SU1256115A1 - Cassegrainian multirange aerial - Google Patents

Abstract

The invention relates to antenna technology. The aim of the invention is to expand the operating range by enabling operation in the third frequency range. The antenna contains the main parabolic mirror 1, the auxiliary elliptical mirror 2, the irradiators 3,4 and 5 of the first, second and third ranges, respectively, as well as the exciting elements (EE) 6. In the first (mid-frequency) range, the irradiator 3 emits electromagnetic waves, which the mirror 2 are reflected on mirror 1 forming a flat phase front in the aperture. The work is carried out according to a two-mirror scheme. In the second (high-frequency) range, mirror 1 is used. And the irradiator 4, made in the form of a horn, the throat of which is formed by a waveguide section, and the side walls - the surface of mirror 2. The work is carried out according to a single-mirror design. In the third (low-frequency) range, the function of the irradiator 5 performs an annular aperture formed by the surface of mirror 2 and an elliptical surface that is confused by it, which are galvanically connected by a waveguide segment. In this case, an electromagnetized field in an annular aperture is excited by means of a VE 6 (pin), whose location is determined by the conditions of excitation of the required types of waves in a radial elliptical waveguide. The work is carried out in a single-mirror design. The goal is achieved by the introduction of the irradiator 5. 1 Il. with 9 (L J.. p

Description

The invention relates to antenna technology and can be used in mobile and stationary radio engineering systems for various purposes.

The purpose of the invention is to expand the operating range by enabling operation in the third frequency range.

The drawing shows a structural diagram of a two-mirror multiband antenna.

A two-mirror multiband antenna contains a main parabolic mirror 1, an auxiliary elliptical mirror 2, an irradiator 3 of the first range, an irradiator 4 of the second range, an irradiator 5 reconstructed, a surface of an auxiliary elliptical mirror 2 and an additional elliptic surface that is confused to it and connected by a waveguide electroplated. In this case, the electromagnetic field in the annular aperture is excited by means of excitation elements 6 (pins), whose location is determined by the conditions of excitation of the required types of waves in a radial elliptical waveguide. The work is carried out according to a single-mirror scheme.

Claims (1)

15 Formula invention A two-mirror multirange antenna containing a main parabolic mirror, an auxiliary elliptical mirror, an irradiator ten - go -, the upper range, the phase center of the auxiliary elliptic mirror 2 and an additional elliptic surface, additionally confused to it, located behind the surface of the auxiliary elliptical mirror 2 and galvanically connected with it, as well as exciting elements 6. Two-mirror multi-band antenna works as follows. In the first (middle) frequency range, the first-band irradiator 3 emits electromagnetic waves that are re-reflected by the auxiliary elliptical mirror 2 onto the main parabolic mirror 1, which forms a flat phase front in the aperture (i.e., a two-mirror scheme is performed). In the second (high-frequency) range, an irradiator 4 of the second range is used, made in the form of a horn, whose throat is formed by a waveguide section, and the side walls - the surface of an auxiliary elliptical mirror 2, and the main parabolic mirror 1, and performed a single-mirror design. Secondly combined with the first focus of the auxiliary elliptical mirror located near the top of the main parabolic mirror, the second-range irradiator made in the form of a horn, whose phase center is aligned with the second focus of the auxiliary elliptical mirror and the focus of the main parabolic mirror, and the surface of the auxiliary elliptical mirror is its side in order to extend the working range by providing the possibility of working in the third In the case of frequencies, a third-range irradiator formed by the surface of an auxiliary elliptical mirror and an additional elliptic surface confocalized to it, located behind the surface of the auxiliary elliptical mirror and galvanically connected with it, is inserted into it, while in the annular gap between the surface of the auxiliary elliptical mirror and its electrofocal mirror. excitatory elements are installed, and In the additionally introduced third (low-frequency) range, the role of an oblique beam of the ring of the gap of the third range performs the same as the plane of the secondary ring gap (ring gap) of the powerful elliptical mirror. VNIIPI Order 4832/53 Circulation 597 Subscription Proizv.-poly. p r-gie, Uzhgorod, st. Project, 4 formed by the surface of the auxiliary elliptical mirror 2 and additionally introduced to it by the elliptical surface confocal, connected galvanically by a waveguide segment. In this case, the electromagnetic field in the annular aperture is excited by means of excitation elements 6 (pins), whose location is determined by the conditions of excitation of the required types of waves in a radial elliptical waveguide. The work is carried out according to a single-mirror scheme. 15 Formula invention A two-mirror multirange antenna containing a main parabolic mirror, an auxiliary elliptical mirror, an irradiator go -, five 0 five five 0 Secondly combined with the first focus of the auxiliary elliptical mirror located near the top of the main parabolic mirror, the second-range irradiator made in the form of a horn, whose phase center is aligned with the second focus of the auxiliary elliptical mirror and the focus of the main parabolic mirror, and the surface of the auxiliary elliptical mirror is its side in order to extend the working range by providing the possibility of working in the third In the case of frequencies, a third-range irradiator formed by the surface of an auxiliary elliptical mirror and an additional elliptic surface confocalized to it, located behind the surface of the auxiliary elliptical mirror and galvanically connected with it, is inserted into it, while in the annular gap between the surface of the auxiliary elliptical mirror and its electrofocal mirror. excitatory elements are installed, and 0, the aperture plane of the annular gap coincides with the aperture plane of the auxiliary elliptical mirror.