JP5682119B2 - Antenna device and receiving device - Google Patents

Description

  The present invention relates to an antenna device applicable to portable electronic devices such as portable AV devices and cellular phones, and a receiving device thereof.

  With the increase in screen size and performance of portable electronic devices, and the downsizing and thinning of television (TV) tuners, portable electronic device terminals that allow TV viewing on the receiving terminal have become popular in the world. .

In recent years, an electronic device such as a communication terminal typified by a cellular phone has been increasing in number having a function of receiving FM radio, digital radio, or digital television broadcast waves.
The sound of the electronic device is also listened to with an earphone (including headphones) through an earphone cable using a coaxial cable.

Also, in electronic devices such as mobile phones equipped with a television receiver, the sound is listened to with earphones, and the earphone cable is formed of a shield cable to function as a receiving antenna, which is also used for high-frequency signal transmission To be done.
A so-called earphone antenna is disclosed in Patent Documents 1 and 2, for example.

Japanese Patent No. 4003671 Japanese Patent No. 4123262

As the above-described earphone antenna, an earphone cable using a φ3.5 mm or φ2.5 mm plug is often used as an antenna for FM broadcast wave reception or one-segment reception.
However, when cylindrical terminals such as φ3.5 and φ2.5 poles are used, there is a disadvantage that high-frequency coupling is large and antenna gain is significantly degraded.

  An object of the present invention is to provide an antenna device and a receiving device that can reduce loss in a terminal coupling portion and can realize high reception performance.

An antenna device according to a first aspect of the present invention includes an audio signal transmission cable including an audio signal plug including a plurality of terminals and a plurality of lines, the audio signal plug being connected to one end side to transmit the audio signal. The audio signal plug is formed at the cylindrical tip portion so that at least the left channel terminal, the right channel terminal, and the ground terminal of the stereo signal are insulated from each other along the cylindrical axis direction. At the rear end, at least a stereo signal left channel terminal, right channel terminal, and ground terminal are formed to be insulated from each other around the cylindrical axis, and the left channel terminal at the front end and the left channel terminal at the rear end are within the cylindrical axis. The right channel terminal at the front end and the right channel terminal at the rear end are electrically connected through the cylindrical shaft, and the ground terminal at the front end. A ground terminal at the rear end is electrically connected through the cylindrical shaft, and the audio signal transmission cable includes at least an audio left (L) line, a right (R) line, and a ground (G) line, Of the left (L) line, the right (R) line, and the ground (G) line, at least a ground (G) line is formed by a coaxial cable with a shield portion covered with a jacket, At least the left channel terminal at the rear end and one end of the left (L) line of the audio signal transmission cable, and the right channel terminal at the rear end of the audio signal plug and the right of the audio signal transmission cable. (R) One end side of the line is connected via a high-frequency cutoff unit having a high-frequency cutoff function, and above the audio signal plug And the ground terminal of the rear end, and a shield portion of the shield portion coaxial cable with the audio signal transmission cable, one end side of the ground (G) line is connected, one end of the audio signal transmission cable And at least one end side of the other end side of the audio signal transmission cable is provided with a relay board portion for connecting to the cylindrical rear end portion of the audio signal plug, An accommodation area for accommodating the cylindrical rear end portion of the audio signal plug is formed, and is arranged in an area facing each terminal of the audio signal plug accommodated along the longitudinal direction of the accommodation area. A connection terminal connected to the plug terminal is formed, and at least a connection line connected to the connection terminal with each terminal of the audio signal plug and the high-frequency cutoff unit are mounted. The

A receiving device according to a second aspect of the present invention includes an antenna device and an electronic device to which the antenna device can be connected and has a broadcast wave receiving function, and the antenna device includes a plurality of terminals. An audio signal transmission cable including a signal plug and a plurality of lines, the audio signal plug being connected to one end side to transmit the audio signal, and the audio signal plug is connected to a cylindrical tip portion. , At least stereo signal left channel terminal, right channel terminal, ground terminal are formed insulated from each other along the cylindrical axis direction, and at least stereo signal left channel terminal, right channel terminal, ground are formed at the cylindrical rear end The terminals are formed to be insulated from each other around the cylindrical axis, the left channel terminal at the front end and the left channel terminal at the rear end are electrically connected through the cylindrical axis, The right channel terminal at the end and the right channel terminal at the rear end are electrically connected through the cylindrical shaft, and the ground terminal at the front end and the ground terminal at the rear end are electrically connected through the cylindrical shaft. The signal transmission cable includes at least an audio left (L) line, a right (R) line, and a ground (G) line, and the audio left (L) line, right (R) line, and ground (G) line. At least a ground (G) line is formed by a coaxial cable with a shield portion covered with a jacket, and at least the left channel terminal at the rear end of the audio signal plug and the left ( L) The right channel terminal at one end of the line and the rear end of the audio signal plug and the audio signal transmission cable. (R) One end side of the line is connected via a high frequency cutoff portion having a high frequency cutoff function, and the ground terminal at the rear end portion of the audio signal plug and the shield portion of the audio signal transmission cable are attached. The shield portion of the coaxial cable and one end side of the ground (G) line are connected , and at least one end side of the one end side of the audio signal transmission cable and the other end side of the audio signal transmission cable is A relay board portion for connecting to the cylindrical rear end portion of the audio signal plug is disposed, and a receiving area for receiving the cylindrical rear end portion of the audio signal plug is formed in the relay board portion. A connection terminal that is disposed in a region facing each terminal of the audio signal plug housed along the longitudinal direction of the housing region and is connected to a corresponding plug terminal is formed, at least A connection line connected to the connection terminal with each terminal of the audio signal plug and the high-frequency cutoff unit are mounted .

  According to the present invention, it is possible to reduce the loss in the terminal coupling portion and realize high reception performance.

It is a figure which shows the receiving system (reception apparatus) containing the portable terminal which is an example of the electronic device (set apparatus) containing the antenna cable which forms the antenna apparatus which concerns on the 1st Embodiment of this invention. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 1st Embodiment of this invention. It is a figure which shows the equivalent circuit of the plug connection part containing the coaxial cable with a shield part and relay board | substrate which form the antenna cable which concerns on this embodiment. It is a figure which shows the structural example of the coaxial cable with a shield part. It is a figure which shows the structural example of the mounting board | substrate in the relay part which concerns on this embodiment. It is a figure which shows the example of mounting to the board | substrate of the 3 pole jack part in a portable terminal (electronic device). It is a figure which shows the 1st peak gain characteristic with respect to the frequency of a receiver at the time of mounting a 3 pole jack part on the board | substrate in a portable terminal (electronic device) like FIG. 6 (A) and (B). It is a figure which shows the 2nd peak gain characteristic with respect to the frequency of a receiver at the time of mounting a 3 pole jack part on the board | substrate in a portable terminal (electronic device) like FIG. 6 (A) and (B). It is a figure which shows the peak gain characteristic with respect to the frequency of a receiver when the ferrite bead as a high frequency interruption | blocking part is mounted in the plug terminal in the mounting board of the relay part of an antenna cable. It is a figure which shows the peak gain characteristic with respect to the frequency of the receiver of a VHF band when an earphone cable is connected to an antenna cable. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 2nd Embodiment of this invention. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 3rd Embodiment of this invention. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 4th Embodiment of this invention. It is a figure which shows the peak gain characteristic with respect to the frequency of the receiver of a VHF band and a UHF band when an earphone cable is connected without using an antenna cable. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 5th Embodiment of this invention. It is a figure which shows the equivalent circuit of the receiving system which concerns on the 6th Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The description will be given in the following order.
1. First Embodiment (First Configuration Example of Receiving System (Receiving Device))
2. Second Embodiment (Second Configuration Example of Receiving System (Receiving Device))
3. Third Embodiment (Third Configuration Example of Receiving System (Receiving Device))
4). Fourth Embodiment (Fourth Configuration Example of Receiving System (Receiving Device))
5. Fifth Embodiment (Fifth Configuration Example of Receiving System (Receiving Device))
6). Sixth Embodiment (Sixth Configuration Example of Receiving System (Receiving Device))

<1. First Embodiment>
[First Configuration Example of Receiving System (Receiving Device)]
FIG. 1 is a diagram illustrating a receiving system (receiving device) including a mobile terminal that is an example of an electronic device (set device) including an antenna cable that forms an antenna device according to the first embodiment of the present invention.
FIG. 2 is a diagram showing an equivalent circuit of the receiving system according to the first embodiment of the present invention.
FIG. 3 is a view showing an equivalent circuit of a plug connection portion including a coaxial cable with a shield portion and a relay substrate forming the antenna cable according to the present embodiment.

  The reception system 10 includes a mobile terminal 20 as an electronic device and an antenna device 30 as main components.

The portable terminal 20 includes, for example, a television receiver, and includes an audio system circuit, a display system circuit, a display unit 21 such as a liquid crystal display device, and an operation unit that performs key input and the like.
The mobile terminal 20 includes a round jack 22 such as three-pole plug 40 to form an antenna device for receiving a high-frequency device signals is connected.
The configuration of the round jack portion 22 will be described in detail later.

  The antenna device 30 of the present embodiment can receive and transmit radio signals in the VHF band to the UHF band used for receiving, for example, FM bands transmitted from broadcast stations and digital television broadcasts. .

The antenna device 30 is mainly formed by a three-pole plug for audio signal 40 and an audio signal transmission cable 50, and the jack portion is formed in the portable terminal 20 which is an electronic device.
In the first embodiment, the audio signal transmission cable 50 is formed by the antenna cable 60 and the earphone cable 70.

In the antenna cable 60, a three-pole plug 40 of φ3.5 mm is connected to one end of the coaxial cable 61 with a shield part via a relay part, and a three-pole jack 63 of φ3.5 mm is formed at the other end.
Caps 64 and 65 are arranged at the connection portion of the three-pole plug 40 by the relay board and the formation portion of the three-pole jack 63.

[Configuration example of 3-pole plug]
The three-pole plug 40 has a left end (Lch) terminal 411, a right channel (Rch) terminal 412, and a ground (GND) of a stereo audio signal in order from the front end side to a cylindrical front end portion 41 inserted into the jack portion 22. ) Terminals 413 are insulated from each other.
In the three-pole plug 40, a GND terminal 421, an Rch terminal 422, and an Lch terminal 423 are insulated from each other at a cylindrical rear end portion 42 connected to one end portion (side) of the antenna cable 60 from the center portion side. Is formed.
In the three-pole plug 40, the Lch terminal 411 at the front end portion 41 and the Lch terminal 423 at the rear end portion 42 are electrically connected through the cylindrical shaft.
The Rch terminal 412 at the front end 41 and the Rch terminal 422 at the rear end 42 are electrically connected through the cylindrical shaft.
GND terminal 42 1 of the GND terminal 413 and the rear end portion 42 of the tip 41 is electrically connected through the cylinder axis.

The antenna cable 60 includes a coaxial cable 61, a relay part 62 disposed at one end of the coaxial cable, and a three-pole jack 63 formed at the other end of the coaxial cable 61.
The relay part 62 is covered with a cap 64, and the three-pole jack 63 is covered with a cap 65.

The coaxial cable 61 includes a plurality of lines, and a three-pole plug 40 is connected to one end side at a relay portion 62 and an earphone cable 70 is formed to be connectable to the other end side via a three-pole jack 63.
The coaxial cable 61 is formed of a coaxial cable with a shield portion covered with a jacket, for example.

[Configuration example of antenna cable (configuration example of coaxial cable with shield)]
FIG. 4 is a diagram illustrating a structure example of a coaxial cable with a shield portion.

The shielded coaxial cable 61 in FIG. 4 is formed by a three-core coaxial cable 610.
The three-core coaxial cable 610 has a plurality of core wires 611, 612, 613 that form an audio L line and R line, and a GND line, and an internal insulator 614 for insulating the core wires 611, 612, 613.
The coaxial cable 610 includes a shield portion 615 as an outer conductor disposed on the outer periphery of the insulator 614 and an outer insulator (outer skin, jacket) 616 such as an elastomer covering the entire outer periphery.

The core wires 611 and 612 forming the R line and the L line correspond to other lines, and the core wire 613 forming the GND line corresponds to one line.

The core wires 611, 612, and 613 are made of polyurethane wires containing aramid fibers, for example.
The insulator 614 is formed by, for example, X-ray irradiation crosslinked PE.
Moreover, the shield part 615 is formed, for example with an annealed copper wire.
Shield portion 615 is formed by a braided shield obtained by braiding a plurality of conductive wires, for example, bare annealed copper wire.
The braided shield is known as an electrostatic shield method that has less flexibility in bending even when bent, and has adequate flexibility, bending strength, and mechanical strength, compared to a horizontal shield. is there.
The core wires 611, 612, 613 and the shield part 615 have impedance at high frequencies.

[Configuration example of relay unit]
Next, a configuration example of the relay unit 62 will be described.
FIG. 2 is a diagram illustrating a specific configuration of the relay unit according to the present embodiment and a connection example of the audio signal transmission cable and the coaxial cable.

The relay part 62 is formed by, for example, a substrate or molding.
On one end side of the relay portion 62, the coaxial cable 610 has the insulator 614, the shield portion 615, and the jacket 616 removed, and the core wires 611, 612, and 613 are exposed.
Further, the jacket 616 is removed in the vicinity of the relay part 62 and the shield part 615 is exposed.
On the other end side of the relay portion 62, the rear end portion 42 of the three-pole plug 40 is disposed so as to face the end portions of the core wires 611, 612, and 613 on one end side of the coaxial cable 610.

In the relay part 62, the Rch terminal 422 of the rear end part 42 of the three-pole plug 40 is connected to a high-frequency cutoff part 621 formed of, for example, an inductor L1 having a high-frequency cutoff function or a ferrite bead FB1.
The Rch terminal 422 of the rear end portion 42 of the three-pole plug 40 is connected to the core wire 611 (Rch line) of the coaxial cable portion 610 via the high frequency cutoff portion 621.

In the relay part 62, a high-frequency cutoff part 622 formed by, for example, an inductor L2 having a high-frequency cutoff function or a ferrite bead FB2 is connected to the Lch terminal 423 of the rear end part 42 of the three-pole plug 40.
The Lch terminal 423 of the rear end portion 42 of the three-pole plug 40 is connected to the core wire 612 (Lch line) of the coaxial cable portion 610 via the high frequency cutoff portion 622.

In the relay part 62, the GND terminal 421 at the rear end part 42 of the three-pole plug 40 is connected to the core wire 613 (GND line) of the coaxial cable 610, and the connection part is connected to the shield part 615 of the coaxial cable 610. .
Thereby, an antenna signal line LANT is formed.

  The high-frequency cutoff units 621 and 622 are mounted on the Lch and Rch audio lines for high-frequency cutoff so that the impedance is low in the voice band and high in the high-frequency region, for example, the VHF band or higher. Yes.

FIG. 5 is a diagram illustrating a configuration example of the mounting board of the relay unit according to the present embodiment.

The mounting substrate 80 is formed in a rectangular shape having a length of 16.1 mm and a width of 5.5 mm.
The mounting substrate 80 has a plug housing region 81 for housing the rear end portion 42 of the three-pole plug 40 having a diameter of 3.5 mm at one end portion in the longitudinal direction.
In this example, the length of the rear end portion 42 of the three-pole plug 40 is about 7.5 mm.
Around the plug accommodating region 81, a GND terminal 82 connected to the GND terminal 421 of the three-pole plug 40 accommodated in the vicinity of the accommodating opening is formed.
An R terminal 83 connected to the Rch terminal 422 is formed at an intermediate portion from the longitudinal tip of the plug housing region 81.
An L terminal 84 connected to the Lch terminal 423 is formed at the longitudinal end of the plug housing region 81.

The mounting substrate 80 has connection terminals 85, 86, 87 to which the core wires 611, 612, 613 of the coaxial cable 610 are connected by solder or the like at the other end in the longitudinal direction.
A ferrite bead FB1 that forms a high-frequency cutoff portion 621 is mounted between the positions where the terminal 83 and the connection terminal 85 are arranged.
A ferrite bead FB <b> 2 that forms a high-frequency cutoff unit 622 is mounted between the terminal 84 and the connection terminal 86.
The terminal 82 and the terminal 87 are connected by the connection wiring LW1. The terminal 83 and the ferrite bead FB1 are connected by a connection wiring LW2. The terminal 84 and the ferrite bead FB2 are connected by a connection wiring LW3.
The ferrite bead FB1 and the connection terminal 85 are connected by a connection wiring LW4. The ferrite bead FB2 and the connection terminal 86 are connected by a connection wiring LW5.

  In the mounting substrate 80, the terminals 421, 422, and 423 of the rear end portion 42 of the three-pole plug 40 are connected by soldering at terminals 82, 83, and 84 corresponding to the plug terminals, respectively, and function as an antenna. It has a structure.

[Configuration example of antenna cable 3-pole jack]
As shown in FIGS. 2 and 3, the three-pole jack 63 includes an Rch terminal 631, an Lch terminal 632, and a GND terminal 633.
In the vicinity of the three-pole jack 63, at the other end of the coaxial cable 610, the insulator 614, the shield 615, and the jacket 616 are removed, and the core wires 611, 612, and 613 are exposed. Further, the jacket 61 is removed in the vicinity of the three-pole jack 63 to expose the shield portion 615.
Then, Rch terminal 631 is connected to the core wire 611, Lch terminal 632 is connected to the core wire 612, GND terminal 6 3 3 are connected to the core wire 613.
In the figure, reference numeral 634 denotes a plug insertion slot.

[Configuration example of earphone cable]
One end of the earphone cable 70 is branched to connect an Rch earphone 71 and an Lch earphone 72, and a φ3.5 mm three-pole plug 73 is connected to the other end.
The three-pole plug 73 can be connected by inserting its cylindrical tip into the three-pole jack 63 of the antenna cable 60, and has an Rch terminal 731, an Lch terminal 732, and a GND terminal 733.
The Rch terminal 731 and the earphone 71 are connected by the Rch line 734, the Lch terminal 732 and the earphone 72 are connected by the Lch line 735, and the GND terminal 733 is connected to the GND lines 736 and 737.

[Configuration Example of Three-Pole Jack 22 of Portable Terminal (Electronic Device)]
As illustrated in FIG. 2, the three-pole jack portion 22 formed in the mobile terminal 20 includes a three-pole jack 221 and lead portions (drawer line portions) 222, 223, and 224.
The lead-out unit 222 is connected to the Rch terminal TR of the three-pole jack and supplies the Rch audio signal to a signal processing system (not shown).
The lead portion 222, high-frequency cutoff portion 225 which is formed by the inductor L and full E Light bead FB, etc. for high-frequency cutoff are inserted (connected).
The lead-out unit 223 is connected to the Lch terminal TL of the three-pole jack and supplies an Lch audio signal to a signal processing system (not shown).
The lead portion 223, high-frequency cutoff portion 226 which is formed by the inductor L and full E Light bead FB, etc. for high-frequency cutoff are inserted (connected).
The lead portion 224 is connected to the ground terminal TG of the three-pole jack and connected to the set ground.
The lead portion 224, high-frequency cutoff portion 227 is formed by the inductor L and full E Light bead FB, etc. for high-frequency cutoff are inserted (connected).
The lead portion 224 is branched into two, and the high frequency cutoff portion 227 is connected to the first branch line LB1. The second branch line LB2 forms an antenna signal line LAMT, is connected to the capacitor C221, and is further connected to the tuner 23 via the capacitor C221.

6A and 6B are diagrams illustrating an example of mounting a three-pole jack portion on a substrate in a portable terminal (electronic device).
FIG. 6A shows an example in which GND lines and signal lines (conductive lines) are formed on the back surface (mounting surface) of the mounting region of the jack portion 22 on the substrate 24.
FIG. 6B shows an example in which a region (non-conductive region) 241 having no GND line or signal line is formed on the back surface (mounting surface) of the mounting region of the jack portion 22.

  FIGS. 7A and 7B show a first example with respect to the frequency of the receiving device when the three-pole jack portion is mounted on the substrate in the portable terminal (electronic device) as shown in FIGS. 6A and 6B. It is a figure which shows a peak gain characteristic.

FIGS. 8A and 8B show a second example of the frequency with respect to the receiving device when the three-pole jack is mounted on the substrate of the portable terminal (electronic device) as shown in FIGS. It is a figure which shows a peak gain characteristic.
In FIGS. 7 and 8A and 8B, the curve indicated by H indicates the characteristics of horizontal polarization, and the curve indicated by V indicates the characteristics of vertical polarization. .
Further, in FIGS. 7 and 8, (C) and (D), charts showing the measurement results in detail in accordance with the characteristic diagrams are shown.

In this example, as shown in FIGS. 6 (A) and 6 (B), the case where this GND is on the back of the jack portion 22 and the case where the GND cable is mounted on the antenna cable 60 and the case where only the antenna cable 60 is attached are shown. This is a case where the antenna gain is measured in a dark room.
FIG. 7 shows a measurement result when the earphone cable 70 is connected, and FIG. 8 shows a measurement result when the antenna cable 60 is used alone.
As can be seen from these figures, when there is no conductive portion such as GND on the mounting surface (rear surface) of the area where the jack portion 22 is arranged, the characteristics are greatly improved as compared with the case where there is no conductive portion.

9A and 9B show the peak with respect to the frequency of the receiving device when the ferrite bead as the high-frequency blocking portion is mounted on the plug terminal on the mounting substrate of the relay portion of the antenna cable 60 and when it is not mounted. It is a figure which shows a gain characteristic.
FIG. 9A shows the measurement result when the ferrite bead as the high frequency cutoff part is mounted, and FIG. 9B shows the measurement result when the ferrite bead as the high frequency cutoff part is not mounted.
9A and 9B, the curve indicated by H indicates the characteristics of horizontal polarization, and the curve indicated by V indicates the characteristics of vertical polarization.
9 (C) and 9 (D) show charts showing the measurement results in detail in accordance with the characteristic diagrams.

  As can be seen from FIG. 9, when the high frequency cutoff part is not connected to the plug terminal, the characteristics are greatly deteriorated, and when the plug terminals are connected, good characteristics can be obtained.

FIG. 10A is a diagram illustrating a peak gain characteristic with respect to the frequency of the receiver in the VHF band when the earphone cable is connected to the antenna cable.
In FIG. 10A, the curve indicated by H indicates the characteristics of horizontal polarization, and the curve indicated by V indicates the characteristics of vertical polarization.
FIG. 10B shows a chart showing the measurement results in detail in accordance with the characteristic diagram.

  As can be seen from FIG. 10, by using the antenna device including the antenna cable and the earphone cable of this embodiment, both the low band and the high band of the VHF band can be received.

<2. Second Embodiment>
[Second Configuration Example of Receiving System (Receiving Device)]
FIG. 11 is a diagram showing an equivalent circuit of the receiving system according to the second embodiment of the present invention.

  The reception system 10A according to the second embodiment is different from the reception system 10 according to the first embodiment in that the antenna cable 60A and the earphone cable 70A are integrally connected instead of the plug connection in the antenna device 30A. There is.

Other configurations are the same as those of the first embodiment.
According to the second embodiment, the same effects as those of the first embodiment described above can be obtained.

<3. Third Embodiment>
[Third Configuration Example of Receiving System (Receiving Device)]
FIG. 12 is a diagram showing an equivalent circuit of the receiving system according to the third embodiment of the present invention.

The receiving system 10B according to the third embodiment is different from the receiving system 10A according to the second embodiment in that a four-pole plug 40B is used as a plug.
Accordingly, a four-core coaxial cable 610B is applied as the antenna cable 60B.
In FIG. 12, the cross section of the coaxial cable 610B is also shown.

The four-pole plug 40B has a microphone (MIC) terminal 414 formed between the Rch terminal 412 and the GND terminal 413 at the tip 41B.
In the four-pole plug 40B, the MIC terminal 424 is formed between the GND terminal 421 and the Rch terminal 422 at the rear end portion 42B.
In the relay unit 62B, the MIC terminal 424 is connected to a high-frequency cutoff unit 623 formed of an inductor L3 or a ferrite bead.
Further, the coaxial cable 610B includes one more core wire 617 than the three-core coaxial cable 610.
One end of the core wire 617 is connected to the high-frequency cutoff unit 623 at the relay unit 62B.
The other end of the core wire 617 is connected to a microphone (MIC) 90, and the MIC 90 is connected to a core wire 613 that is a GND line and a GND line of the earphone cable 70B.

In the jack portion 22B of the portable terminal (electronic device) 20B, the MIC terminal TM is added to the jack 221B, and the lead-out portion 228 is connected to the MIC terminal TM.
Then, the lead portions 228, high-frequency cutoff portion 229 which is formed by the inductor L and full E Light bead FB, etc. for high-frequency cutoff are inserted (connected).

Other configurations are the same as those of the second embodiment.
According to the third embodiment, the same effects as those of the first and second embodiments described above can be obtained.

<4. Fourth Embodiment>
[Fourth Configuration Example of Receiving System (Receiving Device)]
FIG. 13 is a diagram showing an equivalent circuit of the receiving system according to the fourth embodiment of the present invention.

  The receiving system 10C according to the fourth embodiment is different from the receiving system 10A according to the second embodiment in that the earphone cable 70 is connected to the three-pole plug 40 via the relay unit 62C without using the antenna cable. It is to be connected.

FIGS. 14A and 14B are diagrams illustrating peak gain characteristics with respect to frequencies of receiving apparatuses in the VHF band and the UHF band when an earphone cable is connected without using an antenna cable.
In FIGS. 14A and 14B, the curve indicated by H indicates the characteristics of horizontal polarization, and the curve indicated by V indicates the characteristics of vertical polarization.
In FIGS. 14C and 14D, charts showing the measurement results in detail are shown in accordance with the characteristic diagrams.
14A and 14C show the characteristics of the VHF band, and FIGS. 14B and 14D show the characteristics of the UHF band.

As can be seen from FIG. 14, by using the antenna device including the antenna cable and the earphone cable of the present embodiment, both the low band and the high band of the VHF band can be received.

  Even when only a normal earphone cable is used, as can be seen from the antenna gain measurement result of FIG. 14, the UHF band is better with the antenna cable, but the VHF band is equivalent. It is possible to realize an antenna device that can receive as it is.

<5. Fifth Embodiment>
[Fifth Configuration Example of Receiving System (Receiving Device)]
FIG. 15 is a diagram showing an equivalent circuit of the receiving system according to the fifth embodiment of the present invention.

The receiving system 10D according to the fifth embodiment is different from the receiving system 10A according to the second embodiment as follows.
That is, the GND line 613D as one line is formed by the coaxial cable 610D, and the Rch line 611D and the Lch line 612D of the audio signal as other lines are arranged outside and in parallel with the coaxial cable 610D.
As in the second embodiment, the connection in the relay unit 62D is connected to the plug terminal 422 through the high frequency cutoff unit 621, and the Lch line 612D is connected to the plug terminal 423 through the high frequency cutoff unit 622. ing.
In the relay portion 62D, the GND line 613D, the shield portion 615, and the GND terminal 421 of the plug 40 are connected to the coaxial cable 610D to form an antenna signal line LANT.
In relay unit 62D, capacitors C621 and C622 are formed between antenna signal line LANT and Rch line 611D and Lch line 612D.
In this embodiment, a capacitor is arranged. Thereby, it is possible to improve the antenna characteristics.

And the relay part 100 formed with a board | substrate or a mold is arrange | positioned at the other end side of the antenna cable 60D.
In the relay unit 100, the other end of the core wire 613D of the coaxial cable 610D is connected to the GND lines 736 and 737 of the earphone cable 70 by the wiring 101.
The other ends of the signal lines 611D and 612D are connected to high-frequency cutoff units 102 and 103 having a high-frequency cutoff function formed by inductors or ferrite beads.
The high-frequency cutoff unit 102 is connected to the Rch line 734 of the earphone cable 70 by the wiring 104, and the high-frequency cutoff unit 103 is connected to the Lch line 735 of the earphone cable 70 by the wiring 105.

  Also in the fifth embodiment having such a configuration, the same effect as described above can be obtained.

<6. Sixth Embodiment>
[Sixth Configuration Example of Receiving System (Receiving Device)]
FIG. 16 is a diagram illustrating an equivalent circuit of the reception system according to the sixth embodiment of the present invention.

The receiving system 10E according to the sixth embodiment is different from the receiving system 10B according to the third embodiment as follows.
That is, the GND line 613E as one line forms the coaxial cable 610E, and the Rch line 611E, the Lch line 612E, and the MIC line 617E of the audio signal as other lines are arranged outside and in parallel with the coaxial cable 610E. .
As in the third embodiment, the connection in the relay unit 62E is connected to the plug terminal 422 through the high frequency cutoff unit 621, and the Lch line 612E is connected to the plug terminal 423 through the high frequency cutoff unit 622. ing. Further, the MIC line 617E is connected to the plug terminal 424 through the high frequency cutoff unit 623.
In the relay unit 62E, GND line 613E and the shield portion 615 and the GND terminal 421 of the plug 40 B is a core wire in a coaxial cable 610E is connected, the antenna signal line LANT is formed.
In the relay unit 62E, capacitors C621, C622, and C623 are formed between the antenna signal line LANT, the Rch line 611E, the Lch line 612E, and the MIC line 617E.
In this embodiment, a capacitor is arranged.

And the relay part 100E formed with a board | substrate or a mold is arrange | positioned at the other end side of the antenna cable 60E.
In the relay unit 100E, the other end of the core wire 613E of the coaxial cable 610E is connected to the GND lines 736 and 737 of the earphone cable 70 by the wiring 101E.
The other ends of the signal lines 611E, 612E, and 617E are connected to high-frequency cutoff units 102E, 103E, and 106E having a high-frequency cutoff function formed by inductors and ferrite beads.
The high frequency cutoff unit 102E is connected to the Rch line 734 of the earphone cable 70 by the wiring 104E, and the high frequency cutoff unit 103E is connected to the Lch line 735 of the earphone cable 70 by the wiring 105E.
The high frequency cutoff unit 106E is connected to the MIC 90, and the MIC 90 is connected to the wiring 101E and the GND lines 736 and 737 of the earphone cable 70 by the wiring 107E.

  Also in the sixth embodiment having such a configuration, the same effect as described above can be obtained.

  As described above, according to the present embodiment, the loss of the coupling portion is reduced in the antenna that receives the VHF band and the UHF band by using the plug jack often used in normal audio such as φ3.5 mm and φ2.5 mm. It can be reduced and high reception performance can be realized.

In the antenna cable, the transmission cable may be configured with a parallel two line instead of the coaxial structure in the portion connected to the relay unit.
Further, the high-frequency cutoff portion can be formed by winding a cable portion around a magnetic material.

  10, 10A to 10E: Receiving system (receiving device), 20: Portable terminal (electronic device, set), 22, 22B: Jack section, 221, 221B: Jack, 222-224,228 ... Drawer part, 225 to 227, 229 ... High frequency cutoff part, 221 to 223, 23 ... Tuner, 30 ... Antenna device, 40 ... Three-pole plug, 40B ... Four-pole plug 50 ... Audio signal transmission cable, 60 ... Antenna cable, 61 ... Coaxial cable, 62, 100, 100E ... Relay unit, 621-623 ... High frequency blocking unit, 70 ... Earphone Cable, 80 ... mounting substrate, 90 ... microphone (MIC).

Claims (20)

An audio signal plug including a plurality of terminals;
Including a plurality of lines, including an audio signal transmission cable that transmits the audio signal with the audio signal plug connected to one end side,
The audio signal plug is
At least a stereo signal left channel terminal, a right channel terminal, and a ground terminal are formed to be insulated from each other along the cylindrical axis direction on the cylindrical tip.
At the rear end of the cylindrical shape, at least a stereo signal left channel terminal, a right channel terminal, and a ground terminal are formed to be insulated from each other around the cylindrical axis,
The left channel terminal at the front end and the left channel terminal at the rear end are electrically connected through the cylindrical shaft,
The right channel terminal at the front end and the right channel terminal at the rear end are electrically connected through the cylindrical shaft,
The ground terminal at the front end and the ground terminal at the rear end are electrically connected through the cylindrical shaft,
The audio signal transmission cable is
Including at least a left (L) line, a right (R) line, and a ground (G) line of audio;
Of the left (L) line, right (R) line, and ground (G) line of the audio, at least the ground (G) line is formed by a coaxial cable with a shield portion covered with a jacket,
At least the left channel terminal at the rear end of the audio signal plug and one end of the left (L) line of the audio signal transmission cable, and the right channel terminal at the rear end of the audio signal plug and the audio One end side of the right (R) line of the signal transmission cable is connected via a high frequency cutoff unit having a high frequency cutoff function,
The ground terminal at the rear end portion of the audio signal plug, the shield portion of the coaxial cable with the shield portion of the audio signal transmission cable, and one end side of the ground (G) line are connected ,
On one end side of the audio signal transmission cable and at least one end side of the other end side of the audio signal transmission cable, a relay board portion for connecting to the cylindrical rear end portion of the audio signal plug is disposed,
In the relay board part,
An accommodation area for accommodating the cylindrical rear end portion of the audio signal plug is formed, and is arranged in an area facing each terminal of the audio signal plug accommodated along the longitudinal direction of the accommodation area. A connecting terminal to be connected to the plug terminal to be formed,
At least a connection line connected to the connection terminal with each terminal of the audio signal plug, and an antenna device on which the high-frequency cutoff unit is mounted . The shielded coaxial cable of the audio signal transmission cable is
Among the left (L) line, the right (R) line, the ground (G) line, and the microphone line, at least the left (L) line, the right (R) line, and the ground (G) line The antenna device according to claim 1. The audio signal plug is
A microphone terminal is formed on a cylindrical tip portion, being insulated from other terminals along the cylindrical axis direction,
At the rear end of the cylindrical shape, a microphone terminal is formed so as to be insulated from other terminals around the cylindrical axis,
The audio signal transmission cable is
In addition to the left (L) line, the right (R) line, and the ground (G) line of audio, including a microphone line,
The microphone terminal of at least the rear end portion of the audio signal plug and one end side of the microphone line of the audio signal transmission cable are connected via a high frequency cutoff portion having a high frequency cutoff function. The antenna device described. The audio signal transmission cable is
The shielded coaxial cable includes the ground (G) line forming an antenna signal line,
The antenna device according to claim 1, wherein the left (L) line and the right (R) line are arranged in parallel with the shielded coaxial cable. The capacitor is formed between the antenna signal line to which the shield part is connected and the left (L) line and the right (R) line on one end side of the coaxial cable with the shield part. The antenna device described. The audio signal plug is
A microphone terminal is formed on a cylindrical tip portion, being insulated from other terminals along the cylindrical axis direction,
At the rear end of the cylindrical shape, a microphone terminal is formed so as to be insulated from other terminals around the cylindrical axis,
The audio signal transmission cable is
In addition to the left (L) line, the right (R) line, and the ground (G) line of audio, including a microphone line,
The left (L) line, the right (R) line, and the microphone line are arranged in parallel with the coaxial cable with the shield portion,
The microphone terminal at the rear end of the audio signal plug and one end of the microphone line of the audio signal transmission cable are connected via a high-frequency cutoff unit having a high-frequency cutoff function. Antenna device. On one end side of the coaxial cable with the shield part, a capacitance is formed between the antenna signal line to which the shield part is connected and the left (L) line, the right (R) line, and the microphone line. The antenna device according to claim 6. The audio signal transmission cable is
Including earphone cable,
The earphone cable includes at least an earphone cable left (L) signal line, an earphone cable right (R) signal line, and a microphone signal line, at least an earphone cable left (L) signal line and an earphone cable right (R). Including signal lines,
Of the left (L) line, the right (R) line, and the microphone line arranged in parallel to the shielded coaxial cable, at least the other end of the left (L) line and the right (R) line. The high frequency cutoff part which has a high frequency cutoff function is connected between the left (L) signal line for earphone cables and the right (R) signal line for earphone cables, and the antenna according to any one of claims 4 to 7. apparatus. Including a jack portion to which the audio signal plug is connected;
The jack section is
Including a plurality of drawers,
A high-frequency cutoff part having a high-frequency cutoff function is connected to at least the other lead part other than the one lead part that is connected to the audio signal plug to form the antenna signal line,
The one drawer part is
The high frequency cutoff part is connected to one branch part.
The antenna device according to any one of claims 1 to 8, wherein a capacitor is connected to the other branch portion. Including a jack portion in which the audio signal plug is accommodated and connected in the plug accommodating area;
The jack portion is mounted on a substrate, and at least the mounting surface of the jack portion of the substrate is formed as a non-conductive region without a conductive line, and the substrate around the plug housing region has at least the audio signal plug. The antenna device according to any one of claims 1 to 9, wherein a connection terminal and a connection line with each terminal are mounted. An antenna device;
The antenna device is connectable and has an electronic device having a broadcast wave receiving function,
The antenna device is
An audio signal plug including a plurality of terminals;
Including a plurality of lines, including an audio signal transmission cable that transmits the audio signal with the audio signal plug connected to one end side,
The audio signal plug is
At least a stereo signal left channel terminal, a right channel terminal, and a ground terminal are formed to be insulated from each other along the cylindrical axis direction on the cylindrical tip.
At the rear end of the cylindrical shape, at least a stereo signal left channel terminal, a right channel terminal, and a ground terminal are formed to be insulated from each other around the cylindrical axis,
The left channel terminal at the front end and the left channel terminal at the rear end are electrically connected through the cylindrical shaft,
The right channel terminal at the front end and the right channel terminal at the rear end are electrically connected through the cylindrical shaft,
The ground terminal at the front end and the ground terminal at the rear end are electrically connected through the cylindrical shaft,
The audio signal transmission cable is
Including at least a left (L) line, a right (R) line, and a ground (G) line of audio;
Of the left (L) line, right (R) line, and ground (G) line of the audio, at least the ground (G) line is formed by a coaxial cable with a shield portion covered with a jacket,
At least the left channel terminal at the rear end of the audio signal plug and one end of the left (L) line of the audio signal transmission cable, and the right channel terminal at the rear end of the audio signal plug and the audio One end side of the right (R) line of the signal transmission cable is connected via a high frequency cutoff unit having a high frequency cutoff function,
The ground terminal at the rear end portion of the audio signal plug, the shield portion of the coaxial cable with the shield portion of the audio signal transmission cable, and one end side of the ground (G) line are connected ,
On one end side of the audio signal transmission cable and at least one end side of the other end side of the audio signal transmission cable, a relay board portion for connecting to the cylindrical rear end portion of the audio signal plug is disposed,
In the relay board part,
An accommodation area for accommodating the cylindrical rear end portion of the audio signal plug is formed, and is arranged in an area facing each terminal of the audio signal plug accommodated along the longitudinal direction of the accommodation area. A connecting terminal to be connected to the plug terminal to be formed,
A receiving device on which at least a connection line connected to the connection terminal with each terminal of the audio signal plug and the high-frequency cutoff unit are mounted . The shielded coaxial cable of the audio signal transmission cable is
Among the left (L) line, the right (R) line, the ground (G) line, and the microphone line, at least the left (L) line, the right (R) line, and the ground (G) line The receiving device according to claim 11. The audio signal plug is
A microphone terminal is formed on a cylindrical tip portion, being insulated from other terminals along the cylindrical axis direction,
At the rear end of the cylindrical shape, a microphone terminal is formed so as to be insulated from other terminals around the cylindrical axis,
The audio signal transmission cable is
In addition to the left (L) line, the right (R) line, and the ground (G) line of audio, including a microphone line,
The microphone terminal of at least the rear end portion of the audio signal plug and one end side of the microphone line of the audio signal transmission cable are connected via a high frequency cutoff portion having a high frequency cutoff function. The receiving device described. The audio signal transmission cable is
The shielded coaxial cable includes the ground (G) line forming an antenna signal line,
The receiving device according to claim 11, wherein the left (L) line and the right (R) line are arranged in parallel with the shielded coaxial cable. The capacitor is formed between the antenna signal line to which the shield part is connected and the left (L) line and the right (R) line on one end side of the coaxial cable with the shield part. The receiving device described. The audio signal plug is
A microphone terminal is formed on a cylindrical tip portion, being insulated from other terminals along the cylindrical axis direction,
At the rear end of the cylindrical shape, a microphone terminal is formed so as to be insulated from other terminals around the cylindrical axis,
The audio signal transmission cable is
In addition to the left (L) line, the right (R) line, and the ground (G) line of audio, including a microphone line,
The left (L) line, the right (R) line, and the microphone line are arranged in parallel with the coaxial cable with the shield portion,
The microphone terminal of at least the rear end portion of the audio signal plug and one end side of the microphone line of the audio signal transmission cable are connected to each other through a high frequency cutoff portion having a high frequency cutoff function. Receiver device. On one end side of the coaxial cable with the shield part, a capacitance is formed between the antenna signal line to which the shield part is connected and the left (L) line, the right (R) line, and the microphone line. The receiving device according to claim 16. The audio signal transmission cable is
Including earphone cable,
The earphone cable includes at least an earphone cable left (L) signal line, an earphone cable right (R) signal line, and a microphone signal line, at least an earphone cable left (L) signal line and an earphone cable right (R). Including signal lines,
Of the left (L) line, the right (R) line, and the microphone line arranged in parallel to the shielded coaxial cable, at least the other end of the left (L) line and the right (R) line. The high frequency cutoff part which has a high frequency cutoff function is connected between the left (L) signal line for earphone cables and the right (R) signal line for earphone cables, and the reception according to any one of claims 14 to 17. apparatus. Including a jack portion to which the audio signal plug is connected;
The jack section is
Including a plurality of drawers,
A high-frequency cutoff part having a high-frequency cutoff function is connected to at least the other lead part other than the one lead part that is connected to the audio signal plug to form the antenna signal line,
The one drawer part is
The high frequency cutoff part is connected to one branch part.
The receiving device according to any one of claims 11 to 18, wherein a capacitor is connected to the other branch section. Including a jack portion in which the audio signal plug is accommodated and connected in the plug accommodating area;
The jack portion is mounted on a substrate, and at least the mounting surface of the jack portion of the substrate is formed as a non-conductive region without a conductive line, and the substrate around the plug housing region has at least the audio signal plug. The receiving device according to claim 11, wherein a connection terminal and a connection line with each terminal are mounted.

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