RU57973U1 - WIDTH-MOUNTED MICRO-STRIP ANTENNA WITH A WIDTH DIRECTION DIAGRAM - Google Patents

Abstract

The utility model relates to antenna technology and can be used as a standalone antenna or as an element of a phased antenna array with beam scanning in a wide sector of angles, in particular, as a receiving antenna in the equipment of users of space navigation systems (GPS, GLONASS / GPS). The technical result consists in increasing the manufacturability of manufacturing and increasing the reliability of the antenna. The specified technical result is achieved by an aperture-fed microstrip antenna with a wide radiation pattern containing an antenna element made in the form of a printed conductor with a substrate mounted on the screen plane, a high-frequency cable, a high-frequency connector and a power board, while the substrate of the antenna element is made of a glass-shaped dielectric material with a screen metallized internal cavity including the end of the glass, which has a “window” in the metallization in the form of located completely under the printing conductor, the printing conductor is located on the top of the inverted dielectric cup, the power board is located on the bottom surface of the substrate and is a printed circuit board with a microstrip line, which has a ground plane common with the antenna element, which is the metallization of the inner cavity of the glass and the microstrip line runs under the slot perpendicular to it and crosses it in the center, the high-frequency cable passes into the hole in the screen plane RF cable outer conductor is connected to the metallized layer, the inner cup cavity and an inner conductor connected to the microstrip line, the other end is connected to a high frequency connector is used to connect a transmitter or receiver.

Description

The utility model relates to antenna technology and can be used as a standalone antenna or as an element of a phased antenna array with beam scanning in a wide sector of angles, in particular, as a receiving antenna in the equipment of users of space navigation systems (GPS, GLONASS / GPS).

The inventive microstrip antenna (MPA) is designed to receive and transmit radio signals and can be widely used in omnidirectional command, telemetry and communication radio lines, in particular as a receiving antenna in the equipment of users of space navigation systems (GPS, GLONASS / GPS, etc.) . Also, the inventive microstrip antenna can be used as an element of a phased array antenna with beam scanning in a very wide sector of angles.

The width of the radiation pattern of a microstrip antenna (MPA) is determined by the aperture of the printed conductor of the antenna element - with a decrease in aperture, the width of the radiation pattern increases. A decrease in the aperture of the printed conductor is usually achieved by increasing the dielectric constant of the MPA substrate material. However, the process of increasing the dielectric constant of the substrate material is not unlimited, because ultimately leads to a decrease in the radiation efficiency of MPA.

Known disk microstrip antenna containing a dielectric substrate, on one side of which there is a metal screen, and on the other a first disk of a metal emitter, a matching element located between the metal emitter and the metal screen, and a coaxial feeder, while the matching element is made in the form of a second metal disk and a piece of metal conductor, which is connected to the first and second metal emitters at two points located in their centers of symmetry (AS No. 15434 83, class IPC H 01 Q 1/38, published 02.15.90).

Improving the alignment and reducing the dimensions of the antenna is achieved by selecting the dimensions of the second disk, the length of the metal conductor of the emitter disk and the dielectric substrate in accordance with the proposed ratios. In this case, the introduction of the second disk leads to a decrease in the aperture of the antenna and, as a result, to a small expansion of the radiation pattern.

An antenna is also known, which contains a hollow circular cylinder of dielectric, on the outer surface of which a strip conductor is applied in the form of a spiral, and the inner

the surface is metallized and grounded, while the strip conductor has a constant width, and the distance between the turns is half of this width, powered by a coaxial cable (US Patent No. 4,323,900, class IPC 01 Q 1/38 dated 04/06/82). However, this device is complex in terms of technology and configuration.

The closest in technical essence to the proposed device is a microstrip antenna with a wide radiation pattern, containing an antenna element made in the form of a printed conductor with a substrate, a high-frequency cable with a high-frequency connector at the end and a conductive screen, characterized in that the substrate of the antenna element is made of a glass-like shape from dielectric material with a screen metallized inner cavity, while a printed conductor located on top of the dielectric with takana connected to a high-frequency cable through a metallized internal cavity of the substrate and the hole of the conductive screen (RF patent No. 2266591, publ. 20.12.2005).

The disadvantage of this microstrip antenna is that there must be a hole in the substrate for the central core of the high-frequency cable to pass, which is not always advisable, for example, in the case of making a glass (substrate) of ceramic (for technological reasons), the need for a sealed antenna or high temperature effects on the outer surface of the antenna (also for technological reasons).

The technical result is to increase the manufacturability of the antenna.

The specified technical result is achieved by an aperture-fed microstrip antenna with a wide radiation pattern containing an antenna element made in the form of a printed conductor with a substrate mounted on the screen plane, a high-frequency cable, a high-frequency connector and a power board, while the substrate of the antenna element is made of a glass-shaped dielectric material with a screen metallized internal cavity including the end of the glass, which has a “window” in the metallization in the form of located completely under the printing conductor, the printing conductor is located on the top of the inverted dielectric cup, the power board is located on the bottom surface of the substrate and is a printed circuit board with a microstrip line, which has a ground plane common with the antenna element, which is the metallization of the inner cavity of the glass , but

the microstrip line runs under the slit perpendicular to it and crosses it in the center, the high-frequency cable passes into the hole in the screen plane and the external conductor of the high-frequency cable is connected to the metallized layer of the inner cavity of the glass, and the inner conductor is connected to the microstrip line, the second end of the cable is connected to the high-frequency connector and Used to connect a transmitting or receiving device.

Figure 1 shows the structural electrical diagram of the aperture-fed microstrip antenna with a wide radiation pattern. An aperture-fed microstrip antenna with a wide radiation pattern includes a printed conductor 1, a dielectric substrate 2 with a metallized internal cavity 3, a power board 4, a high-frequency cable 5 with a high-frequency connector 6 at the end, and a screen plane 7. The printed conductor 1 and the dielectric substrate 2 comprise an antenna element, and the dielectric substrate 2 is made in the form of an inverted glass with a metallized internal cavity including the end of the glass, which has a “window” in the metallization and in the form of a slit 8, located completely under the printing conductor 1. The printing conductor 1 itself has dimensions exceeding the dimensions of the slit and is located on the outer side of the top of the glass, which is fixed on the screen plane 7.

The power board is a printed circuit board with a microstrip line 9, which has a common ground plane with the antenna element, which is metallized 3 of the inner cavity of the glass. The microstrip line runs under the slit perpendicular to it and crosses it in the center. The wave resistance of the microstrip line 9 is chosen equal to the wave resistance of the high-frequency cable 5. The location of the slit 8 relative to the printed conductor 1, the dimensions of the slit and the length of the length of the microstrip line extending beyond the width of the slit are calculated, including for the case of operation of the antenna in circular polarization mode. The high-frequency cable 5 is electrically connected at one end to the microstrip line 9, the outer conductor of the cable being soldered to the metallized layer 3 of the inner cavity of the cup, and the second end of the cable connected to the high-frequency connector 6. In this case, the high-frequency cable passes through the metallized inner cavity of the cup and the hole in the screen plane 7. The high-frequency connector 6 is used to connect a transmitting or receiving device. The screen plane 7 is electrically connected to the screen metallized

the internal cavity of the glass and serves to create unidirectional radiation (reception) of the microstrip antenna.

The principle of operation of a microstrip antenna is well known and consists in the fact that when a high-frequency signal is fed to the antenna input, high-frequency oscillations of a certain type are excited in it, and the radiation is due to the field "protruding" from the edges of the antenna, namely from the gaps between the printed conductor of the antenna element and screen plane. As the screen plane, the lower metallized surface of the dielectric substrate is usually used. The width of the radiation pattern (ND) is determined by the aperture of the printed conductor 1 of the antenna element, which, in turn, for a fixed operating frequency is inversely proportional to the value of the dielectric constant of the material of the dielectric substrate. With an increase in the dielectric constant of the substrate, the aperture of the printed conductor decreases, and the beam width increases. This property is most often used to expand the bottom of microstrip antennas. However, a decrease in the aperture of the printed conductor 1 ultimately leads to a decrease in the radiation efficiency of the microstrip antenna.

In the inventive microstrip antenna, the radiation pattern is expanded by lifting the antenna element, consisting of a printed conductor 1 and a metallized dielectric substrate 2 above the screen plane 7. This is accomplished by molding the dielectric substrate 2 with a metallized bottom surface 3 in the form of an inverted cup, on top of which and there is a printed conductor 1 of arbitrary shape. The antenna element raised above the conductive screen 7 is equivalent to the action of two emitters: real and imaginary, located specularly under the screen plane 7. The total beam of two such emitters increases the power level radiated in the direction of angles close to the screen plane. The increase in this power leads to the expansion of the bottom of the microstrip antenna. An additional effect on the expansion of the DN gives the presence on the lateral conductive surface of the antenna element of the dielectric layer. The degree of DN expansion depends on the height of the antenna element 1 above the screen plane 5 and the dielectric constant of the substrate material - the higher this value, the wider the DN due to two factors: reducing the size of the printed conductor and “pulling” the field toward the side of the conducting glass surface, dielectric coated.

The excitation of the inventive microstrip antenna is carried out from the microstrip line 9 through the slotted "window" 8 (aperture) located in the metallization 3 of the inner part

cups under the printed conductor 1. The microstrip line 9, crossing the slot 8 in the perpendicular direction (the direction of the current in the line coincides with the direction of the electric lines of force in the slot) excites it, and the slot in turn excites the antenna element. The gap is located in such a way that it crosses the currents in the metallization 3 for the working type of oscillation of the antenna element.

Claims (1)

An aperture-fed microstrip antenna with a wide radiation pattern, containing an antenna element made in the form of a printed conductor with a substrate mounted on the screen plane, a high-frequency cable, a high-frequency connector and a power board, while the substrate of the antenna element is made of a glass-like shape from a dielectric material with a metallic screen internal cavity including the end of the glass, which has a “window” in the metallization in the form of a slit located completely under the printed wire The printed conductor is located on top of the inverted dielectric cup, the power board is located on the bottom surface of the substrate and is a printed circuit board with a microstrip line, which has a ground plane common to the antenna element, which is metallization of the inner cavity of the glass, and the microstrip line runs under slit perpendicular to it and crosses it in the center, the high-frequency cable passes into the hole in the screen plane and the external conductor of the high-frequency cable under It is connected to the metallized layer of the inner cavity of the glass, and the inner conductor is connected to the microstrip line, the second end of the cable is connected to the high-frequency connector and serves to connect the transmitting or receiving device.