JPH02174404A - Plane antenna for mobile communication - Google Patents

Abstract

PURPOSE:To obtain an antenna with simple structure and sufficiently broad band characteristic by providing a table type antenna, a strip line resonator and a capacitor electrode. CONSTITUTION:A conductive plane 10 is connected to a ground plate 20 by link members 11-13. A strip line resonator 30 is provided to the inside of the tape type antenna and a capacitor electrode 40 is provided to a position opposite to the antenna middle part. Both terminals of the resonator 30 are connected to ground, the electrode 40 is installed in the center and resonated at lambda/2 of the operating frequency. Or the one terminal of the resonator 30 is connected to ground, the other terminal is opened, the capacitor electrode 40 is connected to the opening part, the resonator 30 is placed so that the electrode 40 exists in the middle in the inside of the antenna and resonated at lambda/4. A feeding point 50 is provided between the ground terminal of the resonator 30 and the electrode 40 to match the impedance of the plane antenna and the feeder by changing the position.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is a flat plate antenna that is installed on the horizontal part (B root, trunk lid, etc.) of the surface of a car body, etc. This invention relates to a flat antenna for mobile communication such as access.

[Prior Art] Various types of linear antennas have been used as conventional mobile communication antennas. This means that the linear antenna
It is easy to have the maximum radiation characteristics in the horizontal direction and non-directional characteristics in the horizontal plane, which is necessary for mobile communications, and antennas for car phones and MCAs require broadband characteristics. However, the broadband technology for linear antennas has been established, and development and design measures are relatively easy to take.

On the other hand, in recent years, flat plate antennas have been attracting attention as antennas for mobile communications. This is because when a flat plate antenna is installed on a car, there are no protrusions like conventional ones, which eliminates the deterioration of the car's style, reduces wind noise while driving, and reduces contact with car wash equipment, garages, street trees, etc. This is because there are great operational benefits, such as no damage due to no worries about damage.

[Problems to be Solved by the Invention] By the way, when using a flat plate antenna, multilayer structure antennas have been proposed due to the need to provide broadband characteristics. , there is a problem that it is difficult to commercialize.

SUMMARY OF THE INVENTION An object of the present invention is to provide a flat antenna for mobile communications that has sufficient broadband characteristics and has a simple structure.

[Means for Solving the Problems] The present invention provides a method for installing a strip line resonator inside a table type antenna, and providing a capacitor electrode on the strip line resonator at a position facing the center of the table type antenna. It is something that

[Function] In the present invention, a stripline resonator is installed inside a table-type antenna, and a capacitor electrode is provided on the stripline resonator at a position facing the center of the table-type antenna. The communication antenna has a simple structure and has sufficient broadband characteristics.

[Example] FIG. 1 is a diagram showing an embodiment of the present invention.

Figure (1) is a perspective view of the same, Figure (2) is a front view when the connecting plate 14 of Figure (1) is omitted, and Figure (3) is a perspective view of Figure (1). ) is a diagram showing an equivalent circuit of.

In this embodiment, a table type antenna 10, a ground plate 20, a strip line resonator 30 installed inside the table type antenna 10, and a strip line resonator 30 located at a position facing the center of the table type antenna 10, A capacitor electrode 40 provided on the resonator 30 and a feed line 60 having a feed point 50 at a predetermined position of the strip line resonator 30 are provided.

The table-type antenna 10 has a circular conductive flat plate portion and a plurality of connecting members 11, 12, 13, and 14 that electrically connect this flat plate portion to the ground plate 20, and is excited in a monoball mode. It's an antenna.

The strip line resonator 30 has both ends connected to the ground plate 2.
It is grounded to 0 and also serves as an impedance converter. In addition, the capacitor electrode 40 and the table type antenna 1
The capacitance Cc between 0 and 0 is shown by the symbol of a capacitor in FIG. 1(2). Also, in Figure 1 (1),
Although the power supply line 60 is routed from below the ground plate 20, it may be provided in a direction parallel to the ground plate 20, as shown by reference numeral 61.

FIG. 2(1) is a diagram showing the relationship between the table antenna 10 excited in monoball mode and the feed line in the above embodiment.

When the table antenna 10 is excited in the monoball mode (the current flowing through the plate flows uniformly from the center to the periphery), the flat plate antenna 10 is excited in the lowest order mode (λ/
2), the voltage distribution at the center of the table antenna 10 becomes maximum, and the impedance characteristics when viewed from the center of the disk are as shown in Figure 2 (2) near the resonance frequency. It can be considered as a parallel resonant circuit as shown.

FIG. 3(1) is a diagram showing the strip line resonator 30 with a capacitor electrode 40 and grounded at both ends in the above embodiment.

The resonator shown in Fig. 3 (1) has the lowest order mode (λ/2
), the voltage across the capacitor electrode 40 is at its maximum, and the impedance characteristics when viewed from the power supply point 50 of the power supply &160 are:

Near the resonance frequency, it can be regarded as a tapped parallel resonant circuit as shown in FIG. 3(2).

By the way, the embodiments shown in FIGS. 1 (1) and (2)
Table type antenna 10 shown in Figure (1) and Figure 3 (1)
It can be thought of as a combination of the strip line resonator shown in However, in this case, the power supply line 60a shown in FIG. 2(1) is omitted and the power supply line 60 is used. As a result, the primary resonant circuit constituted by the strip line resonator 30 and the secondary resonant circuit constituted by the table-type antenna lO are electrostatically coupled by the inter-plate capacitance Cc. Therefore, in the embodiment shown in FIG. 1(1), a double-tuned circuit due to capacitive coupling is apparently formed near the resonance frequency, as shown in FIG. 1(3).

Here, the resonant frequency of the primary side and the resonant frequency of the secondary side are tuned to the operating frequency, and the coupling capacitance Cc is selected as the critical coupling value, and the impedance of the flat antenna for mobile communication and the feed line shown in Fig. 1 are calculated. The position of the feeding point 50 is selected so that the impedance is matched with the impedance. By doing so, it is possible to reduce the reflection loss of the flat antenna for mobile communication shown in FIG. can be obtained.

By the way, the necessary conditions for a flat plate antenna for mobile communication such as a car phone are directional characteristics (maximum radiation characteristics in the horizontal direction, omnidirectional in the horizontal plane), wide band (
For example, in the case of a car phone, its bandwidth must sufficiently cover 80 MHz), impedance matching (matching between the feed line 60 and the mobile communication flat antenna must be well maintained over a wide band), and mechanical structure (simple and easy to manufacture). It is necessary that the structure is easy to manufacture, and that mechanical errors in manufacturing do not have a large effect on the antenna characteristics.

First, regarding the directional characteristics, the table-type antenna 10 is shaped to excite in monoball mode (that is,
(It has a shape having an axially symmetrical flat plate portion and a plurality of connecting members that electrically connect the flat plate portion to the ground plate 20), thereby making it possible to obtain a predetermined directivity characteristic.

Next, regarding widening the band, flat plate antennas excited in monoball mode generally have a narrow bandwidth, and although it is possible to widen the band to some extent by connecting the circular plate and the ground plate with an earth post. , there are limits to it. Therefore, in the embodiment described above, a strip line resonator 30 is installed inside the table-type antenna IO and is electrostatically coupled to the antenna IO to achieve a wide band.

Next, consider impedance matching.

In order to stably excite the monopole mode mentioned above,
Normally, it is necessary to choose the feeding point in the center of the antenna, but
The central part of the antenna is at the maximum voltage point, and it is difficult to match the antenna and the feed line 60. Therefore, in the above embodiment, the table-type antenna 10 and the strip line resonance are connected via the capacitance Cc. The power supply is connected to the power supply device 30 to supply power. By changing the position of the feed point 50 between the ground end of the strip line resonator 30 and the capacitor electrode 40, the impedance of the mobile communication flat antenna and the impedance of the feed line 60 can be matched. In this way, according to the method of achieving impedance matching by changing the position of the feed point 50 (changing the tap position), there is little effect on the antenna body in terms of directivity, broadbandization, etc. Therefore, the development of flat plate antennas is possible. , it is possible to select the optimal power feeding point relatively easily at the design stage.

Next, regarding the mechanical structure, in the above embodiment, the two parts, the table type antenna IO and the strip line 30, are mechanically separated and processed.

Since it is basically a simple combination of the above two parts, machining is easy when manufacturing the antenna. Therefore, if the product costs are reduced and normal processing accuracy is maintained, the antenna characteristics will not deteriorate and the mechanical strength of the antenna will not be insufficient. Furthermore, if there is a mechanical dimensional error during assembly, it will reduce the coupling capacitance. Although this will result in a change, even in this case, the bandwidth will only change slightly and there will be almost no essential effect on the antenna characteristics.

FIG. 7 is a diagram showing changes in the reflection loss of the antenna when the coupling capacitance Cc is changed in the above embodiment.

FIG. 8(1) is a diagram showing reflection loss measurement in the above embodiment, and FIG. 8(2) is a diagram showing an example of impedance characteristics displayed by Smith chart in the above embodiment.

Regarding the radiation directivity characteristics of the antenna of the above embodiment, when the table-like flat antenna resonates in the monopole mode, the maximum radiation direction of the antenna is approximately horizontal, and the antenna is approximately non-directional in the horizontal plane.

FIG. 9 is a diagram showing an example of the directivity characteristic in the vertical plane when a flat plate antenna is attached to a disc-shaped ground plate having a diameter of 1.5 m in the above embodiment.

In the characteristics shown in Figure 9, the directivity is slightly upward because a finite length ground plate is used, but if an infinite ground plate is used, the directivity becomes almost horizontal. .

FIG. 4(1) is a perspective view showing another embodiment of the present invention, and FIG. 4(2) is a front view in which the connecting member 14 in FIG. 4(1) is omitted.

In this embodiment, instead of the stripline resonator 30, a stripline resonator 31 is used, the length of the stripline being about half that of the resonator 30, and installed only on one side. In this case as well, the capacitor electrode 40 is placed approximately at the center of the table-type antenna 10. In this case as well, an equivalent circuit similar to the circuit shown in FIG. 1(3) is formed.

In the case of the embodiment shown in FIG. 4(1), resonance occurs at λ/4 of the operating frequency.

FIGS. 5 and 6 (1) and (2) are diagrams showing modifications of the table-type antenna 10 in the above embodiment.

The table-type antenna 10a has connecting members 11a and 12a.
, 13a, 14a are table type antenna log
is set at a predetermined point approximately equidistant from its center, rather than at its edge. Also.

The table-type antenna lOb is composed of a regular octagonal flat plate part, and connecting members 11b, 12
In addition to the circular shape and hexagonal shape in which the antenna elements b, 13b, and 14b are provided, a regular polygonal flat plate portion such as a hexagonal shape may be used instead. , 13c, and 14c.

Further, by adjusting the length, width, and diameter of the connecting member, the resonant frequency of the table antenna can be adjusted. In addition, the connecting members 11 to 14, lla
~14a, llb~14b, 11c~14C1 Instead, three or five or more connecting members may be used.

[Effects of the Invention] According to the present invention, the structure of an antenna for mobile communication is simple, and the antenna has sufficient broadband characteristics.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing an embodiment of the present invention.
) is a perspective view thereof, (2) is a front view thereof, and (3) is a diagram showing an equivalent circuit thereof. FIG. 2 (1) is an explanatory diagram when the table-type antenna 10 in the above embodiment operates in monopole mode, and FIG. 2 (2) shows the impedance characteristics seen from the center of the disk at that time. and is an equivalent circuit diagram near the resonance frequency. FIG. 3 (1) is a perspective view showing the strip line resonator 30 in the above embodiment, and FIG. 3 (2) is an equivalent circuit diagram of impedance characteristics when viewed from the feeding point of the feeding line at that time. It is. FIG. 4(1) is a perspective view showing another embodiment of the present invention, and FIG. 4(2) is a front view thereof. FIGS. 5 and 6 (1) and (2) are perspective views showing modifications of the table-type antenna 10 in the above embodiment. FIG. 7 is a diagram showing reflection loss characteristics due to changes in coupling capacitance in the above embodiment. FIGS. 8(1) and 8(2) are diagrams showing reflection loss characteristics and impedance characteristics in the above embodiment. FIG. 9 is a diagram showing the directivity characteristics in the vertical plane in the above embodiment. 10, 10a, 10b, 10c...Table type antenna, O...Ground plate, 0.31...Strip line resonator, 0...Capacitor electrode, 0...Feeding point, 0.61. ...Power line. 10: Table Hi amplifier

Claims (9)

[Claims] (1) A table-type antenna comprising a conductive flat plate portion and a plurality of connecting members that electrically connect the flat plate portion to a ground plate; and a strip line resonator installed inside the table-type antenna. A flat plate antenna for mobile communications, comprising: a capacitor electrode provided on the strip line resonator, the capacitor electrode being located opposite to the center of the table-type antenna; (2) In claim (1), the stripline resonator is grounded at both ends, the capacitor electrode is provided approximately at the center thereof, and the entire stripline resonator is located at approximately the center inside the table-type antenna. A flat plate antenna for mobile communication, which is installed in a mobile communication network and resonates at λ/2 of the operating frequency. (3) In claim (1), the stripline resonator is grounded at one end and open at the other end, the capacitor electrode is connected to this open part, and the stripline resonator A flat plate antenna for mobile communications, characterized in that the entire strip line resonator is grounded so that the capacitor electrode is located approximately at the center, and resonates at λ/4 of the operating frequency. (4) The flat antenna for mobile communication according to claim (1), characterized in that a feeding point is provided between the ground end of the strip line resonator and the capacitor electrode. (5) In claim (1), the impedance of the mobile communication flat antenna and the impedance of the feed line can be adjusted by changing the position of the feed point between the ground end of the strip line resonator and the capacitor electrode. A flat plate antenna for mobile communication characterized by matching. (6) The flat plate antenna for mobile communication according to claim (1), wherein the flat plate portion of the table-type antenna is circular or regular polygonal. (7) The flat antenna for mobile communication according to claim (1), wherein the connecting member is a rod-shaped or plate-shaped conductor. (8) The flat antenna for mobile communication according to claim (1), wherein the resonant frequency of the table-type antenna is adjusted by adjusting the length, width, and diameter of the connecting member. (9) The mobile communication according to claim (1), wherein the capacitor electrode is set so that the capacitive coupling between the table-type antenna and the strip line resonator is approximately in a critical coupling state. flat plate antenna.