JP5849435B2 - Sound reproduction control device - Google Patents

Description

  The present invention relates to a sound reproduction control device having a function of preventing sound leakage when listening to music using earphones or headphones.

  When listening to music with the earphone attached to the ear, if there is a gap between the earphone and the ear canal, the playback sound of the earphone leaks to the outside through this gap. Such a sound leak is often not noticed by the person wearing the earphones and is often annoying to the surroundings. Patent Documents 1 to 3 are documents that disclose techniques related to the prevention of sound leakage. Here, Patent Document 1 discloses a technique for avoiding sound leakage by detecting a middle / high tone signal level in an input signal of an earphone by a detection circuit and suppressing the input signal level of the earphone based on the detection result. ing. Patent Document 2 collects sound leaking from the sound output unit, which is a headphone or an earphone, to the outside of the ear canal using a microphone provided in the vicinity of the sound output unit, and the sound signal to be reproduced and the microphone. A technique is disclosed in which the frequency of an audio signal is analyzed, and when the frequencies match, it is determined that sound leaks and the volume of the audio signal reproduced by the audio output unit is reduced. Patent Document 3 discloses a technique for collecting earphone leakage sound using a microphone of a stereo earphone microphone.

JP-A-5-49091 Japanese Patent Laid-Open No. 2007-43231 JP 2007-88521 A

  By the way, the technique disclosed in Patent Document 1 suppresses the sound when the level of a medium / high sound signal in the input signal of the earphone is high, regardless of whether or not sound leakage occurs from the earphone. The technique disclosed in Patent Document 1 has a problem that even in a situation where sound leakage does not occur, a mid-high sound signal is suppressed in the input signal of the earphone. In addition, the technique disclosed in Patent Document 2 is to determine the state of sound leakage by comparing the sound collected by the microphone outside the earphone or the headphone with the sound output from the earphone. The processing load for determining the situation is heavy, and there is a problem that it is difficult to accurately determine the state of sound leakage particularly in a situation where there is noise around. The technique disclosed in Patent Document 3 also has a similar problem because it collects the leaked sound of the earphone with a microphone outside the earphone.

  The present invention has been made in view of the above-described circumstances, and an acoustic reproduction control device that can accurately detect sound leakage of an earphone or a headphone and prevent sound leakage even in the presence of ambient noise. The purpose is to provide.

  The present invention includes an electrical / acoustic conversion unit and an acoustic / electrical conversion unit, and outputs sound to a space in the external auditory canal by the electrical / acoustic conversion unit in a state where the electrical / acoustic conversion unit is attached to an ear, and the acoustic / electrical conversion. In the sound reproduction control device that controls the operation of the sound input / output device that picks up sound in the space by the unit, the electric / acoustic conversion of the sound input / output device based on the output signal of the sound / electric conversion unit There is provided a sound reproduction control device comprising control means for generating sound leakage data indicating the degree of sound leakage from the sound output to the outside of the ear canal.

  In this sound reproduction control device, when the gap between the sound input / output device and the ear canal increases, the amount of attenuation in the low frequency of the sound output in the ear canal increases according to the degree of increase in the gap. In this sound reproduction control device, using this phenomenon, the control means generates sound leakage data indicating the degree of sound leakage based on the output signal of the sound / electrical converter, so that noise is generated in the environment outside the ear. Sound leakage can be detected accurately even under certain circumstances. Therefore, sound leakage can be effectively prevented.

1 is a diagram illustrating an overall configuration of a sound reproduction system using a sound reproduction control device 10 according to a first embodiment of the present invention. 3 is a block diagram showing a configuration of the sound reproduction control device 10. FIG. When the sound is emitted from the earphone into the ear canal in a state where there is a gap between the earphone and the ear canal, the figure shows how the low frequency component of the sound emitted in the ear canal is attenuated depending on the size of the gap. is there. The longitudinal cross-sectional view which cut | disconnected the earphone 12L or 12R with a microphone in the same embodiment along the virtual plane containing the output axis Z of the sound of the earphone, and the axis Y along the vibration direction of the diaphragm of the driver in the housing | casing of the earphone It is. It is a figure which shows the sound leak indicator 114 and the operation element group 115 provided in the housing | casing of the control main-body part 11 in the embodiment. It is a figure which shows the blinking operation | movement of the sound leak indicator 114 in the embodiment. It is a figure which shows the content of the calculation process of the attenuation amount in the sound reproduction control apparatus 10 which is 2nd Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
<First Embodiment>
FIG. 1 is a diagram showing an overall configuration of a sound reproduction system using a sound reproduction control device 10 according to the first embodiment of the present invention. The sound reproduction system shown in FIG. 1 includes the sound reproduction control device 10 according to the present embodiment and the sound reproduction device 20 that reproduces an audio signal such as music from a storage medium. Here, the sound reproduction control device 10 includes a control main body 11, earphones 12L and 12R with microphones as sound input / output devices, cables 13L and earphones 12L and 12R with microphones and the control main body 11 connected to the control main body 11. 13R, and a cable 14 for connecting the control main body 11 and the sound reproducing device 20 to each other. The cable 14 has a mini jack 14j at the tip, and is connected to the sound reproducing device 20 by the mini jack 14j.

  FIG. 2 is a block diagram illustrating a configuration of the sound reproduction control device 10. The earphones 12L and 12R with microphones in FIG. 1 incorporate drivers 121L and 121R, which are electrical / acoustic conversion units that convert electrical signals into acoustic vibrations (acoustic signals), respectively, and convert acoustic vibrations (acoustic signals) into electrical signals. Microphones 122 </ b> L and 122 </ b> R, which are acoustic / electrical conversion units to be converted, are respectively incorporated. The earphones 12L and 12R with microphones output sound to each space in the ear canal of each ear by the drivers 121L and 121R while being attached to the left and right ears of the user as shown in FIG. The sounds in the ear canal of each ear are collected by 122L and 122R.

  The control main body 11 receives the left and right two-channel audio signals AL1 and AR1 from the sound reproducing device 20 (see FIG. 1) via the cable 14, and levels for preventing sound leakage with respect to these audio signals AL1 and AR1. This is a device that performs adjustment processing, and supplies level-adjusted two-channel audio signals AL3 and AR3 to the earphones 12L and 12R with microphones via the cables 13L and 13R, respectively. In the microphone-equipped earphones 12L and 12R, the audio signals AL3 and AR3 from the control main body 11 are supplied to the drivers 121L and 121R, respectively. The audio signals output from the microphones 122L and 122R of the earphones 12L and 12R with microphones are supplied to the control main body 11 through the cables 13L and 13R, and are used for control for preventing sound leakage.

  Here, the principle of sound leakage detection in this embodiment will be described. In earphones that are used with the earpiece pushed into the ear canal, such as canal earphones, if there is a gap between the earphone and the ear canal, the high-frequency sound that is emitted into the ear canal passes through the gap. While leaking out of the ear, the sound pressure of the sound in the band near 100 Hz is greatly attenuated in the ear canal. FIG. 3 is a diagram illustrating this phenomenon. In FIG. 3, N0 is the amplitude characteristic of the audio signal given to the driver of the earphone inserted in the ear canal, N1 is the sound in the ear canal with a microphone of a predetermined size in the earpiece of the earphone. The amplitude characteristic of the output signal of the microphone when the sound is picked up, N2 is the amplitude characteristic of the output signal of the microphone when the size of the hole of the earpiece is doubled to N1, and N3 is the size of the hole of the earpiece N1 , N4 represents the amplitude characteristic of the microphone output signal when the size of the earpiece hole is quadrupled to N1, respectively. From this figure, the sound pressure of the sound output into the ear canal by the earphone is attenuated by a gap (a hole in the earpiece in the example of FIG. 3) between the earphone and the ear canal in a band near 100 Hz. It can be seen that the attenuation increases as the gap area increases. Therefore, if the attenuation amount in the band near 100 Hz of the sound pressure of the sound output from the earphone into the ear canal is obtained, this attenuation amount increases according to the area of the gap between the earphone and the ear canal and this area. It can be used as data indicating the degree of high frequency sound leakage.

  The control main body 11 in the present embodiment uses this phenomenon to detect sound leakage. That is, based on the audio signal AL1 and the audio signal output from the microphone 122L, the control main body 11 determines the sound pressure attenuation amount in the low frequency range near 100 Hz of the sound output from the driver 121L into the left ear canal. At the same time, based on the audio signal AR1 and the audio signal output from the microphone 122R, the attenuation amount of the sound pressure in the low frequency region near 100 Hz of the sound output from the driver 121R into the ear canal of the right ear is determined. The level of sound leakage is detected based on these attenuation amounts, and the level of the audio signal is adjusted to prevent sound leakage.

  In order to appropriately detect such a sound leak, the earphones 12L and 12R with microphones can output sound into the ear canal and appropriately detect the sound pressure in the ear canal as a result. Is required. FIG. 4 shows the earphone 12L or 12R with a microphone according to the present embodiment cut along a virtual plane including the output axis Z of the sound of the earphone and the axis Y along the vibration direction of the diaphragm of the driver in the housing of the earphone. It is a longitudinal cross-sectional view.

  The housing 201 is hollow and has a flat part 201A for accommodating a driver 121 (corresponding to the drivers 121L and 121R in FIG. 2) and a cylindrical part 201B protruding from the flat part 201A. At the tip (outer peripheral part) of the cylinder part 201B, it is made of a soft elastic body such as rubber, and an umbrella-shaped earpiece 220 having an opening 221 at the center is attached. The earpiece 220 includes a hollow cylindrical portion 222 having an inner diameter capable of accommodating the cylindrical portion 201 </ b> B just inside, and the cylindrical portion 201 </ b> B is fitted into the cylindrical portion 222. The cylindrical portion 201 </ b> B functions as a sound path that guides the acoustic vibration radiated from the driver 121 to the ear canal and simultaneously guides the acoustic vibration in the ear canal to the microphone 122 in a state where the earpiece 220 is inserted into the ear canal.

  Inside the flat part 201A of the housing 201, a tray 202 composed of a recessed part 202A and a collar part 202B is fixed. A permanent magnet 203 is fixed to the recess 202A of the tray 202 by a bobbin 204, and an outer peripheral portion of a substantially disc-shaped diaphragm 205 is fixed to the flange 202B. A coil 206 surrounding the permanent magnet 203 is fixed to the lower surface of the diaphragm 205.

  A space inside the casing 201 is divided into two hollow regions by the diaphragm 205. Of the two hollow regions separated by the diaphragm 205, the hollow region on the side where the permanent magnet 203 is located (in FIG. 4, the hollow region below the diaphragm 205) constitutes the back cavity 212. The hollow region on the non-side (the hollow region above the diaphragm 205 in FIG. 4) constitutes the front cavity 211.

  In such a configuration, a current corresponding to an audio signal supplied from the control main body 11 in FIG. 1 via the cable 13L or 13R flows through the coil 206. Since this current is linked to the magnetic flux flowing through the magnetic circuit composed of the permanent magnet 203 and the tray 202, the coil 206 is driven in the Y-axis direction. As a result, the diaphragm 205 is driven according to the audio signal from the control main body 11 and vibrates in the Y-axis direction.

  Inside the cylindrical portion 201B of the housing 201 is a columnar hollow region that forms part of the front cavity 211, and a microphone 122 (corresponding to the microphones 122L and 122R in FIG. 2) is fixed thereto. The microphone 122 is fixed to the inner wall surface of the cylindrical portion 201 </ b> B with its directional axis directed toward the opening 221 of the earpiece 220.

Sound in the ear canal enters the tube portion 201B from the opening 221 of the earpiece 220, propagates along the inner wall of the tube portion 201B, and is collected by the microphone 122. The microphone 122 generates an analog audio signal corresponding to the sound pressure of the sound propagating through the cylinder portion 201B as described above, and supplies the analog audio signal to the control main body portion 11 via the cable 13L or 13R in FIG.
The above is the configuration of the earphones 12L and 12R with microphone.

  Next, the configuration of the control main body 11 will be described with reference to FIG. 2 again. When the power supply voltage is supplied from the sound reproducing device 20 via the cable 14, the automatic power supply switching unit 101 supplies the power supply voltage to each part in the control main body 11, and the power supply voltage is supplied via the cable 14. If not, the power supply voltage from the battery 102 built in the control main body 11 is supplied to each part in the control main body 11. The analog audio input unit 103 is a circuit that supplies the left and right two-channel audio signals AL1 and AR1 supplied from the sound reproduction device 20 via the cable 14 to the level adjustment unit 111 and also to the A / D conversion unit 104. is there. The amplifier 105 amplifies the L channel audio signal from the microphone 122L of the microphone with earphone 12L and the R channel audio signal from the microphone 122R of the earphone with microphone 12R, respectively, and the amplified audio signals AL2 and AR2 are A / D. This is a circuit supplied to the conversion unit 104. The A / D conversion unit 104 samples the analog audio signals AL1 and AR1 supplied from the analog audio input unit 103 and the analog audio signals AL2 and AR2 supplied from the amplifier 105 at regular sampling periods. And output as digital audio signals DL1, DR1, DL2, and DR2, respectively.

  The signal processing unit 112 is configured by a DSP (Digital Signal Processor) or the like. The signal processing unit 112 is supplied with digital audio signals DL 1, DR 1, DL 2, and DR 2 from the A / D conversion unit 104 by one sample for each sampling period. The signal processing unit 112 includes four first-in first-out buffers each capable of storing a predetermined number of samples, and each of the digital audio signals DL1, DR1, DL2, DR2 supplied from the A / D conversion unit 104 A predetermined number of samples are held in these four buffers. Here, the digital audio signals DL1 and DR1 are signals respectively indicating sound pressures of sounds to be output from the drivers 121L and 121R in the spaces in the external auditory canals of the user's left and right ears. Further, the digital audio signals DL2 and DR2 are signals respectively indicating sound pressures of sounds collected by the microphones 122L and 122R from the spaces in the external auditory canals of the user's left ear and right ear.

  The signal processing unit 112, for example, an LPF (Low Pass Filter) that passes only a low frequency component of, for example, 100 Hz or less to the sample sequence of the audio signal DL1 held in the buffer every time an interval time of 500 ms elapses, for example. (Pass filter) processing is performed, and the amplitude envelope of the audio signal subjected to the LPF processing is detected. The signal processing unit 112 also performs similar LPF processing and amplitude envelope detection processing on the audio signal DL2.

Then, the signal processing unit 112 calculates the latter attenuation amount GL (dB from the former) from the average amplitude value VDL1 of the amplitude envelope obtained from the audio signal DL1 and the average amplitude value VDL2 of the amplitude envelope obtained from the audio signal DL2. ) = 20log ₁₀ (VDL2 / VDL1) is calculated. The amount of attenuation GL corresponds to the size of the gap between the earpiece 220 and the user's ear canal in the acoustic transmission system from the front cavity 221 of the earphone housing 201 to the ear canal and the degree of sound leakage according to the size of the gap. Corresponding. Similarly, the signal processing unit 112 uses the audio signals DR1 and DR2 to calculate the latter low-frequency attenuation GR with respect to the former.

The control unit 113 forms a control center of the control main body unit 11, for example, a CPU (Central
Processing Unit (Central Processing Unit) and ROM (Read that stores the control program executed by this CPU)
Only memory (read-only memory) and RAM (Random) used as a work area for the CPU
Access Memory (random access memory). The control unit 113 controls the display of the degree of sound leakage by the sound leakage indicator 114 provided in the housing of the control main body unit 11, and controls the operation state and signals of the operator group 115 provided in the housing. Based on the attenuation amounts GL and GR calculated by the processing unit 112, each unit in the control main body unit 11 is controlled.

  FIG. 5 is a diagram showing a sound leakage indicator 114 and an operator group 115 provided in the housing of the control main body 11. The sound leakage indicator 114 is a display for displaying the degree of sound leakage of the microphone-equipped earphones 12L and 12R, and includes, for example, an LED (Light Emitting Diode). In addition to the sound leakage indicator 114, the housing is provided with a sound leakage control mode changeover switch 115a, a reproduction / pause changeover switch 115b, and an output volume 115c as an operator group 115. On the back side of the sound leakage control mode change-over switch 115a and the reproduction / pause change-over switch 115b, LEDs that can visually recognize the light emission state are embedded through the switches.

  The control unit 113 in the present embodiment has an automatic mode and a manual mode as sound leakage control modes. Details of the automatic mode and the manual mode will be described later. When an ON event of the sound leakage control mode switching switch 115a occurs in the manual mode, the control unit 113 switches the sound leakage control mode from the manual mode to the automatic mode, and turns on the LED on the back side of the sound leakage control mode switching switch 115a. Further, when an ON event of the sound leakage control mode switching switch 115a occurs in the automatic mode, the control unit 113 switches the sound leakage control mode from the automatic mode to the manual mode, and turns off the LED behind the sound leakage control mode switching switch 115a. Let

  The reproduction / pause changeover switch 115b changes the operation state of the sound reproduction device 20 to a reproduction state in which an audio signal is reproduced from the storage medium and supplied to the control main body unit 11, or the audio signal is reproduced from the storage medium. This is a switch for instructing whether or not to make a temporary stop state. If an ON event of the playback / pause switching switch 115b occurs when the sound playback device 20 is in a paused state, the control unit 113 sends a playback start command via the cable 14 to place the sound playback unit 20 in a playback state. Then, the LED on the back side of the reproduction / pause switching switch 115b is turned on. In addition, when an ON event of the playback / pause switching switch 115b occurs when the sound playback device 20 is in a playback state, the control unit 113 sends a pause command via the cable 14 to pause the sound playback unit 20. The LED on the back side of the playback / pause switch 115b is turned off.

  The control unit 113 generates sound leakage data indicating the degree of sound leakage based on the attenuation amounts GL and GR calculated by the signal processing unit 112. In a preferable aspect, the control unit 113 converts a larger one of the absolute values of the attenuation amounts GL and GR into sound leakage data using a conversion table stored in advance. The conversion table in this case may be created based on the result of obtaining the relationship between the attenuation GL or GR and the volume of the sound leaking outside the ear, for example, by simulation or measurement. In another preferred embodiment, the control unit 113 sets sound leakage data that is obtained by multiplying the larger one of the absolute values of the attenuation amounts GL and GR by a predetermined constant. In another preferable aspect, the control unit 113 sets the larger one of the absolute values of the attenuation amounts GL and GR as sound leakage data. As described above, the attenuation amounts GL and GR are calculated by the signal processing unit 112 every time an interval time of, for example, 500 ms elapses. Therefore, every time the interval time elapses, the sound leakage data is updated by the control unit 113.

  In addition, the control unit 113 controls blinking of the sound leakage indicator 114. FIG. 6 is a diagram showing the manner of blinking control of the sound leakage indicator 114. In FIG. When the sound leakage data is less than the first threshold th1, the control unit 113 determines that no sound leakage has occurred in the earphones 12L and 12R with microphone, and turns off the sound leakage indicator 114. When the sound leakage data is equal to or greater than the first threshold th1 and less than the second threshold th2 (> th1), the control unit 113 causes a small sound leakage to occur in the earphone with microphone 12L or 12R. The sound leakage indicator 114 is blinked at a low speed. Further, when the sound leakage data is equal to or greater than the second threshold th2 and less than the third threshold th3 (> th2), the control unit 113 causes a moderate sound leakage to the earphone with microphone 12L or 12R. The sound leakage indicator 114 is flashed at medium speed. If the sound leakage data is greater than or equal to the third threshold th3, the control unit 113 determines that a large amount of sound leakage has occurred in the earphone with microphone 12L or 12R, and blinks the sound leakage indicator 114 at high speed. Let The user can confirm the degree of sound leakage occurring in the earphones 12L and 12R with microphone based on such blinking of the sound leakage indicator 114. Then, the user who has confirmed the sound leakage can push the earphones 12L and 12R with microphones deeply into his / her ear so that there is no sound leakage.

  Further, the control unit 113 uses the level adjustment unit 111 to adjust the levels of the audio signals AL1 and AR1 for preventing sound leakage. Here, the level adjustment unit 111 is configured to be capable of two types of level adjustments. In the first level adjustment, the audio signals AL1 and AR1 are amplified with a uniform gain designated by the control unit 113 through the entire frequency band, and output as audio signals AL3 and AR3. In the second level adjustment, the following processing is performed for each of the audio signals AL1 and AR1. That is, the original audio signal (for example, audio signal AL1) is divided into a low frequency component of 100 Hz or less and a high frequency component of 100 Hz or more, for example, and only the high frequency component is attenuated by the attenuation amount specified by the control unit 113. Then, the high-frequency component that has undergone the attenuation processing and the low-frequency component obtained from the original audio signal are added, and the addition result is output as the audio signal AL3. Audio signals AL3 and AR3 obtained by such level adjustment are supplied to drivers 121L and 121R through cables 13L and 13R, respectively.

  Which level adjustment the control unit 113 causes the level adjustment unit 111 to perform differs depending on whether the sound leakage control mode is the manual mode or the automatic mode. In the manual mode, the control unit 113 instructs the level adjustment unit 111 to perform the first level adjustment, and causes the audio signals AL1 and AR1 to be amplified with a gain corresponding to the rotation angle of the output volume 115c. On the other hand, in the automatic mode, the control unit 113 instructs the level adjustment unit 111 to perform the second level adjustment. Further, the control unit 113 controls the amount of attenuation instructed to the level adjusting unit 111 according to the sound leakage data, and increases the amount of attenuation given to the high frequency components of the audio signals AL1 and AR1 as the sound leakage data increases. .

In the automatic mode, only the high frequency components of the audio signals AL1 and AR1 are attenuated in accordance with an increase in sound leakage data for the following two reasons. First, in a situation where sound leakage occurs, the sound pressure of the low frequency component of the sound output into the ear canal is reduced. Therefore, if the components in the entire band of the audio signals AL1 and AR1 are uniformly attenuated, This is because the low frequency sound cannot be heard. Secondly, it is the high frequency component of the leaking sound that gives the surrounding people a noisy feeling due to the sound leakage.
The above is the details of the sound reproduction control device 10 according to the present embodiment.

  According to the present embodiment, when the gap between the earpiece 220 of at least one of the earphones 12L or 12R with the microphone (for example, the earphone with microphone 12L) and the user's ear canal becomes large and sound leakage occurs, the audio signal AL1 indicates. The absolute value of the attenuation GL in the low frequency range of the sound indicated by the audio signal AL2 with respect to the sound becomes large. The control unit 113 generates sound leakage data based on the attenuation amount GL, and the sound leakage indicator 114 notifies the degree of sound leakage indicated by the sound leakage data. Therefore, the user can know the degree of sound leakage by using this sound leakage indicator 114, and presses each earpiece 220 of the earphone 12L or 12R with microphone into the ear, or in the manual mode, the output volume is reduced by operating the output volume 115c. Such an operation can prevent sound leakage. In the situation where the automatic mode is selected, the high frequency levels of the audio signals AL1 and AR1 from the sound reproducing device 20 are attenuated in accordance with the increase in the sound leakage data, and the audio signal AL3 and AR3 is supplied to drivers 121L and 121R of earphone with microphone 12L or 12R, respectively. Therefore, the high-frequency sound that gives a noisy feeling to surrounding people due to sound leakage is attenuated, and the adverse effects of sound leakage can be prevented.

Second Embodiment
FIG. 7 is a diagram showing the contents of attenuation amount GL and GR calculation processing performed by the signal processing unit 112 in the sound reproduction control apparatus according to the second embodiment of the present invention. The present embodiment is an improvement of the calculation processing of the attenuation amounts GL and GR in the first embodiment.

  Similar to the first embodiment, the signal processing unit 112 in this embodiment includes a first-in first-out buffer that holds a predetermined number of samples of the audio signals DL1, DR1, DL2, and DR2. For example, every time an interval time of 100 ms elapses, the signal processing unit 112 performs FFT (Fast Fourier Transform) on the sample sequence of the audio signal DL1 held in the buffer, and the amplitude spectrum of the audio signal DL1 P1 (f) is calculated. The signal processing unit 112 also performs similar FFT on the sample sequence of the audio signal DL2, and calculates the amplitude spectrum P2 (f) of the audio signal DL2.

  Then, the signal processing unit 112 obtains a ratio P2 (f) / P1 (f) of the amplitude spectrum P2 (f) with respect to the amplitude spectrum P1 (f), and a frequency with respect to the ratio P2 (f) / P1 (f). The attenuation amount GL is calculated by multiplying the weighting factor W (f) depending on f and adding the multiplication results. The amount of attenuation GL corresponds to the size of the gap between the earpiece 220 and the user's ear canal in the acoustic transmission system from the front cavity 221 of the earphone housing 201 to the ear canal and the degree of sound leakage according to the size of the gap. Corresponding. Here, the weighting factor W (f) becomes maximum at a predetermined frequency in a low frequency range of, for example, 100 Hz or less, and decreases as the frequency moves away from the low frequency side and the high frequency side. Similarly, the signal processing unit 112 uses the audio signals DR1 and DR2 to calculate the attenuation amount GR by a calculation method similar to the calculation of the attenuation amount GL.

  According to the present embodiment, the attenuation amounts GL and GR that more accurately represent the degree of attenuation of the audio signal DL2 (DR2) in the low frequency with respect to the audio signal DL1 (DR1) compared to the first embodiment. Can be calculated. Other points are the same as in the first embodiment.

<Other embodiments>
Although the first and second embodiments of the present invention have been described above, other embodiments can be considered in addition to this. For example:

(1) In each of the above embodiments, the present invention is applied to prevent the sound leakage of the earphone, but the present invention can also be applied to prevent the sound leakage of the headphones. When the present invention is applied to headphones, a microphone serving as an acoustic / electrical converter is provided at a position near the concha ear in the earpad while the headphones are attached to the ear, and an output signal of the microphone The above-described attenuation amounts GL and GR may be calculated using the input signal to the speaker serving as the electrical / acoustic conversion unit of the headphones, and sound leakage may be detected.

(2) Even when the earphone is in close contact with the ear canal without a gap, some amount of attenuation GL and GR is generated, and the magnitude of the amount of attenuation depends on the shape of the ear canal and the like. For this reason, it is considered that there are individual differences in the magnitudes of the attenuation amounts GL and GR when no sound leakage occurs. Therefore, in consideration of this point, the attenuation amounts GL and GR calculated in a state where the earphone is worn without gaps in the ear are stored as reference values, and thereafter, the difference between the calculated attenuation amounts GL and GR and the reference value is stored. Sound leakage data may be generated based on this. Alternatively, each time the attenuation amounts GL and GR are calculated in the sound reproduction control device, a comparison is made with the minimum attenuation value so far, and if an attenuation amount that is less than the minimum value is calculated, the attenuation amount is calculated. To repeat the process of updating the minimum value. The minimum value updated in this way may be used as a reference value, and sound leakage data may be generated based on the difference between the attenuation amounts GL and GR and the reference value.

(3) In the first embodiment, the audio signals AL1, AR1, AL2, and AR2 are converted into digital audio signals DL1, DR1, DL2, and DR2, and the attenuation amounts GL and GR are obtained by digital signal processing using these signals. Calculated. However, instead of doing so, analog signals indicating attenuations GL and GR are generated from the audio signals AL1, AR1, AL2, and AR2 by an analog circuit, and the sound leakage notification and audio are generated based on the analog signals. The levels of the signals AL1 and AR1 may be adjusted.

(4) In each of the above embodiments, the audio signals AL1 and AR1 that are input signals to the electrical / acoustic conversion unit are used as a reference, and the audio signals AL2 and AR2 that are output signals of the acoustic / electrical conversion unit are compared with the reference in the frequency domain. By doing so, sound leakage data indicating the degree of sound leakage was generated. This is because the spectral distributions of the audio signals AL1 and AR1 change from moment to moment, and unless this is used as a reference, there is a gap between the earphone and the ear canal, so the sound pressure of the audio signals AL2 and AR2 is attenuated. This is because it cannot be distinguished whether the sound pressure in the low frequency range of the audio signals AL1 and AR1 itself is attenuated.

  However, it is considered rare that the sound pressures of the audio signals AL1 and AR1 themselves are attenuated over a long period of time. Therefore, sound leakage data may be generated as follows. For example, audio signals AL2 and AR2 that are output signals of the acoustic / electrical converter are divided into frames having a fixed time length, and the spectral distribution of the audio signals AL2 and AR2 is obtained for each frame. Then, based on the spectral distribution of the audio signals AL2 and AR2 obtained for each frame, a frame (for example, spectral intensity over the entire band) estimated that the electrical / acoustic conversion unit outputs a sound having a volume higher than a threshold value. Frames for which the sum of the two is equal to or greater than the threshold value), and for these frames, the ratio Pa / Pb of the spectral intensity Pa of the low band (for example, 100 Hz) and the spectral intensity Pb of the high band (for example, 1000 Hz) is determined. Then, sound leakage data indicating the degree of sound leakage is generated based on, for example, a moving average of the spectrum intensity ratio Pa / Pb. As described above, the degree of sound leakage may be obtained by comparing the spectral intensities of the audio signals AL2 and AR2 in the high frequencies and comparing the reference with the spectral intensities of the audio signals AL2 and AR2 in the low frequencies.

(5) When the user listens to music, the user usually pushes the earpiece sufficiently into the ear canal at first. Therefore, the user starts listening to music from an initial state where there is no sound leakage. Therefore, even if the degree of sound leakage is not calculated, if it is detected and notified that the sound leakage state has changed to a state where sound leakage has occurred, it is possible to prevent the sound leakage from being left unattended. It is considered possible. Therefore, the following may be performed.

  Similarly to the above aspect (4), each of the audio signals AL2 and AR2 is divided into frames to obtain a spectrum distribution, and the electric / acoustic conversion unit sets a threshold based on the spectrum distribution of the audio signals AL2 and AR2 obtained for each frame. Frames that are estimated to output sound having the above volume are obtained, and for these frames, a spectrum intensity Pa in a low frequency (for example, 100 Hz) is obtained. Then, for example, the average value of the spectral intensity Pa within a predetermined time after the user pushes the earpiece into the ear canal and starts listening to music, and the average value is multiplied by a predetermined coefficient smaller than 1 to obtain a threshold value. Ask for. Thereafter, a moving average of the spectrum intensity Pa for each frame is obtained, and when this moving average falls below a threshold value, it is determined that sound leakage has started. As a method for detecting that the user has started listening to music, for example, a pressure sensor that detects pressure applied to the earpiece is provided, and the earpiece is in a state where the sound reproducing device 20 is reproducing the audio signals AL1 and AR1. A method may be considered in which the user starts listening to music when the applied pressure increases or when the sound reproducing device 20 starts reproducing the audio signals AL1 and AR1 after the pressure applied to the earpiece increases.

(6) In the first embodiment, in the manual mode, the level is uniformly adjusted over the entire frequency band of the audio signals AL1 and AR1 according to the operation of the output volume 115c. However, instead of doing so, the level adjustment of only the high frequencies of the audio signals AL1 and AR1 may be performed according to the operation of the output volume 115c.

(7) In the first embodiment, the control unit 113 instructs the level adjustment unit 111 to perform the second level adjustment in the automatic mode, and sets the attenuation amount to be instructed to the level adjustment unit 111 according to the sound leakage data. As the sound leakage data is increased, the amount of attenuation given to the high frequency components of the audio signals AL1 and AR1 is increased. However, the intensity of the audio signals AL1 and AR1 may be involved in the determination of the attenuation amount. More specifically, only when the volume of at least one of the audio signals AL1 and AR1, which are input signals to the electrical / acoustic conversion unit, is equal to or higher than a predetermined threshold value, the high level of the audio signals AL1 and AR1 depends on the sound leakage data. The amount of attenuation given to the band component is increased, and if not, attenuation is not given to the high band component of the audio signals AL1 and AR1. According to this aspect, sound leakage data is only included in a situation where the volume of sound that leaks when the volume of at least one of the audio signals AL1 and AR1 is large and a gap is generated between the earpiece 220 and the user's ear canal can increase. In response, attenuation processing of the high frequency components of the audio signals AL1 and AR1 is performed. Therefore, it is possible to avoid unnecessary attenuation of the high frequency components of the audio signals AL1 and AR1, and to appropriately prevent sound leakage.

(8) In the first embodiment, in the automatic mode, the level adjustment unit 111 gives the attenuation amount corresponding to the sound leakage data only to the high frequency components of the audio signals AL1 and AR1, but the audio signals AL1 and AR1 An attenuation amount corresponding to sound leakage data may be given uniformly over the entire band.

(9) In the first embodiment, in the manual mode, the level adjustment unit 111 gives the audio signals AL1 and AR1 a uniform attenuation amount in accordance with the operation amount of the output volume 1150. In the automatic mode, the level adjustment unit In 111, an attenuation amount corresponding to the sound leakage data is given only to the high frequency components of the audio signals AL1 and AR1. However, a circuit that attenuates only the high frequency components of the input signal as the level adjusting unit 111 may be used so that only the high frequency components of the audio signals AL1 and AR1 are attenuated in both the manual mode and the automatic mode. Good.

(10) The sound leakage data in each of the above embodiments indicates the size of the gap between the earpiece and the ear canal. The volume of sound that actually leaks to the outside of the ear depends on the size of the gap and the electrical / acoustic sound. It is determined by the product of the volume of the input signal to the converter. Therefore, the control main body 11 generates sound leak amount data obtained by multiplying the sound leak data in each of the above embodiments by the volume of the input signal to the electric / acoustic converter, and uses it instead of the sound leak data described above. May be. Alternatively, the sound leakage data of each of the above embodiments may be used to display the degree of sound leakage, and the sound leakage amount data may be used to adjust the level of the input signal to the electrical / acoustic conversion unit. Conversely, the sound leakage data of the above embodiments may be used for level adjustment of the input signal to the electric / acoustic conversion unit, and the sound leakage amount data may be used for displaying the degree of sound leakage.

DESCRIPTION OF SYMBOLS 10 ... Sound reproduction control apparatus, 11 ... Control main-body part, 12L, 12R ... Earphone with a microphone, 13L, 13R, 14 ... Cable, 14j ... Mini jack, 20 ... Sound reproduction apparatus, 101 ... Power supply automatic switching part, 102 ... Battery 103 ... Analog audio input unit 104 ... A / D conversion unit 105 ... Amplifier 111 ... Level adjustment unit 112 ... Signal processing unit 113 ... Control unit 114 ... Sound leakage indicator 115 ... Operator group 115a ... Sound leakage control mode changeover switch, 115b ... Playback / pause changeover switch, 115c ... Output volume.

Claims (5)

An electrical / acoustic conversion unit and an acoustic / electrical conversion unit are provided. In the state where the electrical / acoustic conversion unit is attached to the ear, the electrical / acoustic conversion unit outputs sound to a space in the ear canal, and the acoustic / electrical conversion unit outputs the sound. In the sound reproduction control device that controls the operation of the sound input / output device that picks up the sound inside,
Sound collected by the acoustic / electrical converter based on the sound indicated by the input signal to the electrical / acoustic converter based on the input signal to the electrical / acoustic converter and the output signal of the acoustic / electrical converter Signal processing means for calculating the attenuation in the low frequency range of
Control means for generating sound leakage data indicating the degree of sound leakage outside the ear canal of sound output from the electrical / acoustic converter of the acoustic input / output device based on the attenuation calculated by the signal processing means sound reproduction control apparatus characterized by comprising and. The signal processing means calculates the attenuation amount from the amplitude envelope of the low frequency component of the input signal to the electrical / acoustic conversion unit and the amplitude envelope of the low frequency component of the output signal of the acoustic / electrical conversion unit. The sound reproduction control device according to claim 1. An electrical / acoustic conversion unit and an acoustic / electrical conversion unit are provided. In the state where the electrical / acoustic conversion unit is attached to the ear, the electrical / acoustic conversion unit outputs sound to a space in the ear canal, and the acoustic / electrical conversion unit outputs the sound. In the sound reproduction control device that controls the operation of the sound input / output device that picks up the sound inside,
The low-frequency spectrum intensity and the high-frequency spectrum intensity of the output signal of the acoustic / electrical converter are compared, and based on the comparison result, the sound output from the electrical / acoustic converter of the acoustic input / output device A sound reproduction control apparatus comprising: control means for generating sound leakage data indicating a degree of sound leakage outside the ear canal. Comprising level adjusting means for adjusting the level of an input signal to the electrical / acoustic converter;
The said control means reduces the level of the input signal with respect to the said electrical / acoustic conversion part according to the said sound leakage data by the said level adjustment means, The claim of any one of Claims 1-3 characterized by the above-mentioned. The sound reproduction control device described. The control means reduces the level of the input signal to the electric / acoustic conversion unit according to the sound leakage data by the level adjusting means only when the volume of the input signal to the electric / acoustic conversion unit exceeds a threshold value. The sound reproduction control device according to claim 4, wherein:

Images