RU2726939C1 - Complex of creation of radio-interference to equipment of consumers of global navigation satellite systems - Google Patents

Abstract

FIELD: radio equipment.SUBSTANCE: invention relates to radio engineering and can be used in development of radio-electronic suppression devices (RES) of receivers of consumer equipment of global navigation satellite systems (GNSS), in particular, placed on ships, aircraft, cruise missiles, unmanned aerial vehicles, in systems of precision weapons. In addition, the radio interference station includes a second radio interference transmitter with an antenna angular orientation device in the direction of local objects and the underlying surface in the region of radio suppression object location, due to reflections and multi-beam propagation of radio waves, multiple directions of arrival of interference to antennas of receiving devices of GNSS users are provided. At that, polarization of the antenna of the second transmitter is orthogonal – opposite direction of rotation – as compared to polarization of the signal used in the GNSS system.EFFECT: technical result consists in improvement of suppression efficiency.1 cl

Description

The invention relates to the field of radio engineering and can be used in the development of means of electronic suppression of receiving devices of the equipment of consumers of global navigation satellite systems (GNSS), in particular, placed on ships, aircraft, cruise missiles, unmanned aerial vehicles, in high-precision weapons systems, etc. ...

Known radio interference transmitters containing radio interference shapers, amplifiers and transmitting antennas with appropriate connections and capable of generating radio interference to receivers of users of navigation satellite systems [see, for example, RF utility model No. 30054, IPC Н04K 3/00, publ. June 10, 2003; utility model of the Russian Federation No. 31891, IPC N04K 3/00, publ. August 27, 2003; useful model of the Russian Federation No. 113620, IPC N04K 3/00, publ. 02/20/2012; Dyatlov A.P., Dyatlov P.A., Kulbikayan B.Kh., Electronic warfare against satellite radio navigation systems. - M .: "Radio and communication", 2004, p. 202-211].

The disadvantage of transmitters is the low efficiency of electronic jamming of receivers of GNSS consumers, in which adaptive digital antenna arrays (ADA) are used. The use of the CAR provides, due to the adaptive formation of "zeros" in the antenna pattern of the receiving devices of GNSS consumers, suppression of interference from single sources by 40 dB or more [see, for example, V. Slyusar. Digital antenna arrays. GPS problem solutions. Electronics: Science, Technology, Business. 2009, No. 1, p. 74-78].

Known spatially distributed systems of electronic suppression of receivers of consumers of global navigation satellite systems [see, for example, patent RU No. 2656247, C1, IPC H04K 3/00, publ. 06/04/2018; patent RU No. 2666126, C1, IPC G01S 7/36, H04K 3/00, publ. 09/06/2018]

The disadvantage of spatially distributed systems is also the low efficiency of electronic suppression of receivers of GNSS consumers, in which adaptive CARs are used. The fact is that jamming transmitters of spatially distributed systems have a limited range and are installed from each other at a distance that ensures the continuous stay of a mobile GNSS consumer in the coverage area of at least one jamming module. That is, electronic jamming of the receivers of GNSS consumers in each period of time is provided, as a rule, by one of the transmitters of the system.

The closest in technical essence to the claimed invention is a spatially distributed complex of means of creating radio interference to receiving devices of mobile GNSS consumers, consisting of reconnaissance means, a control point and radio interference stations [see, for example, patent RU No. 2563972, C1, IPC Н04K 3/00 , published September 27, 2015]. The operation of the complex is based on the concentration of the total energy of a set of radio interference of low power, separated in space, in a given region of space at a given time interval. In this case, the creation of deliberate radio interference of high power is ensured by the coordinate-time support of the interaction of reconnaissance means and several radio interference stations.

The disadvantage of the complex is the low efficiency of electronic suppression of receivers of GNSS consumers, in which multi-element adaptive CARs are used. In such antenna arrays, the maximum number of directions in which the formation of "zeros" in the directional pattern of a CAR is N-1, where N is the number of antenna elements of a CAR. [see, for example, Slyusar V. Digital antenna arrays. GPS problem solutions. Electronics: Science, Technology, Business. 2009, No. 1, p. 74-78]. It is also known that in 7 - element and 19 - element CARs it was possible to obtain interference suppression of three and six broadband stations by 50 dB, respectively [see, for example, Yu.A. Soloviev. Satellite navigation systems. - M .: Eco - Trends, 2000, p. 145-149]. The creation of a large grouping of jamming stations located from different directions relative to the radio suppression object seems to be problematic. In addition, the implementation of the known complex requires complex coordinate-time support for the interaction of reconnaissance means and jamming stations, which leads to the presence of extra control links at the operational level when several reconnaissance means and jamming stations operate in one zone.

The technical result of the invention is to increase the efficiency of electronic suppression of receivers of GNSS consumers by irradiating carriers, local objects and the underlying surface with interference and creating, due to reflections and multipath propagation of radio waves, numerous directions of interference to receivers of GNSS consumers. This makes it impossible to form "zeros" in the diagram directivity of the CAR in all directions necessary to compensate for interference, even in antenna arrays with a large number of elements and, accordingly, increases the efficiency of electronic suppression of receivers of GNSS consumers.

The specified technical result is achieved by the fact that in the well-known complex of creating radio interference to the equipment of consumers of global navigation satellite systems (GNSS), containing a reconnaissance station connected by communication lines for detecting and determining the location of the radio suppression object, a control point predicting for a given time interval the area of space where the radio suppression object is located, and a radio interference station with a device for angular orientation of the antenna of the radio interference transmitter in the direction of the radio jamming object, according to the invention, a second radio interference transmitter with a device for angular orientation of the antenna in the direction of local objects and the underlying surface in the area of the radio jamming object is additionally introduced into the radio interference station.

The specified technical result is achieved in that the polarization of the antenna of the second transmitter is orthogonal - the opposite direction of rotation in comparison with the signal polarization used in the GNSS system.

The essence of the invention lies in the fact that a second radio interference transmitter is additionally introduced into the radio interference station with a device for angular orientation of the antenna in the direction of local objects and the underlying surface in the area where the radio suppression object is located, and due to reflections and multipath propagation of radio waves, numerous directions of interference arrival at the antennas of the receiving devices are provided GNSS consumers. This makes it impossible to form "zeros" in the directional pattern of the CAR in all directions necessary to compensate for interference, especially in antenna arrays with a small number of elements. Taking into account that when reflecting radio waves with circular polarization (in the GNSS system signals with circular polarization are used), the direction of rotation of the polarization vector changes to the opposite [see, for example, VN Tatarinov, SV Tatarinov, LP Ligthart. Introduction to the modern theory of polarization of radar signals (Volume 1. Polarization of plane electromagnetic waves and its transformation). - Tomsk: Ed. Tomsk University, 2012, p. 273-276], the polarization of the antenna of the second transmitter is orthogonal - the opposite direction of rotation compared to the polarization of the signal used in the GNSS system. This ensures the polarization-matched reception of interference reflected from the carrier elements, local objects and the underlying surface, by the receivers of GNSS consumers. In addition, with electronic jamming of receivers of navigation equipment of GNSS consumers along the side lobes of their antenna directional patterns, the level of interference at the input of receivers for cross-polarization can be higher than for operating polarization [see, for example, Perunov Yu.M., Fomichev K .I., Yudin LM, Electronic suppression of information channels of weapons control systems. - M .: "Radiotekhnika", 2003, p. 393-394]. This is an additional positive factor in generating orthogonal polarization (cross polarization) interference compared to the signal polarization used in the GNSS system.

Thus, the technical result specified in the invention is achieved.

The proposed complex for creating radio interference to the equipment of consumers of global navigation satellite systems contains a reconnaissance station connected by communication lines for detecting and determining the location of the radio suppression object, a control point predicting for a given time interval the area of space of the location of the radio suppression object, and a radio interference station with two radio interference transmitters with angular orientation devices ... Moreover, the polarization of the antenna of the first radio interference transmitter coincides with the signal polarization used in the GNSS system, and the polarization of the antenna of the second transmitter is orthogonal — the opposite direction of rotation compared to the signal polarization used in the GNSS system.

The purpose of the components of the complex is clear from their name and they are similar to the prototype. All components of the complex can be made using the radio-technical elements produced by the industry. Additionally, the second radio interference transmitter with a device for the angular orientation of the antenna, introduced into the complex for creating radio interference, can be made similar to the transmitter of the prototype. The difference lies in the fact that the antenna of the second transmitter is made with polarization orthogonal (opposite direction of rotation) compared to the signal polarization used in GNSS. It is known, for example, that GNSS GPS uses signals with right-hand circular polarization of radiation [see, for example, Yu. A. Soloviev. Satellite navigation systems. M .: Eco - Trends, 2000, p. 53] and the polarization of the radiation does not change during the GNSS operation. The implementation of circular (left or right directions of rotation) polarization of radiation is provided, for example, by widely used spiral antennas [see, for example, A.Z. Fradin. Antenna feeder devices. M .: Communication, 1977, p. 279]. The implementation of the antenna of the proposed transmitter does not imply the use of any peculiarities in the known antennas with circular polarization of radiation and it can be performed similarly to the known solutions. We estimate the feasibility of technical implementation of the second interference transmitter according to the requirements for its energy potential (the product of the transmitter output power by the antenna gain). Requirements for the energy potential of the second interference transmitter are determined from the condition that the interference power at the input of the GNSS consumer receivers is not less than the power of the satellite navigation signal P ₀ = -157 - -162 dB W [see, for example, Yu.A. Soloviev. Satellite navigation systems. - M .: Eco - Trends, 2000, p. 30-31]. The interference emitted by the second transmitter enters the antenna of the receivers of GNSS consumers due to reflections from structural elements of carriers, local objects and other objects located in the area of the radio suppression object, and multipath propagation of radio waves. The interference power at the input of the receiving devices (P _{n in} ) is determined under conditions of wave propagation in free space [see, for example, Dolukhanov M.P. Propagation of radio waves. Textbook for universities. M., "Communication", 1972, p. 19-24]:

Where:

P _p G _p - the output power and the directivity of the antenna of the second interference transmitter, respectively;

R is the distance from the jammer to the elements of the carriers, local objects and the underlying surface in the area where the receivers of GNSS consumers are located;

σ - effective scattering surface of carrier elements, local objects and underlying surface;

R _about - distance from carrier elements, local objects and underlying surface to receivers of GNSS consumers;

G is the directivity factor of the antennas of the receivers of GNSS consumers;

λ is the wavelength of the carrier oscillation of the GNSS radio signal.

The condition P _p inx ≥ P _o is satisfied when:

Calculations show that for typical values R = 25… 50 km, σ = 1… 10 m ² , R _about = 100… 500 m, G = 1, λ = 0.18; 0.24 m. The condition P _p inx ≥P _about is fulfilled when P _p G _p ≥10 ³ -10 ⁴ W. That is, for example, with the transmitting antenna gain equal to 100 (the antenna radiation pattern width is about 15 × 15 degrees), the transmitter power will be no more than 100 W. Interference transmitters with such a value of the energy potential are known [see, for example, A.I. Paliy. Electronic warfare. M: Military Publishing, 1981, p. 294-303], and the implementation of the second transmitter in the claimed invention can be performed by one of the known solutions, including a similar one to the prototype jammer.

The complex for creating radio interference to the equipment of consumers of global navigation satellite systems works as follows. As in the prototype, upon a command transmitted over the communication line from the control point, the reconnaissance station collects data on the spatial coordinates and parameters of the trajectory of the radio suppression object. Through the communication line, data about the radio suppression object is transmitted to the control point, where the area of space of the radio suppression object location is predicted for a given time interval. In accordance with the plan for the use of the complex, a command about the parameters of the generated interference and the angular orientation to the radio suppression object and to the area of space where the radio suppression object is located is transmitted via the communication line from the control point to the radio interference station for a given time interval. The device for angular orientation of the antenna of the first transmitter of the radio interference station orients the antenna to the object of radio suppression, and the device for angular orientation of the antenna of the second transmitter orients the antenna in the direction of the location space of the object of radio jamming. The radio interference of the first transmitter directly goes to the antennas of the receiving devices of the GNSS consumers, and from the second transmitter after reflections from local objects and the underlying surface in the area where the object of radio suppression and multipath propagation of radio waves is located. Thus, multiple directions of interference to the antennas of the receivers of GNSS consumers are provided.

When the carriers of the receivers of GNSS consumers move, according to information from the reconnaissance station, the location of the radio suppression object is specified and, accordingly, the orientations of the antennas of the jammers are specified. This ensures the continuity of the interference.

This achieves the technical result specified in the invention.

The set of newly introduced elements and connections together with the rest of the elements and connections of the complex does not follow explicitly from the prior art. There are no sources of information in which the specified set of elements and connections alone or in combination with other elements and connections of the proposed complex would be described. This allows us to consider the claimed complex as new and having an inventive step.

The proposed technical solution is practically applicable, since standard radio-electronic assemblies and devices can be used for its implementation. The use of the invention provides an increase in the efficiency of electronic suppression of receivers of GNSS consumers.

Claims (2)

1. A complex for creating radio interference to the equipment of consumers of global navigation satellite systems (GNSS), containing a reconnaissance station connected by communication lines for detecting and determining the location of a radio suppression object, a control point predicting for a given time interval the area of space where the radio suppression object is located, and a radio interference station with an angular orientation device antenna of the radio interference transmitter in the direction of the radio jamming object, characterized in that, in addition, a second radio interference transmitter is introduced into the radio interference station with a device for angular orientation of the antenna in the direction of local objects and the underlying surface in the area of the radio jamming object, while radio interference is transmitted through the communication line from the control point to the station command about the parameters of the generated interference and the angular orientation to the radio suppression object and to the area of the space where the radio suppression object is located for a specified time interval. 2. The complex according to claim 1, characterized in that the polarization of the antenna of the second radio interference transmitter is orthogonal - the opposite direction of rotation in comparison with the signal polarization used in the GNSS system, and the width of the antenna pattern provides simultaneous irradiation of local objects dispersed in space and the underlying surface in the area where the object of radio suppression is located.