KR100933152B1 - Antenna device - Google Patents

Abstract

Easy suppression means for suppressing the interference direction by suppressing the interference with the antenna mounting support, and also for suppressing fluctuations in the antenna directivity pattern under the influence of the feeder or the radome, and easy improvement for improving the VSWR deterioration under the influence of the reflector or the radome. An antenna device having means is provided. The present invention includes a sleeve antenna (25) coupled to a coaxial line (30) and composed of a center conductor (10) and a sleeve (20), and a conical reflector (40), wherein the center conductor is provided on the yaw side of the cone. The sleeve antenna 25 is disposed so that 10 corresponds to the central axis of the cone and the tip of the center conductor 10 is spaced apart from the top of the cone.

Antenna device, sleeve antenna,

Description

Antenna device {ANTENNA APPARATUS}

1 is an antenna configuration diagram showing a configuration of an antenna device of the present invention;

2 is an internal mounting diagram showing an internal mounting form of the antenna device of the present invention;

3 is an external mounting diagram showing an external mounting form of the antenna device of the present invention;

4 is a directivity characteristic diagram showing directivity in the Ｘ-Z plane of the antenna device of the present invention;

5 is a VSWR characteristic diagram of the antenna device of the present invention;

6 is a ripple characteristic diagram of radio waves of the antenna device of the present invention;

7 is a configuration diagram showing another embodiment of the antenna device of the present invention;

8 is a conventional monopole antenna installation form and its characteristic diagram.

10: center conductor 20: sleeve

25: sleeve antenna 30: coaxial line

40: reflector 50: disk for impedance matching

60: disc for interference suppression 70: radome

80, 91: antenna mounting post 90: ground

92: monopole antenna 93: feed line

100: antenna device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna for a base station in mobile communication, and more particularly to an antenna device for a base station suitable for a narrow service area or an antenna device for a relay station in a radio wave dead zone.

The base station antenna in mobile communication is used separately from a base station antenna for the purpose of covering a large area and a base station antenna for the purpose of covering a relatively limited small area. The antenna for the purpose of covering this relatively limited small range area | region is used for covering the dead zone of the radio wave which a radio wave is interrupted by a high-rise building etc., and become what is called the shadow of a building. In the urban area, since such dead zones are relatively scattered, a concept of a multi-hopping system in which relay stations having antennas covering small areas are arranged for each dead zone and relayed to each other to solve the dead zone is examined.

As antennas for base stations suitable for radio wave dead zones or narrow service areas, monopole antennas and dipole antennas are used. In US Patent US 2005/0156804 A1, a description is given of the element shape of a monopole antenna by a finite fingerboard. For example, when such a monopole antenna is used for a base station in a narrow service area or a multi-hopping relay station, when a wall of a building or the like cannot be used, there is a need to install it as a self-standing antenna.

Fig. 8 is a diagram showing a monopole antenna mounting mode in which a monopole antenna is provided as a self-standing antenna and its characteristics. In FIG. 8A, a monopole antenna 92 is provided at the tip of the self-supporting antenna mounting support 91 erected on the ground 90, and is fed by a feed line 93 from a base station or a relay station (not shown). High frequency power of radiation propagation is supplied. Since the finite plate is provided on the ceiling side, the directivity in the X-Z plane generates a main lobe downward in the horizontal direction suitable for radiating radio waves toward the valleys of the building. FIG. 8B is a directional characteristic diagram showing the directivity in the Ｘ-Ｙ plane of the installed monopole antenna 92. The monopole antenna 92 exhibits omni (omni-directional) characteristics on the X-surface and becomes circular, but the radio waves are interfered by the strut 91 and attenuation of the radio waves occurs in the -X direction, and the circular shape is distorted. All. Due to this attenuation, the -X direction becomes degraded or incapable of communication, and it is difficult to eliminate the radio wave dead zone over all directions.

SUMMARY OF THE INVENTION The present invention has been proposed to solve such problems of the prior art, and its object is to suppress the interference with the antenna mounting posts to eliminate the dead direction, and at the same time, to change the antenna directivity pattern caused by the influence of the feed line or the radome. It is an object of the present invention to provide an antenna device having easy suppression means for suppressing and easy improvement means for improving VSWR deterioration due to the influence of a reflector or a radome.

An antenna device of the present invention includes a sleeve antenna coupled to a coaxial line and composed of a center conductor and a sleeve, and a conical reflector, wherein the center conductor coincides with the central axis of the cone on the yaw side of the cone. The sleeve antenna is characterized in that the front end of the center conductor is spaced apart from the top of the.

The antenna device of the present invention is characterized in that an impedance matching disk is provided in the center conductor of the sleeve antenna along the center axis of the cone of the reflector.

The antenna device of the present invention is characterized in that an interference suppressing disk for suppressing interference of radio waves is disposed on the coaxial line side of the sleeve antenna along the central axis of the cone of the reflector.

The antenna device according to the present invention is characterized by providing a conical resin radome, forming a storage space by bringing the bottom surface of the reflector into close contact with the bottom surface of the radome, and storing the sleeve antenna in the storage space.

The antenna device according to the present invention is characterized in that a lateral circumference and a conical radome are provided on an upper surface, the reflector is disposed on the upper surface of the radome, and the sleeve antenna is accommodated in the circumference.

The reflector of the antenna device of the present invention is characterized by being composed of a metal plate, a metal net or a dielectric coated with a metal.

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

1 is an antenna configuration diagram showing the configuration of the antenna device of the present invention. The sleeve antenna 25 is composed of a center conductor 10 and a sleeve 20 coupled to a coaxial line 30 to which high frequency power of radiated radio waves is supplied. In addition, the sleeve antenna 25 is accommodated in a storage space formed by bringing the conical reflector 40 and the bottom face of the conical resin radome 70 into close contact with each other to form the antenna device 100. In storage, the center conductor 10 is arrange | positioned at the yaw side of the cone of the reflector 40 so that the center axis of a cone may coincide, and the tip of a center conductor may be spaced apart at the vertex of a cone.

Further, on the distal end side of the center conductor 10, the deterioration of the VSWR due to the influence of the reflected wave generated in the radome 70 and, in particular, the coupling caused by the center conductor 10 approaching the reflector 40 is improved. An impedance matching disk 50 is provided for this purpose. In the coaxial line 30, the leakage current flowing through the coaxial line 30 is prevented from flowing to the connector side of the transmitter (not shown), and at the same time, radio waves are directly emitted to the conical tip side of the radome 70, In the case where the antenna-mounted support 80 (refer to FIGS. 3 and 7) to which the large interference is generated and the connected antenna mounting pillar (see FIGS. 3 and 7) is in the shape of a pipe, an interference suppressing disk 60 for suppressing the acting as a leak waveguide is provided. It is arranged. By this impedance matching disk 50 and the interference suppressing disk 60, radio waves are efficiently radiated in the direction shown by the broken line, and a main lobe is generated downward in the horizontal direction.

Next, the shape of the antenna device 100 will be described. The opening angle of the conical reflector 40 is 120 degrees in diameter and is about 3.75 wavelengths. The diameter of the disk-shaped impedance matching disk 50 is about 1/8 wavelength. The disk-shaped interference suppressing disk 60 has a diameter of about 1/2 wavelength. The lengths of the center conductor 10 and the sleeve 20 of the sleeve antenna 25 are each 1/4 wavelength. The distance from the upper end of the sleeve 20 to the interference suppression disk 60 is about 3/8 wavelength. The distance from the upper end of the sleeve 20 to the impedance matching disk 50 is about 1/16 wavelength. The distance from the reflector 40 to the impedance matching disk 50 is about 1/16 wavelength.

Fig. 2 is an internal drawing showing the installation form of the inside of the antenna device of the present invention. In FIG. 2A, the sleeve antenna 25 coupled to the coaxial line 30, the impedance matching disk 50 and the interference suppression disk 60, which are matching means, are conical in shape of the radome 70. It is inserted through the circular hole portion at the tip side and fixed. 2 (b) shows the shape of the reflector 40, the bottom surfaces of the reflector 40 and the radome 70 are in close contact with each other, and the antenna device 100 before installation is constituted by the antenna mounting support 80. As shown in FIG. .

3 is an external mounting diagram showing an external mounting form of the antenna device of the present invention. In FIG. 3A, the sleeve antenna 25 is accommodated in a storage space formed by bringing the reflector 40 and the radome 70 into close contact with each other, and is installed in the antenna mounting support 80 to provide the antenna device 100. It consists. 3B is a perspective view of the antenna device 100. This antenna device 100 is provided as a self-supporting antenna on a specific place on the roof of a building or on the ground.

4 is a directivity characteristic diagram showing the directivity in the Ｘ-Z plane of the antenna device of the present invention. In Fig. 4, the main lobe of the directivity characteristic shows a pattern having a maximum gain diagonally downward. Moreover, since the antenna device of this invention is provided in the front-end | tip of the antenna mounting support 80 as shown in FIG. 3, the directivity of the X-Y plane shows a stable omni pattern, without receiving the interference by the support 80. As a result, the dead zone of the radio wave which becomes the shadow of the prop is eliminated, and the place where communication is not possible can be eliminated.

Fig. 5 is a VSWR characteristic diagram showing the effect of the impedance matching disk of the antenna device of the present invention. On the front end side of the center conductor 10, the VSWR characteristic is deteriorated by the influence of the reflected wave generated in the radome 70 and the coupling generated by the center conductor 10 approaching the reflector 40. 5, the broken line shows the case where the disk for impedance matching is not provided, and the solid line shows the case where this disk is provided, respectively, and VSWR characteristic improves 0.5-1.0. In addition, the base station antenna and the relay station antenna can be considered to transmit not only reception but also radio waves of relatively large power, so that the VSWR is preferably 1.3 or less, but can be sufficiently achieved by the effect of this disk.

6 is a ripple characteristic diagram of radiation propagation showing the effect of the interference suppressing disk of the antenna device of the present invention. An interference wave is generated by the leakage current flowing through the coaxial line 30, and radio waves are directly emitted to the tip side of the conical shape of the radome 70 to generate a large interference. In this case, the interference wave acts as a leak waveguide. The interference suppression disk 60 is for solving these problems. 6, the broken line shows the case where the disk for interference suppression is not provided, and the solid line shows the case where this disk is provided, respectively. The main lobe is generated toward the horizontal direction (90 degrees) toward the direction of 45 degrees or less (135 degrees). Further, the radio wave attenuates rapidly in the direction of less than 70 degrees (160 degrees), and is hardly radiated in the 90 degree direction (180 degrees) which is the antenna mounting support 80. The vertical axis is shown in dBi scale. The ripple due to the interference is suppressed by the interference suppressing disk 60, and the ripple characteristic of the radio wave propagates in a pattern having a gentle curve.

7 is a configuration diagram showing another embodiment of the antenna device of the present invention. In Fig. 7, the sleeve antenna 25 coupled to the coaxial line 30, the impedance matching disk 50 and the interference suppression disk 60, which are matching means, have a circumferential side and a conical radome on the upper side. It is inserted into the columnar shape of 70 and is fixed. The reflector 40 is arrange | positioned on the upper surface of the radome 70, and comprises the antenna device 100 before being installed in the antenna mounting support 80. As shown in FIG. By this simple configuration, it is possible to cover the dead zone in indoors with weak wind pressure. In addition, the reflector 40 shown in FIG. 1 and FIG. 7 is comprised from a metal plate, a metal mesh, or the dielectric which coat | covered metal.

As described above, according to the present invention, the influence of the reflector and the radome and the easy suppression means for suppressing the interference direction by suppressing the interference with the antenna mounting support and at the same time suppressing the fluctuation of the antenna directivity pattern under the influence of the feeder or the radome An antenna device with a simple improvement means for ameliorating the VSWR deterioration caused by the above is possible. As a result, in a so-called dead zone of radio waves generated between a small-area base station antenna and a building such as an urban unit, it is installed at a height free of obstacles between other base stations, and relays radio waves at an oblique zone below. It becomes possible to use it as a relay station antenna.

According to the antenna device of the present invention, it is possible to suppress interference with the antenna mounting post to eliminate the dead direction, and at the same time, by an easy suppression means for suppressing fluctuations in the antenna directivity pattern under the influence of the feeder or the radome, and the influence of the reflector and the radome. An antenna device with easy improvement means for improving VSWR deterioration is possible. This has the advantage that it is possible to provide an antenna device that can be used as a small area base station antenna and a relay station antenna.

Claims (6)

A sleeve antenna coupled to the coaxial line and composed of a center conductor and a sleeve, With a conical reflector, Arranging the sleeve antenna on the conical yaw side such that the center conductor coincides with the central axis of the cone shape and the tip of the center conductor is spaced apart from the top of the cone shape; And an interference suppression disk for suppressing interference of radio waves on the coaxial line side of the sleeve antenna along the central axis of the conical shape. The method of claim 1, And an impedance matching disk is provided in the center conductor of the sleeve antenna along the central axis of the cone shape. delete The method according to any one of claims 1 to 2, A conical resin radome is provided, the conical bottom of the reflector and the conical bottom of the radome are brought into close contact with each other to form an accommodating space, and the sleeve antenna is accommodated in the accommodating space. The method according to any one of claims 1 to 2, An antenna device, characterized in that a cylindrical radome having a conical top surface is disposed, the reflector is disposed on the upper surface of the radome, and the sleeve antenna is accommodated in the cylinder. The method according to any one of claims 1 to 2, The reflector is an antenna device, characterized in that consisting of a metal plate, a metal mesh or a metal covering the dielectric.

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