JP2007295242A - Vehicle-mounted antenna and its mounting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To assure wideband antenna characteristics appropriately in each of a plurality of frequency bands. <P>SOLUTION: The element 3 of a loop antenna and the element 4 of a monopole antenna are fed with power at the same feeding point, and a parasitic antenna element 5 is arranged at such a position as electromagnetic coupling takes place between the parasitic antenna element 5 and the element 4 of a monopole antenna. When electromagnetic coupling takes place between the parasitic antenna element 5 and the element 4 of a monopole antenna, a current flows through the parasitic antenna element 5 and resonates on the low frequency side and the high frequency side of UHF band and VHF band. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an in-vehicle antenna mounted on a vehicle and a mounting method thereof.

As an antenna corresponding to a plurality of frequency bands, there is one in which a GPS antenna is mounted in the vicinity of a television antenna, and directivity and polarization characteristics are adjusted using a parasitic element (see, for example, Patent Document 1). .
JP 2005-102183 A

  However, in the above-described Patent Document 1, a television antenna connector and a GPS antenna connector are required separately, and the wiring increases, so that the assembling property is lowered and the cost is increased. There was a problem of becoming. On the other hand, in order to solve these wiring problems, the applicant has applied for Japanese Patent Application No. 2005-194931 as a configuration in which a loop antenna element and a monopole antenna element can be fed at the same feeding point.

  However, in this Japanese Patent Application No. 2005-194931, a wide band antenna characteristic can be secured by a loop antenna in one frequency band (for example, UHF band), but a monopole antenna in another frequency band (for example, VHF band). As a result, it is not possible to appropriately secure wideband antenna characteristics, and there is room for improvement.

  The present invention has been made in view of the above-described circumstances, and the object thereof is to avoid a reduction in assembling property and an increase in cost, and a plurality of frequency bands. An object of the present invention is to provide an in-vehicle antenna and a mounting method thereof that can appropriately ensure broadband antenna characteristics.

  According to the vehicle-mounted antenna according to claim 1, the element of the loop type antenna having an element length formed to a length corresponding to one frequency band among the plurality of frequency bands and the element length of the plurality of frequency bands Since the configuration is such that the element of the monopole antenna formed in the length corresponding to one of the low frequency side and the high frequency side of the other frequency band is fed at the same feeding point, the assembling property is It is possible to avoid a reduction or an increase in cost.

  In addition, a wide band antenna characteristic can be appropriately secured by a loop antenna in one frequency band, and the element length is formed to correspond to the other side of the low frequency side and the high frequency side of the other frequency band. Since the parasitic element is placed in a position where electromagnetic coupling occurs with the element of the monopole antenna and mounted on the vehicle, the parasitic element and the element of the monopole antenna Between the low frequency side and the high frequency side in other frequency bands, and the wideband antenna characteristics can be appropriately achieved in other frequency bands. Can be secured.

  According to the vehicle-mounted antenna according to claim 2, the element of the loop antenna is formed to have a length corresponding to the high frequency band as one frequency band, and the element of the monopole antenna is a low frequency band as the other frequency band. Since the loop antenna element and the monopole antenna element coexist, the size of the entire antenna can be reduced, and the in-vehicle antenna is, for example, an in-vehicle film antenna. As a result, the field of view can be appropriately secured even when mounted on a window.

  According to the on-vehicle antenna described in claim 3, the element of the monopole antenna is formed in a length corresponding to the high frequency side of the other frequency band, and the parasitic element corresponds to the low frequency side of the other frequency band. Since it is formed in length, the structure of the monopole antenna and the parasitic element can coexist and the size of the entire antenna can be reduced. The in-vehicle antenna is mounted on the window as an in-vehicle film antenna, for example. Even if it is a case, a visual field can be ensured appropriately.

  According to the vehicle-mounted antenna according to claim 4, the element length of the parasitic element is obtained by multiplying the wavelength of the radio wave on the other side of the low frequency side and the high frequency side of the other frequency band by about ¼, and the material of the mounting location. The length of the element is multiplied by the wavelength shortening rate due to the dielectric constant, and one end of the element is opened and the other end is grounded to the vehicle body and mounted on the vehicle. The antenna characteristics can be appropriately ensured by considering the wavelength shortening rate.

  According to the vehicle-mounted antenna according to claim 5, the element length of the parasitic element is obtained by multiplying the wavelength of the radio wave on the other side of the low frequency side and the high frequency side of the other frequency band by approximately ½, and the material of the mounting location. The length of the element is multiplied by the wavelength shortening rate, and both ends of the element are opened and mounted on the vehicle. A structure for grounding the power feeding element to the vehicle body can be eliminated, and the antenna characteristics can be appropriately ensured by considering the wavelength shortening rate.

  According to the vehicle-mounted antenna described in claim 6, since the parasitic element is formed in a meander shape, the shape of the parasitic element can be made compact and the element length can be shortened. For example, even if it is mounted on a window as an in-vehicle film antenna, the field of view can be appropriately secured.

  According to the method for mounting an in-vehicle antenna according to claim 7, the element of the loop antenna formed with a length corresponding to one frequency band among a plurality of frequency bands and the element length with a plurality of frequencies. A monopole antenna element formed to a length corresponding to one of the low frequency side and the high frequency side of the other frequency band in the band is fed at the same feeding point, and the element length is other frequency. A parasitic element formed in a length corresponding to the other side of the low frequency side and the high frequency side of the band is disposed at a position where electromagnetic coupling is generated with the element of the monopole antenna and is mounted on the vehicle. As a result, it is possible to obtain the same effects as those described in claim 1 above, and to prevent the assembly performance from being lowered and the cost from being increased. It can be avoided, moreover, it is possible to appropriately secure a broadband antenna characteristic in each of a plurality of frequency bands.

(First embodiment)
Hereinafter, as a first embodiment of the present invention, a case where it is applied to an in-vehicle film antenna that is affixed near a corner portion of a front window of a vehicle will be described with reference to FIGS.
FIG. 2 shows a front view of the in-vehicle film antenna. The in-vehicle film antenna 1 is configured by forming a loop type antenna element 3, a monopole type antenna element 4 and a parasitic element 5 on a film sheet 2 made of a transparent resin. In FIG. 1 and FIG. 2, for convenience of explanation, the fact that it is a transparent resin is indicated by a collection of dots.

  The element 3 of the loop type antenna has a shape bent at an acute angle at one point in the middle, and its element length (length from one end 3a to the other end 3b) is UHF band (470 MHz to 770 MHz). It is formed to a length obtained by multiplying the wavelength of the radio wave (one frequency band in the present invention) by about 1/2 and the wavelength shortening rate (0.7 to 0.8) due to the dielectric constant of the glass of the front window. The one end 3a is a power feeding portion and the other end 3b is a grounding portion.

  The element 4 of the monopole antenna has a shape bent at an acute angle at one point in the middle, and the element length (length from one end 4a to the other end 4b) is VHF band (90 MHz to 220 MHz). ) (The other frequency band in the present invention) is formed to have a length obtained by multiplying the wavelength of the radio wave on the high frequency side by approximately 1/4 and the wavelength shortening rate by the dielectric constant of the glass of the front window. The portion 4a is a power feeding portion, and the other end portion 4b is an open end portion.

  The parasitic element 5 has a shape bent at two points in the middle, and the element length (the length from one end portion 5a to the other end portion 5b) is the wavelength of the radio wave on the low frequency side of the VHF band. It is formed to have a length multiplied by approximately 1/4 and multiplied by a wavelength shortening rate due to the dielectric constant of the glass of the front window, and one end portion 5a is a grounding portion and the other end portion 5b is an open end portion. Has been.

  In this case, a part of the element 4 of the monopole antenna and a part of the parasitic element 5 are arranged in close proximity to each other and substantially parallel to each other. Electromagnetic coupling occurs at locations where they are arranged in parallel and close to each other, and a current flows through the parasitic element 5.

  As shown in FIG. 1, the vehicle-mounted film antenna 1 configured as described above has the ceiling portion 12 a and the pillar portion 12 b of the vehicle body 12 intersecting when the front window 11 is viewed from the inside (vehicle interior side) front. The film sheet 2 is attached to the front window 11 and mounted on the vehicle so that the power feeding parts 3a and 4a are arranged near the corner part. After the film sheet 2 is attached to the front window 11, the inner conductor (signal line) 13a of the power feeding coaxial cable 13 is connected to the power feeding portions 3a and 4a, and the outer conductor (ground line) 13b is conductive. The tape 14 is connected to the vehicle body 12 and grounded. The other end 3 b of the loop antenna element 3 is connected to the vehicle body 12 by the conductive tape 15 and grounded, and the one end 5 a of the parasitic element 5 is connected to the vehicle body 12 by the conductive tape 16. Grounded.

  As described above, according to the first embodiment, the element 3 of the loop antenna and the element 4 of the monopole antenna are configured to be fed at the same feeding point. In addition, since the parasitic element 5 is disposed at a position where electromagnetic coupling is generated with the element 4 of the monopole antenna, the parasitic element 5 can be avoided. And the element 4 of the monopole antenna generate electromagnetic coupling and current flows through the parasitic element 5, so that resonance can be achieved on both the low frequency side and the high frequency side of the VHF band, and even in the VHF band. Broadband antenna characteristics can be appropriately secured.

  In this case, the element 3 of the loop antenna is formed with a length corresponding to the UHF band, and the element 4 of the monopole antenna is formed with a length corresponding to the VHF band. The size of the antenna as a whole can be reduced by the configuration in which the element 4 of the type antenna coexists. In addition, since the element 4 of the monopole antenna is formed with a length corresponding to the high frequency side of the VHF band and the parasitic element 5 is formed with a length corresponding to the low frequency side of the VHF band, the monopole antenna With the configuration in which the element 4 and the parasitic element 5 coexist, the size of the entire antenna can be reduced.

  Further, the element length of the parasitic element 5 is formed by multiplying the wavelength of the radio wave in the VHF band by approximately 1/4 and the wavelength shortening rate due to the dielectric constant of the glass of the front window 11, and one end portion 5a thereof is formed. Since it is mounted so as to be grounded to the vehicle body 12 and the other end 5b is opened, the parasitic element 5 can be miniaturized and the antenna characteristics can be more appropriately considered by considering the wavelength shortening rate. Can be secured.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. In the second embodiment, in the in-vehicle film antenna 21, the parasitic element 23 is formed in a meander shape on the film sheet 22, and the element length (the length from the one end portion 23a to the other end portion 23b) is as described above. It is shorter than the parasitic element 5 described in the first embodiment.
According to the second embodiment, since the parasitic element 23 is formed in a meander shape, the shape of the parasitic element 23 can be made compact and the element length can be shortened. The size can be reduced, and even when mounted on the front window 11, a field of view can be appropriately secured.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIGS. In the third embodiment, in the in-vehicle film antenna 31, the parasitic element 33 is formed on the film sheet 32 in a shape that is substantially parallel to the ceiling portion 12 a of the vehicle body 12. In this case, the element length of the parasitic element 33 (the length from the one end portion 33a to the other end portion 33b) is substantially the same as the element length of the parasitic element 5 described in the first embodiment.
FIG. 5 shows the influence of the parasitic element 33 described above, and shows the measurement results of the VSWR (voltage standing wave ratio) when the parasitic element 33 is arranged and when it is not arranged. Yes. As is clear from FIG. 5, by providing the parasitic element 33, wideband antenna characteristics are secured in the VHF band.
According to the third embodiment, since the parasitic element 33 is formed in a shape substantially parallel to the ceiling portion 12a of the vehicle body 12, the field of view is appropriately secured even when mounted on the front window 11. can do.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. In the fourth embodiment, in the in-vehicle film antenna 41, a monopole element 43 and a parasitic element 44 are formed on the film sheet 42 so that the portions that are close to each other and are substantially parallel to each other become long. In this case, the element length of the monopole element 43 (the length from the one end portion 43a to the other end portion 43b) is substantially the same as the element length of the monopole element 4 described in the first embodiment. The element length of the parasitic element 44 (the length from the one end 44a to the other end 44b) is substantially the same as the element length of the parasitic element 5 described in the first embodiment.
According to the fourth embodiment, since the monopole element 43 and the parasitic element 44 are formed so that the portions that are substantially parallel and close to each other are long, the size of the entire antenna can be reduced. .

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described with reference to FIG. In the fifth embodiment, in the in-vehicle film antenna 51, the parasitic element 53 formed on the film sheet 52 has an element length (length from one end portion 53a to the other end portion 53b) having a low VHF band. It is formed to have a length obtained by multiplying the wavelength of the radio wave on the frequency side by approximately ½ and the wavelength shortening rate by the dielectric constant of the glass of the front window 11, and both end portions 53a and 53b are open ends. Yes.
According to the fifth embodiment, the element length of the parasitic element 53 is set to a length obtained by multiplying the wavelength of the radio wave in the VHF band by approximately ½ and the wavelength shortening rate due to the dielectric constant of the glass of the front window 11. Since both ends 53a and 53b are formed so as to be opened, a structure for grounding the parasitic element 53 to the vehicle body can be eliminated, and the antenna characteristics can be reduced by considering the wavelength reduction rate. Can be secured appropriately.

(Sixth embodiment)
Next, a sixth embodiment of the present invention will be described with reference to FIG. In the sixth embodiment as well, in the in-vehicle film antenna 61, the parasitic element 63 formed on the film sheet 62 has an element length (length from one end portion 63a to the other end portion 63b) having a low VHF band. It is formed to have a length obtained by multiplying the wavelength of the radio wave on the frequency side by approximately ½ and the wavelength shortening rate due to the dielectric constant of the glass of the front window 11, and both end portions 63a, 63b are open ends. Yes.
According to the sixth embodiment, the element length of the parasitic element 63 is set to a length obtained by multiplying the wavelength of the radio wave in the VHF band by approximately ½ and the wavelength shortening rate due to the dielectric constant of the glass of the front window 11. Since the both ends 63a and 63b are formed so as to be opened, the structure for grounding the parasitic element 63 to the vehicle body is not required in the same manner as that described in the fifth embodiment. In addition, the antenna characteristics can be appropriately secured by considering the wavelength shortening rate.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
The in-vehicle film antenna is not limited to a television antenna, but may be an antenna used for other purposes such as a radio antenna, a GPS antenna, a VICS antenna, and an ETC antenna. Not only the vicinity of the corner portion of the front window, but also the vicinity of the corner portion of the rear window, or another location away from the vicinity of the corner portion.

The front view which shows the 1st Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window Front view showing configuration of in-vehicle film antenna The front view which shows the 2nd Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window The front view which shows the 3rd Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window The figure which shows the measurement result of VSWR The front view which shows the 4th Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window The front view which shows the 5th Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window The front view which shows the 6th Embodiment of this invention and shows the aspect by which the vehicle-mounted film antenna was mounted in the front window

Explanation of symbols

  In the drawings, 1 is an in-vehicle film antenna, 3 is an element of a loop antenna, 4 is an element of a monopole antenna, 5 is a parasitic element, 21 is an in-vehicle film antenna, 23 is a parasitic element, 31 is an in-vehicle film antenna, 33 is a parasitic element, 41 is an in-vehicle film antenna, 43 is a monopole antenna element, 44 is a parasitic element, 51 is an in-vehicle film antenna, 53 is a parasitic element, 61 is an in-vehicle film antenna, and 63 is a parasitic element. It is.

Claims (7)

  An element of a loop antenna whose element length is formed to correspond to one frequency band among a plurality of frequency bands, and a low frequency side and a high frequency side of other frequency bands among the plurality of frequency bands Of the monopole antenna formed to a length corresponding to one of the elements, and the element length is formed to a length corresponding to the other of the low frequency side and the high frequency side of the other frequency band The loop antenna element and the monopole antenna element are fed at the same feeding point, and the parasitic element is electromagnetically coupled with the monopole antenna element. A vehicle-mounted antenna, which is mounted on a vehicle and is disposed at a position where the noise is generated. The in-vehicle antenna according to claim 1,
The element of the loop antenna is formed with a length corresponding to a high frequency band as one frequency band, and the element of the monopole antenna is formed with a length corresponding to a low frequency band as another frequency band. A vehicle-mounted antenna characterized by that. In the vehicle-mounted antenna according to claim 1 or 2,
The element of the monopole antenna is formed with a length corresponding to the high frequency side of another frequency band, and the parasitic element is formed with a length corresponding to the low frequency side of the other frequency band. In-vehicle antenna. The in-vehicle antenna according to any one of claims 1 to 3,
The element length of the parasitic element is obtained by multiplying the wavelength of the radio wave on the other side of the low frequency side and the high frequency side of the other frequency band by about 1/4 and the wavelength shortening rate by the dielectric constant of the material of the mounting location. The vehicle-mounted antenna is formed on the vehicle body, wherein one end of the element is opened and the other end is grounded to the vehicle body and mounted on the vehicle. The in-vehicle antenna according to any one of claims 1 to 3,
The length of the parasitic element is obtained by multiplying the wavelength of the radio wave on the other side of the low frequency side and the high frequency side of the other frequency band by about 1/2 and the wavelength shortening rate by the dielectric constant of the material of the mounting location. A vehicle-mounted antenna, which is formed on the vehicle and is mounted on a vehicle with both ends of the element being opened. In the vehicle-mounted antenna according to any one of claims 1 to 5,
A vehicle-mounted antenna, wherein the parasitic element is formed in a meander shape.   The element of the loop type antenna whose element length is formed to the length corresponding to one frequency band among the plurality of frequency bands and the element length of the low frequency side and the high frequency side of the other frequency band among the plurality of frequency bands The monopole antenna element formed with a length corresponding to one side is fed at the same feeding point, and the element length corresponds to the other side of the low frequency side and the high frequency side of the other frequency band. A method for mounting an in-vehicle antenna, characterized in that a parasitic element formed in a length is disposed at a position where electromagnetic coupling is generated with the element of the monopole antenna and mounted on a vehicle.

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