RU143511U1 - SMALL ANCHOROUS CAMERA - Google Patents

Abstract

1. A small anechoic chamber containing a platform for the antenna under study inside the chamber, a radiating antenna in the upper part, and a window is made on the side wall, characterized in that the small anechoic chamber is made in the form of a truncated pyramid (1) from a single integral structure, in the internal volume on top, the camera includes a platform (2) for a radiating antenna with a rotation device and the radiating antenna itself (3), in the middle part of the internal volume, the camera contains a window (4), a radio-tight cover (5), a platform (6) for exploring the first antenna, the antenna under study (7), measuring equipment, the base of the internal chamber volume includes at least two layers of n + 1 wedge-shaped absorbers (8), and the radiating and studied antennas are connected to the measuring equipment outside the camera via communication lines (9 ) .2. A small anechoic chamber according to claim 1, characterized in that the radiating antenna is made on a dielectric board (10) and contains a power divider (11) and two symmetric vibrators (12) .3. A small anechoic chamber according to claim 1, characterized in that the platform (2) for the radiating antenna with the rotation device comprises a base (13), a rotary element (14), a guide sleeve (15), a rod (16) for attaching the radiating antenna, and elements mounting (17), and the rotary element (15) is made in the form of a rotary drum, the outer side of which contains a scale for dividing the angle of rotation in the horizontal plane. 4. A small anechoic chamber according to claim 1, characterized in that the platform (6) for the antenna under study is made of polyurethane foam. The small anechoic chamber according to claim 1, characterized in that to

Description

The utility model relates to antenna technology and can be used in measuring stands for research and testing of satellite and navigation antennas.

The small anechoic chamber (MBK) is designed for testing and research of satellite and navigation antennas.

The main task solved by a small anechoic chamber is attenuation to the required magnitude of reflection at the location of the satellite antenna under study. Thanks to the use of MBK, conditions are created for the prompt and accurate measurement of the noise figure and gain of a satellite dish or navigation antenna.

A known absorption structure and an anechoic chamber, the walls of which are coated with such an absorption structure, in which a layer of ferrite is installed at the bottom of the pyramidal anechoic chamber to reduce return loss to -20 dB, and the absorption material is located so that there is a small hole between them [1].

The range of operation of such an absorber of electromagnetic waves extends from 30 MHz to 3 GHz, which is not enough for the required measuring stand, designed to study satellite dishes up to 12 GHz.

An anechoic chamber is known in which manganese-zinc plates are used as absorbing surfaces, however, the operating frequency range of such a camera is from 30 MHz to 1000 MHz, which is not enough for the required measuring stand designed to study active satellite antennas up to 12 GHz [2].

Known anechoic chamber containing an end wall of radar absorbing pyramids, the axes of which are oriented to the radiation source, the end wall is equipped with two parallel frames, of which the rear is mounted with the possibility of movement [3]. This movement serves to improve anechoicity, but requires a parallelepiped shape of the anechoic chamber. The movement system significantly increases the bulkiness of the camera, since the radar absorbing pyramid is equipped with a rod directed along its axis and secured by spherical joints in the frames. This design does not allow to reduce the size of the anechoic chamber to the size of a desktop or floor device.

Known anechoic chamber, in which to increase the band of operating frequencies, the radar absorbing materials on the adjacent faces of each trihedral prism are selected with overlapping frequency characteristics [4]. This complicates the setup and design of such an anechoic chamber, and a device for rotating and moving each of the trihedral prisms is required, which does not make it compact and ready for operational work in the conditions of a test study of active antennas.

Known anechoic chamber, in which to reduce the measurement error of the diagrams, the cross section is made in the form of a parallelogram, some parallel sides of which are at an acute angle to the vertical plane, and the other two to the horizontal plane [5].

However, this anechoic chamber is made in the form of a closed room, the internal walls, the floor and ceiling of which are flat and covered with radar absorbing material. Therefore, such a solution is not suitable for incorporating this camera into the measuring path for performing operational studies of active antennas.

The closest device of the same purpose to the claimed utility model is a small anechoic chamber (MBK), consisting of a working chamber, the walls of which are coated with radar absorbing material, with a rotatable platform for the antenna under test, a collimator and a horn irradiator inside the working chamber, the camera being made in the form of a vertical assembly of the lower, working, collimator and upper sections. A window is closed on the front wall of the working section, which is closed by a door into which the antenna under test is inserted [6]. The collimator serves to reduce field distortions in the area of the antenna under test. This device is taken as a prototype.

For reasons that impede the achievement of the technical result indicated below when using the known device adopted for the prototype, the presence of a collimator in the known device complicates the MBC, the design is made of several assemblies connected by fasteners, with the formation of gap gaps. The narrow-band collimator limits the working frequency band.

The disadvantage is that all the walls of the chamber chosen for the closest analogue are coated with absorbing material, which reduces the working volume, increases the dimensions of the anechoic chamber and prevents the free placement of the antenna under study in the internal volume.

The principal drawback of MBK with a collimator is the strict requirements for the implementation of the mirror profile, since small deviations of the mirror profile from the calculated value can lead to significant variations in the amplitude and phase of the irradiation field at the aperture of the antenna under study.

The technical result of the proposed technical solution is to increase the accuracy and efficiency of measurements by improving the radio-absorbing characteristics of a small anechoic chamber.

The small anechoic chamber contains a platform for the antenna under investigation inside the chamber, a radiating antenna in the upper part, and a window is made on the side wall.

The essence of the proposed small anechoic chamber is that due to its pyramidal shape and the use of at least two layers of n + 1 wedge-shaped absorbers, it dramatically reduces the electromagnetic field variations in the region of the active or passive antenna under study, and thanks to its compact design, it is included in the measuring path and allows accurate measurements of the characteristics of the antenna. The proposed MBK works in conjunction with a measuring generator operating in a wide frequency range from 1 GHz to 12 GHz.

The technical result of the proposed technical solution is achieved by the fact that the small anechoic chamber is made in the form of a truncated pyramid from a single integral structure, in the inner volume from above the chamber includes a platform for a radiating antenna with a rotator and the radiating antenna itself, in the middle part of the internal volume the chamber contains a window, a radio-hermetic a cover, a platform for the studied antenna, the studied antenna, measuring equipment, the base of the internal volume of the chamber includes at least two layers n + 1 wedge-shaped absorbers (n can be any number), and the emitting and studied antennas are connected to the measuring equipment outside the camera via lines (for example, cable or optical fiber).

In the proposed design, described in the independent clause of the utility model, a change in the near electromagnetic field in the plane into which the antenna under investigation is acquired acquires the most minimal variations, which leads to an increase in the measurement accuracy when examining the antenna as part of the measuring stand.

The radiating antenna of a small anechoic chamber is made on a dielectric board and contains a power divider and two symmetric vibrators.

The platform for a radiating antenna with a rotation device contains a base (for example, a sheet of tin or aluminum), a rotary element, a guide sleeve, a rod for attaching a radiating antenna and fastening elements, the rotary element is made in the form of a rotary drum, the outer side of which contains a scale dividing the angle of rotation in the horizontal plane.

The platform for the antenna under study is made of polyurethane foam.

Wedge-shaped radar absorbers are made of a tetrahedral or pyramidal shape made of foamed polymer material with graphite chips, and the angle of inclination of the side walls of the chamber at the base and the bevel angles of each of the n + 1 wedge-shaped radar absorbers are chosen equal.

The small anechoic chamber is illustrated by the following figures:

FIG. 1 small anechoic chamber included in the measuring path;

FIG. 2 radiating antenna;

FIG. 3 - platform for a radiating antenna with a rotation device;

FIG. 4 - options for installing layers of wedge-shaped absorbers;

FIG. 5 - frequency dependence of the standing wave coefficient of the radiating antenna;

FIG. 6 - wedge-shaped radar absorber;

FIG. 7 - frequency characteristics of the reflection coefficient of a layer of wedge-shaped absorbers with different specific conductivities;

FIG. 8 - dependence of the electric field in the MBC along the line from the radiating antenna to the layer of wedge-shaped absorbers;

FIG. 9 - dependence of the electric field strength in MBC along the line in the plane of the platform for the antenna under study in two coordinates;

FIG. 10 signal propagation in a pyramidal and rectangular chamber;

FIG. 11 - small anechoic chamber (photo).

The small anechoic chamber (1) is made as a single whole sheet metal structure by welding at the joints of joints, which provides shielding of the chamber’s internal volume from electromagnetic interference, which allows reliable localization of directional electromagnetic energy within a certain space by blocking its distribution (Fig. . one).

In the section of the upper part of the truncated pyramid, the camera contains a platform (2) for a radiating antenna with a rotation device and the radiating antenna itself (3), in the middle part of the internal volume, the camera contains a window (4), a radio-sealed cover (5), a platform (6) for the studied antennas, the studied antenna (7), measuring equipment, the base of the internal volume of the chamber includes at least two layers of n + 1 wedge-shaped absorbers (8), and the radiating and studied antennas are connected to the measuring equipment outside the camera, through communication lines zi (9).

The platform (2) for a radiating antenna with a rotation device contains a base (13), made in the form of a cover of sheet metal material. In the center of the base (13), by means of fasteners (17) (for example, bolts, screws or rivets), a guide sleeve (15) is fixed in which a rod (16) is inserted for fastening the radiating antenna (3), and the rod (16) retains the possibility free rotation in the guide sleeve (15) (Fig. 2).

The rod (16), on the one hand (top), is rigidly fixed (by welding) with a rotary element (14) in the form of a rotary drum, inserted through the guide sleeve (15), and on the other hand contains a mount for the radiating antenna (dielectric substrate and mounting elements (17).

The outer side of the rotary element (14) contains a scale for dividing the angle of rotation in the horizontal plane. The angle of rotation of the radiating antenna is determined on this scale.

The rod (16) is made hollow, in the form of a tube, inside which is located the connecting cable of the radiating antenna (3).

A small anechoic chamber (1) is connected to the measuring equipment — the measuring generator (18) using communication lines (9) that pass from above the internal volume of the chamber (1) through the rod (16) of the platform (2) for the radiating antenna with a rotation device and in the middle part from the side of the side window (4) into which the studied antenna (7) is inserted (Fig. 3).

A small anechoic chamber (1) from the side of the cut top of the truncated pyramid is connected to a broadband emitting antenna specially designed for working in this design (3). The camera (1) can be mounted on the floor or on the table. Installation of the studied antenna (7) in the chamber (1) is carried out through the window (4) located in the middle of the internal volume of the chamber (1), equipped with a radio-sealed cover (5). The studied antenna (7) is located on the platform (6). made of polyurethane foam, under which there are at least two layers of n + 1 wedge-shaped radio absorbers (8).

Radio absorbers (8) in the form of tetrahedra or pyramids are made on the basis of foamed polymeric materials with graphite chips and have such indicators as low weight, good flexibility, strength, manufacturability, and high absorption coefficient of the electromagnetic field. The layer is formed by joining the bases of the absorbers (8) on any hard surface (for example, a sheet of cardboard or plywood).

Using a measuring generator (18), which is located outside the camera (1), the antenna under study is calibrated (7) and the gain, SWR, and noise figure are measured (Fig. 1).

The radiating antenna (3) generates a signal from the measuring generator (18).

The radiating antenna (3) is mounted on top, in the truncation of the pyramidal chamber (1), with the dimensions of the base B = 120 * 120 mm and the expansion angle Ф = Т5 ... 20 degrees. The radiating antenna (3) is specially designed for operation in MBC and is a design created on a dielectric board (10), in the form of a board (for example, FR4), on which there is a power divider (11), with a simultaneous phase shift between two output ports 180 ° (Fig. 2). Thus, the radiating antenna (3) consists of two symmetric vibrators (12), combined using a power divider (11) (for example, RF Transformer TCN4-22), which simultaneously performs the role of a phase shifter. The dimensions of the two symmetric vibrators (12) were selected in the form of triangles and experimentally calculated so that the antenna (3) has a broadband of 1.5 to 12 GHz according to the SWR criterion of less than 3. The radiating antenna (3) is located on the board (dielectric substrate) with a thickness of 0.5 mm, and on the other side a circuit is sprayed to which a microcircuit is used, acting as a power divider (11) and phase shifter.

The calculations showed that the broadband emitting antenna (3) is greater if the vibrators (12) of the antenna (3) are in free space, and therefore. the dielectric substrate has a circular shape with a diameter of D = 12 mm and a thickness of h = 0.5 mm and is electrically connected to a chip for dividing (11) power and phase shift.

A feature of the radiating antenna (3) is that its phase center is located in the center of the antenna and changes in the frequency range less than for horn, quadrifilar, and other types of antennas, which are suitable for performing similar functions of excitation of waves in anechoic chambers.

In the middle part of the internal volume of a small anechoic chamber there is a platform (6), on which the antenna under study is located (7). The platform (6) is made of polyurethane foam with a dielectric constant ε = 1.02 and rigidity sufficient for reliable retention of the measured passive or active antenna (7). At least two layers of n + 2 radio absorbers (8) are located under the platform (6). The layers of the radar absorbers (8) are arranged in such a way that the absorption coefficient of such a structure would be the largest among the options for composing such layers (Fig. 4). This is due to the fact that in such a structure, the layers most effectively act on reflected waves, which are “divided” into wave types, due to the specific shape of the wedge-shaped absorbers (8). It is important to choose the optimal radar absorber angles (8), as well as the order of laying the radar absorber (8) in the layer. The absorption coefficient of the total layer is maximum when the angle of inclination of the horn of the pyramidal chamber (1) in the base and the bevel angle of each of the n + 1 wedge-shaped radio absorbers (8) are equal.

The main element of this structure is a radar absorbing coating. Such a radar absorbing coating is made of radar absorbing materials made and composed of wedges, which are in the form of a tetrahedral or pyramidal shape of foamed polymer material with graphite chips (Fig. 6). Radio waves, penetrating into such a material, undergo a maximum attenuation coefficient.

The considered small anechoic chamber (1), including at least two layers of n + 1 wedge-shaped absorbers (8) at the base of the internal volume, is a resonator in which two antennas are located. In order for the electromagnetic wave at the receiving point where the studied antenna (7) is located to be as high as possible, it is necessary to match this antenna with a line that is connected to a measuring generator (transmission coefficient measurement generator and / or noise figure measurement generator). The shortest distance between the two antennas will be a straight line. Therefore, it is important to obtain the same signal in the mounting region of the studied antenna (7), for any characteristics of the studied antenna. This can be obtained if the near field along the line has the character of a monotonically decreasing power (Fig. 4). To obtain such a characteristic, it is necessary to choose the optimal absorption structure (Fig. 4.4) located under the plane onto which the antenna under study is mounted (7).

The reason why the near field along the line may not have a monotonously declining character, but may have a character with bursts and dips, is explained by the fact that there may be rereflections in the internal volume of the chamber (1) (horn) (Fig. 8). In each section of the horn there is a condition for the appearance of a standing wave, the form and picture of which depends on the size of this section.

Since the absorbent coating has a complex rugged shape, it would not be accurate to describe such a surface using the dielectric constant ε and conductivity σ as a continuous material. Therefore, a parametric optimization of the specific conductivity σ was performed (Fig. 7) using the HFSS Ansoft electrodynamic modeling program [7], and it was found that at σ = 0.5 Sim / m, the near-field characteristics are most similar to those experimentally obtained for this value, the reflection coefficient from the surface gives a value of -25 dB in a wide frequency range from 0.5 GHz to 12 GHz (Fig. 5). A complex structure of tetrahedral or pyramidal radio absorbers is used as the main absorber of a small anechoic chamber (1).

In the small anechoic chamber (1), the characteristics of the studied antenna (7) are compared with the characteristics of the reference, already measured and tested antenna, the small anechoic chamber (1) is small, and the attenuation coefficient of the signal from one antenna to another is about 10 dB, which much smaller than standard anechoic chambers.

Due to its small size and the presence of a window (4) for the antenna under study (7), it is convenient to use the camera as part of the measurement setup, and install additional devices outside the camera. Measuring communication lines (9) are located outside the small anechoic chamber (1), in contrast to the standard anechoic chamber.

The shape of existing anechoic chambers is usually in the form of a parallelepiped, usually to create such chambers use rooms and parts of the premises, or the whole building. The small-sized chamber proposed by the applicant has the form of a truncated pyramid (in the form of a horn directional emitter), which saves the space of the inner working volume of the chamber during research, and the chamber itself is part of the measuring path.

The antenna under study (7) is installed in a place that coincides with the axis of the truncated pyramid (pyramidal horn), and the base of the internal chamber volume includes at least two layers of n + 1 wedge-shaped absorbers (8). In FIG. 9. dependence 1 shows that in the case of the choice of reflectors, as shown in FIG. 4.4, the sensitivity of the near field to the position of the antenna under test (7) is the smallest, compared with the non-optimized design, the change in the near electromagnetic field in this case is shown by line 2. This is because the horn shape directs waves that are not absorbed, but partially reflected from the absorbing surface at an angle, and directs them further from the point at which the antenna under study is located (7).

This design of the camera has the advantage over a rectangular camera that the points of reflection of rays from the radiating antenna are located only at the bottom of the camera. At the same time, the bottom of the chamber is covered by a layer of radar absorbing material of considerable thickness. This provides a high level of suppression of reflected rays.

In a rectangular chamber, to achieve the same level of suppression of re-reflected rays, it would be necessary to cover the side walls of the absorber with the same layer, which would significantly increase the size of the chamber. FIG. 10 illustrates a comparative signal propagation characteristic in a pyramidal and rectangular chamber.

The choice of anti-directional coating allows to reduce the reflection coefficient (return loss is not worse - 20 dB).

The trapezoid angle is chosen so as to correspond to the divergence of waves from the phase center of the radiating antenna, which leads to a decrease in the interference of secondary reflection waves.

When working with a small anechoic chamber (1), the antenna under investigation (7), along with useful signals from satellites, is affected by various undesirable fields of natural and artificial origin. In addition, the studied antenna (7) is located in the environment, which adds thermal noise. When assessing the noise properties of the antenna path, all sources of fluctuations should be taken into account [8]. They affect such a generalized characteristic as the effective temperature of the antenna, showing the additional noise contribution to the antenna path. Obviously, the effective temperature of the antenna depends on its radiation pattern and heat loss.

On the other hand, measuring generators measure the noise figure, which is the most universal and widespread characteristic for comparing the noise properties of systems and devices. In the noise figure meter at the input of the tested quadripole set calibrated noise generator (noise tube) [9],

Where

- P _W.out - output power when exposed to all factors of the influence of noise,

- P _h.h.vyh - output noise power, determined only by the input noise generator power (with idealization of the antenna under study and in the absence of noise sources in it).

Thus, the proposed small anechoic chamber (1) can be used for testing and research of satellite and navigation antennas [10].

Consider the functioning of the MBC (Fig. 1). A small anechoic chamber (1), a radiating antenna (3), a test antenna (7) and a measuring generator (18) are included in the measuring path when testing and examining the studied antenna (7). The elements of the measuring path are connected via communication lines (9) (cable, waveguide, fiber). The measuring generator (18) is located outside the small anechoic chamber (1).

In the process of testing and research (Fig. 10) from the output of the measuring generator (18) (generator for measuring the transmission coefficient and / or generator for measuring the noise figure), the signal is fed to the input of the emitting antenna (3), the electromagnetic field of which propagates in the internal volume of the chamber (1 ) in the direction of the antenna under study (7), the signal from which is fed to the input of the measuring generator (18).

The waves reflected from the absorbing surface, incident on the oblique walls of the small anechoic chamber (1), are reflected so that they are removed from the antenna under study (7) (Fig. 9). The studied antenna (7) can be moved in two coordinates to make sure that the measured characteristics vary within no more than 2%.

By adjusting the emitting antenna (3) in the neck of the chamber (1), the signal at the output of the studied antenna (7) is increased to a maximum value.

The measured characteristics of the measuring path are compared with the characteristics of the reference antenna.

The reference is an antenna that has been successfully tested in the actual design of a radio system. If the measured characteristics of the measuring generator (18) of the reference and test antennas do not differ by more than 2%, then the test antenna (7) is recognized as fit for use in the actual design of the radio system.

Testing operations of the measuring path are carried out in accordance with the Instructions for the operation of an automated noise figure meter [11].

In FIG. Figure 11 shows a photograph of a small anechoic chamber designed and manufactured at the Compass ICD. The height of this chamber is 2 m, the height of the absorber layer is 0.5 m.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed utility model:

The tool embodying the claimed utility model in its implementation is intended for use in industry, namely in the radio industry for measuring characteristics, testing and research of satellite antennas and navigation antennas.

For the claimed device in the form described in the independent clause of the stated utility model formula, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed.

The tool embodying the claimed utility model in its implementation is capable of achieving the achievement of the technical result perceived by the applicant.

Sources of literature:

1. Application for the invention of Japan No. JP 20090260603 from 02/02/2011;

2. RF patent for the invention 2447551 from 04/10/2012;

3. USSR inventions SU 1478935 dated 06/23/1987;

4. USSR author's certificate for the invention of SU 1510647 of 06/27/2000;

5. RF patent for the invention No. 2346365 from 10.24.2007;

6. RF patent for utility model No. 5037 of September 16, 1997;

7. “Design and optimization of microwave structures using HFSS Ansoft”, Banks S.E., Kurushin A.A., M., Solon-Press, 2005, 240 s;

8. “Antenna measurements”, Kummer V.Kh., Gillespie E.S., TIIER. 1978, v. 66, No. 4. from. 143-173 .;

9. “Guillermo Gonzales. Microwave Transistor Amplifiers. Analysis and Design ”, 1997, p. 506 .;

10. "Anechoic chambers of the microwave", Mirtsmakher M.Yu., Torganov VA, M .: Radio and communications, 1982. - 128 s;

11. “Instruction manual for an automated noise figure meter”, CJSC NPF Mikran Tomsk, ul. Vershinina, d. 47.

Claims (5)

1. A small anechoic chamber containing a platform for the antenna under study inside the chamber, a radiating antenna in the upper part, and a window is made on the side wall, characterized in that the small anechoic chamber is made in the form of a truncated pyramid (1) from a single integral structure, in the internal volume on top, the camera includes a platform (2) for a radiating antenna with a rotation device and the radiating antenna itself (3), in the middle part of the internal volume, the camera contains a window (4), a radio-tight cover (5), a platform (6) for exploring the first antenna, the antenna under study (7), measuring equipment, the base of the internal chamber volume includes at least two layers of n + 1 wedge-shaped absorbers (8), and the radiating and studied antennas are connected to the measuring equipment outside the camera via communication lines (9 ) 2. A small anechoic chamber according to claim 1, characterized in that the radiating antenna is made on a dielectric board (10) and contains a power divider (11) and two symmetric vibrators (12). 3. A small anechoic chamber according to claim 1, characterized in that the platform (2) for the radiating antenna with the rotation device comprises a base (13), a rotary element (14), a guide sleeve (15), a rod (16) for attaching the radiating antenna and fastening elements (17), and the rotary element (15) is made in the form of a rotary drum, the outer side of which contains a scale for dividing the angle of rotation in the horizontal plane. 4. A small anechoic chamber according to claim 1, characterized in that the platform (6) for the antenna under study is made of polyurethane foam. 5. A small anechoic chamber according to claim 1, characterized in that the wedge-shaped radar absorbers (8) are made of a tetrahedral or pyramidal shape made of foamed polymeric material with graphite chips, the angle of inclination of the side walls of the chamber at the base and the bevel angles of each of n + 1 wedge-shaped radiator (8) are chosen equal.