KR100736227B1 - Feeder horn antenna for parabola antenna - Google Patents

Abstract

A feeder horn antenna for a parabola antenna is provided to lower a cross polarization level by decreasing reflectance of waves on a surface of a dielectric when the waves enter the dielectric from a polarizer of the dielectric so that an amount of the waves reflected from an input end of the polarizer is small. A feeder horn antenna for a parabola antenna includes a waveguide(50) used as a feeder line and a feeding unit(60) connected to the waveguide(50). The waveguide(50) has a circular shape or other shapes. The waveguide(50) has a first part(50a) with an inner diameter gradually smaller as going toward the feeding unit(60) and a second part(50b) having a uniform inner diameter and extending to the first part(50a). The waveguide(50) is made of aluminum. A portion where the first part(50a) starts is connected to a transceiver and the second part(50b) is filled with a dielectric(70). The dielectric(70) expands toward the first part(50a) and the feeding unit(60).

Description

Feeder horn antenna for parabolic antenna

1 is a cross-sectional view of a dish antenna according to the prior art.

2 is a cross-sectional view of a feed antenna of a dish antenna according to the prior art.

3 and 4 are graphs showing the result of the horizontal component among the results of circular polarization simulation for each frequency of the conventional dish antenna shown in FIG. 1.

5 is a cross-sectional view illustrating a feeding antenna structure of a dish antenna according to an embodiment of the present invention.

6 and 7 are graphs showing the results of the horizontal component among the results of simulation of the circular polarization radiation pattern for each frequency of the dish-type antenna including the feed antenna shown in FIG. 5.

* Description of Signs of Major Parts of Drawings *

50: waveguide 50A: first portion of waveguide

50B: second portion of waveguide 50C: slope

60: feeding part 60a, 60b: opening part

70: dielectric 70a: portion extended to the first portion of the dielectric

70b: part extended to the feed part of the dielectric

L1, L2: first and second sections 80: cap

The present invention relates to an antenna, and more particularly, to a feed antenna in a dish antenna.

Since the dish antenna has a strong directivity in the axial direction, it is possible to obtain a higher gain than the half-wavelength dipole antenna and the quarter-wave antenna and to be less disturbed from the external environment. In a dish antenna having such a feature, radio waves converge in one direction and are radiated strongly, which is suitable for linear transmission from one point to another, such as television relay or satellite communication.

Recently, as satellite broadcasting is greatly activated, the demand for a dish antenna is increasing, and various dish antennas are introduced.

 1 shows an example of a dish-shaped antenna (hereinafter, referred to as a conventional antenna) introduced to date.

Referring to FIG. 1, an antenna according to the related art includes a reflector 10 and a feed antenna 20 as main parts. The feed antenna 20 radiates radio waves toward the reflector 10 or receives radio waves reflected from the reflector 10. As shown in FIG. 2, the feed antenna 20 includes a circular waveguide outer conductor 30, a circular waveguide 32 gradually decreasing in diameter toward the feed portion P1, an antenna matching dielectric rod 34, Feeding unit (P1) for emitting a radio wave to the reflector plate 10, and connected to the transceiver and the inside of the circular waveguide input port 40 is air. The antenna matching dielectric rod 34 extends toward the input port 40 by a given length, the vertex being spaced apart from the input port 40 by a given distance. The portion extending toward the input port 40 of the dielectric rod 34 is conical. The dielectric rod 34 also extends into the feed section P1. The portions 34a and 34b extended to the feeding portion P1 of the dielectric rod 34 are curved in a spherical shape to the outside of the waveguide outer conductor 30, unlike the portions extending toward the input port 40. It can be seen that the spherical bent portions 34a and 34b of the dielectric rod 34 extended to the feed portion P1 become thinner and thinner. Accordingly, the curvature of the front surface of the spherical bent portions 34a and 34b of the dielectric rod 34 exposed through the opening 36 open toward the reflecting plate 10 of the feed portion P1 may cause the opening 36 to be opened. It is different from the curvature of the back that is not exposed through.

3 and 4 show the horizontal component of the radiation pattern of this prior art antenna.

3 is a result of measuring at a frequency of 7.5GHz, Figure 8 is a frequency of 8.15GHz. 3 and 4, the first graphs G1 and G11 represent the main beams, and the second graphs G2 and G22 represent cross polarizations.

3 and 4, the cross polarization is less than 17 dB regardless of the frequency used. In other words, when the 0 dB reference is the peak of the first graphs G1 and G11, that is, the main beam, the cross polarization in the prior art becomes -17 dB or less.

In the case of the antenna according to the prior art as described above, since the portions 34a and 34b extended to the feed portion P1 of the dielectric rod 34 are spherical, machining is difficult. Therefore, there is a considerable tolerance between the design form and the actual form of the extended portions 34a and 34b.

As a result, some degree of reflection loss is inevitable, and thus it is inevitable that the cross-polarization performance is inferior in the antenna according to the prior art. Accordingly, the cross polarization of the antenna according to the prior art is -17 dB or less, and does not satisfy -20 dB, which is the cross polarization level required when the waveguide type polarizer is used.

The technical problem to be achieved by the present invention is to improve the problems of the prior art described above, can improve the antenna efficiency (gain) by improving the cross-polarization characteristics, dish-shaped antenna that can facilitate the feeder processing To provide a feed antenna of.

In order to achieve the above technical problem, the present invention provides a waveguide including a first portion having an inner diameter and a second portion having a constant inner diameter, a feeder connected to the second portion and radiating radio waves to a reflecting plate, and the first portion. A feed antenna is provided that fills two portions and extends into the first portion and the feed portion, wherein the portion extended to the first portion comprises a dielectric consisting of two portions having different surface slopes.

In the feeding part, the dielectric may extend in a given length in a direction perpendicular to the second part, and the end part may be gently curved toward the reflecting plate.

An inclined surface may exist on the surface of the first portion.

An outer surface of the portion extending into the feed portion of the dielectric may be covered with a cap.

The dielectric may be PEEK.

By using the present invention, the cross polarization level can be lowered, thereby increasing the antenna efficiency (gain). Moreover, a power supply part can be processed easily.

Hereinafter, a feeding antenna (hereinafter, a feeding antenna of the present invention) of a dish-shaped antenna according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thicknesses of layers or regions illustrated in the drawings are exaggerated for clarity.

Referring to FIG. 5, the feed antenna of the present invention includes a waveguide 50 used as a feed line and a feed unit 60 connected to the waveguide 50. The waveguide 50 may be circular, for example, but may be of other shapes. The waveguide 50 is a portion where the first portion 50A and the first portion 50A whose inner diameter gradually narrows toward the feed portion 60 and the first portion 50A extend up to the feed portion 60, and the second portion 50B having a constant inner diameter. Can be divided into The material of the waveguide 50 may be aluminum, for example. The portion where the first portion 50A starts is connected to a transceiver (not shown). Second portion 50B of waveguide 50 is filled with dielectric 70. The dielectric 70 is a material having heat resistance and a small change in dielectric constant at the X band frequency. For example, the dielectric 70 may be PEEK having a dielectric constant ?? _r of 3.1. The dielectric 70 extends into the first portion 50A and the feed portion 60.

When the type of the dielectric 70 is determined, the inner diameter of the second portion 50B of the waveguide 50 may be determined. In this case, it is necessary to determine the inner diameter of the second portion 50B so that the wave propagation mode in the waveguide 50 is stopped, for example, the TM010 mode in the operating frequency band.

Dielectric 70 is extended to fill only a portion of first portion 50A. The same applies to the power supply unit 60. The portion 70a extending to the first portion 50A of the dielectric 70 decreases in diameter in a direction away from the feed portion 60. However, the expanded portion 70a does not have a constant decrease in diameter from beginning to end.

Specifically, the portion 70a extended to the first portion 50A of the dielectric 70 may include a first section L1 having a first slope and a second section L2 having a second slope. Include. The first section L1 starts at the point where the dielectric 70 begins to expand. The second slope is greater than the first slope. Therefore, the expanded portion 70a is gradually sharpened away from the feed section 60.

When there is an extended portion 70a of the dielectric 70 having such surface slope characteristics in the first portion 50A of the waveguide 50, the first portion of the waveguide 50 from the polarizer (not shown) ( The reflectance at the surface of the extended portion 70a of the radio wave incident on 50A) becomes smaller than before. Therefore, since the amount of radio waves reflected to the input terminal of the polarizer is also reduced, the amount reflected back from the input terminal of the polarizer is also reduced. This result is one factor that lowers the level of cross polarization.

The feed portion 60 includes a portion of the waveguide 50, an extended portion 70b of the dielectric 70, and a cap 80. The material of the cap 80 may be aluminum, for example. The cap 80 covers the outer surface of the expanded portion 70b of the dielectric 70. The expanded portion 70b extends between the waveguide 50 and the cap 80 by a given length in a direction perpendicular to the second portion 50B of the waveguide 50, the end of which is inward, It is gently curved toward the reflecting plate (10 in FIG. 1). The portion extended by a given length in the direction perpendicular to the second portion 50B of the expanded portion 70b has a given thickness.

The power supply unit 60 also has openings 60a and 60b. Openings 60a and 60b are around the second portion 50B of the waveguide 50. Through the openings 60a and 60b, the inner surface of the portion 70b extended to the feed portion 60 of the dielectric 70, that is, the portion facing the reflecting plate, is exposed. Thus, the radio waves radiated from the extended portion 70b of the dielectric 70 are radiated toward the reflector through the openings 60a and 60b.

On the other hand, the first portion 50A of the waveguide 50 has an inclined surface 50C. The inclined surface 50C is only present in a portion of the first portion 50A. The inclined surface 50C is present in a direction away from the feed section 60 at the boundary between the first portion 50A and the second portion 50B. Where such inclined surface 50C is present, the outer diameter of the first portion 50A increases as it moves away from the feed section 60.

The power supply part 60 has a constant area. And the feed part 60 is not far enough from the reflecting plate (10 of FIG. 1). Because of this, it is difficult to see the power supply unit 60 as a point source, and the radio waves emitted from the power supply unit 60 are different from the radio waves emitted from the point sources.

By the way, when the inclined surface 50C having the above characteristics exists in the first portion 50A of the waveguide 50, the propagation characteristics radiated toward the reflecting plate through the openings 60a and 60b of the feed section 60. Is close to the propagation characteristics emitted from the point source. This increases the directivity of the antenna, decreases the reflection loss and lowers the cross polarization level.

6 and 7 show the results for the horizontal component of the circular polarization radiation pattern simulation of the dish-type antenna with a feed antenna of the present invention described above.

FIG. 6 is when the use frequency is 7.5 GHz, and FIG. 7 is when the use frequency is 8.15 GHz.

6 and 7, the first graphs G61 and G71 show the horizontal component radiation patterns of the main beam, for example, the preferential circular polarization, and the second graphs G62 and G72 show the cross polarization, for example, the left line. It shows the horizontal component radiation pattern of the circularly polarized sex.

6 and 7, it can be seen that the cross polarization is less than -20 dB regardless of the used frequency. In addition, it can be seen that the difference between the maximum peak of the main beam and the maximum peak of the cross polarization is 20 dB or more.

6 and 7 and the comparison of FIGS. 3 and 4 showing the results of the conventional simulation, the present invention shows that the difference between the maximum peak of the main beam and the maximum peak of the cross polarization is higher than the prior art, while the cross polarization level is low. It can be seen that.

While many details are set forth in the foregoing description, they should be construed as illustrative of preferred embodiments, rather than to limit the scope of the invention. For example, those skilled in the art to which the present invention pertains will be able to further diversify the material of the dielectric 70. In addition, the portion extending into the first portion 50A of the dielectric 70 may be machined to have three different surface slopes. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the technical spirit described in the claims.

As described above, in the feed antenna provided in the dish-shaped antenna of the present invention, a portion where radio waves are incident from the polarizer of the dielectric existing in the waveguide is composed of two parts having different surface slopes. Accordingly, when radio waves are incident from the polarizer to the dielectric, the reflectance of the radio waves on the surface of the dielectric is lowered, thereby reducing the amount of radio waves reflected back from the input of the polarizer. This results in a low level of cross polarization.

 In addition, an inclined surface exists on the surface of the waveguide separated by a given distance from the feed portion. In the portion where the inclined surface exists, the outer diameter of the waveguide increases as the distance from the feed portion.

Due to this inclined surface, the radio waves radiated from the feed portion have characteristics close to those of the radio waves radiated from the point sources, and thus directivity is increased. In addition, the reflectance is lowered, resulting in a lower level of cross polarization.

In addition, the dielectric extending from the waveguide to the feed portion extends straight in the direction perpendicular to the waveguide, and its tip is gently curved inward. This shape is much simpler than a spherical shape and is easy to process. In addition, the reflection of the transmitted wave can be minimized by leaving the sphere.

Claims (3)

A waveguide including a first portion having an inner diameter and a second portion having a constant inner diameter; A feeding part connected to the second part and radiating radio waves to a reflecting plate; And And a portion filling the second portion and extending to the first portion and the feed portion, wherein the portion extending to the first portion comprises a dielectric comprising two portions having different surface slopes. 2. The power feeding antenna of claim 1, wherein in the feed portion, the dielectric extends in a direction perpendicular to the second portion, and an end portion is gently curved toward the reflecting plate. The power feeding antenna according to claim 1 or 2, wherein an inclined surface is present on the surface of the first portion.

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