KR20120081410A - Dual circular polarization antenna - Google Patents

Abstract

In the present invention, the polarizer is a rectangular polarizer for converting linear polarization into rotational polarization, and at least one of the linear polarization ports has a diaphragm left and right on the sidewall of the larger polarizer in contact with the diaphragm. The present invention relates to a dual rotary polarization antenna having a thin and simple structure, which is formed by configuring one radiating element and forming a feeder network composed of waveguides by using a polarizer arranged so that a linear polarization port is formed on one surface.

Description

Dual Circular Polarization Antenna

The present invention relates to a dual rotary polarization antenna, and to a dual rotary polarization horn array antenna that can improve the performance of the antenna by using a new diaphragm polarizer port structure, simplify the structure of the antenna, and reduce its thickness.

A waveguide is a type of transmission line that transmits electromagnetic waves (MICRO WAVE) or higher frequency (hereinafter referred to as 'electromagnetic waves') energy of more than microwaves, and transmits electromagnetic waves inside a tube formed of an electrical conductor such as copper. It has a kind of high-pass cutoff filter characteristic, and electromagnetic wave of longer wavelength than cutoff wavelength is not transmitted. The wavelength of the electromagnetic wave transmitted along the axis of the waveguide is referred to as an inner tube wavelength.

That is, the waveguide is a hollow metal tube, and the basic mode (MODE) of the wavelength transmitted in the tube has a constant blocking wavelength determined by the size of the waveguide.

In general, low-frequency signals are transmitted through two copper wires, which are conductors. However, at high frequencies, the conductor loss increases due to the surface effect of the conductor, and the dielectric loss due to the surrounding insulation increases.

However, since the waveguide transmits the electromagnetic wave while reflecting it between the inner walls, it has little loss (attenuation) and blocks the inflow of noise from the outside and prevents unnecessary external radiation of the electromagnetic wave. It is suitable and the cross section has various shapes such as round, square, oval and the like.

In the case of radiating (transmitting) electromagnetic waves transmitted in the pipe of the waveguide into the air, the antenna functions as a waveguide antenna or a horn antenna. Antennas transmit and receive.

When the horn antenna using the waveguide does not normally perform impedance matching between the opening for outputting electromagnetic waves and the air layer, a part of the output electromagnetic energy is not output and is reflected and input to the corresponding electronic device. (OUTPUT POWER) is lowered, and the reflected energy degrades the output stage of the electronic circuit and shortens the life.

Therefore, the horn antenna expands the size of the opening step by step to match the impedance so that the maximum energy is radiated.

Microwaves with electromagnetic waves in the range of 1 mm to 1 m of radio frequency, including ultra high frequency (UHF) with a wavelength of 0.1 to 1 meter (m), are called microwaves, and radar during World War II. The use has been activated by the development of (RADAR).

Millimeter wave (WILL) or EXTREMELY HIGH FREQUENCY (EHF) has a wavelength of several millimeters (mm), and cmwave or SUF HIGH FREQUENCY (SHF) has a wavelength of 1 to 10 centimeters (cm).

The higher the frequency, the stronger the straightness, so it is blocked by obstacles in the ground direction and limited to transmission of visible distance, but it is used as a radio communication frequency with satellites because it transmits far distance with less power in the sky direction without obstacles.

Microwave signals over microwaves have very similar properties to light, so optical theory, megaphone's principle of concentrating sound waves, etc. can be applied.

With the development of information and communication technology, high frequency radio waves are frequently used in everyday life. Although many types of linearly polarized waveguide horn array antennas have been developed, it is difficult to develop proper structures in polarizers and feeder networks, which are important in the development of rotating polarized waveguide horn antennas.

There are two types of radio waves: horizontal and vertical polarization, which are linear polarizations, and left polarization (LHCP) and right polarization (RHCP).

The planar dual linearly polarized wave or rotary polarized waveguide mixed array antenna is composed of an array of radiating elements for transmitting or receiving a signal of linearly polarized or rotationally polarized wave. Each of the radiation elements is composed of a horn, a polarizer, and a feeder network. The polarizer includes a first polarization port and a second polarization port through which an incident port and a separated polarization signal enter and exit, and are connected to the first polarization port. The first feeder network, and the second feeder network is connected to the second polarization port. The feeder network located near the horn of the first and second feeder grids is the first-class grid.

At this time, the elements of the feeder network are basically divided into four types: E-Plane break, E-plane T divider, H-Plane break, H-Plane T-divider.

In order to produce a product in the design drawing of the conventional antenna, a method of manufacturing a mock-up according to the designed shape, a method of plating on an injection molding, and a method of processing metal according to the design drawing were typical methods. At this time, the structure of each horn, polarizer, and feeder network is connected like a complicated three-dimensional maze so that it cannot be produced in one plate like a dish antenna, and only several layers of panels can be combined to become an entire antenna.

In the conventional dual rotating polarization antenna, the polarizer of the antenna element is a device that separates the polarization of the rotating polarization, a diaphragm polarizer is used, and uses a structure that is mainly used for the feed horn of the LNB. The diaphragm polarizer is a waveguide device having three input / output ports. One of them is a port for passing the rotation polarization signal, and the other two ports are for passing the linear polarization signal. Diaphragm polarizers can be made from circular waveguides or alternatively can be formed from two rectangular waveguides. When formed from two square waveguides, two rectangular waveguides of the same size are gathered to pass through one diaphragm to a square waveguide.

In the diaphragm polarizer, the linearly polarized signal is converted into a signal of rotational polarization due to the action of the diaphragm, and conversely, the signal of the rotational polarization is converted into a linearly polarized signal. When a linearly polarized signal is incident on one of the two rectangular waveguides, left hand polarization (LHCP) or right hand circular polarization (LHCP) occurs depending on which port is incident.

In the conventional dual rotating polarization waveguide horn antenna, the position of the rotating polarization port in the diaphragm polarizer is opposite to the position of the two ports that are converted into linear polarization, and the two linear polarization ports are divided into two with the diaphragm interposed therebetween. The design of feed grids for single-swivel antennas was easily designed for the combination of E-Plane Bend and E-Plane T splitters, which have been used mainly in the design of conventional flat dual-polarized polarized antennas. In the design of the feeder grid, the positions of the ports connected from the polarizer to the feeder grid are all concentrated in one direction so that the signal connection when connecting according to the conventional combination of E-Plane Bend and E-Plane T splitter The phases were broken with each other, making it impossible to configure the antenna. Overcoming this problem has been made possible by the introduction of the waveguide bending structure from the E-plane to the H-Plane, which has been proposed in the prior application. However, the antenna of the conventional application is possible with four panels in the manufacture of the mock-up, it was possible to manufacture only five panels in the mass production. In the conventional dual linearly polarized antenna, it is possible to manufacture the antenna using only four or three panels. However, in the dual rotary polarized antenna using the conventional waveguide structure, the first polarization port is connected to the first feeder network due to the structure of the polarizer port. In order to unavoidably turn the direction, the middle layer, which was not present in the dual linearly polarized antenna, is required, and the number of panels is additionally required, which adds cost.

Application number 10-2009-0126095

An object of the present invention is to propose a dual linearly polarized antenna having a structure capable of receiving both dual rotation polarization and more simply manufactured.

The problem of the conventional dual polarized polarization antenna is that a certain distance is required to convert from linear polarization to rotational polarization or rotational polarization to linear polarization due to the characteristics of the polarizer, and the diaphragm is in the same direction and location of the two linear polarization ports. It had to be located only on the opposite side of the rotary polarization port of the diaphragm polarizer. For this reason, the waveguide of the second feeder network of the two ports could easily constitute the waveguide feeder network by a repetitive combination of the conventional E-Plane Bend and the E-Plane T distributor, but the structure of the feeder network to be connected to the first polarization port The bending structure from E-Plane to H-Plane was used.A total of 5 antennas were fabricated in the fabrication of the antenna, that is, the layer including the mixed layer and the polarizer upper part, the upper layer of the first feeder layer, the lower layer and the middle layer of the first feeder layer. Production is possible only by separating the panel including the upper layer of the lower layer of the intermediate layer and the upper layer of the second feeder layer, the lower layer of the second feeder layer. In this way, the intermediate layer is removed from the structure in which the intermediate layer is used, so that a total of four antennas are manufactured in the fabrication of the antenna, that is, a layer including a mixed layer and an upper polarizer, an upper layer of the first feeding layer, a lower layer of the first feeding layer, and a second feeding network. The panel including the upper layer of the upper layer, the lower layer of the second class projection layer and the like to provide a dual rotating waveguide antenna and to provide a dual rotating polarization antenna that can be manufactured in a total of four panels.

The configuration of the present invention for achieving the above object, in the flat plate type polarized waveguide antenna for transmitting and receiving the star polarization and the port polarization separately,

In the waveguide antenna, a plurality of waveguide antenna elements which transmit and receive the star polarization and the port polarization, respectively, are arranged and connected to each other by a feeder network.

Each of the waveguide antenna elements includes: a horn for increasing the gain of the radio waves transmitted and received; And a polarizer having a quadrangular cross section separating the electric wave into a starboard polarization and a starboard polarization; wherein the polarizer divides one side lower end facing the upper side of the inner surface in an oblique shape and divides the volume into the same size; And a port for transmitting and receiving by transforming a radio wave divided into a port polarization and a star polarization into linear polarization, respectively.

The first polarized signal separated from the left side or the right side of the diaphragm in the polarizer portion is blocked, and the lower end of the diaphragm is blocked and the rectangular polarizer portion is separated from the side of the four sides of the diaphragm touched. The first port for transmitting or receiving is located, and the second port for transmitting or receiving the second polarized signal is located at the bottom of the other side of the left side or the right side of the diaphragm, the present invention, do.

Preferably, the first and second polarization ports are rectangular waveguides each having a rectangular cross section.

In the polarizer, a stepped protrusion, a square protrusion, an oblique protrusion and an edge shape may be further formed at a lower end or a second port of the side wall or the left or right side of the diaphragm.

Dual rotating polarized waveguide mixed-array antenna according to the present invention is a panel that must be manufactured at the time of production as the structure can be structured in a simple structure by reducing one layer of the waveguide when looking at the vertical plane than using a conventional technology In addition to reducing the number of components, the cost reduction effect is simple, and the structure is simple, which can reduce a lot of problems in manufacturing.

1 is a perspective view drawn in reverse phase of a conventional dual rotary polarization waveguide horn antenna.
2 is a reversed phase diagram of an antenna element according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Through the present invention, the dual rotating polarization antenna can be manufactured with a simpler structure, thereby reducing production costs, and thus, may have many industrial values.

100: horn portion of the flat waveguide horn antenna
200: polarizer
210: first polarization port of the polarizer portion
220: second polarization port of the polarizer portion
230: diaphragm in the polarizer portion
240: square projection of the side wall of the first polarization port side polarizer
250: stepped projection at the entrance of the second polarization port
260: square projection of the side wall of the second polarization port side polarizer
300: first feeder
400: second feeder
310: E-Plane T Junction
320: E-Plane Bend

Claims (1)

In the flat plate type polarization waveguide antenna for separating and transmitting the starboard polarization and the port polarization,
In the waveguide antenna, a plurality of waveguide antenna elements which transmit and receive the star polarization and the port polarization, respectively, are arranged and connected to each other by a feeder network.
Each of the waveguide antenna elements includes: a horn for increasing the gain of the radio waves transmitted and received; And
And a polarizer having a rectangular cross section for separating the radio wave into a starboard polarization and a starboard polarization.
The polarizer includes a diaphragm that divides one side lower end facing the upper end of the inner surface in an inclined shape and divides the volume into the same size; And
It consists of a port that transmits and receives by transforming the radio wave divided into port polarization and star polarization into linear polarization, respectively.
The first polarized signal separated from the left side or the right side of the diaphragm in the polarizer portion is blocked, and the lower end of the diaphragm is blocked and the rectangular polarizer portion is separated from the side of the four sides of the diaphragm touched. And a first port for transmitting or receiving is located, and a second port for transmitting or receiving a second polarized signal is located at the lower end of the other side of the diaphragm on the left or right side of the diaphragm.

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