RU119174U1 - SWITCHABLE DIRECTIONAL FRAME-BEAM ANTENNA - Google Patents

Abstract

1. A switchable directional loop-beam antenna containing a vertically located frame made of a material with low ohmic losses with a conductor coaxially located in it, the inner conductor and the frame are connected to tuning capacitors C-1 and C-2, respectively, and form two strongly interconnected circuits , characterized in that the circuit formed by the inner coaxial conductor and the tuning capacitor C-1 does not participate in radiation, the outer circuit is connected by means of contacts, remotely controlled relays, with horizontally located radiating and compensating beams made of rigid self-supporting beams made of light materials, forming together with them an antenna system. ! 2. Switchable directional frame-beam antenna according to claim 1, characterized in that the circuit formed by the internal coaxial conductor and the capacitor C-1 does not participate in radiation and serves to ensure, if necessary, in-phase or antiphase of the magnetic and electric fields of the corresponding parts antennas. ! 3. The switchable directional loop-beam antenna according to claim 1, characterized in that the emitting beam located on the same side of the proposed antenna as the half of the loop part connected to it forms the main radiation lobe. ! 4. The switchable directional loop-beam antenna according to claim 1, characterized in that the emitting beam located on the opposite side of the half of the loop part connected to it provides suppression of radiation in this direction. ! 5. Switchable directional loop-beam antenna according to claim 1, characterized in that the compensating l

Description

The technical solution relates to the field of radio engineering, in particular to antenna technology and can be used in communication technology.

Known antenna "quarter-wave vertical radiator" K. Rothamel "Antennas" publishing house "Boyanych" St. Petersburg 1998, p. 311-322, which contains a vertically located electrical conductor (for example, wire, rod, pipe) equal to about a quarter of the length waves equipped with a branched grounding system or counterweights.

The disadvantages of the analogue include the inability to receive and transmit in only one selected direction, with the ability to suppress signals in all other directions, distortion of the radiation pattern in the presence of conductive objects and other antennas in the vicinity of the antenna, the need for equipment with a branched grounding system or counterweights.

Also known is the Square Cube antenna by K. Rothamel Antennas, eleventh edition, Danvel Publishing House, Moscow 2005, Volume No. 1, pp. 258-262, which contains an active loop in the form of a square element and spaced apart from it 0.1-0.2 wavelengths, the second of the same wire square, which with the help of an additional training loop turns into a reflector.

The disadvantages of the second analogue include the lack of the ability to quickly, without turning the antenna itself, change the direction of the radiation pattern in the opposite direction, the lack of the ability to work with a circular radiation pattern, the complexity of the supporting structure of the antenna, the need to ensure the height of the antenna suspension, at least ½ wavelength to ensure a small angle elevations in the vertical plane of the radiation pattern, a significant wind load on the antenna, due to the large windage of the structure, is distorted Beam patterns in the presence of conductive objects and other antennas near the antenna.

As a prototype, “Frame beam antenna” was selected, utility model patent No: 92574 dated November 13, 2009, which contains a vertically arranged frame made of a material with low ohmic losses with a coaxially located conductor in it, the frame and inner conductor are connected to capacitors settings C-1 and C-2 and form two strongly interconnected contours. The outer contour is connected to horizontally located beams, forming, together remove the antenna system

The disadvantages of the prototype include the lack of the ability of the antenna to work in only one selected direction, and the inability to suppress signals in all other directions.

The objective of the technical solution is to develop an antenna capable of working both with a circular radiation pattern and in only one selected direction with signal suppression in all other directions, which does not require equipment with an extensive grounding system or counterweights, with the ability to quickly, without turning the antenna itself, changing the radiation pattern in the opposite direction, having a slight windage, requiring one support for installation, with the possibility of Strongly rotation antenna in the desired direction, having a small angle of elevation in the vertical plane directivity pattern, with considerably less adjustment of the suspension long wavelengths, immune to the presence of conductive objects and other antennas in the immediate vicinity of it.

The problem is solved due to the fact that in a switched directional beam-beam antenna containing a vertically arranged frame of material with low ohmic losses, with a conductor coaxially located in it, the inner conductor and frame are connected to the tuning capacitors C-1 and C-2, respectively, and form two strongly interconnected circuits in this case, the circuit formed by the internal coaxial conductor and the tuning capacitor C-1 does not participate in the radiation and serves to ensure in-phase For antiphase, where necessary, the magnetic and electric fields of the antenna elements. In a switched directional beam-beam antenna, the external circuit is connected via contacts, remotely controlled relays, with horizontally located emitting (Fig. 1, rays A and B) and compensating (Fig. 1, rays C and D) rays made by rigid self-supporting , from light materials, forming, together remove the antenna system.

In the proposed antenna, the following differences are provided: two, longer, emitting beams (Figure 1, beams A and B), are made rigid self-supporting, made of light materials and are located in the plane of the frame. In the directional operation mode, the switched directional beam antenna, both emitting beams are connected using one of the normally closed switching contacts (K-1 or K-2 of Figure 1) remotely controlled relays to one of the terminals of the capacitor C-2, in turn connected to one of the two sides of the radiating frame. In the case of operation of the proposed antenna with a circular radiation pattern, each of the beams using normally closed, switching contacts (K-1 and K-2 of Figure 1), the relay is connected to the part of the frame from which it is located. The other two, four times shorter than the emitting rays, compensating beams (Figure 1, beams C and D) are also made rigid self-supporting, made of light materials and they are located at the junction of long beams with the frame. But they are located across the emitting rays and, respectively, across the frame and in the directional mode of operation, they are connected using contacts (K-3 or K-4, Figure 1) of remotely controlled relays, to the opposite, with respect to the connection point of the emitting rays, output of the capacitor C -2 and correspondingly the opposite conclusion of the emitting frame. In the operation mode, switched directional beam-beam antenna, with a circular radiation pattern, these rays using normally open contacts (K-3, K-4 Figure 1) relays are disconnected from the frame and remain unconnected.

In the mode of directional operation, switched directional frame-beam antenna, the voltage and current in the emitting beam, located on the side of the part of the frame to which it is connected, as in the prototype, is in phase with respect to the voltage and current flowing in this parts of the frame. Moreover, as in the prototype, a vertically located frame emits a vertically polarized magnetic component, and a horizontally located beam, a horizontally polarized electric component, which ensures the formation of the front of the radiated electromagnetic wave in the direction of this beam. In the opposite, emitting beam, connected to the frame at the same point as the first beam, but located on the side of the opposite part of the frame, the voltage and current of the beam are in antiphase with respect to the voltage and current in this part of the frame, as a result of this mutual compensation of the fields induced by these voltages and currents. Due to the mutual compensation of the fields, reception and transmission in the direction of this beam is impossible.

Four times shorter, compensating beams located perpendicular to the long, emitting beams and the frame itself, serve to ensure the symmetry of the antenna and create an electric field. They are located at a point in the antenna where the directional operation, due to mutual compensation by the opposite branches of the frame, has a zero-reception sector in the transverse direction, and the beams themselves are arranged so that they also have zero-reception in this direction. When changing the radiation pattern, in the opposite direction, using the contacts of remotely controlled relays, the compensating rays also switch to the opposite part of the frame. In both cases, they do not participate in the formation of the radiation pattern.

In the mode of operation with a circular radiation pattern, using the contacts of remotely controlled relays, the emitting rays are connected, as in the prototype, to the side of the frame with which they are located and contribute to the formation of a circular radiation pattern, and the compensating rays remain not connected and do not participate in radiation . At the same time, a circular radiation pattern is provided.

Thus, the proposed antenna, made in the form of a rigid frame, with rigid self-supporting beams, made of lightweight materials and mounted on one support, has the ability to rotate, and has a slight windage. The antenna is able to work in one selected direction, with the ability to suppress signals in all other directions. In the presented antenna, if necessary, using remotely controlled relays, it is possible, without rotating the antenna itself, to change the direction of the radiation pattern in the opposite direction, or switch the antenna to work, with the same circular pattern as the prototype. The antenna does not require equipment with a branched grounding system or counterweights. In addition, the proposed directional beam antenna is characterized in that the vertically arranged frame emits a vertically polarized magnetic component, and horizontally located emitting rays a horizontally polarized electric component, which ensures the formation of the front of the radiated electromagnetic wave. The formation of the front of the radiated electromagnetic wave occurs directly at the antenna elements, the characteristics of the antenna are practically independent of the height of the antenna suspension. The radiation angle in the vertical plane (elevation angle) is small and is regulated by the tilt of the rays relative to the horizon, the antenna is not affected by surrounding objects, conductors and other antennas located in the immediate vicinity of it.

Between the totality of the essential features of the claimed object and the achieved technical result, there is a causal relationship, namely, the presence of emitting rays made of rigid, self-supporting of light materials and located on one side of the antenna, at a point with common-mode fields of the frame, and on the other side of the antenna in point with antiphase margins of the frame. This, in the presence of compensating beams, also made rigid, self-supporting, of light materials and not involved in the formation of the radiation pattern, allows the antenna to work in the selected direction, with the possibility of suppressing signals in all other directions. The presence of contacts of remotely controlled relays, with the help of which there is a change in the connection points of emitting and compensating rays, allows without changing the antenna itself to change the direction of radiation to the opposite or to form a circular radiation pattern. The presence of emitting and compensating beams allows you to abandon the use of a branched grounding system or counterweights. The formation of the electric and magnetic component of the front of the radiated electromagnetic wave by individual antenna elements ensures independence of the elevation angle in the vertical plane from the antenna installation height and eliminates the distortion of the radiation pattern in the presence of conductive objects and other antennas in the vicinity of the antenna. The presence of only one, necessary for installing the support, allows you to rotate the antenna in the desired direction. With a small elevation angle in the vertical plane of the radiation pattern, it is possible to use the antenna mounting height, significantly less than ½ of the wavelength. In addition, the maximum radiation angle in the vertical plane of the radiation pattern is controlled by the inclination of the rays to the base of the antenna. The antenna has a simple supporting structure and has a slight windage.

The technical nature of the proposed technical solution is illustrated in the drawing, on which:

Figure 1 Schematic diagram of a directional beam-beam antenna

Figure 2 Technological diagram of a directional beam-beam antenna

The proposed switchable directional frame-beam antenna consists of a frame part of the antenna made of coaxially arranged conductors and equipped with tuning capacitors, a beam part made of rectilinear conductors, a group of relays, their control circuits, mast and spacers, insulators, an inductive communication loop with the power supply cable.

The structural elements listed above are made as follows, the antenna frame part is made of coaxially arranged conductors and is equipped with tuning capacitors for the inner conductor and the outer conductor, the beam part is made in the form of rigid self-supporting conductors made of light materials. Remote-controlled relays are equipped with appropriate control circuits. The antenna is powered by a communication loop similar to the communication loop used in the prototype. The frame part and the emitting rays are located in the same plane. Compensating beams, four times shorter than radiating beams, are perpendicular to the radiating beams and frame.

The technical solution described above for a directional beam beam antenna is as follows:

The antenna antenna part, made of coaxially arranged conductors, in the shape of a circle of material with low ohmic losses and equipped with tuning capacitors, is mounted on a dielectric mast using a spacer. Rays made of light materials in the form of rigid, self-supporting conductors are also attached to the mast. The shape of the radiation pattern is controlled remotely using a relay. The antenna is tuned to minimize the standing wave coefficient or maximum readings of the field strength indicator. By changing the angle of inclination of the rays with respect to the mast, the angle of radiation in the vertical plane is regulated, the larger the angle of inclination of the rays, the smaller the angle of radiation. The antenna is powered by a communication loop similar to that described by K. Hagenbuchner. Magnetische Anfennen - ein Erfahrung-bericht, - QSP, 1988, No. 7, S.28-3.

Feasibility study:

1. the ability to work in only one selected direction, with the ability to suppress signals in all other directions.

2. the ability to change the direction of the antenna to the opposite, without turning the antenna itself.

3. The ability to switch the antenna in a circular pattern.

4. the ability to mount the antenna with one support.

5. The ability to rotate the antenna in the desired direction.

6. lack of significant windage

7. the absence of distortion of the radiation pattern in the presence of conductive objects and other antennas in the vicinity of the antenna

8. ensuring a small elevation angle in the vertical plane of the radiation pattern at a suspension height of significantly less than ½ wavelength.

Claims (7)

1. Switchable directional beam beam antenna containing a vertically arranged frame of material with low ohmic losses with a coaxially located conductor in it, the inner conductor and the frame are connected to the tuning capacitors C-1 and C-2, respectively, and form two strongly connected loops characterized in that the circuit formed by the internal coaxial conductor and the tuning capacitor C-1 does not participate in the radiation, the external circuit is connected using contacts remotely controlled by barely, with horizontally located emitting and compensating beams made of rigid self-supporting, from light materials, forming together with them an antenna system. 2. The switched directional beam-beam antenna according to claim 1, characterized in that the circuit formed by the internal coaxial conductor and capacitor C-1 does not participate in the radiation and serves to ensure, if necessary, the phase and antiphase magnetic and electric fields of the corresponding parts antennas. 3. The switchable directional beam beam antenna according to claim 1, characterized in that the emitting beam located on the same side of the proposed antenna as the connected half of the frame part forms the main radiation lobe. 4. The switchable directional beam-beam antenna according to claim 1, characterized in that the emitting beam located on the opposite side of the connected half of the frame portion provides radiation suppression in this direction. 5. The switched directional beam-beam antenna according to claim 1, characterized in that the compensating rays are perpendicular to the radiating rays and the frame itself, serve to ensure the symmetry of the antenna, creating the electric and magnetic fields of the beam portion of the proposed antenna. 6. The switched directional beam antenna according to claim 1, characterized in that the switching of the emitting and compensating beams using remotely controlled relays allows you to change the antenna pattern in the opposite direction. 7. The switchable directional beam-beam antenna according to claim 1, characterized in that the switching of the emitting and compensating beams using remotely controlled relay contacts allows you to change the antenna radiation pattern from directed to circular.