RU167585U1 - Two-polarized multi-frequency planar slit antenna of the shell type - Google Patents

Abstract

The utility model relates to the field of antenna technology, namely to planar antennas that are sensitive to polarization. Shell-type multi-frequency planar slit antenna consisting of a metal substrate with slits, sprayed on top of the dielectric layer substrate, a strip line system for communication with bolometers and a collecting lens. Moreover, in the proposed antenna, the slots do not intersect. The technical result consists in simplifying and accelerating the manufacturing process of the antenna. 13 ill.

Description

The present utility model relates to the field of antenna technology, namely to planar antennas that are sensitive to polarization.

Known planar antennas include a broadband log-periodic antenna (US Patent # US 6,211,839 B1, 2001). It is an antenna consisting of four separate radial elements made with a rotation of 90 degrees relative to the center. Each of these elements has a periodic logarithmic structure. The advantages of such an antenna include a wide operating frequency band, good polarization resolution, simplicity and compactness of execution. However, in practical implementation, combining such an antenna with detectors causes certain technological difficulties. In particular, for studies of the relict radiation polarization, connecting the antenna with cold electron bolometers using a strip line system does not manage to do without crossing the strip lines, which greatly complicates the process of joint manufacture of an antenna and bolometers.

A sinusoidal antenna (US Patent # US 4658262, 1987), which is an antenna also consisting of four separate radial elements, differs from the previous analogue by a sinusoidal periodicity of the structure of the elements, has similar advantages and disadvantages. Having a good resolution in polarization and a wide band of operating frequencies, a sinusoidal antenna, however, requires intersections of strip lines to connect with bolometers. This condition is not acceptable from the point of view of the production technology of such antenna systems and bolometers in a single technological cycle.

The closest analogue (prototype) of the proposed antenna is a planar cross-slot antenna [Chattopadayetal., 2000], which incorporates a metal substrate with four intersecting slots, two for measuring each of the polarizations. This antenna also has good polarization resolution and frequency band characteristics. The disadvantages of such an antenna include the fact that the same structural elements of the antenna (slit) are used to operate on several (two or more) frequency channels. This requirement makes it difficult to obtain the optimal receiving and frequency characteristics of the antenna for each of the frequency channels. Other disadvantages of such an antenna also include the impossibility of collecting the signal from the slots without crossing the strip lines.

The task to which the claimed utility model is directed is to create an antenna for use as a part of ultra-sensitive orbital receiving complexes developed and planned to be launched to study the polarization of CMB radiation - one of the important and topical issues of modern astronomy and cosmology. The requirements for such an antenna were formulated by the European Space Agency (ESA) and are shown in the second column of table 1. An important goal for ESA is to reduce the size of the focal plane by placing multi-frequency pixels in it to collect data at different frequencies. This approach will solve the problem with aberration and uniformity of the radiation pattern along the entire focal plane. To study the polarization of CMB radiation, special requirements are placed on the antenna systems that will be used in COrE. In addition to the possibility of simultaneously receiving two mutually perpendicular polarizations at several frequencies and in one pixel, such an antenna should be well matched with ultra-sensitive detectors of sub-THz radiation.

The multi-frequency planar slit antenna of the shell type consists, like the prototype, of a metal substrate with slits, sprayed on top of the dielectric layer substrate, a strip line system for communication with bolometers and a collecting lens, and differs from the prototype in that the slots do not intersect in the proposed antenna. The technical result is achieved by combining a special arrangement of slots in the shell antenna and their dumbbell shape. An important advantage of a shell-type antenna is that each set of slots is designed to operate on one frequency, which allows you to adjust each system of slots individually, without affecting the characteristics of the antenna elements responsible for working at adjacent frequencies.

The utility model is illustrated by drawings, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only illustrative materials of a particular case of execution:

In FIG. 1 General view of the system and its cross section

In FIG. 2 Design of the central part of the antenna for one frequency

In FIG. 3 Design of the central part of the antenna for two frequencies

The shell-type antenna is a system of slots made in the metal layer 1, which are the main structural elements of the antenna and determine its characteristics. This metal layer is coated with a dielectric layer. On top of the dielectric layer is a system of strip lines that provide the connection of slots and detectors. On the other hand, from the metal layer, there is a substrate 2 on which a spherical lens 3 is fixed with an antireflection coating 4 applied to it.

An embodiment of the central part of the antenna for a single frequency is shown in FIG. 2. The dielectric layer is hidden for clarity of the drawing. The antenna consists of a system of slots 5 tuned to the operating frequency. The narrowing in the center of the slots 6 is a concentrated capacity. The signal collection from the slots is performed using strip lines ending in a concentrated capacitance 7. The signal analysis is performed by detectors 8.

The antenna can be modified to a larger number of frequencies.

The use of cold electron bolometers is proposed as detectors.

The substrate and the lens can be made of silicon. The antireflection coating of the lens can be made of quartz. The dielectric layer may be made of SiO ₂ .

The operation of the device is as follows. A system of four identical slots located at an equal distance from each other form an antenna element responsible for one operating frequency. The length of the slots is selected approximately equal to λ / 2 - half the wavelength at the operating frequency. The gap and the strip line are conjugated using a segment of the strip line located near one of the edges of the gap and ending in a concentrated container. The narrowing in the center of the slit is also a concentrated capacity and serves to fine-tune the resonant frequency of the slit. Also for this purpose, a change in the distance of the strip line to the edge of the slit and the value of the lumped capacitance at which the strip line ends can be used.

To tune the antenna to two or more frequencies, it is necessary to add new system elements consisting of four identical slots located in the same way as in FIG. 2, with symmetry about the center of the entire antenna.

The characteristics of the radiation pattern of the proposed antenna are determined mainly by the distance between the opposite slots. To ensure the optimal angular width of the main beam of the radiation pattern, and its minimum ellipticity, this distance should be approximately equal to λ / 2.

The most important advantage of a shell-type antenna is that each slot system is designed to operate at the same frequency. This allows you to adjust each system of slots individually, without affecting the characteristics of the antenna elements responsible for working at adjacent frequencies. Another practical advantage of the proposed antenna is that the connection of slots and detectors using strip lines can be made without intersecting strip lines, which will simplify and speed up the manufacturing process of such a system of antennas and detectors.

An embodiment of such a system for the two frequencies 75 and 105 GHz required for ESA tasks is shown in FIG. H. Numerical simulation of the system was carried out in the CSTMWS software package.

During the simulation, the following parameters were selected:

silicon substrate 1850 μm thick;

a metal layer 0.15 μm thick;

a dielectric layer of SiO ₂ 0.3 μm thick;

silicon spherical lens with a diameter of 9 mm;

430 μm thick quartz antireflection coating.

In the illustrated version of the antenna, 4 bolometers are used: two at 75 GHz, horizontal and vertical polarization, respectively, and similarly for the frequency of 105 GHz.

The results of numerical simulation of a shell-type antenna are shown in the following figures:

In FIG. 4 Directivity pattern at 75 GHz for horizontal polarization, copolar and cross-polar components.

In FIG. 5 Directivity pattern at 75 GHz for vertical polarization, copolar and cross-polar components.

In FIG. 6 105 GHz radiation pattern for horizontal polarization, copolar and cross-polar components.

In FIG. 7 105 GHz radiation pattern for vertical polarization, copolar and cross-polar components.

In FIG. 8 Frequency dependence of the S11 parameter for the horizontal polarization of the received wave, at Rport = 20 Ohms. The red curve for the slit at a frequency of 75 GHz, the blue curve for the slit at 105 GHz.

In FIG. 9 Frequency dependences of the real (red curve) and imaginary (blue curve) parts of the antenna impedance at 75 GHz, horizontal polarization.

In FIG. 10 Frequency dependences of the real (red curve) and imaginary (blue curve) parts of the antenna impedance at 105 GHz, horizontal polarization.

In FIG. 11 Frequency dependence of the S11 parameter for the vertical polarization of the received wave, at Rport = 20 Ohms. The red curve for the slit at a frequency of 75 GHz, the blue curve for the slit at 105 GHz.

In FIG. 12 Frequency dependences of the real (red curve) and imaginary (blue curve) parts of the antenna impedance at 75 GHz, vertical polarization.

In FIG. 13 Frequency dependences of the real (red curve) and imaginary (blue curve) parts of the antenna impedance at 105 GHz, vertical polarization.

Table 1 shows the numerical characteristics obtained as a result of computer simulation of a shell-type antenna.

Thus, a shell-type antenna is a new unique type of planar antenna, which is sensitive to polarization, and due to its compactness, flexibility of adjustment, convenience and ease of manufacture, as well as a narrow radiation pattern and selectivity of frequency characteristics can be used for a wide range of tasks, including including for future space missions and relict radiation research.

[Chattopaday et al., 2000] Goutam Chattopadhyay, David Miller, Henry G. Le Duc, and Jonas Zmuidzinas, IEEE TRANSACTIONS ON MI-CROWAVE THEORY AND TECHNIQUES, vol. 48, No. 10, OCTOBER 2000.1680-1686.

Claims (1)

A multi-frequency planar slit antenna of the shell type, consisting of a metal substrate with slots, sprayed on top of the dielectric layer substrate, a strip of lines for communication with bolometers and a collecting lens, and characterized in that the slots do not intersect in the proposed antenna.

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