JP2001358639A - Sector antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sector antenna which can reduce interference to an adjacent sector, and restrain the decrease of effective gain of an antenna. SOLUTION: A required antenna pattern of the sector antenna is g(θ), which is obtained assuming that an arrival radio wave from a mobile station to the sector antenna has no spread in the radio wave. A spread pattern of radio wave is ρ(θ), when the radio wave arrives from the mobile station. And when the pattern of the sector antenna is f(θ). In this case, f(θ) satisfying g(θ)=f(θ)*ρ(θ) (χ: convolution) is found and is set as the antenna pattern of the sector antenna.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sector antenna used for mobile communication.

[0002]

2. Description of the Related Art As a method of forming a service area for mobile communication, a circular cell can be covered by installing an omnidirectional antenna at the center of the circle. Further, in order to increase the frequency use efficiency, a sector sector configuration in which a circular cell is divided into a plurality of sector areas is used.
In this case, an antenna pattern having a width corresponding to the angle of the sector is used so as to cover the sector of the sector. If an extremely wide antenna pattern is used, radio waves reach adjacent sectors and cause interference, and strong radio waves cannot be transmitted to the own sector, which is not desirable.

FIG. 1 shows an area formed by sectors and sector antennas. 10 is a circular cell, 11a, 11b, 11c is a sector, 1
2a, 12b, and 12c indicate sector antennas, and 13a indicates an area covered by the antenna 12a. FIG. 2 shows a required antenna pattern of the antenna 12a. The area 13a covers the sector 11a, and it is necessary to minimize the amount of radio wave protruding from the sector 11a. Adjust the antenna pattern to sector 13 in area 13a
It is physically possible to match the shape of 1a, but there is a disadvantage that the antenna becomes large. Therefore, conventionally, a pattern is used in which the antenna gain in the direction of 60 degrees and -60 degrees at the edge of the area becomes half (-3 dB) of the peak value.

[0004] The conventional method of determining the sector antenna pattern is based on the assumption that the antenna pattern of the antenna is stored in an actual city. Preserving the antenna pattern means that the antenna pattern is projected onto the city without changing the shape of the antenna pattern radiated from the position of the steel tower or the like toward the city. This corresponds to a case where radio wave radiation is regarded as light radiation and treated geometrically. However, since the radio waves are reflected and scattered by buildings in the city, the antenna pattern is not accurately stored. Therefore, the antenna pattern is scattered in the city and the projected pattern is diffused. Considering the case where a sharp and easy-to-understand beam is radiated in the city, the pattern projected on the city is diffused and larger than the beam diameter.

[0005] Considering the above in reverse, radio waves radiated from the mobile station are scattered in the streets around the mobile station, and when the radio waves arriving from the base station side are viewed, they have a spatial spread rather than a single line. Looks like a bunch of radio waves. This spread is described in Document 1 ("Mobile Communication", edited by Masaaki Shinshi, published by Maruzen Co., Ltd., pp. 199-202) and Document 2 ("Correlation Coefficient of Base Station Diversity in Land Mobile Communication", IEICE Transactions, B Vol. .J70-B No.4 Published April 1987 PP.476-48
The angle of arrival is shown in 2). The standard deviation of the radio wave arrival spread pattern is the radio wave arrival angle. The angle of arrival of the radio wave is 1 to 2 degrees when the mobile station is at a distance of about 5 km. Also, when the mobile station is in the vicinity of about 500 m, the angle of arrival of radio waves is expected to be as large as about 10 degrees. (For example,
When the reflection / scattering range is considered to be a circle having a constant radius, the angle of arrival of a radio wave decreases when the mobile station is far away, but increases when the mobile station is close. Conventionally, the radius of the cell is 5 to 10 km and the number of sectors is about 3. Therefore, if the radio wave arrival angle is 1 to 2 degrees with respect to the sector angle of 120 degrees, it is difficult to determine the pattern of the sector antenna. The size was negligible. However, in recent years, in order to increase the subscriber capacity of mobile communications, the cell radius has been increased.
It is conceivable that the angle is reduced to about 500 m and the angle of the sector is further reduced (for example, about 30 degrees). In such a situation, an optimal pattern cannot be obtained by the conventional antenna pattern determination method that does not consider the radio wave arrival angle (that is,
Radio waves are radiated to adjacent sectors).

[0006]

As described above, conventionally, when determining the antenna pattern of a sector antenna, the spread of radio waves has not been taken into consideration. Also, it was not clear how to determine the pattern in consideration of the spread of radio waves. An object of the present invention is to determine an antenna pattern of a sector antenna which is optimal in an actual use environment in consideration of the spread of radio waves, and to provide a sector antenna having this antenna pattern.

[0007]

According to the present invention, the above objects are achieved by providing the arrangements set forth in the appended claims. The invention according to claim 1 is characterized in that when a required sector antenna pattern obtained without considering the arrival spread of radio waves is g (θ, φ) and an average spread pattern of radio waves is ρ (θ, φ), g An antenna pattern f (θ, φ) is calculated based on (θ, φ) and ρ (θ, φ), and used as a sector antenna pattern.

According to a second aspect of the present invention, in the first aspect of the invention, the required sector antenna pattern obtained without considering the spread of radio waves is g (θ, φ), Is ρ (θ, φ) and the actual antenna pattern is f (θ, φ), so that the convolution of f (θ, φ) and ρ (θ, φ) becomes g (θ, φ). The antenna pattern f (θ, φ) is used as a sector antenna pattern.

According to a third aspect of the present invention, in the second aspect of the present invention, the antenna pattern f (θ) is obtained by considering the spread of radio waves by considering only the horizontal pattern or only the vertical pattern. Find f (φ). For example,
When only the horizontal direction is targeted, g (θ) = f (θ) * ρ
(θ), or g (φ)
= F (φ) * ρ (φ) antenna pattern f (θ),
Alternatively, f (φ) is used as a sector antenna pattern.

According to a fourth aspect of the present invention, in the first aspect of the present invention, the required sector antenna pattern g (θ) and the average radio wave arrival spread pattern ρ (θ ) Is represented by a normal distribution, and when the respective standard deviations are σ _g and σρ, the sector antenna pattern is a normal distribution function with a standard deviation σ _f = (σ _g ² −σρ ² ) ^1/2 . The invention according to claims 1 to 4 is characterized in that a pattern obtained by subtracting a radio wave arrival spread in advance in consideration of the fact that a radio wave arrival spread is convolved with an antenna pattern in an actual use environment is used. Different from the method.

[0011]

[Function] If an antenna pattern g (θ, φ) that does not consider the average radio wave arrival spread pattern ρ (θ, φ) is used, an actual antenna pattern in the city is a pattern g (θ, φ) to which ρ (θ, φ) is added. θ, φ) * ρ (θ, φ) (*: convolution)
Can be done. As a result, many radio waves serving as interference waves are radiated to the adjacent sector. Also, the antenna gain is reduced due to the spread of the antenna pattern. Therefore, the above problem can be avoided by using a pattern f (θ, φ) narrower than g (θ, φ) in consideration of the average radio wave spread pattern ρ (θ, φ).

In the CDMA system (code division multiple access system) as a radio access system, since the same frequency is used in each sector, radio waves radiated from other than the own sector become interference waves as they are. The present invention, which can reduce radio waves radiated to other sectors, is particularly effective in reducing interference waves in the CDMA system.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS For the sake of simplicity, a case where only horizontal patterns are targeted will be considered here. As shown in Reference 2, the average radio wave arrival spread pattern ρ (θ) can be measured from the correlation coefficient of the level received by two antennas separated by a certain distance. Literature 2 describes ρ when the average radio wave spread pattern ρ (θ) is assumed to be a normal distribution.
The standard deviation of (θ) is determined. In order to directly obtain the function form of the spread of radio waves, there is a method of measuring using a narrow beam.

FIG. 3 shows an example of an average radio wave spread pattern. The average radio wave arrival spread pattern 31 is also a probability density function,

[0015]

(Equation 1) Becomes FIG. 4 shows a required antenna pattern g (θ) that does not consider the spread of radio waves necessary to cover a sector and a sector antenna pattern f (θ) used in the present invention.
The required antenna pattern g (θ) is determined by the shape of the sector. The convolution operation symbol is *, the Fourier transform operation symbol is F (•), and the inverse Fourier transform operation symbol is F
^{If −1} (·), g (θ) = f (θ) * ρ (θ), so that f (θ) is obtained as follows.

F (θ) = F ^-1 [F (g (θ)) / F (ρ (θ))] A sector antenna is manufactured using the antenna pattern f (θ) obtained in this manner. In addition, the radio wave spread pattern ρ (θ) shown in FIG. 3 and the required antenna pattern g (θ) not considering the spread of the radio wave shown in FIG. To σ _g , σρ
When the antenna pattern f (θ) is defined as the standard deviation σ _f =
_Let (σ _g ² −σ ρ ² ) ^{1/2 be} a normal distribution function. (Example)
An embodiment of the present invention will be described with reference to FIG.

A specific description will be given with the following numerical values. The radio wave arrival spread pattern ρ (θ) has a normal distribution with a standard deviation σρ = 10 °. The radio wave arrival spread pattern ρ (θ) 41 is a normal distribution function that needs to cover a 30-degree sector and has a half-value angle of 30 degrees. The antenna pattern obtained in consideration of the spread of radio waves is f (θ) 42. By using the antenna pattern f (θ), a pattern of g (θ) 41 is actually formed.

If the antenna pattern of g (θ) is used without considering the spread of radio waves, g (θ) * ρ (θ) 43 is actually used.
Antenna pattern. The antenna gain of g (θ) is 2.1 dB higher than g (θ) * ρ (θ). The amount of interference radiated outside the 30-degree sector is g (θ) * ρ (θ)
(θ) is reduced to 1 / 1.5. These improvement effects can be obtained by considering the spread of radio waves.

[0019]

According to the present invention, the antenna pattern of a sector antenna is narrowed in consideration of the spread of radio waves caused by radio wave scattering in a city where mobile communication is performed, whereby the amount of interference with adjacent sectors can be reduced, and the effective gain of the antenna is reduced. Can be prevented from being impaired. The present invention is effective in a microcell having a small cell radius since the radio wave arrival angle increases as the cell radius decreases, and is also effective when the sector angle is small. Further, a system using the same frequency in all sectors, such as the CDMA system, is particularly effective in reducing the amount of interference.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an area formed by a sector and a sector antenna.

FIG. 2 is a diagram showing a required antenna pattern covering a sector according to the related art.

FIG. 3 is a diagram showing a radio wave arrival spread pattern.

FIG. 4 is a diagram showing a required antenna pattern g (θ) and a sector antenna pattern f (θ) without considering the spread of radio waves.

FIG. 5 is a diagram showing each antenna pattern in the embodiment.

[Explanation of symbols]

10 Circular cell 11a, 11b, 11c Sector 12a, 12b, 12c Sector antenna 13a Area covered by antenna 12a 31 Radio wave arrival spread pattern 41 Required antenna pattern 42 Sector antenna pattern considering radio wave arrival spread 43 Radio wave arrival spread to required antenna pattern Antenna pattern with folded pattern

Claims (4)

[Claims] A service area is composed of a plurality of cells, each cell is further divided into a plurality of sectors, a base station is arranged in each sector, and a plurality of mobile stations and a sector in which these base stations communicate with each other. In the sector antenna used for the cellular mobile communication system by division, the sector antenna that communicates with the mobile station in the sector is obtained by assuming that the radio wave arriving from the mobile station does not spread the radio wave geometrically. Required antenna pattern
g (θ, φ) [θ is the angle in the horizontal direction, φ is the angle in the vertical direction], and the average spread pattern of radio waves when radio waves arrive from a mobile station is ρ (θ, φ) [θ Is the horizontal angle, φ is the vertical angle], and the antenna pattern f is calculated based on the required antenna pattern g (θ, φ) and the average radio wave spread pattern ρ (θ, φ). A sector antenna wherein (θ, φ) is obtained and used as a sector antenna pattern. 2. The sector antenna according to claim 1, wherein said antenna pattern f (θ, φ) and an average radio wave spread pattern ρ (θ, φ) are subjected to a convolution operation to obtain said required antenna pattern g ( A sector antenna characterized in that an antenna pattern f (θ, φ) when θ, φ) is obtained is used as a sector antenna pattern. 3. The sector antenna according to claim 2, wherein, when the antenna pattern f (θ, φ) is obtained, if only a horizontal antenna pattern is targeted, g (θ) = f (θ) ) * Ρ (θ) or g (φ) = f (φ) * ρ (φ) when only the antenna pattern in the vertical direction is targeted (however, “*” indicates convolution). The antenna pattern f (θ) or f (φ) that satisfies
A sector antenna used as a sector antenna pattern. 4. The sector antenna according to claim 1, wherein the required antenna pattern is g (θ, φ), g (θ), or g (φ).
And the average radio wave spread pattern ρ (θ, φ), ρ (θ) or ρ (φ) is represented by a normal distribution function, and when the respective standard deviations are σ _g and σρ, the antenna pattern f ( θ,
φ), f (θ) or f (φ) is standard deviation σ _f = (σ _g ² −σρ ² )
A sector antenna characterized by a normal distribution function of ^1/2 .