JPH04200104A - Helical feed horn - Google Patents

Abstract

PURPOSE:To make an axial ratio broad, to make the size small and to facilitate assembly by providing a tapered feed horn section whose opening has a maximum diameter to the feed horn, providing a helical element in the horn and connecting the helical element to a microstrip line on a board. CONSTITUTION:An outer appearance of a helical feed horn 10 is cylindrical and a circular opening 18 one side of which is opened is formed, the diameter is decreased from the opening toward the inside and the depth has a conical truncated horn 22 having a reflecting face 20. A helical element 20 is arranged along a center axis line of the horn 22. A focus 27 of an offset parabolic reflecting mirror 12 is placed between the opening 18 and a tip of the helical element 26 toward the opening 18. A high frequency board 28 is provided to a rear side of the reflecting face in face contact thereto. Thus, since the helical element is provided in the horn, the total length of the helical feed horn is decreased and the size is made small.

Description

[Detailed description of the invention] [Field of application in industry] The present invention relates to a feed horn used with a parabolic antenna (including an offset parabolic antenna).
In particular, the present invention relates to a circularly polarized wave-to-linearly polarized wave conversion element, and one using a helical element.

[Prior Art] Conventionally, a -order radiator has a feed horn and a circular waveguide section provided at the rear of the feed horn, and a circularly polarized wave-to-linearly polarized wave conversion element is installed in the circular waveguide section. As, for phase shift: A? t
It is known that a T-body substrate, a metal plate, screws, etc. are provided, and an absorption resistance plate is further provided.

[Problem to be solved by the invention] However, the above-mentioned primary radiator is a circular waveguide in which a circularly polarized wave-to-linearly polarized wave conversion element and an absorption resistor plate are provided in a circular waveguide. There is a problem in that the length of the tube becomes longer, and the length of the entire -order radiator also becomes longer. There are also primary radiators using microstrip patch antennas, etc., but these secondary radiators have problems such as being small or having narrow electrical characteristics, especially the axial ratio band.

An object of the present invention is to provide a helical feed horn that solves the above problems.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a tapered feed horn portion having a maximum diameter at an opening and decreasing in diameter from the opening toward the inside. and a helical element provided within the horn portion along its axis.

Alternatively, a substrate comprising an amplifying section may be provided at the back of the feed horn section, and a helical element may be connected to a microstrip line on this substrate.

Furthermore, the helical feed horn described above is disposed between the opening of the horn portion and the tip of the helical element so that the focal point of the parabolic reflector is located on the axis of the horn portion. It comes.

It is also possible to provide a circular waveguide extending from the innermost part of the horn section.

[Function] According to the present invention, the circularly polarized radio waves arriving at the horn part are
It is converted into linear polarization by a helical element. and,
When a substrate on which an amplification section is formed is provided at the back of the feed horn section, the converted linearly polarized wave is supplied to the microstrip line on this substrate. Furthermore, if the focal point of the parabolic reflector is located between the opening of the horn section and the tip of the helical element and on the axis of the horn section, circularly polarized waves can be efficiently converted into straight lines. Polarization conversion is also performed.

[Example] A first example is shown in FIGS. 1 and 2. The helical feed horn 10 of this embodiment, as shown in FIG.
A low noise block converter 14 is provided at the rear of the helical feed horn 10, which is located near the focal point of the offset parabolic reflector 12.

This hesocal feed horn 10 has a cylindrical appearance as shown in FIG. It has a truncated conical horn part 22 whose innermost part is a reflective surface 20. Further, a feed dome 24 is connected to the opening 18 .

A helical element 26 is provided within the horn portion 22. This helical element 26 is arranged on and along the central axis of the horn section 22. Between the tip of the helical element 26 on the opening 18 side and the opening 18,
A focal point 27 of the offset parabolic reflector 12 is located.

A high frequency substrate 28 is provided on the back side of the reflective surface in surface contact with the reflective surface. On this board, there is a high frequency amplification section 30 that forms part of the low noise block converter 14.
is configured, and its input side microstrip line (
(not shown), a helical element 26 passing through the reflective surface 20
connected to the proximal end of the

Note that the diameter A of the opening 18 of the horn section 22 is, for example, one wavelength or more of the receiving frequency, the diameter B of the reflective surface 20 is, for example, less than l, and the diameter of the helical element 26 is,
For example, input/4, number of turns n is 5 to 10, pitch S
For example, the wire diameter is 1 to 3 mm, and the wire diameter is 0.6 to 1.2 m.
Let it be m.

In the helical feed horn 10 configured in this way, the circularly polarized radio waves reflected by the offset parabolic reflector 12 are collected at the focal point 27 and supplied from there to the helical element 26, where the circularly polarized radio waves are or converted into linearly polarized radio waves. Then, it is amplified by the amplifying section 28.

FIG. 3 shows a second embodiment. In this embodiment, a short circular waveguide section 32 having the same diameter as the minimum diameter section is provided following the minimum diameter section of the horn section 22. The bond end face of this circular waveguide portion 32 is a reflective surface 32a, and the helical element 26 passes through this reflective surface and is connected to the microstrip line on the substrate 28. The rest of the structure is the same as in the first embodiment, so the same parts are given the same reference numerals and the explanation thereof will be omitted.

[Effects of the Invention] As described above, according to the present invention, since the helical element is provided within the horn portion, the overall length of the helical feed horn can be shortened, and miniaturization can be achieved. Moreover, since the helical element is used to convert circularly polarized waves to linearly polarized waves, it is possible to achieve a wide range of axial ratios. Also, I! Since the helical element is directly connected to the microstrip line of the board, which is made up of all 11 sections, there is no need for a waveguide section to transmit linearly polarized waves converted from circularly polarized waves, making it a low-noise flock converter. Not only can it be made smaller, but it can also be easily assembled and adjusted.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view of a first embodiment of a feed horn according to the present invention, FIG. 2 is a side view of an offset parabolic antenna using the feed horn of the first embodiment, and FIG. FIG. 2 is a vertical cross-sectional view of the second embodiment. 22... Horn part, 26... Helical element, 2
7... Focus position t, 32... Waveguide section. Patent applicant DAYX Antenna Co., Ltd. Agent
Person Tetsu Shimizu 2 people 1 person

Claims (4)

[Claims] (1) A tapered feed horn portion whose opening has a maximum diameter and whose diameter decreases from the opening toward the inside, and a helical element provided inside this horn portion along its axis, Equipped with a helical feed horn. (2) The helical feed horn according to claim 1, wherein a substrate provided with an amplifying section is provided on the back of the feed horn section, and the helical element is connected to a microstrip line on the substrate. (3) The helical feed horn according to claim 1 or 2 is provided with a parabolic reflector located between the opening of the horn portion and the tip of the helical element, and at a position on the axis of the horn portion. A helical feed horn characterized by being arranged so that the focal point of the horn is located. (4) The helical feed horn according to claim 1, 2 or 3, further comprising a circular waveguide extending from the innermost part of the horn portion.