KR200140856Y1 - Antenna - Google Patents

Abstract

The present invention relates to an omnidirectional multi-antenna, the omni-directional multi-antenna which enables simultaneous transmission and reception with the same band antenna, and also replaces a plurality of antennas having different bands by one antenna In order to provide an omni-directional multiple antenna that suppresses mutual interference and pattern distortion between the antennas, the transmitting antenna units 6 and 8 and the receiving antenna unit 7 may be used to simultaneously transmit and receive without additional equipment in the same band. It consists of alternating vertical arrangement at intervals of one wavelength, and consists of vertical arrangement of multiple antenna units of different bands, but propagates due to mutual interference between antennas and antennas and scattering phenomena caused by crowding in tower space. In order to suppress deterioration of quality and distortion of the radiation pattern, the distance between the antenna units is 1 Improving the propagation quality of the sheets and configured such that it is possible to sufficiently secure the service area, there is an effect that it is possible to efficiently use a narrow space tower.

Description

Omnidirectional Multiple Antennas

1 is an exemplary view of a multiple antenna according to the present invention.

2 is another exemplary embodiment of a multiple antenna according to the present invention.

3 is a vertical polarization vertical pattern characteristic diagram of a multiple antenna according to the present invention.

* Explanation of symbols for main parts of the drawings

1: coaxial dipole 2: coaxial feeder

3: connector 4: impedance and mode converter

5: snow cover 6: first antenna

7: 2nd antenna 8: 3rd antenna

9: m antenna 10: mount pipe

11: 300 MHz antenna 12: 400 MHz antenna

13: 800 MHz antenna 14: 900 MHz antenna

The present invention is an omni-directional multi-antenna which enables simultaneous transmission and reception with the same band antenna and also replaces multiple antennas having different bands with one antenna to suppress mutual interference and pattern distortion between the antenna and the antenna. It is about.

The omnidirectional antenna currently in use only separates transmission and reception and uses only a certain frequency band, and other expensive equipment (Combiners, Duplexers, etc.) has to be used to transmit and receive simultaneously. In addition, because the antenna must be newly installed in order to operate different bands, the separation distance between the antennas becomes closer in a narrow tower structure. If many antennas are installed in such a narrow tower, there is a problem that the radio wave quality is reduced and the service area is reduced due to the distortion of the radiation pattern caused by scattering phenomenon caused by mutual interference between antennas and the narrow tower space. .

Accordingly, an object of the present invention is to provide an omni-directional multiple antenna capable of simultaneously transmitting and receiving in the same band without additional equipment in the same band.

In addition, the present invention has another object to provide an omni-directional multiple antenna that can be used for the communication of Ultra High Frequency (UHF), microwave (microwave) frequency band.

In addition, the present invention is to use a narrow tower space efficiently by configuring the antenna of several different bands as one antenna, and because the relatively small antenna is installed, the interference between the antenna and the antenna is significantly reduced omni-directional to enable high-quality wireless communication Another object is to provide multiple antennas.

In order to achieve the above object, the present invention provides an antenna in which multiple n-wavelength coaxial dipoles (n is a natural number) are arranged vertically at a 0.7-wavelength interval in a multiple antenna having a plurality of antenna units, and the coaxial dipole n Two coaxial dipoles adjacent to each other in the middle of two vertical arrays are inserted to have a single wavelength so that a transmission antenna unit and a receiving antenna unit having the same frequency band It is characterized by consisting of alternating vertical arrangement at intervals.

In addition, the present invention, in a multi-antenna having a plurality of antenna units, an antenna in which n 1/2 wavelength coaxial dipoles (n is a natural number) vertically arranged at 0.7 wavelength intervals, and in the middle of the n vertical arrangements of the coaxial dipoles. A plurality of antenna units of different bands are arranged vertically with an impedance and mode converter for inserting neighboring coaxial dipoles so as to have one wavelength and converting modes of radio waves and matching impedances. It is characterized by being configured to have one wavelength.

Hereinafter, with reference to the accompanying drawings will be described an embodiment according to the present invention;

1 is an exemplary view of a multi-antenna according to the present invention, 1 is a coaxial dipole, 2 is a coaxial feed line, 3 is a connector, 4 is an impedance and mode converter, 5 is a snow cover, 6 is a first antenna, 7 is The second antenna, 8 represents the third antenna, 9 represents the m antenna, and 10 represents the mount pipe.

As shown in the drawing, n 1 / 2-wavelength coaxial dipoles 1 (n is a natural number) are vertically arranged at a predetermined wavelength interval, and are positioned at the upper end to form a first antenna 6, and the first antenna ( The first coaxial feed line (2) is connected to each coaxial dipole (1) of 6), and the first connector (3) is attached to the lowest end of the first coaxial feed line (2).

N coaxial dipoles (1) are arranged vertically at regular wavelength intervals at regular intervals from the first antenna (6), and the second antenna (7) is formed by placing them in the center thereof, and the second antenna (7) The second coaxial feeder line 2 is connected to each coaxial dipole 1), and a second contactor 3 is attached to the lowermost end of the second coaxial feeder line 2.

Further, n coaxial dipoles (1) are vertically arranged at regular wavelength intervals at regular intervals from the second antenna (7), and the third antenna (8) is formed by placing them at the lower end portion, and the third antenna (8) A third coaxial feed line 2 is connected to each coaxial dipole 1 of (8), and a third connector 3 is attached to the lowest end of the third coaxial feed line 2.

In this manner, the nth coaxial dipoles (1) n are arranged vertically at regular wavelength intervals at regular intervals from the m-th antenna to form the m-th antenna (9), and the m-th antenna (9) The m-th coaxial feeder 2 is connected to each coaxial dipole 1 of M, and the m-th connector 3 is attached to the lowest end of the m-th coaxial feeder 2.

On the other hand, in the configuration of the antenna by the vertical arrangement of the dipole, the impedance and the middle of the vertical arrangement with respect to each of the first antenna (6), the second antenna (7), the third antenna (8) and the m-th antenna (9) A mode converter 4 is inserted to change the mode of propagation and match the impedance so as not to affect the transmission and reception of each antenna.

The coaxial dipoles 1 on both axes with the impedance and mode converter 4 interposed therebetween maintain a constant one-wavelength spacing for feeding in phase and coarse amplitude, and the coaxial dipoles adjacent to the coaxial dipoles 1 on both axes. (1) was spaced 0.7 wavelengths in order to reduce sidelobe and improve beam synthesis.

High frequency (RF) energy through the connector (3) connected to each transmitter is fed to each transmitting antenna through the coaxial feed line (2) to radiate in free space, and each antenna has one wavelength to suppress mutual interference as much as possible. The second antennas 7 are disposed between the first antennas and the third antennas 6 and 8 in order to increase the isolation between transmissions, but are arranged at one wavelength interval without affecting each other.

In addition, the first to fourth antennas 6, 7, 8, and 9 have a snow cover to protect the coaxial dipole 1, the coaxial feed line 2, and the feed point portion from an external environment such as rain or snow. Surrounded by (5), a mount pipe 10 was attached to the connector 3 side of the antenna to facilitate installation of the antenna.

Thus, the transmitting antenna, the receiving antenna, and the transmitting antenna were arranged at a predetermined wavelength interval to constitute one multiple antenna.

2 is another exemplary embodiment of the multiple antenna according to the present invention, 11 is a 300MHz antenna, 12 is a 400MHz antenna, 13 is an 800MHz antenna, 14 is a 900MHz antenna, respectively.

As shown in the figure, n 1 / 2-wavelength coaxial dipoles (1) are arranged vertically at a predetermined wavelength interval, and placed at the upper end to form a 300 MHz band antenna 11, and each coaxial of the 300 MHz band antenna 11 The first coaxial feed line 2 is connected to the dipole 1, and the first connector 3 is attached to the lowest end of the first coaxial feed line 2.

The n coaxial dipoles 1 are vertically arranged at regular wavelength intervals at regular intervals from the 300 MHz band antenna 11, and are positioned at the center to form the 400 MHz band antenna 12, and the 400 MHz band antenna 7 The second coaxial feed line (2) is connected to each coaxial dipole (1), and a second connector (3) is attached to the lowest end of the second coaxial feed line (2).

Further, n coaxial dipoles (1) are vertically arranged at regular wavelength intervals at regular intervals from the 400 MHz band antenna 12, and placed at the lower end thereof to form an 800 MHz band antenna 13, and the 800 MHz band antenna A third coaxial feed line 2 is connected to each coaxial dipole 1 of (13), and a third connector 3 is attached to the lowest end of the third coaxial feed line 2.

In this method, n coaxial dipoles (1) are vertically arranged at regular wavelength intervals at regular intervals from the front end antenna, and are positioned at the lowermost portion to form the 900 MHz band antenna 14, and the 900 MHz band antenna 9 An m-th coaxial feeder line 2 is connected to each coaxial dipole 1, and an m-th connector 3 is attached to a lowermost end of the m-th coaxial feeder line 2 to form an antenna having different bands.

The 800 MHz band antenna 13 arranges n 1 / 2-wavelength coaxial dipoles 1 at 0.7 wavelength intervals, and a half-wavelength coaxial dipole 1 having an impedance and mode converter 4 interposed therebetween. Spaced. This is for the mode converted by the impedance and mode converter 4 to be supplied in the same amplitude and phase to each coaxial dipole 1. Each of the coaxial dipoles 1 having a 0.7 wavelength spacing is for the reduction of the first sidelobe in the vertical plane and for optimal beam synthesis.

Since 300, 400, 800, and 900 MHz antennas (11, 12, 13, 14) have different wavelengths according to their respective frequencies, the separation distance between the antennas and the antennas is 300 MHz, 400 MHz, and 400 MHz. And the gap between the 800MHz antenna is different. Therefore, the separation distance between each antenna was set to 1 wavelength with an isolation of about 30dB.

3 is a vertical polarization vertical pattern characteristic diagram of a multi-antenna according to the present invention, and FIG. 3a is a characteristic diagram of a 300 MHz and 400 MHz band antenna, and FIG. 3b is a characteristic diagram of an 800 MHz band antenna. As shown in the figure, the first side lobe was less than 12 dB.

As the present invention as described above, a relatively small antenna is installed, interference and pattern distortion between the antenna and the antenna can be suppressed to improve the radio wave quality, sufficient service area can be secured, and multiple band antennas are composed of one antenna. Therefore, there is an effect that can effectively use the narrow pylon space.

Claims (4)

2. The antenna of claim 1, wherein an antenna in which n 1 / 2-wavelength coaxial dipoles (n is a natural number) is arranged vertically at a 0.7-wavelength interval, and both coaxial dipoles adjacent to each other in the middle of the n vertical arrays of the coaxial dipoles are inserted into one wavelength. An impedance and mode converter for converting a radio wave mode and matching an impedance, and omitting omnidirectional transmission antenna unit and receiving antenna unit having the same frequency band by alternately vertically arranging each wavelength Multiple antennas. A plurality of feed lines connected to the plurality of antenna units in a one-to-one correspondence and supplying energy to each of the coaxial dipoles; A plurality of connectors connected to the feeder at one end thereof in a one-to-one correspondence; A snow cover that surrounds the antenna outer periphery to protect the coaxial dipole, feed line, and feed point portion from an external environment such as rain or snow; And a mount pipe attached to the connector side to facilitate installation of the antenna. The omni-directional multiple antenna according to claim 1 or 2, wherein the antenna unit is arranged vertically in three antennas as a transmitting antenna, a receiving antenna, and a transmitting antenna. The antenna is arranged by vertically arranging n 1 / 2-wavelength coaxial dipoles (n is a natural number) at 0.7-wavelength intervals, and the two coaxial dipoles adjacent to each other in the middle of the n vertical arrays of the coaxial dipoles are inserted into one wavelength to change the mode of propagation. And an antenna having an impedance and a mode converter for matching impedance and vertically arranging a plurality of antenna units having different bands, wherein the spacing between the antenna units is one wavelength.