuring antenna (4.1.10) of an antenna device (4.1), and a cascade-connected firewall (4.2.8), a radio modem (4.2.9) and radio station (4.2.10), the second input / output of which is connected to the second output and the third inputs of the third antenna switch (4.1.13) of the antenna device (4.1), and the first input / output of the firewall (4.2.8) is connected to the second input / the output of the second network switch (4.2.7), the third output of which is connected to the input of the slewing ring device (4.1.11) antenna device (4.1), and the third input and fourth output of the second network switch (4.2.7) are connected to the first input / output of the controller (4.4). 9. The control and measuring monitoring system according to claim 1, characterized in that the technical condition control point (2.3) of the stationary monitoring station (2) consists of cascade-switched radio stations (2.3.1), a radio modem (2.3.2) and a firewall (2.3.3), the second input / output of which is connected to the first input / output of the network switch (2.3.4), the second, third and fourth inputs / outputs of which are connected to the inputs / outputs of the first (2.3.5), second (2.3 .6) a PC and a server of data on the technical condition (2.3.7), the first input of the radio station (2.3.1) is connected to the second output of the third antenna switch (2.1.9) of the antenna device (2.1), and the first output of the radio station (2.3.1) is connected to the third input of the third antenna switch (2.1.9) of the antenna device (2.1), and the fifth input / output the network switch (2.3.4) is connected to the third input / output of the network switch (2.2.3) of the control and measuring device (2.2). 10. The control and measuring monitoring system according to claim 1, characterized in that the technical condition control point (4.3) of the mobile monitoring station (4) consists of cascade-switched radio stations (4.3.1), a radio modem (4.3.2) and a firewall (4.3.3), the second input / output of which is connected to the first input / output of the network switch (4.3.4), the second input / output of which is connected to the input / output of the PC (4.3.5), and the first input of the radio station (4.3.1 ) is connected to the second output of the third antenna switch (4.1.13) of the antenna device (4.1), and the first output is for the remainder (4.3.1) is connected to the third input of the third antenna switch (4.1.13) of the antenna device (4.1), and the third input / output of the network switch (4.3.4) is connected to the third input / output of the first network switch (4.2.2) control and measuring device (4.2).

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