RU68786U1 - SPHERICAL MIRROR ANTENNA - Google Patents

Abstract

The utility model relates to the field of antenna technology. The spherical mirror antenna contains a hemispherical mirror (1), a horn feed (2) and an additional feed (3). A horn feed is installed in the vicinity of the paraxial focus of the hemispherical mirror. The additional irradiator consists of two rectangular waveguides with open ends (3), curved in opposite directions in the plane of the vector E so that their wide walls are in constant contact with the concave surface of the mirror (1). The outputs of the waveguides (3) through phase shifters (4), (5) and attenuators (6), (7) are connected on the E-tee (8). The output of the horn feed (2) through the phase shifter (9) and the attenuator (10) is connected to the output of the E-tee (8) on the waveguide H-tee (11). The noise immunity of radar stations is increased. 1 n.a.s. f-ly, 5 ill.

Description

The utility model relates to the field of antenna technology and can be used as a mirror antenna with a low level of side lobes of the radiation pattern, which increases the noise immunity of the radar station.

Known spherical mirror antenna (Tingye Li. A Study of Spherical Reflectors as Wide-Angle Scanning Antennas // IRE Trans. On Antennas and Propagation, July 1959, pp223-226), consisting of a hemispherical reflector with a diameter of 304.8 cm and a horn illuminator, an antenna that excites a hole with a diameter of 78.7 cm. The irradiator is a rectangular horn with an aperture size of 3.9 × 3.9 cm ^2, has a beam pattern of 76 ° wide and a level of side lobes of no more than -25 dB, located in the vicinity of the paraxial focus of the mirror on the focal a distance of 74.9 cm from the top of the mirror. At a wavelength of 2.7 cm, a spherical reflector antenna has a beam width in two mutually perpendicular planes of 1.76 ° at a side lobe level of not more than -20 dB and a gain of 39.4 dB.

The main disadvantage of this antenna is the high level of the side lobes of the radiation pattern, i.e. low noise immunity of the radar station.

Known spherical mirror antenna, selected as the closest analogue (A. C. Schell. The Diffraction Theory of Large-Aperture Spherical Reflector Antennas // IEEE Trans. On Antennas and Propagation, July 1963, pp428-432), consisting of a hemispherical mirror with a diameter of 609.6 cm and a combined feed. The combined irradiator consists of a rectangular horn located in the vicinity

paraxial focus at a distance from the aperture of 0.513 · a (a is the radius of the mirror), the first antenna array, whose phase center is at 0.542 · a, and the second antenna array, whose phase center is at 0.575 · a. The aperture region excited by the combined one has a diameter of 304.8 cm. At a wavelength of 3.2 cm, the efficiency of using a hemispherical aperture is 54% when the level of the side lobes of the antenna in the H - plane is no more than -25 dB. Two phase shifters are used to control the phase relationships between the horn feed and antenna arrays.

The main disadvantage of the antenna is the high level of the side lobes of the radiation pattern, therefore, the low noise immunity of the radar station.

The utility model is aimed at increasing the noise immunity of a radar station by reducing the level of the side lobes of the directivity pattern of a spherical mirror antenna.

To solve the problem in the well-known spherical mirror antenna, consisting of a hemispherical mirror and a horn feed located in the vicinity of the paraxial focus of the mirror, the antenna is equipped with an additional feed in the form of two rectangular waveguides with open ends, curved in opposite directions in the plane of the vector E, and their wide the walls are in constant contact with the concave surface of the mirror. The outputs of the waveguides through phase shifters and attenuators are connected to the E-tee, and the output of the horn feed through the phase shifter and attenuators is connected to the output of the E-tee on the waveguide H-tee.

Traditional methods for solving diffraction problems on an ideally conducting hemispherical surface consider one focus area of the field incident on the opening - the focal spot in the vicinity of the paraxial focus. Such methods include: the method of beam and geometric optics, the method of the geometric theory of diffraction,

explanatory phenomena of field focusing at large values of the electric radius of the mirror. An effective tool for solving diffraction problems is the method of integral equations with its modifications - the method of moments, non-orthogonal series, singular integral equations, etc. However, when reducing the integral equation relative to the current excited on the surface of the scattering body to the system of integral equations, the dimension of the system increases sharply for large values of the electric radius, which leads to a large amount of computational procedures and loss of physical interpretation of the results.

At the same time, it is known that diffraction by concave bodies of revolution gives a number of effects that have not yet been widely used to improve the electrical characteristics of spherical mirror antennas. Such physical phenomena are multiple reflections, the effect of the “whispering gallery”, which are clearly manifested when the field source is located near the concave wall of the mirror.

Solution of Maxwell's equations in a spherical coordinate system using the Fourier method using a group of rotations (Ponomarev O.P. Solution of Maxwell's equations in a spherical coordinate system using a group of rotations. Application for spherical mirror antennas // Radio Engineering, 2006, No. 4, p.77-78 ) allows you to get the amplitude-phase distribution of the electric field along the axis of the ideally conducting hemisphere of arbitrary electric radius for a given amplitude-phase distribution of the field in the aperture. At the same time, on the axis of the reflector there are two clearly expressed maxima of energy focusing. The first maximum is in the vicinity of the paraxial focus, due to the focusing of single reflection rays from the central region of the mirror and has an extended form.

Ray focusing in this area has been well studied and is used to correct spherical aberration. The second interference maximum has a smaller extent and characterizes the focusing properties of the edge regions of the aperture of the hemisphere, where the rays experience multiple reflections and the effect of the “whispering gallery” wave is affected.

The graphic materials attached to the application depict:

figure 1 - the proposed spherical mirror antenna with a combined feed;

figure 2 is a normalized radiation pattern of the proposed spherical reflector antenna;

figure 3 - voltage distribution recorded by the spectrum analyzer at points of a fixed position of the measuring probe along the axis of the hemispherical mirror;

figure 4 - spherical mirror antenna with a horn feed (analogue);

figure 5 - spherical mirror antenna with a combined feed (the closest analogue).

The following notations are used on graphic materials:

1 - hemispherical mirror;

2 - horn irradiator;

3 - additional irradiator;

4, 5, 9 - waveguide phase shifters;

6, 7, 10 — waveguide attenuators;

8 - waveguide E-tee;

11 - waveguide H-tee;

12 is a normalized radiation pattern of the proposed spherical mirror antenna excited by a combined irradiator;

13 is a normalized radiation pattern of the proposed spherical reflector antenna excited by the irradiator in the form of the open end of a rectangular waveguide;

14 - distribution of the radial component of the electric field E _r along the axis of a hemispherical mirror with a radius of 22.5 cm at a wavelength of 3.14 cm with a uniform amplitude field distribution in the aperture;

15 - distribution of the radial component of the electric field E _r along the axis of a hemispherical mirror with a radius of 22.5 cm at a wavelength of 3.14 cm with a falling Taylor (first type) amplitude field distribution in the aperture;

16 is the distribution of the radial component of the electric field E _r along the axis of a hemispherical mirror with a radius of 22.5 cm at a wavelength of 3.14 cm with a decreasing Taylor (2 types) amplitude field distribution in the aperture.

An analysis of the amplitude-phase field distributions along the axis of an ideally conducting hemisphere 14, 15, 16 shows the possibility of exciting the opening of a hemispherical mirror by a combined irradiator consisting of a main one located in the first maximum in the vicinity of the paraxial focus and an additional one located in the second interference maximum and exciting edge regions openings. The introduction of an additional irradiator allows to reduce the level of the side lobes of the radiation pattern and increase the noise immunity of the radar station.

The proposed spherical reflector antenna consists of a hemispherical reflector 1, a horn feed 2 and an additional feed 3. The additional feed is two rectangular waveguides, for example, type IEC-100 with open ends, curved in the plane of the vector E in

opposite sides and their wide walls are in constant contact with the concave surface of the mirror. The open ends of the waveguides 3 are located symmetrically to the axis of symmetry of the mirror. The outputs of the waveguides through the phase shifters 4, 5, attenuators 6, 7 are connected to the E-tee 8, the output of the horn feed through the phase shifter 9 and the attenuator 10 is connected to the output of the E-tee 8 on the waveguide H-tee 11.

Spherical reflex antenna works as follows. Electromagnetic waves reflected from the central region of the mirror 1 are received by the horn irradiator 2. Electromagnetic waves reflected from the edge regions of the mirror 1 are received by the open ends of the rectangular waveguides 3. The signals from the outputs of the rectangular waveguides of the additional irradiator pass through phase shifters 4, 5, attenuators 6, 7 , on which the phase and amplitude of the signals are regulated, and are summed on the waveguide E-tee 8. The signal from the output of the horn feed 2 goes to the phase shifter 9, then to the attenuator 10, on which regulated phase and the amplitude of the signal. From the output of the attenuator 10, the signal is summed with the signal from the output of the E-tee 8 on the H-tee 11. The phases of the signals of the additional irradiator 3 at the output of the phase shifters 4, 5 and the phase of the signal at the output of the phase shifter 9 are adjusted so that the main lobes of the antenna pattern excited additional irradiator, were in antiphase with the first side lobe of the antenna pattern excited by the horn irradiator 2. The amplitudes of the signals of the additional irradiator 3 at the output of the attenuators 6, 7 and the amplitude Igna at the output of the attenuator 10 are adjusted so that the level of the main lobe of the antenna excited additional irradiator 3 was equal to that of the first side lobe antenna pattern, the excited feedhorn 2. This achieves a reduction in the side lobe level spherical reflector antenna.

On the experimental setup, due to the choice of amplitude and phase relations between the main and additional waveguide-type irradiators, a normalized radiation pattern of 12 spherical antennas is obtained (β is the angle of rotation of the antenna in the horizontal plane) with the level of the side lobes not higher than -36 dB. The diameter of the aperture of the mirror is 30 cm. The opening of the antenna was irradiated at a wavelength of 3.0 cm from the far zone with a horizontally polarized field.

Thus, by reducing the level of the side lobes of the radiation pattern, the noise immunity of the radar station is increased.

Claims (1)

A spherical mirror antenna, consisting of a hemispherical mirror and a horn feed, located in the vicinity of the paraxial focus of the mirror, characterized in that the antenna is equipped with an additional feed in the form of two rectangular waveguides with open ends, curved in opposite directions in the plane of the vector E, and their wide walls are in constant contact with the concave surface of the mirror, in addition, the outputs of the waveguides through phase shifters and attenuators are connected on the E-tee, and the output of the horn region ents through the phase shifter and an attenuator connected to the output on the E-tee waveguide H-tee.