SU1401537A1 - Double-mirror axially symmetrical aerial - Google Patents

Abstract

The invention relates to antenna technology. The purpose of the invention is to reduce the level of side lobes. The antenna contains the primary mirror 1, the emitter 2 spherich. waves (WIS) and auxiliary mirror (VZ) 3. Mirror 1 is formed by rotating around the axis of symmetry 00 an antenna of a parabola segment, the focal axis of which is T, O is shifted parallel to axis 00 with located on it WIS 2. VZ 3 is formed by rotating around axis 00 a segment of an ellipse, one focus of which coincides with the focus of the parabola forming mirror 1, at point 0, and the other with the phase center of the WIS 2 at point 0. A beam of rays radiating from the phase center O of the ISF 2 is reflected from the OT 3. each of the reflected rays passes through the focus of the corresponding ellipse a and is directed to that part 03 1 which is located on the other side of the axis of symmetry 00. After reflection from the mirror 1, the beam of rays becomes parallel. Depending on the magnitude of the displacement of the axis T, O, relative to the axis 00 and the angle at the apex of the cone of the OG 3, the level of irradiation of the edge and the center of the mirror 1 varies. the irradiation level of the edge of mirror 1 is reduced, i.e. reduction of side, petals. 1 il. (L SP 00 p1

Description

The invention relates to antenna technology and can be used in radio links.

The aim of the invention is to reduce the level of side lobes.

The drawing shows the mutual arrangement of the elements of a two-mirror axisymmetric antenna and the path of the rays,

The two-mirror axisymmetric antenna contains the primary mirror 1, the emitter 2 of the spherical wave and the auxiliary mirror 3.

Main mirror 1 is formed by 15 side-petal levels,

by rotating around the axis of symmetry 00 of a two-mirror axisymmetric antenna of the parabola segment, the focal axis of the center of TiO is shifted parallel to the axis of 00 with the emitter 20 of spherical wave located on it. The auxiliary mirror 3 is formed by rotating around the axis 00 of the segment of the ellipse, one focus of which coincides with the focus of the parabola, which forms the main mirror antenna of the segments confocal 1 at point 0, and the second with. phase - parabolas with parallel shifted

center of the radiator of 2 spherical axis of symmetry by the focal axis and wavelocks at the O.Lips point, the second focus of which is combined

The two-mirror axisymmetric curvature is with the phase center of the emitter. Tenna works as follows. A spherical wave differs in a beam of rays that diverges from a phase phase so that, in order to lower the center O of the emitter, 2 spherical side lobes are cut off from the auxiliary confocal parabolas. and an elliptical mirror 3, then they are scanned on different sides of the symmetric axis

the reflected rays pass through the focal points, and the auxiliary mirror has an appropriate ellipse and directs the shape of the cone with the base facing from that part of the primary mirror 1 towards the main zeokal

which is located on the other side of the axis of symmetry 00. After reflection from the main mirror 1, the beam of rays becomes parallel. Depending on the amount of displacement of the focal axis of the primary mirror 1 relative to the axis of symmetry 00 and the angle at the apex of the cone of the auxiliary mirror 3, the level of irradiation of the edge and center of the primary mirror 1 is reduced. Thus, the level of irradiation of the edge of the primary mirror 1, i.e. . decline

Claims (1)

Invention Formula A two-mirror-axisymmetric antenna containing a spherical wave emitter, the main and auxiliary mirrors, whose surfaces are formed by rotating around the axis of symmetry of a two-mirror axisymmetry which is located on the other side of the axis of symmetry 00. After reflection from the main mirror 1, the beam of rays becomes parallel. Depending on the amount of displacement of the focal axis of the primary mirror 1 relative to the axis of symmetry 00 and the angle at the apex of the cone of the auxiliary mirror 3, the level of irradiation of the edge and center of the primary mirror 1 is reduced. Thus, the level of irradiation of the edge of the primary mirror 1, i.e. decline  antenna antenna segments of the confocal parabola with offset parallel Invention Formula A two-mirror-axisymmetric antenna containing a spherical wave emitter, the main and auxiliary mirrors, whose surfaces are formed by rotating around the axis of symmetry of a two-mirror axisymmetry