JP5397731B2 - Sound leakage simulator - Google Patents

Description

  The present invention relates to an ear-mounted acoustic device having a sound leakage confirmation function.

Ear-mounted acoustic devices such as earphones and headphones have a problem of so-called sound leakage in which sound being reproduced leaks to the outside. As a technique for preventing this sound leakage, a method of automatically adjusting the playback volume according to the volume (sound pressure level) of the environmental sound is known. (Patent Documents 1 to 5)
JP 2008-72677 A Japanese Patent Laid-Open No. 2007-43231 JP 2004-13084 A Japanese Patent Laid-Open No. 9-130885 JP-A-6-6156

  The conventional sound leakage prevention technology described above detects the volume of environmental sound with a sensor and automatically adjusts the playback volume according to the detected value. However, sound leakage at a level that can be heard by the surrounding people occurs. It is impossible for the user of the ear-mounted acoustic device to confirm that it is not. For this reason, in the conventional sound leakage prevention technology, even if sound leakage at a volume that is harsh to the surrounding people actually occurs, the person himself / herself does not notice that, so the sound leakage prevention function is working Nevertheless, the surrounding people feel uncomfortable due to sound leakage. After all, it is up to the user's morals to adjust the playback volume so that the sound leakage of the playback sound he / she is listening to does not disturb others. .

  The problem to be solved by the present invention is that the user listens to and confirms the sound of components that are easily audible to the surrounding people out of the leaking sound, and does not cause sound leakage at a level that can be heard by the surrounding people. It is another object of the present invention to provide an ear-mounted acoustic device and a sound leakage simulator that can adjust the volume of reproduced sound.

  In order to solve the above-described problem, an ear-mounted acoustic device of the first type of the present invention includes an ear-mounted body that is mounted on a human ear and includes an electroacoustic transducer that converts an electrical signal into sound. A sound leak simulator that processes an electric signal from a signal source and supplies the electric signal to the electroacoustic transducer, and the sound leak simulator is a component that is highly likely to be heard as sound leak from the input electric signal. An equalizer means for generating an electric signal corresponding to the sound of the sound, and a mode switching means. By operating the mode switching means, the electric signal from the signal source can be transmitted without going through the equalizer means. It can be used by selectively switching to a normal mode for supplying to an acoustic transducer or a sound leakage confirmation mode for supplying an electrical signal from the signal source to the electroacoustic transducer via the equalizer means. It is those that you configured.

  In order to solve the above problems, a first type of sound leakage simulator according to the present invention is an apparatus for supplying an electric signal from a signal source to an electroacoustic transducer in an ear-wearing body, from an input electric signal. An equalizer means for generating an electric signal corresponding to a sound of a component that is likely to be heard as sound leakage; and a mode switching means. By operating the mode switching means, an electric signal from the signal source is obtained. In a normal mode in which a signal is supplied to the electroacoustic transducer without going through the equalizer means, or in a sound leakage confirmation mode in which an electric signal from the signal source is supplied to the electroacoustic transducer through the equalizer means, It is configured so that it can be selectively switched and used.

  According to the first-type ear-mounted acoustic device and the sound leakage simulator configured as described above, when used in the sound leakage confirmation mode, there is a possibility of being heard as sound leakage in the original reproduced sound. The user who wears the ear wearing body can listen to and confirm the sound (simulated sound) from which only high components are extracted. Then, by adjusting the volume to a level at which the sound cannot be heard, the volume of the reproduced sound can be adjusted so as not to cause sound leakage that can be heard by the surrounding people. Thereafter, by switching to the normal mode and using it, it is possible to listen to the original reproduced sound at a volume that does not cause sound leakage at a level that can be heard by the surrounding people.

  The second type ear-mounted acoustic device of the present invention includes an ear-mounted body that is mounted on a person's ear with an electroacoustic transducer that converts an electrical signal into sound, and an electrical signal from a signal source. A sound leakage simulator for processing and supplying the electroacoustic transducer to the electroacoustic transducer, the sound leakage simulator comprising: filter means for passing only high-band components of the input electric signal; and mode switching means. A normal mode for supplying the electric signal from the signal source to the electroacoustic transducer without passing through the filter means by operating the mode switching means, or the electric signal from the signal source. The sound leakage check mode supplied to the electroacoustic transducer via the filter means can be selectively switched and used.

  In order to solve the above-mentioned problems, a second type of sound leakage simulator of the present invention is an apparatus for supplying an electric signal from a signal source to an electroacoustic transducer in an ear wearing body, The electroacoustic transducer includes a filter unit that allows only a high-band component to pass through, and a mode switching unit, and operates the mode switching unit so that an electric signal from the signal source does not pass through the filter unit. It can be used by selectively switching to the normal mode for supplying to the sound or the sound leakage confirmation mode for supplying the electric signal from the signal source to the electroacoustic transducer via the filter means. .

  According to the second type ear-mounted acoustic device and the sound leakage simulator configured as described above, by using the sound leakage check mode, only the sound of the high-band component in the original reproduced sound is heard. The user himself / herself wearing the wearing body can listen and confirm it. Of the sound being played, especially high-band sounds are likely to be heard as sound leaks. By adjusting the volume to a level at which the sounds cannot be heard, playback is performed so that sound leaks at a level that can be heard by the surrounding people do not occur. The sound volume can be adjusted. Thereafter, by switching to the normal mode and using it, it is possible to listen to the original reproduced sound at a volume that does not cause sound leakage at a level that can be heard by the surrounding people.

  According to the ear-mounted acoustic device and the sound leakage simulator of the present invention, sound leakage that can be heard by surrounding people while the user listens to and confirms the sound of the component that is likely to be heard as sound leakage. The volume of the playback sound can be adjusted so that it does not occur.

Embodiments of the present invention will be described below.
[First embodiment]
FIG. 1 is a functional block diagram showing an example of an ear-mounted acoustic device according to the present invention.

  An ear-mounted acoustic device 1 shown in FIG. 1 includes an earphone (ear-mounted body) 2 and a sound leakage simulator 4 that supplies an electric signal from a portable music player (signal source) 3 to the earphone 2. .

The earphone 2 has a built-in speaker (electroacoustic transducer) 5. The speaker 5 converts an electrical signal sent from the portable music player 3 via the sound leakage simulator 4 into sound.
The sound leakage simulator 4 has a volume controller (volume controller), an equalizer circuit (equalizer) 7, and a mode switch (mode switch) 8.

  The volume controller 6 changes the output volume of the speaker 5 according to the volume control operator 9 that is operated steplessly (rotation operation, slide operation) by the user and the operation amount of the volume control operator 9. And an output adjustment circuit 10.

  The equalizer circuit 7 is a circuit that generates an electrical signal corresponding to a component having a high possibility of being heard as sound leakage from the input electrical signal. The equalizer circuit 7 is created in accordance with the sound leakage characteristics of the earphone 2 measured in advance. That is, the equalizer circuit 7 is designed to generate an electrical signal corresponding to a sound having a component that is likely to be heard as sound leakage when the earphone 2 is used. The output signal of the equalizer circuit 7 is input to the volume controller 6.

  The mode switching device (mode switching means) 8 is a component for selectively switching the operation mode of the sound leakage simulator 4 to the normal mode, the sound leakage confirmation mode, or the mute mode. And a mode switching circuit 12. The mode switching operator 11 is selectively switched to a position corresponding to any one of the normal mode, the sound leakage confirmation mode, and the mute mode by the user. The mode switching circuit 12 inputs an electrical signal from the portable music player 3 to one of the equalizer circuit 7 and the volume controller 6 according to the switching state of the mode switching operator 11 or adjusts the volume with the equalizer circuit 7. It operates so as not to input to either of the devices 6. In other words, the mode switching circuit 12 inputs an electric signal from the portable music player 3 to the volume controller 6 when the mode switching operator 11 is in the normal mode selection state, and the mode switching operator 11 confirms sound leakage. When the mode is selected, an electric signal from the portable music player 3 is input to the equalizer circuit 7. Further, when the mode switching operator 11 is in the mute mode selection state, the electric signal from the portable music player 3 is cut off.

  FIGS. 2A and 2B are perspective views showing an example of the sound leakage simulator 4. The operation units of the volume control operator 9 and the mode switching operator 11 are exposed from the casing 13 of the sound leakage simulator 4. The output adjustment circuit 10, the equalizer circuit 7, and the mode switching circuit 12 are accommodated in the housing 13. One end of the housing 13 is provided with an earphone jack (output terminal hole) 15 to which a connection plug of the earphone cord 14 is detachably connected. Further, a connection cord 16 with the portable music player 3 extends from the other end of the housing 13. A connection plug 17 is provided at the tip of the connection cord 16 so as to be removably connected to the earphone jack (output terminal hole) of the portable music player 3.

  The ear-mounted acoustic device 1 normally supplies an electric signal from the portable music player 3 to the speaker 5 of the earphone 2 without going through the equalizer circuit 7 by operating the mode switching operator 11 of the sound leakage simulator 4. Mode, sound leakage check mode for supplying an electric signal from the portable music player 3 to the speaker 5 of the earphone 2 via the equalizer circuit 7, or a mute mode for completely blocking the electric signal from the portable music player 3 Can be used by switching to

  Therefore, according to this ear-mounted acoustic device 1, by using it in the sound leakage confirmation mode, a sound (simulated sound) obtained by extracting only a component that is likely to be heard as sound leakage from the original reproduced sound is extracted. The user himself / herself wearing the earphone 2 can listen and confirm by himself / herself. Then, by adjusting the volume to a level at which the sound cannot be heard, the volume of the reproduced sound can be adjusted so as not to cause sound leakage that can be heard by the surrounding people. Thereafter, by switching to the normal mode and using it, it is possible to listen to the original reproduced sound at a volume that does not cause sound leakage at a level that can be heard by the surrounding people.

  Next, the principle that the sound leakage can be confirmed and the principle that the volume can be adjusted to a level that does not leak the sound in the ear-mounted acoustic device 1 of the present invention will be described with reference to FIGS.

  FIG. 3A illustrates the frequency characteristic of the output sound A from the earphone 2 when the earphone 2 is worn and listening to music in the normal mode. FIG. 3B illustrates the frequency characteristics of the sound B leaking from the earphone 2 at this time. In this case, out of the output sound A in FIG. 3A, the sound B in FIG. 3B may be heard as a sound leaking sound by a surrounding person (person other than the user) (FIG. 3C). ). Therefore, the volume that is a criterion for determining whether or not sound is leaking is the peak volume in FIG. The frequency characteristic of sound leaking differs depending on the type and structure of the earphone 2. In other words, if the type and structure of the earphone 2 are the same, the frequency characteristics of the sound leaking are the same.

  Therefore, the equalizer circuit 7 is designed based on the sound leakage characteristic unique to the earphone 2 used in combination with the sound leakage simulator 4. In this case, the equalizer circuit 7 having an equalizing characteristic (equalizing the curve) that approximates the peak curve of the frequency characteristic (a curve connecting the peak values of the spectrum) in FIG. 3B is designed. The inherent sound leakage characteristic of the earphone 2 is that the earphone 2 is attached to the ear of the dummy head to reproduce white noise (20 to 20 kHz noise) and the output volume is adjusted to a level at which sound leakage occurs. The sound is picked up by a super-directional microphone installed at a position away from the earphone 2 by a predetermined distance (for example, about 50 cm), and is measured by frequency analysis. Then, an equalizer circuit 7 having an equalizing curve is designed so that a sound signal is output with the frequency characteristics shown in FIG. 3B when white noise of the same level as in the sound leakage characteristic measurement is input.

  FIG. 4A illustrates the frequency characteristics of the sound output from the earphone 2 when the equalizer circuit 7 is turned on, that is, when the use mode of the ear-mounted acoustic device 1 is switched to the sound leakage confirmation mode. Yes. At this time, the frequency characteristic of the electric signal output from the portable music player 3 is the same as that in the normal mode, but the equalized sound B ′ is heard from the earphone 2. If the volume is lowered until the voice B 'is no longer heard (FIG. 4B), no sound leaks. This means that sound leakage does not occur at the adjusted volume. Thereafter, when the use mode of the ear-mounted acoustic device 1 is returned to the normal mode, normal reproduction is performed at an optimal volume that does not leak sound (FIG. 4C).

  As described above, the ear-mounted acoustic device 1 is designed with the equalizer circuit 7 based on the inherent sound leakage characteristics of the earphone 2 used in combination with the sound leakage simulator 4. By reproducing the sound, it is possible to faithfully reproduce the state of sound leakage regardless of the magnitude of the environmental noise. Therefore, in the sound leakage confirmation mode, the user of the earphone 2 confirms the reproduced sound leakage sound by itself, adjusts the output volume so that the sound cannot be heard, and then returns to the normal mode. Regardless of the size, the output volume of the earphone 2 can be adjusted to the maximum volume that does not leak sound.

[Second Embodiment]
Another embodiment of the ear-mounted acoustic device according to the present invention will be described. Here, the same components as those in the ear-mounted acoustic device 1 in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted as appropriate.
FIG. 5 is a functional block diagram showing another example of the ear-mounted acoustic device according to the present invention.

  An ear-mounted acoustic device 21 shown in FIG. 5 includes an earphone (ear-mounted body) 2 and a sound leakage simulator 22 that supplies an electric signal from a portable music player (signal source) 3 to the earphone 2. .

  The earphone 2 has a built-in speaker (electroacoustic transducer) 5. The speaker 5 converts an electric signal sent from the portable music player 3 via the sound leakage simulator 22 into sound.

  The sound leakage simulator 22 includes a volume controller (volume controller) 6, a high-pass filter circuit (filter unit) 23, and a mode switcher (mode switch unit) 8.

  The high-pass filter circuit 23 is a circuit that passes only a high-band component (for example, 5 kHz or more) of the input electric signal. The output signal of the high pass filter circuit 23 is input to the volume controller 6.

  The mode switching circuit 12 inputs an electrical signal from the portable music player 3 to either the high-pass filter circuit 23 or the volume controller 6 according to the switching state of the mode switching operator 11, or the high-pass filter circuit 23 It operates so as not to input to either of the volume controllers 6. In other words, the mode switching circuit 12 inputs an electric signal from the portable music player 3 to the volume controller 6 when the mode switching operator 11 is in the normal mode selection state, and the mode switching operator 11 confirms sound leakage. When the mode is selected, an electric signal from the portable music player 3 is input to the high pass filter circuit 23. Further, when the mode switching operator 11 is in the mute mode selection state, the electric signal from the portable music player 3 is cut off.

  The ear-mounted acoustic device 1 supplies the electric signal from the portable music player 3 to the speaker 5 of the earphone 2 without passing through the high-pass filter circuit 23 by operating the mode switching operator 11 of the sound leakage simulator 22. Selectable in normal mode, sound leak confirmation mode in which electric signal from portable music player 3 is supplied to speaker 5 of earphone 2 through high-pass filter circuit 23, or mute mode in which electric signal from portable music player 3 is completely cut off Can be used by switching to

  Therefore, according to the ear-mounted acoustic device 1, the earphone 2 is worn with a sound (simulated sound) obtained by extracting only the sound of the high-band component from the original reproduced sound when used in the sound leakage confirmation mode. The user himself / herself can listen to and confirm. Of the sound being played, especially high-band sounds are easily heard as sound leaks. By adjusting the volume to a level at which the sounds cannot be heard, playback is performed so that no sound leaks that can be heard by the surrounding people. The sound volume can be adjusted. Thereafter, by switching to the normal mode and using it, it is possible to listen to the original reproduced sound at a volume that does not cause sound leakage at a level that can be heard by the surrounding people.

[Other examples]
In the above embodiment, the sound volume simulator 6 is provided in the sound leakage simulators 4 and 22, but the volume controller 6 is not an essential component of the sound leakage simulator of the present invention. In other words, the volume controller 6 of the sound leakage simulator 4 or 22 may be omitted, and the volume controller of the portable music player 3 may be operated to adjust the playback volume to a volume that does not leak sound.

  In the above embodiment, the sound leakage simulator 4 or 22 is interposed between the earphone 2 and the portable music player 3, but the portable music player 3 may have the function of the sound leakage simulator 4 or 22. In that case, the audio signal output circuit in the portable music player 3 serves as a signal source in the present invention, and an electric signal from the audio signal output circuit is output from the output terminal of the portable music player 3 via the equalizer circuit 7 or the high-pass filter circuit 23. Is output. Further, the function of the sound leakage simulator 4 or 22 may be added to the portable music player 3 by installing a program for realizing the function of the sound leakage simulator 4 or 22 in the portable music player 3. In that case, a plurality of types of equalizing characteristics or high-pass filter characteristics data are installed in the memory of the portable music player 3, and the circuit function of equalizing characteristics or high-pass filter characteristics most suitable for the earphone 2 to be used is provided. You may make it selectable above.

  In the above-described embodiment, the high-pass filter circuit 23 is configured to uniformly pass a component having a frequency equal to or higher than a predetermined frequency in the input electric signal. Instead, it is heard as a sound leak measured in advance. A filter circuit having a characteristic of passing only a component having a high possibility may be used.

  In the above embodiment, the connection cord 16 extends from the housing 13 of the sound leakage simulator 4 and the connection plug 17 is provided at the tip of the connection cord 16. However, the connection cord 16 is omitted, and the housing 13 may be provided with a direct connection plug 17.

  Further, the equalizer circuit 7 or the high-pass filter circuit 23 may be realized using a DSP (Digital Signal Processor).

Functional block diagram showing an example of an ear-mounted acoustic device according to the present invention (A), (b) is a perspective view which shows the form example of a sound leak simulator (A) Histogram illustrating frequency characteristic of sound output from specific earphone (b) Histogram illustrating sound leakage characteristic of the earphone (c) is (b) of output sound A shown in (a) Explanatory drawing about a part of sound B shown in FIG. (A) is an explanatory diagram illustrating the output characteristics of the earphones in the sound leakage confirmation mode. (B) is an explanatory diagram illustrating the output characteristics of the earphones when the volume is lowered until the equalized sound is no longer heard. Explanatory drawing which illustrates the output characteristic of an earphone when it returns to normal mode after adjusting a volume like b) Functional block diagram showing another embodiment of the ear-mounted acoustic device according to the present invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ear mounting type acoustic device 2 Earphone 3 Portable music player 4 Sound leakage simulator 5 Speaker (electroacoustic transducer)
6 Volume controller (volume control means)
7 Equalizer circuit (equalizer means)
8 Mode selector (mode switching means)
DESCRIPTION OF SYMBOLS 9 Volume control operation element 10 Output adjustment circuit 11 Mode switching operation element 12 Mode switching circuit 21 Ear wearing type acoustic device 22 Sound leakage simulator 23 High pass filter circuit (filter means)

Claims (6)

An ear-mounted body that is mounted on a human ear with a built-in electroacoustic transducer that converts electrical signals into sound;
A sound leakage simulator for supplying an electric signal from a signal source to the electroacoustic transducer,
The sound leakage simulator is
Equalizer means for generating an electrical signal corresponding to a sound of a component that is likely to be heard as sound leakage from the input electrical signal;
Mode switching means,
By operating the mode switching means, a normal mode in which an electric signal from the signal source is supplied to the electroacoustic transducer without going through the equalizer means, or an electric signal from the signal source is supplied to the equalizer means. An ear-mounted acoustic device configured to be selectively switched to and used in a sound leakage confirmation mode supplied to the electroacoustic transducer via the connector. An ear-mounted body that is mounted on a human ear with a built-in electroacoustic transducer that converts electrical signals into sound;
A sound leakage simulator for supplying an electric signal from a signal source to the electroacoustic transducer,
The sound leakage simulator is
Filter means for passing only high-band components of the input electrical signal;
Mode switching means,
By operating the mode switching means, a normal mode in which an electric signal from the signal source is supplied to the electroacoustic transducer without passing through the filter means, or an electric signal from the signal source is supplied to the filter means. An ear-mounted acoustic device configured to be selectively switched to and used in a sound leakage confirmation mode supplied to the electroacoustic transducer via the connector.   The ear-mounted acoustic device according to claim 1, further comprising a volume adjusting unit for adjusting an output volume of the electroacoustic transducer. A sound leakage simulator for supplying an electric signal from a signal source to an electroacoustic transducer in an ear wearing body,
Equalizer means for generating an electrical signal corresponding to a sound of a component that is likely to be heard as sound leakage from the input electrical signal;
Mode switching means,
By operating the mode switching means, a normal mode in which an electric signal from the signal source is supplied to the electroacoustic transducer without going through the equalizer means, or an electric signal from the signal source is supplied to the equalizer means. A sound leakage simulator configured to be selectively switched to and used in a sound leakage confirmation mode supplied to the electroacoustic transducer via A sound leakage simulator for supplying an electric signal from a signal source to an electroacoustic transducer in an ear wearing body,
Filter means for passing only high-band components of the input electrical signal;
Mode switching means,
By operating the mode switching means, a normal mode in which an electric signal from the signal source is supplied to the electroacoustic transducer without passing through the filter means, or an electric signal from the signal source is supplied to the filter means. A sound leakage simulator configured to be selectively switched to and used in a sound leakage confirmation mode supplied to the electroacoustic transducer via   The sound leakage simulator according to claim 4 or 5, further comprising a volume adjusting means for adjusting an output volume of the electroacoustic transducer.