RU2629906C1 - Mirror antenna with double polarization and wide scanning angle - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: antenna comprises a reflector which has a profile of parabolic shape in the first section and a profile of hyperbolic shape in the second section, wherein the second section is orthogonal to the first section; and an irradiation structure comprising at least one phased antenna array configured to irradiate at least a portion of the reflector and scan the beam. Moreover, the edges of the parabolic reflector envelope are directed toward the irradiation structure, and the edges of the hyperbolic reflector envelope are directed outward from the irradiation structure.

EFFECT: increased scanning angle of the antenna in one plane while providing the possibility of forming the required directional diagram in another plane without increasing the dimensions, without degrading the efficiency and without increasing the level of the side lobes.

11 cl, 10 dwg

Description

FIELD OF THE INVENTION

The present invention relates to antenna technology and, more specifically, to a mirrored antenna with an irradiating antenna array with double polarization and a wide scanning angle.

State of the art

Constantly increasing user requirements determine the rapid development of mobile communications technology. Currently, active development of 5G millimeter-wave networks is underway, which will be characterized by higher performance indicators based on experience in use, including factors such as the convenience of establishing connections with nearby devices and increased energy efficiency. For millimeter wave technologies, there are many fundamental problems associated with the physics of antenna arrays, the design of a high-speed transceiver, etc.

The main tasks for the integration of antennas in the millimeter range remain cost, low interference, ensuring the required communication quality and energy efficiency. In this case, the communication channel must remain stable when the position of the mobile device with which the communication is conducted is changed. Accordingly, the following requirements are imposed on antennas, for example, base stations:

1) high gain,

2) wide scan angles,

3) high focus

4) low level of side lobes,

5) bipolar beam forming to increase the speed and increase the stability of data transmission,

6) high antenna efficiency.

With the functioning of scanning antennas, the task of increasing the scanning angle is very urgent, since it allows you to increase the efficiency of the system. The scanning angle of a traditional antenna array is usually limited to ± 45 degrees without a significant reduction in gain and without an excessive increase in the level of side lobes. Accordingly, in the traditional embodiment, to cover a 360-degree zone, a minimum of 4 sectors of 90 degrees are required, that is, 4 antennas with a scan angle of ± 45 degrees (Fig. 1). Meanwhile, the use of three antennas instead of four to cover the entire coverage area could significantly reduce the complexity requirements of control and distribution devices on the transceiver side of the base station, reduce its dimensions, and simplify and speed up the installation of the base station. Therefore, it is desirable that each of these three antennas has a scan angle of at least ± 60 degrees.

To implement the expansion of the scanning angle in the millimeter range, special tools are required. Currently, for increasing the scanning angle, for example, a conformal antenna array (cylindrical), a Luneberg lens antenna, and axisymmetric switched antennas are used. These types of antennas allow you to get a scan angle of ± 90 or more. However, these types of antennas have some drawbacks: the presence of a complex switch that introduces additional losses, large spatial dimensions and low efficiency of the antenna aperture.

Traditional antenna arrays are also suitable for obtaining advanced beam scanning through special structures installed in front of the array. These structures cause an additional deflection of the wave front. However, these structures are commonly used for large gratings having wide sides.

Several millimeter-wave solutions are known in the art that are more or less close to the above requirements.

Thus, the publication ʺAn E-band Cylindrical Reflector Antenna for Wireless Communication Systemsʺ 7th European Conference on Antennas and Propagation (EUCAP2013) discloses a cylindrical reflector antenna (Fig. 2A), designed for high-frequency use and has a high gain and relatively low losses. However, such an antenna does not have the ability to scan, has an efficiency of about 60% and works with only one polarization.

Also known is an antenna (Fig. 2B) for use at frequencies of the 23 GHz band, disclosed in ylCylindrical-parabolic reflector with printed antenna structuresʺ IHTM-CMTM, University of Belgrade Journal of Microelectronics, Electronic Components And Materials Vol. 43, No.2 ( 2013), 97-102. It has a radiating structure in the form of a microstrip antenna array of dipoles and a cylindrical reflector. As in the previous example, this antenna does not have the ability to scan and works with only one polarization. In addition, it has an efficiency of only 56% due to the fact that it has a microstrip feeder line for powering the emitters, in which the losses reach 2-3 dB. In the indicated range of millimeter wavelengths, losses in feeder microstrip lines increase significantly due to losses in the dielectric material and technological manufacturing defects (any irregularities, thickenings, narrowing, notches, bends, angles, etc. can lead to re-reflection, spurious radiation and etc.). Therefore, a distributed feeder path system is a disadvantage for millimeter antennas.

Another known antenna (Fig. 2C) is disclosed in Design The Design on the Antenna Array with High Gain and Scanning Beam Be Lu Zhiyong, The 54th Research Institute of CETC, Shijiazhuang, 050081, China, International Conference on Microwave and Millimeter Wave Technology (ICMMT) , 2012. In this case, a cylindrical (parabolic) reflector is irradiated with a special grating to form a scanning beam. This antenna, like the previous ones, works with only one polarization and has a relatively low efficiency (about 60%). In addition, it has a very limited scanning angle (± 20 degrees), which is why 9 antennas are needed to cover a 360-degree zone, and given its extreme cumbersomeness, using such an antenna in mobile base stations is unattractive.

Another well-known technical solution in the millimeter range is the Thomson CSF Radar Maser-T antenna (Fig. 2D). This is a complex scanning antenna array, consisting of many linear microstrip antenna arrays, each of which is connected to a separate transceiver circuit. Nevertheless, despite all its complexity, this antenna is limited by a scanning angle of ± 40 degrees, and its microstrip structure causes large losses in the feeder line and low efficiency.

Thus, well-known technologies are not suitable for the development of antenna devices that would simultaneously meet all of the above requirements.

SUMMARY OF THE INVENTION

In order to eliminate at least some of the aforementioned drawbacks of the prior art, the present invention is directed to a mirrored antenna with an irradiating antenna array with double polarization and a wide scanning angle.

According to the present invention, there is provided an antenna comprising: a reflector that has a parabolic shape in the first section and a hyperbolic shape in the second section, the second section being orthogonal to the first section; and an irradiating structure comprising at least one phased antenna array configured to irradiate at least a portion of the reflector and scan the beam, wherein the edges of the parabolic envelope of the reflector are directed toward the irradiating structure and the edges of the hyperbolic envelope of the reflector are directed away from the irradiating structure.

In one embodiment, the irradiating structure is linear and is coplanar with the hyperbolic profile perpendicular to the line of symmetry of the hyperbola.

In one embodiment, the irradiating structure comprises at least two phased antenna arrays, each of which is configured to irradiate a corresponding portion of the reflector.

In one embodiment, the phased array antenna is configured to form a beam with dual polarization.

In one embodiment, the phased array is waveguide.

In one embodiment, each phased array antenna emitter is a metallic or metallized hollow waveguide open towards the reflector and closed on the opposite side.

In one embodiment, each phased array antenna emitter is a metal or metallized hollow waveguide that is powered by the microstrip line contained therein.

In one embodiment, the waveguide comprises at least one printed circuit board that is located in a plane perpendicular to the axis of the waveguide and separates the waveguide into parts, and is clamped between the separated parts of the waveguide, said at least one printed circuit board comprising a feeder and a waveguide excitation probe, which are made in the form of a microstrip line, the microstrip line being linear and extending perpendicularly through the wall of the waveguide, one end of the microstrip line being supported second dielectric circuit board goes into the waveguide cavity, forming a waveguide probe excitation, the metal in the divided portion of the waveguide is eliminated with the formation of the gutter around the microstrip line.

In one embodiment, each of the at least one printed circuit board comprises two microstrips located symmetrically on both sides of the substrate of the printed circuit board.

In one embodiment, the waveguide comprises two printed circuit boards, the microstrip line of the first printed circuit board being perpendicular to the microstrip line of the second printed circuit board.

In one embodiment, protrusions are formed along the walls in the interior of the waveguide to lower the critical frequency of the waveguide.

The present invention allows to realize an antenna with an improved set of characteristics, in particular, it provides an increase in the scanning angle of the antenna in one plane while making it possible to form the desired radiation pattern in another plane without increasing dimensions, without compromising efficiency and without increasing the level of side lobes. Moreover, if the proposed antenna is used for the base station, the requirements for the complexity of control and distribution devices on the transceiver side of the base station are reduced, the dimensions of the base station are reduced, its installation is simplified and accelerated, and energy efficiency is increased.

Brief Description of the Drawings

FIG. 1 - Traditional 4-sector base station.

FIG. 2A-2D — Examples of known millimeter-wave antennas.

FIG. 3 - Antenna according to the present invention.

FIG. 4 - Characteristics of a hyperbolic reflector in comparison with a traditional cylindrical one.

FIG. 5 - Base station with 3 sectors according to the present invention.

FIG. 6 - Irradiating structure according to the present invention.

FIG. 7 - Phased array antenna emitter (structural fragment) according to the present invention.

FIG. 8 - Microstrip line according to the present invention.

FIG. 9 is a radiation pattern of an antenna according to the present invention in a vertical (elevation) plane.

FIG. 10 is a graph to facilitate the calculation of the hyperbolic reflector profile.

Detailed description

In FIG. 1 shows a traditional 4-sector base station. For each 90 degree sector, there is one antenna with a scan angle of ± 45 degrees. Thus, in the entire coverage area of 360 degrees, the base station implements the functions of mobile communication for mobile stations (MS), such as smartphones, tablets, airborne communication systems, etc.

As mentioned above, in the prior art there is a need to create an antenna with a large scanning angle, which would simplify the design and installation of the base station.

An antenna with an increased scanning angle is shown in FIG. 3. According to the present invention, the antenna comprises a reflector (mirror), which has a parabolic shape in the first section and a hyperbolic shape in the second section, which is orthogonal to the first section. Thus, the shape of the reflector can be described as a parabolic hyperboloid. The antenna also contains an irradiating structure for irradiating the reflector, so that the edges of the parabolic envelope of the reflector are directed to the irradiating structure, and the edges of the hyperbolic envelope of the reflector are directed from the irradiating structure. The irradiating structure contains at least one phased antenna array in order to be able to form a beam pattern and scan the beam.

When using such an antenna, for example, in a base station, it is advisable to arrange it so that the parabolic envelope of the antenna passes in a vertical cross section, and the hyperbolic envelope of the antenna passes in a horizontal cross section.

The proposed shape of the antenna reflector makes it possible to substantially increase the beam scanning angle due to the fact that in such an antenna the side diffraction lobes do not exceed an acceptable level even at a beam angle of 60 degrees, as shown on the right in FIG. 4. In contrast, for example, as depicted on the left in FIG. 4, traditional parabolic-cylindrical antennas, which in one cross section have a flat profile, with a beam deflection angle of more than 45 degrees, have diffraction lobe levels comparable to the level of the main beam, thereby creating a strong level of reception and transmission in undesirable directions. In addition, the antenna gain decreases in the main direction. However, in the proposed antenna there is no significant drop in gain, deterioration in efficiency or directivity compared to traditional millimeter-wave antennas having equal dimensions. This effect can be explained by the fact that a hyperbola reduces the image of an object, i.e., when a hyperbola is applied to an antenna reflector irradiated by a phased antenna array, an (imaginary) decrease in the electric distance between the radiating elements of the array occurs, which makes it possible to comprehensively improve the characteristics of the antenna. The condition imposed on the distance between the radiating elements, in the absence of spurious diffraction lobes:

By reducing the distance between the lattice elements with the help of a hyperbola, it is possible to increase the scanning angle, and the larger the curvature of the hyperbola, the greater the scanning angle. In this case, the actual distance between the lattice elements does not change.

Thus, according to the present invention, as shown in FIG. 5, the base station can be equipped with only three antennas instead of the traditional four or more. An antenna having a scan angle of ± 60 degrees is located in each of the three 120-degree sectors, and the base station effectively covers the entire coverage area, maintaining the required gain level and not creating much interference. Thus, the complexity requirements for control and distribution devices on the side of the transceiver of the base station are reduced, the dimensions of the base station are reduced, its installation is simplified and accelerated, and energy efficiency is increased. Moreover, the possibility of forming the shape of the radiation pattern in the goniometric plane remains.

In one embodiment, the irradiating structure of the antenna in cross section having a hyperbola profile may have a shape close to a circle or square and be located on the optical axis of the antenna. In another embodiment, the antenna irradiating structure may be linear and located symmetrically with respect to the center of the antenna axis in the horizontal plane, that is, coplanar with the hyperbolic profile perpendicular to the symmetry line of the hyperbola (as shown in Fig. 3). The exact shape and location of the irradiating structure depends on the specific application and antenna requirements.

The irradiating structure may contain one phased antenna array that irradiates the entire accessible surface of the reflector. Alternatively, the irradiating structure may comprise two or more phased antenna arrays, each of which irradiates a corresponding portion of the reflector. For example, in FIG. Figure 3 shows two phased antenna arrays: one irradiates the upper half of the reflector, and the other irradiates the lower half of the reflector.

The phased array can be configured to form a beam with double polarization.

In order to further improve the characteristics of the proposed antenna, the phased array can be waveguide, as shown in FIG. 6. The special structure of the emitter and the supply line allows minimizing the losses of the irradiator as a whole, while increasing the antenna efficiency, reducing spurious radiation and, as a result, increasing the gain.

In particular, in the proposed embodiment (Fig. 7), each radiator of a phased antenna array can be a metal or metallized cavity, the walls of which form a hollow waveguide of complex cross section, open towards the reflector and closed on the opposite side. One of the walls of the waveguide, located perpendicular to its axis, is absent, creating conditions for radiation, and the second, opposite rear wall serves as a reflector. The shape and dimensions of the cross-section of the waveguide must satisfy the conditions for the propagation of a regular wave (in particular, the wavelength imposes a size constraint, having a critical value at which a smaller cross-section is not able to transmit the wave). At about a quarter of the wavelength in the waveguide from the rear wall, the emitter (waveguide) is divided into two parts by a plane perpendicular to the axis of the waveguide. In this plane there is a printed circuit board with a feeder and a probe for exciting the waveguide. The feeder and probe are a microstrip line made on a thin film dielectric. The printed circuit board is clamped between the separated parts (halves) of the emitter. Metal in the halves of the emitter around the microstrip line is selected (extracted) along the profile of the gutter, which excludes contact of the microstrip line with the metal elements of the emitter and creates the conditions for the propagation of the TEM wave. The width of the strip line and the transverse dimensions of the gutter are determined by the necessary wave resistance. One end of the microstrip line, supported by the dielectric of the printed circuit board, exits into the cavity of the waveguide, forming a probe that excites the emitter. The length of the probe is approximately equal to ¾ of the height of the waveguide. The exact value is determined by the condition of the best matching of the waveguide with the feeder. Structurally, all the power elements are placed on a common board, and the emitters in a single unit. The power to the emitters comes from a radio frequency (RF) circuit (for example, an RF chip, as shown in Fig. 7).

In order to form a beam with a double polarization, the waveguide (emitter) contains two not in contact with each other printed circuit boards, and the exciting probe of the first printed circuit board is perpendicular to the exciting probe of the second printed circuit board. Thus, independent excitation of two orthogonal polarizations occurs (in particular, horizontal polarization (HP) and vertical polarization (VP)). In the inner space of the waveguide, rectangular protrusions (ribs) are formed along the walls to lower the critical frequency, with restrictions on the transverse dimensions of the waveguide. The protrusions can be longitudinal and transverse. Between the closed end of the waveguide and the first printed circuit board, and also between the first printed circuit board and the second printed circuit board, such protrusions may be formed that are necessary only to excite the polarization wave provided by the exciting probe of the first printed circuit board. Further, protrusions that are necessary for the propagation of waves with both polarizations can be formed between the second printed circuit board and the open end of the waveguide.

The printed circuit board can be double-sided and contain two microstrip located symmetrically on both sides of the substrate of the printed circuit board (Fig. 8). This structure of the microstrip line allows you to optimize the distribution of the lines of the electromagnetic field so that it is concentrated in the air around the microstrip line, thereby significantly reducing losses in the feeder line and increasing the antenna efficiency. For example, in the classical symmetrical strip line at H = 0.8 mm and a frequency of 28 GHz using a Taconic TLY-based dielectric, losses of about 0.5 dB / cm are observed, while in the proposed improved microstrip line with a metal waveguide earthen base and air filling only 0.1 dB / cm loss is observed.

The proposed structure of the phased antenna array allows the formation of a beam with double polarization while maintaining a high antenna efficiency, while the cross-polarization does not exceed -15 dB. In addition, it is possible to form the necessary amplitude-phase distribution and the shape of the radiation pattern in each plane in accordance with the requirements of a particular application.

General characteristics of the proposed antenna using a mirror in the form of a parabolic hyperboloid and low-loss phased waveguide antenna array are as follows: scanning angle ± 60 degrees, beam with double polarization, efficiency = 0.74. Moreover, the losses in the feeder line on the prototype were less than 1.5 dB.

The antenna according to the present invention can be used, for example, in the millimeter range for mobile networks of promising standard 5G, for automobile radars, for search radars, etc.

In this case, for example, as shown in FIG. 9 to the right, using a cosecant radiation pattern easily implemented in such an antenna of a base station in such an elevation plane, one can completely cover the entire coverage area in this plane without loss of gain at its edges, as a result of which neither additional scanning in the angle plane nor the presence of additional antennas are required to properly cover the entire coverage area, in contrast to traditional antennas (shown in Fig. 9 on the left).

The antenna according to the present invention is also fully suitable for use as part of MIMO equipment (multiple inputs - multiple outputs).

The necessary formulas for calculating the hyperbolic profile of the reflector are presented below with reference to FIG. 10. The most characteristic initial parameter M is preferably selected from values 1.3-1.6. At large M values, the scanning angle increases, but the antenna gain decreases. The equation for the hyperbolic profile is as follows:

Where

t is a free parameter,

f is the focal distance.

It should be understood that although in this document to describe various elements, components, areas, layers and / or sections, terms such as "first", "second", "third" and the like can be used, these elements, components , areas, layers and / or sections should not be limited to these terms. These terms are used only to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section may be called a second element, component, region, layer or section without departing from the scope of the present invention. In the present description, the term "and / or" includes any and all combinations of one or more of the corresponding items listed. The elements mentioned in the singular do not exclude the plurality of elements, unless specifically indicated otherwise.

The functionality of the element indicated in the description or claims as a single element can be implemented in practice through several components of the device, and vice versa, the functionality of the elements indicated in the description or claims as several separate elements can be implemented in practice through a single component.

In one embodiment, the elements / blocks of the proposed antenna are located in a common housing, are located on the same frame / structure / printed circuit board and are structurally connected to each other by means of assembly (assembly) operations and functionally by means of communication lines. The mentioned communication lines or channels, unless otherwise indicated, are standard communication lines known to specialists, the material implementation of which does not require creative efforts. A communication line can be a wire, a set of wires, a bus, a track, a wireless communication line (inductive, radio frequency, infrared, ultrasonic, etc.). Communication protocols over communication lines are known to specialists and are not disclosed separately.

The functional connection of elements should be understood as a connection that ensures the correct interaction of these elements with each other and the implementation of one or another functionality of the elements. Particular examples of functional communication may be communication with the possibility of exchanging information, communication with the possibility of transmitting electric current, communication with the possibility of transmitting mechanical motion, communication with the possibility of transmitting light, sound, electromagnetic or mechanical vibrations, etc. The specific type of functional connection is determined by the nature of the interaction of the mentioned elements, and, unless otherwise indicated, is provided by well-known means using principles well known in the art.

The design of the elements of the proposed device is known to specialists in this field of technology and is not described separately in this document, unless otherwise indicated. The antenna elements may be made of any suitable material. These components can be manufactured using known methods, including, by way of example only, machining and investment casting. Assembly, connection and other operations in accordance with the above description also correspond to the knowledge of a person skilled in the art and, therefore, will not be explained in more detail here.

Although exemplary embodiments have been described in detail and shown in the accompanying drawings, it should be understood that such embodiments are merely illustrative and not intended to limit the present invention, and that the present invention should not be limited to the particular arrangements and constructions shown and described, since In the art, based on the information set forth in the description and knowledge of the prior art, various other modifications may be apparent in Rianta of the invention without departing from the spirit and scope of the invention.

Claims (14)

1. An antenna containing: a reflector that has a parabolic shape in the first section and a hyperbolic shape in the second section, the second section being orthogonal to the first section; and an irradiating structure comprising at least one phased antenna array configured to irradiate at least a portion of the reflector and scan the beam, moreover, the edges of the parabolic envelope of the reflector are directed toward the irradiating structure, and the edges of the hyperbolic envelope of the reflector are directed from the irradiating structure. 2. The antenna according to claim 1, wherein the irradiating structure is linear and is located coplanarly with a hyperbolic profile perpendicular to the line of symmetry of the hyperbola. 3. The antenna according to claim 1, in which the irradiating structure contains at least two phased antenna arrays, each of which is configured to irradiate a corresponding part of the reflector. 4. The antenna according to claim 1, in which the phased antenna array is configured to form a beam with double polarization. 5. The antenna according to claim 1, in which the phased antenna array is a waveguide. 6. The antenna according to claim 5, in which each radiator of the phased antenna array is a metal or metallized hollow waveguide, open towards the reflector and closed on the opposite side. 7. The antenna according to claim 5, in which each radiator of the phased antenna array is a metal or metallized hollow waveguide, which is fed using the microstrip line contained therein. 8. The antenna according to claim 7, in which the waveguide contains at least one printed circuit board, which is located in a plane perpendicular to the axis of the waveguide and separates the waveguide into parts, and is clamped between the separated parts of the waveguide, said at least one printed circuit board containing a feeder and a waveguide excitation probe, which is made in the form of a microstrip line, wherein the microstrip line is linear and passes perpendicularly through the wall of the waveguide, with one end of the microstrip line supported by a dielectric Rick circuit board goes into the waveguide cavity to form a waveguide probe excitation, wherein the metal in the divided waveguide portions removed to form a trench around the microstrip line. 9. The antenna according to claim 8, in which each of the at least one printed circuit board contains two microstrip located symmetrically on both sides of the substrate of the printed circuit board. 10. The antenna of claim 8, wherein the waveguide comprises two printed circuit boards, wherein the microstrip line of the first printed circuit board is perpendicular to the microstrip line of the second printed circuit board. 11. The antenna according to claim 7, wherein protrusions are formed in the interior of the waveguide along the walls to lower the critical frequency of the waveguide.

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