KR200355454Y1 - Square Lattice Horn Array Antenna for Circularly Polarized Reception - Google Patents

Abstract

The present invention relates to a square lattice horn array antenna for receiving circular polarized waves, and particularly, in a circular lattice horn array antenna for receiving circular polarized waves consisting of a pyramidal horn (1) having a square opening and a square waveguide (2), The six conductor plates 31 cut at an inclination angle corresponding to the inclination angle of the pyrimid-type horn 1 are combined to form a lattice with each other, and each of the conductor plates 31 corresponds to the inclination angle of the pyramid horn 1. 9 small square lattice horn antenna elements 3 are formed inside the pyramid horn 1, and are formed at four corners of the nine small square lattice horn antenna elements 3, respectively. Except for the small square lattice horn antenna element 3, the inside of the small square lattice horn antenna element 3 is provided with a retardation compensating dielectric plate 4 having different thicknesses for high gain and opticalness. The dual circular polarization of the band can be received.

Description

Square Lattice Horn Array Antenna for Circularly Polarized Reception

The present invention relates to a square lattice horn array antenna for receiving circular polarization, and more particularly, to a dual circular polarization receiving horn antenna capable of simultaneously receiving left or right rotating circularly polarized square horns having a horn opening and a feed waveguide part in a forward direction. In the opening, a thin metal plate inclined at a certain height and angle is formed to form nine small square lattice horn antenna elements to receive a double gain of high gain and wide band.

In general, the antenna is for radiating or receiving radio waves in a free space, but there are various classification criteria, but can be generally classified into a linear antenna, an aperture antenna, a micro strip antenna, an array antenna, a reflector antenna, and a lens antenna.

The radio waves radiated from the antenna have a predetermined pattern, and the polarized waves of the radio waves are classified into linear polarization, circular polarization, and elliptic polarization according to the direction in which the electric field or the magnetic field vibrate and the direction in which the waves proceed.

Among the several antennas described above, an array antenna refers to an antenna in which many antenna elements are arranged to adjust the phase of the excitation current of each element, and the main beam is formed with the antennas in a specific direction and in the same phase. And the like.

In addition, the circular polarization among the polarizations of the radio waves radiated from the antenna is a radio wave in which the end of the vector representing the magnitude and direction of the electric field is a circle in a plane perpendicular to the direction of propagation. This 90 ° can be divided into two different linearly polarized components, but when the amplitudes differ, the synthesized wave is elliptical on a plane perpendicular to the direction of propagation, which is called an elliptical polarization and is perpendicular to the direction of propagation in a circular or elliptical polarization. The rotation of the electric field vector in the clockwise direction toward the direction of propagation is called the right-turn ellipse polarization and the rotation in the counterclockwise direction is called the left-turn ellipse polarization.

In the prior art, a horn antenna mainly used for an antenna for ultra-high frequency communication transmission is composed of a pyramidal horn 1 having a rectangular opening and a rectangular feed waveguide 2, as shown in FIG. The antenna can be used as an antenna that can transmit and receive only linearly polarized wave with medium gain.

Meanwhile, in the conventional horn antenna, the circular polarization is a propagation path in which the vertical electric field component and the horizontal electric field component have a 90 ° phase difference, and as shown in FIGS. 2A to 2C, both the vertical electric field component and the horizontal can be transmitted and received by the antenna. Since it is necessary to use an antenna having a structure having a circular horn 11 and a circular waveguide 21 or a square horn 12 and a square waveguide 22 or a rhombus horn 13 and a rhombus waveguide 23, the antenna is formed. .

In addition, in order to obtain a high gain due to the transmission and reception of radio waves, these antenna elements are arranged two-dimensionally at appropriate intervals on a plane, and the radio waves are collected at a point through a feed line connected to them to form a high gain array antenna. .

In addition, the spacing between the antenna elements of the array antenna is about 0.5 to 1.0 times the frequency wavelength of transmitting and receiving, the side lobe can be minimized and a high gain can be obtained, but the conventional horn antenna of Figure 1 and 2a to 2c As shown in Fig. 2, since the openings are mainly two wavelengths or more than tens of wavelengths, they cannot be physically disposed on a high gain array antenna and used as antenna elements. Also, when the openings are rectangular, the circular polarization itself cannot be transmitted. have.

The present invention has been devised to solve the above-mentioned conventional problems, and is arranged in a manner of space feeding the small horn antenna elements by partitioning the inside of the opening of the rectangular horn antenna into nine small square lattice horn antenna elements. In addition to increasing the gain, it is also possible to transmit and receive double circularly polarized waves in a wide band by using a square with a aspect ratio of 1: 1, and provides a square lattice horn array antenna for circularly polarized reception that can be used in a planar array in two dimensions. Its purpose is to.

The object of the present invention described above, in the square lattice horn array antenna for circularly polarized wave reception consisting of a square pyramid horn and a square waveguide, the six conductor plates are coupled to each other to form a grid, each conductor plate is a pyramid Nine small square lattice horn antenna elements are formed inside the pyramid horn so as to have an inclination angle corresponding to the inclination angle of the horn, and for compensating phase differences of different thicknesses in the small square lattice horn antenna elements except four corners. This can be achieved by providing a dielectric plate.

Therefore, the space-fed circularly polarized antenna can be arranged in two dimensions, so that circular gain of high gain can be obtained.

1 is a perspective view of a conventional rectangular horn antenna

2A to 2C are exemplary views of horn antennas for conventional circular polarization reception.

3 is an exploded perspective view of the present invention array antenna

Figure 4 is a longitudinal cross-sectional view of the present invention antenna

5 is a front view of the present invention antenna

Explanation of symbols for main parts in the drawings

1: pyramidal horn 2: square waveguide

3: small square lattice horn antenna element 4: dielectric plate for phase difference compensation

31: conductor plate

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

3 is an exploded perspective view of the inventive antenna, FIG. 4 is a longitudinal cross-sectional view of the inventive antenna, and FIG. 5 is a front view of the inventive antenna.

According to this, in a square lattice horn array antenna for circularly polarized wave reception composed of a square pyramid horn (1) and a square waveguide (2),

Six conductor plates 31 whose both ends are cut at an inclination angle corresponding to the inclination angle of the pyrimid-type horn 1 are joined to form a lattice with each conductor plate 31, and each of the conductor plates 31 is an inclination angle of the pyramid horn 1. It is a basic feature that nine small square lattice horn antenna elements 3 are formed inside the pyramid horn 1 by having an inclination angle corresponding thereto.

In addition, the present invention provides a phase difference compensation inside the small square lattice horn antenna element 3 except for the small square lattice horn antenna element 3 formed at four corners among the nine small square lattice horn antenna elements 3 described above. It is characterized in that an additional dielectric plate 4 is provided.

In this case, the thicknesses of the phase difference compensating dielectric plates 4 installed in the small square lattice horn antenna elements 3 located at the center of the small square lattice horn antenna elements 3 are small in front, rear, left and right. It is formed thicker than the thickness of the phase difference compensating dielectric plate 4 provided in the square lattice horn antenna element 3 so that the phase difference between the received radio waves passing through all the small square lattice horn antenna elements 3 is independent of the distance difference. It is characterized by.

Referring to the effect of the present invention configured as described above are as follows.

First, in the square opening of the pyramid horn 1, six conductor plates 31 whose both ends are cut at an inclination angle corresponding to the inclination angle of the pyrimid horn 1 are joined to form a lattice with each other. 9 small square lattice horn antenna elements 3 are formed inside the pyramid horn 1, and each conductor plate 31 is disposed to have an inclination angle corresponding to the inclination angle of the pyramid horn 1. The small square lattice horn antenna elements 3 are then connected to the square waveguide 2 via space feeding.

In this case, the horizontal and vertical lengths of the small square lattice horn antenna elements 3 are about 0.5 to 1.0 times the wavelength to increase the array gain, and the ratio is 1: 1 square to form a double circular polarization. Enables sending and receiving of

On the other hand, the lattice structure of the small square lattice horn antenna elements 3 has a configuration in which the width of the pyramidal horn 1 is divided into three, and each lattice portion is operated as the small square lattice horn antenna element 3, respectively. The length of the lower portion of each small square lattice horn antenna element 3 is slightly larger than the length of the square waveguide 2 so that the signal can be matched without reflection.

On the other hand, in the small square lattice horn antenna elements 3, the phase difference of the feed signal due to the distance difference between the nine small square lattice horn antenna elements 3 occurs due to the space feeding, and the gain is reduced.

Therefore, in the present invention, the inside of the small square lattice horn antenna elements 3 except for the small square lattice horn antenna elements 3 formed at four corners of the small square lattice horn antenna elements 3 may have different thicknesses. A phase plate compensating dielectric plate 4 is additionally installed so that the same phase signal can be transmitted and received with high gain.

At this time, a small square lattice horn antenna element 3 located in the center of the small square lattice horn antenna elements 3 is inserted with a thick phase difference compensating dielectric plate 4 to increase the phase delay. A small square lattice horn antenna element 3 positioned at the front, rear, left, and right sides of the horn antenna element 3 is inserted with a relatively thin phase difference compensating dielectric plate 4 to reduce phase delay, and has diagonal edges. In the small square lattice horn antenna element 3, the phase difference is eliminated by not inserting the phase difference compensating dielectric plate 4 so that the phase difference between the radio waves received by all the small square lattice horn antenna elements 3 I can eliminate it.

On the other hand, by arranging several horn antennas to which the present invention is applied in a horizontal and vertical direction in a two-dimensional plane, a square lattice horn array antenna for circularly polarized wave reception is formed.

As described above, according to the present invention, the inside of one square horn antenna opening is partitioned into nine small square lattice horn antenna elements through several conductor plates, and the phase difference between these small square lattice horn antenna elements is a dielectric. Compensation by inserting the plate is a very useful design, such as being able to receive high-gain, wide-band dual circular polarization.

Claims (3)

A square lattice horn array antenna for circularly polarized wave reception composed of a pyramidal horn (1) having a square opening and a square waveguide (2), Six conductor plates 31 whose both ends are cut at an inclination angle corresponding to the inclination angle of the pyrimid-type horn 1 are joined to form a lattice with each conductor plate 31, and each of the conductor plates 31 is an inclination angle of the pyramid horn 1. A rectangular lattice horn array antenna for circularly polarized reception, characterized in that nine small square lattice horn antenna elements (3) are formed inside the pyramid horn (1) so as to have an inclination angle corresponding thereto. The method according to claim 1, Among the nine small square lattice horn antenna elements 3 described above, except for the small square lattice horn antenna elements 3 formed at four corners, the dielectric plate for phase difference compensation 4 is provided inside the small square lattice horn antenna elements 3. And a lattice horn array antenna for circularly polarized wave reception. The method according to claim 2, The thickness of the phase difference compensating dielectric plate 4 installed in the small square lattice horn antenna element 3 located at the center portion is provided in the small square lattice horn antenna element 3 positioned at the front, rear, left, and right sides thereof. It is formed thicker than the thickness of the phase difference compensating dielectric plate 4 so that the phase difference between the received radio waves passing through all the small square grating horn antenna elements 3 is independent of the distance difference. Array antenna.