JP5422717B1 - Low profile antenna device - Google Patents

Abstract

A while suppressing the height sufficiently wide-band to provide a provide a low profile antenna device possible.
A low-profile antenna device includes a conductor plate, an inverted L-type or inverted-F antenna element, and a parasitic element. The antenna element 20 includes an antenna upright portion 21 that rises from the conductor plate 10 and an antenna main body portion 22 that is bent and extends from the tip of the antenna upright portion 21. The parasitic element 30 includes a parasitic rising portion 31 that rises from the conductor plate 10 and a parasitic body portion 32 that is bent and extends from the tip of the parasitic rising portion 31. The parasitic rising portion 31 is an antenna rising portion. At least a part extends along the antenna upright portion 21 so as to face each band so as to be excited by the antenna 21, and the parasitic body portion 32 is seen from above the conductor plate 10. It extends so that the space | interval with 22 becomes wider than the space | interval of the parasitic standup 31 and the antenna standup 21.
[Selection] Figure 1

Description

  The present invention relates to a low-profile antenna device, and more particularly to a low-profile antenna device that uses a parasitic element to achieve a wide band by a double resonance effect.

  Currently, various antenna devices are mounted on vehicles. As such antenna devices, for example, there are AM / FM radio antennas capable of receiving AM broadcasts and FM broadcasts, and as AM / FM radio antennas, Generally, a rod antenna is used. The rod antenna includes an element portion in which an element (helical element) made of a spiral conductor is covered with a cover, and a base portion for attaching the element portion.

  When this rod antenna is attached to the vehicle body, the element part protrudes greatly from the vehicle body, which may damage the aesthetics and design of the vehicle, may be damaged during garage storage or car washing, and is exposed outside the vehicle. There is also a risk that the element part may be stolen.

  Due to these problems, the height of the entire antenna device is made lower than that of the rod antenna, and the element is housed in the antenna case to protect it from being exposed to the outside of the vehicle. A low-profile antenna device configured with a shark fin shape (shark fin shape) has been proposed. Many of such low-profile antenna devices have a height of 70 mm or less and a length in the longitudinal direction of around 200 mm in consideration of legal regulations and the like.

However, such a low-profile antenna device has problems such as narrowing of the frequency band and low gain due to the influence of the low posture of 70 mm or less. Therefore, various low-profile antenna devices that use a parasitic element to achieve a wide band by the double resonance effect have been developed. For example, Patent Document 1, by etching the conductive thin film on a dielectric substrate disposed vertically, placing the inverted L-shaped antenna element and the parasitic element up and down with respect to the base, the purpose of wide-band A low-profile antenna device is disclosed.

JP 2003-258527 A

  However, the low-profile antenna device disclosed in Patent Document 1 described above has a configuration in which the antenna element and the parasitic element are arranged above and below, so that the height cannot be sufficiently reduced. Further, since the antenna characteristics become worse as the antenna element approaches the base, it has been difficult to obtain sufficient characteristics while suppressing the height. Furthermore, the antenna element and the parasitic element are configured by etching the conductive thin film on the substrate, and the opposing surface of the antenna element and the parasitic element is only the thickness of the conductive thin film. Therefore, the double resonance effect may not be sufficiently obtained.

In view of the such circumstances, it is intended to provide a low profile antenna device capable of sufficiently broad banded while suppressing the height.

  In order to achieve the above-described object of the present invention, a low profile antenna device according to the present invention is an inverted L type comprising a conductor plate having a feeding point and a short-circuit point, and a conductor having a belt surface perpendicular to the conductor plate. Alternatively, an inverted F-type antenna element, which is connected to a feeding point of a conductor plate, and includes an antenna upright standing up from the conductor plate and an antenna main body bent and extended from the tip of the antenna upright, A parasitic element composed of a type or inverted-F antenna element and a conductor having a strip surface perpendicular to the conductor plate, connected to the short-circuit point of the conductor plate, It consists of a parasitic body that bends and extends from the tip of the feed erection, and at least a part of the parasitic erection faces each other along the antenna erection so as to excite the antenna erection So that it extends approximately parallel and is unpaid The main body portion is intended the distance between the antenna body extends so as to be wider than the distance between the parasitic raised portion and the antenna raised portion comprises a parasitic element.

  Here, the parasitic body of the parasitic element extends from the top of the conductor plate so that the distance from the antenna body gradually increases from the parasitic stand-up to the open end and the open end is widest. If it is good.

  The parasitic body of the parasitic element may extend so that the distance from the antenna body as viewed from the top of the conductor plate is widest from the parasitic stand up to the middle of the open end. .

  Further, the antenna element may be folded so that the antenna upright portion and / or the antenna main body portion can increase the electrical length.

  The low-profile antenna device of the present invention has an advantage that a sufficiently wide band can be achieved while suppressing the height.

FIG. 1 is a schematic view for explaining a low-profile antenna device of the present invention. FIG. 2 is a VSWR characteristic graph when the distance between the antenna main body and the parasitic main body is changed in the low-profile antenna device of the present invention. FIG. 3 is a schematic top view for explaining another example of the low-profile antenna device of the present invention. FIG. 4 is a VSWR characteristic graph when the distance between the antenna main body and the parasitic main body is changed in the low profile antenna apparatus of the present invention shown in FIG. FIG. 5 is a partial cross-sectional schematic side view for explaining an example in which the antenna element of the low profile antenna device of the present invention is deformed. FIG. 6 is a schematic diagram for explaining an example in which an inverted F-type antenna element is used in the low-profile antenna device of the present invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described together with illustrated examples. FIG. 1 is a schematic diagram for explaining a low-profile antenna device of the present invention, in which FIG. 1 (a) is a perspective view, FIG. 1 (b) is a side view, and FIG. 1 (c) is a top view. Respectively. As illustrated, the low-profile antenna device of the present invention is mainly composed of a conductor plate 10, an antenna element 20, and a parasitic element 30.

  The conductor plate 10 is a conductive plate-like body having a feeding point 11 and a short-circuit point 12. For example, a signal line of a coaxial cable for feeding from a tuner is connected to the feeding point 11. The short-circuit point 12 is grounded, for example, is directly short-circuited to the conductor plate 10. For example, the conductor plate 10 may be formed of a conductive plate itself, or may be formed of a dielectric substrate having a conductive thin film provided on the surface.

  In the illustrated example, the antenna element 20 is an inverted L-type antenna element. The inverted L-type antenna element 20 in the illustrated example is made of a conductor having a band surface perpendicular to the conductor plate 10. The antenna element 20 is connected to the feeding point 11 of the conductor plate 10. The antenna element 20 includes an antenna upright portion 21 and an antenna body portion 22. The antenna upright portion 21 is a portion that rises from the conductor plate 10. The antenna main body 22 extends from the tip of the antenna upright portion 21 while being bent. Specifically, the inverted L-type antenna element 20 is an L-shaped conductor having a band surface having a predetermined width in the vertical direction with respect to the conductor plate 10. The antenna body 22 is on the long side of the L shape.

  The parasitic element 30 is made of a conductor having a band surface perpendicular to the conductor plate 10. The parasitic element 30 is connected to the short-circuit point 12 of the conductor plate 10. The parasitic element 30 includes a parasitic upper portion 31 and a parasitic main body 32. The non-powered rising portion 31 is a portion that rises from the conductor plate 10. Further, the parasitic body 32 is bent and extends from the tip of the parasitic stand 31. Here, in the low-profile antenna device of the present invention, the parasitic erected portion 31 is at least partially parallel to each other along the antenna erected portion so as to be excited by the antenna erected portion 21. It is extended. That is, the band surface of the antenna upright portion 21 and the band surface of the non-feeding upright portion 31 are arranged so as to increase the facing area. As a result, the parasitic upper portion 31 excites the antenna upper portion 21 more strongly. For this reason, the double resonance effect appears more strongly. Further, in order to widen the band by obtaining the multiple resonance effect, the parasitic element 30 only needs to have an electrical length different from that of the antenna element 20. Generally, the parasitic element 30 may be configured to be shorter than the antenna element 20 and the band may be widened to the high band side with respect to the target frequency of the antenna element 20. The parasitic body 32 extends so that the distance between the parasitic body 31 and the antenna body 22 is wider than the gap between the parasitic body 31 and the antenna 21 when viewed from above the conductor plate 10. That is, in the state of FIG. 1C, the parasitic body 32 extends so that the distance from the antenna body 22 gradually increases from the parasitic standup 31 to the open end, and the open end becomes the widest. Yes. The non-feeding main body 32 may extend linearly so that the open end is wide as in the illustrated example, or may extend so that the open end is wide in an arcuate shape. Furthermore, in the illustrated example, the example in which the parasitic main body 32 side is separated from the antenna main body 22 is shown, but the present invention is not limited to this, and the antenna main body side is separated from the parasitic main body side. Of course, it may be configured as follows. That is, the antenna main body and the parasitic main body may be arranged so that the open end side is widest. Furthermore, not only is the relationship widened when viewed from the top of the conductor plate, but the distance between the antenna body and the parasitic body when viewed from the side of the conductor plate becomes wider toward the open end. You may arrange | position so that it may become wide by a relationship, ie, an up-and-down relationship.

  FIG. 2 is a VSWR characteristic graph when the distance between the antenna main body and the parasitic main body is changed in the low-profile antenna device of the present invention. Specifically, the gap between the antenna main body 22 and the parasitic main body 32 on the feeding point 11 side (W1 in FIG. 1C) is fixed to 4 mm, and the open end side is gradually widened. It is a VSWR characteristic when the distance (W2 in FIG. 1C) on the open end side is changed to 4 mm, 7 mm, and 15 mm. As shown in the figure, it can be seen that the band becomes wider as the open end side becomes wider.

  As described above, in the low-profile antenna device of the present invention, the antenna upright portion and the parasitic stand-up portion are configured such that the band faces face each other, and the antenna main body portion and the parasitic main body portion are gradually widened on the open end side. By doing so, it is possible to increase the bandwidth while suppressing the height.

  In the illustrated example described above, an example in which the antenna main body and the parasitic main body are gradually widened on the open end side has been described. However, the present invention is not limited to this, and some intervals are widened. It does not matter. FIG. 3 is a schematic top view for explaining another example of the low-profile antenna device of the present invention. In the figure, the parts denoted by the same reference numerals as those in FIG. As shown in the figure, the low-profile antenna device of the present invention may be configured such that the gap between the parasitic main body 32 and the antenna main body 22 is widest from the parasitic upper end 31 to the middle of the open end. . That is, the parasitic body part 32 may be configured in a U shape when viewed from the top of the conductor plate 10. Even if comprised in this way, compared with the case where an antenna main-body part and a parasitic body part are arrange | positioned in parallel, a broadband-ization is attained.

FIG. 4 is a VSWR characteristic graph when the distance between the antenna main body and the parasitic main body is changed in the low profile antenna apparatus of the present invention shown in FIG. Specifically, the distance between the antenna body 22 and the parasitic body 32 on the feeding point 11 side (W1 in FIG. 3) is fixed to 4 mm, and the center distance (W2 in FIG. 3) is changed to 4 mm and 15 mm. VSWR characteristics when the distance (W3 in FIG. 3) on the open end side is changed to 4 mm and 15 mm. As shown in the figure, when W1-W2-W3 is 4 mm-15 mm-15 mm, the widest band is obtained. It can be seen that the band is wider than when the main body 22 and the non- feed main body 32 are arranged in parallel at an interval of 4 mm (4 mm-4 mm-4 mm). Thus, depending on the antenna arrangement, the central portion may swell and the open end side may be closed. For example, even if the appearance of the antenna device is a case where there is not much space at the tip portion, if there is a space at the center portion, it is possible to increase the bandwidth by widening the interval between the center portions.

  In FIG. 1 and the like, the antenna element 20 and the parasitic element 30 have substantially the same shape. However, the present invention is not limited to this, as long as they are opposed to the extent that a double resonance effect is obtained. The antenna element 20 and the parasitic element 30 of the present invention are made of a conductor having a band surface, and are configured so that the band surfaces face each other, so that the facing area is large, so the degree of freedom of the shape of the antenna element 20 is high. . Therefore, when it is desired to make the antenna element as long as possible in a small space such as a low-profile antenna device, the antenna element 20 can be configured to be refracted to some extent.

  FIG. 5 is a partial cross-sectional schematic side view for explaining an example in which the antenna element of the low profile antenna device of the present invention is deformed. In the figure, the parts denoted by the same reference numerals as those in FIG. As shown in the drawing, in this example, the space behind the cover 50 that defines the outline of the low-profile antenna device is used, and the antenna upright portion 21 is bent backward in the middle so as to earn the electrical length of the antenna element. It extends to the rear end. From there, the antenna main body portion 22 bends and extends so as to be along the upper surface of the cover 50, and the open end side of the antenna main body portion 22 is folded back to extend the electrical length of the antenna element. It is configured. On the other hand, in the parasitic element 30, the parasitic upper portion 31 extends straight up to the upper surface of the cover 50, and then bends and extends along the upper surface of the cover 50. The parasitic element 30 in the illustrated example is configured to have an electrical length shorter than that of the antenna element 20. And although it is not clear from the side view of FIG. 5, as in the state shown in FIG. 1 (c), in this example also, the open end side of the parasitic body part 32, that is, the front side is widened. It is extended.

  Even in such a configuration, the parasitic rising portion 31 and the antenna rising portion 21 have portions extending in parallel so that their band faces face each other, and therefore, as in the other illustrated examples, In addition, since a sufficient double resonance effect can be obtained, a wide area can be achieved. Furthermore, since the degree of freedom of the shape of the antenna element is high, it is possible to obtain desired characteristics even in a small space such as a low profile antenna device. In the illustrated example, both the antenna upright part and the antenna main body part are folded back to increase the electrical length, but the present invention is not limited to this, and only the antenna upright part or only the antenna main body part is folded back. It may be configured.

  In the illustrated example described above, the example using the inverted L-type antenna element as the antenna element has been described, but the present invention is not limited to this. FIG. 6 is a schematic diagram for explaining an example in which an inverted F-type antenna element is used in the low-profile antenna device of the present invention. FIG. 6 (a) is a side view, and FIG. 6 (b) is a side view. Each top view is shown. In the figure, the parts denoted by the same reference numerals as those in FIG. As shown in the figure, even when an inverted F-type antenna element is used as the antenna element 20, the band surfaces of the antenna upright portion 21 connected to the feeding point 11 and the parasitic upright portion 31 of the parasitic element 30 are opposite to each other. As such, the configuration may extend substantially in parallel. And what is necessary is just to comprise so that the open end side of the parasitic body part 32 may become wide. As a result, as in the case where the above-described inverted L-type antenna element is used, it is possible to increase the bandwidth.

  Note that the low-profile antenna device of the present invention is not limited to the illustrated examples described above, and various modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 10 Conductor plate 11 Feeding point 12 Short-circuiting point 20 Antenna element 21 Antenna standing part 22 Antenna main body part 30 Parasitic element 31 Parasitic rising part 32 Parasitic main part 50 Cover

Claims (4)

A low-profile antenna device, the low-profile antenna device,
A conductor plate having a feeding point and a short-circuit point;
An inverted-L or inverted-F antenna element made of a conductor having a strip surface perpendicular to the conductor plate, the antenna rising portion being connected to a feeding point of the conductor plate and rising from the conductor plate; An inverted L-type or inverted F-type antenna element consisting of an antenna main body bent and extended from the tip;
A parasitic element made of a conductor having a strip surface perpendicular to the conductor plate, connected to a short-circuit point of the conductor plate, bent from a parasitic erection rising from the conductor plate and a tip of the parasitic erection The parasitic erection part extends at least partially along the antenna erection so that the respective band faces face each other so as to excite the antenna erection. The parasitic body extends so that the distance between the band surface of the antenna body and the antenna body is wider than the distance between the parasitic surface and the belt surface of the antenna.
A low-profile antenna device comprising:   2. The low-profile antenna device according to claim 1, wherein the parasitic main body portion of the parasitic element is gradually opened from the parasitic upper portion to the open end when viewed from above the conductor plate. A low-profile antenna device characterized by extending so that an end is widest.   2. The low-profile antenna device according to claim 1, wherein the parasitic main body portion of the parasitic element is widest between the parasitic main body and the open end when viewed from above the conductor plate. A low-profile antenna device characterized by extending so as to become.   4. The low-profile antenna device according to claim 1, wherein the antenna element is folded so that the antenna upright portion and / or the antenna main body portion can obtain an electrical length. Type antenna device.