JPS6033614Y2 - horn reflector antenna - Google Patents

Description

[Detailed Description of the Invention] This invention relates to a horn reflector antenna in which a horn portion is provided with a step or an iris.

In general, horn reflector antennas have the characteristic of emitting less radiation in wide-angle directions, so conical ones in particular are often used as the primary radiator of Cassegrain antennas by taking advantage of this characteristic.

However, in conventional horn reflector antennas, the electromagnetic field distribution is different between the E-plane and the H-plane, so the beam width of the electromagnetic waves radiated is different between the E-plane and the H-plane. Cassegrain antennas that use the primary radiator have their own limits to improving the aperture efficiency.

This invention eliminates such conventional drawbacks and can be applied both in the E plane and in the H plane.
The aim is to increase the aperture efficiency of the Cassegrain antenna by making the in-plane beam widths approximately equal.

This will be explained in detail below using figures.

The figure shows a horn reflector antenna that is an embodiment of this invention, where 1 is a conical horn, 2 is a parabolic reflector of revolution, 3 is a shield member, and 4a and 4b are conical horns. This is a step installed on the inner wall of the building that generates higher-order state waves.

By the way, the phase amount Φ1. which changes while the higher-order shape wave TM generated at the step 4a and the fundamental shape wave TE□1° progresses to the step 4b. Φ2 is the diameter of the inner wall at the steps 4a and 4b, respectively.

If D2 and the length between the steps 4a and 4b are L, the following equation can be used.

Φ1 = April (ρ meditation ■N・ (D2 D,) y, ), ” 1
+5in-t (ship n()-?rD2 k, λ -1-sin-"(U)) πD1 ... (1) Φ2 ""(7"-1+5in-' (Hawa() -~
σW Desperation 2 (D2 Di) ko entry
πD2 ko-in-1-5in-”
(No good)) πD1...(2) Here, kx = 3.8317° ko = 1.841° Input: Wavelength.

Therefore, TE□□ at the step 4b.

mode TM11゜ The mode phase difference φ is given by the following equation.

φ=Φ2 −Φ1 ...(3) Approximately what is this phase difference φ? By selecting r/2 radians or π radians, the TE11' mode and TM□□ are established at the aperture surface of the horn 1.

mode can be made in phase.

Like this, TE1□.

By combining the mode and the TM□1'' mode, the electric field distribution on the aperture plane has the same shape in the E plane as in the H plane.

Therefore, the radiation pattern in the E plane is also the same as that in the H plane.

Although the above description has been made with respect to a conical horn reflector antenna, the present invention is not limited to this and can of course be applied to a pyramidal horn reflector antenna.

Further, in the above embodiment, a step is provided on the inner wall to generate a high-order state wave, but it is also possible to create a structure by providing an iris on the inner wall.

Since this invention is constructed as described above, it is possible to obtain a horn reflector antenna having the same beam width in the E plane and the H plane with a simple structure.

[Brief explanation of the drawing]

The figure is a schematic configuration diagram of a horn reflector antenna showing an embodiment of this invention, in which 1 is a horn, 2 is a paraboloid of revolution reflector, 3 is a shield member, and 4a. 4b is a step. In the drawings, the same or corresponding parts are designated by the same reference numerals.

Claims (1)

[Scope of utility model registration request] In a horn reflector antenna having a horn, a rotating parabolic reflector, and a shielding member, a step or iris for generating higher-order state waves is provided on the wall surface of the radio wave path of the horn, and the fundamental state wave is generated at the aperture surface of the horn. A horn reflector characterized in that the phase difference between the higher-order state waves generated at the step or the iris is selected to be W/2 or π radian, and the fundamental state waves and the higher-order state waves are combined. antenna.