RU2185696C1 - Corner antenna - Google Patents

Abstract

FIELD: radio engineering; antenna systems for very-high-frequency communication systems including cellular ones. SUBSTANCE: antenna has corner reflector 16 with aperture angle φ formed by conducting plates 10, 12 that function as main mirrors and antenna feed 18 disposed inside corner reflector. Additional conducting plates 26, 28 are introduced in corner reflector to function as additional mirrors. Plates 26, 28 are tilted through angles α and β to aperture of corner reflector, their edges are parallel to those of conducting plates 10, 12 of main mirrors and to edge 14 of corner reflector. Values of angles φ, α and β are chosen from conditions α, β, φ<π; α+β+φ>2π. EFFECT: provision for developing corner antenna with sector-shaped directivity pattern in azimuth plane. 11 cl, 4 dwg

Description

 The invention relates to radio engineering, and in particular to antenna systems and can be used in the technique of ultrashort-wave, in particular cellular, communications.

 To work in the range of decimeter and meter waves, angular antennas or, as they are called, antennas with an angular reflector are often used. The design, in its simplest form, includes two flat plates forming a reflector (reflector), between which a linear irradiator is placed. As an irradiator, as a rule, either a single vibrator or a linear vibrating grating are used. Typically, the irradiator axis is located in the bisectorial plane of the antenna. With the proper choice of the reflector angle and the distance from the axis of the vibrator to the top of the angle, it is possible to provide a favorable addition of the wave field reflected from the reflector with the wave field created directly by the vibrator. With a symmetrical arrangement of the irradiator relative to the reflector plates and relatively small dimensions of the reflector, maximum radiation is provided mainly in the direction of the bisector of the angle. The height of the reflector is usually chosen slightly greater than the length of the irradiator, and the width of each plate is not less than the wavelength (see, for example, the monograph — Aisenberg GZ, Yampolsky VG, Tereshin ON, “VHF Antennas”, n / a Aizenberg G.Z., M., Communication, 1977, part 2, p.122-135) [1].

 The use of angular antennas is not limited to a single element: combining a large number of the angular antennas mentioned above allows creating a compact antenna system that implements a multi-beam mode of emission / reception of radio waves and is promising for cellular radio communication systems (see, for example, EP 0624919 A1, NTT MOBILE COMMUNICATIONS NETWORK INC, H 01 Q 25/00, 11.17.1994) [2].

A number of inventions relate to giving the reflector a shape other than flat, which provides a given directivity of the antenna. So, for example, in the antenna according to the patent US 3803622, 343/836, 04/09/1974 [3], the 90 ^o- reflector has symmetrical limbs 0.23λ wide facing outward at an angle of 10 ^o , where λ is the wavelength of electromagnetic waves at In this case, the length of the reflectors themselves in the radiation direction is 0.21λ, and the irradiator is placed at a distance of 0.12λ from the edge. The antenna according to the patent DE 1211499, SIEMENS ..., H O1 Q, 11/30/1967 [4] presents an antenna containing a broadband emitter and a complex-shaped reflector having reflector elements installed at different angles, as well as nomograms for choosing the distance from edges, sizes and angles of placement of reflectors.

 More complex designs of corner antennas contain improvements in the design of reflectors. So, from the publication (see, JP 11205030 A, Ueda Japan Radio Co Ltd., H 01 Q 15/18, 07/30/1999) [5], an antenna with a corner reflector formed of two conductive plates connected at a given angle is known aperture, and from the excitation element installed at a given distance from the plates. Flat conductors are attached to the plates in the aperture direction, placed with a gap relative to the edges of the said plates. In this way, the problem of obtaining a high antenna gain without increasing the physical area of the opening of the corner reflector is solved. This is useful for reducing the wind load on the structure.

 The analysis shows that the above sources of information [1] - [5] do not contain recommendations for creating an angular antenna that forms a radiation pattern of a sector shape, for example, a "U-shaped" radiation pattern. Such an antenna is in the azimuthal plane, i.e. in a plane perpendicular to the edge of the corner reflector, it is characterized by a certain shape of the radiation pattern in a given sector of angles and a sharp decline in radiation outside this sector. If the radiation level almost does not change inside the sector, then such a radiation pattern is called U-shaped. Such an antenna is very useful for organizing areas of uniform transmission / reception of radio waves, for example, for mobile communication systems, as well as in a number of other applications.

 Thus, the object of the invention is the creation of a corner antenna with a sector radiation pattern in the azimuthal plane.

 The technical result is achieved in that the antenna comprises a corner reflector formed by two rectangular conductive plates connected at an angle φ and performing the functions of the main reflectors, an irradiating device located in the cavity of the said corner reflector. The device is characterized in that additional rectangular conductive plates are introduced into it, which serve as additional reflectors. Each additional rectangular conductive plate is placed at an angle to the same plate of the main reflectors and connected to the latter along an edge parallel to the connection line of the main reflectors.

The values of the mentioned angles satisfy the conditions
α, β, φ <π; α + β + φ> 2π, (1)
where α, β are the angles at which the plates of the main reflectors are connected with the plates of additional reflectors.

The corner antenna may be characterized in that said irradiating device is arranged relative to said conductive plates of the main reflectors at distances s ₁ and s ₂ satisfying the relations:
5 / 8λ> (s ₁ , s ₂ )> 1 / 8λ, (2)
where: λ- is the wavelength of electromagnetic waves in the medium filling the cavity of the corner reflector.

 The angle antenna can be characterized by the fact that the said irradiating device is made in the form of a linear array of emitters.

 The angle antenna can also be characterized in that the said irradiating device is made in the form of a linear array of emitters, each of which is made in the form of an electric vibrator.

 The corner antenna can also be characterized in that said conductive plates are made of metal sheets.

 The corner antenna can also be characterized in that the corner reflector is made of a single sheet of metal.

 The angle antenna can be characterized by the fact that the said angle reflector is made of polymer materials, and the conductive plates are formed by laminating the cavity of the reflector with metal.

 The angle antenna can also be characterized in that the end surfaces of the said angle reflector are provided with covers fastened to the reflector, with the possibility of attaching to the latter antenna mounting elements and means for connecting to the antenna-feeder path.

 A corner antenna may also be characterized in that said covers are made of conductive material.

 The angle antenna may also be characterized in that said reflector cavity is filled with dielectric material.

 The corner antenna can be characterized in that the opening of the corner reflector is covered with a radome made of radiolucent material.

The invention is illustrated in the figures, where
in FIG. 1 shows a cross section of a patented corner antenna in a horizontal plane,
figure 2 is a General view of the corner antenna according to this invention,
figure 3 - comparison of radiation patterns in the azimuthal plane for patentable antenna design and conventional angular antenna.

 In FIG. 4 shows an example of the implementation of the reflector at the same time with a cowl from a profiled pipe.

 The implementation of the patented corner antenna is preceded by a selection of parameters based on the specific requirements of use. The operating frequency band is set (for an example implementation of the antenna it is 1700 - 2000 MHz), as well as the maximum size of the aperture. Then determine the type of irradiating device based on the requirements of the direction of the polarization vector of electromagnetic radiation. For the described implementation example, vertical polarization is set, which is ensured by the use of vertical vibrators. For a vibrator, a horizontal radiation pattern is known - it is uniform.

Then, according to the invention, reflector parameters with the geometry shown in FIG. 1 are selected. By choosing the length of the vibrator and the distances s ₁ , s ₂ (in the range satisfying the condition 5 / 8λ> (s ₁ , s ₂ )> 1 / 8λ, the wave resistance of the vibrators is selected so that the imaginary part of the input resistance is close to zero and the active - was close to the characteristic resistance of the transmission line exciting the vibrator. For symmetrical placement s ₁ = s ₂ , in this case, this size is indicated in figure 1 as "s". If there is a power divider between the transmission line and the cable (in the case of an irradiator in the form of a lattice), then the active part of the input resistance mentioning utogo divider must be equal to the characteristic impedance of the transmission line exciting the vibrator.

 After that, using methods of computational electrodynamics, for example, the method of integral equations (see Davydov A.G., Pimenov Yu.V. EDEM3D software package for studying the electrodynamic characteristics of perfectly conducting three-dimensional objects // Electrodynamics of Microwave and EHF, 1999, vol. 7, issue 2, pp. 24-26)), calculate the antenna pattern in the horizontal plane. Then, the geometric parameters of the antenna are selected in order to obtain a radiation pattern of a given shape, for example, with maximum squareness, using multidimensional optimization methods (see, for example, Aoki M. Introduction to functional optimization methods. - M., "Science". 1976).

The corner antenna (Fig. 1) contains reflective conductive plates 10, 12 connected along the edge 14 along parallel faces. The plates 10, 12, performing the functions of the main reflectors, form an angular reflector 16 with an angle φ in the aperture. Irradiators 18 are placed at distances s ₁ , s ₂ from the reflecting plates 10, 12 and at a distance s from the edge 14. In the particular case, if irradiators 18 are placed in the bisectorial plane 20 of the angle reflector, then s ₁ = s ₂ = s • sin ( φ / 2).
To the conductive plates 10, 12 in the direction of their width, i.e. in the direction of the aperture of the antenna, additional conductive reflective plates 26, 28 of dimensions a, b are attached to their edges 22, 24. The edges of the plates 22, 24 are parallel to the edge 14 and form additional reflectors located at angles α and β to the main reflectors. The value of the angles satisfies the condition α, β, φ <π; α + β + φ +> 2π.
If the antenna should have a symmetrical radiation pattern, then the angles and sizes are chosen accordingly: α = β, a = b.

 The antenna has an aperture of size A and full size w in the direction of radiation.

 A general view of the experimental sample of the patented antenna is shown in FIG. 2. At the ends of the corner reflector 16, covers 30, 32 are installed and attached, which are elements for attaching the irradiators 18 and the electrical connector 34, designed to connect the irradiating device to the antenna-feeder path. Covers can be made of conductive material.

 The irradiators 18 are made in the form of a linear array of emitters 40, placed parallel to the edge 14. Each of the emitters 40 is made in the form of an electric vibrator. The design of such emitters 40 is known and in this invention emitters are used for a known purpose. The antenna height in the vertical plane is L.

As an example of the invention, a corner antenna is synthesized and implemented, having a U-shaped characteristic of the radiation pattern in the sector ± 30 ^o . The values of the corresponding geometric parameters are summarized in the table. The geometrical parameters of a corner antenna sample [1], with which a comparison was made during the tests, are also given there.

The values of the selected angles φ, α, β for the experimental sample of the patented antenna satisfy the above conditions (1), (2):
(1) 162 ^° , 129 ^° , 129 ^° <π; 162 ^o +129 ^o +129 ^o = 420 ^o > 2π,
(2) 5 / 8λ> (s • sin (φ / 2))> 1 / 8λ, for λ _cf = 158 mm the condition 60>35> 20 is fulfilled.

In FIG. Figure 3 presents the results of measuring radiation patterns for two antennas in the azimuthal (horizontal) plane. The dependence of the gain (KU) for a conventional angular antenna [1] (curve 1) and the corresponding characteristic for the patented antenna design (curve 2) at a frequency of 1.92 GHz are presented. The gain of both antennas is normalized by the KU value of the patented antenna at θ = 0. It can be seen that the patented antenna design provides a more uniform level of radiated power (unevenness 1 dB) in the 60-degree sector than the known angular antenna (unevenness 3 dB). In this case, the patented antenna has a radiation level for angles θ> 90 ^° less, and the minimum value of KU in the sector ± 30 ^o approximately 1 dB more than the known antenna.

 Studies of the patented antenna showed that the antenna gain in the indicated frequency range 1.8-2.0 GHz is 14.1-14.3 dB, which is close to the expected value. The standing wave coefficient (SWR) was determined both in the absence and in the presence of matching elements. In the first case, the SWR was less than 1.5 in the frequency range 1.8-2.1 GHz. When using a matching element (a strip line at the open end), the determined SWR value was also less than 1.5, but in a wider frequency range of 1.7-2.3 GHz.

 The obtained experimental data indicate that an antenna with a sector type radiation pattern has good characteristics and its use in communication systems is promising.

 The angular reflector of the patented antenna can be made using various technologies, for example, by stamping, which is flexible at the same time for all relevant structural elements, including end caps made of metal sheet, mainly aluminum alloys. These same elements or their individual parts can be formed separately with their subsequent assembly. In addition, the reflector can be made of plastic mass by pressing methods with subsequent coating (lamination) of the internal surfaces of the metal foil. The cavity of the reflector together with the emitters can be filled with polystyrene foam or other similar material from the group of non-polar solid dielectrics, and also contain other non-metallic protective elements that prevent the penetration of precipitation. So, opening the corner reflector can be closed by a fairing made of radiolucent material (not shown).

 A separate solution is the implementation of the reflector from the dielectric extended profile of a tubular shape (figure 4). The profile during molding using an extruder can be set by any one, proceeding not only from the necessary parameters of the corner reflector, that is, the sizes and inclination angles of the faces 101, 121, 261, 281, but also the fairing 50, as well as the fastening elements (not shown). However, the main advantage in this case will be the fact that there will be no need for a separate protective element - a fairing in the aperture of the reflector and complete tightness along the side surface is ensured.

 Irradiators can be performed by various methods. In particular, the technology of manufacturing printed emitters by lithography methods — etching of metallized dielectric material, or by other methods can be applied. Similarly, electrical matching elements can be manufactured. The above information indicates the industrial applicability of the patented invention.

Claims (11)

 1. A corner antenna comprising a corner reflector formed by two rectangular conductive plates connected at an angle φ and acting as main reflectors, an irradiating device located in the cavity of the said corner reflector, additional rectangular conductive plates serving as additional reflectors, each additional rectangular conductive plate placed at an angle to the same plate of the main reflectors and connected to the latter along the edge parallel to the line connections of the main reflectors, the values of the mentioned angles satisfy the conditions α, β, φ <π; α + β + φ> 2π, where α, β are the angles at which the plates of the main reflectors are connected to the plates of the additional reflectors. 2. The device according to claim 1, wherein said irradiating device is placed relative to said conductive plates of the main reflectors at distances s ₁ and s ₂ satisfying the ratios 5 / 8λ> (s ₁ , s ₂ )> 1 / 8λ, where: λ is the length waves of electromagnetic waves in the medium filling the cavity of the corner reflector.  3. The device according to claim 1 or 2, in which said irradiating device is made in the form of a linear array of emitters.  4. The device according to claim 1 or 2, in which said irradiating device is made in the form of a linear array of emitters, each of which is made in the form of an electric vibrator.  5. The device according to any one of paragraphs. 1-4, in which said conductive plates are made of metal sheets.  6. The device according to any one of paragraphs. 1-4, in which the corner reflector is made of a single sheet of metal.  7. The device according to any one of paragraphs. 1-4, in which the said corner reflector is made of polymeric materials, and the conductive plates are formed by laminating the cavity of the reflector with metal.  8. The device according to any one of paragraphs. 1-7, in which the end surfaces of the said corner reflector are provided with covers fastened to the reflector, with the possibility of attaching to the latter antenna mounting elements and means for connecting to the antenna-feeder path.  9. The device of claim 8, wherein said caps are made of conductive material.  10. The device according to any one of paragraphs. 1-9, in which said cavity of the reflector is filled with dielectric material.  11. The device according to any one of paragraphs. 1-10, in which the opening of the corner reflector is closed by a fairing made of radiolucent material.

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