RU2824323C1 - Multiband microstrip antenna element with inductive spatial separation of radiators and common feed point - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering and serves as a radiating or receiving antenna element of a radio path in multi-band wireless information communication systems or in radio navigation systems. Result is achieved by spatial separation of emitters in antenna topology and providing their electrical connection with power points located on central emitter of topology, using concentrated inductive elements having low-pass filter properties and providing frequency separation of signals of different operating ranges.

EFFECT: providing operation of the antenna in several frequency ranges isolated from each other using a common antenna feed circuit for all operating ranges.

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Description

The invention relates to the field of radio engineering and can be used as a radiating or receiving antenna element of a radio path in multi-band wireless information and communication systems or in radio navigation systems.

The device "Multi-range microstrip antenna of the stack type" is known (patent RU 2315398 C1 published on 20.01.2008 Bulletin No. 2). In this design, the presence of several operating ranges is achieved by installing several microstrip antennas on top of each other. In this case, the emitter of the lower antenna element is the ground plane of the antenna element installed above it. The disadvantage of this approach to the formation of several operating ranges of the antenna is a multiple increase in the height of the device when working in several operating ranges, the presence of at least one feed point for each antenna element of the design, low technology of assembly and adjustment of the antenna. Also, in the stack type design, the position of the phase centers in each of the operating ranges varies greatly, which makes it difficult to use antennas with such a design in precision radio navigation systems.

Also known is the device "Compact multi-band microstrip antenna of circular polarization (variants)" (patent RU 2722629 C1 published 02.06.2020 Bulletin No. 16). In the design of this antenna, several emitters operating in different ranges, located on the upper plane of the dielectric substrate and separated from each other by gaps in the metallization, are excited by capacitive coupling with a conductive strip located between two layers of dielectric material and connected at one end to a common feed point of the antenna. The disadvantage of this design is the inability to reduce its size by using substrates with high permittivity, since in this case the capacitive coupling of the conductive strip with the emitters located above it is destroyed, which leads to a loss of antenna performance. Another disadvantage of this design is that circular polarization in each of the operating ranges is provided by the topology of the emitters, which is less effective than providing polarization by imposing a phase on several power points, and in the presented design, the presence of several power points in a number of cases is not possible due to their strong connection with each other along the field.

The closest to the described invention, selected as a prototype, is the device "Multi-band circular polarization antenna with metamaterial" (patent RU 2480870 C1 published on 27.04.2013 Bulletin No. 12). Just like in the described invention, in the prototype device the operation of the device in several frequency ranges is ensured by the concentric arrangement of additional emitters around the main central emitter, to which the feed points are connected. The difference is that in the prototype, unlike the described invention, the connection of the external concentrically located emitters with the central emitter is carried out not by means of decoupling chokes, but by means of a direct connection by conducting elements of the topology. Reactive elements are inserted into the break in the topology of concentrically located emitters, providing their additional matching with the feed points. The disadvantage of a direct connection of emitters to each other is that the emitters are connected to each other. In view of this, the formation of the directivity diagram and the phase center of the antenna in each of the ranges occurs taking into account the field distribution over the entire surface of the antenna element, which can lead to a distortion of the diagram shape and a shift in the phase center, which does not occur in the presence of decoupling between the emitters of different ranges. The use of reactive elements in the gap between the emitters for their coordination, as is done in the prototype under consideration, leads to a decrease in the quality factor of the emitter and, as a consequence, to a decrease in its gain.

The claimed invention is intended to operate as a receiving or transmitting antenna element of multi-band wireless information and communication systems or radio navigation systems.

The technical result provided by the invention consists in ensuring the operation of the antenna in several frequency ranges isolated from each other using a common antenna power supply circuit for all operating ranges.

The technical result is achieved by spatially separating the emitters in the antenna topology and providing their electrical connection with the power points located on the central emitter of the topology, using concentrated inductive elements that have the properties of a low-pass filter and provide frequency separation of signals of different operating ranges.

The technical result is achieved due to the fact that a multi-band microstrip antenna element with inductive spatial separation of emitters and a common feed point Antenna consisting of a dielectric substrate of a circular shape located on a conductive screen of arbitrary shape, on the upper side of which radiating elements are made in the form of a central disk and one or more rings concentrically located around it, wherein one or more antenna feed points are connected to the central disk, and the connection of the concentric rings with the feed points is ensured by means of concentrated inductive elements in a quantity not less than the number of feed points installed between the central disk and the concentric ring and between adjacent concentric rings, wherein the inductive elements are uniformly distributed along the perimeter of the concentric rings, and the value of their own inductance is selected in such a way as to block the propagation of a signal at the operating frequency of the central disk and to ensure the passage of a signal at the operating frequency of the concentric rings in the case of their installation between the disk and the concentric ring closest to it, and to block the propagation of a signal on operating frequency of the inner concentric ring and ensure the passage of a signal at the operating frequency of the outer concentric rings if they are installed between adjacent concentric rings.

In this case, the dielectric substrate is made in the shape of a square.

In this case, the radiating elements are made in the shape of a square.

The device is illustrated by the drawings Fig. 1 and Fig. 2, which show the designs of antenna elements with inductive spatial separation of the radiators and a common feed point, where Fig. 1 shows the design of a round antenna element, and Fig. 2 shows the design of a square antenna element.

The claimed device consists of a conductive screen (1) of arbitrary shape and size, on which a dielectric substrate (2) of a round (Fig. 1) or square (Fig. 2) shape is installed. On the plane of the substrate (2), which is not in contact with the screen (1), a central emitter (3) of a round (Fig. 1) or square (Fig. 2) shape, made of a conductive material, is located. Additional emitters (4) in the form of rings (Fig. 1) or squares (Fig. 2), made of a conductive material, the number of which is one less than the number of operating ranges of the antenna, are concentrically located around the central emitter (3). Adjacent additional emitters (4) are electrically connected in pairs to each other and to the central emitter (3) by means of concentrated inductive elements (5), uniformly distributed along the perimeter of each connection, the number of which on each paired connection is greater than or equal to the number of feed points (6) of the antenna. The antenna feed points (6) are located on the central radiator (3), are electrically connected to it and have no ohmic contact with any other conductive elements of the antenna structure.

The device operates as follows.

In case of antenna operation as a transmitter. The signal from the transmitter is fed to the antenna feed points (6). The conducting screen (1) is a zero potential surface. In case of presence of several feed points (6) in the antenna design, in order to provide circular polarization of the radiated field, the signal should be fed to them taking into account the phase difference equal to the angular distance between them. Matching of the input resistance of the feed points (6) with the output resistance of the transmitter is provided by shifting the feed points (6) toward the edge of the central radiator (3) and the thickness of the dielectric substrate (2). The signal fed to the feed points (6) is radiated by the outer edges of the central radiator (3) and additional radiators (4). The frequency of the radiated signal is determined by the diameters of the outer radiating edges of the central radiator (3) and additional radiators (4) and the dielectric constant of the substrate (2). In this case, the concentrated inductive elements (5), performing the function of a low-pass filter, block the propagation of the signal at the radiation frequency of the outer edge of the central emitter (2) further to the additional emitters (4) and provide electrical connection of the additional emitters (4) with the power points (6) at the radiation frequencies of the outer edges of the central emitters. Similarly, the concentrated inductive elements (5), installed between the additional emitters (4), block the propagation of the signal at the radiation frequency of the outer edge of the internal additional emitter (4) and provide electrical connection of the external additional emitter (4) with the power points (6). The frequency of the signal blocked by the concentrated inductive elements is determined by the value of their own inductance. Thus, the concentrated inductive elements (5) provide frequency decoupling of the radiating edges and, as a consequence, independent beam formation at the radiation frequencies of the latter.

In case of antenna operation as a receiver. The signal from the surrounding space arrives at the outer edges of the central radiator (3) and additional radiators (4). The frequency of the received signal is determined by the diameters of the outer radiating edges of the central radiator (3) and additional radiators (4) and the dielectric constant of the substrate (2). The received signal from the outer edges through the concentrated inductive elements (5) arrives at the feed points (6). In this case, the concentrated inductive elements (5), performing the function of a low-pass filter, block the propagation of the signal at the radiation frequency of the outer edge of the central radiator (2) to the additional radiators (4) and the propagation of the signal at the radiation frequency of the outer edge of the internal additional radiator (4) to the external additional radiators (4). The frequency of the signal blocked by the concentrated inductive elements is determined by the value of their own inductance. Thus, concentrated inductive elements (5) provide frequency decoupling of the radiating edges and, as a consequence, independent beam formation at the radiation frequencies of the latter. The received signal from the feed points (6) can be transmitted to the input of the signal receiver. The conducting screen (1) in this case is the surface of zero potential. In the case of several feed points (6) in the antenna design, in order to ensure reception of a signal with circular polarization of the field, the signal must be taken from them taking into account the phase difference equal to the angular distance between them. Matching the output resistance of the feed points (6) with the input resistance of the receiver is ensured by shifting the feed points (6) to the edge of the central radiator (3) and the thickness of the dielectric substrate (2).

Brief description of the drawings.

Fig. 1 shows the design of a circular antenna element with inductive spatial separation of the emitters and a common feed point.

Fig. 2 shows the design of a square antenna element with inductive spatial separation of the radiators and a common feed point.

Claims (1)

A multi-band microstrip antenna element with inductive spatial separation of emitters and a common feed point, consisting of a dielectric substrate of a circular or square shape, located on a conductive screen of arbitrary shape, on the upper side of which radiating elements are made in the form of a central disk or square and one or more ring or square elements concentrically located around it, wherein one or more antenna feed points are connected to the central radiating element, and the connection of the concentric radiating elements with the feed points is ensured by means of concentrated inductive elements in a quantity not less than the number of feed points installed between the central emitter and the concentric emitter and between adjacent concentric emitters, wherein the inductive elements are uniformly distributed along the perimeter of the concentric emitters, and the value of their own inductance is selected in such a way as to block the propagation of a signal at the operating frequency of the central emitter and ensure the passage of a signal at the operating frequency of the concentric emitters in the case of their installation between the central and the concentric emitter closest to it and to block the propagation of a signal at the operating frequency of the internal concentric emitter and to ensure the passage of a signal at the operating frequency of the external concentric emitters in the event that they are installed between adjacent concentric emitters.

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