RU2617517C1 - Nonstationary periscopic antenna system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: antenna system consists of a free-center support, a radiator located inside the free-center support, a re-emitter mounted on the support and having the ability to change the azimuth orientation within the wide range (to rotate). Moreover, the re-emitter is located in such a way that the center of its projection is also inside the support. In this case, the emitter is made in the form of an antenna with rotating field polarization, and a polarizer is installed between the emitter and the re-emitter, transforming the wave with circular polarization into a wave with a different polarization and having the ability to change the azimuth orientation in wide ranges (to rotate), wherein the polarizer and the re-emitter is rigidly interconnected.

EFFECT: eliminating the polarization plane change, when changing the orientation of the re-emitter.

2 cl, 1 dwg

Description

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

In many cases, to increase the range of radio communication systems and radar, antennas must be installed at a considerable height. For example, antennas for microwave links to provide direct visibility are usually installed on poles 70-100 m high. In this case, it becomes necessary to either place transceiver equipment directly on the pole or use a long RF path to transmit the RF signal from the equipment located below to the antenna located on the mast. The transceiver equipment usually has significant weight and size indicators, so placing the equipment directly on the support leads to a complication of the construction of the support, to a significant increase in its weight and cost, especially if there is a need to change the direction of radiation of the antenna (ed. St. USSR No. 202243, cl. 21a ⁴ , 1967). To transmit the RF signal from the transceiver equipment located below to the antenna located on the mast, it becomes necessary to use a long RF path, which complicates the equipment and, as a result, reduces reliability and increases cost, as well as complicates its maintenance during operation. When changing the direction of radiation of the antenna, it becomes necessary to use a rotating joint. When changing the direction of antenna radiation in two planes, it is necessary to use two rotating joints and a vertical rotation mechanism of the antenna located on a rotating platform (ed. St. USSR No. 1810940 A1, IPC H01Q 3/04, 1991). All this leads to a significant complication of the equipment, to a decrease in reliability and an increase in cost.

The use of periscopic antenna systems allows to eliminate these problems.

The periscopic antenna system consists of a lower mirror-emitter located on the ground, and an upper mirror-re-radiator mounted sideways on the edge of the support. The lower mirror can be placed either directly on the side at the foot of the support, or at a distance from it. “The upper re-emitter mirror is usually flat; the lower mirror has a paraboloidal surface. It is also possible to use lower mirrors with an ellipsoidal surface. The contour of the upper mirrors is elliptical, rectangular or rhomboid; the projection of the opening of the upper mirror onto a plane normal to the direction of propagation has the form of a circle or square. ” Mirrors with round (in projection) openings provide a greater gain, as well as a decrease in side lobes (VHF antennas. G.Z. Aizenberg, V.G. Yampolsky, O.N. Tereshin, Part 2, M., Communication, 1977, pg. 99-101).

In this antenna system, the transceiver equipment is located on the ground, which simplifies the design of the support and reduces its cost, the RF path between the equipment and the lower mirror has a relatively short length and, therefore, has high reliability, low cost and is easy to maintain. However, it is also necessary to ensure a change in the direction of radiation.

So, in a remote analogue of the claimed invention, the antenna system contains an emitter located next to the transceiver equipment, and an upper re-emitter mirror mounted on top of the support, and the orientation of the re-emitter mirror changes both in elevation and azimuth (USSR Author's Certificate No. 112601 Cl. 24a ⁴ 66 ₀₅ , H01Q 3/12, 1957).

In this antenna system, it is possible to change the orientation of the re-emitter mirror within small limits, which allows changing the direction of radiation.

However, this antenna system has the following disadvantages:

- the impossibility of changing the orientation in azimuth of the re-emitter mirror over a wide range (antenna rotation);

- the complex design of the antenna orientation device. To change the direction of radiation, a mechanical change in the position of the mirror is necessary. Such an antenna orientation system has a complex structure and is difficult to operate. This is due to the need for a mechanical change in the position of the mirror both in elevation and in azimuth. In addition, a change in the slope leads to a change in the projection of the aperture of the upper mirror onto the plane, normal to the direction of propagation, which affects the radiation pattern (since a decrease in the projection leads to an increase in the size of the side lobes, an expansion of the main lobe of the radiation pattern) (VHF antennas. Eisenberg, V.G. Yampolsky, and O.N. Tereshin (Part 2, M., Communication, 1977, p. 116). To avoid this, it is necessary to significantly increase the size of the mirror, which causes an increase in its weight, windage, which, in turn, leads to an increase in the inertia of the system, which further increases the time of changing the direction of radiation. All this, ultimately, significantly increases the cost of the antenna system;

- a change in the plane of polarization with a change in the orientation of the mirror re-emitter.

A closer analogue, selected as a prototype in connection with the similarity of the technical task being performed, is an antenna system consisting of a support with a free center, a radiator located inside the support with a free center, a re-emitter mirror mounted on the support and having the ability to change the azimuth orientation in wide (rotate), and the re-emitter mirror is located in such a way that the center of its projection is also inside the support, and the emitter is located in the upper part of the support, in a place that excludes yanie structural support elements and deteriorating the noise immunity (patent №2561238, Nonstationary periscope antenna system IPC H01Q 3/04, H01Q 19/10).

This antenna system is different:

- the possibility of changing over a wide range, up to the circular, orientation of the mirror-re-emitter, which allows you to change the direction of radiation.

However, this antenna system has a drawback.

The use of a microwave signal of any other than circular polarization with a change in the orientation of the re-emitter mirror leads to a change in the plane of polarization. A change in the plane of polarization with a change in the orientation of the re-emitter mirror can lead either to a significant decrease in the level of the receiving signal (in the case of using this antenna system in radio relay communication) or to a significant decrease in the level of the received reflected echo signal (in the case of using this antenna system in radar) ( Design of lens, scanning, wide-range antennas and feeder devices. Zhuk M.S., Molochkov Yu.B. M., "Energy", 1973, p. 127, 128).

The technical result of the invention is the elimination of changes in the plane of polarization when changing the orientation of the re-emitter.

An additional technical result is an arbitrary change in the plane of polarization, not associated with a change in the orientation of the re-emitter.

The specified technical result is achieved by the fact that in an antenna system consisting of a support with a free center, a radiator located inside the support with a free center, a re-emitter mounted on the support and able to change the azimuth orientation in a wide range (rotate), and the re-emitter is located such so that the center of its projection is also inside the support, the emitter is made in the form of an antenna with rotating polarization of the field, and a polarizer is installed between the emitter and the re-emitter, transforming yuschy wave with circular polarization into waves with different polarization and having the ability to change the orientation of the azimuthally over a wide range (rotated), wherein the polarizer and the re-radiator are rigidly interconnected.

An additional result is achieved by the fact that the polarizer has the ability to change the azimuth orientation over a wide range (rotate), regardless of the orientation of the re-emitter.

Known antenna devices using polarizers. So, for example, the antenna system (US 2994873 A, 08/01/1961) uses a polarizer made in the form of a grid of parallel wires spaced from each other at a distance of less than half the wavelength (wire reflector 15 (US 2994873 A, FIG. 9)). The wires run parallel to the electric field E and, therefore, reflect only the microwave signal having horizontal polarization (parallel to the electric field E). A microwave signal having vertical polarization (perpendicular to the electric field E) passes through this grid. The polarizer (wire reflector) is fixed (it does not change its position when the re-emitter orientation changes) and serves to ensure that the signal from the transmitter is fed to the antenna, and the received signal from the antenna is fed to the input of the receiver. The separation of the receiving and transmitting signals occurs due to the fact that the receiving signal and the signal from the transmitter have different polarizations. Thus, in this antenna system, when the orientation of the re-emitter changes, the plane of polarization changes. In addition, there is no change in the type of polarization of the microwave signal.

In the proposed device:

- the polarizer made movable can change its position;

- when the orientation of the reemitter is changed, there is no change in the plane of polarization;

- there is a change in the type of polarization (polarizer, converts a wave with circular polarization into a wave with a different polarization).

Thus, the proposed device has structural features other than the antenna system (US 2994873 A, 08/01/1961), which are used in it for a different purpose.

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 drawing.

In FIG. 1 shows the proposed antenna system.

In the drawing and in the text, the following notation:

1 - emitter;

2 - support with a free center;

3 - re-emitter;

4 - polarizer.

The antenna system contains: a radiator 1 located inside a support with a free center 2, and a re-emitter 3 is located so that the center of its projection is also inside a support 2. The emitter 1 is made in the form of an antenna with rotating polarization of the field, and between the emitter 1 and the re-emitter 3 a polarizer 4 is installed, which converts a wave with circular polarization into a wave with a different polarization and has the ability to change the azimuth orientation over a wide range (rotate), and the polarizer 4 and re-emitter 3 are rigidly interconnected.

The antenna system works as follows.

The microwave signal is fed to the input of the emitter 1, (which can be made in the form of a spiral antenna, horn, etc.), then the signal coming from the emitter 1 passes through the polarizer 4, which converts the microwave signal with rotating polarization of the field into a signal from another polarization, for example linear, is reflected by a re-emitter 3 mounted on the support 2. Support 2 is a structure with a free center, i.e. the design within which the microwave signal propagates. The emitter 1 is located inside the support 2, the re-emitter 3 is located so that the center of its projection is also inside the support 2. Thus, the microwave signal passes from the emitter 1 to the re-emitter 3, inside the support 2, the center of which is free for the passage of the microwave signal. This allows the re-emitter 3 to rotate around an axis passing through the free center of the support 2. The presence of a polarizer 4, which has the ability to change the azimuthal orientation in wide (rotate), and rigidly connected with the re-emitter 3, allows you to emit a microwave signal in which the polarization does not change when rotation of the re-radiator 3. Polarizer 4, which converts a microwave signal with a rotating field polarization into a signal with a different polarization, can have a different design, can be either pass-through or reflective (Line design ovyh, scanning, wide-band antennas and feeders. Beetle MS Molochkov YB M., "Energy", 1973, p. 129 ... 134). In the case of using a polarizer 4 of a reflective type, it is necessary to install a polarizer 4 directly on the re-emitter 3 (the polarizer 4 and the re-emitter 3 are rigidly interconnected). In this case, the polarizer 4 is actually used as a re-emitter 3. The rotation of the re-emitter 3 (polarizer 4) allows you to radiate and receive a signal with the same polarization, and the plane of polarization does not change when the orientation of the re-emitter 3. If you use a pass-through polarizer 4 to exclude changes in the plane of polarization when the orientation of the re-emitter 3 changes, it is necessary that the polarizer 4 and re-emitter 3 change their position (rotate) synchronously, i.e. were tightly interconnected. The emitter 1 can be made, for example, in the form of a two-input spiral antenna operating with a wave with both right and left polarizations (O.A. Yurtsov, A.V. Runov, A.N. Kazarin. Spiral antennas. M., Soviet Radio, 1974, p. 147, 148).

In some cases, for example in radar, it is necessary that the antenna system allows you to radiate microwave signals not only in different directions, but also that the polarization vector of the (linear) signal in the same direction has a different slope at different times, for example, the polarization should be now vertical, then horizontal or inclined. For this, it is necessary that the polarizer 4 be able to change the orientation regardless of the orientation of the re-emitter 3. In this case, changing the relative position of the re-emitter 3 and the polarizer 4, we obtain a different slope of the polarization vector in the same direction. The polarizer 4 can be either a reflective type or a passage type. Using a polarizer 4 through type has a simpler design.

Using the proposed technical solutions allows you to create an antenna system that allows you to perform a circular overview, while maintaining or changing the necessary plane of polarization of the microwave signal when changing the orientation of the re-emitter, which has high manufacturability and low cost.

Claims (2)

1. Antenna system consisting of a support with a free center, an emitter located inside the support with a free center, a re-emitter mounted on the support and able to change azimuthal orientation over a wide range (rotate), with the re-emitter located so that its projection center is also located inside the support, characterized in that the emitter is made in the form of an antenna with a rotating field polarization, and a polarizer is installed between the emitter and the re-emitter, which converts the wave with circular polarization it into a wave with a different polarization and having the ability to change the azimuth orientation over a wide range (rotate), and the polarizer and re-emitter are rigidly interconnected. 2. The antenna system according to claim 1, characterized in that the polarizer has the ability to change the azimuth orientation over a wide range (rotate) regardless of the orientation of the re-emitter.

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