RU2616286C1 - Spatial-distribution complex of radio jamming navigation equipment of global navigation systems with multi-functional use of electronic equipment - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method is performed by applying a plurality of spaced interference transmitters of small capacity with the total interference energy concentration in the predetermined area at the predetermined time interval, wherein the spatial-distribution complex of radio jamming the navigation equipment of the global navigation system consumers with the multi-function using of the electronic equipment consists of the control station and the interference stations, performed and interrelated in a certain way.

EFFECT: provision of radio interference to navigation equipment for users of global navigation satellite systems.

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Description

The invention relates to the field of radio engineering and can be used to create deliberate high-power radio interference placed on high-speed and highly maneuverable mobile devices receiving devices of consumer navigation equipment (NAP), operating on the signals of global navigation satellite systems (GNSS), by using a set of radio interference transmitters spaced in space low power with a concentration of the total energy of the radio noise in a given region of space at a given in ervale time.

Known network-centric spatially distributed system based on small-sized modules intelligence and interference [Radzievsky V.G. Network-centric spatially separated system based on small-sized intelligence and interference modules [Text] / Radio engineering. - 2012. - No. 6. - S. 4-11], consisting of small reconnaissance and interference modules located in the immediate vicinity of electronic equipment, some of these small reconnaissance and interference modules have the additional function of controlling a limited set of reconnaissance and interference modules and communications by a control and information processing center, data transmission repeater, reconnaissance sensors, placed to increase the range on flying and lifting facilities, reconnaissance information processing center, center and control and processing heel data spatially distributed intelligence system and interference.

The disadvantage of a network-centric spatially distributed system based on small-sized reconnaissance and interference modules is that this system does not provide the detection of radio suppression objects for NAPs operating on GNSS signals placed on high-speed and highly maneuverable mobile devices.

Known spatially distributed complex of means for creating radio interference [Patent No. 2563972 of the Russian Federation, IPC H04K 3/00. Spatially distributed set of means for creating radio interference / A.V. Zhuravlev [et al.] (RF); NPP PROTEK OJSC (RF). - No. 2014111857/07; Announced on 03/27/2014; Publ. 09/27/2015. - 2 p.], Consisting of a control point having time-coordinate and navigation support equipment, a power supply unit, a control panel, a display unit, a transmitting antenna, a receiving antenna, a control channel radio station, and a computer that performs the functions of determining the predicted time interval areas of the location space of the object of radio suppression and control of jointly spaced in space intelligence stations having a transmitting antenna, a receiving antenna, a radio channel of the control channel power supply unit, time-coordinate and navigation support equipment, equipment for detecting and determining the location of a radio jamming object with an antenna, a computer that generates and transmitting along the lines of intra-object communication codograms of initialization of the operation of the equipment for detecting and determining the location of a radio jamming device, and radio interference stations having a transmitting antenna, a receiving antenna, radio stations of the control channel, power supply unit, equipment to ordinate-time and navigation support, a radio interference transmitter control unit, a radio interference transmitter with a radio interference radiation antenna, a radio interference antenna angular orientation device, a radio interference antenna angular position control unit, a calculator that provides an angular orientation of the main lobes of the radiation patterns of antennas emitting radio interference a given region of the location space of the radio suppression object to the devices of the navigation equipment of consumers, driver running on the signals of global navigation satellite systems, the required total power level of radio interference with the optimization used along spaced radio stations according to their location and number, as well as temporary regulations work stations on the radio emission.

The disadvantage of this complex is that the spatially distributed complex of means for creating radio interference includes reconnaissance stations collectively spaced in space, which are additional radiating expensive objects that have significant dimensions and weight, low reconnaissance and survivability of equipment with active single-position or bistatic radar.

The aim of the invention is the development of a spatially distributed complex for the creation of radio interference to the navigation equipment of consumers of global navigation systems with multifunctional use of electronic equipment providing radio intelligence and radio suppression.

This goal is achieved by the fact that in the well-known spatially distributed set of means for creating radio interference, a control meter is additionally introduced into the control center, designed to determine the coordinates of the carrier of the corresponding component of the complex, an active antenna, a filter for interference signal filters, a filter module for sounding signals, a module for measuring sounding signals , unit for determining its own coordinates, while the active antenna is connected to the input of the filter module interference signals, output cat connected to the input of the probe signal filter module, connected to the corresponding input of the probe signal measurement module, in addition, the second inputs of the interference signal filter module, probe filter module and probe signal measurement module are connected to the output of the unit for determining the corresponding coordinates, which is interconnected with the receiver a control station calculator, wherein the output of the probe filter module is connected to the corresponding input of the receiver, into each of N stations radio interference, an additional meter has been introduced to determine the coordinates of the carrier of the corresponding frequency of the complex, an active antenna, an interference signal filter module, a probe signal filter module, a probe signal measurement module, a probe signal generation unit, while the active antenna is connected to the input of the interference signal filter module, the output of which is connected to the input of the probe filter module, connected to the corresponding input of the probe module In addition, the second inputs of the interference signal filter module, the probe signal filter module, and the probe signal measurement module are connected to the input of the eigen-coordinate determination unit, which is interconnected with the receiver and transmitter of the radio interference station, and the input of the probe signal filter module is connected to the corresponding input of the station receiver radio noise, the probe signal generating unit is interconnected with the computer of the radio interference station.

The invention is illustrated by figures.

In FIG. 1 shows a hypothetical layout of a spatially distributed radio interference generating complex for navigation equipment of global navigation systems consumers with multifunctional use of electronic equipment, FIG. 2 shows a structural and functional diagram of a set of radio-electronic equipment of a control center, and in FIG. 3 shows a structural-functional diagram of a set of electronic equipment and a radio interference station.

), где n - порядковый номер, а N - количество станций радиопомех в КОМПЛЕКСЕ.Spatially distributed complex for creating radio interference to navigation equipment of consumers of global navigation systems with multifunctional use of electronic equipment, hereinafter referred to as COMPLEX, consists of a control center 4 and radio interference stations 3 ₁ , 3 ₂ , ..., 3 _n , ..., 3 _N (or 3 _n ,

), where n is the serial number, and N is the number of radio interference stations in the COMPLEX.

The control point 4 consists of a radio station 5 with a transmitting antenna 6 and a receiving antenna 7, a computer 8 with a control panel 9 and a display 10, an eigen-coordinate determination unit 11, an active antenna 12, a receiver 13, an interference signal filter module 14, a probe signal filter module 15 , a module for measuring sounding signals 16, a power supply 17.

состоит из радиостанции 18 с предающей антенной 19 и приемной антенной 20, вычислителя 21 с пультом управления 22 и дисплеем 23, блока определения собственных координат 24, активной антенны 25, приемоизмерителя 26, модуля фильтров помеховых сигналов 27, модуля фильтров зондирующих сигналов 28, модуля измерения зондирующих сигналов 29, блока управления передатчиком 30, передатчика радиопомех 31, передающей антенны 32, блока управления передающей антенны 33, устройства ориентирования передающей антенны 34, блока синтезатора зондирующего сигнала 35, блока питания 36.Radio interference station 3 _n ,

consists of a radio station 18 with a transmitting antenna 19 and a receiving antenna 20, a computer 21 with a control panel 22 and a display 23, an eigen-coordinate determining unit 24, an active antenna 25, a receiver 26, an interference signal filter module 27, a probe signal filter module 28, a measurement module sounding signals 29, the control unit of the transmitter 30, the transmitter of the radio noise 31, the transmitting antenna 32, the control unit of the transmitting antenna 33, the orienting device of the transmitting antenna 34, the synthesizing unit of the probing signal 35, the pi tania 36.

The equipment in control room 4 has the following connections. The transmitter 8 with the first output is connected to the input of the radio station 5, the second output is connected with the first input of the eigen-coordinate determination unit 11, and the third output with the display 10. The output of the radio station 5 is connected to the first input of the calculator 8. The output of the control panel 9 is connected to the fourth input of the calculator 8. Block determining own coordinates 11, the first output is connected to the second input of the calculator 8, the second output to the first input of the receiver 13, the third output to the second input of the probe measurement module 16, with the second mod input coaxial filters of the probe signal 15, with the second input of the interference signal filter module 14. The output of the receiver 13 is connected to the second input of the eigen-coordinate determination unit 11. The output of the active antenna 12 is connected to the first input of the interference signal filter module 14. The output of the interference signal filter module 14 is connected to the first input of the probe filter module 15. The second output of the probe filter module 15 is connected to the second input of the receiver 13, the first output is connected to the first input of the probe measurement module signal 16, the output of which is connected to the third input of the transmitter 8.

имеет следующие соединения. Вычислитель 21 первым выходом соединен с входом радиостанции 18, вторым выходом соединен с первым входом блока определения собственных координат 24, третьим выходом соединен с входом блока формирования зондирующего сигнала 35, четвертым выходом с первым входом блока управления радиопередатчика 30, пятым выходом соединен со входом с блоком управления передающей антенны 33, шестым входом с дисплеем 23. Выход радиостанции 18 соединен с первым входом вычислителя 21. Выход пульта управления 22 соединен с седьмым входом вычислителя 21. Блок определения собственных координат 24 первым выходом соединен со вторым входом вычислителя 21, вторым выходом с первым входом приемоизмерителя 26, третьим выходом со вторым входом модуля измерения зондирующих сигналов 29, со вторым входом модуля фильтров зондирующего сигнала 28, со вторым входом модуля фильтров помехового сигнала 27. Выход приемоизмерителя 26 соединен со вторым входом блока определения собственных координат 24. Выход активной антенны 25 соединен с первым входом модуля фильтров помехового сигнала 27. Выход модуля фильтров помехового сигнала 27 соединен с первым входом модуля фильтров зондирующего сигнала 28. Второй выход модуля фильтров зондирующего сигнала 28 соединен со вторым входом приемоизмерителя 26, первый выход соединен с первым входом модуля измерения зондирующих сигналов 29, выход которого соединен с третьим входом вычислителя 21.Radio interference station equipment 3 _n ,

has the following compounds. The calculator 21 has a first output connected to the input of the radio station 18, a second output connected to the first input of the eigen-coordinate determining unit 24, a third output connected to the input of the probe signal generating unit 35, a fourth output to the first input of the control unit of the radio transmitter 30, and a fifth output connected to the input of the unit control transmitting antenna 33, the sixth input with a display 23. The output of the radio station 18 is connected to the first input of the calculator 21. The output of the control panel 22 is connected to the seventh input of the calculator 21. Block determination own coordinates 24 with the first output connected to the second input of the calculator 21, the second output with the first input of the receiver 26, the third output with the second input of the probe measurement module 29, with the second input of the probe filter module 28, with the second input of the interference signal filter module 27. Output the receiver 26 is connected to the second input of the unit for determining its own coordinates 24. The output of the active antenna 25 is connected to the first input of the filter module of the interference signal 27. The output of the filter module of the interference signal 2 7 is connected to the first input of the probe signal filter module 28. The second output of the probe signal filter module 28 is connected to the second input of the receiver 26, the first output is connected to the first input of the probe signal measurement module 29, the output of which is connected to the third input of the transmitter 21.

The first output of the probe signal generating unit 35 is connected to the fourth input of the transmitter 21, the second output is connected to the second input of the transmitter control unit 30. The first output of the transmitter control unit 30 is connected to the fifth input of the transmitter 21, the second output is connected to the input of the radio interference transmitter 31. The first output of the transmitter radio interference 31, the second output is connected to the third input of the transmitter control unit 30. The first output of the transmitting antenna unit 33 is connected to the sixth input of the calculator 21, the second output is connected to the device Orientation of the transmitting antenna 34.

являются оборудованием автоматизации управления, решающим комплекс задач организации взаимодействия данными между составными частями КОМПЛЕКСА.A computer 8 with a control panel 9 and a display 10 of a control point 4, a special computer 21 with a control panel 22 and a display 23, a radio interference station 3 _n ,

They are automation control equipment that solves the complex tasks of organizing data interaction between the components of COMPLEX.

являются помехозащищенным оборудованием, обеспечивающим внутрикомплексный информационный обмен цифровой информации по согласованному протоколу на требуемых дистанциях связи, определяемых позициями составных частей КОМПЛЕКСА.A radio station 5 with a transmitting antenna 6 and a receiving antenna 7 of a control point 4, a radio station 18 with a transmitting antenna 19 and a receiving antenna 20, a radio interference station 3 _n ,

they are interference-proof equipment that provides an integrated information exchange of digital information according to an agreed protocol at the required communication distances determined by the positions of COMPLEX components.

являются оборудованием координатно-временного и навигационного обеспечения мобильного средства-носителя составной части КОМПЛЕКСА путем определения координат данного мобильного средства и приемной позиции активной многопозиционной радиолокационной системы, путем определения значений временных и частотных параметров прямого и отраженного зондирующих сигналов S_ИЗ и S_ОЗ с привязкой к шкале единого времени с использованием данных координатно-временного обеспечения.Eigen-coordinate determination unit 11, active antenna 12, receiver 13, interference signal filter module 14, sounding signal filter module 15, probe signal measurement module 16 of control point 4, eigen-coordinate determination module 24, active antenna 25, receiver 26, interference filter module signals 27, a filter module of sounding signals 28, a module for measuring sounding signals 29, radio interference station 3 _n ,

they are the equipment of the coordinate-time and navigation support of the mobile carrier vehicle of the COMPLEX component by determining the coordinates of this mobile vehicle and the receiving position of the active multi-position radar system, by determining the values of the time and frequency parameters of the direct and reflected sounding signals S _FROM and S _OZ with reference to the scale single time using data of the coordinate-time support.

являются оборудованием формирования, усиления преднамеренных или зондирующих радиосигналов путем поставки радиопомех или излучения зондирующего радиосигнала в момент реализации способа активной многопозиционной радиолокации.Radio interference transmitter 31, transmitting antenna 32, transmitting antenna control unit 33, transmitting antenna orienting device 34, probe synthesizer synthesizer unit 35, radio interference station 3 _n ,

They are equipment for the formation, amplification of intentional or probing radio signals by supplying radio noise or radiation of a probing radio signal at the time of implementation of the active multi-position radar method.

, оборудование электроснабжения и электропитания, предназначенное для электрообеспечения составных частей КОМПЛЕКСА.The power supply unit 17 of the control point 4 and the power supply unit 36 of the radio interference station 3 _n ,

, equipment for power supply and power supply, intended for power supply of COMPLEX components.

после совершения марша из района сосредоточения или выполнения маневра по смене местоположения находятся в заданных позиционных районах в готовности к функционированию по назначению. Блок питания 17 пункта управления 4 и блок питания 36 станции радиопомех 3_n,

обеспечивают электропитанием все оборудование составных частей КОМПЛЕКСА.Spatially distributed complex for creating radio interference to navigation equipment of consumers of global navigation systems with multifunctional use of electronic equipment works as follows. COMPONENT COMPONENTS, control point 4 and radio interference stations 3 _n ,

after making a march from the area of concentration or performing a maneuver to change the location, they are in the specified position areas in readiness for functioning as intended. The power supply unit 17 of the control point 4 and the power supply unit 36 of the radio interference station 3 _n ,

provide power to all equipment of COMPLEX components.

с пульта управления 9 и 22 вводят в вычислитель 8 и 21 команду на проведение инициализации. Вычислитель 8 и 21, получив команду на проведение инициализации, осуществляет процедуру проверки работоспособности оборудования и определения местоположении составных частей КОМПЛЕКСА. Полученный результат инициализации вычислитель 8 и 21 выводит на дисплей 10 и 23.Operators of control room 4 and radio interference station 3 _n ,

from the control panel 9 and 22 enter into the calculator 8 and 21 the command to initialize. Calculator 8 and 21, having received the initialization command, carries out the procedure of checking the equipment operability and determining the location of COMPLEX components. The resulting initialization result, the calculator 8 and 21 displays on the display 10 and 23.

полученный результат инициализации и полученные от блока определения собственных координат 24 автономные координаты местоположения передает через радиостанцию 18, передающую антенну 19, приемную антенну 7, радиостанцию 5 на вычислитель 8, который, в свою очередь, формирует массив данных о пространственных координатах и техническом состоянии станций радиопомех 3_n,

, выводит информацию на дисплей 10 для визуализации в графическом и текстовом форматах. При неполучении вычислителем 8 результата инициализации в течение заданного интервала времени интерпретируется как факт технической неисправности (неработоспособности) станции помех 3_n.The computer 21 stations radio interference 3 _n ,

the obtained initialization result and the autonomous location coordinates received from the eigen-coordinates determining unit 24 are transmitted through the radio station 18, the transmitting antenna 19, the receiving antenna 7, the radio station 5 to the transmitter 8, which, in turn, generates an array of data on the spatial coordinates and technical condition of the radio interference stations 3 _n ,

, displays information on the display 10 for visualization in graphic and text formats. If the calculator 8 does not receive the initialization result within a given time interval, it is interpreted as a fact of a technical malfunction (inoperability) of the interference station 3 _n .

.The operator of the control center, taking into account the data on spatial coordinates and technical condition, according to the requirements of the COMPLEX application plan or an extraordinary order from a higher authority, enters from the control panel 9 into the calculator 8 a data collection initialization command to determine the spatial coordinates, the parameters of the path of the mobile vehicle suppression 2 _m determine the spatial coordinates Q _i region of space 1 _m predicted for a given in time interval (t _Hi , t _Ki ) of the location of the radio suppression object 2 _m , as well as the formation of the squad of radio interference stations

.

работы станций радиопомех 3_n,

в режиме излучения зондирующего сигнала для реализации способа активной многопозиционной радиолокации. План-график D_ИЗС регламентирует последовательность интервалов времени (абсолютных значений моментов времени начала и окончания) работы в общем случае каждой из станций радиопомех 3_n,

на излучение зондирующего сигнала в заданном для каждого интервала времени пространственном направлении, характеризуемом углами ориентациями передающей антенны 32 в азимутальной и угломестной плоскостях для обеспечения максимальной эффективности использования ограниченного энергопотенциала станции радиопомех 3_n.Calculator 8, having accepted the command, forms a schedule

operation of radio interference stations 3 _n ,

in the radiation mode of the probe signal to implement the method of active multi-position radar. The schedule D of the _ISS regulates the sequence of time intervals (absolute values of the time of the beginning and end) of the work in the general case of each of the radio interference stations 3 _n ,

radiation of the probe signal in the spatial direction specified for each time interval, characterized by the angles of the orientations of the transmitting antenna 32 in the azimuthal and elevation planes to maximize the efficiency of using the limited energy potential of the radio interference station 3 _n .

, характеризующих пространственные координаты и параметры траектории движения мобильного средства-носителя объекта радиоподавления 2_m, которые вместе с план-графиком D_ИЗС в соответствии с протоколом внутрикомплексного информационного обмена передает через радиостанцию 5 и передающую антенну 6 в адрес работоспособных станций радиопомех 3_n,

.In the next step, the calculator 8 generates data request codograms of the time and frequency parameters tied to the single time scale, adopted by the eigen-coordinate determining unit 24, the active antenna 25, the receiver-receiver 26, the filter of interference signal filters 27, the filter module of sounding signals 28, and the probe measurement module signals 29 sounding signals

characterizing the spatial coordinates and parameters of the path of the mobile carrier vehicle of the radio suppression object 2 _m , which, together with the schedule D of the _ISS, in accordance with the protocol of intra-complex information exchange, transmits via radio station 5 and transmitting antenna 6 to operable radio interference stations 3 _n ,

.

.Radio signals containing a codogram through a receiving antenna 20 and a radio station 18 are fed to a computer 21 of each operable radio interference station 3 _n ,

.

, формирует и передает по линиям внутриобъектовой связи кодограммы инициализации работы блока управления передатчиком 30 блока управления передающей антенны 33, блока синтезатора зондирующего сигнала 35.Calculator 21, having accepted the codogram from the composition of the reconnaissance station 3 _n ,

, generates and transmits via the intra-object communication lines the initialization codes of the operation of the control unit of the transmitter 30 of the control unit of the transmitting antenna 33, the synthesizer of the probe signal 35.

The synthesizer block of the probe signal 35, having received a codogram, generates a probe signal, which transmits to the second input of the transmitter control unit 30.

The control unit of the transmitting antenna 33, having received a codogram, generates and transmits signals to the address of the orientation device of the transmitting antenna 32 corresponding to the given angles of the spatial orientation of the transmitting antenna 32 in the formats of specialized control interfaces for the functional modules of this device.

Transmitter control unit 30, receiving Overheads and received from probing signal synthesizer unit 35 the probe signal, generates and transmits a transmitter address radio 31 corresponding to the schedule D _IFH work station radio 3 _n on the radiation probe signal overheads and signals in formats specialized control interfaces with its functional modules and devices.

The transmitting antenna 32 emits sounding generated and amplified by the radio interference transmitter 31 sounding radio signals in a given spatial direction.

работает в готовности к приему излучаемого (прямого) и отраженного мобильным средством - носителем объекта радиоподавления зондирующих радиосигналов.Throughout the entire considered operating time interval of the COMPLEX in the active multi-position radar mode, the unit for determining its own coordinates 11, the active antenna 12, the receiver 13, the filter module of the interference signals 14, the filter module of the probing signals 15, the module for measuring the sounding signals 16 of the control point 4 and the unit for determining its own coordinates 24, active antenna 25, receiver 26, interference signal filter module 27, probe signal filter module 28, probe signal measurement module 29 s radio interference 3 _n ,

It works in readiness for the reception of the radiated (direct) and reflected by a mobile device - the carrier of the object of radio suppression of sounding radio signals.

) аддитивная смесь S_НПЗ, состоящая из навигационных сигналов от навигационных спутников ГНСС (S_H), помеховых сигналов от передатчиков радиопомех 31 станций радиопомех 3_n (S_П), в случае их одновременного излучения с зондирующим сигналом, излучаемого и отражаемого зондирующих сигналов (S_З) с выхода активной антенны 12 (25), поступает на первый вход модуля фильтров помеховых сигналов 14 (27). Модуль фильтров помеховых сигналов 14 (27) осуществляет режекцию (удаление) из принятой аддитивной смеси сигналов S_НПЗ всех помеховых сигналов S_П, идентифицируемых и локализуемых на фоне различного рода шумов (S_Ш), присутствующих на выходе активной антенны 12 (25). В результате такой фильтрации на выходе модуля фильтров помеховых сигналов 14 (26) в идеальном случае на фоне некомпенсированных шумов будет присутствовать аддитивная смесь навигационных и зондирующих сигналов S_НЗ.Accepted by active antenna 12 (25) (for control point 4 in brackets for radio interference stations 3 _n ,

) additive mixture S of the _refinery , consisting of navigation signals from GNSS navigation satellites (S _H ), interfering signals from radio interference transmitters 31 radio interference stations 3 _n ( _SP ), in case of their simultaneous emission with a probing signal, emitted and reflected sounding signals (S _C ) from the output of the active antenna 12 (25), it enters the first input of the filter module interference signals 14 (27). The interference signal filter module 14 (27) rejects (removes) from the received additive mixture S _refinery signals S all interference signals S _P identified and localized against the background of various kinds of noise (S _W ) present at the output of the active antenna 12 (25). As a result of such filtering, at the output of the filter module of interfering signals 14 (26), ideally, against the background of uncompensated noise, an additive mixture of navigation and sounding signals S _NS will be present.

From the output of the interference signal filtering module 14 (26), an additive mixture of navigation and sounding signals S _NS , as well as uncompensated noise is transmitted to the first input of the sounding signal filtering module 15 (28). The probe signal filter module 15 (28) identifies and selects the emitted (S _FR ) and reflected (S _OZ ) probe signals, followed by the output of these signals to the first output and then to the first input of the probe parameters measuring module 16 (29). In addition, the probe signal filter module 15 (28) rejects the probe signals S _З from the mixture of navigation and probe signals S _НЗ with the output of the navigation signals S _H against the background of uncompensated noise from the second output to the second output of the receiver 13 (26).

The module for measuring the parameters of the probing signals 16 (29) provides the determination of the time and frequency parameters of the probing signals S _IZ and S _OZ (delay time, Doppler frequency, etc.) with reference to a single time scale (E _CCD-3n - for radio interference station 3 _n , E _CCD-4 - for the control point 4), characterizing the spatial coordinates and parameters of the trajectory of the mobile vehicle carrier of the radio suppression object 2 _m . From the output of the module for measuring the parameters of the probing signals 16 (29), the synchronized values of the time and frequency parameters of the probing signals are transmitted to the third input of the calculator 8 (21). The computer 21 on the basis of the data E of the _CCD-3n generates report codograms and transmits them through the radio station 18 and the transmitting antenna 19 to the address of the control point 4.

, через приемную антенну 7 и радиостанцию 5 поступают в вычислитель 8.Radio signals containing codograms,

, through the receiving antenna 7 and the radio station 5 enter the transmitter 8.

) и от аппаратуры пункта управления 4 (Е_ПЗС-4), вычислитель 8 автоматически решает задачу определения пространственных координат, параметров траектории движения мобильного средства-носителя объекта радиоподавления 2_m и определения пространственных координат Q_i области пространства 1_m прогнозируемого на заданный интервал времени (t_Hi, t_Ki) местоположения объекта радиоподавления 2_m, а также формирования наряда станций радиопомех

.On the basis of an array of data on the values of the time and frequency parameters of the probing signals S _FROM and S _OZ received from radio interference stations (E _CCD-3n ,

) and from the equipment of control point 4 (E _CCD-4 ), calculator 8 automatically solves the problem of determining the spatial coordinates, the trajectory of the mobile vehicle carrier medium of the radio suppression object 2 _m and determining the spatial coordinates Q _{i of the} region of space 1 _m predicted for a given time interval ( t _Hi , t _Ki ) the location of the radio suppression object 2 _m , as well as the formation of the squad of radio interference stations

.

The results of solving these problems, the calculator 8 gives for visualization on the display 10.

согласно предписаниям плана применения КОМПЛЕКСА или внеочередному указанию вышестоящего органа управления вводит с пульта управления 9 в вычислитель 8 команду инициализации процедуры постановки радиопомех объекту радиоподавления 2_m в области пространства 1_m.Operator of control room 4, taking into account data on the order of radio interference stations

in accordance with the requirements of the COMPLEX application plan or an extraordinary instruction of a higher governing body, it enters from the control panel 9 into the calculator 8 a command to initialize the procedure for setting the radio interference to the radio suppression object 2 _m in the area of space 1 _m .

по назначению на интервале времени (t_Hi, t_Ki) с параметрами излучаемых радиопомех

и параметрами угловой ориентации передающей антенны 32, которые в соответствии с протоколом внутрикомплексного информационного обмена передает через радиостанцию 5 и передающую антенну 6 в адрес включенных в наряд

станций радиопомех 3_n.The computer 8, having accepted the command to initialize the procedure for setting the radio interference, generates codograms of regulations on the use of radio interference stations 3 _n ,

according to purpose on a time interval (t _Hi , t _Ki ) with parameters of emitted radio interference

and the angular orientation parameters of the transmitting antenna 32, which in accordance with the protocol of the intra-complex information exchange transmits through the radio station 5 and the transmitting antenna 6 to the address included in the outfit

radio interference stations 3 _n .

, то есть

.Radio signals containing codograms of regulations, through the receiving antenna 20 and the radio station 18 are supplied to the transmitter 21 of the radio interference station 3 _n included in the outfit

, i.e

.

); кодограмму задания блоку управления передатчиком 30, содержащую определенные предписанием амплитудные, частотные, фазовые и временные параметры помехового сигнала (

), которые должны быть сформированы и усилены передатчиком радиопомех 31.Having accepted and processed the codograms of the requirements, the calculator 21 generates and transmits via the intra-object communication lines: the codogram of the task to the transmitting antenna control unit 33, containing the angular orientation parameters of the transmitting antenna 32 defined by the prescription (

); the codogram of the task to the transmitter control unit 30, containing the amplitude, frequency, phase and time parameters of the interfering signal defined by the prescription (

), which must be formed and amplified by the radio interference transmitter 31.

кодограммы и сигналы в форматах специализированных интерфейсов управления функциональными модулями этого устройства.The control unit of the transmitting antenna 33 upon receipt of the control codogram generates and transmits to the address of the orientation device of the transmitting antenna 34 corresponding to the parameters

codograms and signals in the formats of specialized control interfaces for the functional modules of this device.

.The orientation device of the transmitting antenna 33, by processing these commands and signals, provides the orientation of the transmitting antenna 32 corresponding to the parameters

.

) и передает его на вход передатчика радиопомех 31.The transmitter control unit 30, upon receipt of the control codogram, generates an interfering signal with a specific requirement of amplitude, frequency, phase and time parameters (from the array

) and transmits it to the input of the radio interference transmitter 31.

псевдослучайного временного регламента работы

кодограммы и сигналы в форматах специализированных интерфейсов управления его функциональными модулями и устройствами усиливает их и передает на передающую антенну 32.The radio interference transmitter 31 upon receipt of the control codogram and the interference signal from the control unit of the transmitter 30 generates radio interference having the corresponding parameters

pseudo-random time schedule

codograms and signals in the formats of specialized control interfaces for its functional modules and devices amplifies them and transmits to a transmitting antenna 32.

The transmit antenna 32 emits radio interference generated and amplified by the radio transmitter 31 in the direction of a space region of 1 _m .

, обеспечивается уровень суммарной мощности некогерентных радиопомех не ниже требуемого для гарантированного радиоподавления НАЛ ГНСС.Thus, in the space region of 1 _{m, the} set of radio interference stations included in the outfit

, the level of the total power of incoherent radio interference is ensured not lower than that required for guaranteed radio suppression of the NAL GNSS.

The COMPLEX's work in creating radio noise in single regions of space 1 _m for non-intersecting time intervals (t _Ki ≤t _{Hi + 1} , i = 1, 2, 3, ...) seems to be a sequence of implementations of the above-mentioned regular single-cycle operation.

с учетом их текущего местоположения и технических возможностей по созданию радиопомех, последовательного сокращения ресурса (в первую очередь - количества) станций радиопомех для включения в очередной наряд (

) и приоритета (важности) объектов радиоподавления 2_m.If it is necessary to create radio interference simultaneously in several areas of the space 1 _m , the COMPLEX operation appears to be a parallel (quasi-parallel) implementation of several regular single cycles of operation. In this case, the task of control point 4 is the dynamic optimization of the generated orders of the radio interference station

taking into account their current location and technical capabilities for creating radio interference, a consistent reduction in the resource (primarily the number) of radio interference stations for inclusion in the next outfit (

) and priority (importance) of radio suppression objects 2 _m .

In the extreme case, if it is impossible to rank radio suppression objects 2 _m by priority, if it is impossible or inexpedient to localize areas of the radio jamming space 1 _m due to the significant number of spatially distributed radio suppression objects 2 _m , the COMPLEX will consist in forming the widest (approaching a circular) region of space in the azimuthal plane creating radio interference.

Claims (1)

A spatially distributed set of means for creating radio interference to the navigation equipment of consumers of global navigation systems with multifunctional use of electronic equipment containing a radio station connected to a transmitting and receiving antenna, as well as a power supply unit, while the radio station is connected to a computer connected to a control panel and a display, and the computer It is intended for determination of the area of location space predicted for a given time interval. of the radio suppression and control object of the N radio interference stations spaced in space N, each of which contains a radio channel of the control channel connected to the transmitting and receiving antennas, a power supply unit, while a radio station of the radio channel of the radio interference control station is connected to a radio interference station calculator connected to the control panel and a display, a computer radio interference station is designed to provide the angular orientation of the radiation patterns of antennas emitting radio interference, the radio interference station also contains a radio interference sensor with a radio interference antenna control unit, a radio interference transmitter control unit, a radio interference antenna angular orientation device, the transmitter control unit and a radio interference antenna angular position control unit associated with a radio interference station calculator, characterized in that an additional measuring instrument for determining the coordinates of the carrier of the corresponding component of the complex, active antenna, filter module of interfering signals, module filters of sounding signals, a module for measuring sounding signals, a unit for determining its own coordinates, while the active antenna is connected to the input of the filter module of interfering signals, the output of which is connected to the input of the filter module of sounding signals connected to the corresponding input of the module for measuring sounding signals, in addition, the second inputs the interference signal filter module, the probe signal filter module and the probe signal measurement module are connected to the output of the unit for determining the respective coordinates inat, which is interconnected with a receiver and calculator of the control point, and the output of the probe signal filter module is connected to the corresponding input of the receiver, an receiver is added to each of the N radio interference stations, designed to determine the coordinates of the carrier of the corresponding frequency of the complex, an active antenna, an interference signal filter module, probe signal filter module, probe signal measurement module, probe signal generation unit, while active ant it is connected to the input of the interference signal filter module, the output of which is connected to the input of the probe signal filter module connected to the corresponding input of the probe signal measurement module, in addition, the second inputs of the interference signal filter module, the probe signal filter module and the probe signal measurement module are connected to the input unit for determining its own coordinates, which is interconnected with the receiver and transmitter of the radio interference station, and the input of the filter module of the probing signals ene to a corresponding input priemoizmeritelya radio station, a probing signal forming unit is interconnected with the calculator radio station.

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