JPH0993036A - Vertical diversity antenna - Google Patents

Abstract

(57) [Abstract] [PROBLEMS] To realize a vertical diversity antenna that can be electrically matched and has no deterioration in radiation characteristics without increasing the antenna diameter (radome diameter). SOLUTION: The tip of a strip line 5 that feeds an antenna unit is branched, and one branched line 51 is provided.
Is connected to the antenna element, and the other line 52 is connected to the antenna element after being laid out in a U shape so as to be separated from the other strip line 4. The difference between the lengths of the two lines 51 and 52 is set to be an integral multiple of 360 ° when converted to the phase difference of feeding to the antenna element. [Effect] Since adverse effects due to electrical coupling between the strip line 5 feeding the antenna unit in the preceding stage and the strip line 4 feeding the antenna unit in the succeeding stage can be avoided, electrical matching can be achieved, and VSWR deterioration and radiation can be achieved. It is possible to realize a vertical diversity antenna without deterioration of characteristics.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vertical diversity antenna, and particularly, it has a relatively narrow frequency band used.
The present invention relates to a vertical diversity antenna which is used by independently feeding power to a multi-stage antenna unit.

[0002]

2. Description of the Related Art An antenna for a base station of a simple mobile phone is omnidirectional in a horizontal plane and has a vertical beam tilt of 0 °.
A vertical diversity antenna in which two independent antenna units (the beam direction in the vertical plane is the horizontal direction) are vertically arranged is used. In order to simply configure such a vertical diversity antenna, for example, two strip lines may be arranged on a flexible printed circuit board (FPC board) provided inside the antenna, and power may be supplied to the antenna unit from each.

FIG. 8 is a front view of an FPC board of such a simple vertical diversity antenna. As shown in the figure, two strip lines are arranged on the FPC board and
The PC boards are run in parallel, one branching at a position relatively close to the power feeding section and the other branching at a position relatively far from the power feeding section. After branching, the patch antenna elements are fed with power through the feeding points.

As shown in the cross section of FIG. 9, the FPC board is sandwiched on both sides by an insulator and further sandwiched by a conductor ground plane. Therefore, the radiation from the strip line on the FPC board does not disturb the directivity of the patch antenna element. Patch antenna elements are arranged symmetrically and in multiple stages on both outsides of these conductor ground planes. The cross-sectional dimensions and cross-sectional layout of each patch antenna element and ground plane are selected to obtain omnidirectionality in the horizontal plane. And, the strip line and the patch antenna element,
A short circuit is made by a power feed pin penetrating the insulator and the conductor ground plane, and power is fed from the strip line to the patch antenna elements on both outer surfaces of the conductor ground plane through the power feed pins. It is fed by an independent strip line for each antenna unit,
It can be used for diversity reception with two antenna units.

The dielectric loss of the feed circuit of the vertical diversity antenna as described above affects the antenna gain and cannot be ignored. Usually, in order to reduce the dielectric loss and gain the gain, it is practiced to make the insulator a foam and increase the degree of foaming as much as possible to reduce the proportion of resin.
For example, an electron beam crosslinked foamed polyolefin is used as the foam, and the foamed product has a specific gravity of 0.05 g / cm ³ . As the FPC board, a board in which polyimide or polyester is used as a base film and copper foil is applied thereto is used. If such a combination of substrate and insulator materials is adopted, the wavelength shortening rate K (K = 1 / √ε _r ; ε), which is the ratio of the wavelength λ _g in the power feeding circuit to the wavelength λ in vacuum, is adopted.
_{The r} is the relative permittivity of the insulator), which is about 0.95. On the other hand, in such a vertical diversity antenna, the pitch P (see FIG. 8) of the patch antenna elements is set to 0.degree. Of the wavelength .lamda. In vacuum in order to maximize the antenna gain within the range where the side lobe is not significantly deteriorated. It is selected about 9 times. Therefore, the relationship between the pitch P of the patch antenna elements and the wavelength λ _g in the feeding circuit is: P = 0.9λ = 0.9λ _g /K=(0.9/0.95)
λ _g ≈0.95λ _g , and the pitch P has a value very close to λ _g . In addition, in order to set the beam tilt in the vertical plane to 0 °, the length of the line feeding each antenna element after branching is
Since the antenna elements must be selected so that they are fed in phase, they are set to the same length.

This means that the strip line branching and folding line and the original strip line or the line of another antenna unit run in parallel (a in FIG. 8).
It means that the length of the portion (b and c) is about 1/2 of the wavelength λ _g in the power feeding circuit. Such a portion where two lines run in parallel is generally known as a "coupled strip line". If the length of the portion running parallel is sufficiently smaller than the wavelength lambda _g of the feed circuit, the influence of the coupling is not permissible to ignore the designed wavelength lambda _g 1 /
When the length is about 4, the coupling degree becomes large enough to reach -3 dB (50%) depending on the coupling conditions, which cannot be ignored in design.

[0007]

As described above, in the vertical diversity antenna shown in FIG. 8, since the length of the strip line parallel running portion is about ½ of the wavelength λ _g , the parallel running line The electrical characteristics of the power feeding circuit deviate from the design due to the coupling between them, a mismatch occurs in the power feeding circuit, and the deterioration of the radiation characteristics due to the deterioration of VSWR (voltage standing wave ratio) of the entire antenna and the change of distribution ratio. There is concern that it will occur.

Therefore, the distance between the lines (d in FIG. 8) is set so as to minimize the coupling between the parallel lines.
₁ and d ₂ ) is desired.
However, since the antenna diameter is limited, the width of the FPC board is limited, and the FPC board cannot be separated as much as possible. Therefore,
It is good to say that there is a trade-off relationship between the deterioration of the VSWR and radiation characteristics due to the coupling between the lines running in parallel and the reduction in the size of the vertical diversity antenna.

Therefore, an object of the present invention is to solve the above-mentioned technical problems and to realize a vertical diversity antenna that can achieve electrical matching without increasing the antenna diameter, and that does not deteriorate VSWR or radiation characteristics. That is.

[0010]

A vertical diversity antenna as set forth in claim 1 for achieving the above object has four antenna elements arranged in a vertical direction and a front stage 2
Antenna unit consisting of two antenna elements and the second stage 2
It is divided into an antenna unit consisting of one antenna element.

Then, two strip lines are provided in parallel with each other along the vertical direction on the printed circuit board, each strip line is branched on the printed circuit board, and the antenna element of each antenna unit is passed through the branch destination. I am trying to supply power. One of the branched strip lines that feeds the antenna unit in the previous stage is connected to the antenna element, and the other line is diverted and routed so as to be separated from other strip lines and then routed to the antenna element. The difference between the lengths of the two lines connected to each other is set to be 360 ° or an integral multiple thereof when converted into a phase difference of feeding to the antenna element.

According to another aspect of the vertical diversity antenna of the present invention, one of the branched strip lines feeding the antenna unit in the subsequent stage is connected to the antenna element, and the other line is the "one line".
It is connected to the antenna element after being diverted so as to be separated from the antenna element, and the difference between the lengths of both lines is set to be 360 ° or an integer multiple thereof when converted to the feeding phase difference to the antenna element. It is what

According to the third aspect of the invention, the two strip lines provided on the printed circuit board run parallel to each other on both sides of the center line of the printed circuit board, and the branch of the strip line is Y-shaped or T-shaped. It is a letter-shaped branch. According to the configuration of claim 1, the tip of the strip line that feeds the antenna unit in the preceding stage is branched, and one of the branched lines is connected to the antenna element, and
Since the other line is connected to the antenna element after being detoured so as to be separated from the other stripline and then connected to the antenna element, the "other line" and the other stripline that feeds the antenna unit in the subsequent stage The distance can be increased and the bond can be weakened.

At this time, since the feeding phase difference to the antenna element of each branched line is set to 360 ° or an integral multiple thereof, when the directivity of the entire antenna unit is considered, the feeding is performed in the same phase. This is equivalent to that, and the directivity of the entire antenna unit does not change. Further, since the branched "one line" is directly connected to the antenna element, coupling with another strip line for feeding the antenna unit in the subsequent stage does not become a problem.

From the above, it is possible to avoid an adverse effect due to electrical coupling between the strip line feeding the antenna unit in the preceding stage and the strip line feeding the antenna unit in the succeeding stage, so that electrical matching can be achieved and V
It is possible to realize a vertical diversity antenna without deterioration of SWR and deterioration of radiation characteristics. According to the configuration of claim 2, one of the branched strip lines feeding the antenna unit in the subsequent stage is connected to the antenna element, and the other line is separated from the “one line”. Since it is connected to the antenna element after detouring and routing like this, "the other line",
The distance from "one line" can be increased, and the coupling between the signals branched from the strip line can be weakened.

According to the third aspect of the invention, the two strip lines provided on the printed circuit board run parallel to each other on both sides of the center line of the printed circuit board, and the branch of the strip line is Y-shaped or T-shaped. It is a letter-shaped branch. With such Y-shaped or T-shaped branching, a bilaterally symmetric branching pattern can be obtained, and equal distribution of signals most advantageous in terms of gain can be reliably achieved.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. FIG. 1 is an exploded perspective view of a horizontal omnidirectional vertical diversity antenna, and FIG. 2 is a partial cross-sectional view of the vertical diversity antenna seen from a side surface thereof.
FIG. 3 is an elevation view of the vertical diversity antenna as seen from the front.

In this vertical diversity antenna, sufficiently thick metallic conductor base plates 1a and 1b are opposed to each other, and a printed circuit board 3 sandwiched between insulating conductors 2a and 2b is sandwiched between the conductor base plates 1a and 1b. There is. The conductor ground planes 1a, 1
On the outer surface of b, patch antenna elements 6a-6
d, 6a'-6d 'are arranged at regular intervals.

Strip lines 4 and 5 which are wirings for feeding the patch antenna elements 6a-6d and 6a'-6d 'are formed in parallel on one surface of the printed circuit board 3. The strip line 4 is branched on the way to supply signals to the patch antenna elements 6a, 6b, 6a ', 6b' through feeding pins 7a, 7b, and the strip line 5
Also branched in the middle, and patch antenna elements 6c, 6d, 6
Signals are supplied to c'and 6d 'through power supply pins 7c and 7d. At the base end of each of the strip lines 4 and 5,
The connector 10 for connecting the coaxial cable is mounted (see FIGS. 2 and 3), and the interval between the parallel portions of the strip lines 4 and 5 is the interval y between the connectors 10.
Regulated by.

Reference numeral 8 is a patch antenna element 6a-6.
It is an insulating ring for separating d, 6a'-6d 'from the conductive ground planes 1a, 1b by a certain distance. FIG. 4 is a cross-sectional view taken along the line AA of FIG. 3, in which patch antenna elements 6a and 6a ′ connected to both ends of the feed pin 7a are arranged with a constant distance from the conductor ground planes 1a and 1b. Although the power supply pin 7a is shown as penetrating the conductor base plates 1a and 1b, the insulating plates 2a and 2b, and the printed circuit board 3, the printed circuit board 3 is actually used.
The upper stripline 4 is soldered to the portion 4a (see FIG. 5) and the patch antenna elements 6a and 6a '.
However, the feed pin 7a may be threaded to tighten the patch antenna elements 6a and 6a 'with nuts. In addition, the power supply pin 7a can be screwed with a male screw and a female screw.
The strip line 4 may be divided into two pieces and tightened from both. Although a cylinder is shown by reference numeral 9 in FIG. 4, this is a radome for protecting the entire antenna and is not shown in FIGS. 1 to 3.

Since the strip lines 4 and 5 are sandwiched between the conductor base plates 1a and 1b, unnecessary radiation from the strip lines 4 and 5 can be prevented. As a result, horizontal omnidirectionality can be realized, and power can be supplied to each element through the strip lines 4 and 5 formed on the printed board 3, and the conductor ground planes 1a and 1b are arranged on both sides thereof. The strength of the antenna itself can be given by the conductor base plates 1a and 1b.

Therefore, it is possible to use an ordinary flexible substrate that can be easily processed as the printed circuit board 3 while sufficiently securing the strength of the entire antenna, which can reduce the material cost and facilitate the processing. . Since the pattern of the power supply stripline is formed on the printed circuit board, the coaxial line does not have to be drawn in, the coaxial line can be saved, and the configuration of the antenna can be simplified.

The print patterns of the strip lines 4 and 5 are shown in FIG. The strip line 5 is branched in a T shape in the middle, and one line 51 branched in a T shape is bent at a right angle at a position intersecting with the center line and connected to the tip portion 5d for soldering the power feeding pin 7d. , The other line 52 is detoured so as to be separated from the strip line 4 and is routed in a U-shape, and is bent at a right angle at a position intersecting the center line, and is connected to the tip portion 5c for soldering the power feeding pin 7c. ing. The strip line 4 is branched in a T shape on the way, and one line 41 branched in a T shape is bent at a right angle at a position intersecting with the center line and is connected to a tip portion 4b for soldering the power feeding pin 7b.
The other line 42 is detoured so as to be separated from the one line 41, is routed in a U-shape, and is bent at a right angle at a position intersecting with the center line, and is attached to the tip portion 4a for soldering the power feeding pin 7a. linked.

The difference between the distances from the two T-shaped branched lines 51 and 52 to the tip in the middle of the strip line 5 is an integral wavelength, that is, 360 when converted to the feeding phase difference to the antenna element. ° or an integral multiple thereof. T in the middle of the strip line 4
The difference in distance from the two lines 41 and 42 branched in a letter shape to the tip is also set to be 360 ° or an integral multiple thereof when converted into an integer wavelength, that is, a phase difference of feeding to the antenna element. ing.

By adopting such a print pattern, the distance d between the one T-shaped line 52 of the strip line 5 and the other strip line 4
The distance (see FIG. 5) can be separated from the conventional distance d ₂ (see FIG. 8) by about twice, and the electric coupling between the two can be weakened. In addition, the antenna elements 6a, 6b (6a ',
The same applies to 6b '), since the feed phase difference is set to 360 ° or an integral multiple thereof, the vertical directivity pattern can be the same as the pattern when there is no feed phase difference.

Furthermore, the distance d '(see FIG. 4) between one of the T-shaped branches 41 of the strip line 4 and the other strip line 4 is also 2 compared to the distance d ₁ shown in FIG. They can be separated by a factor of about two, and the electrical coupling can be weakened. Further, the antenna elements 6c, 6d (6c ', 6d
Since the feeding phase difference to (d 'is also the same) is set to 360 ° or an integral multiple thereof, the vertical directivity pattern can be the same as the pattern when there is no feeding phase difference.

Therefore, the stripline portion 5
Since adverse effects due to electrical coupling between the strip lines 1, 52 and 41 and the strip line 4 and adverse effects due to electrical coupling between the strip line portion 51 and the strip line 5 can be avoided, electrical matching can be achieved and antenna elements can be provided. Combined with the fact that the feeding phase difference is 360 ° or an integral multiple thereof, it is possible to realize a vertical diversity antenna without deterioration of radiation characteristics.

Although the branch has a T-shape, it is not necessarily limited to the T-shape and may have a Y-shape. Also, as shown in FIG. 5, there are bends 43 and 53 in the middle of the strip lines 4 and 5, and this bend is due to the space y between the bases of the strip lines 4 and 5.
The distance between the T-shaped branches is adjusted.

It should be noted that there is a portion (length x ₄ ) which is bent at a right angle at a position where one T-shaped branched line 51 of the strip line 5 intersects with the center line and is connected to the tip portion 5d. There is. The presence of this portion (length x ₄ ) is to make the previous pattern of the strip line 5 branched into a T-shape symmetrical. However, there is a problem in that this portion and the strip line 4 are slightly coupled. The part (length x) where the other T-shaped branched line 52 of the strip line 5 is bent at a right angle at a position intersecting the center line and connected to the tip 5c.
₃ ), a part (length x ₂ ) of the strip line 4 which is bent at a right angle at a position where one of the T-shaped branched lines 41 intersects with the center line and which is connected to the tip 4b, the T of the strip line 4 There is a similar problem in a portion (length x ₁ ) where the other line 42 branched in a letter shape is bent at a right angle at a position intersecting the center line and connected to the tip portion 4a.

Therefore, if this coupling is reduced,
As shown in FIG. 6, one of the strip-lined T-shaped lines is connected to the tip at a position intersecting the center line, that is, x ₁ = x ₂ = x ₃ = x ₄ = 0. The pattern may be changed as follows. Since the vertical diversity antenna has the above-described configuration, each of the patch antenna elements 6a-6d and 6a'-6d 'constitutes a patch surface. Each patch surface is I ₁ , I ₂ , II
₁ and II ₂ (see Fig. 2), the patch surface I
₁ and I ₂ are configured in two stages and the same signal is supplied,
Two antenna units I are configured and patch planes II ₁ and II ₂
And are configured in two stages and are supplied with the same signal to configure one antenna unit II.

Next, specific design guidelines including materials and dimensions of each part will be shown. First, the conductor base plates 1a and 1b are made of aluminum and have a thickness of 4.5 mm and a height of 700 mm. If this material has this thickness, sufficient strength can be obtained even when it is erected as a base antenna or a mobile antenna. Also, because of its conductivity, it can be used as a lightning conductor if it is grounded.

The insulating plates 2a and 2b may be made of synthetic resin foam such as expanded polypropylene, expanded polyethylene, expanded polystyrene, and expanded urethane. The foam may be electron beam crosslinked. The substrate 3 is a flexible substrate (FPC) made of polyimide or polyester as a base film and a copper foil applied thereto.

Patch antenna elements 6a-6d, 6a'-
6d 'is normally made of a brass or copper plate. The width of the patch antenna element is L ₂ , the distance between the opposing patch antenna elements is D, and the width of the conductor ground plane is L ₁ (see FIG. 4). The directivity of the entire surface of the patch antenna element is determined by the relationship between the width L ₁ of the conductor ground plane and the width L ₂ of the patch antenna element, and the opposing patch including the effect of the array factor due to the distance D between the opposing patch antenna elements. The horizontal directivity of the two surfaces of the antenna element is determined.

In this horizontal plane combined directivity, when the distance D between the opposing patch antenna elements becomes relatively large, the directivity in the front and back directions decreases, and when the distance D becomes relatively small, the front and back There is a property that the directivity in the back surface direction is increased, and by selecting the directivity of one surface of the patch antenna element and the distance D between the facing patch antenna elements, the horizontal surface non-directionality of the two facing patch antenna elements. Is obtained.

Although the embodiment of the invention has been described above, the invention is not limited to the above-described embodiment, and the strip line pattern of the substrate 3 may be appropriately changed within the scope of the invention. . For example, in the example of FIG. 5 described above, one of the strip-lined T-shaped lines is bent at a right angle to the opposite side at the position intersecting the center line and connected to the tip end, but the strip-lined T-shaped line is formed. One of the branched lines may be bent forward at the position where it intersects with the center line. FIG. 7 shows an example of such forward bending, that is, an example in which the lengths x ₁ , x ₂ , x ₃ , x ₄ are negative (<0). Even with this strip line pattern, it is possible to obtain the same effects as the example of FIG.
Other various modifications can be made without changing the gist of the present invention.

[0036]

As described above, according to the first aspect of the present invention, it is possible to avoid an adverse effect due to electrical coupling between the strip line feeding the antenna unit in the preceding stage and the strip line feeding the antenna unit in the succeeding stage. Therefore, it is possible to realize a vertical diversity antenna that is electrically matched and has no deterioration in radiation characteristics.

Further, the "other line" is detoured so as to be separated from the other strip lines. However, since this detour is naturally performed within the range of the printed circuit board, the width of the printed circuit board is set to the conventional vertical diversity. Antenna (Fig. 8
(See) and no difference. Therefore, it is possible to achieve the object of achieving a vertical diversity antenna that can achieve electrical matching without increasing the antenna diameter and that does not deteriorate VSWR or radiation characteristics. Further, if the coupling between striplines is allowed as in the conventional case, a vertical diversity antenna having a smaller size than the conventional case can be realized.

According to the second aspect of the present invention, since the coupling between the signals branched from the strip line feeding the antenna unit in the subsequent stage can be weakened, electrical matching can be achieved and the phase difference of feeding to the antenna element can be obtained. Is 360 ° or an integral multiple thereof, it is possible to realize a vertical diversity antenna without deterioration of radiation characteristics.

According to the third aspect of the present invention, the two striplines provided on the printed circuit board are formed into Y-shaped or T-shaped branches, thereby forming a bilaterally symmetrical branching pattern. Therefore, it is possible to ensure even distribution of signals, and it is possible to realize a vertical diversity antenna having the highest gain in a given antenna element interval.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a vertical diversity antenna.

FIG. 2 is a partial cross-sectional view of a vertical diversity antenna.

FIG. 3 is a front elevation view of a vertical diversity antenna.

FIG. 4 is a sectional view of the vertical diversity antenna taken along the line AA.

FIG. 5 is an elevation view of a flexible printed circuit board.

FIG. 6 is an elevational view of a flexible printed circuit board according to another embodiment.

FIG. 7 is an elevation view of a flexible printed circuit board according to still another embodiment.

FIG. 8 is an elevation view of a conventional flexible printed circuit board of a vertical diversity antenna.

FIG. 9 is a partial cross-sectional view of a flexible printed circuit board of a conventional vertical diversity antenna.

[Explanation of symbols]

 1a, 1b Metallic conductor base plate 2a, 2b Insulation plate 3 Printed circuit board 4, 5 Strip line 6a-6d, 6a'-6d 'Patch antenna element 7a, 7b Feed pin 8 Insulation ring 41, 42, 51, 52 Branched line

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akira Ono 3-22 Nakanoshima, Kita-ku, Osaka City Kansai Electric Power Co., Inc. (72) Inventor Koyuki Ito 3-3-22 Nakanoshima, Kita-ku, Osaka Kansai Denryoku Co., Ltd. (72) Inventor Noriyuki Tako 1-3-1, Shimaya, Konohana-ku, Osaka No. 3 Sumitomo Electric Industries, Ltd. Osaka Plant (72) Inventor Toshihiko Aki 1-3-1, Shimaya, Konohana-ku, Osaka City Sumitomo Electric Industries Ltd. (72) Inventor Kenichi Harada Shimano, Konohana-ku, Osaka 1-3, Sumitomo Electric Industries, Ltd. Osaka Works (72) Inventor Hisao Ikuta 18-21, Chayamachi, Kita-ku, Osaka City, Osaka Prefecture Japan Arm (72) Akio Ikeda Yoshio Ikeda 18-21 Chayamachi, Kita-ku, Osaka-shi, Osaka

Claims (3)

[Claims] 1. Four antenna elements are arranged in a vertical direction and divided into an antenna unit consisting of two antenna elements in the front stage and an antenna unit consisting of two antenna elements in the rear stage, and two strips are formed on a printed circuit board. Lines are provided in parallel with each other along the vertical direction,
In a vertical diversity antenna in which each strip line is branched on the printed circuit board and power is fed to the antenna element of each antenna unit through the branch destination, one of the branched strip lines that feeds the antenna unit at the previous stage is , Is connected to the antenna element, and the other line is diverted and routed so as to be separated from the other stripline, and then connected to the antenna element. The difference in the length of both lines is the power feeding to the antenna element. A vertical diversity antenna, which is set to be 360 ° or an integral multiple thereof when converted into a phase difference. 2. One of the branched strip lines feeding the antenna unit at the subsequent stage is connected to the antenna element, and the other line is diverted so as to be separated from the "one line". Connected to an antenna element after being routed, and a difference in length between both lines is set to be 360 ° or an integral multiple thereof when converted into a phase difference of feeding to the antenna element. The vertical diversity antenna according to Item 1. 3. The two strip lines provided on the printed circuit board run parallel to each other on both sides of the center line of the printed circuit board, and the branch of the strip line is a Y-shaped or T-shaped branch. The vertical diversity antenna according to claim 1, which is characterized in that.