JP2006287721A - Earphone microphone - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an earphone microphone which successfully functions a part or the whole of a cord as an antenna line for receiving airwaves of a television or a radio, etc. and is attached by a user to whom it is attached without a sense of incongruity. <P>SOLUTION: The earphone microphone has a relay part 5 on which a microphone circuit is loaded in the middle of the cord for connecting a connector part 6 to a speaker part 7 and is connected to equipment 4 having an acoustic signal input/output function via the connector part 6. The cord is formed by attachably/detachably connecting a relay cord 2 having the connector part 6 on one edge and the relay part 5 having a jack part 5A on the other edge to an earphone 3 having a plug part 5B to be engaged into the jack part 5A on one edge and the speaker part 7 on the other edge, receives the airwaves using the relay cord 2 as an antenna and inputs the airwaves in the equipment 4 via the connector part 6. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention includes a speaker and a microphone, is connected to a device having an acoustic signal input / output function, emits sound from the speaker based on the sound output signal of the device, and also collects sound collected by the microphone. The present invention relates to an earphone microphone that inputs an acoustic input signal to the device based on the antenna function and has an antenna function in which a function of receiving broadcast radio waves is added to the cord.

  In general, earphones and headphones are connected to communication devices such as telephones and radios, audio devices, etc., for example, in places where sound cannot be emitted to the outside or in environments such as noise, It is used for listening to audio signals such as music. In some cases, a portable audio device is worn to listen to music while moving. If these devices have a function such as a television or radio, an antenna for receiving a broadcast radio signal is required. In some cases, this antenna is provided in a device. However, particularly in a mobile phone or a portable audio device, there are problems such as a reduction in the size of the device due to this antenna and a failure to obtain a required sensitivity.

  Therefore, it is preferable to provide an antenna where the radio wave is easily received by extending to the outside of the device. For example, Patent Document 1 shown below discloses a technology of a headphone with a built-in antenna in which an antenna is provided on the headphone. This built-in antenna headphone incorporates multiple antennas with different lengths used for receiving radio signals (radio signals) in the band that connects the left and right acoustic units to stabilize radio waves in a wide range of frequencies. It can be received.

  Further, Patent Document 2 shown below shows an apparatus that receives FM radio waves using a headphone cord as an antenna. According to this, the length between the remote control operation unit located between the plug of the headphone cord and the headphone and the cord portion between the plug is about 1/4 wavelength of the FM frequency to be received. The remote control unit is provided with a high frequency choke coil that separates the cord portion between the remote control unit and the plug from the headphone (acoustic unit) side in a high frequency manner. In this manner, the cord portion from the remote control operation unit to the plug appropriately acts as an FM broadcast receiving antenna.

JP 2003-274477 A (2nd to 12th paragraphs, FIG. 1) JP-A-9-331209 (9th to 15th paragraphs, FIG. 1)

  As an external device to which the headphone with a built-in antenna shown in Patent Document 1 is connected, a portable AV (audio / visual) device or the like can be considered. In recent years, not only a telephone function but also various functions such as a digital camera function, an Internet connection function, a TV and radio tuner function have been added to a mobile phone that is more portable than a portable AV device. Mobile phones are often carried even when they do not have a bag, etc. In such cases, the earphone type that can be easily bundled is more suitable than the headphone type that has poor storage properties. Excellent portability. In addition, an earphone used for a mobile phone needs to have a function of collecting transmitted voice, not just listening to received voice, in order to use it for a call. An earphone having a telephone call function has already been put into practical use as an earphone microphone device that is connected to a mobile phone, outputs received voice from the earphone, and inputs transmitted voice from the microphone.

  Usually, a mobile phone is equipped with an antenna for a call. However, since the frequency of a broadcast radio wave of a television or radio and the carrier wave frequency of the mobile phone are greatly different, the antenna for a call provided on the mobile phone is used. It is not preferable to use it as a receiving antenna for TV or radio broadcast waves. In addition, it is not preferable to reduce the size of the apparatus by providing an antenna different from the antenna for calling. Therefore, when used as a telephone, it is preferable that an earphone microphone functioning as a receiver for a call is provided with an antenna function. The earphone microphone with an antenna function is required to receive a radio signal in a wide frequency band with high sensitivity and to add an antenna function at a low cost.

  The techniques described in Patent Documents 1 and 2 are excellent methods for causing the integrated headphones and earphones to function well as antennas. And by adding a microphone function to this, it is also possible to obtain an earphone microphone with an antenna function. However, particularly in the case of the inner ear type (the type in which the earphone is inserted into the ear), the earphone often does not fit the user's ear. Even in that case, if the function as an antenna is required, the user must endure and continue to use it. And it means that the earphone has been worn for a certain period of time, and it is not preferable that the earphone can not be put up and removed in a short time or cannot be worn for a long time.

  The present invention has been made in view of such problems, and makes part or all of the cords function well as an antenna wire for receiving broadcast radio waves from a television, radio, etc., and can be worn comfortably by the wearing user. An object is to provide a possible earphone microphone.

In order to achieve this object, the characteristic configuration of the earphone antenna according to the present invention is as follows:
A connector part is provided at one end, a speaker part is provided at the other end, and a relay part with a microphone circuit mounted in the middle of the cord connecting the both ends is provided. The cord is connected to a device having a function, and the cord includes the connector portion at one end and the relay cord including the relay portion having a jack portion at the other end, A plug part that fits into the jack part at one end and an earphone that is provided with the speaker part at the other end, and is detachably connected, and receives broadcast radio waves using the relay cord as an antenna. The broadcast radio wave is input to the device.

According to this characteristic configuration, the broadcast cord is received by using the relay cord as an antenna. Therefore, it is possible to provide a stable antenna that can exhibit a certain reception performance regardless of the type of the earphone provided with the speaker. For example, when it is desired to increase the reception sensitivity around a specific frequency, the length of the relay code may be set to a length that improves the sensitivity with respect to the specific frequency. In this way, it is possible to always maintain good reception sensitivity for a specific frequency regardless of the earphone.
Further, even when the inner earphone does not fit the ear of the user wearing the earphone, it can be easily replaced. Since the connection with the device is carried out by the relay cord, the earphone can be freely replaced with a type that does not have an antenna function. As a result, it is possible to provide an earphone microphone that can be worn without a sense of incongruity by the user who wears it.

  The relay cord includes an acoustic output signal line for transmitting the acoustic output signal from the device, an acoustic input signal line for transmitting an acoustic input signal from the relay unit to the device, and the device from the relay unit. A control signal line for transmitting a control signal to be controlled, and the acoustic output signal line preferably functions as the antenna.

  A device to which the earphone microphone with an antenna function of the present invention is connected is provided with a feeding branch circuit that separates received broadcast radio waves. In addition to the earphone microphone according to the present invention, an earphone antenna or the like that does not have a microphone function can be connected to this device in terms of versatility. Therefore, it is efficient that the signal line of the simplest earphone is made to function as an antenna and a power supply branch circuit corresponding to this is provided in the device. Therefore, when the relay cord has the acoustic output signal line, the acoustic input signal line, and the control signal line as described above, it is preferable that the acoustic output signal line functions as an antenna.

  Further, the acoustic input signal line and the control signal line have an inductor in series with each signal line in the relay section and the connector section, and the acoustic output signal line has an inductor in series in the relay section. It is suitable to have.

  The broadcast radio wave has a higher frequency (approximately several tens of megahertz (MHz)) than the frequency of the acoustic signal (approximately 0 to 20 k (kilo) Hz). When the relay cord has an acoustic output signal line, an acoustic input signal line, and a control signal line, and the acoustic output signal line is used as an antenna, the high frequency signal of the received broadcast radio wave affects other signal lines. . When viewed from the acoustic input signal line and the control signal line, crosstalk noise is received by the high frequency signal. When viewed from the acoustic output signal line (antenna), the energy of the received high-frequency signal flows out to other signal lines and the signal is attenuated. This is inconvenient for both the sound input signal line and the control signal line on the noise receiving side and the sound output signal line where the signal is attenuated. According to the above configuration, the acoustic input signal line and the control signal line have the inductor in series with each signal line in the relay portion and the connector portion. Since the impedance is high for the high frequency signal, it is possible to suppress the high frequency signal flowing out to the acoustic input signal line and the control signal line. In addition, since the acoustic output signal line has an inductor in series with each signal line in the relay unit, it is possible to suppress the high-frequency signal from propagating to the earphone and to suppress noise heard from the user's ear.

  Since these inductors are provided in the relay cord, the earphone can be used by arbitrarily replacing a general-purpose one. As a result, it is possible to provide an earphone microphone that can function satisfactorily as an antenna line for receiving broadcast radio waves and can be worn without a sense of incongruity by the user who wears it.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram showing an example of a mobile phone system using an earphone microphone according to the present invention. The cellular phone 4 (corresponding to the device of the present invention) is equipped with a television or radio reception function (tuner function). When receiving broadcast radio waves from a television or radio, the earphone microphone 1 attached to the mobile phone 4 is used as an antenna. The earphone microphone 1 is configured to be separable (detachable) into the relay cord 2 and the earphone 3.

  The relay cord 2 includes a connector unit 6 connected to the mobile phone 4 at one end and a relay unit 5 having a jack unit 5A at the other end. A connector portion 6 </ b> A shown in FIG. 1 is an example of the connector portion 6 when connected to the side surface of the mobile phone 4. The connector portion 6B is an example of a connector portion 6 that uses a portion that is generally used as a charging terminal at the bottom of the mobile phone 4. As described above, the connector section 6 can take various forms as long as it can be physically connected to the mobile phone 4.

  The relay unit 5 has a substrate (see reference numeral 50 in FIG. 2) on which a microphone circuit is mounted, and the earphone microphone 1 and the mobile phone 4 constitute a hands-free set. On the substrate, in addition to a microphone circuit using an electret microphone (see reference numeral 52a in FIG. 2), a switch circuit for controlling on-hook and off-hook during a hands-free call, a control circuit (see reference numeral 53a in FIG. 2), etc. Is installed. This substrate is housed in a case, and a through hole is provided as a sound hole 52 in order to transmit acoustic vibration to the microphone 52a. The case is also provided with a switch operation unit 51 that transmits an operation to a switch (see reference numeral 51a in FIG. 2) that controls on-hook and off-hook during a hands-free call.

  The earphone 3 includes a plug portion 5B that fits with the jack portion 5A at one end portion, and a pair of speaker portions 7 that correspond to left and right acoustic signals at the other end portion. In the present embodiment, an inner phone is used as the speaker unit 7, but of course, another type of speaker such as a headphone may be used.

  As described above, the mobile phone 4 (device) is equipped with a television or radio reception function (tuner function). FIG. 2 is a wiring diagram showing an example of the earphone microphone according to the embodiment of the present invention. As shown in FIG. 2, the earphone 3 provided with the pair of left and right speakers 7 and the plug portion 5B and the relay cord 2 are connected by fitting the plug portion 5B and the jack portion 5A provided in the relay portion 5 together. Is done. The relay cord 2 has an acoustic output signal line 21, an acoustic input signal line 22, and a control signal line 23 as the signal line 20. The acoustic output signal line 21 is a signal line that transmits an acoustic signal from the mobile phone 4 to the speaker 7 via the relay unit 5 in response to the left and right acoustic signals. The sound input signal line 22 is a signal line for transmitting the sound collected by the microphone 52 a provided in the relay unit 5 to the mobile phone 4. The control signal line 23 is a signal line that transmits a control signal between the mobile phone 4 and the control circuit 53a that cooperates with the switch circuit 51a that performs on-hook and off-hook control.

  In the present embodiment, the mobile phone 4 employs a system called a differential system (differential) for output of acoustic signals. As the name indicates, the balanced method represents the acoustic signal by taking the differential between the left and right acoustic signals. Therefore, as shown in FIG. 2, the acoustic output signal line 21 is configured to have two signal lines in which the left and right acoustic signals are plus and minus. The left and right signal line pairs form a twisted pair in which the signal line pairs are spirally wound together. The balanced method has an advantage that noise is less likely to be picked up than the unbalanced method described later because GND is not interposed. However, by adopting a twisted pair structure as described above, the noise resistance is further improved. When connecting to the earphone 3, it is a four-pole connection.

  On the other hand, what is called an unbalanced system (single ended) represents an acoustic signal by a potential difference between the left and right acoustic signals and ground (hereinafter, GND). Since the GND is common, the connection with the earphone 3 is a three-pole connection. Thus, the number of poles of the plug portion 5B of the earphone 3 differs depending on the transmission method of the acoustic signal from the mobile phone 3. In carrying out the present invention, any method may be used as a method for transmitting an acoustic signal. That is, the earphone 3 may be of any type as long as it matches the transmission method of the acoustic signal of the mobile phone 4. When the relay unit 5 performs conversion between the balanced method and the unbalanced method, the methods of the earphone 3 and the mobile phone 4 do not have to match. In other words, the earphone microphone 1 as a whole may be any device that can transmit an acoustic signal from the mobile phone 4 to the speaker 7 satisfactorily.

  In the present embodiment, the acoustic input signal line 22 is also a twisted pair. Since the reason is the same as that of the acoustic output signal line, description thereof is omitted. On the other hand, in the example shown in FIG. 2, the control signal line 23 is a parallel line and does not employ a twisted pair. Since only three types of power supply VCC, ground GND, and signal SIG are shown as the control signal line 23, it is not preferable to form a twisted pair with these three lines. However, as is well known, the power supply VCC and the ground GND may be a twisted pair, and the signal SIG may be a single wire or a twisted pair with another ground.

Here, the acoustic output signal line 21 of the relay cord 2 is caused to function as an antenna ATN that receives broadcast radio waves. In this case, the antenna ATN functions as a monopole antenna, and the length thereof is preferably ½ wavelength and ¼ wavelength of the wavelength λ of the broadcast wave to be received as is well known. The wavelength λ of the electromagnetic wave is
λ = speed of light in vacuum c / frequency f (Equation 1)
Indicated. For example, if the target frequency f is 97 MHz, the wavelength λ1 is
λ1≈3090 [mm]
Thus, the ½ wavelength and ¼ wavelength are 1545 mm and 773 mm, respectively. Therefore, in practice, the portion (antenna ATN) that acts as the antenna of the relay cord 2 may be about 773 mm long.

  By the way, the relationship shown in Formula 1 is based on the premise that the speed of electromagnetic wave travel matches the speed of light in vacuum. Here, the light velocity c in vacuum is the reciprocal of the square root of the product of the vacuum dielectric constant and the vacuum magnetic permeability. Actually, the dielectric constant increases due to the influence of a conductor such as a signal line and an insulator such as a resin around the conductor, so that the speed of propagation of the electromagnetic wave is slower than in a vacuum. Therefore, the length of the antenna ATN for receiving the broadcast radio wave satisfactorily even at the same frequency does not match the wavelength λ1 shown above. Therefore, in actuality, the calculation of the theoretical value, the measurement of the characteristic impedance of the relay cord 2, the experiment of obtaining the optimum value by measuring the power of the received radio wave by causing the relay cord 2 to act as the transmitting side antenna, etc. The length should be determined. That is, the length of the relay cord 2 may be determined by obtaining a wavelength shortening rate by any one of the above methods or a combination thereof.

  Thus, since only the relay cord 2 acts as an antenna to receive broadcast radio waves, the reception performance does not depend on the earphone 3. Therefore, it is possible to provide a stable antenna capable of exhibiting a certain reception performance regardless of the earphone 3 provided with the speaker 7. Therefore, even when the inner earphone (speaker 7) does not fit in the ear of the user wearing the earphone 3, this can be easily replaced. Since the connection with the mobile phone 4 is carried out by the relay cord 2, the earphone 3 can be freely replaced with a type that does not have an antenna function. As a result, it is possible to provide the earphone microphone 1 that can be worn without a sense of incongruity by the wearing user.

  Incidentally, the relay cord 2 has an acoustic output signal line 21, an acoustic input signal line 22, and a control signal line 23. When the acoustic output signal line 21 is used as an antenna, a high frequency signal of the received broadcast radio wave affects other signal lines. When viewed from the acoustic input signal line 22 and the control signal line 23, crosstalk noise is received by the high frequency signal. When viewed from the acoustic output signal line 21, the received high-frequency signal flows out to other signal lines, and the energy is attenuated. This is inconvenient for both the sound input signal line 22 and the control signal line 23 on the noise receiving side and the sound output signal line 21 where the signal is attenuated.

  Therefore, as shown in FIG. 2, the acoustic input signal line 22 and the control signal line 23 include an inductor in series with each signal line in the relay unit 5 and the connector unit 6. Specifically, the relay unit 5 includes an inductor L52 in series with each signal line of the acoustic input signal line 22 and an inductor L53 in series with each signal line of the control signal line 23. Further, the connector unit 6 includes an inductor L62 in series with each signal line of the acoustic input signal line 22 and an inductor L63 in series with each signal line of the control signal line 23. These inductors L52, L53, L62, and L63 have high impedance for high-frequency signals, and can suppress the outflow of power. The acoustic output signal line 21 includes an inductor L51 in series with each signal line in the relay unit 5. Thereby, it can suppress that a high frequency signal propagates to the earphone 3, and can suppress the noise heard from a user's ear.

  FIG. 3 is a diagram for explaining an example of an inductor mounting form in the connector section 6 shown in FIGS. 1 and 2. Here, a configuration in which the inductor L62 of the acoustic input signal line 22 and the inductor L63 of the control signal line 23 are attached to the connector 6B shown in FIG.

  As shown in FIG. 3B, the connector 6B solders the pins 64 to the board 62 and connects the signal lines 20 of the relay cord 2 on the board surface opposite to the protruding direction of the pins 64. ing. The connection surface between each signal line 20 and the substrate 62 is molded according to the inner shape of the mold housing 65. The mold 61 is covered with a mold housing 65, the pin housing 63 is covered from the pin 64 side of the substrate 62, and the substrate 62 is sandwiched from both sides to form the connector portion 6B (see FIG. 3A). At this time, as shown in FIG. 3C, if surface mount type inductors L62 and L63 are mounted on the substrate surface on the mold 61 side, parts may be broken during molding. Therefore, as shown in FIG. 3B, inductors L62 and L63 are mounted on the side where the pin 64 is mounted to suppress the occurrence of problems such as cracking of components.

  The present invention can be applied to an earphone microphone that includes a speaker that emits sound and a microphone that obtains sound and has an antenna function. This earphone microphone is a device that has a tuner function for receiving broadcast radio waves such as TV and radio, a function for outputting sound obtained by broadcasting, recording, and communication, and a function for recording, communicating, and controlling by receiving sound. You can connect to and use it. For example, it can be used by connecting to a mobile phone, an audio device with a recording function, a device with a voice recognition control function, or the like.

1 is a schematic configuration diagram showing an example of a mobile phone system using an earphone microphone according to the present invention. The wiring diagram which shows an example of the earphone microphone which concerns on embodiment of this invention FIGS. 1A and 1B are diagrams for explaining an example of a mounting form of an inductor in the connector section 6. FIG. 1A is a completed view, FIG. 2B is an assembled view, and FIG.

Explanation of symbols

1 Earphone microphone 2 Relay cord 3 Earphone 4 Mobile phone (equipment)
5 Relay part 5A Jack part, 5B Plug part 6 Connector part 7 Speaker (speaker part)

Claims (3)

A connector part at one end, a speaker part at the other end, a relay part with a microphone circuit mounted in the middle of the cord connecting both ends, and an acoustic signal input / output function via the connector part An earphone microphone connected to a device having
The code is
A relay cord provided with the relay portion having the connector portion at one end and a jack portion at the other end,
A plug portion that fits into the jack portion at one end portion, and an earphone that includes the speaker portion at the other end portion are detachably connected,
An earphone microphone that receives broadcast waves using the relay cord as an antenna and inputs the broadcast waves to the device.   The relay cord controls an acoustic output signal line for transmitting the acoustic output signal from the device, an acoustic input signal line for transmitting an acoustic input signal from the relay unit to the device, and controls the device from the relay unit. The earphone microphone according to claim 1, further comprising: a control signal line that transmits a control signal, wherein the acoustic output signal line functions as the antenna. The acoustic input signal line and the control signal line have an inductor in series with each signal line in the relay portion and the connector portion,
The earphone microphone according to claim 2, wherein the acoustic output signal line includes an inductor in series at the relay unit.

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