JP2005039594A - Antenna assembly and composite antenna assembly - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To take control of the directivity of an antenna without enlarging the whole of an assembly. <P>SOLUTION: In the antenna assembly 1, a first radiating element 2 and a second one 3 are mounted on a base plate 4, so that linear sides 2a to 2c and linear sides 3a to 3c are parallel to each other. Antenna currents through the linear sides 2a to 2c and the linear sides 3a to 3c flow parallel to reinforce each other, so that an array antenna can be formed between the first and second radiating elements 2, 3. Thus, appropriate control can be exercised over the directivity of composite radio waves made by combining the radio waves radiated from the first and second elements 2, 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an antenna device and a composite antenna device used for mobile communication, for example.

2. Description of the Related Art Conventionally, there is an antenna device that controls the directivity of radio waves by tilting a radiating element and mounting it on a substrate (see, for example, Patent Document 1).
JP-A-9-83242

  However, in the configuration in which the radiating element is tilted and mounted on the substrate, there is a problem in that the height of the antenna device increases as the radiating element is tilted, and the entire apparatus becomes large. In addition, when several radiating elements having different radio wave directivities are mounted on the same substrate, a configuration in which one of the radiating elements is inclined is complicated in the configuration for mounting these radiating elements. There was also a problem.

  The present invention has been made in view of the above circumstances, and a first object is to provide an antenna device that can appropriately control the directivity of radio waves in a desired direction without increasing the size of the entire device. The second object of the present invention is to provide a composite antenna device that can easily mount radiating elements when several radiating elements having different radio wave directivities are mounted on the same substrate. There is to do.

  According to the invention described in claim 1, each of the plurality of radiating elements each having at least two straight sides sandwiching the bent portion is provided, and at least one straight side of one radiating element and the other. Since one radiating element and another radiating element are mounted on the substrate so that at least one straight side of the radiating element is substantially parallel, at least one straight line in the one radiating element is provided. The antenna current flowing in the side portion and the antenna current flowing in the at least one straight side portion in the other radiating elements flow in substantially parallel and strengthen each other, so that an array is formed between one radiating element and another radiating element. An antenna can be formed.

  Therefore, the length and relative positional relationship between at least one straight side portion in one radiating element and at least one straight side portion in the other radiating element are adjusted in a substantially parallel relationship. By adjusting the phase difference between the antenna currents flowing in substantially parallel, the combined radio wave of the radio wave radiated from one radiating element and the radio wave radiated from another radiating element, that is, radiated from a plurality of radiating elements The directivity of radio waves can be controlled. As a result, unlike conventional ones, it is not necessary to incline the radiating elements and mount them on the board, and the directivity of radio waves is controlled appropriately in the desired direction without increasing the overall size of the device. can do.

  According to the second aspect of the present invention, since one radiating element and the other radiating element are configured in the same shape and mounted in a substantially point-symmetrical position, the location where the antenna current flows substantially in parallel The array antenna can be efficiently formed between one radiating element and another radiating element.

  According to the invention described in claim 3, since one radiating element and another radiating element are connected by a microstrip line, a feeding point and an antenna current for flowing an antenna current to the one radiating element are It is possible to eliminate the need to separately provide a feeding point for flowing to another radiating element, and the configuration can be simplified.

  According to the invention described in claim 4, the plurality of radiating elements according to any one of claims 1 to 3 and another radiation that radiates radio waves having different directivities from the radio waves radiated from the plurality of radiating elements. Since it is configured to mount a plurality of radiating elements and different radiating elements on the same substrate, when mounting several radiating elements having different radio wave directivities on the same substrate, Without radiating any of the radiating elements, the radiating elements can be easily mounted, and the directivity of the radio wave radiated from the radiating elements can be appropriately controlled.

  According to the invention described in claim 5, since the plurality of radiating elements and another radiating element are mounted on the same substrate via the same dielectric, the portion mounted via the dielectric, The antenna performance of these radiating elements can be improved, and the number of parts can be reduced by sharing the dielectric by making the dielectric on which a plurality of radiating elements are mounted the same as the dielectric on which another radiating element is mounted. Can be reduced.

  According to the invention described in claim 6, since another radiation element is mounted between one radiation element and another radiation element among the plurality of radiation elements, the one radiation element and the other radiation element are mounted. The space between the elements can be used effectively, and the entire apparatus can be reduced in size.

(First embodiment)
A first embodiment in which the present invention is applied to an antenna device used for ETC communication will be described below with reference to FIGS. FIG. 1 is an external perspective view of the antenna device. The antenna device 1 is configured by mounting a first radiating element 2 (one radiating element referred to in the present invention) and a second radiating element 3 (other radiating elements referred to in the present invention) on a substrate 4. Yes.

  The first radiating element 2 is formed to have a length corresponding to one wavelength of a radio wave (5.8 GHz band radio wave) used in ETC communication, and is bent at two locations, thereby The straight side portions 2a to 2c are configured in a crank shape with the bent portions 2d and 2e sandwiched therebetween. In this case, the bending angle of the bent portions 2d and 2e is “90 degrees”. Similar to the first radiating element 2, the second radiating element 3 is formed in a length corresponding to one wavelength of a radio wave used in ETC communication, and is bent at two locations. The three straight side portions 3a to 3c are formed in a crank shape sandwiching the bent portions 3d and 3e. Also in this case, the bending angle of the bent portions 3d and 3e is “90 degrees”.

  The first radiating element 2 is mounted at a predetermined interval from the substrate 4 so that both ends thereof are supported by the vertical pins 5 and 6, and the second radiating element 3 is Both ends are mounted on the vertical pins 7 and 8 so as to be supported at a predetermined distance from the substrate 4. The reason why each of the first radiating element 2 and the second radiating element 3 is formed in a crank shape is to generate circularly polarized waves.

  The first radiating element 2 and the second radiating element 3 have the same shape and are mounted at point-symmetrical positions rotated by “180 degrees” about the point “O” in the figure as a point-symmetrical center. . In other words, the straight side 2a in the first radiating element 2 and the straight side 3a in the second radiating element 3 are in a parallel relationship, and the straight side 2b in the first radiating element 2 and the second radiating element 3 has a parallel relationship with the straight side 3b, and the straight side 2c of the first radiating element 2 and the straight side 3c of the second radiating element 3 have a parallel relationship. The point “O” is also the center of the substrate 4.

  A point where the vertical pin 5 connected to the first radiating element 2 is in contact with the substrate 4 is a feeding point 9, and further, a vertical pin 6 connected to the first radiating element 2 and The vertical pin 7 connected to the second radiating element 3 is connected by a microstrip line 10.

  Next, the effect | action of an above-described structure is demonstrated with reference to FIG. 2 and FIG. In the configuration described above, the antenna current flows to the first radiating element 2 by being fed from the feeding point 9 to the first radiating element 2. Further, power is supplied from the feeding point 9 to the second radiating element 3 through the first radiating element 2 and the microstrip line 10, whereby an antenna current flows to the second radiating element 3.

  In this case, since the first radiating element 2 and the second radiating element 3 have the same shape and are mounted in a point-symmetrical position, the antenna current flowing in the linear side portion 2a in a certain time zone. And the antenna current flowing in the straight side portion 3a flow in parallel and strengthen each other, and the antenna current flowing in the straight side portion 2b and the antenna current flowing in the straight side portion 3b flow in parallel and strengthen each other. Thus, the antenna current flowing through the straight side 2c and the antenna current flowing through the straight side 3c flow in parallel and strengthen each other. As a result, the first radiating element 2 and the second radiating element 3 form an array antenna.

Here, the inventors measured the influence on the radio wave directivity of the length of the straight side portions 2a to 2c in the first radiating element 2 and the length of the straight side portions 3a to 3c in the second radiating element 3. . The inventors changed the lengths of the straight side portions 2a to 2c in the first radiating element 2 and the lengths of the straight side portions 3a to 3c in the second radiating element 3 to values shown in FIG. The directivity of radio waves in the case of was measured. In FIG. 2, “L ₁₁ ” to “L ₁₃ ” are the lengths of the straight side portions 2 a to 2 c in the first radiating element 2, and “L ₂₁ ” to “L ₂₃ ” are This is the length of the straight side portions 3a to 3c in the second radiating element 3.

  As apparent from FIG. 2, the length of the straight side portions 2a to 2c in the first radiating element 2 and the length of the straight side portions 3a to 3c in the second radiating element 3 are adjusted, and the antenna current flowing in parallel is adjusted. By adjusting the phase difference, the directivity of the combined radio wave of the radio wave radiated from the first radiating element 2 and the radio wave radiated from the second radiating element 3 can be controlled in a desired direction. That is, in the case of ETC communication, as shown in FIG. 3, the directivity of radio waves is controlled to a direction inclined by “about 23 degrees” with respect to the traveling direction of the vehicle (left direction in FIG. 3) from the zenith direction. be able to. In this case, the inventors measured with the relative positional relationship between the first radiating element 2 and the second radiating element 3 fixed, but the first radiating element 2 and the second radiating element were measured. 3 to change the directivity of the combined radio wave of the radio wave radiated from the first radiating element 2 and the radio wave radiated from the second radiating element 3 in a desired direction. Can be controlled.

  As described above, according to the first embodiment, in the antenna device 1, the first radiating element 2 and the second radiating element are arranged so that the straight side portions 2 a to 2 c and the straight side portions 3 a to 3 c are parallel to each other. Since the element 3 is mounted on the substrate 4, the antenna currents flowing through the straight side portions 2 a to 2 c and 3 a to 3 c flow in parallel and strengthen each other, so that the first radiating element 2 and the second radiating element 2 An array antenna can be formed with the radiating element 3. Therefore, by adjusting the length and relative positional relationship of the straight side portions and adjusting the phase difference between the antenna currents flowing in parallel, the radio wave radiated from the first radiating element 2 and the second radiating element 3 are adjusted. The directivity of the combined radio wave with the radio wave radiated from the radio wave can be controlled, so that the radio wave directivity can be appropriately controlled in a desired direction without increasing the size of the entire apparatus.

In this case, since the first radiating element 2 and the second radiating element 3 are configured in the same shape and mounted in a point-symmetric position, the number of locations where the antenna current flows in parallel is increased. The array antenna can be efficiently formed between the first radiating element 2 and the second radiating element 3.
Further, in this case, since the first radiating element 2 and the second radiating element 3 are connected by the microstrip line 10, the feeding point and the antenna current for flowing the antenna current to the first radiating element 2 are used. It is possible to eliminate the need to separately provide a feeding point for flowing the current to the second radiating element 3, and the configuration can be simplified.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 1st Embodiment, and a different part is demonstrated. In the second embodiment, in the antenna device 11, the first radiating element 2 and the second radiating element 3 described in the first embodiment are mounted on the substrate 4 via the dielectric 12. In this case, the microstrip line 13 connecting the first radiating element 2 and the second radiating element 3 is described in the first embodiment because of the influence of the dielectric 12 disposed on the substrate 4. The microstrip line 10 has a different pattern shape.

  As described above, according to the second embodiment, in the antenna device 11, the first radiating element 2 and the second radiating element 3 are mounted on the substrate 4 via the dielectric 12. The antenna performance can be improved by the amount of mounting via the dielectric 12.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 1st Embodiment, and a different part is demonstrated. The third embodiment is applied to a composite antenna device in which a radiating element used for ETC communication and a radiating element used for GPS communication are mounted on the same substrate.

  That is, in the third embodiment, the composite antenna device 21 includes the first radiating element 2 and the second radiating element 3 described in the first embodiment described above mounted on the substrate 4 and GPS communication. A quadrangular third radiating element 22 (another radiating element referred to in the present invention) used in the above is mounted on the substrate 4 via a dielectric 23. In this case, the quadrangular third radiating element 22 is mounted in the space between the first radiating element 2 and the second radiating element 3 at the center of the substrate 4.

  As described above, according to the third embodiment, in the composite antenna device 21, the first radiating element 2 and the second radiating element 3 used for the ETC communication described in the first embodiment and the GPS communication. Since the third radiating element 22 used in the above is mounted on the substrate 4, when the radiating elements 2, 3, and 22 having different radio wave directivities are mounted on the same substrate 4, these radiating elements are used. The radiating elements 2, 3, and 22 can be easily mounted without mounting any of the radiating elements 2, 3, and 22, and the directivity of the radio waves radiated from the radiating elements 2, 3, and 22 Gender can be controlled appropriately. In addition, the space between the first radiating element 2 and the second radiating element 3 can be used effectively, and the entire apparatus can be reduced in size.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 3rd Embodiment, and a different part is demonstrated. In the fourth embodiment, the composite antenna device 31 includes the first radiating element 2, the second radiating element 3, and the third radiating element 22 described in the third embodiment via the same dielectric 32. It is mounted on the substrate 4.

  As described above, according to the fourth embodiment, in the composite antenna device 31, the first radiating element 2, the second radiating element 3, and the third radiating element 22 are connected via the same dielectric 32. Since it is configured to be mounted on the substrate 4, the antenna performance can be improved by the amount of mounting via the dielectric 32, and the dielectric on which the first radiating element 2 and the second radiating element 3 are mounted. By sharing the dielectric with the same dielectric that mounts the third radiating element, the number of components can be reduced.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
As shown in FIG. 7, in the antenna device 41, each of the first radiating element 42 and the second radiating element 43 may be bent at one location. Further, as shown in FIG. 8, in the antenna device 51, each of the first radiating element 52 and the second radiating element 53 may be bent at three locations.
In each embodiment, the bending angle at which the linear side portion is bent may be an angle other than “90 degrees”.
The number of radiating elements that control the directivity of radio waves may be two or more.

FIG. 1 is an external perspective view showing a first embodiment of the present invention. A diagram showing the relationship between the length of the straight side and the directivity of radio waves Diagram showing changes in directivity of radio waves External perspective view showing a second embodiment of the present invention External perspective view showing a third embodiment of the present invention External perspective view showing a fourth embodiment of the present invention External perspective view showing another embodiment of the present invention 7 equivalent diagram

Explanation of symbols

In the drawings, 1 is an antenna device, 2 is a first radiating element (one radiating element), 2a to 2c are straight side portions, 2d and 2e are bent portions, and 3 is a second radiating element (other radiating elements). 3a to 3c are straight side portions, 3d and 3e are bent portions, 4 is a substrate, 10 is a microstrip line, 11 is an antenna device, 12 is a dielectric, 13 is a microstrip line, 21 is a composite antenna device, and 22 is Third radiating element (another radiating element), 23 is a dielectric, 31 is a composite antenna device, 32 is a dielectric, 41 is an antenna device, 42 is a first radiating element, 43 is a second radiating element, 51 Is an antenna device, 52 is a first radiating element, and 53 is a second radiating element.

Claims (6)

  Each includes a plurality of radiating elements each having at least two straight sides sandwiching the bent portion, and at least one straight side in one radiating element and at least one straight side in another radiating element An antenna device characterized in that one radiating element and another radiating element are mounted on a substrate so that and are substantially parallel to each other. The antenna device according to claim 1, wherein
An antenna device, wherein one radiating element and another radiating element are configured in the same shape and mounted at a substantially point-symmetrical position. In the antenna device according to claim 1 or 2,
An antenna device, wherein one radiating element and another radiating element are connected by a microstrip line.   A plurality of radiating elements according to any one of claims 1 to 3 and another radiating element that radiates radio waves having different directivities from radio waves radiated from the plurality of radiating elements. A radiating element is mounted on the same substrate. In the composite antenna device according to claim 4,
A composite antenna apparatus comprising a plurality of radiating elements and another radiating element mounted on the same substrate via the same dielectric. In the composite antenna device according to claim 4 or 5,
A composite antenna device, wherein another radiating element is mounted between one radiating element and another radiating element among a plurality of radiating elements.

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