JP2011172122A - High frequency receiving/transmitting cable and receiving apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high frequency receiving/transmitting cable and receiving apparatus which enable influences on a reception performance to be reduced at a maximum regardless of connected equipment while maintaining portability or flexibility and further enable a transmission loss to be reduced. <P>SOLUTION: A high frequency receiving/transmitting cable includes: a high frequency transfer part 32 for receiving or transmitting a high frequency signal; a coaxial transmission cable 31 for transmitting a received signal; and a relay part 33 to which the high frequency transfer part and the coaxial transmission cable are connected and which relays a signal. The high frequency transfer part and the coaxial transmission cable are formed from a coaxial cable with a shielded part covered with a jacket, the relay part 33 is disposed in an intermediate part of the coaxial transmission cable to form a first transmission cable part 31a and a second transmission cable part 32b and in the first transmission cable part and the second transmission cable part, high frequency cutoff parts 35, 36 for cutting-off in a high frequency manner are disposed at a position separated from the relay part 33 by a predetermined distance L. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a high-frequency receiving transmission cable applicable to portable electronic devices such as portable AV devices and cellular phones, and a receiving apparatus thereof.

  With the increase in screen size and performance of portable electronic devices and the downsizing and thinning of television (TV) tuners, portable electronic devices that allow TV viewing at receiving terminals are becoming popular in the world. .

In addition, products that allow TV viewing by attaching a TV tuner module to a portable electronic device that originally does not have a TV receiving function are popular.
When receiving a TV signal, these devices prepare an external antenna separately or use a built-in antenna attached to a product.

  Currently, in portable terminals such as portable audio devices and communication terminals, an earphone cable having a remote control function for providing a relay unit and controlling the terminal from there in order to improve user convenience when viewing with the earphone. Is widely used.

In portable terminals, input / output parts are being shared as the terminals become smaller.
The earphone cable has a structure having many signal lines such as a microphone signal, a reception button, a remote control function, and an antenna function as well as the original audio.
As a result, transmission signals are becoming higher in frequency and cable diameters are increasing with the increase in the number of cables.

In recent years, an electronic device such as a communication terminal typified by a mobile phone has been increasingly equipped with a function of receiving FM radio, digital radio, or 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

  By the way, for models with an external antenna, there is no problem if it is a fixed set, but when considering the usage assuming movement, it is shunned due to portability and difficulty in mounting when viewing outdoors. I guess that.

In the case of a built-in antenna, reception performance is often not exhibited for the following reasons.
In the case of a built-in antenna, a whip antenna is generally adopted. However, in order to form an electric field using the ground GND of the set, if the size of the set to be attached is not determined, the antenna is optimal. It is difficult to design.
Further, when the set to be attached is not developed for TV viewing, the original reception performance may not be exhibited due to the influence of unnecessary radiation emitted from the terminal itself and noise flowing in the set GND.

Specifically, as shown in FIG. 1, unnecessary radiation from the set 1 may be received by the antenna 2 of the set itself, and the reception performance may not be sufficiently exhibited.
Also, as shown in FIG. 2, noise overflowing from the GND of the set 1A having the signal processing unit 3 wraps around and is received by the antenna 2A of the set itself.

As described above, the built-in antenna deteriorates in both gain and reception sensitivity unless the set side is designed optimally.
Also, it is not practical to carry the external antenna separately from the trouble of installation.
There is a demand for an antenna that can reduce the influence on reception performance to the maximum, regardless of the set, while maintaining portability.

Moreover, as shown in FIG. 3, the earphone cable 4 currently proposed forms an antenna with the L cable 4L and the R cable 4R.
The cables 4L and 4R are connected to the coaxial line and one end of the audio signal line 6 through the balun 5, and the other end of the coaxial line and the audio signal line 6 can be viewed on the TV by the jack 7 (electronic device) 1B. Connected to.

However, since the earphone cable 4 forms an antenna by the L cable 4L and the R cable 4R, the antenna characteristic is better when the angle formed by the cables 4L and 4R is larger.
Therefore, it is necessary to fix the angle of the existing earphone cable in order to improve the reception performance, and there is a possibility that the flexibility of the earphone cable and the convenience of carrying are impaired.
In addition, since the high-frequency signal line and the coaxial line are shared, there is a disadvantage that transmission loss of the high-frequency signal is large.

  The present invention is a high-frequency reception transmission cable capable of reducing the influence on reception performance as much as possible regardless of connected devices while maintaining portability and flexibility and reducing transmission loss. And providing a receiving apparatus.

  A high-frequency reception transmission cable according to a first aspect of the present invention includes a high-frequency transmission unit for receiving or transmitting a high-frequency signal, a coaxial transmission cable for transmitting the received signal, the high-frequency transmission unit, and the coaxial transmission. A high-frequency transmission part and the coaxial transmission cable are formed by a coaxial cable with a shield part covered with a jacket, and the coaxial transmission cable is The relay unit is disposed in an intermediate portion so as to form a first transmission cable unit and a second transmission cable unit, and at least one of the first transmission cable unit and the second transmission cable unit is provided with a predetermined distance from the relay unit. A high-frequency cutoff unit that cuts off at a high frequency is disposed at a position of a distance.

  A receiving apparatus according to a second aspect of the present invention includes a high-frequency receiving transmission cable and an electronic device to which the high-frequency receiving transmission cable can be connected and having a broadcast wave receiving function. A high-frequency transmission unit for receiving or transmitting a high-frequency signal, a coaxial transmission cable for transmitting the received signal, the high-frequency transmission unit and the coaxial transmission cable are connected, and a relay unit that relays the signal; The high-frequency transmission part and the coaxial transmission cable are formed by a coaxial cable with a shield part covered with a jacket, and the coaxial transmission cable forms a first transmission cable part and a second transmission cable part. The relay portion is disposed in the middle portion, and at least one of the first transmission cable portion and the second transmission cable portion includes the relay portion. High-frequency cutoff unit for cutting off high frequency manner is arranged at the position of Luo predetermined distance.

  According to the present invention, while maintaining portability and flexibility, it is possible to reduce the influence on reception performance to the maximum regardless of connected devices, and to reduce transmission loss.

It is a figure for demonstrating the problem of unnecessary radiation. It is a figure for demonstrating the problem of the wraparound of the noise from set GND. It is a figure for demonstrating the subject of the existing earphone cable. 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 high frequency receiving transmission cable which forms the antenna cable which concerns on embodiment of this invention. It is a figure which shows the structural example of the coaxial cable with a shield part. It is a figure which shows the specific structure of the relay part which concerns on this embodiment, and the connection example of a coaxial transmission cable and a coaxial cable. It is a figure for demonstrating the principle as an antenna of the high frequency receiving transmission cable which concerns on this embodiment. The figure which shows the amount which the antenna takes in the radiation of a set by measuring the power of the antenna connected to the set with the power supply of the set in the anechoic chamber of the receiving apparatus of this embodiment and the comparative example. is there. In the receiver of this embodiment and a comparative example, it is a figure which shows the data which actually attached the antenna to the set and measured the minimum receiving sensitivity. It is a figure which shows the peak gain characteristic with respect to the frequency of the receiver at the time of using the high frequency receiving transmission cable which concerns on this embodiment for an actual machine. It is a figure which shows the specific structure of the relay part of the 1st application example which concerns on this embodiment, and the connection example of a coaxial transmission cable and a coaxial cable. It is a figure which shows the specific structure of the relay part of the 2nd application example which concerns on this embodiment, and the example of a connection of a coaxial transmission cable and a coaxial cable. It is a figure for demonstrating the effect of this embodiment as contrast with FIG. It is a figure which shows the example which comprised the high frequency receiving transmission cable of this embodiment integrally with the strap.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The description will be given in the following order.
1. 1. Configuration example of receiving system (receiving device) 1. First configuration example of high-frequency reception transmission cable 3. Configuration example of relay unit 4. Configuration example of connection part with earphone cable 5. Configuration example of high-frequency cutoff unit 6. Noise suppression effect First application example 8. Second application example

<1. Configuration Example of Receiving System (Receiving Device)>
FIG. 4 is a diagram illustrating a reception system (reception apparatus) including a mobile terminal that is an example of an electronic apparatus (set apparatus) including a high-frequency reception transmission cable that forms an antenna cable according to an embodiment of the present invention.

  The reception system 10 includes a mobile terminal 20, a high frequency reception transmission cable 30, and an earphone cable 40 as main components.

The portable terminal 20 includes a television receiver, for example, and includes a display unit 21 such as an audio system circuit, a display system circuit, and a liquid crystal display device, and an operation unit 22 that performs key input and the like.
The portable terminal 20 includes an RF plug 23 to which a high-frequency receiving transmission cable 30 that forms an antenna cable for receiving a high-frequency signal is connected, an audio plug, and a round jack portion 24.

  The high-frequency receiving and transmitting cable 30 of the present embodiment can receive and transmit radio signals in the VHF band to UHF band used for receiving, for example, FM bands transmitted from broadcast stations and digital television broadcasts. It is.

The high-frequency reception transmission cable 30 includes a coaxial transmission cable 31, a high-frequency transmission unit 32, a relay unit 33, an audio plug 34, a connection unit 35 with the earphone cable 40, and a high-frequency blocking unit 36 using an inductor or a ferrite core.
In addition, the connection part 35 can be comprised including a high frequency interruption | blocking part.

In the high-frequency cutoff unit 32 and the connection unit 35, an inductor or the like that exhibits a high-frequency cutoff function is disposed at a predetermined distance L from the relay unit 33.
The position at a predetermined distance L from the relay unit 33 is set to a point (position) that is a constant multiple n of the electrical length ¼λ (λ is the wavelength) of the use band. However, n is a positive integer.
The relay unit 33 is connected to the coaxial transmission cable 31 and the high-frequency transmission unit 32. The structure will be described in detail later.

  In this embodiment, the coaxial transmission cable 31 and the high-frequency transmission part 32 are formed by a coaxial cable with a shield part covered with, for example, a jacket.

The coaxial transmission cable 31 functions as an antenna cable, and a relay portion 33 is disposed at an intermediate portion so as to form a first transmission cable portion 31a and a second transmission cable portion 31b.
The one end side of the 1st transmission cable part 31a and the one end side of the 2nd transmission cable part 31b are formed so that it may exist in the board-like relay part 33, for example.
A connection part 35 including a high-frequency cutoff part is formed at a position on the other end side of the distance L from the relay part 33 of the first transmission cable part 31a.
A high frequency cutoff unit 32 is formed at a distance L from the relay unit 33 of the second transmission cable unit 31b.
The other end side of the second transmission cable portion 31b from the position where the high frequency cutoff portion 32 is formed is formed as a third transmission cable portion 31c, and an audio plug 34 is connected to the end of the third transmission cable 31c. Yes.

In the present embodiment, as will be described in detail later, the high-frequency transmission unit 32 is formed in the relay unit 33 by a coaxial cable 37 for high-frequency signal transmission having a coaxial structure.
The coaxial cable 37 has one end connected to the relay unit 33 and the other end connected to the RF plug 23.

<2. Configuration example of a high-frequency receiving transmission cable>
[Configuration of coaxial cable with shield]

  FIG. 5 is a diagram illustrating a structural example of a coaxial cable with a shield portion.

The shielded coaxial cable of FIG. 5 is formed by a three-core coaxial cable 310, and insulates a plurality of core wires 311, 312, 313 and core wires 311, 312, 313 that form an audio L line and an R line. An internal insulator 314 is included.
The coaxial cable 310 has a shield part 315 as an outer conductor disposed on the outer periphery of the insulator 314 and an outer insulator (outer skin, jacket) 316 such as an elastomer covering the entire outer periphery.
The core wires 311, 312, 313 are formed of, for example, an aramid fiber-containing polyurethane wire.
The insulator 314 is formed by, for example, X-ray irradiation crosslinked PE.
Moreover, the shield part 315 is formed, for example with an annealed copper wire.
Shield portion 315 is formed of 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 311, 312, 313 and the shield part 315 have impedance at high frequencies.

The first transmission cable part 31a, the second transmission cable part 31b, and the third transmission cable part 31c forming the coaxial transmission cable 31 have the structure shown in FIG.
The coaxial cable 37 forming the high-frequency transmission unit 32 has the same configuration as the structure of FIG. However, the number of core wires may be one.

<3. Example of relay unit configuration>
Next, a configuration example of the relay unit 33 will be described.
FIG. 6 is a diagram illustrating a specific configuration of the relay unit according to the present embodiment, and a connection example of the coaxial transmission cable and the coaxial cable.

The relay portion 33 is formed by, for example, a substrate or molding.
In the relay portion 33, the coaxial transmission cable 31 is separated into a first transmission cable portion 31a on the connection portion 35 side with the earphone cable 40 and a second transmission cable portion 31b on the audio plug side, and the core wire 311 is separated by the separation portion SPRT1. 312 and 313 are exposed.
That is, in the relay portion 33, the coaxial transmission cable 31 is separated by removing the insulator 314, the shield portion 315, and the jacket 316.
In addition, the jackets 316a and 316b are removed in the vicinity of the separation part SPRT1, and the shield parts 315a and 315b are exposed.

In the separation part SPRT1, the core wire 311a of the first transmission cable part 31a on the connection part 35 side and the core wire 311b of the second transmission cable part 31b on the audio plug side are connected via an inductor L1 for high frequency cutoff.
The core wire 312a of the first transmission cable portion 31a on the connection portion 35 side and the core wire 312b of the second transmission cable portion 31b on the audio plug side are connected via an inductor L2 for high frequency cutoff.
The core wire 313a of the first transmission cable portion 31a on the connection portion 35 side and the core wire 313b of the second transmission cable portion 31b on the audio plug side are connected via an inductor L3 for high frequency cutoff.

A balance-unbalance converter (balun) 330 is arranged in the vicinity of the separation unit SPRT1.
The coaxial cable 37 is disposed so that one end side of the coaxial cable 37 is substantially orthogonal to the coaxial transmission cable 31 with the balun 330 interposed therebetween.
The coaxial cable 37 has a core wire 311 d exposed at one end near the balun 330.
Further, in the vicinity of the exposed portion of the core wire 311d, the jacket 316d is removed and the shield portion 315d is exposed.
The core wire 311 d of the coaxial cable 37 is connected to the shield part 315 a of the first transmission cable part 31 a on the connection part 35 side through one terminal 331 of the balun 330.
The shield part 315 d of the coaxial cable 37 is connected to the shield part 315 b of the second transmission cable part 31 b on the audio plug side via the other terminal 332 of the balun 330.
By arranging the balun 330 in the relay unit 33, it is possible to block noise that circulates from the electronic device (set) 20 while transmitting a high-frequency signal.

The coaxial cable 37 has a core wire 311d exposed at the other end.
Further, in the vicinity of the exposed portion of the core wire 311d, the jacket 316d is removed and the shield portion 315d is exposed.
The other end side core wire 311 d is connected to the tuner 25 in a state where it is connected to the RF plug 23 of the mobile terminal 20.
The other end side shield part 315d is connected to the set ground GND in a state where it is connected to the RF plug 23 of the mobile terminal 20.
Thereby, noise can be sent to the set side.

  The relay part 33 having the above configuration forms a dipole antenna.

<4. Configuration Example of Connection Portion 35 with Earphone Cable 40>
Next, a configuration example of the connection unit 35 will be described.
In the connection portion 35, the other end side of the first transmission cable portion 31a is separated by removing the insulator 314, the shield portion 315, and the jacket 316.
Further, the shield 315a is exposed by removing the jacket 316a on the other end side of the first transmission cable portion 31A.

One end of a high frequency cutoff inductor L11 is connected to the core wire 311a of the first transmission cable portion 31a of the connecting portion 35.
One end of a high frequency cutoff inductor L12 is connected to the core wire 312a of the first transmission cable portion 31a on the connection portion 35 side.
One end of the high frequency cutoff inductor L13 is connected to the core wire 313a of the first transmission cable portion 31a on the connection portion 35 side.
In the connection part 35, each terminal of the audio jack 352 is connected to the other end side of the inductors L11, L12, L13 forming the high-frequency cutoff part 351.

<5. Configuration Example of High Frequency Blocking Section 36>
Next, a configuration example of the high-frequency cutoff unit 36 will be described.
In the high-frequency cutoff unit 36, the coaxial transmission cable 31 is separated into a second transmission cable unit 31b on the relay unit 33 side and a second transmission cable unit 31c on the audio plug side, and the cores 311, 312 and 313 are separated by the separation unit SPRT2. Exposed.
That is, in the high-frequency cutoff unit 36, the coaxial transmission cable 31 is separated by removing the insulator 314, the shield unit 315, and the jacket 316.
Further, the jackets 316b and 316c are removed in the vicinity of the separation part SPRT2, and the shield parts 315b and 315c are exposed.

In the separation unit SPRT2, the core wire 311b of the second transmission cable unit 31b on the relay unit 33 side and the core wire 311c of the third transmission cable unit 31c on the audio plug side are connected via an inductor L21 for high-frequency cutoff.
The core wire 312b of the second transmission cable portion 31b on the relay portion 33 side and the core wire 312c of the third transmission cable portion 31c on the audio plug side are connected via a high frequency cutoff inductor L22.
The core wire 313b of the second transmission cable portion 31b on the relay portion 33 side and the core wire 313c of the third transmission cable portion 31c on the audio plug side are connected via an inductor L23 for high frequency cutoff.

In the third transmission cable portion 31c, the core wires 311c, 312c, and 313c are exposed at the other end portion.
In addition, the shield 315d is exposed by removing the jacket 316d in the vicinity of the exposed portions of the core wires 311c, 312c, and 313c.
The other end side core wires 311c, 312c, and 313c are connected to the audio circuit 26 in a state of being connected to the audio plug 34 of the portable terminal (set) 20.
The other end side shield part 315c is connected to the set ground GND while being connected to the audio plug 34 of the portable terminal 20.
Thereby, noise can be sent to the set side.

As described above, in the present embodiment, the relay unit 33 is provided with the inductors L1, L2, and L3 as a high-frequency cutoff unit, and allows low frequencies such as voice to pass therethrough and compare with a radio or TV. At high frequencies, it behaves like blocking.
The first transmission cable portion 31a and the second transmission cable portion 31b each have a length that is a constant multiple of λ / 4 of the band used as an antenna.
The first transmission cable portion 31 a and the second transmission cable portion 31 b are separated in high frequency by inductors L 1, L 2, and L 3 as high frequency cutoff portions, and each is connected to the balun 330.
The third transmission cable portion 31c also has a coaxial structure, and the shield portion 315c is connected to the set ground GND so as to prevent unwanted radiation and noise from the set 20 from jumping into the signal line.

Next, the principle of the high frequency reception transmission cable 30 according to this embodiment as an antenna will be described.
FIG. 7 is a diagram for explaining the principle as an antenna of the high-frequency receiving transmission cable 30 according to the present embodiment.

In this embodiment, the transmission cable has a coaxial structure, and shield portions 315a, 315b, and 315d, which are outer conductors, are used as elements.
The length is supplied to the element via the balun 330, with one side, that is, the length of the first transmission cable portion 31a and the second transmission cable portion 31b being a constant multiple of λ / 4 of the band used as an antenna. Thus, a dipole antenna is configured.
Further, the balun 330 reduces the influence of noise that circulates from the set ground GND.
Due to the inductors L11, L12, and L13 serving as the high-frequency cutoff portions of the connection portion 35 and the inductors L21, L22, and L23 of the high-frequency cutoff portion 36, the impedance is high and no current flows at high frequencies.

<6. Noise suppression effect>
Next, the noise suppression effect of the receiving apparatus 10 according to the present embodiment will be considered in association with FIG. 8 and FIG.

FIG. 8 shows the amount that the antenna captures the radiation of the set by measuring the power of the antenna connected to the set while the set is turned on in the anechoic chamber of the receiving apparatus of this embodiment and the comparative example. Is shown.
8A shows the noise waveform of the comparative example, FIG. 8B shows the noise waveform of this embodiment (this case), and FIG. 8C shows the measurement result as a table.
8A and 8B, the vertical axis indicates power and the horizontal axis indicates frequency.
In addition, as a comparative example, the rod antenna data and the data of this case are shown together.
According to FIG. 8, it turns out that this case is not receiving the noise from a set compared with a comparative example.

FIGS. 9A and 9B are diagrams showing data obtained by measuring the minimum reception sensitivity by actually attaching the antenna to the set in the receiving apparatus of the present embodiment and the comparative example.
In FIG. 9A, the vertical axis indicates the minimum reception sensitivity, and the horizontal axis indicates the physical channel of the television. In FIG. 9A, the curve indicated by X indicates the characteristic of the comparative example, and the curve indicated by Y indicates the characteristic of the present case.
FIG. 9B shows the measurement results as a table.
According to FIG. 9, it is confirmed that the present case is able to receive even at lower power than the comparative example.

10A to 10D are diagrams showing peak gain characteristics with respect to the frequency of the receiving apparatus when the high-frequency receiving transmission cable according to the present embodiment is used in an actual machine.
FIG. 10 shows characteristics in the UHF band.
As shown in FIG. 10A, an example in which the high-frequency receiving transmission cable 30 according to the present embodiment is applied to an actual machine (set) 25A is schematically shown.
In FIG. 10B, the curve indicated by H indicates the characteristic of horizontal polarization, and the curve indicated by V indicates the characteristic of vertical polarization.
10 (C) and 10 (D) show charts showing the measurement results in detail in accordance with the characteristic diagrams.

  As can be seen from the figure, the vertical polarization V can be received without any problem since the cross polarization ratio is smaller than that of a normal dipole antenna.

<7. First application example>
Next, a first application example of the present embodiment will be described.
FIG. 11 is a diagram illustrating a specific configuration of the relay unit of the first application example according to the present embodiment, and a connection example of the coaxial transmission cable and the coaxial cable.

The first application example is different from the configuration of FIG. 6 in that the audio plug 34A has three standard poles and the cost is reduced.
In this case, at the other end of the third transmission cable portion 31c, the shield portion 315c is connected to the core wire 312c and connected to the set ground GND.

  In the first application example, the same effect as described above can be obtained.

<8. Second application example>
Next, a second application example of the present embodiment will be described.
FIG. 12 is a diagram illustrating a specific configuration of the relay unit of the second application example according to the present embodiment, and a connection example of the coaxial transmission cable and the coaxial cable.

The second application example is different from the configuration of FIG. 6 in that the cost is reduced by removing the inductor as the high-frequency cutoff unit in the connection unit 35.
In this case, the core wires 311a, 312a, and 313a of the first transmission cable portion 31a are directly connected to the respective terminals of the audio jack 352 in the connection portion 35A.

  In the second application example, the same effect as described above can be obtained.

As described above, according to this embodiment, the high-frequency reception transmission cable 30 includes the coaxial transmission cable 31, the high-frequency transmission unit 32, the relay unit 33, the audio plug 34, the connection unit 35, and the high-frequency cutoff unit using an inductor or a ferrite core. 36 is comprised.
In the high-frequency cutoff unit 32 and the connection unit 35, an inductor or the like that exhibits a high-frequency cutoff function is disposed at a predetermined distance L from the relay unit 33.
The position at a predetermined distance L from the relay unit 33 is set to a point (position) that is a constant multiple n of the electrical length ¼λ (λ is the wavelength) of the use band.
In this embodiment, the coaxial transmission cable 31 and the high-frequency transmission part 32 are formed by a coaxial cable with a shield part covered with, for example, a jacket.
The coaxial transmission cable 31 functions as an antenna cable, and a relay portion 33 is disposed at an intermediate portion so as to form a first transmission cable portion 31a and a second transmission cable portion 31b.
The one end side of the 1st transmission cable part 31a and the one end side of the 2nd transmission cable part 31b are formed so that it may exist in the board-like relay part 33, for example.
A connection part 35 including a high-frequency cutoff part is formed at a position on the other end side of the distance L from the relay part 33 of the first transmission cable part 31a.
A high frequency cutoff unit 32 is formed at a distance L from the relay unit 33 of the second transmission cable unit 31b.
The other end of the second transmission cable portion 31b from the position where the high-frequency cutoff portion 32 is formed is formed as a third transmission cable portion 31c, and an audio plug is connected to the end of the third transmission cable 31c. .
In this embodiment, the high frequency transmission part 32 is formed in the relay part 33 by the coaxial cable 37 for high frequency signal transmission which takes a coaxial structure. The coaxial cable 37 has one end connected to the relay unit 33 and the other end connected to the RF plug 23.
Therefore, according to the present embodiment, the following effects can be obtained.

Therefore, according to the present embodiment, while maintaining large portability and flexibility, it is possible to reduce the influence on reception performance as much as possible regardless of connected devices, and to reduce transmission loss. it can.
As a result, the performance of the earphone cable can be improved, and the earphone cable can be reduced in size and productivity.
In addition, the high frequency transmission part 32 can also be formed as a high frequency signal distribution point.
Further, the coaxial transmission cable 31 functions as an antenna cable, and the high-frequency transmission unit 32 can be formed as a connection point with the antenna cable.

  FIG. 13 is a diagram for explaining the effect of this embodiment as a comparison with FIG.

In the comparative example shown in FIG. 3, since the earphone cable 4 forms an antenna by the L cable 4L and the R cable 4R, the antenna characteristic is better when the angle formed by the cables 4L and 4R is larger.
Therefore, it is necessary to fix the angle of the existing earphone cable in order to improve the reception performance, and there is a possibility that the flexibility of the earphone cable and the convenience of carrying are impaired.
In addition, since the high-frequency signal line and the coaxial line are shared, there is a disadvantage that transmission loss of the high-frequency signal is large.

On the other hand, the high-frequency reception transmission cable 30 of the present embodiment is different from the comparative example in the portion that functions as an antenna, and the antenna performance is improved even if the angle is not specified.
In addition, the high-frequency reception transmission cable 30 does not have a shared portion of the high-frequency signal line and the coaxial transmission line, and can greatly reduce high-frequency loss.

The high-frequency receiving and transmitting cable 30 of the present embodiment has excellent flexibility and portability because the antenna performance is improved without specifying the angle.
Therefore, for example, as shown in FIG. 14, the strap 50 can be integrally attached.
The strap 50 has detachable portions 52 and 53 formed in the middle of the strap string 51, and can be disconnected or connected in the middle.
In the example of FIG. 14, the connecting portion 35 is configured to be integrally attached to the strap string 51. A strap holding string 54 is attached to the relay portion 33. This part is formed to be detachable from the relay part 33.

In the high-frequency receiving transmission cable, the transmission cable may be configured by a parallel two line instead of the coaxial structure at the portion where the transmission cable is connected to the relay unit.
Further, the high-frequency cutoff portion can be formed by winding a cable portion around a magnetic material.
The high-frequency reception transmission cable can also be configured as an antenna cable device for transmitting power by connecting to a power supply circuit of a set terminal and a power output device such as a DC converter or a power transmission connector such as a cigar plug. is there.

  DESCRIPTION OF SYMBOLS 10 ... Reception system (reception apparatus), 20 ... Portable terminal (electronic device, set), 23 ... RF plug, 25 ... Tuner, 26 ... Audio circuit, 30 ... High frequency reception Transmission cable, 31 ... Coaxial transmission cable, 31a ... First transmission cable part, 31b ... Second transmission cable part, 31c ... Third transmission cable part, 32 ... High frequency transmission part, 33 ... Relay unit, 330 ... Balun, 34 ... Audio plug, 35 ... Connection unit, 36 ... High frequency cutoff unit, 40 ... Earphone cable.

Claims (19)

A high-frequency transmission unit for receiving or transmitting a high-frequency signal;
A coaxial transmission cable for transmitting the received signal;
The high-frequency transmission unit and the coaxial transmission cable are connected, and have a relay unit that relays signals,
The high-frequency transmission unit and the coaxial transmission cable are
Formed by a coaxial cable with a shield part covered by a jacket,
The coaxial transmission cable is
The relay unit is arranged in the middle so as to form the first transmission cable unit and the second transmission cable unit,
A high-frequency receiving transmission cable, wherein at least one of the first transmission cable portion and the second transmission cable portion is provided with a high-frequency cutoff portion that cuts off at a predetermined distance from the relay portion. The high-frequency receiving and transmitting cable according to claim 1, wherein the position of the predetermined distance from the relay unit at which the high-frequency cutoff unit is disposed is a point that is a constant multiple of the electrical length 1 / 4λ (λ is the wavelength) of the use band. The coaxial transmission cable is
A core cable and a shield part are formed by a coaxial cable formed concentrically,
The coaxial transmission cable is
The high-frequency receiving transmission cable according to claim 1 or 2, wherein a high-frequency cutoff unit is inserted between core wires of the first transmission cable unit and the second transmission cable unit in the relay unit. The high frequency transmission part is
A core cable and a shield part are formed by a coaxial cable formed concentrically,
The coaxial cable forming the high-frequency transmission unit is
On one end side, a core wire is connected to the shield part of the first transmission cable part on one side of the high-frequency cutoff part of the coaxial transmission cable,
The high-frequency receiving transmission cable according to claim 3, wherein a shield part is connected to the shield part of the second transmission cable part on the other side of the high-frequency cutoff part of the coaxial transmission cable. The relay section
Including a balun
The core wire of the coaxial cable forming the high-frequency transmission portion and the shield portion of the first transmission cable portion on one side of the high-frequency cutoff portion of the coaxial transmission cable are connected via one terminal of the balanced / unbalanced converter. ,
The shield part of the coaxial cable forming the high-frequency transmission part and the shield part of the second transmission cable part on the other side of the high-frequency cutoff part of the coaxial transmission cable are connected via the other terminal of the balance-unbalance converter. The high-frequency receiving transmission cable according to claim 4. The second transmission cable portion of the coaxial transmission cable is
The high-frequency receiving transmission cable according to any one of claims 3 to 5, wherein the high-frequency cutoff unit is inserted into the core wire at a predetermined distance from the relay unit. The first transmission cable portion of the coaxial transmission cable is
The high frequency reception transmission cable according to any one of claims 1 to 6, wherein an audio jack is connected in a position region at a predetermined distance from the relay unit. The high-frequency reception transmission cable according to any one of claims 1 to 7, wherein the high-frequency transmission unit is a high-frequency signal distribution point. The coaxial transmission cable functions as an antenna cable,
The high-frequency reception transmission cable according to any one of claims 1 to 8, wherein the high-frequency transmission unit is a connection point with the antenna cable. A high-frequency receiving transmission cable;
The high frequency receiving transmission cable is connectable, and has an electronic device having a broadcast wave receiving function,
The high frequency receiving transmission cable is
A high-frequency transmission unit for receiving or transmitting a high-frequency signal;
A coaxial transmission cable for transmitting the received signal;
The high-frequency transmission unit and the coaxial transmission cable are connected, and includes a relay unit that relays signals,
The high-frequency transmission unit and the coaxial transmission cable are
Formed by a coaxial cable with a shield part covered by a jacket,
The coaxial transmission cable is
The relay unit is arranged in the middle so as to form the first transmission cable unit and the second transmission cable unit,
A receiving device in which at least one of the first transmission cable unit and the second transmission cable unit is provided with a high-frequency cutoff unit that cuts off at a predetermined distance from the relay unit at a high frequency. The receiving apparatus according to claim 10, wherein the position of the predetermined distance from the relay unit at which the high-frequency cutoff unit is disposed is a point that is a constant multiple of the electrical length 1 / 4λ (λ is the wavelength) of the used band. The coaxial transmission cable is
A core cable and a shield part are formed by a coaxial cable formed concentrically,
The coaxial transmission cable is
The receiving device according to claim 10 or 11, wherein a high-frequency cutoff unit is inserted between core wires of the first transmission cable unit and the second transmission cable unit in the relay unit. The high frequency transmission part is
A core cable and a shield part are formed by a coaxial cable formed concentrically,
The coaxial cable forming the high-frequency transmission unit is
On one end side, a core wire is connected to the shield part of the first transmission cable part on one side of the high-frequency cutoff part of the coaxial transmission cable,
A shield part is connected to the shield part of the second transmission cable part on the other side of the high-frequency cutoff part of the coaxial transmission cable;
The receiving device according to claim 12, wherein the other end side is connectable to a tuner of the electronic device. The relay section
Including a balun
The core wire of the coaxial cable forming the high-frequency transmission portion and the shield portion of the first transmission cable portion on one side of the high-frequency cutoff portion of the coaxial transmission cable are connected via one terminal of the balanced / unbalanced converter. ,
The shield part of the coaxial cable forming the high-frequency transmission part and the shield part of the second transmission cable part on the other side of the high-frequency cutoff part of the coaxial transmission cable are connected via the other terminal of the balance-unbalance converter. The receiving device according to claim 13. The second transmission cable portion of the coaxial transmission cable is
The receiving device according to any one of claims 12 to 14, wherein the high-frequency cutoff unit is inserted into the core wire at a predetermined distance from the relay unit. In the coaxial transmission cable,
The first transmission cable portion is connected to an audio jack in a position area at a predetermined distance from the relay portion,
The receiving device according to any one of claims 12 to 15, wherein the second transmission cable unit is connectable to an audio terminal of the electronic device at an end opposite to a connection end with the relay unit. The second transmission cable portion is
The receiving device according to claim 16, wherein the shield portion is connected to the core wire and connected to the ground of the electronic device at an end opposite to the connection end with the relay portion. The receiving apparatus according to claim 10, wherein the high-frequency transmission unit is a high-frequency signal distribution point. The coaxial transmission cable functions as an antenna cable,
The receiving device according to claim 10, wherein the high-frequency transmission unit is a connection point with the antenna cable.

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