JP2018164209A - Acoustic equipment, acoustic equipment control method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an acoustic equipment, acoustic equipment control method and program, capable of more effectively reducing power consumption while maintaining ease of hearing sound.SOLUTION: The present invention comprises: a speaker 5 for outputting sound on the basis of output sound data; a setting part 711 for setting acoustic characteristics relating to sound production from the speaker 5; a battery residual detection circuit 62 for detecting a battery residue amount; and an adjustment processing part 713 for adjusting the acoustic characteristics set by the setting part 711 on the basis of a detection result detected by the battery residue amount detection circuit 62.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an audio device represented by a hearing aid, an audio device control method, and a program.

Conventionally, portable small-sized audio equipment such as hearing aids are not assumed to be used with a power supply from an external power source connected to a cable, and are driven by a built-in battery or a small battery. For this reason, it is desired to save power as much as possible and to have a remaining battery level.
In this regard, Patent Document 1 discloses a technique for lowering the gain of audio output in a hearing aid when the remaining battery level is low.
According to such a technique, power consumption can be suppressed when the remaining battery level is low, and the remaining battery level can be extended.

JP 2010-212833 A

  However, the hearing aid described in Patent Document 1 has a problem that, when the remaining battery level is low, the common gain is lowered for all frequencies, so that it is difficult to hear sound.

  The present invention has been made in view of the circumstances as described above, and an acoustic device, an acoustic device control method, and a program that can reduce power consumption more effectively while maintaining ease of hearing a sound. Is intended to provide.

In order to solve the above-described problem, an audio device according to the present invention includes:
A sound generator that outputs sound based on output sound data;
A setting unit for setting an acoustic characteristic related to the sound generation from the sound generation unit;
A battery level detector for detecting the remaining battery level;
An adjustment processing unit for adjusting an acoustic characteristic set by the setting unit based on a detection result detected by the battery remaining amount detection unit;
It is characterized by having.

  According to the present invention, it is possible to more effectively reduce power consumption while maintaining ease of hearing sounds.

It is a principal part external appearance perspective view of the hearing aid which is an audio equipment in this embodiment. It is the principal part block diagram which showed the control structure of the hearing aid which is an audio equipment in this embodiment. It is explanatory drawing which shows the image of an auditory optimization process. It is a graph which shows the relationship between a frequency and the power consumption required for correction | amendment of a frequency characteristic. It is a flowchart which shows the sound output process of the audio equipment in this embodiment. It is a flowchart which shows the auditory optimization process in this embodiment. It is a flowchart which shows the power saving process in this embodiment.

An embodiment of an acoustic device according to the present invention will be described with reference to FIGS. In this embodiment, although the case where an audio equipment is a hearing aid is illustrated, an audio equipment is not limited to a hearing aid.
The embodiments described below are given various technically preferable limitations for carrying out the present invention, but the scope of the present invention is not limited to the following embodiments and illustrated examples.

《Configuration of hearing aid as an acoustic device》
FIG. 1 is an external perspective view of an essential part showing a schematic configuration of a hearing aid which is an acoustic device in the present embodiment. FIG. 2 is a principal block diagram showing a control configuration of the hearing aid in the present embodiment.
As shown in FIG. 1, the hearing aid 1 of the present embodiment is an ear hook type, a hearing aid main body 2, an earphone-type speaker 5 connected to the hearing aid main body 2 via an arm portion 3, and a microphone. 4 etc.
The hearing aid main body 2 is provided with a hearing optimization test start switch 21, an answer switch 23, a volume adjustment unit 24, a power switch 25, and the like.

The microphone 4 is a sound wave input unit that collects sound waves (sound data) from the outside and inputs them to the control device.
In the present embodiment, the microphone 4 is provided at a position where the microphone 4 is arranged near the user's ear hole when the user wears the hearing aid 1.
As shown in FIG. 2, the microphone 4 is connected to the control device 7 via a microphone preamplifier 41. The analog circuit can be stabilized through the microphone preamplifier 41. Note that providing the microphone preamplifier 41 is not essential.
The speaker 5 is a sound generator that outputs sound based on output sound data.
As shown in FIG. 2, the speaker 5 is connected to the control device 7 via a speaker amplifier 51, and outputs sound according to control of a sound output control unit 712 described later.
In the present embodiment, the speaker 5 is inserted into the user's ear hole when the hearing aid 1 is worn by the user.

The auditory optimization test start switch 21 is a switch for starting an auditory optimization test described later.
As shown in FIG. 2, the hearing optimization test start switch 21 is connected to the control device 7, and the hearing optimization test by the setting unit 711 is started by pressing the hearing optimization test start switch 21. .
The answer switch 23 is a response input unit that outputs a response signal associated with the input operation when a user operation is input. In this embodiment, the user inputs an answer in the hearing optimization test.
In this embodiment, the voice guide prompts the user to perform a switch operation in the case of “OK” or “YES”. When the answer switch 23 is pressed by the user, the control unit 71 A signal to that effect is input to the setting unit 711.
In the answer switch 23, different response signals may be associated with the long press operation and the short press operation of the switch. In this case, various operation inputs can be performed while reducing the number of switches and simplifying the apparatus configuration.

The volume adjusting unit 24 inputs a volume up or volume down instruction signal to the control unit 71 according to the position to be pressed, for example. When an instruction signal is input from the volume adjustment unit 24, the sound output control unit 712 performs volume control of sound output from the speaker 5 in accordance with the instruction signal.
The power switch 25 is for switching on / off the power supply of the hearing aid 1 by a pressing operation. When the power switch 25 is operated, the operation signal is sent to the control device 7 via the power circuit 61, and the controller 71 performs power ON / OFF control.
In addition, inside the hearing aid main body 2, a battery 6 (for example, a button battery) constituting a power supply unit that supplies power to each part of the hearing aid 1 and a circuit board 26 on which various electronic components are mounted are arranged.

In the present embodiment, a battery remaining amount detection circuit 62 is provided on a power supply path from the battery 6 constituting the power supply unit.
The remaining battery level detection circuit 62 is a remaining battery level detection unit that detects the remaining battery level of the battery 6 by detecting a voltage on the power feeding path, for example. The detection result (detection voltage) by the remaining battery level detection circuit 62 is output to the adjustment processing unit 713 of the control device 7.
The detection of the remaining battery level by the remaining battery level detection circuit 62 may be performed at any time, or may be performed at a timing when the power is turned on, at every predetermined time interval, or the like.
Note that the configuration of the remaining battery level detection unit that detects the remaining battery level of the battery 6 is not limited to that illustrated here. Further, the method of detecting the remaining battery level of the battery 6 by the battery remaining amount detection unit is not limited to the example illustrated here, and various methods can be used.

In the present embodiment, the control device 7 is a computer of the hearing aid 1 configured by, for example, an LSI or the like.
The control device 7, the power supply circuit 61 and the remaining battery level detection circuit 62 are mounted on a circuit board 26 provided in the hearing aid body 2, for example.
As shown in FIG. 2, the hearing aid 1 includes a control device 7 having a control unit 71 and a storage unit 72.
The control device 7 is provided with a digital filter (hereinafter referred to as “DSP 73”) and the like. Examples of the DSP 73 provided in the control device 7 include a band-pass filter, a high-pass filter, a low-pass filter, a shelving filter, a graphic equalizer, a parametric equalizer, and the like. In addition, DSP73 provided in the control apparatus 7 is not limited to what was illustrated here, Various filters can be used.

The storage unit 72 stores information necessary for the control unit 71 to realize various functions.
As shown in FIG. 2, the storage unit 72 includes a program storage unit 720 that stores programs such as an auditory optimization program 722 and a power saving processing program 727 in addition to a system program 721 for overall control of the hearing aid 1. I have.
The storage unit 72 stores data necessary for the control unit 71 to perform various processes.
For example, the storage unit 72 of the present embodiment stores various types of sound data. Specifically, the storage unit 72 includes an instruction voice data storage area 724 for storing instruction voice data, and a test sound source data storage area 725 for storing test sound source data. The instruction voice data storage area 724 and the test sound source data storage area 725 are integrated in an LSI or the like constituting the control device 7 as a waveform ROM, for example.

The instruction voice data stored in the instruction voice data storage area 724 is instruction voice data for guiding the user in the auditory optimization test performed in the present embodiment.
In the present embodiment, since the instruction voice data is provided and the user is guided by voice, the user does not get lost in operation and does not need to include a display unit. Can do.
The test sound source data stored in the test sound source data storage area 725 is sound data output for the test in the auditory optimization test.
In this embodiment, a sound having a frequency belonging to a general human audible sound range is stored as test sound source data. For example, the frequencies are 100 hz, 300 hz, 500 hz, 1000 hz, 3000 hz, 5000 hz, 8000 hz, 12000 hz, 14000 hz, and the like. Are available. Note that the test sound source data is not limited to that exemplified here.

The storage unit 72 includes an optimization information storage area 726 for storing optimization information.
The optimization information stored in the optimization information storage area 726 is user-specific information obtained as a result of performing an auditory optimization test on the user, and is the minimum information that the user can hear for each frequency. Data indicating the volume. The optimization information can be rewritten and updated when a new result is obtained by performing the above test.

  The control unit 71 is configured by a processing IC such as a CPU. In the present embodiment, the control unit 71 functions as a setting unit 711, a sound output control unit 712, and an adjustment processing unit 713. The functions of the control unit 71 as the setting unit 711, the sound output control unit 712, and the adjustment processing unit 713 are the cooperation of the CPU and the like of the control unit 71 and various programs stored in the program storage unit 720 of the storage unit 72. It is realized by doing.

The setting unit 711 outputs a test sound based on test output sound data that arbitrarily designates at least one of frequency and volume from the speaker 5, and when the test sound is generated from the speaker 5. The user's auditory characteristics relating to at least one of frequency and volume are determined according to the response signal from the answer switch 23, and the acoustic characteristics relating to the sound output from the speaker 5 are set based on the auditory characteristics. The acoustic characteristics include various contents, but in the present embodiment, a case where the frequency characteristics are set is illustrated.
Here, the setting of the frequency characteristics related to the sound generation from the speaker 5 which is the sound generation unit means that the signal input to the hearing aid 1 is subjected to signal processing for increasing the gain to a level that is easy for the user to hear for each frequency. .
Hereinafter, setting of acoustic characteristics by the setting unit 711 (that is, setting of frequency characteristics in the present embodiment) will be specifically described.

Specifically, the setting unit 711 performs an auditory optimization test, acquires information about the level of the volume that can be heard by the user for an arbitrary frequency, and based on this, it is difficult for the user to hear For the frequency, a hearing aid process is performed to increase the gain to make it easier to hear.
FIG. 3 is an explanatory diagram showing an image of auditory optimization processing. In FIG. 3, the top horizontal line (broken line) indicates a case where hearing is at a normal level, and shows a substantially flat gain at each frequency. On the other hand, the curves shown in FIG. 3 show the gain at each frequency of people in their 40s, 50s, and 70s from the top, and the higher the frequency, the lower the gain and the lower the hearing. Show.
In this way, as people get older, it becomes more difficult to hear high-frequency sounds, and the gain decreases. For example, in the curve shown as an example of the 70's, the gain is greatly reduced as compared with a normal hearing person. In this case, in order to realize a hearing level similar to that of a normal hearing person, it is necessary to adjust the gain to be increased by the amount indicated by the upward arrow for each frequency. The adjustment method for increasing the gain is not particularly limited. For example, a gain based on the user's auditory characteristics is set in the DSP 73 such as a shelving filter, and the necessary amount at each frequency (that is, the amount indicated by the arrow in FIG. 3). Only) Boost the gain.
Specifically, for example, if the user's hearing level is 3 dB at a frequency of 1000 hz, the setting unit 711 increases the gain of the hearing aid 1 at the frequency of 1000 hz to 3 dB. Further, for example, when the frequency is 14000 hz and 20 dB, the gain of the DSP 73 such as a shelving filter is adjusted so that the gain at the frequency of 14000 hz is 20 dB (setting of frequency characteristics related to sound generation from the speaker 5 as the sound generation unit).
In this way, by adjusting the gain of the DSP 73 such as the shelving filter of each frequency and setting it as a value optimized for the user, a flat sound level for the user can be provided.

  The sound output control unit 712 controls sound output from the speaker 5 which is a sound generation unit. Specifically, the sound output control unit 712 applies a filter or the like set by the setting unit 711 corresponding to the user's auditory characteristics, and causes the speaker 5 to output sound according to the user's auditory characteristics.

The adjustment processing unit 713 adjusts at least one of the range and degree of frequency characteristic correction (hearing process) by the setting unit 711 according to the remaining battery level of the battery 6 detected by the remaining battery level detection circuit 62. It is.
FIG. 4 is a graph showing the relationship between frequency and power consumption required for frequency characteristic correction (hearing process). In FIG. 4, a solid line that draws a curve indicates the power consumption required for correcting the frequency characteristics.
As shown in FIG. 4, the audible region in which a person can generally hear a sound is about 20 Hz to 20000 Hz, of which 20 Hz to 200 Hz is a low frequency band (hereinafter referred to as “low range”), and 201 Hz to 2000 Hz is the middle. When frequency frequency correction (hearing process) performed in the setting unit 711 is performed when a frequency band of about (hereinafter “middle range”) and 2001 Hz to 20000 Hz are set to a high frequency band (hereinafter “high range”) The power consumption is higher at lower frequencies and lower at higher frequencies.
For this reason, from the viewpoint of power saving, it is effective to cut the correction of frequency characteristics (hearing aid processing) in the low range and mid range.

Therefore, in the present embodiment, when the remaining battery level is 100% or a level close to 100% (this is assumed to be full), the frequency characteristic correction (hearing process) by the setting unit 711 is shown in FIG. If the remaining battery level is “high”, the frequency characteristics are corrected only in the low frequency range (hearing aid processing). When the battery level is “medium”, the frequency characteristics correction (hearing process) is cut by 50% and the battery level is “low”. In this case, the adjustment processing unit 713 adjusts the frequency characteristic correction (hearing process) by the setting unit 711 so as to cut 100% of the frequency characteristic correction (hearing process) in the low and middle ranges. Adjust at least one of
Note that there is no particular limitation on the remaining battery level when the remaining battery level (that is, when the value detected by the remaining battery level detection circuit 62 is about that level). This is a matter set appropriately.

In addition, the adjustment processing unit 713 in the present embodiment, at least one of the range and degree of correction of the frequency characteristic by the setting unit 711 so as to lower the correction level of the frequency characteristic by the setting unit 711 as the remaining battery level decreases. When adjusting the white noise, white noise is added to an arbitrary frequency. Specifically, an oscillator (oscillation circuit) for adding white noise is configured by the DSP 23, and this is added to an arbitrary frequency.
By applying white noise, it is possible to obtain a hearing aid effect by stochastic resonance, and it is possible to suppress the deterioration of the degree of hearing compared to a case where the correction level of the frequency characteristic is simply lowered.

In the present embodiment, the high frequency band is not a target for cutting the frequency characteristic correction (hearing process) regardless of the level of the remaining battery level. This is because even if the correction of frequency characteristics (hearing process) is cut for the high frequency range, the power consumption for the hearing aid processing is originally a low band compared to the low frequency range and the mid frequency range. One reason is that is low.
Further, if the correction of frequency characteristics (hearing process) is cut for the high frequency range, not only the sound quality is deteriorated, but also a frequency band of about 200 to 4000 hz centering on the mid range mainly including human voice components such as conversation. Speech recognition and speaker recognition will also be reduced. This is considered to be caused by cutting the hearing aid processing in the high frequency region and making the sound obscured and the outline of the sound in speech etc. unclear.
Therefore, in the present embodiment, the frequency characteristic correction (the hearing aid processing) level is maintained for the high range and the outline of the sound in the utterance or the like is maintained, while the frequency characteristic correction (for the low range, the mid range, or both ( Hearing aid processing) was cut to save power.
In addition, there is a concern that hearing may worsen by cutting the frequency characteristics correction (hearing process) for the low range, mid range, or both. In this regard, stochastic resonance can be achieved by adding white noise. I made a hearing aid to compensate for the worsening of hearing.
This cuts frequency characteristics correction (hearing aid processing) for low and middle power efficient power savings, effectively reducing power consumption and increasing the speech recognition level by leaving the hearing aid processing in the high range. Furthermore, the hearing can be reinforced by adding white noise to the portion where the hearing aid processing has been cut, and both power saving and suppression of a decrease in the speech recognition level can be achieved.

《Effects of hearing aids as acoustic equipment》
Next, a control method of the hearing aid 1 that is an acoustic device in the present embodiment will be described.
FIG. 5 is a flowchart showing the entire processing by the hearing aid in the present embodiment.
As shown in FIG. 5, when the power switch 25 of the hearing aid 1 is turned on (step S1), after initialization (step S2), external sound waves (sound data) are transmitted from the microphone 4 through the microphone preamplifier 41. When input, the control unit 71 performs an AGC (auto gain control) process for adjusting the sensitivity for each corresponding frequency in accordance with the size of the input sound data (step S3).
Next, the control device 7 performs hearing aid processing (step S4). The hearing aid process is a main process of the hearing aid 1 of the present embodiment that outputs a sound with a sound that is easy for the user to hear. As the hearing aid processing, DSP 23 (auditory optimization correction value) such as a shelving filter set in the setting unit 711 based on the adjustment data such as the user's auditory optimization information from the optimization information storage area 726 of the storage unit 72. Is applied to the input sound data and the frequency characteristics are adjusted. Then, the sound output control unit 712 outputs the adjusted sound data from the speaker (earphone) 5 via the speaker amplifier 51.

While the power is on, the control unit 71 always determines whether or not the hearing optimization test start switch 21 is turned on (step S5), and when the hearing optimization test start switch 21 is turned on ( In step S5; YES, the process proceeds to auditory optimization processing (see step S6, FIG. 6).
On the other hand, when the auditory optimization test start switch 21 is not turned on (step S5; NO) and when the auditory optimization process (step S6) is completed, the control unit 71 further turns off the power switch 25. If the power switch 25 is turned off (step S7; YES), the apparatus power is turned off and the process is terminated. On the other hand, when the power switch 25 is not OFF (step S7; NO), the process returns to step S3, and when the hearing optimization process (step S6) is performed, the hearing aid process reflecting the result (step S6). Step S4) is repeated.

FIG. 6 shows details of the auditory optimization process (step S6) shown in FIG.
When the hearing optimization test start switch 21 is turned on (step S5 in FIG. 5; YES), the setting unit 711 of the control unit 71 reads out the instruction voice data from the instruction voice data storage area 724, for example, “Sound is heard. Then press the answer switch "to output the voice from the speaker 5 (step S11).
In addition, it is preferable to output the sound for the operation instruction as a low frequency sound that can be heard by many users. Further, it is preferable that the sound volume be sufficiently high as long as it does not become uncomfortable for the user.
Then, the setting unit 711 reads the test sound source data from the test sound source data storage area 725, outputs a test sound based on the test sound source data from the speaker 5, and sets the timer 10 seconds (step S12). For example, when auditory optimization processing is performed at nine points of frequencies of 100 hz, 300 hz, 500 hz, 1000 hz, 3000 hz, 5000 hz, 8000 hz, 12000 hz, and 14000 hz, the test sound of the lowest frequency of 100 hz is first used as the sound volume during the test. Is output from the speaker 5 for 10 seconds at the lowest volume set.
The setting unit 711 determines whether or not the answer switch 23 has been operated (step S13). If the answer switch 23 is not operated (step S13; NO), the setting unit 711 determines whether or not another 10 seconds have elapsed. Is determined (step S14). If 10 seconds have not elapsed (step S14; NO), the process returns to step S13 and is repeated.
On the other hand, when 10 seconds have elapsed (step S14; YES), the setting unit 711 further determines whether or not the test has been completed up to the maximum volume N assumed in the test for the sound of the frequency (step S15). ). When the sound of the frequency has not been finished up to the maximum volume N (step S15; NO), the setting unit 711 reads out the instruction voice data from the instruction voice data storage area 724, for example, “Next volume”. While outputting the sound from the speaker 5 (step S16), the volume of the sound having the frequency is increased by one step (for example, 3 dB) (step S17), and the process returns to step S11 to repeat the process.

On the other hand, when the user hears the sound, the user operates the answer switch 23 (step S13; YES), and the setting unit 711 determines that the volume can be heard by the user for the frequency (step S18) or the maximum volume for a certain frequency. When the test is completed up to N (step S15; YES) and the setting unit 711 determines that the user cannot hear the sound of the frequency (step S19), the setting unit 711 sets all the frequencies planned for the test. It is determined whether or not the test has been completed for a sound of N (for example, 14000 hz) (step S20).
If the test has not been completed for all the sounds having the frequency N (step S20; NO), the setting unit 711 reads the instruction sound from the instruction sound data storage area 724, for example, “the sound of the next frequency. "Is output from the speaker 5 (step S21), and the frequency is changed to the next frequency (for example, 300 hz) (step S22). That is, the setting unit 711 reads test sound source data of the sound of the next frequency from the test sound source data storage area 725. And it returns to step S11 and repeats a process similarly.

On the other hand, when the test is completed for all sounds having the frequency N (step S20; YES), the setting unit 711 reads out the instruction voice from the instruction voice data storage area 724, for example, “the auditory optimization process has ended. Is output from the speaker 5 (step S23).
Then, the sound volume level (gain) determined for each frequency in the test is stored in the optimization information storage area 726 as auditory optimization information (adjustment data) indicating the user's auditory characteristics (step S24). The auditory optimization process ends. The setting unit 711 sets a gain based on the user's auditory characteristics to the GSP 73 such as a shelving filter, and when the next hearing aid process (step S4 in FIG. 5) is performed, the DSP 73 such as the shelving filter is set. Apply to sound data to adjust frequency characteristics.
Here, the frequency characteristic in the amplification factor of the output of the speaker 5 according to the user's auditory characteristic by the setting unit 711 has been described. However, for example, the sensitivity of the input of the microphone 4 is adjusted according to the user's auditory characteristic. You may go.

Moreover, in this embodiment, the power saving process for suppressing the power consumption of a hearing aid is performed in parallel with the whole process of the hearing aid 1 shown in FIG.
FIG. 7 is a flowchart showing power saving processing in the present embodiment.
As shown in FIG. 7, the adjustment processing unit 713 determines whether or not the remaining battery level is full (step S31). The timing for determination may be any time while the power is turned on, may be the timing when the power is turned on, or may be every predetermined time interval.
Specifically, the power saving control unit 713 determines the level of the remaining battery level from the detection result detected by the remaining battery level detection circuit 62.
If the remaining battery level is full (step S31; YES), hearing aid processing is performed for all frequencies that are subject to hearing aid processing (step S32).
On the other hand, when the remaining battery level is not full (step S31; NO), the adjustment processing unit 713 further determines whether or not the remaining battery level is “high” (step S33). If the remaining battery level is “high” (step S31; YES), the hearing aid process is cut 100% only for the frequencies belonging to the low frequency range (see FIG. 4) (step S34).
On the other hand, when the remaining battery level is not “high” (step S33; NO), the adjustment processing unit 713 further determines whether or not the remaining battery level is “medium” (step S35). When the remaining battery level is “medium” (step S35; YES), the hearing aid processing is cut by 50% for the frequencies belonging to the low and middle bands (see FIG. 4), and the low and middle bands are cut. A predetermined level of white noise is added to the frequency (for example, 30 dB of white noise is added) (step S36).
On the other hand, if the remaining battery level is not “medium” (step S35; NO), the adjustment processing unit 713 determines that the remaining battery level is “low”, and the frequencies belonging to the low and middle bands ( 4), the hearing aid process is cut 100% (step S37).
As described above, when the remaining battery level is not full, the power consumption can be efficiently reduced by cutting the hearing aid processing at frequencies belonging to the low and middle ranges (see FIG. 4) according to the remaining battery level. In addition, leaving the hearing aid processing of the frequencies belonging to the high frequency (see FIG. 4), and adding the hearing aid using stochastic resonance by adding white noise to the part where the hearing aid processing is cut, The outline is kept clear, and a decrease in the speech recognition level that is particularly important for the hearing aid 1 is suppressed.

《Effects of hearing aids as acoustic equipment》
As described above, according to the present embodiment, the adjustment processing unit 713 determines at least one of the range and the degree of correction of the frequency characteristic by the setting unit 711 based on the detection result detected by the remaining battery level detection circuit 62. It comes to adjust.
In this way, it is possible to save power according to the remaining battery level, and to achieve both the reduction of power consumption and the function as the hearing aid 1 that makes it easy to hear sound.

In the present embodiment, the setting unit 711 determines the user's auditory characteristic regarding at least one of frequency and volume, and corrects the frequency characteristic related to sound generation from the speaker according to the detection result. Yes.
For this reason, the user can easily adjust the hearing aid 1 so as to have a frequency characteristic suitable for his / her hearing characteristics without going to a specialty store or the like, and can save troublesome work.

Further, in the present embodiment, the adjustment processing unit 713 performs the operation in the low frequency band compared to the high frequency band when the remaining battery level detected by the remaining battery level detection circuit 62 is less than or equal to a predetermined level. At least one of the range and degree of correction of the frequency characteristic by the setting unit 711 is adjusted so as to lower the correction level of the frequency characteristic.
Compared with the high frequency band, the power consumption for correcting the frequency characteristics is large in the low frequency band. For this reason, by reducing the correction level of the frequency characteristic for the low frequency band, it is possible to realize power saving more efficiently.
Further, in the present embodiment, the adjustment processing unit 713 performs at least one of a range and a degree of correction of the frequency characteristic by the setting unit 711 according to a plurality of levels of the remaining battery level detected by the remaining battery level detection circuit 62. Is adjusted to multiple stages.
Since the power consumption for correcting the frequency characteristics varies depending on the frequency band in which this is performed, adjusting how much correction is performed for which frequency band according to the remaining battery level enables more efficient power saving. In addition to being able to be realized, it is possible to achieve both the achievement of the function as the hearing aid 1 that is an acoustic device and the power saving while maintaining the hearing level as much as possible.

Furthermore, in the present embodiment, the adjustment processing unit 713 adjusts at least one of the range and degree of correction of the frequency characteristic by the setting unit 711 so as to lower the correction level of the frequency characteristic by the setting unit 711. Thus, white noise is added to an arbitrary frequency.
When the frequency characteristic correction level is lowered, the audible level is deteriorated accordingly. However, as in this embodiment, white noise is added together with the reduction of the frequency characteristic correction level (cutting of hearing aid processing). Thus, the hearing level can be reinforced by stochastic resonance.
Accordingly, it is possible to realize the hearing aid 1 having a high hearing effect even with power saving by reducing power consumption and maintaining a long battery life while preventing deterioration of the hearing level.

In the present embodiment, a test sound for arbitrarily designating at least one of an arbitrary frequency and volume is output from the speaker 5, and the answer switch 23 when the test sound is generated from the speaker 5 is used. In response to the input operation, the setting unit 711 determines the user's auditory characteristic regarding either frequency or volume, and sets the frequency characteristic or input / output characteristic related to the sound generation from the speaker 5 based on the auditory characteristic.
Thereby, even if it does not set using special machines, such as a specialty store, a user can adjust the hearing aid 1 so that it may become a sound output suitable for his auditory characteristic.
Further, in the present embodiment, test sounds are sequentially output while changing the volume for each of a plurality of different frequencies, and depending on the input timing at which volume the input operation from the answer switch 23 is performed for each frequency, The volume at which the sound of each frequency becomes an audible sound for the user is determined.
For this reason, the user can adjust the hearing aid 1 by a simple method of performing an input operation when a sound output from the speaker 5 is heard.

  In this embodiment, the microphone 4 is provided as a sound wave input unit to which an external sound wave is input, and the setting unit 711 amplifies the input sensitivity of the microphone 4 or the output of the speaker 5 according to the user's auditory characteristics. Sets the frequency characteristics of the rate. For this reason, whatever sound is input from the microphone 4, it is possible to output an appropriate sound that matches the user's auditory characteristics.

<Modification>
Although the embodiments of the present invention have been described above, the present invention is not limited to such embodiments, and various modifications can be made without departing from the scope of the present invention.

For example, in the present embodiment, the case where the acoustic device is a hook-type hearing aid is illustrated, but an ear-hole type hearing aid that is used by being fitted in the ear hole may be used, or a hearing aid that is lowered from the neck may be used.
The acoustic device is not limited to a hearing aid, and may be a “sound collector” that has not received medical approval as a hearing aid.
Furthermore, the audio device is not limited to a “hearing aid” device that improves the sound when it is difficult to hear the sound, and can be applied to any device that corrects the sound so that the user can hear it in a desired manner. Therefore, the present invention can be widely applied to a speaker system installed indoors, such as a PA (Public Address) system, or a speaker used by hand.

Moreover, although the case where the microphone 4 is provided as a sound wave input unit to which an external sound wave is input is illustrated in the present embodiment, the input sound is not limited to the sound from the microphone 4.
For example, when the audio device is a music playback device, a sound source input unit such as an input terminal to which sound source data is input from an external device may be provided.
In this case, the setting unit 711 may set the frequency characteristics of the input sensitivity of the input terminal or the amplification factor of the output of the speaker 5 according to the auditory characteristics of the user.
By doing in this way, even if it is an audio equipment which takes in music data etc. from the outside and reproduces, an audio equipment can be adjusted so that sound output according to a user's auditory characteristic may be performed.
Furthermore, the speaker 5 may be one that generates sound based on output sound data stored in a storage unit or the like. Also in this case, the setting unit 711 can realize an acoustic device that outputs sound with a sound that is easy to hear for the user by setting the frequency characteristic of the amplification factor of the output of the speaker 5 according to the auditory characteristic of the user. .

Further, in the present embodiment, the configuration in which white noise is added only when the remaining battery level is “medium” and the hearing aid processing in the low and middle ranges is cut by 50% is exemplified. However, white noise is added. Is not limited to this case. For example, white noise may be added for all frequencies to improve the overall hearing level.
In addition, white noise may be added to the low frequency range where the hearing aid process is cut even when the remaining battery level is “high”. Even if the remaining battery level is “low” level, white noise may be added as long as power for adding white noise can be secured.

In the present embodiment, the remaining battery level is divided into four levels of “full”, “many”, “medium”, and “low” levels, and at least of the range and degree of correction of the frequency characteristics by the setting unit 711. Although an example of changing one of the adjustments and whether to add white noise has been shown, the level classification of the remaining battery level is not limited to these four stages.
For example, a “very small” level that is smaller than the “low” level may be provided so that a mode that consumes less power can be taken, or the level may be divided into two or less levels.

Further, in the present embodiment, the setting unit 711 performs the auditory optimization process of adjusting the gain for each frequency to perform the adjustment according to the user's auditory characteristics, but the adjustment performed by the setting unit 711 is performed on this basis. It is not limited. For example, the setting unit 711 may perform non-linear optimization processing that adjusts input / output characteristics so that the output sound does not become unpleasant and unpleasant by the user together with or instead of auditory optimization processing.
Here, the setting of the input / output characteristics related to the sound generation from the speaker 5 which is the sound generation unit is the non-linear amplification for controlling the amplification degree in the output from the speaker 5 according to the magnitude of the input sound to the hearing aid 1. To do.

  Moreover, in this embodiment, although the case where the battery 6 which comprises the power supply part which supplies electric power to each part of the hearing aid 1 is a button battery etc. was illustrated, a battery is not limited to a disposable battery, By charging, for example. It may be a rechargeable battery that can be returned and used.

In the present embodiment, the setting unit 711 performs the auditory optimization test for determining the auditory characteristics of the user for the auditory optimization process for adjusting the gain for each frequency. It is not mandatory to do testing.
For example, the acoustic device (the hearing aid 1 in the present embodiment) is in a state in which a hearing optimization test is performed in advance using a dedicated device at a specialized store or the like where it is purchased, and gain adjustment based on the test result is completed. There may be.
In this case, the setting unit 711 performs auditory optimization processing that adjusts the gain for each frequency by applying a DSP 73 or the like set in advance according to the user's auditory characteristics.

  In this embodiment, an example is shown in which a test for examining the user's auditory characteristics is performed at nine points of frequencies of 100 hz, 300 hz, 500 hz, 1000 hz, 3000 hz, 5000 hz, 8000 hz, 12000 hz, and 14000 hz. It is not limited to 9 points. The test may be performed at a smaller number of points, or more detailed tests may be performed for a plurality of frequencies.

In the present embodiment, the audible area is set to about 20 Hz to 20000 Hz, of which 20 Hz to 200 Hz is a low range, 201 Hz to 2000 Hz is a mid range, and 2001 Hz to 20000 Hz is a high range. It is not necessary to limit the region to this range, and the region may be expanded beyond this, or may be narrowed below this.
The frequency range for correcting the frequency characteristics (hearing process) is not limited to the range illustrated here.
In addition, the frequency at which the low frequency, mid frequency, and high frequency are separated is not limited to the example shown here.
For example, in accordance with the user's auditory characteristics, frequency characteristics correction (hearing process) may be performed until the remaining battery level becomes extremely low, particularly in a frequency band that requires correction. In addition, the user may be able to select and set a range for cutting the correction of frequency characteristics (hearing process).

Although several embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-described embodiments, but includes the scope of the invention described in the claims and equivalents thereof. .
The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as set forth in the claims attached to the application of this application.
[Appendix]
<Claim 1>
A sound generator that outputs sound based on output sound data;
A setting unit for setting an acoustic characteristic related to the sound generation from the sound generation unit;
A battery level detector for detecting the remaining battery level;
An adjustment processing unit for adjusting an acoustic characteristic set by the setting unit based on a detection result detected by the battery remaining amount detection unit;
An acoustic device comprising:
<Claim 2>
2. The acoustic according to claim 1, wherein the adjustment processing unit adjusts at least a frequency characteristic among acoustic characteristics set by the setting unit based on a detection result detected by the battery remaining amount detection unit. machine.
<Claim 3>
The acoustic device according to claim 1, wherein the setting unit further corrects the acoustic characteristic set according to a user's auditory characteristic.
<Claim 4>
The adjustment processing unit adjusts at least one of a range and a degree of correction of acoustic characteristics by the setting unit based on a detection result detected by the detection unit. The acoustic device according to any one of 3.
<Claim 5>
The adjustment processing unit has a frequency so as to lower the correction level of another frequency band that leaves some audible frequency bands when the remaining battery level detected by the remaining battery level detection unit falls below a predetermined level. The acoustic device according to any one of claims 1 to 4, wherein a characteristic is adjusted.
<Claim 6>
The adjustment processing unit, when the remaining battery level detected by the remaining battery level detection unit becomes equal to or less than a predetermined level, sets a correction level of a frequency characteristic in a low frequency band compared to a high frequency band. 6. The acoustic device according to claim 1, wherein at least one of a range and a degree of correction of the frequency characteristic by the setting unit is adjusted to be lowered.
<Claim 7>
The adjustment processing unit adjusts at least one of a range and a degree of correction of the frequency characteristic by the setting unit in a plurality of stages according to a plurality of levels of the remaining battery level detected by the remaining battery level detection unit. The acoustic device according to any one of claims 1 to 6, wherein
<Claim 8>
When the adjustment processing unit adjusts at least one of the range and degree of correction of the frequency characteristic by the setting unit so as to lower the correction level of the frequency characteristic by the setting unit, the adjustment processing unit also adds white noise to an arbitrary frequency. The acoustic device according to claim 6, wherein the acoustic device is added.
<Claim 9>
A response input unit that outputs a response signal associated with the input operation when a user operation is input;
The setting unit causes the sound generation unit to output a test sound based on the test output sound data that arbitrarily designates at least one of frequency and volume, and the test sound is generated from the sound generation unit. In response to an input operation from the response input unit, a user's auditory characteristic regarding at least one of frequency and volume is determined, and based on the auditory characteristic, the frequency characteristic related to the sound generation from the sound generation unit is corrected The acoustic device according to any one of claims 1 to 8, wherein the acoustic device is characterized.
<Claim 10>
It has a sound wave input unit that receives sound waves from the outside,
The said setting part correct | amends the frequency characteristic in the input sensitivity of the said sound wave input part according to the said auditory characteristic of a user, or the amplification factor of the output of the said sound production | generation part, The Claim 1 characterized by the above-mentioned. The acoustic device according to any one of Items 9.
<Claim 11>
It has a sound source input unit that receives sound source data from an external device,
The said setting part correct | amends the frequency characteristic in the input sensitivity of the said sound source input part according to the said auditory characteristic of a user, or the amplification factor of the output of the said sound production | generation part, The Claim 1 characterized by the above-mentioned. The acoustic device according to any one of Items 9.
<Claim 12>
The sound generation unit is adapted to generate sound based on output sound data stored in the storage unit,
The said setting part correct | amends the frequency characteristic of the amplification factor of the output of the said sound-emitting part according to the said auditory characteristic of a user, The Claim 1 characterized by the above-mentioned. Acoustic equipment.
<Claim 13>
A sound generation process for outputting sound based on output sound data;
An optimization process for correcting the frequency characteristics related to the sound generation in the sound generation process;
A battery level detection process for detecting the battery level;
A power saving processing step of adjusting at least one of a range and a degree of correction of the frequency characteristic in the optimization processing step based on a detection result detected in the battery remaining amount detection step;
A method for controlling an audio device, comprising:
<Claim 14>
To computer of audio equipment,
A sound generation function that outputs sound based on output sound data;
An optimization processing function for correcting a frequency characteristic related to sound generation by the sound generation function;
A battery level detection function for detecting the battery level,
A power saving processing function that adjusts at least one of the range and degree of correction of the frequency characteristic by the optimization processing function based on the detection result detected by the remaining battery level detection function;
A computer-readable program characterized by realizing the above.

DESCRIPTION OF SYMBOLS 1 Hearing aid 4 Microphone 5 Speaker 62 Battery remaining charge detection circuit 71 Control part 72 Memory | storage part 73 DSP
711 Setting unit 712 Sound output control unit 713 Adjustment processing unit 726 Optimization information storage area 727 Power saving processing program

Claims (14)

A sound generator that outputs sound based on output sound data;
A setting unit for setting an acoustic characteristic related to the sound generation from the sound generation unit;
A battery level detector for detecting the remaining battery level;
An adjustment processing unit for adjusting an acoustic characteristic set by the setting unit based on a detection result detected by the battery remaining amount detection unit;
An acoustic device comprising:   2. The acoustic according to claim 1, wherein the adjustment processing unit adjusts at least a frequency characteristic among acoustic characteristics set by the setting unit based on a detection result detected by the battery remaining amount detection unit. machine.   The acoustic device according to claim 1, wherein the setting unit further corrects the acoustic characteristic set according to a user's auditory characteristic.   The adjustment processing unit adjusts at least one of a range and a degree of correction of acoustic characteristics by the setting unit based on a detection result detected by the detection unit. The acoustic device according to any one of 3.   The adjustment processing unit has a frequency so as to lower the correction level of another frequency band that leaves some audible frequency bands when the remaining battery level detected by the remaining battery level detection unit falls below a predetermined level. The acoustic device according to any one of claims 1 to 4, wherein a characteristic is adjusted.   The adjustment processing unit, when the remaining battery level detected by the remaining battery level detection unit becomes equal to or less than a predetermined level, sets a correction level of a frequency characteristic in a low frequency band compared to a high frequency band. 6. The acoustic device according to claim 1, wherein at least one of a range and a degree of correction of the frequency characteristic by the setting unit is adjusted to be lowered.   The adjustment processing unit adjusts at least one of a range and a degree of correction of the frequency characteristic by the setting unit in a plurality of stages according to a plurality of levels of the remaining battery level detected by the remaining battery level detection unit. The acoustic device according to any one of claims 1 to 6, wherein   When the adjustment processing unit adjusts at least one of the range and degree of correction of the frequency characteristic by the setting unit so as to lower the correction level of the frequency characteristic by the setting unit, the adjustment processing unit also adds white noise to an arbitrary frequency. The acoustic device according to claim 6, wherein the acoustic device is added. A response input unit that outputs a response signal associated with the input operation when a user operation is input;
The setting unit causes the sound generation unit to output a test sound based on the test output sound data that arbitrarily designates at least one of frequency and volume, and the test sound is generated from the sound generation unit. In response to an input operation from the response input unit, the user's auditory characteristic regarding at least one of frequency and volume is determined, and the frequency characteristic related to the sound generation from the sound generating part is corrected based on the auditory characteristic The acoustic device according to any one of claims 1 to 8, wherein It has a sound wave input unit that receives sound waves from the outside,
The said setting part correct | amends the frequency characteristic in the input sensitivity of the said sound wave input part according to the said auditory characteristic of a user, or the amplification factor of the output of the said sound production | generation part, The Claim 1 characterized by the above-mentioned. The acoustic device according to any one of Items 9. It has a sound source input unit that receives sound source data from an external device,
The said setting part correct | amends the frequency characteristic in the input sensitivity of the said sound source input part according to the said auditory characteristic of a user, or the amplification factor of the output of the said sound production | generation part, The Claim 1 characterized by the above-mentioned. The acoustic device according to any one of Items 9. The sound generation unit is adapted to generate sound based on output sound data stored in the storage unit,
The said setting part correct | amends the frequency characteristic of the amplification factor of the output of the said sound-emitting part according to the said auditory characteristic of a user, The Claim 1 characterized by the above-mentioned. Acoustic equipment. A sound generation process for outputting sound based on output sound data;
A setting processing step for setting an acoustic characteristic related to sound generation in the sound generation step;
A battery level detection process for detecting the battery level;
An adjustment processing step of adjusting the acoustic characteristics set in the setting processing step based on the detection result detected in the battery remaining amount detection step;
A method for controlling an audio device, comprising: To computer of audio equipment,
A sound generation function that outputs sound based on output sound data;
A setting processing function for setting an acoustic characteristic related to sound generation by the sound generation function;
A battery level detection function for detecting the battery level,
An adjustment processing function for adjusting an acoustic characteristic set by the setting processing function based on a detection result detected by the battery remaining amount detection function;
A computer-readable program characterized by realizing the above.

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