JP2010114797A - Plate-like antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a plate-like antenna operable over a wide band in bands of two frequencies while being small-sized. <P>SOLUTION: A plate-like antenna 1 includes a hot dipole element 10 and a grounding dipole element 11. The hot dipole element 10 is formed in an elongated rectangular plate shape and an elongated rectangular protruding portion 10a is formed so as to extend from a terminal portion of a shorter side. The grounding dipole element 11 is formed in the same elongated and rectangular plate shape as the hot dipole element 10 and a protruding portion 11a is formed to extend from a terminal portion of a shorter side in an elongated rectangular shape and to face the protruding portion 10a. Power is fed from a power feeding cable 12 to the protruding portion 10a and the protruding portion 11a. By adjusting dimensions of the protruding portion 10a and the protruding portion 11a, the plate-like antenna 1 can be matched to the power feeding cable 12. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a plate-like antenna having a built-in matching circuit that matches an antenna made of a plate-like element and a feeding means.

2. Description of the Related Art Conventionally, as a transmission / reception antenna mounted on a wireless communication device, a small antenna is desired for convenience of carrying. FIG. 27 is a front view showing a configuration of an example of a conventional small antenna.
A plate-like antenna 100 shown in FIG. 27 is a dipole antenna, and includes an elongated rectangular plate-like hot dipole element 110 and an earth dipole element 111. The hot dipole element 110 and the earth dipole element 111 are formed in an elongated rectangular shape by processing a metal plate. A portion where the end portions of the hot dipole element 110 and the earth dipole element 111 face each other serves as a feeding point, and a feeding cable 112 that is a coaxial cable is connected to the feeding point. In this case, the core wire 112 a of the power feeding cable 112 is connected to the end of the hot dipole element 110, and the shield conductor 112 b of the power feeding cable 112 is connected to the end of the earth dipole element 111. As a result, a plate antenna 100 that is a dipole antenna including the hot dipole element 110 and the earth dipole element 111 is configured.

  In the conventional plate antenna 100, the frequency characteristic of the voltage standing wave ratio (VSWR) when the length L of the hot dipole element 110 and the earth dipole element 111 is about 71.6 mm and the width W is about 20 mm is shown. As shown in FIG. Referring to FIG. 28, VSWR is the smallest at 900 MHz indicated by the inverted triangle mark 1, and about 1.4 is obtained. Moreover, about 18.6% of the specific resonance band where VSWR is 2.0 or less is obtained. The VSWR at 2000 MHz is about 7.2 as indicated by the inverted triangle mark 2, and the 2000 MHz band is a frequency band that cannot be practically used. From this, it is presumed that the hot dipole element 110 and the earth dipole element 111 having the above dimensions resonate only at 900 MHz.

Further, FIG. 29 shows an antenna radiation pattern in the 900 MHz band in a plane perpendicular to the surfaces of the hot dipole element 110 and the earth dipole element 111 in the conventional plate antenna 100 arranged on the 90 ° and 270 ° axes. . Referring to FIG. 29, the radiation pattern of the plate antenna 100 is an 8-shaped pattern, and is strongly radiated in both directions perpendicular to the plane of the plate antenna 100, and is not substantially radiated in the major axis direction of the plate antenna 100. In this case, linearly polarized waves in the major axis direction in a plane parallel to the plate antenna 100 are radiated, and a maximum gain of about 2.3 dBi is obtained in the directions of about 0 ° and about 180 ° in FIG. The half-value angle in this radiation pattern is about 79 deg.
Furthermore, FIG. 30 shows the antenna radiation pattern in the vertical plane in the 2000 MHz band of the conventional plate antenna 100. Referring to FIG. 30, the radiation pattern of the plate antenna 100 is a substantially 8-shaped pattern, and is strongly radiated in both directions perpendicular to the plane of the plate antenna 100, and is not substantially radiated in the major axis direction of the plate antenna 100. . In this case, linearly polarized waves in the major axis direction in a plane parallel to the plate antenna 100 are radiated, and a high maximum gain of about 4.3 dBi is obtained in the directions of about 0 ° and about 180 ° in FIG. The half-value angle in this radiation pattern is as narrow as about 45 deg.

In the conventional plate antenna 100, although it is small, about 18.6% is obtained as a specific band of the 900 MHz band, and a good radiation pattern is obtained. However, some wireless communication devices are required to operate in a two-frequency band, and a required specific bandwidth of 20% or more is required. However, the conventional plate antenna 100 has a problem that it cannot meet this requirement.
Accordingly, an object of the present invention is to provide a plate-like antenna that can operate in a wide band in two frequency bands while being small.

  In order to achieve the above object, a plate antenna according to the present invention includes a first hot element formed in an elongated rectangular shape, and an elongated shape provided so as to extend from the end of the short side of the first hot element. A rectangular second hot element, a first ground element formed in an elongated rectangular shape and disposed substantially on the major axis of the first hot element, and extended from the end of the short side of the first ground element And an elongated rectangular second hot element provided so that the long side faces the long side of the second hot element, and a power feeding means for feeding power to the second hot element and the second ground element, The main feature is a configuration in which the second hot element and the second ground element that are arranged to face each other are used as matching means.

  The plate antenna of the present invention operates in the first use frequency band by the whole plate antenna, and operates in the second use frequency band by the second hot element and the second ground element. In addition, the length, interval, or width of the second hot element and the second ground element, which are used as the matching means, can be matched with the power feeding means. As a result, it is possible to operate in a two-frequency band, and to make the band wider than that of a conventional plate antenna. In addition, the matching means is built in the plate antenna, and the plate antenna having the matching means can be a small plate antenna.

FIG. 1 is a plan view showing the principle configuration of the plate antenna 0 of the present invention.
A plate-shaped antenna 0 shown in FIG. 1 is a rectangular elongated plate-like first hot element 01a and a rectangular elongated plate-like shape provided so as to be electrically connected to one end of the short side of the first hot element 01a. A hot dipole element 01 composed of the second hot element 01b, a rectangular elongated plate-shaped first ground element 02a, and a rectangular provided so as to be electrically connected to one end of the short side of the first ground element 02a And an earth dipole element 02 composed of a long and narrow plate-like second earth element 02b. The hot dipole element 01 and the earth dipole element 02 constitute a dipole antenna, and the hot dipole element 01 and the earth dipole element are arranged so that one side surface of the second hot element 01b and one side surface of the second ground element 02b face each other. 02 is arranged so as to partially overlap, and a power feeding unit 04 that feeds power is provided between the second hot element 01b and the second ground element 02b. In the plate antenna 0 shown in FIG. 1, the second hot element 01b is separated from the first hot element 01a, and the second ground element 02b is separated from the first ground element 02a. Have

  A matching circuit 03 that matches the plate antenna 0 to the power feeding unit 04 is configured by utilizing the fact that the second hot element 01b and the second ground element 02b are arranged to face each other to form an impedance circuit. . In the matching circuit 03, the impedance of the matching circuit 03 is changed by adjusting the distance between the second hot element 01b and the second ground element 02b and the length and width of the second hot element 01b and the second ground element 02b. By doing so, the plate-like antenna 0 is aligned with the power feeding unit 04. The total length of the first hot element 01a and the second hot element 01b and the total length of the first ground element 02a and the second ground element 02b are L1, and the length L1 is the first length L1. The length of resonance in the used frequency band. The lengths of the second hot element 01b and the second ground element 02b are L2, and the length L2 is a length that resonates with the second use frequency band. As a result, the plate antenna 0 operates in a two-frequency band. In addition, the matching circuit 03 is built in the plate antenna 0. In the matching circuit 03, the second hot element 01b and the second ground element 02b are arranged so as to face each other. Antenna 0 can be used.

Next, FIG. 2 is a plan view showing the configuration of the plate antenna 1 according to the first embodiment of the present invention.
The plate-like antenna 2 of the first embodiment shown in FIG. 2 includes a hot dipole element 10 and an earth dipole element 11 that operate as a dipole antenna made by processing a metal plate. The hot dipole element 10 is formed in a substantially rectangular elongated plate shape, and is formed such that a part thereof is cut out in a rectangular shape at one end portion and a rectangular elongated plate-shaped protruding portion 10a protrudes from the one end portion. The earth dipole element 11 has the same shape as the hot dipole element 10 and is formed in a substantially rectangular elongated plate shape. A part of the ground dipole element 11 is cut out in a rectangular shape at one end, and the rectangular elongated plate-like protruding portion 11a. Is formed so as to protrude from one end. The earth dipole element 11 has a relationship in which the hot dipole element 10 is disposed by being rotated by approximately 180 °. The protrusion 10 a is formed integrally with the hot dipole element 10, and the protrusion 11 a is formed integrally with the earth dipole element 11. That is, the protrusion 10a and the protrusion 11a correspond to the second hot element 01b and the second ground element 02b in the plate antenna 0 shown in FIG. 1, and the hot dipole element 10 excluding the protrusion 10a and the protrusion 11a The portion of the earth dipole element 11 corresponds to the second hot element 01b and the second earth element 02b in the plate antenna 0 shown in FIG.

  The hot dipole element 10 and the earth dipole element 11 are arranged so as to partially overlap so that one side surface of the protruding portion 10a and one side surface of the protruding portion 11a face each other. Further, the core wire 12a of the power feeding cable 12 that is a coaxial cable is connected to a predetermined position of the protruding portion 10a, and the shield conductor 12b of the power feeding cable 12 is connected to the predetermined position of the protruding portion 11a, so that the hot dipole element 10 and the earth dipole are connected. Power is supplied to the element 11. In this case, the plate-like antenna 1 is matched to the feeding cable 12 by utilizing the fact that the protruding portion 10a and the protruding portion 11a are arranged to face each other to form an impedance circuit. When matching, the gap Gp between the protruding portion 10a and the protruding portion 11a and the length FL and width Fw of the protruding portion 10a and the protruding portion 11a are adjusted to change the impedance between the two to supply power. The plate antenna 1 is aligned with the cable 12. In the hot dipole element 10 and the earth dipole element 11, the length of the long side not cut is AL, the length of the cut long side is EL, and the length (width) of the short side is EW. It is said that.

When an example of the dimensions of the plate antenna 1 when operating the plate antenna 1 of the first embodiment in two frequencies of 900 MHz band and 2000 MHz band, the lengths of the long sides of the hot dipole element 10 and the earth dipole element 11 will be described. The EL is about 50 mm, the length FL of the protrusion 10a and the protrusion 11a is about 30 mm, and the length AL is EL + FL of about 80 mm. The short side length EW is about 20 mm, the width Fw of the protrusions 10a and 11a is about 8 mm, and the gap Gp between the protrusions 10a and 11a is about 4 mm. Moreover, the core wire 12a of the power feeding cable 12 is connected to the tip of the protruding portion 10a, and the shield conductor 12b is connected to the position of the protruding portion 11a corresponding to the tip of the protruding portion 10a.
FIG. 3 shows the frequency characteristics of the voltage standing wave ratio (VSWR) of the plate antenna 1 of the first embodiment when the above-mentioned dimensions are set and the characteristic impedance of the feeder cable 12 is about 50Ω. Referring to FIG. 3, the VSWR is smallest at 900 MHz indicated by the inverted triangle mark 1, and a good VSWR of about 1.0 is obtained. In addition, the specific resonance band in the 900 MHz band with a VSWR of 2.0 or less is a wide band of about 22.8%. Furthermore, a good VSWR of about 1.2 is obtained for the VSWR at 2000 MHz as indicated by the inverted triangle mark 2, and the specific resonance band in the 2000 MHz band with a VSWR of 2.0 or less is a wide band of about 27.9%. Is obtained. Thus, the plate-like antenna 1 having the above dimensions operates in a wide band in two frequency bands of 900 MHz band and 2000 MHz band. In addition, the matching means composed of the protruding portion 10a and the protruding portion 11a is built in the plate-like antenna 1, and in the matching means, the protruding portion 10a and the protruding portion 11a are arranged so as to face each other. The plate-like antenna 1 can be obtained.

Further, the hot dipole element in the plate antenna 1 according to the first embodiment, which has the above dimensions and is arranged on the 90 ° and 270 ° axes when the characteristic impedance of the feeding cable 12 is about 50Ω, is used. FIG. 4 shows an antenna radiation pattern in the 900 MHz band in a plane perpendicular to the planes of 10 and the earth dipole element 11. Referring to FIG. 4, the radiation pattern of the plate antenna 1 is an 8-shaped pattern, and is strongly radiated in both directions perpendicular to the surface of the plate antenna 1, and is not substantially radiated in the major axis direction of the plate antenna 1. In this case, linearly polarized waves in the major axis direction on a plane parallel to the plate antenna 1 are radiated, and a maximum gain of about 2.2 dBi is obtained in the directions of about 0 ° and about 180 ° in FIG. In addition, the half-value angle in this radiation pattern is about 74 deg.
Furthermore, FIG. 5 shows an antenna radiation pattern in the 2000 MHz band in the vertical plane of the plate antenna 1 of the first embodiment. Referring to FIG. 5, the radiation pattern of the plate-like antenna 1 is a distorted figure-eight pattern that is strongly radiated in both directions substantially perpendicular from the surface of the plate-like antenna 1, and in the major axis direction of the plate-like antenna 1. Is also weakly radiated. In this case, a linearly polarized wave in the major axis direction in a plane parallel to the plate antenna 1 is radiated, and a maximum gain of about 1.7 dBi is obtained in the direction of about 24 ° and the direction of about 156 ° in FIG. Further, the half-value angle in this radiation pattern is about 111 deg, which is a wide half-value angle. As described above, the plate-like antenna 1 of the first embodiment having the above dimensions has a radiation pattern having no problem in communication in the two frequency bands of 900 MHz band and 2000 MHz band.

Next, changes in the impedance of the feeding point when the dimensions of each part are changed in the plate antenna 1 of the first embodiment will be described. FIG. 6 shows the dimensions of each part in the plate-like antenna 1 of the first embodiment. In addition to the dimensions shown in FIG. 2, the connection position of the power feeding part 13 is shown. The power feeding part 13 is a power feeding cable 12 having a core wire 12a and a shield conductor 12b. The power feeding part 13 is a projecting part 10a at a position of a length Pp from the tip of the projecting part 10a of the hot dipole element 10 and a projecting part at a corresponding position. 11a.
First, FIGS. 7 and 8 show changes in antenna impedance at a feeding point to which the feeding portion 13 of the plate antenna 1 is connected when the width Fw of the protruding portion 10a and the protruding portion 11a is changed from 2 mm to 10 mm. In this case, the length EL of the long side of the hot dipole element 10 and the earth dipole element 11 is about 50 mm, the length FL of the protrusion 10a and the protrusion 11a is about 30 mm, and the distance between the ends of the protrusion 10a and the protrusion 11a. The distance Gp ′ is about 5 mm, the distance Gp between the side surfaces of the projecting portion 10a and the projecting portion 11a is about 4 mm, and the length Pp indicating the connection position of the power feeding unit 13 is about 0 mm, and the hot dipole element 10 and the earth dipole element The width EW of 11 is linked to the width Fw, and EW = (2Fw + Gp). The plate thickness of the hot dipole element 10 and the earth dipole element 11 is about 1 mm, and the impedance of the power feeding unit 13 is about 50Ω (the characteristic impedance of the power feeding cable 12 is about 50Ω).

  FIG. 7 shows the change of the resistance component of the antenna impedance at the feeding point. When the width Fw of the protruding portion 10a and the protruding portion 11a is changed from 2 mm to 10 mm, it is almost constant at about 47Ω at 900 MHz. Thus, at 2000 MHz, it is substantially constant at about 39Ω. FIG. 8 shows a change in reactance component in the antenna impedance at the feeding point. When the width Fw of the protruding portion 10a and the protruding portion 11a is changed from 2 mm to 10 mm, from about −14Ω at 900 MHz. Since it changes to about + 4Ω and changes from about −37Ω to about + 5Ω at 2000 MHz, the impedance at the feeding point can be finely adjusted. When the width Fw is about 8 mm, the antenna impedance at the feeding point is about 47.5-2.7Ω at 900 MHz and about 40.6-0.3Ω at 2000 MHz, approaching the pure resistance, An impedance most matched with 50Ω, which is the impedance of the power feeding unit 13, can be obtained.

Next, the gap Gp between the side surfaces of the projecting part 10a and the projecting part 11a arranged to face each other is changed from 2 mm to 10 mm, and the width Fw of the projecting part 10a and the projecting part 11a is interlocked with the distance Gp so that Fw = (EW −Gp) / 2, and the change in antenna impedance at the feeding point to which the feeding portion 13 of the plate antenna 1 is connected when the width EW of the hot dipole element 10 and the earth dipole element 11 is about 20 mm is shown in FIGS. 10 shows. The other dimensions of the plate-like antenna 1 are the same as those described above.
FIG. 9 shows a change in the resistance component of the antenna impedance at the feeding point. When the gap Gp between the side surfaces of the projecting portion 10a and the projecting portion 11a arranged to face each other is changed from 2 mm to 10 mm, 900 MHz. However, at 2000 MHz, it changes from about 18Ω to about 135Ω. FIG. 10 shows a change in reactance component of the antenna impedance at the feeding point. When the gap Gp between the side surfaces of the projecting portion 10a and the projecting portion 11a arranged to face each other is changed from 2 mm to 10 mm. The impedance changes from about −15Ω to about + 42Ω at 900 MHz and from about −15Ω to about + 10Ω at 2000 MHz, so that the impedance can be adjusted. When the gap Gp is about 4 mm, the antenna impedance at the feeding point is about 47.5-2.7Ω at 900 MHz, and about 40.6-0.3Ω at 2000 MHz, approaching the pure resistance, An impedance most matched with 50Ω, which is the impedance of the power feeding unit 13, can be obtained.

Next, the length FL of the protrusion 10a and the protrusion 11a is changed from 15 mm to 45 mm, the width Fw of the protrusion 10a and the protrusion 11a is about 8 mm, and the width EW of the hot dipole element 10 and the earth dipole element 11 is about FIG. 11 and FIG. 12 show changes in antenna impedance at a feeding point to which the feeding unit 13 of the plate antenna 1 is connected when the thickness is 20 mm. The other dimensions of the plate-like antenna 1 are the same as those described above.
FIG. 11 shows a change in the resistance component of the antenna impedance at the feeding point. When the length FL of the protruding portion 10a and the protruding portion 11a is changed from 15 mm to 45 mm, it is almost constant at about 47Ω at 900 MHz. However, it changes from about 32Ω to about 80Ω at 2000 MHz. FIG. 12 shows a change in reactance component of the antenna impedance at the feeding point. When the length FL of the protruding portion 10a and the protruding portion 11a is changed from 15 mm to 45 mm, about −9Ω at 900 MHz. From about −61Ω to about + 13Ω at 2000 MHz, the impedance can be adjusted. When the length FL is about 30 mm, the antenna impedance at the feeding point is about 47.5-2.7Ω at 900 MHz and about 40.6-0.3Ω at 2000 MHz, approaching the pure resistance, An impedance most matched with 50Ω, which is the impedance of the power feeding unit 13, can be obtained.

Next, the length EL of the long side where the protruding portion 10a and the protruding portion 11a are cut out is changed from 30 mm to 60 mm, the width Fw of the protruding portion 10a and the protruding portion 11a is about 8 mm, the hot dipole element 10 and the ground FIG. 13 and FIG. 14 show changes in the antenna impedance at the feeding point to which the feeding portion 13 of the plate antenna 1 is connected when the width EW of the dipole element 11 is about 20 mm. The other dimensions of the plate-like antenna 1 are the same as those described above.
FIG. 13 shows a change in the resistance component of the antenna impedance at the feeding point. When the length EL of the long side where the protruding portion 10a and the protruding portion 11a are cut out is changed from 30 mm to 60 mm, It changes from about 11Ω to about 96Ω at 900 MHz, and from about 27Ω to about 58Ω at 2000 MHz. FIG. 14 shows a change in reactance component of the antenna impedance at the feeding point. When the long side length EL of the protruding portion 10a and the protruding portion 11a is changed from 30 mm to 60 mm. Furthermore, since it changes from about −50Ω to about −3Ω at 900 MHz, and from about 0Ω to about + 20Ω at 2000 MHz, the impedance can be adjusted. It is preferable to adjust the resonance frequency of the plate antenna 1 by changing the length EL. When the length EL is about 50 mm, the antenna impedance at the feeding point is about 47.5-2.7Ω at 900 MHz and about 40.6-0.3Ω at 2000 MHz, approaching the pure resistance, An impedance most matched with 50Ω, which is the impedance of the power feeding unit 13, can be obtained.

Next, the length Pp indicating the connection position of the power feeding unit 13 is changed from 0 mm to 16 mm, the width Fw of the protrusions 10a and 11a is about 8 mm, and the width EW of the hot dipole element 10 and the earth dipole element 11 is about FIG. 15 and FIG. 16 show changes in antenna impedance at a feeding point to which the feeding unit 13 of the plate antenna 1 is connected when the thickness is 20 mm. The other dimensions of the plate-like antenna 1 are the same as those described above.
FIG. 15 shows the change of the resistance component of the antenna impedance at the feeding point. When the length Pp indicating the connection position of the feeding unit 13 is changed from 0 mm to 16 mm, it is constant at about 50Ω at 900 MHz. However, it changes from about 24Ω to about 41Ω at 2000 MHz. FIG. 16 shows a change in reactance component of the antenna impedance at the feeding point. When the length Pp indicating the connection position of the feeding unit 13 is changed from 0 mm to 16 mm, about −5Ω at 900 MHz. However, since the frequency changes from about −38Ω to about 0Ω at 2000 MHz, the impedance can be adjusted. Then, it is preferable to adjust the resonance frequency of the plate antenna 1 by changing the length Pp. When the length Pp is about 0 mm, the antenna impedance at the feeding point is about 47.5-2.7Ω at 900 MHz and about 40.6-0.3Ω at 2000 MHz, approaching the pure resistance, An impedance most matched with 50Ω, which is the impedance of the power feeding unit 13, can be obtained.

  As described above, the width Fw and the length FL of the protruding portion 10a and the protruding portion 11a in the plate-like antenna 1 of the first embodiment, the gap Gp between the side surfaces of the protruding portion 10a and the protruding portion 11a disposed opposite to each other, By changing the length EL of the long side where the protruding portion 10a and the protruding portion 11a are cut and the length Pp indicating the connection position of the feeding portion 13, the impedance of the plate antenna 1 is controlled and matched. Since the impedance can be easily set, the resonance frequency can be easily set and the ratio band can be increased.

Next, a plan view showing the configuration of the plate antenna 2 of the second embodiment of the present invention is shown in FIG.
The plate-like antenna 2 of the second embodiment shown in FIG. 17 includes a hot dipole element 20 and a ground dipole element 21 that are made by processing a metal plate. The hot dipole element 20 is formed in a substantially rectangular elongated plate shape, a part of which is cut out in a rectangular shape at one end portion to form a rectangular elongated plate-like protruding portion 20a, and a meander line is formed in the other end portion. A bent portion 20b that is bent in a shape is formed. The earth dipole element 21 has the same shape as the hot dipole element 20 and is formed in a substantially rectangular elongated plate shape. A part of the ground dipole element 21 is cut out in a rectangular shape at one end, and the rectangular elongated plate-like protruding portion 21a. And a bent portion 21b bent in a meander line shape is formed at the other end. The earth dipole element 21 has a relationship in which the hot dipole element 20 is disposed by being rotated by approximately 180 °.

The hot dipole element 20 and the earth dipole element 21 are arranged so as to partially overlap so that one side surface of the protruding portion 20a and one side surface of the protruding portion 21a face each other. Further, the power feeding unit 23 is connected to a predetermined position between the projecting portion 20a and the projecting portion 21a. In this case, the plate-like antenna 2 is matched with the power feeding portion 23 by utilizing the fact that the protruding portion 20a and the protruding portion 21a are arranged to face each other to form an impedance circuit. When matching, it can be matched by means similar to the means for adjusting the dimensions of each part in the plate-like antenna 1 of the first embodiment. Furthermore, impedance adjustment can be performed by the bent portions 20b and 21b. The plate-like antenna 2 of the second embodiment can make the plate-like antenna 2 have multiple resonances at three or more frequencies by the action of the bent portions 20b and 21b, and operate in a wide band in a band of three or more frequencies. become. In addition, the matching means composed of the protruding portion 20a and the protruding portion 21a is built in the plate-like antenna 2, and in the matching means, the protruding portion 20a and the protruding portion 21a are arranged so as to face each other. The plate-like antenna 2 can be obtained.
In addition, you may make it form the bending part 20b and the bending part 21b shown in FIG. 17 in the other end of the 1st hot element 01a and the 1st earth element 02a in the plate-shaped antenna 0 shown in FIG. 1, respectively.

Next, FIG. 18 is a plan view showing the configuration of the plate antenna 3 according to the third embodiment of the present invention.
The plate-like antenna 3 of the third embodiment shown in FIG. 18 includes a hot dipole element 30 and an earth dipole element 31 that are made by processing a metal plate. The hot dipole element 30 is formed in a substantially rectangular elongated plate shape, and is partially cut out in a rectangular shape at one end to form a rectangular elongated plate-shaped protruding portion 30a and divided protruding pieces 30b. Yes. The earth dipole element 31 has the same shape as the hot dipole element 30 and is formed in a substantially rectangular elongated plate shape. A part of the ground dipole element 31 is cut out in a rectangular shape at one end, and the rectangular elongated plate-like protruding portion 31a. And the projecting piece 31b divided. The earth dipole element 31 has a relationship in which the hot dipole element 30 is rotated by approximately 180 °.

The hot dipole element 30 and the ground dipole element 31 are arranged so as to partially overlap so that one side surface of the protruding portion 30a and the protruding piece 30b and one side surface of the protruding portion 31a and the protruding piece 31b face each other. The projecting portion 30a and the projecting piece 30b divided into two are connected by a lumped constant element 34, and the projecting portion 31a and the projecting piece 31b divided into two are also concentrated. They are connected by a constant element 34. Further, the projecting portion 30a and the projecting piece 31b are also connected by the lumped constant element 34, and power is supplied from the power feeding unit 33 to the projecting piece 30b and the projecting portion 31a. In this case, the plate antenna 33 is matched to the feeding portion 33 by adjusting the impedance values of the three lumped constant elements 34 connected between the protruding portion 30a, the protruding piece 30b, the protruding portion 31a, and the protruding piece 31b. Can be made. The plate-like antenna 3 according to the third embodiment operates in a wide band, for example, in two frequencies of 900 MHz band and 2000 MHz band. In addition, the plate-like antenna 3 is provided with a matching means including the protruding portion 30a, the protruding piece 30b, the protruding portion 31a, the protruding piece 31b, and the plurality of lumped constant elements 34. Since the part 31a and the protruding piece 31b are arranged so as to face each other, the small plate antenna 3 can be obtained.
The second hot element 01b and the second ground element 02b in the plate antenna 0 shown in FIG. 1 are divided into two parts, and the lumped constant element 34 is connected between them as shown in FIG. Also good.

Next, FIG. 19 shows a plan view showing the configuration of the plate-like antenna 4 of the fourth embodiment of the present invention, and FIG. 20 shows a side view thereof.
The plate-like antenna 4 of the fourth embodiment shown in these drawings includes a hot dipole element 40 and a ground dipole element 41 that are made by processing a metal plate. The hot dipole element 40 is formed in a substantially rectangular elongated plate shape, and a rectangular elongated plate-like protruding portion 40a is formed by cutting out a part of the one end portion in a rectangular shape. The earth dipole element 41 has the same shape as the hot dipole element 40 and is formed in a substantially rectangular elongated plate shape. A part of the ground dipole element 41 is cut out in a rectangular shape at one end portion to form a rectangular elongated plate-like protruding portion 41a. Is formed. The earth dipole element 41 has a relationship in which the hot dipole element 40 is disposed by being rotated by approximately 180 °. The hot dipole element 40 and the earth dipole element 41 are arranged so as to partially overlap so that one side surface of the protruding portion 40a and one side surface of the protruding portion 41a face each other. Further, the power feeding portion 43 is connected to a predetermined position between the protruding portion 40a and the protruding portion 41a. Further, flat and thin rectangular reflectors 44 are arranged at predetermined intervals so as to face the lower side of the hot dipole element 40 and the earth dipole element 41.

In the plate-like antenna 4 of the fourth embodiment, the plate-like antenna 4 is aligned with the power feeding portion 43 by utilizing the fact that the protruding portion 40a and the protruding portion 41a are arranged to face each other and become an impedance circuit. When matching, it can be matched by means similar to the means for adjusting the dimensions of each part in the plate-like antenna 1 of the first embodiment. Further, since the reflection plate 44 is provided, the radiation pattern and gain of the plate antenna 4 can be controlled. Furthermore, the plate-like antenna 4 of the fourth embodiment operates in a wide band in two frequency bands, for example, 900 MHz band and 2000 MHz band. In addition, the matching means composed of the protruding portion 40a and the protruding portion 41a is built in the plate-like antenna 4, and the matching means is arranged so that the protruding portion 40a and the protruding portion 41a face each other. The plate-like antenna 4 can be obtained.
19 and 20 are arranged at predetermined intervals so as to face the lower sides of the hot dipole element 01 and the earth dipole element 02 in the plate antenna 0 shown in FIG. You may make it do.

Next, FIG. 21 shows a plan view showing the configuration of the plate-like antenna 5 of the fifth embodiment of the present invention, and FIG. 22 shows a side view thereof.
The plate-like antenna 5 of the fifth embodiment shown in these drawings includes a hot dipole element 50 and a ground dipole element 51 which are formed by processing a metal plate. The hot dipole element 50 is formed in a substantially rectangular elongated plate shape, and a rectangular elongated plate-like protruding portion 50a is formed by cutting out a part of the one end in a rectangular shape. The earth dipole element 51 has the same shape as that of the hot dipole element 50 and is formed in a substantially rectangular elongated plate shape. A part of the ground dipole element 51 is notched in a rectangular shape at one end and is a rectangular elongated plate-like protruding portion 51a. Is formed. The earth dipole element 51 has a relationship in which the hot dipole element 50 is disposed by being rotated by approximately 180 °. The hot dipole element 50 and the earth dipole element 51 are arranged so as to partially overlap so that one side surface of the protruding portion 50a and one side surface of the protruding portion 51a face each other. Further, the power feeding portion 53 is connected to a predetermined position between the protruding portion 50a and the protruding portion 51a. Further, flat and thin rectangular reflectors 54 are arranged at predetermined intervals so as to face the lower sides of the hot dipole element 50 and the earth dipole element 51, and bent portions 54 a are respectively provided at both ends of the reflector 54. Is formed.

The plate-like antenna 5 of the fifth embodiment matches the plate-like antenna 5 to the power feeding portion 53 by utilizing the fact that the protruding portion 50a and the protruding portion 51a are arranged to face each other and become an impedance circuit. When matching, it can be matched by means similar to the means for adjusting the dimensions of each part in the plate-like antenna 1 of the first embodiment. Further, the plate antenna 5 of the fifth embodiment operates in a wide band in two frequency bands, for example, 900 MHz band and 2000 MHz band. In addition, the matching means composed of the protruding portion 50a and the protruding portion 51a is built in the plate-like antenna 5, and in the matching means, the protruding portion 50a and the protruding portion 51a are arranged so as to face each other. The plate-like antenna 5 can be obtained. Furthermore, by using the reflecting plate 54 provided with the bent portions 54a at both ends, the plate-like antenna 5 can be reduced in size, and the radiation pattern and gain can be further controlled in the plate-like antenna 5. Will be able to.
21 and 22 is provided with bent portions 54a so as to face the lower side of the hot dipole element 01 and the earth dipole element 02 in the plate antenna 0 shown in FIG. May be arranged at predetermined intervals.

Next, FIG. 23 is a perspective view showing the configuration of the plate antenna 6 according to the sixth embodiment of the present invention.
The plate-like antenna 6 of the sixth embodiment shown in FIG. 23 includes a hot dipole element 60 and an earth dipole element 61 that are made by processing a metal plate. The hot dipole element 60 is formed by bending a substantially rectangular elongated plate so as to be substantially along an arc centered on the major axis, and a rectangular elongated plate-like projecting portion is partially cut out at one end. 60a is formed. The earth dipole element 61 has the same shape as the hot dipole element 60, and is formed by bending a substantially rectangular elongated plate so as to be substantially along an arc centered on the major axis, and a part of the earth dipole element 61 is rectangular at one end. A rectangular elongated plate-like protrusion 61a is formed by being cut out. The earth dipole element 61 has a relationship in which the hot dipole element 60 is disposed by being rotated by approximately 180 °. The hot dipole element 60 and the earth dipole element 61 are arranged so as to partially overlap so that one side surface of the protruding portion 60a and one side surface of the protruding portion 61a face each other. Further, the power feeding unit 63 is connected to a predetermined position between the projecting part 60a and the projecting part 61a.

  In the plate-like antenna 6 of the sixth embodiment, the plate-like antenna 6 is matched with the power feeding portion 63 by utilizing the fact that the protruding portion 60a and the protruding portion 61a are arranged to face each other and become an impedance circuit. When matching, it can be matched by means similar to the means for adjusting the dimensions of each part in the plate-like antenna 1 of the first embodiment. Further, the plate antenna 6 of the sixth embodiment operates in a wide band in two frequency bands, for example, 900 MHz band and 2000 MHz band. In addition, the matching means including the projecting portion 60a and the projecting portion 61a is built in the plate-like antenna 6, and the matching means is arranged so that the projecting portion 60a and the projecting portion 61a are opposed to each other. The plate-like antenna 6 can be obtained. Furthermore, since the hot dipole element 60 and the earth dipole element 61 are formed to be curved, the plate antenna 6 can be further reduced in size.

Next, a perspective view showing the configuration of the plate antenna 7 of the seventh embodiment of the present invention is shown in FIG.
The plate-like antenna 7 of the seventh embodiment shown in FIG. 24 includes a hot dipole element 70 and a ground dipole element 71 that are made by processing a metal plate. The hot dipole element 70 is formed by bending a substantially rectangular elongated plate substantially along a circle centered on the major axis to have a C-shaped cross section, and at one end portion, a part thereof is cut into a rectangular shape to form a rectangular elongated shape. A plate-like protrusion 70a is formed. The earth dipole element 71 has the same shape as the hot dipole element 70, and is formed in a substantially C-shaped cross section by bending a substantially rectangular elongated plate substantially along a circle centering on the major axis. The portion is cut out in a rectangular shape to form a rectangular elongated plate-like protrusion 71a. The earth dipole element 71 has a relationship in which the hot dipole element 70 is disposed by being rotated by approximately 180 °. The hot dipole element 70 and the earth dipole element 71 are arranged so as to partially overlap so that one side surface of the protruding portion 70a and one side surface of the protruding portion 71a face each other. In addition, a power feeding unit 73 is connected to a predetermined position between the projecting part 70a and the projecting part 71a.
Thus, the plate-like antenna 7 of the seventh embodiment is such that the curvature of the hot dipole element 60 and the earth dipole element 61 in the sixth embodiment is curved until the cross section becomes C-shaped, Since other configurations are the same as those of the sixth embodiment, description thereof will be omitted. Note that the plate-like antenna 7 of the seventh embodiment also operates in a wide band in two frequency bands of 900 MHz band and 2000 MHz band, for example, and can be further downsized.
The hot dipole element 01 and the earth dipole element 02 in the plate antenna 0 shown in FIG. 1 may be curved as shown in FIG. 23 or FIG.

Next, FIG. 25 is a perspective view showing the configuration of the plate antenna 8 according to the eighth embodiment of the present invention.
The plate-like antenna 8 of the eighth embodiment shown in FIG. 25 includes a hot dipole element 80 and a ground dipole element 81 that are made by processing a metal plate. The hot dipole element 80 is formed of a substantially rectangular elongated plate, and its long axis is curved and is partially cut out in a rectangular shape at one end portion to form a rectangular elongated plate-like projecting portion 80a. Has been. The earth dipole element 81 has the same shape as that of the hot dipole element 80 and is formed of a substantially rectangular elongated plate. The long axis of the earth dipole element 81 is curved. A part of the earth dipole element 81 is cut into a rectangular shape at one end. A rectangular elongated plate-shaped protrusion 81a is formed. The ground dipole element 81 has a relationship in which the hot dipole element 80 is rotated by approximately 180 °. The hot dipole element 80 and the ground dipole element 81 are arranged so as to partially overlap so that one side surface of the protruding portion 80a and one side surface of the protruding portion 81a face each other. In addition, a power feeding portion 83 is connected to a predetermined position between the protruding portion 80a and the protruding portion 81a.

  In the plate-like antenna 8 of the eighth embodiment, the plate-like antenna 8 is matched with the power feeding portion 83 by utilizing the fact that the protruding portion 80a and the protruding portion 81a are arranged to face each other and become an impedance circuit. When matching, it can be matched by means similar to the means for adjusting the dimensions of each part in the plate-like antenna 1 of the first embodiment. Further, the plate antenna 8 of the eighth embodiment operates in a wide band in two frequency bands, for example, 900 MHz band and 2000 MHz band. In addition, the matching means composed of the projecting portion 80a and the projecting portion 81a is built in the plate antenna 8, and in the matching means, the projecting portion 80a and the projecting portion 81a are arranged so as to face each other, so that the small size The plate antenna 8 can be obtained. Furthermore, since the hot dipole element 80 and the earth dipole element 81 are formed with their major axes curved, the plate antenna 8 can be further miniaturized.

Next, a perspective view showing the configuration of the plate antenna 9 of the ninth embodiment of the present invention is shown in FIG.
The plate-like antenna 9 of the ninth embodiment shown in FIG. 26 includes a hot dipole element 90 and a ground dipole element 91 that are made by processing a metal plate. The hot dipole element 90 is formed of a substantially rectangular elongated plate, and its long axis is curved so that the cross-section becomes a substantially semicircular shape. A part of the hot dipole element 90 is cut into a rectangular shape at one end, and the rectangular elongated shape. A plate-like protrusion 90a is formed. The earth dipole element 91 has the same shape as that of the hot dipole element 90 and is formed of a substantially rectangular elongated plate. The long axis of the earth dipole element 91 is curved so that the cross section is substantially semicircular. The portion is cut out in a rectangular shape to form a rectangular elongated plate-like protruding portion 91a. The earth dipole element 91 has a relationship in which the hot dipole element 90 is disposed by being rotated by approximately 180 °. The hot dipole element 90 and the ground dipole element 91 are arranged so as to partially overlap so that one side surface of the protruding portion 90a and one side surface of the protruding portion 91a face each other. In addition, a power feeding portion 93 is connected to a predetermined position between the protruding portion 90a and the protruding portion 91a.
Thus, the plate-like antenna 9 of the ninth embodiment is such that the degree of curvature of the hot dipole element 80 and the earth dipole element 81 in the eighth embodiment is curved until the plate-like antenna 9 is substantially ring-shaped. Since the other configuration is the same as that of the eighth embodiment, the description thereof is omitted. Note that the plate antenna 9 of the ninth embodiment also operates in a wide band in two frequency bands, for example, 900 MHz band and 2000 MHz band, and can be further downsized.
Note that the hot dipole element 01 and the earth dipole element 02 in the plate antenna 0 shown in FIG. 1 may be curved as shown in FIG. 25 or FIG.

The plate antenna according to the present invention described above is an antenna that can operate in the 900 MHz band and the 2000 MHz band. However, the present invention is not limited to this, and by changing the dimensions of the hot dipole element and the earth dipole element, any 2 The antenna can operate in a frequency band. In addition, the plate antenna according to the present invention can be used as an external antenna for enhancing transmission / reception power in a mobile phone, or as an antenna of a communication module not equipped with an antenna.
The plate antenna according to the present invention is formed by processing a metal plate, but is not limited thereto, and the plate antenna is formed on a printed board or an insulating film by vapor deposition, adhesion, or printing. be able to. Furthermore, the impedance of the power feeding unit (power feeding cable) is not limited to 50Ω, and may be other impedances such as 75Ω.

It is a top view which shows the fundamental structure of the plate-shaped antenna of this invention. It is a top view which shows the structure of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the frequency characteristic of the voltage standing wave ratio (VSWR) of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the antenna radiation pattern in the 900 MHz band of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the antenna radiation pattern in 2000 MHz band of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the dimension of each part of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the resistance component of antenna impedance when changing the protrusion F of the plate-shaped antenna concerning 1st Example of this invention, and the width | variety Fw of a protrusion. It is a figure which shows the change of the reactance component of the antenna impedance at the time of changing the width | variety Fw of the protrusion part of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the resistance component of antenna impedance at the time of changing the space | interval Gp between the protrusion parts of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the reactance component of the antenna impedance at the time of changing the space | interval Gp between the protrusion parts of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the resistance component of antenna impedance at the time of changing the length FL of the protrusion part of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the reactance component of the antenna impedance at the time of changing the length FL of the protrusion part of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the resistance component of antenna impedance when changing the length EL of the long side which is not notched of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the reactance component of the antenna impedance at the time of changing the length EL of the long side which is not notched of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the resistance component of antenna impedance at the time of changing length Pp which shows the position of the feeding point of the plate-shaped antenna concerning 1st Example of this invention. It is a figure which shows the change of the reactance component of antenna impedance at the time of changing length Pp which shows the position of the feeding point of the plate-shaped antenna concerning 1st Example of this invention. It is a top view which shows the structure of the plate-shaped antenna concerning 2nd Example of this invention. It is a top view which shows the structure of the plate-shaped antenna concerning 3rd Example of this invention. It is a top view which shows the structure of the plate-shaped antenna concerning 4th Example of this invention. It is a side view which shows the structure of the plate-shaped antenna concerning 4th Example of this invention. It is a top view which shows the structure of the plate-shaped antenna concerning 5th Example of this invention. It is a side view which shows the structure of the plate-shaped antenna concerning 5th Example of this invention. It is a perspective view which shows the structure of the plate-shaped antenna concerning 6th Example of this invention. It is a perspective view which shows the structure of the plate-shaped antenna concerning 7th Example of this invention. It is a perspective view which shows the structure of the plate-shaped antenna concerning 8th Example of this invention. It is a perspective view which shows the structure of the plate-shaped antenna concerning 9th Example of this invention. It is a top view which shows the structure of an example of the conventional plate-shaped antenna. It is a figure which shows the frequency characteristic of the voltage standing wave ratio (VSWR) of the conventional plate-shaped antenna. It is a figure which shows the antenna radiation pattern in the 900MHz band of the conventional plate-shaped antenna. It is a figure which shows the antenna radiation pattern in the 2000MHz band of the conventional plate-shaped antenna.

Explanation of symbols

0 plate antenna, 1 plate antenna, 2 plate antenna, 3 plate antenna, 4 plate antenna, 5 plate antenna, 6 plate antenna, 7 plate antenna, 8 plate antenna, 9 plate antenna, 01 hot dipole element, 01a first hot element, 01b second hot element, 02 ground dipole element, 02a first ground element, 02b second ground element, 03 matching circuit, 04 feeding part, 10 hot dipole element, 10a protruding part 11 Ground dipole element, 11a Protruding part, 12 Feed cable, 12a Core wire, 12b Shield conductor, 13 Feeding part, 20 Hot dipole element, 20a Protruding part, 20b Bending part, 21 Earth dipole element, 21a Protruding part, 21b Bending part , 23 Power feeding unit, 30 Hot dipole element, 30a Projection, 30b Projection piece, 31 Earth dipole element, 31a Projection part, 31b Projection piece, 33 Plate antenna, 33 Feeding part, 34 Lumped constant element, 40 Hot dipole element, 40a Projection part, 41 Earth dipole element, 41a Projection Part, 43 feeding part, 44 reflecting plate, 50 hot dipole element, 50a protruding part, 51 earth dipole element, 51a protruding part, 53 feeding part, 54 reflecting plate, 54a bent part, 60 hot dipole element, 60a protruding part, 61 Earth dipole element, 61a Protruding part, 63 Feeding part, 70 Hot dipole element, 70a Protruding part, 71 Earth dipole element, 71a Protruding part, 73 Feeding part, 80 Hot dipole element, 80a Protruding part, 81 Earth dipole element, 81a Protruding part, 83 Power feeding part 90 hot dipole element, 90a protruding part, 91 earth dipole element, 91a protruding part, 93 feeding part, 100 plate antenna, 110 hot dipole element, 111 earth dipole element, 112 feeding cable, 112a core wire, 112b shield conductor

Claims (9)

A hot dipole element composed of a first hot element formed in an elongated rectangular plate shape, and an elongated rectangular second hot element provided so as to extend from the end of the short side of the first hot element;
A first grounding element formed in an elongated rectangular plate shape and arranged so that its major axis is substantially aligned with the first hot element; and extending from the end of the short side of the first grounding element; An earth dipole element composed of an elongated rectangular second hot element provided so that a side thereof faces one side of the second hot element;
Power supply means for supplying power to the second hot element and the second ground element;
The sum of the long side of the first hot element and the long side of the second hot element and the sum of the long side of the first ground element and the long side of the second ground element are The length of the long side of the second hot element and the length of the long side of the second ground element are substantially the same as those of the second used frequency band. The length resonates with the center frequency,
The plate-like antenna, wherein the second hot element and the second ground element that are arranged to face each other constitute a matching means for matching with the power feeding means. A hot dipole element that is formed in an elongated rectangular plate shape, and is formed so that the elongated rectangular first protrusion extends from the end of one short side;
A second projecting portion that is formed in an elongated rectangular plate shape and has an elongated rectangular shape extending from an end portion of one short side so that one side is opposed to one side of the first projecting portion An earth dipole element that is arranged so that its major axis is aligned with the hot dipole element, and
Power supply means for supplying power to the first protrusion and the second protrusion,
The lengths of the long sides of the hot dipole element and the earth dipole element are lengths that resonate at substantially the center frequency of the first use frequency band, and the lengths of the long sides of the first protrusion and the second protrusion Is a length that resonates at approximately the center frequency of the second use frequency band,
The plate-like antenna, wherein the first projecting portion and the second projecting portion arranged to face each other constitute a matching means for matching with the power feeding means.   3. The plate antenna according to claim 1, wherein a bent portion is formed on an outer end side of the hot dipole element and the earth dipole element.   The second hot element and the second ground element are formed by being divided into two parts, the second hot element divided into two parts is connected by a lumped constant element for matching, and the second part divided into two parts Two ground elements are connected by a lumped constant element for matching, and the second hot element divided into two and the second ground element divided into two are connected by a lumped constant element for matching. The plate antenna according to claim 1.   The first projecting portion and the second projecting portion are divided into two parts, the first projecting part divided into two parts is connected by a lumped constant element for matching, and the first part divided into two parts Two projecting portions are connected by a lumped constant element for matching, and the first projecting portion divided into two and the second projecting portion divided into two are connected by a lumped constant element for matching. The plate antenna according to claim 2.   3. The plate antenna according to claim 1, wherein the hot dipole element and the earth dipole element are disposed on a reflector plate having a long and narrow rectangular shape and spaced apart by a predetermined distance.   6. The plate antenna according to claim 5, wherein both short sides of the reflecting plate are bent at substantially right angles.   3. The plate antenna according to claim 1, wherein the hot dipole element and the earth dipole element are curved so as to substantially follow an arc centered on a major axis.   3. The plate antenna according to claim 1, wherein major axes of the hot dipole element and the earth dipole element are curved.

Images