JP2012142879A - Sector antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sector antenna which is capable of suppressing radiation of interference waves to a cover area of another sector antenna while maintaining a predetermined beam width.SOLUTION: The sector antenna comprises: a pair of dipole feeding elements 11 arranged in parallel at an interval on a plane A; a reflective plate 12 which has a reflecting surface R parallel to the plane A and reflects radio waves radiated from the pair of dipole feeding elements 11; and a pair of first passive elements 13 which are arranged in parallel on the same plane B parallel to the plane A so as to sandwich the pair of dipole feeding elements 11 between themselves and the reflective plate 12 and are separated from each other at an interval narrower than that between the pair of dipole feeding elements 11.

Description

  The present invention relates to a sector antenna that radiates vertically polarized waves in a cover area of a predetermined angle.

  An antenna in a radio communication base station or the like is configured to be able to perform radio communication over 360 degrees in all directions by combining a plurality of sector antennas that radiate vertically polarized waves in a cover area of a predetermined angle.

  As shown in FIGS. 5A and 5B, the sector antenna 50 includes a pair of dipole feeding elements 51 arranged in parallel on the plane A with a space therebetween, and a reflecting surface R parallel to the plane A. And a reflecting plate 52 that reflects radio waves radiated from the pair of dipole power feeding elements 51.

  For example, in the case of a three-sector configuration (a cover area of 120 degrees per sector), the interval between the pair of dipole feed elements 51 is adjusted so that the beam width (full width at half maximum) is 70 degrees, and thus configured. The three sector antennas 50 are combined to form a communication area over all 360 degrees.

JP 2010-226196 A

  By the way, in recent wireless communication, multi-level modulation is used to speed up communication. Multi-level modulation requires a high CN ratio (Carrier to Noise ratio), and the sector antenna is required to suppress radiation (interference wave suppression) toward other sectors.

  In order to suppress the emission of interference waves to the cover areas of other sector antennas, it is effective to reduce the beam width, but this will reduce the cover area of each sector antenna.

  Accordingly, an object of the present invention is to provide a sector antenna that can suppress the emission of interference waves to the cover area of another sector antenna while maintaining a predetermined beam width.

  In order to achieve this object, the present invention has a pair of dipole feeding elements arranged parallel to each other at a distance on a plane, a reflecting surface parallel to the plane, and the pair of dipoles. A reflector that reflects radio waves radiated from the feed element, and the pair of dipole feed elements are arranged so as to be sandwiched between the reflector and arranged in parallel on the same plane parallel to the plane; A sector antenna including a pair of first parasitic elements spaced apart by a smaller interval than the pair of dipole feed elements.

  The electrical length of the first parasitic element is preferably shorter than ½ wavelength with respect to the resonance frequency of the pair of dipole feeder elements.

  The electrical length of the first parasitic element is preferably 0.8 times or more of a half wavelength with respect to the resonant frequency of the pair of dipole feeder elements.

  A pair disposed between the pair of dipole feed elements and the reflector and disposed in parallel on the same plane parallel to the plane and spaced apart by a larger distance than the pair of dipole feed elements The second parasitic element may be further provided.

  The electrical length of the second parasitic element is preferably equal to ½ wavelength with respect to the wavelength of the resonance frequency of the pair of dipole feeder elements.

  The reflector is disposed so as to be sandwiched between the pair of second parasitic elements and is disposed in parallel on the same plane parallel to the plane, and is narrower than the pair of second parasitic elements. A pair of third parasitic elements spaced apart from each other may be further provided.

  The electrical length of the third parasitic element is preferably equal to ½ wavelength with respect to the wavelength of the resonance frequency of the pair of dipole feeder elements.

  According to the present invention, it is possible to suppress radiation of interference waves to the cover areas of other sector antennas while maintaining a predetermined beam width.

Is a diagram illustrating a sector antenna according to the present invention, (a) is a perspective view, (b) is a X ₁ -X ₁ cross-sectional view taken along line, (c) is a plan view. It is a figure which shows the example of a dimension of the sector antenna of FIG. (A), (b) is a figure explaining the effect of the sector antenna based on this invention. (A), (b) is a figure explaining the effect of the sector antenna based on this invention. Is a diagram showing a conventional sector antenna, which is (a) is a perspective view, (b) the X ₂ -X ₂ sectional view taken along line.

  The sector antenna according to the present invention includes at least a pair of dipole feed elements arranged in parallel on a plane at intervals, and a reflecting surface parallel to a plane on which the pair of dipole feed elements are arranged. A reflector that reflects radio waves radiated from the pair of dipole feed elements and a pair of dipole feed elements sandwiched between the reflectors and parallel to the plane on which the pair of dipole feed elements are placed And a pair of parasitic elements that are arranged in parallel on the same plane and spaced apart by a smaller distance than the pair of dipole feeding elements.

  The parasitic element is for suppressing the emission of interference waves to the cover areas of other sector antennas. The electrical length of the parasitic element is preferably shorter than ½ wavelength with respect to the resonant frequency wavelength of the pair of dipole feeder elements, and preferably shorter than ½ wavelength with respect to the resonant frequency wavelength of the pair of dipole feeder elements. The wavelength of the resonance frequency of the pair of dipole feed elements should be set to 0.8 times or more of the half wavelength, and more preferably, the wavelength of the resonance frequency of the pair of dipole feed elements is 0.5. It should be 9 times. By making the electrical length of the parasitic element shorter than half the wavelength of the resonance frequency of a pair of dipole feeding elements, the radiation directivity of the dipole feeding element is drawn to the parasitic element, and the cover of other sector antennas Interference wave radiation to the area can be suppressed.

  According to the sector antenna having such a structure, since the parasitic element that suppresses the radiation of the interference wave to the cover area of the other sector antenna is provided, the cover area of the other sector antenna is maintained while maintaining a predetermined beam width. It is possible to suppress the emission of interference waves.

  A preferred embodiment of the present invention based on this sector antenna will be described below with reference to the accompanying drawings. The parasitic element in the sector antenna described above corresponds to the first parasitic element in the embodiment described below.

1A and 1B are diagrams showing a sector antenna according to a preferred embodiment of the present invention, in which FIG. 1A is a perspective view, FIG. 1B is a cross-sectional view taken along line X ₁ -X ₁ , and FIG. It is.

  As shown in FIGS. 1 (a) and 1 (b), the sector antenna 10 according to the present embodiment includes a pair of dipole feed elements 11 arranged in parallel on the plane A with a space therebetween, The reflector 12 has parallel reflecting surfaces R, and is arranged so as to sandwich the pair of dipole feeders 11 between the reflector 12 and the reflector 12 that reflects radio waves radiated from the pair of dipole feeders 11. And a pair of first parasitic elements 13 arranged in parallel on the same plane B parallel to the plane A and spaced apart by a smaller distance than the pair of dipole feed elements 11, and a pair of dipole feed elements 11 A pair of second parasitic elements 14 disposed between the reflector 12 and parallel to the same plane C parallel to the plane A and spaced apart by a larger distance than the pair of dipole feed elements 11. And the reflecting plate 12 as a pair of second parasitic elements 1 And a pair of third parasitic elements arranged in parallel on the same plane D parallel to the plane A and spaced apart by a smaller distance than the pair of second parasitic elements 14. And an element 15.

  A pair of dipole feeding elements 11, a pair of first parasitic elements 13, a pair of second parasitic elements 14, and a pair of third parasitic elements 15 form one set. A plurality of sets (four sets in FIG. 1A) are arranged at predetermined intervals along the longitudinal direction.

  The dipole power feeding element 11 is a dipole antenna, and is provided with a power feeding portion 17 at the center of two rod-shaped radiating elements 16 arranged in a straight line. By supplying power to the power supply unit 17, vertically polarized waves having a predetermined wavelength are radiated from the two radiating elements 16.

  The reflector 12 is also referred to as a reflector, and reflects the radio wave radiated from the dipole feeding element 11 on the reflecting surface R to form the main radiation direction (the direction of the arrow 18 in FIG. 1B) in a predetermined direction. Is for.

  Both side portions 19 of the reflector 12 are bent toward the main radiation direction side so as to suppress the emission of interference waves to the cover areas of other sector antennas, and the radio waves radiated from the dipole feed element 11 are reflected by the reflector 12. It is comprised so that it may suppress going around to the surface (back surface) opposite to the reflective surface R.

  As described above, the first parasitic element 13 is for suppressing the emission of interference waves to the cover areas of other sector antennas, and its electrical length is the resonance frequency of the pair of dipole feeder elements 11. The wavelength of the resonance frequency of the pair of dipole feed elements 11 is preferably shorter than the half wavelength. The wavelength is preferably 0.8 times or more, more preferably 0.9 times half the wavelength of the resonance frequency of the pair of dipole feed elements 11.

  The second parasitic element 14 is for forming a null point in the cover area of the other sector antenna in order to reduce the influence of the other sector antenna on the radio wave radiated. The electrical length of the second parasitic element 14 is preferably equal to ½ wavelength with respect to the wavelength of the resonance frequency of the pair of dipole feeder elements 11. Note that “null” in the present specification is not limited to the case where the radiation gain is zero, but means that the radiation gain is made as small as possible.

  The third parasitic element 15 is for suppressing the radio wave radiated from the dipole feeding element 11 from entering the back surface of the reflector 12. The electrical length of the third parasitic element 15 is preferably equal to ½ wavelength with respect to the wavelength of the resonance frequency of the pair of dipole feed elements 11.

  These dipole feeding element 11, first parasitic element 13, second parasitic element 14, and third parasitic element 15 are supported by an insulating resin or the like (not shown). As shown in FIG. Arranged so that the centers are aligned.

  As shown in FIG. 1B, the sector antenna 10 is accommodated in a cylindrical radome 20 having a circular cross section and is installed in a radio communication base station or the like.

  Here, an example of a preferable dimension of the sector antenna 10 will be described. Here, the dimensions when the operating frequency is 860 MHz will be described.

  The sector antenna 10 is formed symmetrically with respect to the center line O as a boundary. The dipole feed element 11 is arranged such that the distance from the center line O is 67 mm and the distance from the reflector 12 is 58 mm.

  The reflector 12 is formed with a width of 184 mm and a height of both side portions 19 of 5 mm. The longer the reflector 12 is, the better.

  The first parasitic element 13 is arranged such that the distance from the center line O is 53 mm and the distance from the reflector 12 is 82 mm. The length of the first parasitic element 13 is 148 mm.

  The second parasitic element 14 is disposed such that the distance from the center line O is 92 mm (184 mm / 2) and the distance from the reflector 12 is 10 mm. The length of the second parasitic element 14 is 166 mm.

  The third parasitic element 15 is arranged such that the distance from the center line O is 75 mm and the distance from the reflector 12 is 41 mm. The length of the third parasitic element 15 is 166 mm.

  The sector antenna 10 of this size radiates vertically polarized waves in a 120-degree cover area.

  Next, the operation of the present invention will be described.

  Using various sector antennas, the normalized radiation gain was evaluated by setting the main radiation direction to 0 degree. Here, the normalized radiation gain is a radiation gain normalized by setting the radiation gain in the main radiation direction of various sector antennas to 0 dB.

  As shown in FIG. 3 (a), the conventional sector antenna 50, the sector antenna 10 of the present embodiment, the second parasitic element 14 and the third parasitic antenna 50, which are configured to have a cover area of 120 degrees. Evaluation was performed using a device without the parasitic element 15 and a device without the third parasitic element 15 from the sector antenna 10. The result is shown in FIG.

  As can be seen from FIG. 3B, by adding the first to third parasitic elements 13, 14, and 15 to the configuration of the conventional sector antenna 50, the cover area of other sector antennas, that is, the non-cover area. It is possible to suppress the emission of interference waves.

  In the configuration in which the first parasitic element 13 is added, the radiation gain in the non-cover area is greatly reduced while maintaining a predetermined beam width. In addition, in the configuration in which the second and third parasitic elements 14 and 15 are added, the radiation gain in the main radiation direction (the direction of −120 degrees and 120 degrees) of the sector antenna covering the non-covered area is greatly reduced. .

  Further, when the electric field strength distributions of the conventional sector antenna 50 and the sector antenna 10 according to the present embodiment are examined by calculation, as shown in FIG. 4A, in the conventional sector antenna 50, both sides of the reflector 52 are provided. However, as shown in FIG. 4B, in the sector antenna 10 according to the present embodiment, the electric field wrap from the both side portions 19 of the reflector 12 to the back side is suppressed. It had been. This means that in the sector antenna 10 according to the present embodiment, the emission of interference waves to other sectors is suppressed compared to the conventional sector antenna 50.

  As can be seen from the above results, according to the sector antenna of the present invention, it is possible to suppress the emission of interference waves to the cover areas of other sector antennas while maintaining a predetermined beam width.

  Further, in the sector antenna of the present invention, the arrangement interval between the feeding elements or the non-feeding elements becomes narrower as it is arranged at a position farther from the reflector, so that it is accommodated in a cylindrical radome having a circular cross section. In this case, a radome having a small diameter can be used, and the secondary effect of downsizing the sector antenna can be obtained.

DESCRIPTION OF SYMBOLS 10 Sector antenna 11 Dipole feed element 12 Reflector 13 First parasitic element 14 Second parasitic element 15 Third parasitic element 16 Radiation element 17 Feed part 18 Arrow 19 indicating main radiation direction Both sides 20 of reflector , B, C, D Plane R Reflective surface O Center line

Claims (7)

A pair of dipole feed elements arranged in parallel on the plane and spaced apart from each other;
A reflecting plate having a reflecting surface parallel to the plane and reflecting radio waves radiated from the pair of dipole feeding elements;
The pair of dipole feed elements are arranged so as to be sandwiched between the reflecting plates, and are arranged in parallel on the same plane parallel to the plane, and are spaced apart by a narrower distance than the pair of dipole feed elements. A pair of first parasitic elements;
A sector antenna comprising:   2. The sector antenna according to claim 1, wherein an electrical length of the first parasitic element is shorter than a half wavelength with respect to a wavelength of a resonance frequency of the pair of dipole feeding elements.   3. The sector antenna according to claim 2, wherein an electrical length of the first parasitic element is set to 0.8 times or more of a half wavelength with respect to a wavelength of a resonance frequency of the pair of dipole feeding elements.   A pair disposed between the pair of dipole feed elements and the reflector and disposed in parallel on the same plane parallel to the plane and spaced apart by a larger distance than the pair of dipole feed elements The sector antenna according to claim 1, further comprising a second parasitic element.   5. The sector antenna according to claim 4, wherein an electrical length of the second parasitic element is equal to a half wavelength with respect to a wavelength of a resonance frequency of the pair of dipole feeder elements.   The reflector is disposed so as to be sandwiched between the pair of second parasitic elements and is disposed in parallel on the same plane parallel to the plane, and is narrower than the pair of second parasitic elements. The sector antenna according to claim 4 or 5, further comprising a pair of third parasitic elements spaced apart from each other.   The sector antenna according to claim 6, wherein an electrical length of the third parasitic element is equal to a half wavelength with respect to a wavelength of a resonance frequency of the pair of dipole feeder elements.