RU2620195C1 - Resonant antenna - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: resonant antenna, consisting of a base; an antenna element mounted above it, fed through peripheral elements with period of 90° on the azimuth of four current leads; printed circuit board, located on the lower side of the base; and the output connector of antenna, is provided with a truncated hollow cone mounted on the base coaxially to it and made of a dielectric with relative dielectric permittivity of 3.5 to 5 and low losses on SHF, antenna element is located on the upper base of the dielectric cone in the center, and the circuit board is provided with a four-channel summing chip located in its center.

EFFECT: improve the stability of phase center position and reduce the dimensions of antenna.

4 cl, 3 dwg, 1 tbl

Description

The invention relates to antenna technology and can be used as a separate receiving, transmitting or transceiving global navigation satellite system (GNSS) antenna or element of a phased antenna array.

Known GNSS antenna, which is a flat slot antenna array, excited from the back side of the wave traveling in the microstrip transmission line [US patent No.20020067315, class. G03F 7/09; H01P 5/08; H01Q 1/36; H01Q 13/10; H01Q 13/20; H01Q 21/26; H01Q 9/27, publ. 2002-06-06].

A disadvantage of the known antenna is the design complexity and insufficiently high stability of the position of the phase center (± 5 mm).

A known microstrip antenna, the square radiator of which is fed at two points with a 90 ° phase shift, using a printed circuit board containing a hybrid power divider and installed either on the lower side of the base of the antenna or on the upper side of the radiator [US patent No. 3972049, class. H01Q 9/04; H01Q 9/40, publ. 1976-07-27].

The disadvantage of this design is narrowband (receiving signals only in the frequency range L1) and low stability of the position of the phase center (± 10 - ± 15 mm).

The closest technical solution to the proposed one is a resonant antenna, consisting of a base, an antenna element installed above it, fed through four current leads located on the periphery of the element with a period of 90 ° in azimuth, located on the lower side of the base of the printed circuit board and the antenna output connector [A. Popugaev E. Development of GNSS antennas at the Institute of Integrated Circuits (IIS) named after Fraunhofer, Collection of materials of the VI International Scientific Congress, State Educational Institution of Higher Professional Education “Siberian State Geodetic Academy”, Ministry of Education and Science of the Russian Federation, Novosibirsk, 2010, p. 86-94]. The power circuit of the antenna element for the implementation of the necessary amplitude-phase distribution in order to achieve the right circular polarization is made in microstrip (printed) design and is located on the lower part of the base. The circuit is located in the center of the circuit board and includes a hybrid ring, two resistive dividers. Antenna matching is done using transformers and loops.

The main disadvantages of the known antenna are large dimensions (diameter 146 mm, height 25 mm) and insufficiently high stability of the position of the phase center (± 8 mm).

The objective of the invention is to improve the stability of the position of the phase center and reduce the dimensions of the antenna.

The problem is solved in that the resonant antenna, consisting of a base, an antenna element installed above it, fed through four current leads located on the periphery of the element with a period of 90 ° in azimuth, located on the lower side of the base of the printed circuit board and the output connector of the antenna, the latter is equipped with a truncated hollow the dielectric cone mounted on the base coaxially with it, the antenna element is made round and located on the upper base of the dielectric cone in the center, the circuit board is equipped with A four-channel summing microcircuit located in its center.

Mostly the cone is made of a dielectric with a relative permittivity of 3.5 to 5 and low microwave losses, for example fiberglass, textolite, hetinax or porcelain.

It is advisable to conduct the current leads of the antenna element in the form of cylindrical metal pins having a height of two sections with diameters d ₁ and d ₂ , with d ₁ > d ₂ , the current lead section with a diameter d ₁ connected to the antenna element, and the current lead section with a diameter d ₂ connected to a printed circuit chip boards, the outputs of which are connected by 50-Ohm strip conductors of equal length with sections of current leads of diameter d ₂ , and its input is connected by a printed 50-Ohm conductor with the output connector of the antenna.

It is advisable to obtain a left-handed rotating polarization, arrange the printed circuit board with the microcircuit on the upper plane of the base in the cavity of the dielectric cone.

To achieve the specified technical result, the antenna element is given a circular shape and a truncated hollow dielectric cone is inserted between it and the base.

The introduction of a dielectric, in which the wavelength decreases to the square root of the dielectric constant of this dielectric, reduces the size of the antenna, which is a half-open resonator. This resonator, although it is half-open, i.e. It has an implicit resonance, yet it has dimensions associated with the wavelength. The use of a dielectric, which allows to reduce the resonant size, and leads to an increase in the stability of the position of the phase center of the antenna, because the smaller the dimensions of the antenna, the less its phase center shifts when waves are incident on it at different angles. In the limit, when the antenna is compressed to a point, its phase center will coincide with this point and, therefore, its position will generally not depend on the direction of arrival of the wave.

The microcircuit is made in the form of a four-channel summing microcircuit, creating a uniform amplitude and quadrature phase power distribution between the current leads.

The microstrip circuit of the prototype, located in the center of the circuit board and including a hybrid ring and two resistive dividers in the working frequency range of the antenna, creates significant amplitude and phase errors in the distribution of power between the current leads. These errors lead to instability of the position of the phase center of the antenna in the operating frequency range.

Thanks to the use of a four-channel summing microcircuit, it is possible to create a uniform amplitude and quadrature phase power distribution between the current leads, which is slightly dependent on the frequency, with fewer errors compared to the prototype and, accordingly, with a more stable position of the phase center in the working frequency range of the antenna.

In FIG. 1 shows a general sectional view of a resonant antenna.

In FIG. 2 is a plan view of a resonant antenna.

In FIG. 3 - radiation patterns of a resonant antenna.

The resonant antenna consists of a base 1, a truncated hollow dielectric cone 2 and an antenna element 3 located on the upper part of the dielectric cone 2. The cone 2 is made of a dielectric with a relative permittivity of 3.5 to 5 and low microwave losses, for example fiberglass, textolite, getinaksa or porcelain.

The antenna has a printed circuit board 4 located on the lower side of the base 1, and the current leads of the antenna element 3 located on the periphery of the antenna element 3 with a period of 90 ° in azimuth and passing through the holes of the dielectric cone 2.

Current leads are made in the form of cylindrical metal pins having two sections 5 and 6 in height with diameters d ₁ and d ₂ , with d ₁ > d ₂ , section 5 of the current lead with diameter d ₁ connected to the antenna element 3, and section 6 of the current lead with diameter d ₂ connected with a microcircuit of a printed circuit board 4, the outputs of which are connected by 50-Ohm strip conductors of equal length with sections 6 of current leads of diameter d ₂ , and its input is connected by a printed 50-Ohm conductor with an output connector of antenna 7. Sections of 5 metal pins of diameter d ₂ serve to match the antenna element 3 with 50 Ohm transmission lines. The semi-open nature of the resonator, excited by pins of diameter d ₂ , allows you to match the antenna element 3 with the power transmission lines in a wide frequency band: from 1160 to 1615 MHz. The length of the portion 6 of the current lead included in the printed circuit board 4 should be minimal so as not to short-circuit the current lead to the base 1 of the antenna.

The printed circuit board 4 incorporates a microcircuit 8, made in the form of a four-channel summing microcircuit, creating a uniform amplitude and quadrature phase power distribution between current leads 3, located in the center of the circuit board 4, the outputs of which are connected by 50-ohm strip conductors of equal length with metal pins of section 6 diameter d ₂ , and its input is connected by a printed 50-Ohm conductor to the output connector of the antenna 7.

The principle of operation of the antenna in transmission mode is as follows: electromagnetic energy through a four-channel summing chip 8 (in transmission mode, chip 8 works as a power divider, dividing the power supplied to its input into four parts with phases 0 °, 90 °, 180 °, 270 ° and bringing it to the current leads), enters the half-open resonator formed by the base 1 and the antenna element 3, and radiates into space through the gap formed by the edge of the antenna element 3 and the base 1.

Thus, the antenna emits four linearly polarized electromagnetic waves having phase shifts of 0 °, 90 °, 180 °, 270 °. The results of the interference of such waves is, as is known, [Panchenko S.A., Nefedov E.I. Microstrip antennas, Radio and communication, 1986, 134] - a wave of elliptical polarization. According to the principle of reciprocity [Drabkin A.L., Zuzenko V.L., Kiselev A.G. Antenna-feeder devices, M. Sovetskoe Radio, 1971, 137] the antenna when operating in the reception mode has the same characteristics (including the operating frequency range, radiation pattern and polarization characteristics) as when working in the transmission mode.

The printed circuit board 4 provides power to four sections of 6 metal pins of diameter d ₂ with phase shifts from pin to pin 90 ° in a clockwise direction to create a right-handed rotating polarization.

The data on the gain (KU), the ellipticity coefficients (FE) and the stability of the position of the phase center (Δφ) are given in the table.

The investigated antenna has smaller dimensions compared to the prototype antenna (φ120 × 17 mm compared to φ146 × 25 mm) and better stability of the phase center position (± 1 mm compared to ± 8 mm).

The proposed antenna is made of simple materials - metal plates and a dielectric (for example, a type of fiberglass) and does not require tuning work. Having a fairly small size and weight, it can be integrated into airborne receiving or transmitting systems.

An additional advantage of the proposed antenna is the suppression of radiation in the lower half-space, so that the characteristics of the antenna are not affected by objects surrounding it.

Claims (4)

1. The resonant antenna, consisting of a base, an antenna element mounted above it, fed through four current leads located on the periphery of the element with a period of 90 ° in azimuth, located on the lower side of the base of the printed circuit board and antenna output connector, characterized in that the antenna is equipped with a truncated hollow a cone mounted on the base coaxially with it and made of a dielectric with a relative permittivity of 3.5 to 5 and low microwave losses, the antenna element is located on the upper Considerations dielectric cone in the center, with the printed circuit board is equipped with four-summation chip located at its center. 2. The resonant antenna according to claim 1, characterized in that, as a dielectric, fiberglass, textolite, getinax or porcelain are used. 3. The resonant antenna according to claim 1, characterized in that the current leads of the antenna element are made in the form of cylindrical metal pins having two sections in height with diameters d ₁ and d ₂ , where d ₁ > d ₂ , the current lead section with a diameter of d _{1 is} connected to the antenna element, and a portion of the current lead with a diameter of d _{2 is} connected to a microcircuit of a printed circuit board, the outputs of which are connected by 50-Ohm strip conductors of equal length with sections of current leads of a diameter of d ₂ , and its input is connected by a printed 50-Ohm conductor to the output connector of the antenna. 4. The resonant antenna according to claim 1, characterized in that to obtain a left-handed rotating polarization, the printed circuit board with the microcircuit is located on the upper plane of the base in the cavity of the dielectric cone.

Images