KR200334060Y1 - Vertical polarization omnidirectional antenna and horizontal polarization omnidirectional antenna using dielectric board - Google Patents

Abstract

The present invention relates to an omni directional antenna used in a mobile communication base station (TRS, CELLULAR, PCS, IMT-2000, ISM-Band).

In the present invention, after forming a pattern of a patch antenna on the front surface of a dielectric substrate having a metal film, it is rolled up to form a sleeve-like dipole to implement a vertical or horizontal polarized omnidirectional antenna.

The vertical or horizontal polarized omnidirectional antenna according to the present invention can minimize the characteristics of the upper side lobe, which is the cause of interference between adjacent base stations, and also because the antenna pattern is formed on the dielectric substrate, the antenna has uniform characteristics by simplifying the fabrication process. It is possible to mass-produce, and there is an effect that the antenna can be reduced in size and light weight.

Description

VERTICAL POLARIZATION OMNIDIRECTIONAL ANTENNA AND HORIZONTAL POLARIZATION OMNIDIRECTIONAL ANTENNA USING DIELECTRIC BOARD}

The present invention relates to an antenna technology used in mobile communication base stations (TRS, CELLULAR, PCS, IMT-2000, ISM-Band).

Signals transmitted from conventional mobile communication base stations and terminals cause many modifications due to the buildings in the city center and the surrounding environment. These altered signals directly affect the call quality. This problem is often referred to as a fading phenomenon, and its root cause may be a problem in propagation path.

Diversity is mainly used for the purpose of solving fading by multipath. Diversity technique is a method to solve the fading phenomenon by receiving and properly combining a plurality of signals affected by the fading independently of each other. There are various types of diversity techniques, but the representative ones are the spatial diversity technique and the polarization diversity technique. In the present invention, the fading phenomenon is solved by using both.

FIG. 1 is an embodiment of a vertically polarized omnidirectional antenna for a repeater, which has been used in the related art.

2A is a front view of a vertical polarized omnidirectional antenna for a repeater using a dielectric substrate, and FIG. 2B is a side view of a vertical polarized omnidirectional antenna for a repeater using a dielectric substrate. Antenna as shown in the figure is manufactured in a structure that can not be arranged vertically even using a dielectric circuit board.

3 is a cross-sectional view of a vertically polarized omnidirectional antenna for a base station, which is conventionally used. The antenna is manufactured by processing a metal material such as copper or aluminum, and then connecting a plurality of radiating elements to a feed line to form a radiating element and a feeding part. The lower the frequency, the larger the size of the radiating element, so the weight of the antenna increases, and the higher the frequency, the smaller the size of the radiating element, which is inconvenient to be precisely processed. In addition, since the assembly of the radiating element must be all performed manually, there is a problem that the antenna characteristics are not uniform because productivity is decreased because the assembly takes a lot of time, and the product is produced by hand.

The present invention has been made to solve the above-mentioned problems, and the production process is simplified, mass production of antennas with uniform characteristics, small size and light weight of the antennas, fading using spatial diversity technique and polarization diversity technique The purpose is to improve the call quality by solving the phenomenon.

Figure 1 is an embodiment of a vertically polarized omnidirectional antenna for a repeater used in the prior art.

2A is a front view of a vertically polarized omnidirectional antenna for a repeater using a conventional dielectric substrate.

Figure 2b is a side view of a vertically polarized omnidirectional antenna for a repeater using a conventional dielectric substrate.

3 is a cross-sectional view of a vertically polarized omnidirectional antenna for a base station that has been conventionally used.

Figure 4 is a development of a vertically polarized omnidirectional antenna using a dielectric substrate according to the present invention.

5 is a diagram illustrating a process of rounding a vertically polarized omnidirectional antenna using a dielectric substrate.

6 is a side view of a vertical, horizontally polarized omnidirectional antenna using a dielectric substrate.

7 is an exploded view of a horizontally polarized omnidirectional antenna using a dielectric substrate.

8 is a diagram illustrating a process of rounding a horizontally polarized omnidirectional antenna using a dielectric substrate.

9 is a view showing the standing wave ratio of the vertically polarized omnidirectional antenna using a dielectric substrate according to the present invention.

10 is a view showing the standing wave ratio of the horizontally polarized omnidirectional antenna using a dielectric substrate according to the present invention.

11 is a view showing a radiation pattern of a vertically polarized omnidirectional antenna using a dielectric substrate according to the present invention.

12 is a view showing a radiation pattern of a horizontally polarized omnidirectional antenna using a dielectric substrate according to the present invention.

(Explanation of symbols for the main parts of the drawing)

10: radiating element formed on the dielectric substrate 20: dielectric substrate

30: microstrip transmission line 31: input impedance (50Ω)

32,36: impedance matching unit 33,34: power distribution unit

35: transformer (0.25λ) 40: cable

50: feed connector 60: snow cover (radome)

70: radiating element support pipe 80: styrofoam

90: antenna support pipe

The device of the present invention for achieving the above object is a radiation element unit for receiving an external signal generated from the terminal and propagating the signal generated from the base station equipment or repeater to free space, the transmission and output of the input and output signals, impedance matching and distribution role An antenna comprising a power supply unit for performing a function and an input / output connector for performing a function of inputting and outputting energy transmitted through the power supply unit to a base station equipment or a repeater, wherein the radiating element is a rectangular patch on a dielectric substrate having a metal film A dielectric formed in the antenna pattern and having a feed section at the bottom center of the square pattern to generate vertical polarization, wherein the feed section is formed by forming a wiring circuit on the dielectric substrate, the dielectric having the radiating element section and the feed section formed thereon The board is rolled up to form a cylindrical shape A vertically polarized wave non-directional antenna using a dielectric substrate, characterized by.

On the other hand, the antenna includes a radiating element support pipe for supporting the radiating element portion, an antenna supporting pipe for supporting the radiating element supporting pipe and the input / output connector, and a snow cover that protects the radiating element portion and the feeding part and is connected to the antenna supporting pipe. The radiating element support pipe is installed at a central portion of the cylindrical antenna, and a styrofoam is attached to the outside of the radiating element support pipe, and a dielectric substrate having the radiating element is attached to the outside of the styrofoam. The antifog cover is installed outside the dielectric substrate.

Another apparatus of the present invention for achieving the above object is a radiating element unit for receiving an external signal generated from a terminal and propagating a signal generated from a base station equipment or a repeater to free space, transmission and output of the input and output signals, impedance matching and distribution An antenna comprising a feeding part serving as a role and an input / output connector configured to input and output energy transmitted through the feeding part to a base station equipment or a repeater, wherein the radiating element part has a rectangular shape on a dielectric substrate having a metal film. A patch antenna pattern is formed, and a horizontally polarized wave is generated by placing a feeder at a center of one side of the rectangular pattern. The feeder is formed by forming a wiring circuit on the dielectric substrate. Round the formed dielectric substrate to form a cylindrical shape A horizontal polarized wave non-directional antenna using a dielectric substrate, characterized in that the rock.

On the other hand, the antenna includes a radiating element support pipe for supporting the radiating element portion, an antenna supporting pipe for supporting the radiating element supporting pipe and the input / output connector, and a snow cover that protects the radiating element portion and the feeding part and is connected to the antenna supporting pipe. The radiating element support pipe may be installed at a central portion of the cylindrical antenna, and a styrofoam may be attached to the outside of the radiating element support pipe, and a dielectric substrate having the radiating element may be attached to the outside of the styrofoam. The anti-fog cover is installed outside the dielectric substrate.

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

4 is an exploded view of a vertically polarized omnidirectional antenna using a dielectric substrate according to the present invention, and FIG. 5 is a diagram illustrating a process of rounding a vertically polarized omnidirectional antenna using a dielectric substrate. The energy transmitted through the feed connector 50, which is an input / output terminal, is connected to the micro stripline 30 through the transmission cable 40. The feed connector 50, which is an input / output terminal, and the micro stripline 30, which is a transmission line, The feed connector 50, which is connected to a flexible cable and is an input / output terminal, is installed by processing both surfaces of the antenna support pipe 90. The energy input to the micro stripline 30 is applied to the characteristic impedance 50? 31, and the applied energy is input to the primary matching circuit 32. Lines 33 and 34 distribute the input energy, of which only 33 / n of the total radiating element is applied to line 33, and the remaining (n-1) / n energy is the secondary of the next radiating element. Is applied to the matching circuit. The applied power and phase is determined by the designer's design dimensions. Therefore, the problem that the designer could not design arbitrarily in the arrangement by the proximity electric field, which is one of the most commonly used power feeding methods in the conventional vertically polarized omnidirectional antenna has been improved.

7 is an exploded view of a horizontally polarized omnidirectional antenna using a dielectric substrate, and FIG. 8 is a diagram illustrating a process of rolling a horizontally polarized omnidirectional antenna using a dielectric substrate. The configuration of the horizontally polarized omnidirectional antenna is the same as that of the above-described vertically polarized omnidirectional antenna except that the feeding portion of the antenna is 90 ° different from that of the vertically polarized wave.

6 is a cross-sectional view of a vertical and horizontal polarized omnidirectional antenna using a dielectric substrate. Referring to FIG. 6, a styrofoam 80 is installed outside the radiating element support pipe 70 in which the radiating element support pipe 70 is installed at the center portion. The radiating element support pipe 70 and the styrofoam 80 are fixed using acrylic double-sided tape. Fixing the radiating element on the outside of the styrofoam 80 using the acrylic double-sided tape in the same way, using the anti-fog cover 60 outside the radiating element to protect the internal circuit from external force. Radiating element support pipe is connected to the antenna support pipe, the snow cover 60 is also connected to the antenna support pipe (90).

9 shows the standing wave ratio of the vertically polarized omnidirectional antenna using the dielectric substrate according to the present invention, and FIG. 10 shows the standing wave ratio of the horizontally polarized omnidirectional antenna using the dielectric substrate according to the present invention. As shown in the figure, since the standing wave ratio value does not exceed 1.5 in the measurement frequency range, the performance of the antenna will be relatively good. When the standing wave ratio is 1.5, about 96% of the output is radiated.

11 illustrates a radiation pattern of a vertically polarized omnidirectional antenna using a dielectric substrate according to the present invention, and FIG. 12 illustrates a radiation pattern of a horizontally polarized omnidirectional antenna using a dielectric substrate according to the present invention.

The present invention is not limited to the embodiments described above, it can be variously modified and changed by those skilled in the art, which is included in the spirit and scope of the present invention defined in the appended claims.

By using the vertically polarized omnidirectional antenna and the horizontally polarized omnidirectional antenna using the dielectric substrate according to the present invention, the call quality can be improved by solving the fading phenomenon, and the production process can simplify the production process and mass produce the antenna having uniform characteristics. It can reduce the size and weight of the antenna.

Claims (4)

A radiating element unit for receiving an external signal generated from a terminal and propagating a signal generated from a base station equipment or a repeater to a free space; A power supply unit for transmitting / outputting an input / output signal, impedance matching, and distribution; And In the antenna configured to include an input and output connector for performing a function for inputting and outputting the energy transmitted through the feeder to the base station equipment or repeater, The radiating element portion is configured to form a vertical patch antenna pattern on the dielectric substrate having a metal film, and then to generate a vertical polarization by placing a feed position at the bottom or top center of the rectangular pattern, The feeding part is formed by forming a wiring circuit on the dielectric substrate, Vertically polarized omnidirectional antenna using a dielectric substrate, characterized in that to form a cylindrical shape by rolling the dielectric substrate formed with the radiating element portion and the feed portion round. The method of claim 1, Radiating element support pipe for supporting the radiating element portion; An antenna support clamp for supporting the radiating element support pipe and the input / output connector; And Further comprising a snow cover that protects the radiating element and the feeder and is connected to the antenna support clamp, The radiating element support pipe is installed at the central portion of the cylindrical antenna, styrofoam is attached to the outside of the radiating element support pipe, and a dielectric substrate having the radiating element is attached to the outside of the styrofoam is attached to the outside of the dielectric substrate. Vertical polarized omnidirectional antenna using a dielectric substrate, characterized in that the cover is installed. A radiating element unit for receiving an external signal generated from a terminal and propagating a signal generated from a base station equipment or a repeater to a free space; A power supply unit for transmitting / outputting an input / output signal, impedance matching, and distribution; And In the antenna configured to include an input and output connector for performing a function for inputting and outputting the energy transmitted through the feeder to the base station equipment or repeater, The radiating element part is configured to form a rectangular patch antenna pattern on the dielectric substrate having a metal film, and to generate a horizontal polarization by placing a feeder in the center of one side of the rectangular pattern, The feeding part is formed by forming a wiring circuit on the dielectric substrate, A horizontally polarized omnidirectional antenna using a dielectric substrate, wherein the dielectric substrate on which the radiating element portion and the feeding portion are formed is rolled round to form a cylindrical shape. The method of claim 1, Radiating element support pipe for supporting the radiating element portion; An antenna support pipe supporting the radiating element support pipe and the input / output connector; And Further comprising a snow cover that protects the radiating element and the feeder and is connected to the antenna support clamp, The radiating element support pipe is installed at the central portion of the cylindrical antenna, styrofoam is attached to the outside of the radiating element support pipe, and a dielectric substrate having the radiating element is attached to the outside of the styrofoam is attached to the outside of the dielectric substrate. Horizontally polarized omnidirectional antenna using a dielectric substrate, characterized in that the cover is installed.