RU169151U1 - BROADBAND DIRECTED ANTENNA WITH DOUBLE POLARIZATION - Google Patents

Abstract

The utility model relates to antenna technology. A dual polarized broadband directional antenna consists of two linearly polarized antennas, each of which consists of active vibrators, a screen that feeds a coaxial line. Each linearly polarized antenna consists of at least two active vibrators, the shoulders of the active vibrators of one antenna being the shoulders of the active vibrators of the second antenna, and at least two balancing transformers connected to the active vibrators. The technical result is to achieve high isolation between the inputs of the antenna. 9 s.p. f-ly, 2 ill.

Description

The invention relates to antenna technology and can be used as a directional antenna for wireless networks.

Patent CN 102117961 A, “Wideband dual polarization directional radiation unit and antenna”, is known from the state of the art (published on July 6, 2011). The double polarized broadband directional emitting unit is located on the reflector / reflective plate so that the antenna is formed, and contains: a retaining element, radiating parts, a power cable and at least one of three structures that increase the matching band, including cutouts located on each radiating parts, a loading section mounted on the lower surface of each radiating part and a conductive element connecting the power cable and the radiating parts, mounted below the top ited emitting parts in which holes accomplished group, each group of openings comprises one opening in the form of a polygon by the center and the other two openings in the form of a polygon on the right and left from the first opening. The disadvantages of the prototype are:

low coefficient of directional action of a single block,

To achieve high directivity, it is possible to combine several units into an antenna array, but for this it is necessary to add a power circuit that must contain at least four coaxial power lines and at least two power dividers, which negatively affects the manufacturability of the antenna as a whole.

Also known is a planar antenna of double polarization No. 2276822 dated 01/14/2004 (published on 05/20/2006), made in the form of a square metal plate placed above a conductive surface, with pairwise antiphase exciting elements connected to it, the diagonal length of the square metal plate is equal to the radiation wavelength, and the antiphase exciting elements of orthogonal linear polarizations are connected to the metal plate in pairs symmetrically along its orthogonal diagonals.

The above antenna has the following disadvantages:

a smaller operating frequency band due to the use of a printed emitter;

lower coefficient of directional action.

As the closest prototype, we consider a broadband directional antenna No. 146938 dated February 24, 2014 (published on October 20, 2014, Bulletin No. 29), which is an antenna array of two large-band enlarged vibrators with shoulders in the form of disks located above the screen, and also having Four additional passive vibrators located above the shoulders of the active vibrators. Active vibrators are powered through a two-wire line of variable cross-section. The antenna has a balancing device and a high-frequency connector mounted on the antenna screen. The shoulders of active vibrators, passive vibrators, a screen, a two-wire line and a balancing device are made of sheet metal.

The disadvantage of the above analogue antenna is:

the inability to emit waves with mutually orthogonal linear polarizations.

The technical task of the utility model is to create a broadband technological small-sized bipolar antenna with a high gain and high isolation between the antenna inputs in the band +/- 25% of the center frequency.

The technical result of the utility model is to achieve high isolation between the inputs of the antenna.

The specified technical result is achieved due to the fact that the claimed utility model consists of two antennas with linear polarization, each of which consists of active vibrators, a screen supplying a coaxial line, each antenna with linear polarization consists of at least two active vibrators, and the shoulders the active vibrators of one antenna are the shoulders of the active vibrators of the second antenna, at least two balancing transformers connected to the active vibrators.

A dual polarized broadband directional antenna contains two linearly polarized antennas located on the same plane, each of which consists of a pair of symmetrical active broadband vibrators, the shoulders of which are conductive plates with two / three symmetry planes, for example, discs with a diameter of about 0.46 length waves at medium frequency and located above the common, for both antennas, a conductive screen at a distance of 0.11 wavelengths. The shoulders of the vibrators of the first antenna are the shoulders of the vibrators of the second antenna, and the axes of the vibrators of the first antenna are parallel to each other and perpendicular to the axes of the vibrators of the second antenna. Additionally, in each antenna four passive vibrators common to both antennas can be used in the form of conductive plates with two / three planes of symmetry, for example, disks with a diameter of 0.34 wavelengths at a medium frequency and active vibrators located above the centers of shoulders at a distance of 0.073 wavelengths . A balancing transformer is connected to each active vibrator. The outputs of the balancing transformers inside a pair of parallel vibrators can be connected to the arms of the power divider, the input of which is the input of one antenna. The balancing transformer is two segments of a symmetrical line of the same length, and they are connected at one end in parallel and can be connected to the arm of a tee power divider, and at the other connected in series and connected to the input of the active vibrator. The tee power divider consists of two segments of an asymmetric transmission line of the same length, which are connected to each other from one end in parallel, and form a divider input in this connection, and the other ends are inputs of the divider arms and can be connected to balun transformers. Two balancing transformers of one antenna and a power divider connected to them can be implemented on one printed circuit board. The printed circuit boards of both antennas can be located one above the other near the level of the shoulders of the active vibrators. To protect the antenna from aggressive effects, a dielectric casing can be fixed to the screen from the side of the radiating elements, or the entire antenna can be placed in a dielectric box.

The essence of the utility model is illustrated by drawings (Fig. 1, Fig. 2).

In FIG. 1 shows a General view of the antenna, where:

1 - conductive jumpers;

2 - shoulders of active vibrators;

3 - antenna screen;

4 - passive vibrators;

5, 6 - holder;

7, 8 - printed circuit boards;

9 - contact pads for feeding the shoulders of active vibrators;

10, 11 - contact pads of the input of the first antenna;

12 - axis of the vibrators of the first antenna;

13 - axis of the vibrators of the second antenna;

14 - protective dielectric casing of the antenna;

15 - diameter of the disk / shoulder of the active vibrator;

16 - the distance between the screen and the active vibrator;

17 - the size of the active vibrator;

18 - the distance between the active vibrators;

19 - the distance between active and passive vibrators;

20 - diameter of passive vibrators;

21 - screen size.

In FIG. 2 shows a double-sided printed circuit board of one of the antennas with two balancing transformers, a power divider and a part of the coaxial line supplying the antenna, while the conductors of the upper conducting layer are conventionally marked in black and the lower ones in gray, where:

7 - printed circuit board;

9 - contact pads for powering the shoulders of active vibrators;

10, 11 - contact pads of the input of the first antenna;

22 - balancing transformer;

23 - tee power divider;

24 - a narrow conductor segment of an asymmetric transmission line;

25 - segments of a symmetrical transmission line;

26 - a common wide conductor of segments of an asymmetric transmission line;

27 is a fragment of a supply coaxial transmission line;

28 - interlayer jumpers of the printed circuit board.

Consider an example of the implementation of a dual-polarized broadband directional antenna, consisting of four active vibrators, four passive vibrators 4, four balancing transformers 22, holders 5 and 6, two power dividers, a supply coaxial line 27, a shield 3 and a protective dielectric casing 14. The shoulders are active vibrators are made in the form of conductive disks 2 with a diameter of 15, which is equal to (0.44 ÷ 0.47) ⋅λ at the middle frequency and are parallel to the screen 3 at a distance of 16 equal to 0.11⋅λ. The size of the active vibrator 17 is (0.98 ÷ 1.08) ⋅λ, and the distance between the active vibrators 18 is (0.65 ÷ 0.75) ⋅λ at the middle frequency. At a distance of 19 equal to 0.07⋅λ from the shoulders of the active vibrators, four passive vibrators are arranged in parallel in the form of discs 4 with a diameter of 20 equal to (0.33 ÷ 0.36) ⋅λ at the middle frequency. The center of each of the four disks 4 is located above the center of one of the four disks 2 and lies with it on the same axis perpendicular to the plane of the screen 3. The disks of passive vibrators 4 are attached to the disks of active vibrators with holders 5. The disks of 2 active vibrators, in turn , are attached to the screen 3 by means of holders 6. Each arm of the active vibrators of the antenna has two conductive jumpers 1 that are in contact with the contact pads 9. The active vibrators are powered through a balancing transformer 22, each of which is made of two segments of a symmetrical transmission line 25 of the same length, while the segments 25 are connected at one end in parallel and connected to the arm of the power divider 23, and at the other connected in series and connected to the contact pads 9. When implementing an antenna with a tee power divider, it contains two shoulders in the form of segments of an asymmetric transmission line of the same length, connected at one end to each other in parallel, and on the other hand, each segment is connected to a separate balancing t transformer 22. The segments are formed by narrow 24 and wide 26 conductors. At the point of parallel connection of the segments, contact pads 11 and 10 are installed, which have contact with the conductors 24 and 26, respectively. The pads 11 and 10 are the input / output of the antenna and are designed to connect to them a coaxial transmission line 27, or a coaxial connector, or a transceiver. The size 21 of screen 3 is (1.1 ÷ 1.9) ⋅λ.

The screen, passive vibrators, shoulders of active vibrators can be made of sheet metal with the same processing method, and two balancing transformers and one power divider of each antenna can be made on a single printed circuit board.

The antenna works as follows:

when applying the RF signal to the input of the divider 23 of the printed circuit board 7, through the contact pads 10 and 11, the signal power is divided equally and in the same phase enters through the segments of the asymmetric line formed by the conductors 24 and 26 to the balancing transformers 22 and then through them along the symmetrical segments line 25, to the contact pads 9. Then, through jumpers 1, the signal enters the inputs of active vibrators. As a result, a pair of active antenna vibrators lying on axes 12 are fed in-phase, with equal amplitude, and together with passive vibrators 4 and screen 3 form linear polarization radiation parallel to axes 12 from screen 3 towards passive vibrators 4. The width of the main lobe of the radiation pattern in the horizontal plane (X0Z), it mostly depends on the distance between the active vibrators 18 and the screen sizes 21, and in the vertical plane (Y0Z) on the sizes of the screen 21 and the size 17 of the active vibrators.

Similarly, the antenna works, the active vibrators of which lie on the axes 13, and the input / output of which is located on the printed circuit board 8.

As a result, two antennas are capable of independently generating radiation in the same direction, but with mutually orthogonal polarizations. Due to this, a dual-polarized broadband directional antenna can operate simultaneously with two receivers or two transmitters and provide a communication system using polarization separation of radio wave propagation channels. Also, this system can be used in anti-fading systems with polarized antenna spacing.

The described design options allowed to obtain the following main characteristics when implementing the antenna in the frequency range 1700-2700 MHz:

standing wave coefficient (SWR) at the input of the antenna in variants matching with the coaxial line of 50 Ohms or 75 Ohms no more than 1.5;

gain in the specified frequency range 12.5 ÷ 15.0 dB with respect to the isotropic emitter;

isolation between the inputs of the antenna is more than 30 dB;

level of lateral radiation no more - 12 dB;

the dimensions of the antenna, taking into account the dimensions of the casing, are 240 × 240 × 32 mm.

The specified technical result is achieved due to the fact that the shoulders of the active vibrators of one antenna are the shoulders of the active vibrators of the second antenna, as well as the presence of two symmetrizing transformers connected to the active vibrators in the composition of the broadband directional antenna with double polarization.

Claims (10)

1. Broadband directional antenna with double polarization, consisting of two antennas with linear polarization, each of which consists of active vibrators, a screen supplying a coaxial line, characterized in that each antenna with linear polarization consists of at least two active vibrators moreover, the shoulders of the active vibrators of one antenna are the shoulders of the active vibrators of the second antenna of at least two balancing transformers connected to the active vibrators. 2. Broadband directional antenna with double polarization according to claim 1, characterized in that the axes of the active vibrators of one antenna are parallel to each other and perpendicular to the axes of the active vibrators of the second antenna. 3. Broadband directional antenna with double polarization according to claim 1, characterized in that it contains at least one printed circuit board. 4. Broadband directional antenna with double polarization according to claim 1, characterized in that it contains at least two power dividers. 5. Broadband directional antenna with double polarization according to claim 1, characterized in that each antenna with linear polarization contains at least four passive vibrators located above the centers of the shoulders of the active vibrators, and passive vibrators are common for linear polarized antennas. 6. Broadband directional antenna with double polarization according to claim 1, characterized in that it contains a dielectric casing. 7. Broadband directional antenna with double polarization according to claim 1, characterized in that the antenna is placed in a dielectric box. 8. Broadband directional antenna with double polarization according to claim 1, characterized in that the screen, passive vibrators, shoulders of active vibrators are made of sheet metal with the same processing method. 9. Broadband directional antenna with double polarization in PP. 3 and 4, characterized in that two balancing transformers and one power divider are made on a single printed circuit board. 10. Broadband directional antenna with double polarization according to claim 3, characterized in that it contains two printed circuit boards located one above the other near the shoulder level of the active vibrators.

Images