JPH07303005A - Antenna system for vehicle - Google Patents

Abstract

PURPOSE:To provide an antenna system for vehicle in which low posture and miniaturization can be attained and used, for example, in a mobile telephone, etc. CONSTITUTION:First and second loop antennas 11, 12 are formed by arranging first and second parallel loop plates 111, 121 on a ground conductor plate 13 setting prescribed intervals, respectively, providing a vertical feed plate 14 in common to them, and providing vertical short-circuit plates 112, 122. Those loop antennas 11, 12 are constituted of the parallel loop plates 111, 121, the common vertical feed plate 14 and the vertical short-circuit plates 112, 122, and a coaxial cable 15 is connected to the vertical feed plate 14 at a feed point 16. Three radiant elements can be formed with a vertical feed plate 13 and the vertical short-circuit plates 112, 122. The parallel loop plates 111, 121, the verical feed plate 14 and the vertical short-circuit plates 112, 122 are comprised by segmenting from a metallic plate, respectively.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna device for quasi-microwave communication used for, for example, a car telephone, and particularly for a vehicle compatible with a single band and a multi band which is effectively mounted on a car. The present invention relates to an antenna device.

[0002]

2. Description of the Related Art A variety of these quasi-microwave antennas have been developed with the spread of car telephones, etc., but especially when they are used for vehicles, they are small in size because they need to be housed in a limited space. There is a demand for higher performance, and a lower attitude is required, and in the state where these requirements are satisfied, higher gain and omnidirectionality are required in terms of performance.

In response to such demands for vehicle mounting, for example, a low-profile type vehicle-mounted antenna as disclosed in Japanese Patent Laid-Open No. 4-369902 has been proposed. According to the low-profile vehicle-mounted antenna proposed here, for example, the height is 52 m.
It is possible to reduce the posture to about m, but it is difficult to make the posture low enough.

Further, for example, the document "Modified Transmission Line Antenna for Mobile Communication" (IEICE AP91-8)
2: 10 September 1991), a dual structure loop antenna was introduced, and this loop antenna has a height of 30 mm and a low profile and is miniaturized. However, since the loop antenna introduced here is composed of wire rods, it is difficult to easily process it due to its structure, which leads to a significant cost increase and practical application. Not in.

On the other hand, in recent years, car telephones (800 MHz, 1500 MHz), G
There are many media such as PS, VICS, PHS, etc. However, since each media has a different frequency, a separate antenna is required for each media.

A problem here is that various problems occur due to the large number of mounted antennas. In other words, simply because only the number of media is required, multiple antennas are installed in one vehicle, which causes problems in appearance or interior design (aesthetics) and mounting space, and also in terms of cost. Is.

On the other hand, as an antenna device for dual frequency use, a dual frequency antenna has been disclosed in Japanese Utility Model Laid-Open No. 5-41121. That is, the dual frequency antenna has a first straight line portion provided on the first and second dielectric layers and on a surface of the first dielectric layer opposite to a surface in contact with the second dielectric layer. It is provided between the loading ring-shaped patch antenna and the first dielectric layer and the second dielectric layer so that the linear portion is orthogonal to the linear portion of the first linear portion loading ring-shaped patch antenna. The second linear portion loaded ring-shaped patch antenna provided, the ground conductor provided on the surface of the second dielectric layer opposite to the surface in contact with the first dielectric layer, and the first and second And a feed line connected to each of the ring-shaped patch antennas loaded in the straight section.

However, this conventional technique (actual Kaihei 5-
No. 41211) has a problem that the directivity of radio waves is unsuitable for an antenna device for an in-vehicle telephone and the cost is high because a high frequency dielectric is used.

[0009]

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and is capable of being lowered to a position suitable for a single band, and can be stored in a limited space. A single band that can be effectively applied to, for example, a car phone, so that it can be downsized as much as possible, and the requirements of high gain and omnidirectionality in performance can be satisfied. It is intended to provide a corresponding vehicle antenna device.

Further, the present invention has been made in view of the above points, and can be stored in a limited space by being able to be sufficiently lowered in posture so as to be particularly suitable for multi-band use. In addition to being miniaturized, the requirements for high gain and omnidirectionality in performance are satisfied, for example, for multi-band vehicles that can be effectively applied to, for example, car telephones. It is intended to provide an antenna device.

[0011]

In a vehicle antenna device according to one aspect of the present invention, a predetermined space is set above a ground conductor plate, and a conductive plate material is formed into a loop shape parallel to the ground conductor plate. The first and second parallel loop portions configured as described above are arranged, and the vertical power feeding portion is provided so as to be commonly connected to each of the first and second parallel loop portions. Further, first and second vertical short-circuit portions connected to the ground conductor plate are provided at positions symmetrical to the position of the vertical power feeding portion with respect to the first and second parallel loop portions, respectively.
The first parallel loop portion, the vertical feeding portion, the first vertical short-circuit portion, and the ground conductor plate constitute a first loop antenna, and the second parallel loop portion, the vertical feeding portion, and the second vertical short-circuit portion. The second loop antenna is constituted by the ground conductor plate and the ground conductor plate.

In a vehicle antenna device according to another aspect of the present invention, a predetermined interval is set above the ground conductor plate, and the conductive plate members are formed in a loop shape parallel to the ground conductor plate. The first, second and third parallel loop portions are arranged, and the vertical power feeding portion is provided so as to be commonly connected to each of the first, second and third parallel loop portions. Further, the first, second and third connection with the ground conductor plate is made at a position symmetrical to the position of the vertical power feeding part with respect to each of the first, second and third parallel loop parts.
A vertical short-circuit part is provided, and the first parallel loop part, the vertical power supply part, the first vertical short-circuit part and the ground conductor plate form a first
A second loop antenna is constituted by the second parallel loop portion, the vertical feeding portion, the second vertical short-circuit portion and the ground conductor plate, and the third parallel loop portion, the vertical feeding portion. , The third vertical short-circuit portion and the ground conductor plate constitute a third loop antenna.

[0013]

In the vehicle antenna device of one aspect configured as described above, the dual structure in which the second loop antenna is put in the plate-shaped first loop antenna is provided. Therefore, the manufacturing is simplified with the miniaturization. In such a plate-shaped antenna device,
Various different current paths are generated in the first and second loop antennas, the standing wave ratio is suppressed, and the bandwidth can be sufficiently widened. Therefore, it is downsized so that it can be stored in a limited space with a low profile, and it is omnidirectional in performance and high in gain, and is sufficient for, for example, a single-band compatible mobile phone. The function is demonstrated.

According to another aspect of the vehicle antenna device configured as described above, the second loop antenna is placed in the plate-shaped first loop antenna, and the second loop antenna is provided. It has a triple structure such that the third loop antenna can be put in the loop antenna of
Manufacturing is simplified with miniaturization. In such a plate-shaped antenna device, different current paths are generated in the first, second, and third loop antennas, the standing wave ratio is suppressed, and the bandwidth is sufficiently widened. it can. Therefore, it is downsized so that it can be housed in a limited space with a low profile, and it is also omnidirectional in performance and high in gain, which is sufficient for, for example, a car phone compatible with multiband. The function is demonstrated.

[0015]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows the configuration of the first embodiment. The antenna device according to the first embodiment is used for a single band, for example, 800 MHz band mobile telephone, and is an electrical device determined by a plate-shaped first resonance frequency. The first loop antenna 11 having a length has a double structure in which the second loop antenna 12 having an electric length determined by the second resonant frequency which is also plate-shaped is inserted.

The first and second loop antennas 11
And 12 are configured with a common ground conductor plate 13. The first loop antenna 11 is provided with a first parallel loop flat plate 111 which is arranged above the ground conductor plate 13 at a predetermined interval, and the first parallel loop flat plate 1 is provided.
11 is formed by cutting a metal plate into a rectangular loop. A vertical feeding plate 14 is provided at the center of one side of the first parallel loop plate 111 so as to extend in a direction perpendicular to the plane of the parallel loop plate 111. A first vertical short-circuit flat plate 112 is provided so as to be connected to the ground conductor plate 13 at a position symmetrical to the above.

Here, the end portion of the vertical power supply flat plate 14 is integrally attached to the ground conductor plate 13, for example, the insulating plate 1.
It is fixed at the eight portions so that the vertical power supply plate 14 and the ground conductor plate 13 are insulated.

The second loop antenna 12 is also provided with a second parallel loop flat plate 121 which is also formed by cutting a plate material into rectangular loops, and the parallel loop flat plate 121 is located at the center of one side thereof. The vertical feed plate 14 that is commonly used as the first parallel loop plate 111 is connected to the first parallel loop plate 111. Further, the vertical feed plate 14 is connected to the ground conductor plate 13 at a position symmetrical to the mounting position of the vertical feed plate 14. Two vertical short-circuit plates 122 are provided.

The radiating element of the first loop antenna 11 is
The grounding conductor plate 13, the vertical short-circuiting flat plate 112 and the vertical feeding flat plate 1 which are arranged on the grounding conductor plate 13 in a plane parallel with a predetermined distance L1.
4 and further comprises a first parallel loop flat plate 111. Similarly, the radiating element of the second loop antenna includes a grounding conductor plate 13, a vertical short-circuiting plate 122 and a vertical feeding plate 14, which are arranged on the grounding conductor plate 13 in a plane parallel at a predetermined distance L2, and further, a second parallel loop. It is composed of a flat plate 121.
The first and second loop antennas 11 and 12 have the same feeding point 1 to which the coaxial cable 15 is connected.
6 and share the same vertical power supply flat plate 14.

In the structure of the power feeding portion, the coaxial cable 15 is arranged on the ground conductor plate 13 for the purpose of lowering the posture, the outer conductor of the coaxial cable 15 is connected to the ground conductor plate 14, and the center conductor is Feeding point 1 at the lower end of the vertical feeding plate 14
6 is electrically connected. Ground conductor plate 1
3, a plurality of through holes 171, 172, ... Are formed, but these through holes 171, 172, ... Are used for positioning when the antenna device is housed in an antenna case (not shown). It is used as appropriate, and its position is selected so that it has little influence on the current path flowing between the radiating elements.

[0021] The frequencies currently used by car telephones in Japan are divided into two frequency bands: 810-885 [MHz] for reception and 898-956 [MHz] for transmission. Therefore, in the antenna device shown in this embodiment, the antenna device is divided into the first and second loop antennas 11 and 12 having individual resonance frequencies for transmission and reception, respectively. The loop antennas 11 and 12 are connected in parallel to form a low-frequency dual structure loop antenna for dual frequency, which is integrated as one antenna.

This dual structure loop antenna device is constituted by a plate-shaped structure, and a vertical feed plate common from the coaxial cable 15 to the first loop antenna 11 and the second loop antenna 12 is used. A high-frequency current I is supplied to 14. This high frequency current I is
And the second parallel loop plates 111 and 121 together with the vertical shorting plates 112 and 122.

Here, the antenna element in this antenna device is divided into an element portion contributing to radiation and an element portion contributing to impedance. In the element portion contributing to radiation, the first and second loop antennas are provided. Vertical feeding flat plate 14 which is the same feeding part of 11 and 12 and vertical shorting flat plate 1 which is the shorting part of antennas 11 and 12, respectively.
Emit vertically polarized waves by 12 and 122. At this time, the high frequency current I supplied to the vertical feed plate 14 common to the first and second loop antennas 11 and 12 is
The gain is increased as compared with the open-ended antenna in the same phase, and the high-frequency current I flowing in the vertical short-circuit plates 112 and 122 of the first and second loop antennas 11 and 12, respectively, is vertical. Distance L1 between the power supply plate 14 and each of the vertical short-circuit plates 112 and 122
And L2.

On the other hand, the elements contributing to the impedance are the first and second parallel loop flat plates 111 and 1.
There is 21. This is because the transmission line is formed together with the image line formed on the ground conductor plate 13, so that the impedance is controlled by the heights H1 and H2 according to the transmission path theory. The impedance is high when is large.

In the dual structure loop antenna thus constructed, the vertical feeding flat plate 1 which is three radiating elements
4. The vertical short-circuit plates 112 and 122 increase the gain to facilitate impedance matching with the feeder line for feeding the antenna, and the resonance frequency f ₀ thereof can be changed to desired values by changing the antenna length and the shape parameter. The characteristics can be obtained and the design is facilitated.

Further, since each element is formed into a plate shape by the flat plate structure, various different current paths are generated in each of the plate-like elements, and the voltage standing wave ratio (VSWR) is obtained.
Can be suppressed. 2A and 2B show the effect of the plate-shaped element. FIG. 2A shows the case where the loop antenna is composed of the linear body, and FIG. 2B shows the case where the loop antenna is composed of the plate-shaped body as in the embodiment. In each case, the vertical axis represents the voltage standing wave ratio (VSWR), and the horizontal axis represents the frequency (MHz).

Generally, the voltage standing wave ratio (VSWR) is required to be 1.9 or less, and the range is the frequency bandwidth ΔW [MHz] used, and the diameter shown in FIG. In the case of a linear body of 4 mm, “ΔW = ΔW
1 + ΔW2 ”and its bandwidth ΔW is approximately 90 MHz
Is. On the other hand, in the case of the diagram (B) configured by the plate-shaped body having a width of 6 mm and a thickness of 0.6 mm, the voltage standing wave ratio (VSWR) is suppressed and the usable frequency bandwidth ΔW is about 200 MHz. Broadband.

In the antenna device constructed as described above, since it is composed of a plate material, one plate material can be manufactured by press working, and in comparison with the case where it is composed of a wire material. As a result, the processing can be sufficiently simplified, and the cost can be greatly reduced. In addition, since the loop antenna made of plate material in this way can be configured with a small number of connecting parts, it is possible to reliably improve the mechanical strength, and there are also few points to connect using solder or the like. Therefore, good electrical conductivity can be maintained. And, more importantly, since various current paths can be set in the plate-like body, the voltage standing wave ratio (VSWR) can be effectively suppressed and the ratio band “ΔW / f ₀ (%)” can be set. Can be ensured widely.

In the above embodiment, the first and second parallel loop flat plates 111 and 12 are processed by processing the plate-like body.
1 is composed of insulating printed boards 211 and 22 having the same shape as the loop flat plate as shown in FIG.
By the loops 212 and 222 in which a conductive thin film is printed on each surface of 1 and etched into a loop shape,
You may make it comprise the 1st and 2nd parallel loop flat plates 111 and 121. Printed circuit board 21
1 and 221, the parallel loop flat plate 111
And the mechanical strength of 121 is further improved.

Further, in the above-described embodiments, the loop shape of each of the first and second parallel loop flat plates 111 and 121 is constituted by a quadrangle.
These parallel loop plates 111 and 12
It is also possible that both 1 are circular in shape. In this case, the vertical power supply plate 14 and the vertical short-circuit plates 112 and 122 are
The circle should be attached at a position that divides it into two.
The shape of the parallel loop flat plates 111 and 121 can be arbitrarily designed in consideration of the design surface such as an ellipse. By changing the shape of the parallel loop flat plates in this way, an antenna having a high degree of freedom can be obtained. Device design is possible.

In the case where the antenna element including the parallel loop flat plate is cut out from the plate-like body, as shown in FIG. 5B, the first and second parallel loop flat plates 111, 121, the vertical power supply plate 14, and the vertical short-circuit plates 112 and 122 are cut out so that the shape of the grounding conductor plate 13 is integrally continuous, and by bending this, it is bent as shown in FIG. It can also be assembled to form a predetermined dual structure loop antenna.

Here, in FIG. 1B, the first parallel loop flat plate 111 and the grounding conductor plate 13 are connected by the vertical feeding flat plate 14, but this metal plate is cut out and bent ( A) After assembling the antenna device as shown in the figure, the connection piece 141 is cut off so that the vertical power supply plate 14 and the ground conductor plate 13 are not electrically connected.

In order to further reduce the size of the antenna device having such a structure, it may be considered to use the first and second dielectric substrates 25 and 26 as shown in FIG. That is, the first and second parallel loops 111
, 121, and a first dielectric substrate 25 having a thickness corresponding to the distance between the ground conductor plate 13 and the second parallel loop flat plate 121.
A second dielectric substrate 26 having a thickness corresponding to the space between the second dielectric substrate 26 and the second dielectric substrate 26 is placed on the ground conductor plate 13 to form a laminated structure. Then, conductive thin films are formed on the surfaces of the first and second dielectric substrates 25 and 26, respectively, and etched to form the first and second loops 251 and 261. And the second parallel loop flat plates 111 and 121 are configured.

Here, the first and second dielectric substrates 25 and 26 stacked on the ground conductor plate 13 are fixed pieces 271 and 2 so that the stacked state is maintained.
It is fixed by 72. Although not shown in detail, the ground conductor plate 1 is fixed by the fixing pieces 271 and 272.
3 and the loops 251 and 261 are not electrically connected to each other, and a vertical power supply plate and a vertical short-circuit plate are provided so as to be connected to the loops 251 and 261.

That is, the first loop 251 forming the first parallel loop flat plate 111 is formed on the surface of the dielectric substrate 25 having a good dielectric constant ε of high frequency characteristics, and further below the dielectric substrate 25. The dielectric substrate 26 having a dielectric constant equivalent to that of the first and second loops 251 is formed by forming the second loop 261 on the surface of the dielectric substrate 26.
The electrical length 1 / ε of each element including and 262 can be shortened, the size can be effectively reduced, and the mechanical structure can be surely made strong.

In the above description, the operating frequency of 800M is particularly mentioned in the description of the configuration and operation.
I intended the Hz band, but this is just one example,
For example, it can be applied not only to the 1.5 GHz band but also to any other frequency band.

Next, referring to FIG. 7, as a second embodiment according to the present invention, two frequency bands (80
0MHz band mobile phone, 1500MHz band mobile phone)
A multi-band compatible antenna device for handling will be described.

As shown in FIG. 7 in which the same components as those in FIG. 1 described above are denoted by the same reference numerals, the antenna device according to the second embodiment has a ground conductor plate 13 and this ground. A first parallel loop flat plate 11 in which a conductive plate material provided in parallel with the ground conductor plate 13 is formed into a loop shape by setting a predetermined interval on the conductor plate 13.
1 and.

This antenna device is connected to the first parallel loop plate 111, and the parallel loop plate 111 is connected to the first parallel loop plate 111.
The vertical feed plate 14 set vertically to the parallel feed plate 14 is connected to a position symmetrical to the position of the vertical feed plate 14 with respect to the first parallel loop plate 111, and set vertically to the parallel loop plate 111. This parallel loop flat plate 111
And a first vertical short-circuit plate 1 for connecting the ground conductor 13 to the grounding conductor 13.
12 and the ground conductor plate 13 are provided between the ground conductor plate 13 and the parallel loop flat plate 111 in parallel with the ground conductor plate 13, and the conductive plate member is formed into a loop shape. Then, the vertical power supply flat plate 14 has a second parallel loop flat plate 121 which is commonly connected to the first parallel loop flat plate 111.

Further, this antenna device is connected to the second parallel loop flat plate 121 at a position symmetrical to the position of the vertical feed flat plate 14 and is set perpendicularly to the second parallel loop flat plate 121. Then, a second vertical short-circuit flat plate 122 connecting the second parallel loop flat plate 121 and the ground conductor plate 13, a first parallel loop flat plate 111 on the ground conductor plate 13, and a second vertical short-circuit flat plate 111 on the ground conductor plate 13. Between the parallel loop flat plate 121 and the grounding conductor plate 13, the conductive plate material is formed into a loop shape, and the vertical power feeding flat plate 14 has the first and second parallel loop flat plates 111,
121 and a third parallel loop flat plate 131 configured to be commonly connected.

Further, this antenna device is connected to the third parallel loop flat plate 131 at a position symmetrical to the position of the vertical feed flat plate 14, and is set perpendicular to the third parallel loop flat plate 131. A third vertical short-circuit flat plate 132 for connecting the third parallel loop flat plate 131 and the ground conductor plate 13.

In this antenna apparatus, the parallel loop flat plate 111, the vertical feed flat plate 14, the ground conductor plate 13 and the first vertical short-circuit flat plate 112 constitute the first loop antenna 11 and the second parallel loop flat plate. 12
The second loop antenna 12 is constituted by the first vertical short-circuit flat plate 14, the ground conductor plate 13 and the second vertical short-circuit plate 122, and the third parallel loop flat plate 131, the vertical feed flat plate 14, the ground conductor plate 13 and the Vertical short-circuit flat plate 13
The second loop antenna 10 is composed of 2.

Here, the third loop antenna 10 is
It is for the 500 MHz band. Further, the two loop antennas including the first loop antenna 11 and the second loop antenna 12 are for the 800 MHz band, and the 800 MHz band loop antenna is completely the same as that described in the first embodiment. They are the same.

The operating principle of the third loop antenna 10 of the above 1500 MHz band has been described in the first embodiment.
Since it is the same as that of the 00 MHz band antenna, its explanation is omitted, but its antenna characteristics are as shown in FIG.
Bandwidth: ΔW1 = 170 MHz is obtained in the 00 MHz band, bandwidth: ΔW2 = 90 MHz in the 1500 MHz band
As a result, it becomes possible to realize a multi-band compatible vehicle antenna device that can be used in any of these two frequency bands.

The antenna element used in this embodiment is also made of a plate-shaped material as shown in FIG. 7, so that the productivity is good. In the description of FIG. 7, two of three loop antennas are used to widen the 800 MHz band,
In the case of using one for a relatively narrow 1500 MHz band, in the case of supporting two bands that are relatively narrow, as shown in FIG. Good.

That is, FIG. 9 is exactly the same as FIG. 7 except that the second loop antenna 12 and its related components are removed from FIG. 7, and the first loop antenna 11 and the third loop antenna 11 are the same.
2 is an example in which two loop antennas including the loop antenna 10 of FIG.

As described above, according to the antenna device of the second embodiment, for example, 800M, which requires a relatively wide ratio band, is used.
The multi-band can be achieved for car telephones in the Hz band and the 1500 MHz band, which has a high frequency, and it is a low-profile antenna and has high productivity due to the flat antenna element.

Although the antenna element is formed of a flat plate in the description of the second embodiment, other shapes such as a round bar may be used, and FIGS. 3 to 6 showing a modification of the first embodiment. This configuration may be appropriately adopted in the second embodiment as well.

[0049]

As described above, according to the vehicle antenna device of the present invention as described in detail above, it is possible to achieve a sufficiently low posture and to make it compact so that it can be housed in a limited space. The requirements for high gain and omnidirectionality can be satisfied in terms of performance, and it is effective, for example, for single-band and multi-band car telephones. Can be applied to.

[Brief description of drawings]

1A is a perspective view showing a vehicle antenna device according to a first embodiment of the present invention, and FIG. 1B is a side view of the same.

2A and 2B are diagrams showing standing wave ratio characteristics, where FIG. 2A shows a case of using a wire rod, and FIG. 2B shows a case of using a plate member as shown in the first embodiment. Show.

FIG. 3 is a perspective view showing an antenna device according to a modification of the first embodiment of the present invention.

FIG. 4 is a perspective view showing an antenna device according to a modification of the first embodiment of the present invention.

FIG. 5A is a perspective view showing an antenna device according to a modification of the first embodiment, and FIG. 5B is an exploded view showing this antenna device.

FIG. 6 is a perspective view showing an antenna device according to a modification of the first embodiment.

7A is a perspective view showing an antenna device according to a second embodiment of the present invention, and FIG. 7B is a side view of the same.

FIG. 8 is a diagram showing antenna characteristics of the first embodiment.

FIG. 9A is a perspective view showing an antenna device according to a modification of the second embodiment, and FIG. 9B is a side view of the same.

[Explanation of symbols]

11, 12 ... First and second loop antennas, 11
1, 121 ... First and second parallel loop flat plates, 11
2, 122 ... Vertical short-circuit flat plate, 13 ... Ground conductor plate, 14 ...
Vertical feeding flat plate, 15 ... coaxial cable, 16 ... feeding point, 2
11, 221 ... Printed circuit boards, 212, 222, 25
1, 261 ... Loop, 25, 26 ... First and second dielectric substrates, 10 ... Third loop antenna, 131 ... Third
Parallel loop flat plate, 132 ... Vertical short-circuit flat plate

Claims (11)

[Claims] 1. A ground conductor plate made of a plate-shaped conductive member and provided in parallel with the ground conductor plate with a predetermined gap therebetween.
A first parallel loop portion made of a loop-shaped conductive member, and a conductive member having one end connected to the first parallel loop portion and the other end connected to the ground conductor plate via an insulating portion. A vertical feed part and a conductive member having one end connected to a position symmetrical to the position of the vertical feed plate with respect to the first parallel loop part and the other end connected to the vertical feed part; A short-circuited portion of No. 1 and a position between the ground conductor plate and the first parallel loop portion, a part of which is connected to the vertical power feeding unit and which is provided in parallel with the ground conductor plate. A second parallel loop portion formed of a conductive member, one end of which is connected to a position symmetrical to the position of the vertical power feeding portion with respect to the second parallel loop portion, and the other end of which is connected to the vertical power feeding portion. And a second short-circuit portion made of a conductive material, The parallel loop portion, the vertical feed portion, the ground conductor plate, and the first short-circuit portion form a first loop antenna, and the second parallel loop portion, the vertical feed portion, the ground conductor plate, and the second short-circuit portion form a first loop antenna. 2. A vehicle antenna device, wherein two loop antennas are configured, and the first loop antenna and the second loop antenna resonate at two different frequencies. 2. The first and second parallel loop portions are
The antenna device for a vehicle according to claim 1, wherein plate members each made of a conductive material are cut and formed in a loop shape. 3. The first and second parallel loop portions,
2. The vehicle antenna device according to claim 1, wherein each of the antenna devices is formed by forming a loop with a thin film of a conductor formed on the surface of an insulating substrate. 4. The first and second parallel loop portions,
It is formed by forming conductor thin films on the surfaces of the first and second flat plate-shaped bases each made of a dielectric material having a predetermined thickness, and etching the conductor thin films leaving loop shapes. The vehicle antenna device according to claim 1, wherein the first and second bases are set on a conductor plate in an overlapping manner. 5. The antenna device for a vehicle according to claim 1, wherein the first and second loop antennas are formed by cutting and bending one conductive plate material together with the ground conductor plate. 6. A grounding conductor plate, and a first parallel loop formed in parallel with the grounding conductor plate by setting a predetermined space above the grounding conductor plate and forming the conductive material into a loop shape. Section, a vertical power feeding section connected to the first parallel loop section and set perpendicularly to the first parallel loop section, and a position symmetrical to the position of the vertical power feeding plate with respect to the first parallel loop section. A first vertical short-circuit portion which is connected to the first parallel loop portion and which is vertically set to the first parallel loop portion to connect the first parallel loop portion and the ground conductor plate; It is located above the ground conductor plate and the first parallel loop portion and is provided in parallel with the ground conductor plate, and a conductive material is formed into a loop shape so that the vertical power feeding portion has the first parallel portion. A second parallel loop portion that is commonly connected to the loop portion, and A second parallel loop portion is connected to a position symmetrical to the position of the vertical power feeding portion, is set perpendicular to the parallel loop portion, and connects the parallel loop portion and the ground conductor plate to each other. Of the vertical short-circuit portion, the first parallel loop portion on the ground conductor plate, and the second parallel loop portion, and is provided in parallel with the ground conductor plate, and is made of a conductive material. And a third parallel loop portion in which the vertical power feeding portion is commonly connected to the first and second parallel loop portions, and the vertical power feeding portion with respect to the third parallel loop portion. A third vertical short-circuit portion which is connected to a position symmetrical to the position of the part and which is set perpendicularly to the third parallel loop part to connect the third parallel loop part and the ground conductor plate. And a first parallel loop portion, a vertical power feeding portion, a ground conductor plate, and The first vertical short-circuit portion constitutes a first loop antenna, and the second parallel loop portion, the vertical short-circuit portion, the ground conductor plate and the second vertical short-circuit portion constitute a second loop antenna, and An antenna device for a vehicle, wherein the parallel loop portion, the vertical power feeding portion, the ground conductor plate, and the third vertical short-circuit portion constitute a third loop antenna. 7. The vehicle according to claim 6, wherein each of the first, second and third parallel loop portions is formed by cutting a plate material made of a conductive material into a loop shape. Antenna device. 8. At least one of the first, second and third parallel loop portions is configured by forming a loop by a thin film of a conductor formed on the surface of an insulating substrate. 7. The vehicle antenna device according to claim 6. 9. A conductor thin film is formed on the surface of a flat plate-shaped base made of a dielectric material in which at least one of the first, second and third parallel loop portions has a predetermined thickness, and the conductor thin film is formed. The vehicle antenna device according to claim 6, wherein the thin film is formed by etching while leaving a loop shape, and the base is set on the ground conductor plate. 10. The at least one of the first, second and third loop antennas is formed by cutting out and bending one conductive plate material together with the ground conductor plate. The vehicle antenna device described. 11. A plurality of loop antennas that resonate at two or more different frequencies, a vertical feed element section shared by the plurality of loop antennas, and a plurality of vertical short-circuit element sections that the plurality of loop antennas separately have. And a grounding conductor plate that is connected to the vertical feeding element section and the plurality of vertical short-circuiting element sections and is shared by the plurality of loop antennas.