JPH10209733A - Surface-mounted type antenna and antenna system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use two resonance frequencies by an antenna and to make the device small-sized by connecting an auxiliary radiation electrode to a radiation electrode, and turning it on and off and changing inductance components. SOLUTION: An auxiliary radiation electrode 5 is formed integrally with a radiation electrode, provided on the main surface of a polygonal base body 2 formed of a dielectric or magnetic body, and a high-frequency connection between the auxiliary radiation electrode and a ground electrode 3 is made by turning the control voltage of a diode D on and off as a switching element of a switching device 10. At the on time, inductance components of both the radiation electrodes 4 and 5 become parallel and resonate at a high frequency of an antenna circuit and at the off time, the inductance component of the radiation electrode 4 resonates at a low frequency. At the high frequency resonance time, currents flow to the radiation electrode 4 and auxiliary radiation electrode 5 in nearly the same direction and then polarization loss is reduced to obtain good reception sensitivity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a surface mount antenna used for mobile communication equipment and the like, and an antenna device using the surface mount antenna.

[0002]

2. Description of the Related Art A conventional antenna is disclosed in Japanese Patent Laid-Open No. 7-22 / 1995.
An example disclosed in Japanese Patent Publication No. 1537 will be described with reference to FIG.

In FIG. 23, reference numeral 131 denotes a surface-mounted antenna, which includes a base 132 formed by molding a dielectric such as ceramic. The base 132 is provided with a through-hole 133 opened on two opposing side surfaces.
The radiation electrode 134 is formed by applying a conductor to the inner peripheral surface of the element 3. Also, the power supply electrode 135 and the side surface electrode 136 are provided on one side surface where the through hole 133 is opened.
a, 136b are formed, and the side electrode 136 is formed on the other side.
c is formed. Here, the side electrodes 136a, 136
6b is insulated from the radiation electrode 134, and the power supply electrode 135 and the side surface electrode 136c are electrically connected to the radiation electrode 134.

[0004] In the surface-mounted antenna 131 thus configured, a capacitance component generated between the side electrodes 136a and 136c and between the side electrodes 136b and 136c;
An inductance component generated by the radiation electrode 134,
The resonance frequency is determined by the external dimensions of the base 132 and the like.

As another conventional antenna, an antenna disclosed in Japanese Patent Publication No. 5-88003 is taken as an example, and its configuration will be described with reference to FIG.

In FIG. 24, reference numeral 141 denotes a plate-shaped loop antenna, and two conductor plates 142 arranged to face each other.
a, 142b and insulating plates 143a, 143 disposed between the opposing sides of these conductor plates 142a, 142b.
43b, 143c and 143d form a wireless device case. Then, power is supplied to an arbitrary position on one side of the conductor plates 142a and 142b facing each other, for example, between the corners D1 and D2 facing each other. The other sides facing each other, for example, the corners A1 and A2 facing each other, and C1 and C2 are short-circuited by conductors 144a and 144c, respectively, thereby operating as a loop antenna that changes the polarization directivity of the antenna. I do.

[0007]

In general, there is a demand for miniaturization of a surface mount antenna, but in a conventional surface mount antenna, the resonance frequency is defined by the shape of the electrodes, the outer dimensions of the base, and the like. Therefore, when the external dimensions of the base are reduced along with the miniaturization, there is a problem that the frequency bandwidth is narrowed.

In a conventional loop antenna,
It has no function of controlling impedance characteristics, requires an external matching circuit, is not suitable for miniaturization, and is not suitable for surface mounting. Further, although the polarization can be switched, the frequency bandwidth cannot be increased by switching the frequency.

Accordingly, an object of the present invention is to provide an antenna which is small, can be used by switching to a plurality of resonance frequencies, and can be surface-mounted, and an antenna device using the same.

[0010]

In order to achieve the above object, a surface mount antenna according to the present invention comprises:
A base made of a dielectric or magnetic material, having one main surface, the other main surface, and a plurality of side surfaces; a ground electrode provided mainly on one main surface of the base; and a main electrode mainly provided on the other main surface of the base. A radiating electrode having one end forming an open end, the other end having an extending portion formed continuously and integrally with the ground electrode, and one end disposed close to the open end of the radiating electrode. Feeding electrode, one end near the other end of the radiation electrode, was formed integrally and continuously with the radiation electrode,
It is characterized by comprising one or more auxiliary radiation electrodes.

Further, in the surface mount antenna according to the present invention, a base made of a dielectric or magnetic material and having one main surface, the other main surface, and a plurality of side surfaces, and at least one surface of the base body A ground electrode provided;
Being provided over one or more surfaces of the substrate,
A radiation electrode having an open end at one end and an extension formed integrally with the ground electrode at the other end, and a feed electrode arranged at one end corresponding to the open end of the radiation electrode And one or more auxiliary radiation electrodes formed integrally with the radiation electrode at one end near the other end of the radiation electrode.

Also, in the antenna device of the present invention,
It is characterized by having a surface mounting antenna and a switching device for turning on / off a high frequency connection between the auxiliary radiation electrode and the ground electrode of the surface mounting antenna.

Further, in the antenna device of the present invention,
The switching device includes a switching element connected in series to the auxiliary radiation electrode, a capacitor having one end grounded, and a high-impedance element that increases impedance at high frequencies, and the capacitor and the high-impedance element are each It is characterized by being connected in parallel to a switching element.

Further, in the antenna device of the present invention,
The surface mount antenna and the switching device are provided on one main surface of an antenna substrate to be integrated.

According to the surface-mounted antenna and the antenna device using the same according to the present invention, the switching device is connected to the auxiliary radiation electrode to form the antenna device, and the switching device is operated to ground the radiation electrode. By changing the inductance component of the portion, it is possible to switch to a plurality of resonance frequencies for use.

In the case where the auxiliary radiation electrode is provided on the same side surface or an adjacent side surface of the base on which the extending portion of the radiation electrode is provided, when forming the inductance component using the auxiliary radiation electrode together with the radiation electrode, The directions in which the current flows between the radiation electrode and the auxiliary radiation electrode are substantially equal to each other. Here, since the polarization directivity is defined by the direction in which the current flows, the polarization loss is reduced due to a small gap between the two electrodes in the direction of the current.
Therefore, when switching and using the resonance frequency, good sensitivity is obtained.

Further, in the surface-mounted antenna and the antenna device according to the present invention, since a plurality of resonance frequencies can be obtained without using a plurality of antennas, the antenna and the antenna device can be downsized. In addition, there is no mutual interference between the antennas when a plurality of antennas are used, and the characteristics are stabilized.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A configuration of a surface mount antenna according to one embodiment of the present invention will be described with reference to FIG.

In FIG. 1, reference numeral 1 denotes a surface mount antenna, which is formed on a surface of a base 2 formed of ceramics or the like.
A ground electrode 3, a radiation electrode 4, an auxiliary radiation electrode 5, and a power supply electrode 6 are formed. Among them, the ground electrode 3
Mainly provided on one main surface 7a of the base 2, a part thereof extends to the side surface 8a of the base 2 to form an extension 3a.

The radiation electrode 4 is mainly formed in a substantially band shape on the other main surface 7b of the base 2, one end of which extends to the side surface 8a of the base 2 to form an open end 4a. I have.
The open end 4a is arranged close to the extension 3a of the ground electrode 3. Further, a part of the other end 4b of the radiation electrode 4 forms an extended portion 4b1 continuously and integrally with the ground electrode 3 formed on the one main surface 7a via the side surface 8b of the base 2. The auxiliary radiation electrode 5 mainly includes the base 2
One end extends to the other main surface 7b of the base 2 and is formed integrally with the radiation electrode 4 in the vicinity of the other end 4b of the radiation electrode 4; On the other hand, it extends around the main surface 7a and is insulated from the ground electrode 3. The power supply electrode 6 is mainly provided on the side surface 8 a of the base 2, and one end 6 a thereof is connected to the other main surface 7 b of the base 2.
The other end 6 b is arranged on one main surface 7 a of the base 2 insulated from the ground electrode 3. The term “extension” and “extension portion” as used herein indicate that one thing extends further from a certain portion and that the portion extends.

Next, the configuration of an antenna device using the surface mount antenna 1 will be described with reference to FIG.

In FIG. 2, reference numeral 100 denotes an antenna device, which is obtained by connecting the switching device 10 to the surface mount antenna 1.

The surface-mount antenna 1 is surface-mounted on one main surface of a printed circuit board 9 and has a ground electrode 3.
Are joined to a ground electrode 9 a provided on one main surface of the printed circuit board 9. The power supply electrode 6 is joined to an input terminal (not shown) provided on one main surface of the substrate 9.

On the other hand, the switching device 10 comprises a diode D as a switching element, an inductor L as a high impedance element for increasing the impedance in high frequency, and capacitors C1 and C2. Each is made of a chip component, and is surface-mounted on one main surface of the printed circuit board 9. Switching device 1
The diode D constituting 0 is connected to the auxiliary radiation electrode 5 of the surface mount antenna 1 via the pad P1, and is connected to the capacitor C1 and the inductor L via the pad P2. The inductor L is connected to the pad P
3 and the capacitor C2.
1 and C2 are connected to the ground electrode 9a of the printed circuit board 9. The switching device 10 configured as described above is connected to a set-side voltage control mechanism (not shown).

Next, the operation of the antenna device 100 will be described with reference to FIG.

FIG. 3 is an equivalent circuit diagram of the antenna device 100. The signal source portion A corresponds to the signal source of the surface mount antenna, the antenna portion B corresponds to the surface mount antenna itself, and the switching device corresponds to the switching device. A circuit is configured from the unit C. Here, the correspondence between the surface mount antenna 1 of FIG. 1 and each part of FIG. 3 will be described. R2 is a radiation resistance between the open end 4a of the radiation electrode 4 and the extension 3a of the ground electrode 3, C12 is a capacitance component generated between the open end 4a and the extension 3a. Reference numeral 12 denotes a conductor line composed of the radiation electrode 4 and the auxiliary radiation electrode 5, L11 denotes an inductance component of the radiation electrode 4, L12 denotes an inductance component of the auxiliary radiation electrode 5, and C13 denotes the other end 5a of the auxiliary radiation electrode 5. And a capacitance component generated between the ground electrode 3. In FIG. 3, the same reference numerals as in FIG. 2 denote parts corresponding to the respective parts of the switching device 10 in FIG. Although not shown, the input terminal IN of the switching unit C is connected to a voltage control mechanism (not shown) on the set side.

When a signal is input from the high-frequency signal source 11 having the signal source impedance R1, the energy of the input signal resonates in this circuit, and a part of the energy is radiated into the air to function as an antenna. I do. here,
The voltage applied to the switching device 10 is adjusted by the voltage control mechanism on the set side, and the diode D of the switching device 10
By performing N / OFF, the resonance frequency is switched. That is, when the diode D is turned on, the inductance component of the surface mount antenna 1 is mainly composed of a parallel circuit of the inductance components L11 and L12, so that a relatively high resonance frequency can be obtained.
When the diode D is OFF, the inductance component is
Since it is mainly composed only of the inductance component L11, a relatively low resonance frequency can be obtained.

Further, since the auxiliary radiation electrode 5 is at the DC ground potential, it is not necessary to provide another circuit for the DC path of the diode D. That is, switching with less variation is possible with a relatively simple circuit configuration.

Here, as means for turning on / off the auxiliary radiation electrode 5, as shown in FIG. 4, it is conceivable to construct a circuit by replacing the diode D and the capacitor C 1. Since this and the capacitor C1 resonate in series, switching cannot be performed, which is not suitable for practical use. With the configuration shown in FIG. 2, such series resonance does not occur. In FIG. 4, the same or corresponding portions as in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted.

As described above, in the surface-mount type antenna 1, the switching device 10 is connected to the auxiliary radiation electrode 5 to form the antenna device 100, and the switching device 10 is operated to change the inductance component. It can be used by switching to two resonance frequencies. In addition, since the auxiliary radiation electrode 5 is provided on the same side surface 8b of the base 2 on which the extending portion 4b1 of the radiation electrode 4 is provided, when the auxiliary radiation electrode 5 is used together with the radiation electrode 4 to form an inductance component, FIG. As shown schematically, currents flow in the directions of arrows P and Q in the radiation electrode 4 and the auxiliary radiation electrode 5, respectively. Thus, in these two electrodes, the directions in which the current flows are substantially equal to each other. Here, since the polarization directivity is defined by the direction in which the current flows, the polarization loss is reduced due to a small gap between the two electrodes in the direction of the current. Therefore, when switching and using the resonance frequency,
Good sensitivity is obtained.

The surface-mounted antenna 1 and the antenna device 100 have strong directional characteristics in a direction perpendicular or nearly perpendicular to the thickness direction of the printed circuit board 9 when mounted and used on the printed circuit board 9. Therefore, it is possible to mount another component on the other main surface of the printed circuit board 9. Also, because of having such directional characteristics, the surface mount antenna 1 and the antenna device 10
For example, when 0 is mounted on a mobile communication device, there is no possibility that the antenna characteristics are deteriorated even when the mobile communication device is used in contact with a human head.

In the surface-mounted antenna 1 and the antenna device 100, two resonance frequencies can be obtained without using two antennas, so that the antenna and the antenna device can be downsized. In addition, there is no mutual interference between the antennas generated when two antennas are used, and the characteristics are stabilized.

In the above embodiment, the case where a diode is used as a switching element in the switching device constituting the antenna device has been described. However, the invention is not limited to the diode, and a transistor, an FET, or the like may be used. Further, in the above embodiment, the inductor presented as the high impedance element may be replaced with a resistor, and the resistor in this case may be connected in series to a switching element such as a diode.

As described above, the surface-mounted antenna 1 and the antenna device 100 can be used by switching to two resonance frequencies. However, in order to achieve a desired resonance frequency, it is necessary to use a conventional antenna. In some cases, fine adjustment of the resonance frequency is required. The method of the fine adjustment will be described.

In the surface mount antenna 1 shown in FIGS. 1 and 2, the resonance frequency can be increased by trimming the open end 4a of the radiation electrode 4 and its vicinity or the feed electrode 6. Further, by trimming the extending portion 4b of the radiation electrode 4 or the auxiliary radiation electrode 5, the resonance frequency can be lowered. In addition,
These trimmings can be achieved by, for example, shaving off a part of the electrode with a router or the like, or cutting off a part of the electrode by a laser trimming method.

As shown in FIGS. 6A and 6B,
A plurality of projections A may be formed in advance in the vicinity of the open end 4a of the radiation electrode 4 of the surface mount antenna 1, the feed electrode 6, and the auxiliary radiation electrode 5, and the projections A may be trimmed. .

The switching device 1 is connected to the surface mount antenna 1.
If the trimming is performed after the antenna device 100 is formed after the connection of the switching device 10, the variation in the resonance frequency due to the variation in the characteristics of the elements such as the diode constituting the switching device 10 can be adjusted. Therefore, after adjusting the resonance frequency of the surface-mounted antenna 1 alone, the labor of adjustment is reduced as compared with the case where the resonance frequency of the antenna device 100 is further adjusted.

Next, a modification of the antenna device shown in FIG. 2 will be described with reference to FIG. 1 and 2 are denoted by the same reference numerals, and description thereof is omitted.

In FIG. 7, the antenna device 12 includes the surface mount antenna 1, the switching device 10, and the antenna substrate 13. The antenna substrate 13 is for integrating the surface mounting antenna 1 and the switching device 10 to constitute the antenna device 12 as one component, and the other main surface 13b of the antenna substrate 13 is used as one main surface of the printed circuit board 9. 9a
It is used by surface mounting. Of these, antenna substrate 1
Numeral 3 is smaller than the printed circuit board 9 and has a space for mounting the surface mount antenna 1 and the switching device 10, and a ground electrode 14 and a power supply terminal (not shown) are provided on the main surface 13a. Have been. The surface-mounted antenna 1 is formed by forming a ground electrode 3, a radiation electrode 4, an auxiliary radiation electrode 5, and a feed electrode 6 on a base 2, and is surface-mounted on one main surface 13a of the antenna substrate 13. The ground electrode 3 is joined to the ground electrode 14 of the antenna substrate 13, and the power supply electrode 6 is connected to a power supply terminal (not shown) of the antenna substrate 13. The switching device 10 includes a diode D, an inductor L for choke, and capacitors C1 and C2. These elements are each formed of a chip component.
The antenna substrate 13 is surface-mounted on one main surface 13a.
The diode D constituting the switching device 10 is connected to the auxiliary radiation electrode 5 of the surface mount antenna 1 via the pad P1, and is connected to the capacitor C1 and the inductor L via the pad P2. Further, the inductor L is connected to the capacitor C2 via the pad P3, and the capacitors C1 and C2 are connected to the ground electrode 14 of the antenna substrate 13. The switching device 10 configured as described above is connected to a voltage control mechanism (not shown) on the set side via the printed circuit board 9 in a state where the antenna device 12 is mounted on the printed circuit board 9.

In the antenna device 12 configured as described above, the same effects as those of the first embodiment can be obtained, and it is not necessary to prepare a switching device on the set side. 9 can be implemented.

Hereinafter, modifications of the surface mount antenna shown in FIG. 1 will be described with reference to FIGS. In these modifications, similarly to the surface mount antenna shown in FIG. 1, the antenna device is formed by surface mounting on a normal printed circuit board or a small antenna substrate, and a switching device is connected to form an antenna device. It can be switched and used, and the same effects as those of the surface mount antenna and the antenna device shown in FIGS. 1 and 2 can be obtained. In addition,
8 to 14, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.

In FIG. 8, reference numeral 21 denotes a surface-mounted antenna. One end 24a of the radiation electrode 24 forms an open end on the other main surface 7b of the base 2, and the other end 24b is a side surface from the other main surface 7b of the base 2. 8b.
A part of the other end 24 b of the radiation electrode 24 is connected to the one main surface 7 of the base 2.
a extending part 2 extending integrally with the ground electrode 3
4b1. The auxiliary radiation electrode 25 is formed integrally with the radiation electrode 24 at one end near the other end 24 b of the radiation electrode 24, and the other end 25 a is formed on the base 2.
And is insulated from the ground electrode 3. Further, a part of the ground electrode 3 forms an extension 3a on the side surface 8a of the base 2, one end 26a of the power supply electrode 26 is disposed on the side surface 8a of the base 2, and the other end 26b is connected to one main surface. 7a is disposed insulated from the ground electrode 3.

In the surface-mounted antenna 21 and the antenna device using the same, the same effects as those of the surface-mounted antenna and the antenna device shown in FIGS. 1 and 2 can be obtained. Is formed so as to extend around the side surface 8b of the base 2 and the distance from the ground electrode 3 is small, so that the loss of the ground portion is reduced and the antenna efficiency is improved.

Next, in FIG. 9, reference numeral 31 denotes a surface mount type antenna, one end 34a of the radiation electrode 34 extends to the side surface 8a of the base 2 to form an open end, and the other end 34b corresponds to the base 2
And a part of the other end 34b reaches one main surface 7a of the base 2 to form an extension 34b1 continuously and integrally with the ground electrode 3. In addition, the radiation electrode 3
In the vicinity of the other end 34b of the base 4, one end of the auxiliary radiation electrode 35 is formed continuously and integrally with the radiation electrode 34, and the other end 35a of the auxiliary radiation electrode 35 wraps around the one main surface 7a of the base 2, It is arranged insulated from the ground electrode 3.
Further, a part of the ground electrode 3 forms an extension 3 a on the side surface 8 a of the base 2. Also, one end 36 of the power supply electrode 36
a is disposed on the side surface 8a of the base 2, and the other end 36b is disposed on the one main surface 7a insulated from the ground electrode 3.

In the surface-mounted antenna 31, since the open end 34a of the radiation electrode 34 is arranged close to the ground electrode 3, the capacitance component increases. Therefore, it is possible to reduce the size without deteriorating the frequency characteristics.

The surface-mounted antenna 31 and the antenna device using the same have the same advantages as those of the surface-mounted antenna and the antenna device shown in FIGS.

Next, in FIG. 10, reference numeral 41 denotes a surface-mounted antenna, and the radiation electrode 44 has a substantially meandering shape.
One end 44a forms an open end on the other main surface 7b of the base 2. The other end of the radiation electrode 44 is bifurcated, and one of the bifurcated portions is continuously integrated with the ground electrode 3 formed on the one main surface 7 a via the side surface 8 c of the base 2. The extension portion 44b1 is formed at the bottom.
The auxiliary radiation electrode 45 is provided so as to extend from the other main surface 7b of the base 2 to the one main surface 7a via the side surface 8b,
One end is formed continuously and integrally with the other forked portion of the radiation electrode 44 near the other end 44b of the radiation electrode 44, and the other end 45a is insulated from the ground electrode 3 on one main surface 7a of the base 2. It is arranged. One end 46a of the power supply electrode 46 extends to the other main surface 7b of the base 2,
The other end 46 is close to the open end 44 a of the radiation electrode 44.
b is arranged on one main surface 7a insulated from the ground electrode 3.

Here, the extending portion 44b1 of the radiation electrode 44
Is provided on the side surface 8c adjacent to the side surface 8b of the base 2 on which the auxiliary radiation electrode 45 is provided, so that the direction in which the current flows differs between the extending portion 44b1 and the auxiliary radiation electrode 45. However, in the radiation electrode 44, the meander-shaped portion occupies the majority, and the length dimension of the extending portion 44b1 and the auxiliary radiation electrode 45 is very small with respect to the length dimension of the meander-shaped portion. Therefore, when connecting a switching device and switching and using the resonance frequency,
There is no risk of sensitivity degradation due to polarization loss.

In the surface-mounted antenna 41 and the antenna device using the same, the same effects as those of the surface-mounted antenna and the antenna device shown in FIGS. 1 and 2 can be obtained.

Next, in FIG. 11, reference numeral 51 denotes a surface-mounted antenna, and the radiation electrode 54 has a substantially meandering shape.
One end is open end 54a at the other main surface 7b of the base 2.
And the other end goes around the side surface 8 d of the base 2 to form an extended portion 54 b continuously and integrally with the ground electrode 3. An auxiliary radiation electrode 55 bent at a right angle is provided on the side surface 8 d of the base 2. One end of the auxiliary radiation electrode 55 is formed integrally with the radiation electrode 54 in the vicinity of the other end of the radiation electrode 54, and the other end 55a is
It is arranged around one main surface 7a of the base 2 so as to be insulated from the ground electrode 3. Also, one end 5 of the power supply electrode 56
6a is disposed on the other main surface 7b of the base 2 in the vicinity of the open end 54a of the radiation electrode 54, and the other end 56b is connected to the one main surface 7b.
a is insulated from the ground electrode 3. Further, extending portions 3a1 and 3a2 of the ground electrode 3 are formed on the side surfaces 8c and 8d of the base 2, respectively.

In the surface-mounted antenna 51 and the antenna device using the same, the same effects as those of the surface-mounted antenna and the antenna device shown in FIGS. 1 and 2 can be obtained.

Next, in FIG. 12, reference numeral 61 denotes a surface-mounted antenna, and a radiation electrode 64 is provided on the other main surface 7 of the base 2.
b, the end of which is open-ended
4a, and the other end goes around the side surface 8b of the base 2,
An extension 64b is formed integrally with the ground electrode 3. The auxiliary radiation electrode 65 formed on the side surface 8b of the base 2 is bent at a right angle, and one end thereof is formed integrally with the radiation electrode 64 near the other end of the radiation electrode 64. The other end 65a goes around the one main surface 7a of the base 2 and is insulated from the ground electrode 3. A power supply electrode 66 is also provided on the side surface 8b of the base 2, and one end 66a of the power supply electrode 66 is disposed on the other main surface 7b of the base 2 in proximity to the open end 64a of the radiation electrode 64. The other end 66b is arranged on one main surface 7a insulated from the ground electrode 3.

In the surface-mounted antenna 61 and the antenna device using the same, the same effects as those of the surface-mounted antenna and the antenna device shown in FIGS. 1 and 2 can be obtained.

Next, in FIG. 13, reference numeral 71 denotes a surface-mounted antenna, and a radiation electrode 74 is provided on the other main surface 7 of the base 2.
b is provided on almost the entire surface, part of which is open end 74
a, and the other part goes around the side surface 8 c of the base 2 to form an extended part 74 b integrally with the ground electrode 3. The side surface 8c of the base 2 has
, Two auxiliary radiation electrodes 75a and 75b are provided. One end of each of the auxiliary radiating electrodes 75a and 75b is formed integrally with the radiating electrode 74 near the other end of the radiating electrode 74, and the other end goes around the one main surface 7a of the base 2 and is grounded. It is arranged insulated from the electrode 3. The power supply electrode 76 is provided on the side surface 8 d of the base 2, and one end 76 a of the power supply electrode 76 is arranged on the other main surface 7 b near the open end 74 a of the radiation electrode 74, and the other end 76 b
Are arranged on one main surface 7a of the base 2 insulated from the ground electrode 3.

In the surface-mounted antenna 71 thus configured, a switching device is connected to each of the auxiliary radiation electrodes 75a and 75b to form an antenna device, and the switching device is operated to change the inductance component. Then, it can be used by switching to a plurality of resonance frequencies. That is, assuming that the inductance component generated by the radiation electrode 74 is L1, the inductance component generated by the auxiliary radiation electrode 75a is L2, and the inductance component generated by the auxiliary radiation electrode 75b is L3, the inductance component of the antenna is mainly composed of L1. If it is mainly composed of L1 and L2, if it is mainly composed of L1 and L3, and
By switching to any of the cases mainly composed of L1, L2 and L3, four resonance frequencies can be realized. Other effects are the same as those of the surface mount antenna shown in FIG.

Next, in FIG. 14, reference numeral 81 denotes a surface-mounted antenna, and a ground electrode 83 and a radiation electrode 84 are provided on the entire surface of one main surface 7a and the other main surface 7b of the base 2, respectively. Of these, a part of the ground electrode 83 extends to the side surface 8b of the base 2, and the extended portions 83a, 83b
Is formed. Further, one end 84a of the radiation electrode 84 is
It extends to the side surface 8b of the base 2 and forms an open end. On the other hand, a part of the other end 84b of the radiation electrode 84 extends around the side surface 8a of the base 2 to form an extension 84b1 integrally with the ground electrode 83. One end of the auxiliary radiation electrode 85 provided on the side surface 8 a is formed integrally with the radiation electrode 84 in the vicinity of the other end of the radiation electrode 84. Further, the other end 85 a of the auxiliary radiation electrode 85 extends around the one main surface 7 a of the base 2 and is arranged so as to be insulated from the ground electrode 83. The power supply electrode 86 has one end 86 a disposed on the side surface 8 b of the base 2 and the other end 86 a
b is disposed on one main surface 7a, and the other end 86b is insulated from the ground electrode 83. Here, the side surface 8b of the base 2
, The open end 84a of the radiation electrode 84 and the feed electrode 8
6, one end 86a and two extending portions 83a and 83b of the ground electrode 83 are arranged close to each other.

Next, an experimental result on the characteristics of the surface mount antenna having the same configuration as the surface mount antenna 81 will be described. In this experiment, 15 mm long and 10 mm wide were used.
This is a surface-mounted antenna having a base having a size of 6 mm and a height of 6 mm and a relative dielectric constant of εr = 21.

When a switching device (not shown) was connected to such a surface mount antenna and the antenna device was constructed and its characteristics were measured, when the diode of the switching device was turned on,
The radiation pattern shown in FIG. 15 and the reflection loss characteristics shown in FIG. 17 were obtained. When the diode was turned off, the radiation pattern shown in FIG. 16 and the reflection loss characteristics shown in FIG. 18 were obtained. As is apparent from these data, two resonance frequencies could be realized without deteriorating the gain.

Next, the configuration of a surface mount antenna according to another embodiment of the present invention will be described with reference to FIG. The same or corresponding portions as those of the surface mount antenna shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.

In FIG. 19, reference numeral 91 denotes a surface-mounted antenna, and a ground electrode 9 is provided on the surface of the rectangular parallelepiped base 2.
3. A radiation electrode 94, an auxiliary radiation electrode 95, and a feeding electrode 96 are formed. Among them, the ground electrode 93 is provided mainly on the side surface 8c parallel to the longitudinal direction of the base 2, and a part thereof extends to the one main surface 7a of the base 2 to form an extension 93a, and the other Extends to the other main surface 7b of the base 2 to extend
3b. The radiation electrode 94 is provided on a side surface 8 d facing the side surface 8 c of the base 2, and has one end extending to the other main surface 7 b of the base 2 and an open end 94 a proximate to the extension 93 b of the ground electrode 93. Is formed. On the other hand, the other end of the radiation electrode 94 goes around the other main surface 7 b of the base 2, and the ground electrode 93 on the side surface 8 c of the base 2.
And an extended portion 94b is integrally formed. Also,
One end of the auxiliary radiation electrode 95 provided on the side surface 8c of the base 2 is formed integrally with the radiation electrode 94 in the vicinity of the other end of the radiation electrode 94.
It is formed so as to extend around one main surface 7a of the base 2. The power supply electrode 96 is mainly provided on the side surface 8 c of the base 2, and one end 96 a thereof extends to the one main surface 7 a of the base 2 corresponding to the open short 94 a of the radiation electrode 94. Further, fixing electrodes 97a and 97b that are in contact with the one main surface 7a are provided on the side surface 8d of the base 2. Fixing electrode 97a,
Reference numeral 97b is for attaching the solder at the time of surface mounting to assist in fixing the antenna.

In the surface-mounted antenna 91 configured as described above, a high-frequency signal is input through the power supply electrode 96 to emit a radio wave. Further, although not particularly shown, it is surface-mounted on a normal printed board or a small antenna board, the auxiliary radiation electrode 95 is connected to a switching device, and the gap between the auxiliary radiation electrode 95 and the ground electrode 93 is turned on for a high-frequency signal. By turning ON / OFF, the resonance frequency can be switched. That is, at the time of ON, a relatively high resonance frequency is obtained by adding the inductance component of the auxiliary radiation electrode 95 to the inductance component of the radiation electrode 94, and at the time of OFF, the inductance component of the antenna mainly depends on the radiation electrode 94. Since it is composed only of the inductance component, a relatively low resonance frequency can be obtained.

Here, when the surface-mounted antenna 91 is surface-mounted, one main surface 7a of the base 2 becomes a mounting surface, and the ground electrode 93 and the radiation electrode 94 are strong in a direction parallel to the mounting surface. It has directional characteristics.

In the surface-mounted antenna 91, the ground electrode 93 and the radiation electrode 94 are provided on the side surfaces 8c and 8d of the base 2 facing each other. Therefore, the distance between these electrodes is increased, and a wider frequency characteristic is realized.

In the surface-mounted antenna 91 and the antenna device using the same, two resonance frequencies can be obtained without using two antennas, so that the antenna and the antenna device can be downsized. In addition, there is no mutual interference between the antennas generated when two antennas are used, and the characteristics are stabilized.

In the surface-mounted antenna 91 and the antenna device using the same, the resonance frequency can be adjusted by trimming each electrode, as in the first embodiment. Furthermore, although not specifically shown,
A projection may be formed on each electrode in advance, and the projection may be trimmed.

If a switching device is combined with the surface-mounted antenna 91 to form an antenna device and then trim electrodes, the resonance frequency of the surface-mounted antenna 91 alone is adjusted, and then the antenna device is further used. As compared with the case where the resonance frequency is adjusted, the adjustment labor is reduced.

Hereinafter, a modification of the surface mount antenna shown in FIG. 19 will be described with reference to FIGS. In these modifications, similarly to the surface mount antenna shown in FIG. 19, the antenna device is formed by surface mounting on a normal printed board or a small antenna board, and a switching device is connected to form a plurality of resonance frequencies. It can be switched and used, and the same effects as those of the surface mount antenna and the antenna device shown in FIG. 19 can be obtained. 20 to 22, the same or corresponding parts as in FIG. 19 are denoted by the same reference numerals, and the description thereof will be omitted.

Referring to FIG. 20, reference numeral 101 denotes a surface-mounted antenna. A ground electrode 103, a radiation electrode 104, an auxiliary radiation electrode 105, and a feed electrode 106 are formed on the surface of a rectangular parallelepiped base 2. Of these, ground electrode 1
Numeral 03 is mainly provided on a side surface 8c parallel to the longitudinal direction of the base 2, a part of which extends to one main surface 7a of the base 2 to form an extended portion 103a, and the other portion is the other of the base 2 The extended portion 103b is formed to extend to the main surface 7b. The radiation electrode 104 is provided in a substantially meandering shape on a side surface 8d facing the side surface 8c of the base 2, and one end thereof is provided on the other main surface 7b of the base 2.
To form an open end 104a. On the other hand, the other end of the radiation electrode 104 goes around the other main surface 7 b of the base 2, and the ground electrode 103 formed on the side surface 8 c of the base 2.
And an extended portion 104b is formed integrally with the substrate. One end of the auxiliary radiation electrode 105 has a radiation electrode 104.
Is formed continuously and integrally with the radiation electrode 104 in the vicinity of the other end of the base 2.
a. In addition, the power supply electrode 106
Is provided on the side surface 8c of the base 2 and has one end 106a
Extends on one main surface 7a of the base 2 corresponding to the open end 106a of the radiation electrode 106.

The surface-mounted antenna 101 and the antenna device using the same have the same effects as those of the surface-mounted antenna shown in FIG. 19 and the antenna device using the same.

Next, in FIG. 21, reference numeral 111 denotes a surface-mount type antenna, and a ground electrode 113, a radiation electrode 114, an auxiliary radiation electrode 115,
The power supply electrode 116 is formed. Among them, the ground electrode 113 is provided on a side surface 8 c parallel to the longitudinal direction of the base 2, and has an extended portion 113 a on one main surface 7 a of the base 2. Further, the radiation electrode 114 is provided in a substantially meandering shape on a side surface 8 d facing the side surface 8 c of the base 2, and one end is provided on the base 2.
Extends to one main surface 7a to form an open end 114a, and the other end goes around the other main surface 7b of the base 2 and is continuously and integrally formed with the ground electrode 113 formed on the side surface 8c of the base 2. An extension 114b is formed. Here, the auxiliary radiation electrode 115 is provided on the side surface 8 c of the base 2, and one end is formed continuously with the radiation electrode 114 near the other end of the radiation electrode 114, and the other end 115 a is formed on the base 2. On the other hand, it is formed around the main surface 7a. The power supply electrode 116 is provided on the side surface 8c of the base 2 and has one end 1 thereof.
Reference numeral 16a extends to the one main surface 7a and is arranged close to the open end 114a of the radiation electrode 114.

The surface-mounted antenna 111 and the antenna device using the same have the same effects as those of the surface-mounted antenna shown in FIG. 19 and the antenna device using the same.

Next, in FIG. 22, reference numeral 121 denotes a surface-mounted antenna, and a ground electrode 123, a radiation electrode 124, an auxiliary radiation electrode 125,
The power supply electrode 126 is formed. Among them, the ground electrode 123 and the power supply electrode 126 are both provided on the side surface 8c parallel to the longitudinal direction of the base 2, and have an extended portion 123a and one end 126a on one main surface 7a of the base 2, respectively. Further, the radiation electrode 124 is provided in a substantially meandering shape on a side surface 8d facing the side surface 8c of the base 2, and one end of the side surface 8d
c, and extends to the side surface 8b adjacent to c, forming an open end 124a. Further, the other end of the radiation electrode 124 extends around the side surface 8a facing the side surface 8b and extends around the side surface 8c to form an extended portion 124b integrally with the ground electrode 123. Here, one end of the auxiliary radiation electrode 125 having a shape bent at a right angle is formed integrally with the radiation electrode 124 in the vicinity of the other end of the radiation electrode 124,
The other end 125a is formed to extend to the side surface 8c of the base 2. The power supply electrode 126 is provided on the side surface 8 c of the base 2, and one end 126 a thereof extends to the one main surface 7 a and is arranged corresponding to the open end 124 a of the radiation electrode 124.

The surface-mounted antenna 121 and the antenna device using the same have the same effects as those of the surface-mounted antenna shown in FIG. 19 and the antenna device using the same.

In each of the above embodiments, the case of using a substrate made of ceramic has been described. However, a surface-mounted antenna having a substrate formed by molding a dielectric or magnetic material other than ceramic and an antenna using the same were used. The present invention can be applied to an antenna device.

Further, in each of the above embodiments, the case where one or two auxiliary radiation electrodes are provided has been described. However, by providing three or more auxiliary radiation electrodes, surface mounting capable of coping with more resonance frequencies can be achieved. The present invention also includes a type antenna and an antenna device using the same.

[0076]

According to the surface-mounted antenna and the antenna device of the present invention, the switching device connected to the auxiliary radiation electrode is operated to change the inductance component and switch the antenna device to a plurality of resonance frequencies. Can be used.

When the auxiliary radiation electrode is provided on the same side surface of the base on which the extending portion of the radiation electrode is provided, when forming the inductance component using the auxiliary radiation electrode together with the radiation electrode, the radiation electrode and the auxiliary electrode are formed. The direction in which the current flows between the radiating electrode and the radiating electrode is substantially equal to each other. Here, since the polarization directivity is defined by the direction in which the current flows, the polarization loss is reduced due to a small gap between the two electrodes in the direction of the current. Therefore, when switching and using the resonance frequency, good sensitivity is obtained.

According to the surface mount antenna and the antenna device of the present invention, a plurality of resonance frequencies can be obtained without using a plurality of antennas.
The size of the antenna and the antenna device can be reduced. In addition, there is no mutual interference between the antennas when a plurality of antennas are used, and the characteristics are stabilized.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a surface mount antenna according to one embodiment of the present invention.

FIG. 2 is a perspective view showing an antenna device using the surface mount antenna of FIG. 1;

FIG. 3 is a circuit diagram showing an equivalent circuit of the antenna device of FIG. 2;

FIG. 4 is a circuit diagram in which the equivalent circuit of FIG. 3 is partially changed.

FIG. 5 is a perspective view schematically showing a direction in which a current flows in the surface mount antenna of FIG.

6 (a) and 6 (b) are perspective views showing modifications of the electrode shape of the surface mount antenna of FIG. 1;

FIG. 7 is a perspective view showing another antenna device according to the present invention.

FIG. 8 is a perspective view showing a modification of the surface mount antenna of FIG. 1;

FIG. 9 is a perspective view showing another modification of the surface mount antenna of FIG. 1;

FIG. 10 is a perspective view showing still another modification of the surface mount antenna of FIG. 1;

FIG. 11 is a perspective view showing still another modified example of the surface mount antenna of FIG. 1;

FIG. 12 is a perspective view showing still another modification of the surface mount antenna of FIG. 1;

FIG. 13 is a perspective view showing still another modification of the surface mount antenna of FIG. 1;

FIG. 14 is a perspective view showing still another modification of the surface mount antenna of FIG. 1;

FIG. 15 shows directivity characteristics of the antenna device using the surface mount antenna of FIG. 14 when the diode is ON.

FIG. 16 shows directivity characteristics of the antenna device using the surface mount antenna of FIG. 14 when the diode is off.

FIG. 17 shows reflection loss characteristics of the antenna device using the surface mount antenna of FIG. 14 when the diode is ON.

FIG. 18 is a graph showing the return loss characteristics of the antenna device using the surface mount antenna of FIG. 14 when the diode is turned off.

FIG. 19 is a perspective view showing a surface mount antenna according to another embodiment of the present invention.

FIG. 20 is a perspective view showing a modification of the surface mount antenna of FIG.

FIG. 21 is a perspective view showing another modification of the surface mount antenna of FIG. 19;

FIG. 22 is a perspective view showing still another modification of the surface mount antenna of FIG.

FIG. 23 is a perspective view showing a conventional surface mount antenna.

FIG. 24 is a perspective view showing another conventional surface mount antenna.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 surface mount antenna 2 base 3 ground electrode 3a ground electrode extension 4 radiation electrode 4a opening end of radiation electrode 4b other end of radiation electrode 4b1 extension of radiation electrode 5 auxiliary radiation electrode 6 feed electrode 7a One of base Main surface 7b The other main surface of the substrate 8a, 8b Side surface of the substrate 10 Switching device 100 Antenna device C1, C2 Capacitor D Diode (switching element) L Inductor (high impedance element)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI H01Q 23/00 H01Q 23/00

Claims (5)

[Claims] 1. A base made of a dielectric or magnetic substance and having one main surface, another main surface, and a plurality of side surfaces; a ground electrode provided mainly on one main surface of the base; A radiating electrode provided on the other main surface, one end of which forms an open end, and the other end has an extending portion formed continuously and integrally with the ground electrode; and one end forms an open end of the radiating electrode. A feed electrode disposed in close proximity, and one or more auxiliary radiation electrodes, one end of which is formed integrally with the radiation electrode in the vicinity of the other end of the radiation electrode. Surface mount antenna. 2. A base made of a dielectric or magnetic material and having one main surface, another main surface, and a plurality of side surfaces; a ground electrode provided on at least one surface of the base; Provided over one or more surfaces,
A radiation electrode having an open end at one end and an extension formed integrally with the ground electrode at the other end, and a feed electrode disposed at one end corresponding to the open end of the radiation electrode And one or more auxiliary radiation electrodes, one end of which is formed integrally with the radiation electrode in the vicinity of the other end of the radiation electrode. 3. A surface mounted antenna according to claim 1 or 2, and a switching device for turning on / off a high frequency connection between the auxiliary radiation electrode and the ground electrode of the surface mounted antenna. Characteristic antenna device. 4. The switching device includes a switching element connected in series to the auxiliary radiation electrode, a capacitor having one end grounded, and a high impedance element for increasing impedance in a high frequency range, wherein the capacitor and the high impedance Elements, each being connected in parallel to the switching element,
The antenna device according to claim 3. 5. The antenna device according to claim 3, wherein the surface mount antenna and the switching device are provided integrally on one main surface of an antenna substrate.