JP3663951B2 - Surface mount antenna and communication device using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a surface mount antenna used for mobile communication equipment and the like.
[0002]
[Prior art]
A conventional surface mount antenna disclosed in Japanese Patent Laid-Open No. 10-13138 will be described with reference to the drawings.
[0003]
In FIG. 7, a surface-mounted antenna 10 has a first ground electrode 2 and a stripline-like length of λ / 4 on the surface of a rectangular parallelepiped base 1 made of a dielectric material such as ceramics, resin, or a magnetic material. An approximate radiation electrode 3, a feeding electrode 4, and a second ground electrode 5 are formed.
[0004]
Among these, the first ground electrode 2 is formed on one main surface 1 a of the base 1, and the radiation electrode 3 is formed on the other main surface 1 b of the base 1.
One end of the radiation electrode 3 forms an open end 3 a on the end face 1 c of the base 1, and the other end extends to the end face 1 d of the base 1 and is connected to the first ground electrode 2.
The power supply electrode 4 has one end provided on one main surface 1 a of the substrate 1 and the other end extended on the end surface 1 c, and is opposed to the open end 3 a of the radiation electrode 3 through a gap 6. .
The power supply electrode 4 is connected to a high frequency signal source 7.
Further, one end of the second ground electrode 5 is provided in the vicinity of the open end 3 a of the radiation electrode 3 on the end surface 1 c of the base 1, and the other end is connected to the first ground electrode 2.
[0005]
An equivalent circuit of the surface mount antenna 10 configured as described above is shown in FIG.
In the figure, an equivalent circuit 20 is composed of an inductor 11, resistors 12 and 13, and capacitors 14, 15, 16 and 17.
Among these, the resistor 12, the inductor 11, the capacitor 16, and the capacitor 17 constitute a series circuit in which both ends are grounded.
Further, a resistor 13 and capacitors 14 and 15 are connected in parallel between the connection portion of the inductor 11 and the capacitor 16 and the ground.
Further, the connection portion between the capacitor 16 and the capacitor 17 is connected to the high-frequency signal source 18.
[0006]
Here, the relationship between the surface-mounted antenna 10 of FIG. 7 and the equivalent circuit 20 will be described.
[0007]
The inductor 11 is the self-inductance of the radiation electrode 3, the resistor 12 is the internal resistance of the radiation electrode 3, the capacitor 14 is a capacitance generated between the open end 3a of the radiation electrode 3 and the first ground electrode 2, and the capacitor 15 is the radiation electrode. 3 is generated between the open end 3a of the radiating electrode 3 and the power supply electrode 4 between the open end 3a of the radiating electrode 3 and the power supply electrode 4. The capacitor 17 and the capacitor 17 are capacitors generated between the power supply electrode 4 and the first ground electrode 2.
The resistor 13 is a radiation resistance of the surface mount antenna 10.
[0008]
Next, the operation of the surface mount antenna 10 will be described using the equivalent circuit 20.
[0009]
The resonance circuit of the surface mount antenna 10 is mainly composed of an inductor 11, a resistor 13, and capacitors 14 and 15.
Among these, the capacitor 15 has a larger capacity than the capacitor 14 and is inserted in parallel with the capacitor 14 to increase and stabilize the capacitance component of the resonance circuit.
[0010]
When a signal is input from the high-frequency signal source 18 to the resonance circuit via the capacitor 16, the energy of the input signal resonates in the resonance circuit, and a part of the energy is radiated into the air to function as an antenna.
This radiated energy can be said to be energy consumed by the resistor 13 in terms of an equivalent circuit.
[0011]
The capacitor 16 has a function of matching with an external circuit together with the capacitor 17 in addition to a function as an inlet for supplying energy to the resonance circuit.
[0012]
The resonance frequency of the surface mount antenna 10 configured as described above is based on an inductance component composed of the self-inductance of the radiation electrode 3 and a capacitance generated between the open end 3a of the radiation electrode 3 and the second ground electrode. Defined by the volume component.
[0013]
[Problems to be solved by the invention]
However, the conventional surface mount antenna 10 has the following problems.
[0014]
That is, in the manufacturing process, when each electrode is printed on the substrate 1, a so-called printing misalignment in which the electrode pattern deviates from a desired position may occur.
[0015]
For example, as shown in FIG. 9, when there is no printing displacement of the electrode pattern, the distance between the second ground electrode 5 and the edge of the end surface 1c on the end surface 1c of the substrate 1 is L3.
On the other hand, as shown in FIG. 10, when the electrode pattern is shifted upward in the drawing, the distance L31 between the second ground electrode 5 and the edge of the end surface 1c on the end surface 1c of the substrate 1 is The distance is smaller than the distance L in FIG. 9, and the capacitance generated between the open end 3a of the radiation electrode 3 and the second ground electrode 5 is increased.
Here, the capacitance constitutes a capacitance component that defines the resonance frequency of the surface-mounted antenna 10, and the resonance frequency becomes lower than a desired value as the capacitance increases.
[0016]
As shown in FIG. 11, when the electrode pattern is shifted downward in the drawing, the distance L32 between the second ground electrode 5 and the edge of the end face 1c of the substrate 1 becomes large, and the radiation electrode 3 The capacitance generated between the open end 3a and the second ground electrode 5 decreases, and as a result, the resonance frequency becomes higher than a desired value.
[0017]
In order to correct such variations in resonance frequency, complicated frequency adjustment operations such as trimming of electrode patterns are required.
Accordingly, an object of the present invention is to provide a surface-mounted antenna in which the variation in resonance frequency when the printing deviation of the electrode pattern occurs is suppressed, and the labor for frequency adjustment is reduced.
It is another object of the present invention to provide a communication device using such a surface mount antenna.
[0019]
[Means for Solving the Problems]
In order to achieve the above object, in the present invention,
A first ground electrode is formed on one main surface of a rectangular parallelepiped base made of a dielectric or magnetic material;
Stripline-like radiation electrode is formed on the other main surface of the substrate,
One end of the radiation electrode is continuously bent from the other main surface of the base to the first end face of the base, forming a first open end at the first end face, and the other part of the base of the base. Forming a second open end on the other main surface;
The other end of the radiation electrode is connected to the first ground electrode,
The first end surface of the base body is opposed to the first open end of the radiation electrode via a gap, and a ridge line where one end intersects the other main surface of the base body and the first end surface. A surface-mount antenna that forms a second ground electrode that is opposed to the second open end of the radiation electrode and has the other end connected to the first ground electrode across a portion ,
Each electrode is formed by printing an electrode pattern,
A taper-shaped notch is formed at the time of printing the electrode pattern in the ridge line portion of the base to suppress a variation in resonance frequency caused by printing deviation of the electrode pattern with respect to the radiation electrode .
[0020]
In addition, a first ground electrode is formed on one main surface of a rectangular parallelepiped base made of a dielectric or magnetic material,
Stripline-like radiation electrode is formed on the other main surface of the substrate,
One end of the radiation electrode is continuously bent from the other main surface of the base to the first end face of the base, forming a first open end at the first end face, and the other part of the base of the base. Forming a second open end on the other main surface;
The other end of the radiation electrode is connected to the first ground electrode,
The first end surface of the base is opposed to the first open end of the radiation electrode via a gap, and a ridge line portion where one end intersects the other main surface of the base and the first end surface. A surface-mounted antenna formed by forming a second ground electrode facing the second open end of the radiation electrode and having the other end connected to the first ground electrode ,
Each electrode is formed by printing an electrode pattern,
On the other end side of the radiation electrode, on the ridge line portion where the other main surface of the substrate and the second end surface formed to face the first end surface of the substrate intersect, the other main surface of the substrate A taper-shaped notch and a rectangular notch are formed at the time of printing the electrode pattern, including the second end face, to suppress variations in resonance frequency caused by printing deviation of the electrode pattern. .
[0021]
In addition, the communication device according to the present invention includes a surface mount antenna having the above-described configuration.
[0022]
According to the surface mount antenna of the present invention, when the capacitance component that defines the resonance frequency increases or decreases due to printing deviation of the electrode pattern, the inductance component decreases or increases due to the notch provided in the electrode pattern. The decrease and increase of the resonance frequency are offset.
In this way, variations in resonance frequency are suppressed, and the effort of frequency adjustment is reduced.
[0023]
In addition, according to the communication device according to the present invention, since the surface-mounted antenna that suppresses the variation in the resonance frequency due to the printing deviation of the electrode pattern and reduces the time for frequency adjustment is used, the manufacturing cost is reduced.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
The structure of the surface mount antenna according to the first embodiment of the present invention will be described with reference to FIG.
In the figure, the same or corresponding parts as in FIG. 7 are denoted by the same reference numerals, and the description thereof is omitted.
[0025]
In FIG. 1, a surface-mounted antenna 10 a is formed by forming a first ground electrode 2, a radiation electrode 3, a feeding electrode 4, and a second ground electrode 5 on the surface of a base 1.
[0026]
One end of the radiation electrode 3 is bent from the other main surface 1b of the substrate 1 to the first end surface 1c of the substrate 1 to form the first open end 3a, and the other portion is the other main surface 1b of the substrate 1. A second open end 3b is formed above.
[0027]
The other end of the radiation electrode 3 is extended to a second end surface 1 d formed at a position facing the first end surface 1 c of the base 1, and the first ground electrode 2 formed on one main surface of the base 1. Connected to.
[0028]
The other end of the feeding electrode 4 formed on the first end face 1c of the base 1 is opposed to the first open end 3a of the radiation electrode 3 via the gap 6 on the first end face 1c. The second ground electrode 5 is opposed to the second open end 3b of the radiation electrode 3 with one end sandwiching a ridge line portion R1 where the other main surface 1b of the base 1 and the first end surface 1c intersect. It is formed.
[0029]
A tapered notch 8 is formed in the ridge portion R1 of the base body 1 with respect to the radiation electrode 3 over the other main surface 1b and the first end face 1c of the base body 1. Here, the notch 8 is used to suppress variations in resonance frequency caused by printing misalignment of the electrode pattern forming the radiation electrode 3, the feeding electrode 4, and the second ground electrode 5 on the first end surface 1 c of the substrate 1. Is.
[0026]
Next, the effect of the notch 8 in the surface mount antenna 10a will be described with reference to FIGS.
[0027]
FIG. 2 shows a case where there is no printing misalignment of the electrode pattern on the end face 1c of the substrate 1 in the manufacturing process of the surface mount antenna 10a.
In FIG. 2, the distance between the second ground electrode 5 and the edge of the end face 1c of the substrate 1 is denoted by L1, and the width dimension of the radiation electrode 3 at the edge of the end face 1c is denoted by L2.
[0028]
Here, FIG. 3 shows a case where the electrode pattern of FIG. 2 is shifted upward in the drawing.
[0029]
In FIG. 3, the distance L11 between the second ground electrode 5 and the edge of the end face 1c of the substrate 1 is smaller than the distance L1 in FIG.
As described above, as the distance between the open end 3a of the radiation electrode 3 and the ground electrode 5 is reduced, the capacitance generated in this portion is increased.
[0030]
At the same time, due to the notch 8, the width dimension L21 of the radiation electrode 3 at the edge of the end face 1c of the substrate 1 becomes larger than the width dimension L2 of FIG. 2, and as a result, the self-inductance of the radiation electrode 3 decreases. To do.
[0031]
In this way, an increase in the capacitance component that defines the resonance frequency of the surface mount antenna 10a and a decrease in the inductance component occur at the same time, so a decrease and an increase in the resonance frequency are offset.
[0032]
FIG. 4 shows a case where the electrode pattern of FIG. 2 is shifted downward in the drawing.
[0033]
At this time, the distance L12 between the second ground electrode 5 and the edge of the end surface 1c of the substrate 1 is relatively large, and the width dimension L22 of the radiation electrode 3 at the edge of the end surface 1c is relatively large. It will be small.
As a result, the capacitance component of the surface mount antenna 10a decreases, the inductance component increases, and the increase and decrease of the resonance frequency are offset.
[0034]
As described above, in the surface-mounted antenna 10a, the variation of the resonance frequency is suppressed, and the labor for frequency adjustment is reduced.
[0035]
Here, the change amount of the inductance component can be controlled by adjusting the inclination angle P of the notch 8 shown in FIG. 2 so that the change of the resonance frequency is canceled out.
[0036]
Although not shown in particular, when the electrode pattern is printed on the other main surface 1b of the base 1, the inductance component is adjusted by the portion of the notch 8 on the other main surface 1b side, and the resonance frequency changes. Offset.
[0037]
As described above, in the surface-mounted antenna 10a, the variation in the resonance frequency when the electrode pattern is misprinted is suppressed, and the labor for frequency adjustment is reduced.
[0038]
Note that the notch 8 does not extend over the other main surface 1b and the end surface 1c of the base 1, but may be provided only on one of the surfaces.
Furthermore, the notch 8 may be other shapes such as a semicircular shape or a rectangular shape instead of the tapered shape.
[0039]
The radiation electrode 3 may have other shapes such as a substantially L shape, a substantially U shape, or a meander shape.
[0040]
Next, the structure of the surface mount antenna according to the second embodiment of the present invention will be described with reference to FIG.
In the figure, the same or corresponding parts as in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.
[0041]
In FIG. 5, reference numeral 10 b denotes a surface mount antenna, which has a radiation electrode 3 and other electrodes provided on the surface of the substrate 1.
Here, the other main surface of the substrate 1 is in contact with the radiation electrode 3 at the tangential portion R2 of the substrate 1 where the second end surface 1d formed opposite to the other main surface 1b of the substrate 1 and the first end surface 1c intersects. A notch 21 and a notch 22 are formed across the surface 1b and the second end face 1d.
[0042]
Among these, the notch 21 has a tapered shape and is formed across the other main surface 1b and the end surface 1d of the base 1.
[0043]
The notch 22 has a rectangular shape, and includes a horizontal portion 22a and a vertical portion 22b on the drawing straddling the other main surface 1b and the end surface 1d of the base 1, and has a substantially L shape as a whole.
Here, the horizontal portion 22 a of the notch 22 defines the portions 31 and 32 of the radiation electrode 3 that face each other.
Further, the vertical portion 22b is for reducing the width dimension of the radiation electrode 3.
Thus, by reducing the width dimension of the radiation electrode 3, the influence of the notch 21 on the formation of the self-inductance of the radiation electrode 3 can be increased.
[0044]
The electrode shape (electrode pattern) formed on the one main surface 1a and the end surface 1c of the substrate 1 is the same as that shown in FIG.
[0045]
In the surface mount antenna 10b configured as described above, the capacitance generated between the portions 31 and 32 of the radiation electrode 3 facing each other constitutes a part of the capacitance component that defines the resonance frequency.
[0046]
When the electrode pattern print misalignment occurs on the one main surface 1b or the end surface 1d of the substrate 1, the distance between the portions 31, 32 of the radiation electrode 3 that are opposite to each other changes, and the capacitance generated in this portion. Changes.
At the same time, the width of the radiation electrode 3 is reduced or enlarged due to the inclination of the notch 21, and the self-inductance of the radiation electrode 3 changes.
As a result, the decrease and increase of the resonance frequency are canceled out, and a desired resonance frequency is obtained.
[0047]
As described above, in the surface-mounted antenna 10b, variation in the resonance frequency when the electrode pattern is misprinted is suppressed, and the labor for frequency adjustment is reduced.
[0048]
Note that the notch 21 does not extend over the other main surface 1b and the end surface 1d of the base 1, but may be provided only on one of the surfaces.
Furthermore, the notch 8 may be other shapes such as a semicircular shape or a rectangular shape instead of the tapered shape.
[0049]
Further, the shape of the notch 22 is not limited to the above-described shape as long as it defines portions facing the radiation electrode.
[0050]
In the first and second embodiments, the case where the radiation electrode 3 of the substrate 1 has a substantially rectangular shape has been described. However, the radiation electrode may have another shape such as a substantially U shape or a meander shape. .
[0051]
In the second embodiment, the case where the electrode pattern notches are provided on both the end face 1c side and the end face 1d side of the base 1 has been described. However, the electrode pattern notches are provided only on the end face 11d side of the base 1. May be provided.
[0052]
Next, a cellular phone is taken as an example of a communication device using the surface mount antenna of each of the above embodiments, and the configuration thereof will be described with reference to FIG.
[0053]
In the figure, a ground electrode and a feeding electrode (both not shown) of the surface-mounted antenna 10a are soldered to a substrate 101 constituting the mobile phone 100.
[0054]
Thus, in the mobile phone 100, the use of the surface-mounted antenna 10a suppresses variations in the resonant frequency and reduces the frequency adjustment effort, thereby realizing a reduction in manufacturing cost.
[0055]
Similar to the surface-mounted antenna 10a, the surface-mounted antennas 10b and 10c can also be mounted on the mobile phone 100.
[0056]
【The invention's effect】
According to the surface mount antenna of the present invention, when the capacitance component that defines the resonance frequency increases or decreases due to the printing deviation of the electrode pattern, the inductance component decreases or increases due to the notch provided in the electrode pattern. The decrease and increase of the resonance frequency are offset.
In this way, variations in resonance frequency are suppressed, and the effort of frequency adjustment is reduced.
[0057]
In addition, according to the communication device according to the present invention, since the use of the surface mount antenna that suppresses the variation of the resonance frequency due to the printing deviation of the electrode pattern and reduces the frequency adjustment effort, the manufacturing cost is reduced. The
[Brief description of the drawings]
FIG. 1 is a perspective view of a surface mount antenna according to a first embodiment of the present invention.
2 is a front view showing a state in which there is no printing misalignment of the electrode pattern of the surface-mounted antenna of FIG. 1. FIG.
3 is a front view showing a state where the electrode pattern of the surface-mounted antenna of FIG. 1 is shifted upward. FIG.
4 is a front view showing a state in which the electrode pattern of the surface-mounted antenna of FIG. 1 is shifted downward. FIG.
FIG. 5 is a perspective view of a surface mount antenna according to a second embodiment of the present invention.
FIG. 6 is a perspective view showing a communication device according to the present invention.
FIG. 7 is a perspective view of a conventional surface mount antenna.
8 is a circuit diagram showing an equivalent circuit of the surface-mounted antenna of FIG.
9 is a front view showing a state in which there is no printing deviation of the electrode pattern of the surface-mounted antenna of FIG.
10 is a front view showing a state in which the electrode pattern of the surface-mounted antenna of FIG. 7 is shifted upward. FIG.
11 is a front view showing a state in which the electrode pattern of the surface-mounted antenna of FIG. 7 is shifted downward. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Base 1a One main surface 1b The other main surface 1c, 1d End surface 2 First ground electrode 3 Radiation electrode 3a Open end 31 Opposing part 32 Opposing other part 4 Feeding electrode 5 Second ground electrode 6 Gap 10a, 10b Surface mount antenna 8, 21, 22 Notch 100 Mobile phone (communication device)

Claims (3)

A first ground electrode is formed on one main surface of a rectangular parallelepiped base made of a dielectric or magnetic material;
Stripline-like radiation electrode is formed on the other main surface of the substrate,
One end of the radiation electrode is continuously bent from the other main surface of the base to the first end face of the base, forming a first open end at the first end face, and the other part of the base of the base. Forming a second open end on the other main surface;
The other end of the radiation electrode is connected to the first ground electrode,
The first end surface of the base body is opposed to the first open end of the radiation electrode via a gap, and a ridge line where one end intersects the other main surface of the base body and the first end surface. A surface-mount antenna that forms a second ground electrode that is opposed to the second open end of the radiation electrode and has the other end connected to the first ground electrode across a portion ,
Each electrode is formed by printing an electrode pattern,
A surface having a taper-shaped notch formed at the time of printing the electrode pattern on the ridge line portion of the base body, the taper-shaped notch for suppressing variation in resonance frequency caused by printing deviation of the electrode pattern with respect to the radiation electrode. Mountable antenna. A first ground electrode is formed on one main surface of a rectangular parallelepiped base made of a dielectric or magnetic material;
Stripline-like radiation electrode is formed on the other main surface of the substrate,
One end of the radiation electrode is continuously bent from the other main surface of the base to the first end face of the base, forming a first open end at the first end face, and the other part of the base of the base. Forming a second open end on the other main surface;
The other end of the radiation electrode is connected to the first ground electrode,
The first end surface of the base body is opposed to the first open end of the radiation electrode via a gap, and a ridge line where one end intersects the other main surface of the base body and the first end surface. A surface-mount antenna that forms a second ground electrode that is opposed to the second open end of the radiation electrode and has the other end connected to the first ground electrode across a portion ,
Each electrode is formed by printing an electrode pattern,
On the other end side of the radiation electrode, on the ridge line portion where the other main surface of the substrate and the second end surface formed to face the first end surface of the substrate intersect, the other main surface of the substrate A tapered notch and a rectangular notch are formed at the time of printing the electrode pattern, including the second end face, for suppressing variations in resonance frequency caused by printing deviation of the electrode pattern. Surface mount antenna.   A communication device comprising the surface-mounted antenna according to claim 1.

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