KR960004352Y1 - Polarization converting device without feed horn - Google Patents

Abstract

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Description

Satellite Broadcast Signal Polarization Converter

1 is a schematic diagram of an LNB including a feed horn for a conventional polarization conversion.

2 is a structural diagram of a feed horn provided in front of a conventional LNB.

3 is an incident waveform and reflection waveform diagram for explaining the installation position of a probe in a conventional LNB square waveguide.

4 is a front view of the present invention LNB waveguide.

5 is a side cross-sectional view of the inventive LNB waveguide.

6 is an explanatory diagram of the structure of the probe of the present invention.

* Explanation of symbols for main parts of the drawings

20: LNB 22: circular waveguide

24: double probe

The present invention relates to an LNB for receiving BS broadcasts, and in particular, a satellite that directly converts a circular polarization into a linear polarization in an LNB library without a separate feed horn for converting a satellite broadcast signal received as a circular polarization into a linear polarization. A broadcast signal polarization converter.

Conventional polarization receivers for processing satellite broadcast signals received by circular polarization, as shown in Figure 1 by installing a feed horn 12 in front of the rectangular (square) waveguide of the LNB (10) parabolic antenna ( The circularly polarized wave received at 14) is converted into linearly polarized wave in the feed horn 12, and the linearly polarized wave is vertically incident on the rectangular waveguide of the LNB ₁₀ in TM ₁₀ mode to use a standing wave generated on the waveguide wall. It is pulled through the probe to the strip line of the DeFron PCB.

In this case, the feed horn 12 provided at the front end of the LNB 10 is formed by inserting the dielectric 18 into the cylindrical metal body 16 at 45 degrees or 135 degrees, as shown in FIG. The reception source polarizations of two linearly polarized waves having a phase difference are converted into in-phase with each other, thereby making them again linearly polarized. In addition, the reason for converting the circularly polarized wave is that when transmitting satellite broadcast signal, the transmitting side transmits two linearly polarized waves having the same amplitude at 90 degrees out of phase and converts them into circularly polarized waves. This is because it must be converted to polarization and processed.

On the other hand, the signal converted into linearly polarized light in the feed horn 12 is input to the rectangular waveguide 11 of the LNB 10, which is incident on the rectangular waveguide 11 of the LNB 10 as shown in FIG. The reflected wave by the incident wave is generated by the waveguide wall surface. Since the reflected wave (standing wave) has a maximum value at the λ / 4 position, the probe 13 is installed at this point A to take the signal out to the microstrip line of the depron PCV 15.

As can be seen here, although the feed horn 12 has a simple function of converting a circularly polarized signal into a linearly polarized signal, the feed horn 12 is made of a metal material itself, so that the satellite broadcasting receiving system is connected to an ODU (Out Door Unit). Since the increase in size and weight is accompanied by the problem that a severe load burden is given to their installed parabolic antenna (14).

The present invention provides an ultra-small LNB corresponding to the miniaturization of a parabolic antenna for satellite broadcasting reception.

This invention is achieved by removing the feed horn installed at the LNB front end and modifying the waveguide structure and the probe of the LNB.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 4 and 5, the waveguide of the LNB 20 is formed as a circular waveguide 22, and the λ / 4 point in the circular waveguide 22 is λ / 2 length and λ / 4 length. The double probe 24 is installed, and the common lead of the double probe 24 is connected to a microstrip line on the depron PCB.

The operation and effects of the present invention configured as described above will be described.

Referring to FIGS. 4 to 6, the circularly polarized wave input from the parabolic antenna enters the circular waveguide 22 of the LNB 20 to generate the reflected wave. Where electric field of reflected wave Since a double probe 24 formed of two pairs of lambda / 2 length and lambda / 4 length, respectively, is provided at the point A (λ / 4) where is the maximum, an input polarization phase difference of 90 degrees occurs.

Therefore, the circularly polarized wave input with the 90 ° phase difference is converted into linearly polarized phase in phase. That is, since the length between a-b of the double probe 24 is designed to be λ / 4 and the length between b-c is designed to be λ / 2, the signals transmitted to each probe have a 90 ° phase difference.

The signal converted into linearly polarized in phase is transmitted to the microstripline of the Teflon PCB through the common lead of the double probe 24.

Therefore, the present invention enables the circular polarization-linear polarization conversion through the deformation of the LNB waveguide and the deformation of the probe without installing a separate circular polarization-linear polarization feed horn at the front end of the LNB library. The unique effects that can be produced will appear.

Claims (1)

In the LNB for BS broadcast reception, a waveguide of the LNB 20 is formed in a circular shape, and a double probe 24 including? / 2 and? / 4 length probes is provided at the? / 4 position of the reflected wave in the LNB waveguide. Satellite broadcast signal polarization converter characterized in that the installation.