RU2427947C2 - Antenna system with varied shape of directional diagram - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: antenna system with varied shape of radiation directional diagram (DD) comprises an exciting antenna and a horn attachment. The exciting antenna comprises a metal reflector screen, which has a flat base and side walls arranged along the perimetre of the base, and also a radiator installed on the base in its centre, to which a coaxial feed cable is connected. The horn attachment, the radiator and the flat base of the metal reflector screen have a rectangular shape. The narrow end of the horn attachment has a shape of a wave guide, which is arranged with the possibility of electromechanical connection to side walls of the reflector screen base.

EFFECT: reduced dimensions, prime cost, increased amplification, simplified compact nonvolatile antenna system with varied shape of directional diagram.

6 cl, 5 dwg

Description

The invention relates to the field of radio engineering, and more specifically to combined structures of primary antenna elements and assemblies with secondary devices designed to generate the desired antenna pattern, namely, antenna systems with a variable radiation pattern that can be used at wireless points access (WAP).

The rapid development and increased use of various compact radio devices, such as echo-radar motion sensors, wireless access points (WAPs), repeaters and base stations for mobile communications, required the development of small directional antennas necessary to form an optimal service area.

The use of such a set of antennas for installation inside the building and indoors proved to be necessary to ensure high-quality radio communications in the conditions of the service area with a complex configuration.

Optimal from the point of view of maximum gain at minimum sizes are microstrip antennas, which are widely used in small-sized radio equipment and antenna arrays.

Microstrip antennas are now widely described in various specialized literature, see, for example, P. Bhartia, Inder Bahl, R. Garg and A. Ittipiboon, "Microstrip Antenna Design Yandbook (ARTECH HOUSE ANTENNAS AND PROPAGATION LIBRARY)", Artech House Publishers , 01 November, 2000 [1] or Panchenko B.A., Nefedov E.I., "Microstrip antennas" (Radio and Communication), 1986 [2].

The disadvantage of microstrip antennas is that their design does not allow changing the antenna gain and, as a result, changing the shape (width) of its radiation pattern.

A general analysis of various designs of directional radiation antennas shows that the horn antennas are the most efficient directional radiation antennas, although they are quite large in size.

Closest to the claimed invention, a horn antenna that allows you to change the shape of the radiation pattern described in Japanese patent No. 8330843 [3], which consists of a main horn and additional extension horn nozzles. A change in the gain and pattern of a given horn antenna is achieved by extending or folding the horn nozzles. When folded, the horn nozzles work like a locking cup. When unfolded, the horn inserts work as a continuation of the main horn and form a horn with a wide aperture. The length of such a horn antenna, taking into account the extended inserts, reaches about 1.5λ, and the height L = λ / 2 ÷ 3λ / 2. The power of such an antenna is carried out using a waveguide and a coaxial waveguide transition. Electromechanical drives are used to add and extend the speaker elements. This antenna is selected as a prototype of the claimed invention.

The disadvantage of the horn antenna of the prototype are as follows. High demands are made on the manufacture of retractable horn inserts, which significantly increases their cost. So the internal dimensions of the insert must coincide with the counterpart, otherwise a gap is formed that breaks the electrical connection of the parts, as a result of which the emitted field is distorted on the resulting inhomogeneity and the antenna gain may be less.

The existing antennas of wireless radio networks have the following disadvantages:

- They can provide only a fixed service area, thereby limiting functionality and increasing the cost of installing a wireless network as a whole, since in order to overlap the service area of a radio network, it is necessary to increase the number of antennas and calculate their installation locations.

- If it is necessary to rebuild the service area, it is not enough just to rebuild the radio network system, so there is a need to purchase additional equipment to replace the existing one, which increases the cost of the system. The current operating conditions of wireless networks require the design of a small antenna, low cost and optimal radiation pattern.

Thus, the task to which the claimed invention is directed is to develop a simple and compact non-volatile antenna system with a variable shape of the beam, with reduced dimensions, with low cost, with increased gain.

The technical result is achieved by creating a new design of the antenna system with a variable shape of the beam containing the exciting antenna and the horn nozzle, while the exciting antenna consists of a metal reflector screen, which has a flat base and side walls located along the perimeter of the base, as well as an emitter installed on the base in its center, to which a coaxial power cable is connected, and the horn nozzle, emitter and flat base of the metal reflector screen have a straight a gel shape, with the distinguishing feature of such an antenna is that the narrow end of the horn nozzle has the shape of a waveguide, which is electromechanically connected to the side walls of the base of the reflector screen.

In a preferred embodiment of the invention, the optimal arrangement and geometric dimensions of the main elements of the antenna system are provided, namely, the lengths of the sides of the rectangular emitter are 0.44λ and 0.26λ, where λ is the average wavelength of the emitted signal, the height of the side walls of the base of the reflector screen coincides with the height of the waveguide of the horn nozzle is 0.12λ, the side walls of the base of the reflector screen are located along the perimeter of the square with a side length equal to 0.85λ, the emitter is made in the form of a plate and installed it is mounted at a height of 0.07λ from the base, the length of the side of the aperture of the horn nozzle is 1.32λ, and the total height of the horn nozzle is 0.33λ.

For the functioning of the antenna system, it makes sense that all its elements are located symmetrically on an axis perpendicular to the base of the reflector screen.

For the functioning of the antenna system, it makes sense that the exciting antenna was from a set of antennas, which contains a microstrip antenna printed on a printed circuit board, a microstrip antenna with air filler and a dipole antenna with a reflector.

For the functioning of the antenna system, it makes sense that circular polarization is realized in the exciting antenna. Circular polarization can be realized on a microstrip antenna by supplying it with two identical signals with a phase shift of +/- 90 degrees through two orthogonal points on its surface or by using two orthogonally mounted dipole antennas, applying the same signals with a phase shift +/- to them 90 degrees.

For the functioning of the antenna system, it makes sense that the horn nozzle was made in the form of a pyramidal horn.

For a better understanding of the proposed invention the following is a detailed description with the corresponding drawings.

Figure 1 - diagram of the antenna system according to the invention: 1.1 is a side view, 1.2 is a top view.

Figure 2 - graph of the calculated data of the FAC microstrip antenna and antenna system according to the invention.

figure 3 is a graph of the gain, in the direction of the main maximum radiation, microstrip antenna and antenna system according to the invention.

4 (views 4.1 and 4.2) are radiation patterns of a microstrip antenna and an antenna system according to the invention.

5 (types 5.1 and 5.2) is a diagram of the use in rooms of different configurations of a microstrip antenna (view 5.1) and the antenna system according to the invention (view 5.2).

Let us consider in more detail the embodiment of the proposed antenna system using a microstrip antenna as an exciting one. The air-filled microstrip antenna has an emitter plate 4 with side dimensions c = 0.44λ and d = 0.26λ (where λ is the average wavelength of the emitted signal), height H _p and is fed by coaxial cable 5.

The size of the emitter plate 4 of the microstrip antenna and the height of its installation above the screen H _{p are} calculated by standard, well-known methods for calculating microstrip antennas using air (ε = 1) and for a given average wavelength λ.

Instead of an airborne microstrip antenna, you can use a printed antenna, a dipole, or other compact pathogens.

The screen on which the emitter plate of the microstrip antenna is placed has metal walls with a height H _w = 0.12λ, which are located along the perimeter of the square with the side size a = 0.85λ. They are designed to install the horn nozzle 3 close to the surface 2 of the screen. On the horn nozzle, places 6 for attaching to the screen 1 are provided.

The main geometric dimensions of the antenna system of this invention are determined experimentally and optimized for maximum antenna gain with minimum dimensions.

The optimal dimensions shown in Fig. 1 were obtained on a prototype microstrip antenna tuned for an average frequency of the operating range of 8.85 GHz, which corresponds to a wavelength of λ≈33.9 mm. The aperture size of such an antenna, as well as the flat part of the surface of the ground reflector screen 1, was equal to a = 0.85λ. The size of the emitter plate is c = 0.44λ and d = 0.26λ, the height of the emitter plate above the ground is H _p = 0.07λ, and the height (or thickness) of the microstrip antenna without taking into account the wall thickness of the reflector and the installed horn nozzle H _w = 0,12λ. With these sizes, the maximum experimentally measured antenna gain, in a given frequency range, is at least +7.4 dB, FIG. 3. Experimentally, the dimensions of the horn nozzle were selected. The size of the aperture after installing the nozzle on the microstrip antenna turned out to be b = 1.32λ, the height of the horn nozzle turned out to be equal to H _h = 0.33λ. With these sizes, the maximum experimentally measured antenna gain, in a given frequency range, is not less than +10.4 dB, FIG. 3. Thus, the installation of such a horn nozzle made it possible to increase the antenna gain by 3 dB in the entire frequency range.

If you need to change the gain, you can make horn nozzles of other sizes. So with an increase in the size of the aperture and the height of the horn nozzle, the antenna gain will increase.

Figure 1.1 presents the General configuration of the design of the horn microstrip antenna of the present invention. Microstrip antenna without horn nozzle has a wide radiation pattern, Fig. 4.1, 4.2, Fig. 5.1. The installation of the horn nozzle narrows the radiation pattern of the microstrip antenna, which increases its gain, Fig. 4.1, 4.2, Fig. 3, Fig. 5.2.

The best way to use this antenna indoors is illustrated by Figures 5.1 and 5.2, where the antenna 8 is mounted on the top of the wall in the room or hall 7. The main lobe of the antenna pattern can be changed by installing a horn nozzle, which allows you to evenly distribute the radiated power in the service area with various configuration of the room.

The antenna system described in the present invention is designed to work in the structure of various radio communication systems where directional transmission or directional reception of a radio signal in a wide frequency range is required, for example:

1) in wireless local area networks (WLAX) to work in the structure of base stations (WAP);

2) in various cellular communication devices such as repeaters or as an element of the antenna array for base stations;

3) in security systems and premises.

The main idea of the proposed invention is to create an antenna that combines two different types: a compact pathogen antenna (for example, a microstrip antenna) and a horn antenna (horn nozzle). The combination of these two types of antennas is based on the following principle - the antenna excites an electromagnetic wave in a short horn fragment with a field distributor that is as similar as possible to a field distribution in a similar section of a horn antenna. The antenna implements the ability to install a horn nozzle on the base design of the exciting antenna, which allows changing its beam pattern and, as a result, increasing its gain.

In connection with the foregoing, the main feature of this invention is a simple, small-sized, non-volatile, cheap antenna design with a variable radiation pattern.

In this case, the antenna consists of a radiator and a horn nozzle, providing an increase in gain by 3 dB.

Installing the antenna with the necessary amplification is done manually, once during the installation of the antenna, taking into account the configuration of the room, by installing horn nozzles on the antenna.

This allows you to provide a high signal level throughout the service area.

All parts of the antenna system of the present invention are simple in shape and made of a uniform and uniform conductive material. This allows them to be manufactured in mass production easily and cheaply, using foil stamping or plastic molding followed by a conductive coating. For the manufacture of the printed-circuit antenna, a foil board is suitable, which also performs the functions of the supporting structure.

Although the above embodiment of the invention has been set forth to illustrate the present invention, it is clear to those skilled in the art that various modifications, additions and substitutions are possible without departing from the scope and meaning of the present invention disclosed in the attached claims.

Claims (6)

1. An antenna system with a variable radiation pattern, comprising an exciting antenna and a horn nozzle, while the exciting antenna consists of a metal reflector screen that has a flat base and side walls located along the perimeter of the base, as well as an emitter mounted on its base the center to which the coaxial power cable is connected, the horn nozzle, emitter and flat base of the metal reflector screen have a rectangular shape, characterized in that the narrow end of the horn waveguide has a nozzle shape which is adapted to connection to the electromechanical sidewalls base-reflector screen. 2. The antenna system according to claim 1, characterized in that the lengths of the sides of the rectangular emitter are 0.44λ and 0.26λ, where λ is the average wavelength of the emitter signal, the height of the side walls of the base of the reflector screen coincides with the height of the waveguide of the horn nozzle and is equal to 0.12λ, the side walls of the base of the reflector screen are located along the perimeter of the square with a side length equal to 0.85λ, the emitter is made in the form of a plate and installed at a height of 0.07λ from the base, the side length of the aperture of the horn nozzle is 1.32λ, and the full the height of the horn nozzle is 0.33λ. 3. The antenna system according to claim 1, characterized in that the horn nozzle is made of several horn fragments with the possibility of their sequential electromechanical connection to each other. 4. The antenna system according to claim 1, characterized in that the exciting antenna is selected from a set of antennas that contains a microstrip antenna printed on a printed circuit board, an air-filled microstrip antenna and a dipole antenna with a reflector. 5. The antenna system according to claim 1, characterized in that the circular antenna is implemented in the exciting antenna. 6. The antenna system according to claim 1, characterized in that the horn nozzle is made in the form of a pyramidal horn.

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