RU2724368C1 - Secondary radar antenna system - Google Patents

Abstract

FIELD: antenna equipment.SUBSTANCE: invention relates to antenna engineering and can be used in designing antenna systems in secondary radar. Antenna system of the main channel in the form of a phased antenna array consisting of radiating elements has at least one device which enables connection of one or more radiating elements to both the main channel signals and SLS channel signals. Additional technical result is achieved by the fact that except for one (main) device, providing connection to one (or multiple) radiating elements (columns) signals of both main channel and SLS channel signals, introduced is at least one additional device, also providing connection to other or several other radiating elements of both main channel signals and SLS channel signals, also introduced is a unit which generates the required amplitude-phase distribution to form a differential beam pattern of the SLS antenna channel, connected to both said devices, which provide connection to radiating elements of signals of both main channel and SLS channel signals.EFFECT: increased width of operating frequency band of antenna system, which includes main antenna (antenna of main channel) and separate additional suppression antenna (SLS channel antenna), while maintaining small beamwidth and low level of side lobes RP of main antenna (antenna of main channel), simple design of antenna system, low weight and dimensions; besides, increase in space view speed is achieved.1 cl, 3 dwg

Description

The invention relates to antenna technology and can be used to create antenna systems in secondary radar.

When creating secondary radars, the problem arises of creating antenna systems that provide the transmission and reception of microwave signals through two independent channels. Moreover, in some cases it is required to install a small secondary radar antenna system in the radar

In a secondary radar station, targets such as airplanes are identified using radar transponders installed on each aircraft and interrogated by transmitted radar signals.

The ground-based radar station, referred to as the interrogator, transmits polling signals to the responder, which, in turn, transmits a response signal to the interrogator (Patent RU 2146379, G01S 13/78, H03G 3/30).

Since secondary radar systems are subject to the influence of synchronous interference arising from the transmission and reception of VRL signals on the side lobes of the radiation pattern (LH), it is likely that the transponder mounted on board the aircraft will receive a signal emitted from the side lobe of the LN, which will lead to distortion of the information received by the ground interrogator, and overload of the defendant. To exclude the response of the transponder from the signal emitted from the side lobe of the beam (fulfilling the established requirements (GOST R 51845-2001 SECONDARY RADAR SYSTEMS FOR AIR TRAFFIC CONTROL. General technical conditions, paragraphs 5.2.5, 5.2.7, 5.2.8, 7.1.1.7, ..., 7.1.1.8, 7.1.2.3, 7.1.2.5, 7.1.4.9, 7.1.4.6.4):

- reduce the level of the side lobes of the main channel (usually in the horizontal plane);

- use special methods of suppressing request signals received by the responder along the side lobe of the interrogator's DN and signals received by the VRL along the side lobes.

The implementation of special methods for suppressing request signals requires the inclusion of additional pulses (signals of the side-lobe suppression channel) in the code-sending request and response and a special form of the radar station beam providing an excess of the level of these signals over the level of request signals in the area of the side lobes of the main channel antenna (request channel) (Aviation radar, Davydov P.S., Sosnovsky A.A., Khaimovich I.A. Directory, M., Transport, 1984, p. 75).

To obtain the necessary special MD, two antennas are used, each of which is connected either to the input of the main channel equipment or to the input of the side lobe suppression channel equipment (PBL). These antennas together create the necessary radiation patterns. Antennas can be made both with the combined use of feeder path elements and radiating elements, for example, antennas that form a total radiation pattern for the main channel and a difference radiation pattern for the side lobe suppression channel, and two completely independent antennas.

So, in a remote analogue of the claimed invention, containing an antenna array made using horn emitters, ring bridges, dividers, attenuators, the formation of the total radiation pattern for the main channel and the difference radiation pattern for the channel suppression side lobes of the channel (Aviation radar, P. Davydov S., Sosnovsky A.A., Khaimovich I.A., Directory, M., Transport, 1984, pp. 111 ... 113).

This device suppresses request signals received by the transponder along the side lobe of the main channel of the interrogator and signals received by the VRL along the side lobes of the main channel of the main channel and has a relatively small antenna, since there are no separate antennas of the main channel and the PBL channel, the main channel antenna and the channel PBL combined, that is, share the radiating elements.

However, this device has the following disadvantages:

- the presence of a large number (by the number of horn emitters) of additional devices (ring bridges, dividers) that provide the formation of total and differential radiation patterns, which greatly complicates the antenna-feeder system, complicates the design of the entire antenna system, including the rotation mechanisms of the antenna, and ultimately increases weight and cost;

- relatively low rate of view of the space. To start the transponder, it is necessary that the signal level of the request exceeds the signal level of the PBL channel by at least 9 dB. The gap width of the differential DN is small (of the order of 2 degrees), this is due to the fact that the entire antenna array is used to create the differential radiation pattern (Aviation radar, P. Davydov, A. Sosnovsky, I. A. Khaimovich, Directory , M., Transport, 1984, p. 112). Therefore, the necessary ratio of signal levels (request signal and signal of the PBL channel) is performed in a very small area near the maximum of the channel length of the request channel. To identify the aircraft, the interrogator must receive at least a certain number of pulses from the transponder. The minimum time (the minimum number of pulses) required for communication between the interrogator and the responder is determined by the frequency of the repetition of the request and response signals, the width of the dip of the differential DN and the speed of rotation of the antenna (the rate of view of space). Since the maximum repetition frequency of request signals is limited, this time is determined mainly by the width of the region where the level of the request signal exceeds the signal level of the PBL channel by at least 9 dB. Thus, if the region where the level of the request signal exceeds the signal level of the PBL channel by at least 9 dB is small, then the antenna rotation speed should also be small. To increase the speed of rotation of the antenna, it is necessary to expand the area within which the necessary ratio of signal levels is performed. For this, additional attenuation is introduced in the feeder path of the PBL channel, reducing the signal level of the PBL channel. However, a significant decrease in the signal level of the PBL channel leads to the fact that the level of the side lobes of the request channel begins to exceed the signal level of the PBL. As a result, the transponder mounted on board the aircraft will receive a signal emitted from the side lobe of the request channel's DN, and this, in the end, also imposes restrictions on the antenna rotation speed;

- the small bandwidth of the working frequencies, due, in particular, to the presence of a large number of frequency-dependent devices (ring bridges). To ensure the operation of the antenna system in the desired ranges, 2 separate, independent systems are used.

A closer analogue, selected as a prototype in connection with the similarity of the technical task being performed, is the secondary radar antenna system, consisting of the main antenna of the interrogation channel, an antenna of the side-lane suppression channel installed outside the antenna of the main channel, a device that provides electrical communication between the antenna of the main channel and side lobe suppression channel antennas (Patent RU 2626221 H01Q 21/06, H01Q 25/00)

This antenna system does not use a large number of additional devices, which simplifies the design of the antenna system, reduces its weight and cost.

However, this antenna system has the following disadvantages:

- increased dimensions and weight due to the presence of both the main antenna (the antenna of the main channel), which itself can have large dimensions, necessary to ensure a relatively small width of the main beam of the beam and a low level of side lobes, and a separate additional antenna of suppression (antenna channel PBL ) mounted outside the main channel antenna web, often at a considerable distance from the main channel antenna.

- a small bandwidth of the operating frequencies, since in order to obtain a technical result (reducing the side lobe level, the main beam width of the channel channel antenna), it is necessary to provide a certain amplitude and phase distribution on the radiators of the antenna array (as a rule, in-phase) in both modes (mode request and response) and for both channels (main channel and PBL channel). The presence of an extended feeder path common to the main channel and the PBL channel, which also has a large number of different frequency-dependent devices (for example, different types of dividers), does not allow one to obtain the required phase distribution in a wide frequency band. This is due to the fact that for each of the frequencies there will be a different phase shift, different from the others, and the presence of an extended feeder path leads to the fact that the difference in phase shifts for different frequencies will be of great importance. When using the device (Patent RU 2626221 H01Q 21/06, H01Q 25/00) even in the RBS system due to the difference in the frequencies of reception and transmission (GOST R 51845-2001 SECONDARY RADAR SYSTEM FOR CONTROL OF AIR MOTION. General technical conditions, paragraphs .. 5.2.1, 5.3.2.2) the difference in phase shifts is significant and depends on the length of the extended feeder path common to the main channel and the PBL channel. To eliminate this, the use of microwave phase shifters is necessary. With the simultaneous use of systems, for example, RBS and EC GRLO, the use of microwave phase shifters no longer provides the necessary phase distribution, since the operating frequency band of microwave phase shifters is limited (microwave phase shifters and switches. Features of creation on p-in diodes in integral design. Khizha G. S., Vendik I.B., Serebryakova E.A. - M., "Radio and Communications", 1984 st. 164). Therefore, to work in several operating frequency ranges, the presence of frequency-separation devices and several different (in terms of the number of working ranges) phase shifters are required. In addition, the use of phase shifters significantly complicates the antenna system, due to the presence for each of the phase shifters, control devices, etc.

The technical result of the invention is an increase in the operating frequency bandwidth of the antenna system, which includes the main antenna (main channel antenna) and a separate additional suppression antenna (PBL channel antenna), while maintaining a small beam width and a small level of the side lobes of the main antenna (main antenna) channel), simplicity of design of the antenna system, low weight and dimensions.

An additional technical result is an increase in the rate of view of space.

The specified technical result is achieved by the fact that at least one device is introduced into the antenna system of the main channel in the form of a phased antenna array consisting of radiating elements in the form of columns, which ensures connection to one or several radiating elements (depending on the required shape antenna pattern of the PBL channel), both the signals of the main channel and the signals of the PBL channel.

An additional technical result is achieved by the fact that in addition to one (main) device, which provides connection to one or more radiating elements (columns of radiating elements) of the signals of both the main channel and the PBL channel signals, at least one additional device is introduced, which also provides connection to at least one of the remaining radiating elements (columns) of the signals, both the main channel and the signals of the PBL channel. Moreover, these devices outputs connected to the block that creates the necessary amplitude-phase distribution for the formation of a differential radiation pattern of the antenna channel PBL.

The simultaneous use of the main channel antenna system and the PBL channel antenna system is known (Patent RU 2626221, H01Q 21/06, H01Q 25/00, Patent RU 2122218, G01S 13/44). In both of these antenna systems in the antenna system of the side lobe suppression channel:

- for transmitting a PBL signal (receiving a signal for PBL equipment), antennas of both the PBL channel and the main antenna of the request channel are used in full (the entire main antenna of the request channel is used);

- the location of the antenna side channel suppression channel is precisely defined. It is installed either outside the main antenna of the request channel (Patent RU 2626221, H01Q 21/06, H01Q 25/00), or the PBL antenna is located on the axis of the antenna system, between the emitters of the main antenna of the request channel (Patent RU 2122218, G01S 13/44);

- the method of constructing the main antenna of the query channel can be any (radiating elements can be combined (constructively and functionally) both in columns and in rows).

The inventive device has distinctive features:

- for transmitting a PBL signal (receiving a signal for PBL equipment), only part (one or several columns) of the main antenna of the request channel is used. This part is an antenna, like a PBL channel;

- the location of the antenna side channel suppression channel is not defined, it can be any;

- radiating elements of the main antenna of the request channel can be made in the form of separate emitters or can be combined only in columns.

Thus, the proposed antenna system differs from the considered known antenna systems in both the methods of constructing the antenna system (including the PBL antenna) and the design features.

This allows us to conclude that the claimed invention meets the patentability criterion of "inventive step".

The invention will be more clear from the above description and the accompanying drawings, which depict the following:

Figure 1 shows a structural diagram of the proposed antenna system.

In Fig.2 shows a structural diagram of the proposed p. 2, the antenna system.

Figure 3 shows the radiation patterns formed by the antenna system of the main channel of the inventive device, the difference radiation pattern generated by the antenna system of the side lobe suppression channel of the claimed device according to claim 1 and the difference radiation pattern formed by the antenna system of the side lane suppression channel of the claimed device according to claim . 2.

Figure 1-3 and in the text the following notation:

1 - radiating elements (columns) of the antenna array;

2 - a device that provides the connection to the radiating element (columns) of signals, both the main channel and the signals of the PBL channel;

3 - a radiating element (column) of the antenna array connected to a device that provides the connection of signals, both the main channel and the signals of the PBL channel;

4 - equipment of the main channel;

5 - apparatus for suppressing side lobes (PBL);

6 - an additional device that also provides the connection to another radiating element of the signals, both the main channel and the channel signals PBL;

7 - radiating element (column) of the antenna array connected to an additional device that provides the connection of signals, both the main channel and the signals of the PBL channel;

8 is a block that creates the necessary amplitude-phase distribution for the formation of a differential radiation pattern of the antenna channel PBL.

9 is a radiation pattern formed by the antenna system of the main channel of the inventive device;

10 is a radiation pattern formed by the antenna system of the suppression channel of the side lobes of the inventive device according to claim 1;

11 is a differential radiation pattern formed by the antenna system of the side lobe suppression channel of the inventive device according to claim 2, option 1;

12 is a difference radiation pattern formed by the antenna system of the side lobe suppression channel of the inventive device according to claim 2, option 2.

The antenna system contains:

- radiating elements of the antenna array, which can be made in the form of individual emitters or in the form of columns (1);

- a device (2) that provides signals to the radiating element (columns), both from the main channel equipment (4) and signals from the side lobe suppression equipment (5) to the radiating element (3). Device (2) can be made in the form of a switch on semiconductor diodes (Ilchenko M.E., Osipov V.G. Electrically controlled microwave switches on semiconductor diodes (review), Izv. Universities of the USSR. Radio Engineering, 1977 vol. 20, No. 2 ), can be performed in the form of a divider (adder) (Design and calculation of microwave elements on strip lines, L. L. Maloradsky, L. M. Yavich, “Soviet Radio”, 1972). The implementation of the device (2) in the form of a switch on semiconductor diodes allows you to get the minimum loss of the microwave signal, but requires a low-frequency control source of current and voltage, which complicates the design of the antenna system. The implementation of the device (2) in the form of a divider can do without a low-frequency control source, which greatly simplifies the design of the antenna system, but increases the loss of the microwave signal;

- a radiating element (column) of the antenna array (3) connected to the device (2), which provides the connection of signals, both the main channel and the signals of the PBL channel. The radiating element (3) along with the radiating elements (1) forms the antenna of the main channel, i.e. structurally included in the entire antenna array. At the same time, the radiating element (3) is the antenna (or part of the antenna) of the PBL channel;

- equipment of the main channel (4);

- equipment for suppressing side lobes (PBL) (5);

- an additional device (6), which also provides the connection to another radiating element of the signals from the equipment of the main channel (4), as well as signals from the apparatus for suppressing the side lobes (5) to the radiating element (7). The additional device (6) can also be made in the form of a switch on semiconductor diodes or in the form of a divider (adder);

- the radiating element (7) of the antenna array is connected to an additional device (6) that provides the connection of signals of both the main channel and the signals of the PBL channel. The radiating element (7) is also structurally included in the entire antenna array (main channel antenna) and is part of the PBL channel antenna, which forms a differential radiation pattern for the PBL channel;

- block (8) creates the necessary amplitude-phase distribution for the formation of a differential radiation pattern of the PBL antenna channel. Block (8) can be made, for example, in the form of a ring bridge (Design of lens, scanning, wide-range antennas and feeder devices., Zhuk M.S. and Molochkov Yu.B. M., "Energy", 1973). Block (8) is attached to both devices (2) and (6).

The antenna system works as follows.

The radiating elements 1 of the antenna system, including the radiating element (radiating elements of the column) (3), connected through the device (2) to the equipment of the main channel (4), form together the radiation pattern of the antenna of the main channel with a narrow main lobe and side lobes of a small power level.

The narrow main lobe and the low level of the side lobes are due to the increased, due to the inclusion of the PBL channel antenna in the main channel of the antenna, which leads to a decrease in the overall dimensions of the antenna system, while maintaining the simplicity of the antenna system design, low weight and cost.

The radiating element (radiating elements of the column) (3) of the antenna system, connected through the device (2) to the equipment of the side-lobe suppression channel (5), forms the radiation pattern of the antenna of the side-lane suppression channel.

The increase in the working frequency bandwidth of the antenna system is achieved due to the fact that there is virtually no common part of the feeder path for the main channel and the PBL channel, and a small phase shift (less than 10 degrees), which gives the device (2), and which can affect the diagram directivity of the antenna of the main channel, can be easily compensated.

In antenna arrays having an amplitude distribution decreasing towards the edges, when using the device (2) in the form of a divider, it is desirable to use a radiating element (3), which is installed closer to the edge of the antenna array. In this case, a lower level of the microwave signal of the main channel entering the radiating element (3), compared with the level of the microwave signal entering the symmetrically located radiating element, has little effect on the shape of the general radiation pattern of the antenna of the main channel. Thus, a decrease in the level of a microwave signal by 3 dB in a radiating element (3) located on the edge of the antenna array for a array of 12 radiating elements having an amplitude distribution falling to the edges leads to an increase in the level of the side lobes of the radiation pattern of the main channel by about 1 dB, the width of the main lobe of the radiation pattern of the main channel remains unchanged. When using the device (2) in the form of a divider, as a radiating element (3) in antenna arrays having a uniform amplitude distribution, the location of the radiating element (3) is less important. So when using a radiating element (3) installed in the center of the antenna array web having a uniform amplitude distribution, the level of the side lobes of the directivity pattern of the main channel increases by 1 dB. When using a radiating element (3) installed in the center of the antenna array of 12 radiating elements, having an amplitude distribution falling toward the edges, the level of the side lobes of the directivity pattern of the main channel increases by 5 dB. The implementation of the device (2) in the form of an unequal amplitude divider will lead to less attenuation of the microwave signal of the main channel in the radiating element (3), which will practically not lead to an increase in the level of the side lobes of the radiation pattern of the main channel.

When using the device (2) in the form of a switch, as a radiating element (3) in antenna arrays having any amplitude-phase distribution, the location of the radiating element (3) does not matter, since in this case the level of the microwave signal of the main channel is practically not is changing.

Depending on the requirements for the directivity pattern of the PBL antenna, several devices can be introduced into the antenna system of the main channel in the form of a phased antenna array, each of which provides connection to one (each to its own) of the radiating elements (columns) of signals, both the main channel and and signals of the PBL channel. Several radiating elements can be connected to this device, however, an extended feeder path common to the main channel and the PBL channel appears, the length of which, of course, is much less than the length of the common feeder path of the antenna system selected as a prototype (Patent RU 2626221 H01Q 21/06 , H01Q 25/00).

In some cases, a small secondary antenna radar system is required in the radar. In a small antenna system of the primary channel of the secondary radar, the signal level of the request exceeds the signal level of the PBL channel by 9 dB in a very small area near the maximum of the channel of the request channel (OK). This circumstance limits the speed of rotation of the antenna (the rate of view of the space). To increase the area in which the level of the request signal exceeds the signal level of the PBL channel by 9 dB, additional attenuation is introduced in the feeder path of the PBL channel, reducing the signal level of the PBL channel. But a decrease in the signal level of the PBL channel can cause the level of the side lobes of the request channel to exceed the signal level of the PBL, as a result of which the transponder mounted on board the aircraft will receive a signal emitted from the side lobe of the signal path of the request channel. Therefore, to avoid this, the decrease in the signal level of the PBL channel should be insignificant. However, a slight decrease in the signal level does not allow to significantly increase the area with the necessary excess of the signal level of the request above the signal level of the PBL channel, which limits the speed of rotation of the antenna (the rate of view of the space).

An increase in the rate of the space survey can be achieved through the use of a difference radiation pattern formed by radiating elements (3) and (7) included in the antenna array.

The radiating element (3) is connected to the device (2), which provides the connection of signals, both the main channel and the signals of the PBL channel. The radiating element (7) is connected to an additional device (6), which also provides the connection to another radiating element (7) of signals from the main channel equipment (4) and signals from the side lobe suppression equipment (5). The device (2) and the additional device (6) are connected to the block (8), which creates the necessary amplitude-phase distribution for the formation of a differential radiation pattern of the PBL antenna of the channel. Devices (2) and (6) can be made in the form of a switch on semiconductor diodes or in the form of a divider (adder). Block (8) can be made, for example, in the form of a ring bridge or, if the operating ranges are very different, to create the necessary phase distribution use can be used, for example, frequency separation devices, broadband dividers (microwave technology. Textbook. Manual) for Universities, N.M. Sovetov, M., "Higher School", 1976 pp. 88-90, Microwave Circuit Analysis and Automatic Design.V. Fusco, translated from English by A.A. Volman, A.D. Muravtsova, under the editorship of V.I. Volman, M Radio and Communication 1990 p. 271) and microwave lines of different lengths. Using for generating a differential radiation pattern of individual emitting elements allows, in contrast to the difference radiation pattern of a PBL antenna in an analogue of the claimed invention (Aviation radar, Davydov P.S., Sosnovsky A.A., Khaimovich I.A., Directory, M., Transport, 1984, p. 111 ... 113) to obtain a differential radiation pattern (11) with a "wide zero" (the width of the dip is 11.8 degrees) (see Fig. 3). The obtained difference beam pattern of the PBL channel (11) with a “wide zero” allows you to increase the area in which the signal level of the request exceeds the signal level of the PBL channel by 9 dB from 5.6 deg (in the antenna system claimed in claim 1) to 11.8 hail (in the antenna system claimed in claim 2) and, therefore, increase the rate of view of the space.

The use of elements located in different places of the antenna array as radiating elements (3) and (7) allows one to obtain difference radiation patterns (11) (12) of the PBL channel (Fig. C) of different shapes and with a different region in which the signal level of the request exceeds the signal level of the PBL channel by 11.8 degrees (radiation pattern (11)) and 9.6 degrees (radiation pattern (12)).

Using the proposed invention will increase the bandwidth of the antenna system including the main antenna (main channel antenna) and a separate additional suppression antenna (PBL channel antenna), while maintaining a small beam width and a small level of the side lobes of the main antenna (main antenna) channel), the simplicity of the design of the entire antenna system, its small weight and dimensions, as well as to increase the rate of view of the space.

Claims (2)

1. The antenna system of the secondary radar, consisting of an antenna system of the main channel in the form of a phased antenna array containing radiating elements, characterized in that at least one device is introduced that provides connection to one or more radiating elements of both the signals of the main channel and the signals side lobe suppression channel (PBL). 2. The secondary radar antenna system according to claim 1, characterized in that at least one additional device is introduced, which also provides the connection to another or several other radiating elements of both the signals of the main channel and the signals of the PBL channel, and a unit is created that creates the necessary the amplitude-phase distribution for the formation of a differential radiation pattern of the antenna of the PBL channel, connected to both devices, which provide the connection to the radiating elements of the signals of the main channel and the signals of the PBL channel.

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