JP2004328330A - Antenna device, integrated antenna device and integrated mobile antenna device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To adequately control directivity to obtain the maximum gain of a radio wave radiated from an antenna device in the desired direction. <P>SOLUTION: In the integrated mobile antenna device 1, an antenna element 5 for VICS is mounted in a location deviated in the -x direction (direction opposed to the running direction of a vehicle) from the center of a circuit substrate 2. Moreover, a radio wave absorbing material 7 to absorb a leakage current outputted from an antenna element 3 for ETC is provided between the circuit substrate 2 and a ground plate 9. In addition, an antenna element 4 for GPS and the antenna element 3 for ETC are arranged in a positional relation in which the antenna device for GPS operates as a waveguide of the radio wave radiated from the antenna device for ETC. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an antenna device having an antenna element mounted on a circuit board, an integrated antenna device having a plurality of antenna elements having different frequency characteristics mounted on the same circuit board, and an in-vehicle integrated device configured to be mountable on a vehicle. The present invention relates to an antenna device.
[0002]
[Prior art]
Conventionally, for example, an antenna element for satellite communication used to acquire the current position of a vehicle, an antenna element for road-to-vehicle communication used to acquire congestion information, parking space information, etc. By mounting an antenna element for road-to-vehicle communication used for automatically collecting road tolls on the same circuit board, an antenna device for satellite communication and an antenna device for road-to-vehicle communication can be separated. There is an integrated antenna device (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP 2001-267843 A
[0004]
[Problems to be solved by the invention]
In this case, the reason that the antenna device for satellite communication is desired to have a hemispherical directivity in which the maximum gain is obtained in the zenith direction from the horizontal plane including the mounting position, and it is also desirable to have a small size and a low attitude. Therefore, the antenna is generally formed of a dielectric patch antenna, and is generally mounted on a central portion on a circuit board having an area larger than the mounting area in order to provide symmetry. On the other hand, the antenna device for road-to-vehicle communication starts in a direction inclined from the zenith direction to the traveling direction of the vehicle because the road-to-vehicle communication is started just before the roadside antenna installed at the gate of the traveling lane. There is a demand for directivity that provides a maximum gain.
[0005]
However, these satellite communication antenna devices and roadside-vehicle communication antenna devices have a problem that it is difficult to control the directivity so that the maximum gain is obtained in a desired direction.
[0006]
The present invention has been made in view of the above circumstances, and has as its object to provide an antenna device that can appropriately control directivity so that the maximum gain of a radiated radio wave is obtained in a desired direction. An object of the present invention is to provide an antenna device and a vehicle-mounted integrated antenna device.
[0007]
[Means for Solving the Problems]
According to the antenna device of the first aspect, since the antenna element is mounted at a position deviated from the center of the circuit board, for example, the antenna element is placed in the −x direction (horizontal direction) from the center of the circuit board. If the antenna is mounted at a position deviated from the antenna element, the main radio wave generated from the current flowing through the antenna element has directivity in which the maximum gain can be obtained in the + z direction (the zenith direction). The secondary radio wave generated from the current flowing through the circuit board due to the above has a large amount of current on the + x direction side when viewed from the antenna element on the circuit board, and therefore, is inclined in the + x direction from the + z direction. As a result, the combined radio wave obtained by combining the main radio wave and the sub radio wave, which is the radio wave from the antenna device, also has the maximum gain in the direction inclined from the + z direction to the + x direction. It is composed of a directional. Thus, when the antenna element is mounted at a position deviated from the center of the circuit board, the maximum gain of the radio wave radiated from the antenna device is adjusted in a desired direction by adjusting the degree of deviation from the center. The directivity can be appropriately controlled so as to be obtained.
[0008]
According to the antenna device described in claim 2, since the radio wave absorber that absorbs the leakage current output from the antenna element is provided between the circuit board and the ground plane, the leakage current output from the antenna element is provided. As a result, unnecessary radio waves are not radiated from the end of the base plate, and the main radio waves generated from the current flowing through the antenna element are not affected by the unnecessary radio waves. Thus, by providing the radio wave absorber, the directivity can be appropriately controlled so that the maximum gain of the radio wave radiated from the antenna device is obtained in a desired direction.
[0009]
According to the integrated antenna device described in claim 3, one of the plurality of antenna elements having different frequency characteristics acts as a director or a reflector of a radio wave radiated from another antenna device. Since one antenna element and another antenna element are arranged in a positional relationship, for example, if one antenna device acts as a director of a radio wave radiated from another antenna device, the other antenna device is used. The radio wave radiated from the antenna device is electromagnetically coupled with the one antenna device and re-radiated from the one antenna device. Thereby, by adjusting the positional relationship between one antenna element and another antenna element, the directivity is appropriately controlled so that the maximum gain of a radio wave radiated from another antenna device is obtained in a desired direction. be able to.
[0010]
According to the vehicle-mounted integrated antenna device of the fourth aspect, since the first antenna element for road-vehicle communication is mounted at a position off the center of the circuit board, for example, the first road-vehicle communication is achieved. Is mounted in a position deviated from the center of the circuit board in the -x direction (the direction opposite to the traveling direction of the vehicle), the current flowing through the first road-to-vehicle communication antenna element can be reduced. Although the generated main radio wave has directivity in which the maximum gain is obtained in the + z direction (zenith direction), the main radio wave is generated by the current flowing through the circuit board due to the first road-vehicle communication antenna element. The generated secondary radio wave includes a large amount of current on the circuit board in the + x direction (the traveling direction of the vehicle) when viewed from the first road-vehicle communication antenna element. Gain in the direction inclined to As a result, the combined radio wave obtained by combining the main radio wave and the sub radio wave, which is the radio wave from the first road-vehicle communication antenna device, also has the maximum gain in the direction inclined from the + z direction to the + x direction. Is obtained. Thereby, the directivity is set so that the maximum gain of the radio wave radiated from the first road-vehicle communication antenna device is obtained in a desired direction, in this case, in a direction inclined from the zenith direction to the traveling direction of the vehicle. Can be appropriately controlled.
[0011]
Also, since the radio wave absorber for absorbing the leakage current output from the second road-vehicle communication antenna element is provided between the circuit board and the ground plane, the second road-vehicle communication antenna element is provided. Unnecessary radio waves are not radiated from the end of the ground plane due to the leakage current output from the main plate, and the main radio waves generated from the current flowing through the second road-vehicle communication antenna element are unnecessary radio waves. Without being affected, the satellite communication antenna device is positioned in such a manner that the satellite communication antenna device acts as a director or a reflector of the radio wave radiated from the second road-to-vehicle communication antenna device. Since the antenna element and the second road-to-vehicle communication antenna element are arranged, for example, the antenna apparatus for satellite communication can be used as a director for radio waves radiated from the second road-to-vehicle communication antenna apparatus. Made as In this case, the radio wave radiated from the second road-vehicle communication antenna device is electromagnetically coupled with the satellite communication antenna device and is re-radiated from the satellite communication antenna device. Become. Thus, by providing the radio wave absorber and adjusting the positional relationship between the second road-vehicle communication antenna element and the satellite communication antenna element, radiation is radiated from the second road-vehicle communication antenna apparatus. The directivity can be appropriately controlled so that the maximum gain of the radio wave is also obtained in a desired direction, in this case, a direction inclined from the zenith direction to the traveling direction of the vehicle.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment in which the present invention is applied to a vehicle-mounted integrated antenna device configured to be mountable on a vehicle and integrated with a GPS antenna device, a VICS antenna device, and an ETC antenna device will be described with reference to the drawings. Will be explained. FIG. 1 is a perspective view showing the overall configuration of the vehicle-mounted integrated antenna device. FIGS. 2A and 2B show the vehicle-mounted integrated antenna device shown in FIG. This is shown by a side view.
[0013]
In the in-vehicle integrated antenna device 1, on the front surface 2a side (the upper surface side in FIG. 1) of the circuit board 2, the traveling direction of the vehicle is set to the + x direction, and the direction opposite to the traveling direction of the vehicle is set to the -x direction. From the + x direction to the −x direction, the ETC antenna element 3 (the second road-vehicle communication antenna element in the present invention) and the GPS antenna element 4 (the satellite communication antenna element in the present invention) ) And the VICS antenna element 5 (the first antenna element for road-to-vehicle communication in the present invention) are mounted in this order. In other words, the antenna element 3 for ETC and the antenna element 5 for VICS are mounted on an end of the circuit board 2 which is off the center, and the antenna element 4 for GPS is mounted on the center of the circuit board 2. Has been implemented.
[0014]
Each of the antenna elements 3 to 5 has a structure in which a dielectric is sandwiched between a radiation electrode and a ground electrode, and is constituted by a low-profile dielectric-loaded circularly polarized patch antenna. Also, the radio waves used in the ETC system are in the 5.8 GHz band, the radio waves used in the VICS system are in the 2.5 GHz band, and the radio waves used in the GPS system are in the 1.5 GHz band. Of the antenna elements 3 to 5, the circumference of the radiation electrode of the GPS antenna element 4 is the longest.
[0015]
A shield case 6 is mounted on the back surface 2 b side (the lower surface side in FIG. 1) of the circuit board 2. The shield case 6 is for amplifying a radio signal captured by the GPS antenna element 4. An electric circuit (not shown) including an amplifier and the like is built in. In this case, the shield case 6 is used to prevent radio waves radiated from the built-in electric circuit from leaking to the outside as unnecessary radio waves and to prevent external radio waves from being mixed as unnecessary radio waves. It is configured to have sexual characteristics.
[0016]
Further, on a lower surface of the shield case 6 and corresponding to the antenna element 3 for ETC, a flat radio wave absorber 7 made of a conductive metal material mixed with rubber or resin material is arranged. Is established. The circuit board 2, each of the antenna elements 3 to 5, the shield case 6, and the radio wave absorber 7 are housed in a rectangular parallelepiped antenna radome 8 (omitted in FIG. 1). It is arranged on the ground plate 9 which is also used. In this case, the shape of the base plate 9 is determined by the mounting position and the mounting space of the in-vehicle integrated antenna device 1, and the antenna element for the system having the lowest frequency (in this case, the antenna element 4 for GPS). ) Is formed as a square having a length of about 波長 wavelength based on the resonance frequency.
[0017]
From the shield case 6, a feed line 10 common to each of the antenna elements 3 to 5 is drawn out. In this case, a three-wave combining circuit (not shown) is mounted by sharing one feeder line 10 among the antenna elements 3 to 5 as described above. Note that a configuration may be adopted in which one of the antenna elements 3 to 5 shares one feed line, and in that case, a two-wave combining circuit (not shown) is mounted. .
[0018]
In the above configuration, the size of each component is as follows, as shown in FIG.
・ Entenna element 3 for ETC
Dimension "6mm" in the traveling direction of the vehicle x "9mm" in the vehicle width direction
X thickness "5mm"
・ GPS antenna element 4
Dimension "12mm" in the traveling direction of the vehicle x "18mm" in the vehicle width direction
X thickness "5mm"
・ VICS antenna element 5
Dimension "9 mm" in the traveling direction of the vehicle x "6 mm" in the vehicle width direction
X thickness "5mm"
・ Circuit board 2
Dimension "46mm" in the traveling direction of the vehicle x "46mm" in the vehicle width direction
X thickness "0.8mm"
・ Shield case
Thickness "3mm"
-Radio wave absorber 7
Dimension "20mm" in the traveling direction of the vehicle x "40mm" in the vehicle width direction
× Thickness "3mm"
・ Ground plate 9
Dimension "90mm" in the traveling direction of the vehicle x "90mm" in the vehicle width direction
[0019]
The distance between the antenna element 3 for ETC and the antenna element 4 for GPS in the traveling direction of the vehicle is “9 mm”, and the distance between the antenna element 4 for GPS and the antenna element 5 for VICS is set. Of the vehicle in the traveling direction is “10 mm”. In the drawings, in order to clarify the configuration of the present invention, the scale is different from the actual size.
[0020]
In the vehicle-mounted integrated antenna device configured as described above, the ETC antenna device includes the ETC antenna element 3 and the ground plane 9, and the GPS antenna apparatus includes the GPS antenna element 4 and the ground plane 9. , And the VICS antenna device is composed of the VICS antenna element 5 and the ground plane 9, that is, each antenna apparatus shares the ground plane 9 acting as a ground. The in-vehicle integrated antenna device 1 is mounted on an instrument panel of the vehicle.
[0021]
Next, the directivity of radio waves radiated from each of the GPS antenna device, the VICS antenna device, and the ETC antenna device will be sequentially described as the operation of the above configuration.
[0022]
(1) Directivity of radio wave radiated from GPS antenna device
First, the directivity of a radio wave radiated from the GPS antenna device will be described with reference to FIG. In FIG. 3, for convenience of explanation, only the GPS antenna element 4 is shown, and the ETC antenna element 3 and the VICS antenna element 5 are omitted. The radio wave radiated from the GPS antenna device includes a main radio wave generated from a current flowing through the GPS antenna element 4 and a sub radio wave generated from a current flowing through the circuit board 2 due to the GPS antenna element 4. It is determined by combination with the next radio wave.
[0023]
In this case, since the GPS antenna element 4 is mounted at the center of the circuit board 2 and the circuit board 2 has a shape larger than the GPS antenna element 4, the + z axis, which is the zenith direction, is used. The directivity is such that the maximum gain is obtained in the direction, and the gain decreases as the angle of inclination increases toward the low elevation angle. As a result, the directivity of the radio wave radiated from the GPS antenna device coincides with the communication area of the GPS system, so that the GPS antenna device can appropriately capture the GPS radio wave. Become. In FIG. 1, the directivity of radio waves radiated from the GPS antenna device is indicated by a two-dot chain line P.
[0024]
(2) Directivity of radio wave radiated from VICS antenna device
Next, the directivity of radio waves radiated from the VICS antenna device will be described with reference to FIG. In FIG. 4, for convenience of explanation, only the VICS antenna element 5 is shown, and the ETC antenna element 3 and the GPS antenna element 4 are omitted. The radio wave radiated from the VICS antenna device includes a main radio wave generated from a current flowing through the VICS antenna element 5 and a sub-wave generated from a current flowing through the circuit board 2 due to the VICS antenna element 5. It is determined by combination with the next radio wave.
[0025]
In this case, the VICS antenna element 5 is mounted at an end off the center of the circuit board 2, that is, the VICS antenna element 5 is shifted in the −x direction from the center of the circuit board 2. Since it is mounted at the position, the main radio wave generated from the current flowing through the VICS antenna element 5 has the directivity of obtaining the maximum gain in the + z direction. The secondary radio wave generated from the current flowing through the circuit board 2 due to the above-mentioned state has a large amount of current on the + x direction side as viewed from the VICS antenna element 5 on the circuit board 2, The directivity is such that the maximum gain is obtained in the direction inclined in the + x direction. As a result, the combined radio wave obtained by combining the main radio wave and the sub radio wave, which is the radio wave from the VICS antenna device, is also in the + x direction from the + z direction. Maximum gain is directivity obtained inclined direction.
[0026]
As a result, the directivity of the radio wave radiated from the VICS antenna device matches the communication area of the VICS system, so that the VICS antenna device can appropriately capture the VICS radio wave. Become. In FIG. 1, the directivity of radio waves radiated from the VICS antenna device is indicated by a two-dot chain line Q. The same principle is applied to the case where the antenna element 5 for VICS is linearly polarized.
[0027]
(3) Directivity of radio wave radiated from the ETC antenna device
Next, the directivity of a radio wave radiated from the ETC antenna device will be described with reference to FIGS. here,
(3-1) Influence by the presence or absence of the ground plate 9
(3-2) Influence by presence / absence of antenna element 4 for GPS
(3-3) Effect of presence / absence of radio wave absorber 7
Will be described sequentially.
[0028]
(3-1) Influence by the presence or absence of the ground plate 9
First, the "effect due to the presence or absence of the base plate 9" will be described with reference to FIGS. In FIG. 5, for convenience of explanation, only the antenna element 3 for ETC is shown, and the antenna element 4 for GPS and the antenna element 5 for VICS are omitted. In this case, the radio wave radiated from the ETC antenna device is caused by the main radio wave generated from the current flowing through the ETC antenna element 3 and the ETC antenna element 3 if the ground plane 9 is not provided. Is determined by synthesis with the secondary radio waves generated from the current flowing through the circuit board 2. On the other hand, if there is the ground plane 9, these main radio waves and the secondary radio waves, It is determined by combination with a radio wave generated from a current flowing through the ground plane 9 by being coupled to the ground plane 9 at high frequency from the circuit board 2 through the wall surface of the shield case 6. The radio wave generated from the current flowing through the ground plane 9 is dominant in the area at the end of the ground plane 9 (the area indicated by hatching M in FIG. 5).
[0029]
FIG. 6 shows a mode in which the directivity of the radio wave radiated from the antenna device for ETC changes depending on the presence or absence of the ground plane 9. The broken line indicates the characteristic when the ground plane 9 is not provided, and the solid line indicates the characteristic. And the base plate 9 are shown. As is clear from FIG. 6, the radio wave radiated from the ETC antenna device has directivity in which the maximum gain is obtained in a direction inclined about 30 deg from the + z direction to the −x direction when the ground plane 9 is not provided. However, if the ground plate 9 is provided, on the other hand, if the ground plate 9 is present, it is coupled to the ground plate 9 from the circuit board 2 through the wall surface of the shield case 6 at a high frequency and flows to the ground plate 9. Due to the influence of the radio waves generated from the current, the directivity is such that the maximum gain is obtained in a direction inclined by about 15 deg from the + z direction to the −x direction (see “arrow B” in FIG. 6).
[0030]
(3-2) Influence by presence / absence of antenna element 4 for GPS
Next, "effects due to the presence or absence of the GPS antenna element 4" will be described with reference to FIGS. In FIG. 7, for convenience of explanation, only the antenna element 3 for ETC and the antenna element 4 for GPS are shown, and the antenna element 5 for VICS is omitted. In this case, the radio wave radiated from the ETC antenna device is not electromagnetically coupled to the GPS communication antenna device if the GPS antenna element 4 is not provided. On the other hand, if the GPS antenna element 4 is provided, the antenna element 4 is electromagnetically coupled with the GPS communication antenna device and re-emitted.
[0031]
FIG. 8 shows a mode in which the directivity of the radio wave radiated from the antenna device for ETC in the state where the ground plane 9 is present changes depending on the presence or absence of the antenna element 4 for GPS. The characteristics when there is no antenna element 4 are shown, and the solid line shows the characteristics when there is the antenna element 4 for GPS. That is, the graph shown by the broken line in FIG. 8 is the same as the graph shown by the solid line in FIG.
[0032]
As is clear from FIG. 8, the radio wave radiated from the ETC antenna device in the state where the ground plane 9 is present is the same as that described in FIG. , The directivity at which the maximum gain is obtained in a direction inclined from the + z direction to the −x direction (the direction opposite to the traveling direction of the vehicle) (see “arrow B” in FIG. 8). If the antenna element 4 is provided, the radio wave radiated from the antenna device for ETC is electromagnetically coupled with the antenna device for GPS communication and re-radiated, so that the overall directivity is − Although it moves in the x direction, the positional relationship between the first maximum gain direction and the second maximum gain direction is reversed, so that the maximum gain is obtained from the + z direction in the + x direction (the traveling direction of the vehicle). (See “arrow C” in FIG. 8). This indicates that the influence of the presence or absence of the GPS antenna element 4 is greater than the influence of the presence or absence of the ground plane 9.
[0033]
FIG. 9 shows a mode in which the directivity of the radio wave radiated from the antenna device for ETC without the ground plane 9 changes depending on the presence or absence of the antenna element 4 for GPS. The characteristics when there is no antenna element 4 for GPS are shown, and the solid line shows the characteristics when there is an antenna element 4 for GPS. That is, the graph shown by the broken line in FIG. 9 is the same as the graph shown by the broken line in FIG.
[0034]
As is clear from FIG. 9, the radio wave radiated from the antenna device for ETC in the state where the ground plane 9 is not present is also the same as that in FIG. 6 described above if the antenna element 4 for GPS is not present. As described, although the directivity is such that the maximum gain is obtained in the direction inclined from the + z direction to the −x direction (see “arrow A” in FIG. 9), there is the GPS antenna element 4. In this case, the radio wave radiated from the antenna device for ETC is electromagnetically coupled with the antenna device for GPS communication and re-radiated, so that the entire directivity moves in the −x direction. When the positional relationship between the first maximum gain direction and the second maximum gain direction is reversed, the directivity is such that the maximum gain is obtained from the + z direction to the + x direction (see “arrow D” in FIG. 9). This also indicates that the influence of the presence or absence of the GPS antenna element 4 is greater than the influence of the presence or absence of the ground plane 9.
[0035]
FIG. 10 shows an aspect in which the directivity of the radio wave radiated from the ETC antenna device with the GPS antenna element 4 is changed depending on the presence or absence of the ground plane 9. 9 shows the characteristics in the case where there is no base plate 9, and the solid line shows the characteristics in the case where the base plate 9 is present. That is, the graph shown by the broken line in FIG. 10 is the same as the graph shown by the solid line in FIG. 9 described above, and the graph shown by the solid line in FIG. 10 is shown by the solid line in FIG. Same as the graph.
[0036]
(3-3) Effect of presence / absence of radio wave absorber 7
Next, "effects due to the presence or absence of the radio wave absorber 7" will be described with reference to FIG.
FIG. 11 shows a mode in which the directivity of the radio wave radiated from the antenna device for ETC in a state where the ground plate 9 and the antenna element 4 for GPS are present changes depending on the presence or absence of the radio wave absorber 7. Indicates the characteristics when the radio wave absorber 7 is not provided, and the solid line indicates the characteristics when the radio wave absorber 7 is provided. That is, the graph shown by the broken line in FIG. 11 is the same as the graph shown by the solid line in FIG. 8 and the graph shown by the solid line in FIG.
[0037]
As is clear from FIG. 11, the radio wave radiated from the ETC antenna device in the state where the ground plane 9 and the GPS antenna element 4 are present, when the radio wave absorber 7 is present, the radio wave is emitted from the + z direction to the + x direction. The first maximum gain is obtained in a direction inclined by about 23 deg (see the arrow E in FIG. 11), and the directivity is such that the second maximum gain is obtained near the zenith direction (0 deg) (FIG. 11). Middle "arrow F"). As a result, the directivity of the radio wave radiated from the ETC antenna device coincides with the communication area of the ETC system, so that the ETC antenna device can appropriately radiate and capture the ETC radio wave. It becomes possible. In FIG. 1, the directivity of the radio wave radiated from the antenna device for ETC is indicated by a two-dot chain line R.
[0038]
By the way, the configuration in which the antenna element 3 for ETC, the antenna element 4 for GPS, and the antenna element 5 for VICS are mounted on the circuit board 2 has been described above. Of these, even if only the antenna element necessary for the purpose or application is mounted on the circuit board 2, the same principle is applied. In addition, considering that the in-vehicle integrated antenna device 1 is attached to the instrument panel of the vehicle as described above, a certain restriction is imposed on the size of the entire device, so that the radiation is radiated from the ETC antenna device. As a method of controlling the directivity of radio waves, a method of providing the radio wave absorber 7 is more preferable than a method of adjusting the positional relationship between the antenna element 3 for ETC and the antenna element 4 for GPS.
[0039]
As described above, according to the present embodiment, in the in-vehicle integrated antenna device 1, the VICS antenna element 5 is displaced from the center of the circuit board 2 in the −x direction (the direction opposite to the traveling direction of the vehicle). Since it is mounted at the position, the main radio wave generated from the current flowing through the VICS antenna element 5 has directivity in which the maximum gain can be obtained in the + z direction. The secondary radio wave generated from the current flowing through the circuit board 2 has a large amount of current on the + x direction (the traveling direction of the vehicle) on the circuit board 2 when viewed from the VICS antenna element 5. , And a directivity in which the maximum gain is obtained in a direction inclined from the + z direction to the + x direction. As a result, the combined electric wave obtained by synthesizing the main electric wave and the auxiliary electric wave, which are electric waves from the VICS antenna device, also has a + z The directivity maximum gain is obtained in a direction inclined in the + x direction from the direction. Accordingly, when the VICS antenna element 5 is mounted at a position deviated from the center of the circuit board 2, the degree of the deviation from the center is adjusted, and the radio wave radiated from the VICS antenna device is adjusted. The directivity can be appropriately controlled so that the maximum gain is obtained in a desired direction, in this case, in the traveling direction of the vehicle.
[0040]
Further, in the integrated antenna device 1 mounted on the vehicle, the radio wave absorber 7 that absorbs the leakage current output from the antenna element 3 for ETC is provided between the circuit board 2 and the ground plane 9. Unnecessary radio waves are not emitted from the end of the base plate 9 due to the output leakage current, and the main radio waves generated from the current flowing through the antenna element 3 for ETC are affected by the unnecessary radio waves. In addition, the GPS antenna element 4 and the ETC antenna element 3 are arranged in such a positional relationship that the GPS antenna apparatus acts as a waveguide for radio waves radiated from the ETC antenna apparatus. Therefore, radio waves radiated from the ETC antenna device are electromagnetically coupled with the GPS antenna device and re-radiated from the GPS antenna device. Telecommunications is a directional maximum gain is obtained in a direction inclined from the + z-direction in the + x direction from the antenna device. Thus, by providing the radio wave absorber 7 and adjusting the positional relationship between the ETC antenna element 3 and the GPS antenna element 4, the maximum gain of the radio wave radiated from the ETC antenna device can be increased. Direction, in this case, directivity can be appropriately controlled so as to be obtained in the traveling direction of the vehicle.
[0041]
The present invention is not limited to the above-described embodiment, but can be modified or expanded as follows.
The present invention is not limited to a configuration applied to an integrated antenna device in which a GPS antenna device, a VICS antenna device, and an ETC antenna device are integrated, and is a configuration applied to an antenna device provided with an antenna device of another system. May be. Further, the present invention is not limited to the in-vehicle antenna device, and may be applied to an antenna device used for another purpose.
[0042]
A configuration in which the GPS antenna element and the ETC antenna element are arranged in a positional relationship such that the GPS antenna apparatus acts as a reflector of the radio wave radiated from the ETC antenna apparatus may be adopted.
The size of each component and the positional relationship of each antenna element may be any as long as they correspond to the desired direction in which the maximum gain of the radio wave is obtained.
[Brief description of the drawings]
FIG. 1 is a perspective view showing one embodiment of the present invention.
FIG. 2 is a side view
FIG. 3 is a diagram schematically showing the directivity of radio waves radiated from a GPS antenna device.
FIG. 4 is a diagram schematically showing the directivity of a radio wave radiated from an antenna device for VICS.
FIG. 5 is a diagram schematically showing the directivity of radio waves radiated from an antenna device for ETC.
FIG. 6 is a graph showing a mode in which the directivity of a radio wave radiated from an antenna device for ETC changes.
FIG. 7 is a diagram corresponding to FIG. 5;
FIG. 8 is a diagram corresponding to FIG. 6;
FIG. 9 is a diagram corresponding to FIG. 6;
FIG. 10 is a diagram corresponding to FIG. 6;
FIG. 11 is a diagram corresponding to FIG. 6;
[Explanation of symbols]
In the drawing, 1 is an integrated antenna device mounted on a vehicle, 2 is a circuit board, 3 is an antenna element for ETC (an antenna element for second road-to-vehicle communication), 4 is an antenna element for GPS (antenna element for satellite communication) Reference numeral 5 denotes an antenna element for VICS (first antenna element for road-to-vehicle communication), 7 denotes a radio wave absorber, and 9 denotes a ground plane.

Claims (4)

A combined radio wave in which an antenna element is mounted on a circuit board, and a main radio wave generated from a current flowing through the antenna element and a secondary radio wave generated from a current flowing through the circuit board due to the antenna element are synthesized. Is an antenna device radiated as radio waves from the antenna device,
An antenna device, wherein the antenna element is mounted at a position deviated from a central portion of the circuit board. An antenna device in which an antenna element is mounted on a circuit board, and a ground plane is disposed at a predetermined interval from the circuit board,
An antenna device, comprising: a radio wave absorber for absorbing a leakage current output from the antenna element between the circuit board and the ground plane. A plurality of antenna elements having different frequency characteristics are mounted on the same circuit board, and an integrated antenna device in which the plurality of antenna devices are integrated,
An integrated antenna device wherein one antenna element and another antenna element are arranged in a positional relationship such that one antenna device acts as a director or a reflector of a radio wave radiated from another antenna device. . A first antenna element for road-to-vehicle communication, a second antenna element for road-to-vehicle communication, and an antenna element for satellite communication having different frequency characteristics are mounted on the same circuit board. A ground plane is disposed at a predetermined interval from the circuit board, and a first roadside-vehicle communication antenna apparatus, a second roadside-vehicle communication antenna apparatus, and a satellite communication antenna apparatus are integrated. A vehicle-mounted integrated antenna device,
A first roadside-vehicle communication antenna element is mounted at a position off the center of the circuit board, and is output from the second roadside-vehicle communication antenna element between the circuit board and the ground plane. A radio wave absorber that absorbs leakage current is provided, and the satellite communication antenna device is positioned so as to act as a waveguide or a reflector of radio waves radiated from the second road-to-vehicle communication antenna device. A vehicle-mounted integrated antenna device, wherein the satellite communication antenna element and the second road-vehicle communication antenna element are arranged.

Images