JPH0766620A - Antenna - Google Patents

Abstract

PURPOSE:To provide a shield loop antenna whose performance is equivalent to a conventional shield loop antenna. CONSTITUTION:In the shield loop antenna provided with an electric field component shielding part for which a loop-like conductor is shielded so as to make the sensitivity of electric field components small as much as possible and to provide the sensitivity of magnetic field components only, the loop-like conductor is formed on one surface of a double sided printed board as loop-like copper foil patterns 12 and 14. Also, the electric field component shielding part is constituted as a parallel plate line formed by the loop-like copper foil pattern 12 and the copper foil pattern 16 on the other surface provided opposing to the loop-like copper foil pattern 12. Also, an electrode is formed by the copper foil pattern 31 on the other surface opposing to the loop-like copper foil pattern 14 and a capacitor for matching impedance is constituted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna for transmitting / receiving radio equipment, and more particularly to an improved structure of a shield loop antenna.

[0002]

2. Description of the Related Art FIG. 6 is a block diagram showing an ordinary loop antenna, wherein 1 is a loop antenna, 2 is an impedance matching capacitor, 3 is a feeding coaxial cable, and 4 is a received signal by the loop antenna 1. An ordinary loop antenna has an adverse effect when an electric field component E is generated between the ground plane or the metal object 5 and an antenna having sensitivity only to the magnetic field component is required. This is because, when an electric field component is generated, an ordinary loop antenna characteristically receives a composite of the electric field component and the magnetic field component, and cannot purely receive the magnetic field component.

Therefore, there is a shield loop antenna as an antenna provided with an electric field component shield portion for shielding an electric field component, and FIG. 7 is a configuration diagram of the shield loop antenna. In FIG. 7, 6 is a shield loop antenna, 7 is a semi-rigid coaxial cable as an electric field component shield part, 8 is a copper wire having the same thickness as the semi-rigid coaxial cable 7, 9 is a received signal by the shield loop antenna, and 10 is a connection part. is there.

When manufacturing such a shielded loop antenna, a connecting portion 10 between the coaxial cable 7 and the copper wire 8 is manufactured.
It is manufactured by soldering using a special jig or the like for connection in step 1 or connection of the matching capacitor 2. The shielded loop antenna, that is, the magnetic field antenna, is often used in a portable wireless device because it has a characteristic that the reception gain is not attenuated even when it is close to the human body (correctly, when orthogonal).

[0005]

Since the conventional shielded loop antenna is constructed as described above, there is a problem that the product cost of the semi-rigid coaxial cable is high. Further, since the soldering is performed using a special jig or the like, there is a problem that the manufacturing cost is high.

The present invention has been made to solve the above problems, and an object thereof is to obtain an inexpensive shield loop antenna having the same performance as a conventional shield loop antenna.

[0007]

An antenna according to the present invention has an electric field component shield portion in which a loop-shaped conductor is shielded in order to minimize the sensitivity of an electric field component and to have the sensitivity of only a magnetic field component. In a shielded loop antenna, a looped conductor is formed as a looped copper foil pattern on one surface of a double-sided printed circuit board, and an electric field component shield part is provided on the copper foil pattern on the other surface and the copper foil pattern on the other surface. It is configured as a parallel plate line formed by a foil pattern.

Further, the loop-shaped conductor is formed as a loop-shaped copper foil pattern on one surface of the double-sided printed circuit board, and the electric field component shield portion is provided on the other surface provided opposite to the loop-shaped copper foil pattern. It is configured as a parallel plate line formed by a copper foil pattern, and an impedance matching capacitor is formed by facing the loop-shaped copper foil pattern and forming electrodes on the other surface by the copper foil pattern.

Further, the loop-shaped conductor is formed as a loop-shaped copper foil pattern on one surface of the flexible printed wiring board, and the electric field component shield portion is provided on the loop-shaped copper foil pattern and the other surface provided opposite to the loop-shaped copper foil pattern. It is configured as a parallel plate line formed by a copper foil pattern, and
The feed line to the shielded loop antenna has a parallel plate configuration formed by the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface.

Further, the loop-shaped conductor is formed as a loop-shaped copper foil pattern on one surface of the flexible printed wiring board, and the electric field component shield portion is provided on the loop-shaped copper foil pattern and the other surface provided opposite to the loop-shaped copper foil pattern. A shielded loop antenna, which is configured as a parallel plate line formed by a copper foil pattern, and which forms an impedance matching capacitor by facing the loop-shaped copper foil pattern and forming an electrode by the copper foil pattern on the other surface. The power supply line to the is a parallel plate structure formed by the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface.

[0011]

In the present invention, the loop-shaped conductor is formed as a loop-shaped copper foil pattern on one surface of the double-sided printed circuit board, and the electric field component shield portion is provided on the other side of the loop-shaped copper foil pattern so as to face the loop-shaped copper foil pattern. Since it is configured as a parallel plate line formed by the copper foil pattern on the surface, it is possible to obtain improvements such as a lower unit price and a lower manufacturing cost than the case where a semi-rigid coaxial cable is used. In addition, mass productivity is improved.

Further, since the impedance matching capacitor is composed of the dielectric of the double-sided printed board and the copper foil pattern, the capacitor as a component can be deleted. Further, the work cost due to the soldering can be reduced.

Further, the feed line to the shielded loop antenna has a parallel flat plate structure formed of the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface, whereby the feed portion and the antenna portion are connected. Eliminates discontinuity at the connection.

[0014]

EXAMPLES Example 1. FIG. 1 is an outline view of a shield loop antenna according to a first embodiment of the present invention.
(B) shows the back surface. Reference numeral 11 is a shielded loop antenna according to the present invention, 12 is a surface copper foil pattern of a parallel plate line portion, 13 is an impedance matching chip capacitor, and 14 is a copper foil forming a loop conductor together with the surface copper foil pattern 12 of the parallel plate line portion. It is a pattern. Reference numeral 15 is a power feeding coaxial cable, and 16 is a back surface copper foil pattern of the parallel plate line portion. Reference numeral 17 is a back surface through hole, 18 is a front surface through hole, and 17 and 18 are connected. A core wire 19 of the coaxial cable 15 is soldered to the copper foil pattern 12. 20 is an outer conductor of the coaxial cable 15,
Soldered to the surface through hole 18.

Copper foil pattern 1 forming a parallel plate line portion
The copper foil pattern 14, which forms a loop-shaped conductor with the copper foil patterns 2 and 16 and the copper foil pattern 12, is formed of a double-sided printed circuit board. FIG. 2 is a cross-sectional view of the parallel flat plate line portion.
Is a dielectric substrate of a double-sided printed circuit board.

In the first embodiment, the portion of the conventional shielded loop antenna 6 shown in FIG. 7 that corresponds to the semi-rigid coaxial cable 7, that is, the electric field component shield portion is a parallel plate formed by front and back surface copper foil patterns 12 and 16. A copper foil pattern 1 that is composed of a line part, and the part corresponding to the copper wire 8 is on one side.
The configuration of 4 has the same performance as the conventional shielded loop antenna. Further, by using the chip matching capacitor 13 as the impedance matching capacitor 2, the capacitor 13 can be automatically inserted at the time of antenna assembly. Here, it is assumed that the characteristic impedance of the semi-rigid coaxial cable 7 is 50Ω. In addition, the impedance of the parallel plate line section is Z
_When the thickness of the double-sided printed board is h, the pattern width of the copper foil patterns 12 and 16 is W, and the dielectric constant of the board is ε _r ,

[0017]

[Equation 1]

Can be approximated by Therefore, by determining each constant so as to match this calculation, it is possible to realize a transmission line having a characteristic impedance of 50Ω of a parallel plate line. A single-sided copper foil pattern 14 which is line-symmetric with respect to the copper foil pattern 12 on the surface of the parallel plate line and the center line 22 is formed, and the copper foil patterns 12 and 14 form a loop-shaped conductor. In the shielded loop antenna according to the first embodiment, a looped conductor and a parallel plate line as an electric field component shield part are formed by a double-sided printed circuit board so that a chip capacitor can be automatically inserted as a matching capacitor, and a feeder line can also be used. Since it is only soldered to the board, it has excellent mass productivity. In this way, a shielded loop antenna having the same characteristics as the shielded loop antenna shown in FIG. 5 and having a low cost can be manufactured. In FIG. 1B showing the back surface of FIG. 1, the feeding coaxial cable 15 is not shown.

Example 2. FIG. 3 is an outline view of a shielded loop antenna according to a second embodiment of the present invention.
(B) shows the back surface. In FIG. 7, the parts denoted by the same reference numerals as those in FIG. 1 indicate the same parts, and 31 is a copper foil pattern on the back surface for giving a capacitance component. Since the structure of the copper foil pattern 31 on the back surface is parallel to the structure of the copper foil pattern 14 on the front surface through the thickness of the substrate and has a capacitance component between them, the chip capacitor 13 is attached. The same effect can be obtained. Therefore, according to the second embodiment, since the matching capacitor as a component is not necessary, the antenna can be manufactured at a lower cost than the first embodiment.

Copper foil pattern 3 as capacitor electrode
In No. 1, since the capacitance component changes by changing the length of its outer shape, it is possible to find an appropriate capacitance value for antenna matching by adjusting the outer length of the copper foil pattern 31. Therefore, for example, at the time of trial manufacture, the length of the copper foil pattern 31 can be adjusted as described above to determine the length corresponding to the appropriate capacitance value, and the pattern of this length can be used for mass production.

In the second embodiment, the power feeding coaxial cable 1 is used.
The connection of 5 is as follows. That is, the core wire 19 is soldered to the surface copper foil pattern 12 by passing the core wire 19 together with the insulator 25 from the back surface through the hole 23 provided in the substrate 21. The outer conductor 20 is soldered to the back surface copper foil pattern 16. In FIG. 2, the copper foil pattern 12 and the copper foil pattern 14 are 12 on the left side and 14 on the right side of the center line 22. Also,
The copper foil pattern 16 and the copper foil pattern 31 are indicated by a one-dot chain line 2
At the border of 4, the left side is 31 and the right side is 16.

Example 3. FIG. 4 is an outline view of a shield loop antenna according to a third embodiment of the present invention, in which FIG.
(B) shows the back surface. 4, parts that are the same as or correspond to those in FIG. 1 are given the same reference numerals, and descriptions thereof will be omitted.
32 is a flexible printed wiring board (hereinafter referred to as FPC) used in place of the dielectric substrate 21 of Example 1, 33
Is a feed line of a parallel plate line formed on the FPC 32. Instead of using the coaxial cable 15, a rectangular portion is newly provided in the downward direction of the drawing in the shape of the FPC 32, and a surface copper foil pattern is formed on the surface of the portion. The pattern surface 12 is provided by extension, and the back surface is formed by extending the pattern surface of the back surface copper foil pattern 16.
Further, the reception signal 9 is obtained by providing one of the connection portions on the front surface copper foil pattern 12 and the other on the back surface copper foil pattern 16.

From the above, the feed line is also a parallel plate line and is directly connected to the loop antenna section, so that signal loss due to discontinuity between the feed section and the antenna section can be reduced, and The work cost of soldering during assembly can be reduced.

In this embodiment, the above-mentioned embodiment 1 is replaced by F
Although a PC is used and a feed line of a parallel plate line is used, the same may be applied to the second embodiment. An example of this case is shown in FIG. FIG. 5 is an outline view of a shield loop antenna according to another embodiment of the present invention,
(A) shows the front surface and (b) shows the back surface. Note that the description of the reference numerals and operations is the same as that of the above-described third embodiment, and therefore will be omitted.

[0025]

As described above, according to the present invention, the loop-shaped conductor is formed as a loop-shaped copper foil pattern on one surface of the double-sided printed board, and the electric field component shield portion is opposed to the loop-shaped copper foil pattern. Since it is configured as a parallel plate line formed with the copper foil pattern on the other surface provided, the unit cost and manufacturing cost can be reduced, and an antenna with the same performance as the conventional shielded loop antenna can be obtained. There is.

Further, since the impedance matching capacitor is composed of the dielectric of the double-sided printed circuit board and the copper foil pattern, the capacitor as a component is unnecessary. Further, the work cost due to the soldering can be reduced. Therefore, the antenna can be manufactured at a lower cost.

Further, the feed line of the shielded loop antenna is a parallel flat plate formed by the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface, so that the connecting portion between the feed portion and the antenna portion is formed. It is possible to reduce the signal loss due to the discontinuity of and the assembly work cost.

[Brief description of drawings]

FIG. 1 is an outline view showing a shield loop antenna according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view of a parallel plate line section.

FIG. 3 is an outline view showing a shield loop antenna according to a second embodiment of the present invention.

FIG. 4 is an outline view showing a shield loop antenna according to a third embodiment of the present invention.

FIG. 5 is an outline view showing a shield loop antenna according to another embodiment of the present invention.

FIG. 6 is a configuration diagram showing a normal loop antenna.

FIG. 7 is a configuration diagram showing a conventional shielded loop antenna.

[Explanation of symbols]

 11 Shield Loop Antenna 12 Copper Foil Pattern 13 Chip Capacitor 14 Copper Foil Pattern 15 Coaxial Cable 16 Copper Foil Pattern 21 Conductor Substrate 31 Copper Foil Pattern 32 Flexible Printed Wiring Board 33 Feed Line

Claims (4)

[Claims] 1. A shielded loop antenna having an electric field component shield part in which a looped conductor is shielded in order to minimize the sensitivity of the electric field component and to have the sensitivity of only the magnetic field component. It is formed as a loop-shaped copper foil pattern on one surface of the printed circuit board, and the electric field component shield part is formed by the loop-shaped copper foil pattern and the copper foil pattern on the other surface provided opposite to the parallel pattern. An antenna characterized by being configured as a flat line. 2. A shielded loop antenna having an electric field component shield part in which a looped conductor is shielded in order to minimize the sensitivity of the electric field component and to have the sensitivity of only the magnetic field component. It is formed as a loop-shaped copper foil pattern on one surface of the printed circuit board, and the electric field component shield part is formed by the loop-shaped copper foil pattern and the copper foil pattern on the other surface provided opposite to the parallel pattern. An antenna, characterized in that it is configured as a flat plate line, and an impedance matching capacitor is configured by forming an electrode with the copper foil pattern on the other surface facing the loop-shaped copper foil pattern. 3. A shielded loop antenna having an electric field component shield part in which the looped conductor is shielded so as to minimize the sensitivity of the electric field component and to have the sensitivity of only the magnetic field component. It is formed as a loop-shaped copper foil pattern on one surface of the printed wiring board, and the electric field component shield part is formed by the loop-shaped copper foil pattern and the copper foil pattern on the other surface provided opposite to the loop-shaped copper foil pattern. It is configured as a parallel plate line, and the feed line to the shield loop antenna is a parallel plate configuration formed by the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface. And the antenna. 4. A shielded loop antenna having an electric field component shield part in which the looped conductor is shielded so as to minimize the sensitivity of the electric field component and to have the sensitivity of only the magnetic field component. It is formed as a loop-shaped copper foil pattern on one surface of the printed wiring board, and the electric field component shield part is formed by the loop-shaped copper foil pattern and the copper foil pattern on the other surface provided opposite to the loop-shaped copper foil pattern. A parallel plate line is formed, and an impedance matching capacitor is formed by forming an electrode with a copper foil pattern on the other surface facing the loop-shaped copper foil pattern, and a feed line to the shield loop antenna. By the flexible printed wiring board, the loop-shaped copper foil pattern and the copper foil pattern on the other surface An antenna characterized by having a parallel plate configuration formed.