RU2513985C1 - Method for radio camouflaging stationary objects - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: in the method for radio camouflaging stationary objects, which detects information signals from satellite navigation systems distributed in space, interfering signals are generated the main lobe of the beam pattern of the navigation receiver using jamming means oriented in space in the upper hemisphere and at a height H=tg(α)·D, where α is the angle between the edge of the main lobe of the beam pattern and the horizon; D is the distance from a separate specific jamming means to the navigation receiver, wherein the interfering signal is chirp modulated in a frequency band equal to the variation range of Doppler frequencies of the detected signal.

EFFECT: enabling active jamming in the main beam pattern of antenna systems of navigation receivers of high-precision weapons and unmanned aerial vehicles.

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Description

The invention relates to techniques for electronic suppression of navigation systems and communication systems for weapons and military equipment.

A known method of protecting a strategic object (see US Pat. No. 3896439, IPC IPC: G018 7/38, H04K 3/00, published. 07/22/1975), in which when registering the signal reflected from the object, the interference signal is generated by modulating the received signal Radar thermal noise, the source of which is the input amplifier, the subsequent summation of the signals transmitted through the open switches of the key circuits in the adder and the amplification in the output amplifier. To ensure isolation between the input and output circuits and to control the operation of the detected radar station, an alternating gating of the input switch and the output UHF is performed. If the input of the device receives not one radar signal, but several, each with its own carrier frequency, then two or more frequency channels can be opened simultaneously. As a result, the spectral density of the interference power in each of them decreases, and therefore, the radar suppression efficiency decreases. An additional property of such a device is the ability to simultaneously create obstructive interference. In this case, the noise source, which is used as an input amplifier, can be connected directly to the output amplifier using a switch. The device effectively interferes with the airborne radar (radar) operating at close frequencies (in the same frequency channel). In a situation when several radar stations are located in the antenna pattern (BOTTOM) of the SP and they operate at different frequencies / in different frequency channels /, due to the increase in the width of the interference spectrum, the interference power density will decrease. For example, if the radiations of two radars in different frequency channels are simultaneously received, then the power density of the interference generated by each of them will decrease by half, and therefore, the suppression range will decrease by 1.4 times.

There is a method of protecting stationary (strategic) objects from high-precision weapons (WTOs) equipped with a navigation receiver by registering information signals from satellite navigation systems distributed in space, generating an interference signal, electronic suppression of satellite navigation systems (SNA) signals (for example, Navstar ") Ground-based (see VV Tsvetnov et al. Electronic warfare: radio masking and noise immunity, M., MAI. 1999, pp. 230-233).

The disadvantage of this method is the work in the side lobe of the radiation pattern of the antenna system of the navigation receiver. Also, a significant drawback is the possibility of operational direction finding of means for setting ground-based interference and their destruction.

Therefore, jamming from the ground requires, at a minimum, increasing the power of the interfering signal by 15-20 dB.

Most of the existing WTO samples of NATO countries in control systems use information from the Navstar SNA, better known as GPS. The WTO nomenclature, using information from the SNA, includes: Excalibur-type artillery shells, a universal set of equipment for free-falling JDAM bombs, cruise missiles of all modifications, non-nuclear intercontinental ballistic missiles (ICBMs), all unmanned aerial vehicles (UAVs) modifications. The experience of recent local wars shows that the number of WTOs using information from the SNA is growing exponentially. These types of WTO have a significant advantage, namely: high accuracy, all-weather, simplified control system. However, this advantage is also the “Achilles heel” of these types of WTOs - effective suppression of signals from the SNA, turns the WTO into ordinary weapons with the corresponding circular probability of deviation.

More than two decades have passed since the creation of the operational control segment (OCS), which includes the Central Management Station (MCS) in Shriver, Colorado (Schreiver AFB, Colorado) and surveillance stations around the world; launch of the first GPS satellites. During this time, several generations of satellites were developed, built and launched, the operation of the system was constantly supported by the operational control segment. Today, GPS is entering the new millennium with a far-reaching system modernization program, both on earth and in space.

The US Department of Defense (DoD US) initially developed the global positioning system (GPS) in the 70s only as a satellite navigation system for solving military tasks. In the early 80s, the Federal Commission on Radio and Navigation Planning carried out a combination of the development of the Ministry of Defense and the Ministry of Transport (DoT) in the field of further transforming the system into a global tool for positioning, navigation and time synchronization (PNT - positioning, navigation, and timing). The 1996 Presidential Directive and regulations (National Defense Authorization Act for Fiscal Year 1998, Public Law 105-85, section, 2281, November 18, 1997) oblige the US government and the Department of Defense to provide Precise Positioning Service (PPS) for military and other authorized users. In the future, the policy provides for the development of measures aimed at preventing the use of the GPS system even after its modernization by enemy forces, so that the United States and allies maintain a military advantage without disrupting the work of civilian GPS users.

Navstar satellite navigation system creates a navigation field with global coverage. To destroy the navigation field of this system, several approaches are possible.

1. Destruction of the satellite constellation. To solve this problem, it is necessary to at least disable 12 spacecraft of the Navstar SSS in order to destroy the permanent global coverage of the system. The solution to this problem requires the launch of 6 interceptor vehicles into 6 target orbits, which is a technically complex and economically expensive undertaking.

2. Destruction of control centers of the Navstar Naval Navigation System. The solution to this problem will not give a tangible effect, since the newest constellation of spacecraft SNS Navstar is equipped with an inter-satellite communication system and correction of time scales and ephemeris, which allows the satellite constellation to operate autonomously for at least 90 days.

3. The direct impact on the navigation receiver (NP) SNA Navstar. The solution to this problem is to interfere with navigation receivers, which is the most technically simple and economical way to disable navigation receivers. The disadvantage of this method is the local suppression of the navigation field of the SNA Navstar, depending on the power of the jamming means and their spatial position relative to the receivers.

The technical task of the present invention is the formation of interference signals from the upper hemisphere of a precision weapon (target) to increase the effectiveness of electronic suppression (protection of strategic objects from precision weapons equipped with a navigation receiver, and survivability of the jammer).

To implement the technical task in the method of radio masking of stationary objects, recording information signals from satellite navigation systems distributed in space, generating an interfering signal, interfering signals are generated in the main lobe of the radiation pattern of the navigation receiver using spatial jamming means oriented in space in the upper hemisphere and derived to the height

where α is the angle between the edge of the main lobe of the radiation pattern and the horizon; D is the distance from a single specific means of setting interference to the navigation receiver, while the interfering signal is modulated according to the linear frequency law in a frequency band equal to the range of variation of the Doppler frequencies of the recorded signal.

Analysis of the WTO and UAVs shows that the antenna systems of the NP are located so that the main lobe of the radiation pattern is directed at the satellites. Therefore, jamming from the ground requires at least an increase in the power of the interfering signal by 15-20 dB to compensate for the work in the side lobe of the radiation pattern of the NP. To effectively suppress the data of the NP, it is necessary to derive means of setting the interference to a height (1) sufficient to generate an interfering signal in the region of the main lobe of the antenna pattern of the navigation receiver. The interference signal is modulated according to the linear-frequency law in the frequency band equal to the range of Doppler frequencies.

To deliver means of setting interference to the required height, you can use an anti-aircraft guided missile (SAM) and an unguided rocket launcher multiple launch rocket system (NURS MLRS). Moreover, in each rocket it is necessary to install several dozen means of jamming. To maintain them at altitude, you can use nacelles with helium or hydrogen, which open after separation from missiles. This approach of withdrawal will allow covering a large area of a strategic object with one gulp.

The antenna pattern of the navigation receivers is typically 160 degrees wide.

Therefore, for interference to enter the main lobe of the radiation pattern, the height of the jamming means should be equal to:

H = tg (α) · D,

where α is the angle between the edge of the main lobe of the radiation pattern and the horizon; D is the distance from the jammer to the navigation receiver. The drawing shows the dependence of the height of the lifting means jamming from the range to the NP.

Thus, a complete disguise occurs - an increase in the technical efficiency of electronic suppression in a duel situation.

Claims (1)

The method of radio masking of stationary objects, by recording information signals from satellite navigation systems distributed in space using navigation receivers, generating an interfering signal, characterized in that the interfering signals are formed in the main lobe of the radiation pattern of the navigation receiver by arranging jamming means in space in the upper hemisphere and elevated to a height H = tg (α) · D, where α is the angle between the edge of the main lobe of the radiation pattern and the horizontal ont; D is the distance from a single specific means of setting interference to the navigation receiver, while the interfering signal is modulated according to the linear frequency law in a frequency band equal to the range of variation of the Doppler frequencies of the recorded signal.