JP6286653B2 - hearing aid - Google Patents

Description

  The present invention relates to a hearing aid with improved convenience.

  This type of conventional hearing aid includes means for determining whether or not a hearing aid is attached to the ear of the hearing aid wearer, for example, when the hearing aid is attached to the ear of the hearing aid wearer. When it is determined that the device is attached, the power source for driving the hearing aid is turned on (as a prior art similar to this, there is Patent Document 1 below).

Japanese Patent No. 5099436

  In the above conventional example, the hearing aid cannot be comfortably used even though the hearing aid is detected by various sensors or the like and can be switched ON / OFF of the hearing aid. Sometimes. For example, if the hearing aid is turned on when the hearing aid is not installed in the ear hole (ear canal) of the hearing aid wearer without a gap, the sound from the hearing aid microphone is amplified inside the hearing aid and output from the earphone (speaker) Is done. Then, the sound leaks from the gap between the ear holes and is input to the microphone again, and the sound loops between the microphone and the earphone of the hearing aid to cause howling.

  In other words, in the conventional hearing aid, even if the hearing aid is not properly worn in the ear of the hearing aid wearer, the hearing aid is turned on, and as a result, howling may occur. Depending on the usage situation, it was extremely inconvenient.

  Therefore, the present invention aims to improve usability.

  In order to achieve this object, the present invention provides a hearing aid including a microphone, a hearing aid processing unit that amplifies sound input from the microphone, and an earphone that outputs sound amplified by the hearing aid processing unit. A main body including the microphone, the hearing aid processing unit, and the earphone; a power supply unit that supplies power to the microphone, the hearing aid processing unit, and the earphone of the main body; A sensor that is brought into contact with the human body when it is worn and measures an electroencephalogram, and an electroencephalogram detection unit to which the sensor is connected, and the electroencephalogram detection unit, when no electroencephalogram is detected via the sensor, The amplification degree of the hearing aid processing unit is lowered or the operation of the hearing aid processing unit is stopped, thereby achieving the intended purpose.

  As described above, the present invention is a hearing aid including a microphone, a hearing aid processing unit that amplifies sound input from the microphone, and an earphone that outputs sound amplified by the hearing aid processing unit. A body part having the hearing aid processing part and the earphone, a power supply part for supplying power to the microphone, the hearing aid processing part and the earphone of the body part, and a hearing aid wearer wearing the body part A sensor that is brought into contact with a human body and that measures an electroencephalogram, and an electroencephalogram detection unit to which the sensor is connected, and when the electroencephalogram detection unit does not detect an electroencephalogram through the sensor, Since the degree of amplification is reduced or the operation of the hearing aid processing unit is stopped, it is extremely easy to use.

  That is, in the present invention, the electroencephalogram detection unit determines whether or not the hearing aid is attached to the ear hole without a gap depending on whether or not an electroencephalogram is detected via the sensor. When worn, the degree of amplification of the hearing aid processing unit of the hearing aid is reduced or the operation of the hearing aid processing unit is stopped.

  Therefore, in the state where the hearing aid is attached to the ear hole, if the brain wave is not detected through the sensor, that is, if there is a gap in the ear hole, the degree of amplification of the hearing aid processing unit of the hearing aid is reduced or this hearing aid. Since the operation of the processing unit is stopped, occurrence of howling can be reduced. As a result, it is extremely easy to use.

The figure explaining the use condition of the hearing aid concerning one embodiment of the present invention. Block diagram of the hearing aid Hearing aid operation flowchart The figure explaining operation of the hearing aid

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1)
In FIG. 1, reference numeral 1 denotes a hearing aid (sound transmission device) attached to the ear 3 of the hearing aid wearer 2, and the hearing aid 1 is a main body attached near the entrance of the ear 3 of the hearing aid wearer 2 as shown in FIG. 1. A hearing aid wearer 2 with a case 4, an earphone 5 (speaker) inserted into an ear hole (not shown) with the main body case 4 attached to the ear 3, and a main body case 4 attached to the ear 3 And a microphone 6 disposed toward the opposite side. Here, the ear hole is, for example, the ear canal.

  Further, as shown in FIG. 2, the microphone 6 is connected to a control unit 8 via an AD converter 7, and the earphone 5 is connected to the control unit 8 via a DA converter 9.

  Furthermore, a hearing aid processor 10 is connected to the controller 8, and the hearing aid processor 10 adjusts the gain amplification level according to the hearing level of the hearing aid wearer 2.

  The hearing aid processing unit 10 stores hearing aid data of the hearing aid wearer 2, and the hearing aid processing unit 10 performs hearing aid processing on the audio data input from the microphone 6 using the hearing aid data. Then, by outputting the sound subjected to the hearing aid processing from the earphone 5, a hearing aid environment most preferable for the hearing aid wearer 2 is provided.

  That is, the sound input from the microphone 6 of the hearing aid 1 is amplified inside the hearing aid 1 and output from the earphone 5.

  In FIG. 2, reference numeral 11 denotes a battery (an example of a power supply unit) that supplies power to each part. If the battery 11 is attached to the main body case 4, power can be supplied to each part. If it is removed from the power supply, the power supply to each part will be cut off.

  The battery 11 is connected to the control unit 8, and the power supply to each unit of the hearing aid 1 is switched by switching the power drive ON / OFF by the control unit 8. When the power is turned on, for example, the earphone 5, The main body of the hearing aid 1 such as the microphone 6 is driven.

  Here, as shown in FIG. 1, the hearing aid 1 has an insertion portion 12 that is inserted into the ear hole while the main body case 4 is attached to the ear 3. The insertion unit 12 includes a sensor 13 that contacts a part of the human body of the hearing aid wearer 2 in a state where the hearing aid 1 is worn by the hearing aid wearer 2.

  For example, the sensor 13 measures the brain wave of the hearing aid wearer 2 and measures the bioelectric potential of the hearing aid wearer 2, for example.

  Since the bioelectric potential measurement in this electroencephalogram detection is a technique that has already been publicly known, detailed description thereof is omitted here.

  Then, from the stability of the bioelectric potential of the hearing aid wearer 2 measured by the sensor 13, for example, the state where the hearing aid 1 is attached to the ear 3 of the hearing aid wearer 2 is connected to the sensor 13 as shown in FIG. The determination is made by the electroencephalogram detection unit 14.

  The sensor 13 includes, for example, three electrodes 13a, 13b, and 13c exposed on the surface of the insertion portion 12. The three types of electrodes are a ground electrode, a reference electrode, and a measurement electrode, respectively. Here, the brain waves of the hearing aid wearer 2 may be measured with higher accuracy by arranging measurement electrodes at two or more locations.

  Since the bent part of the ear canal from the first curve to the second curve (front direction of the face) is often related to howling, for example, in the case of an earphone type hearing aid, the sensor 13 is arranged at that part. Is preferred. That is, it is preferable that the electrode 13a, the electrode 13b, and the electrode 13c are disposed in the first curve corresponding part or the part corresponding to the area between the first curve and the second curve.

  The electrode 13a, the electrode 13b, and the electrode 13c are biased to a part of the human body of the hearing aid wearer 2 when the insertion portion 12 of the hearing aid 1 is inserted into the ear hole of the hearing aid wearer 2, for example, It is made to contact with elasticity.

  The strength of the contact can be adjusted as appropriate, and it is sufficient that the hearing aid wearer 2 does not feel uncomfortable and the sensor 13 can measure the brain wave with a desired accuracy.

  That is, the electrodes 13a, the electrodes 13b, and the electrodes 13c are brought into contact with the human body securely along the unevenness of a part of the human body so that the brain waves can be accurately measured.

  Specifically, for example, the electrode 13a, the electrode 13b, and the electrode 13c may be formed of a conductive material having flexibility or elasticity.

  Further, the electrode 13a, the electrode 13b, and the electrode 13c are not limited to being provided in the insertion portion 12. That is, it is only necessary that the hearing aid 1 is provided so as to be able to contact a part of the human body of the hearing aid wearer 2 when the hearing aid wearer 2 is worn.

  For example, in the case of an ear-mounted hearing aid in which the main body case 4 is worn on the upper part of the ear 3 of the hearing aid wearer 2, the electrode 13 a and the electrode 13 b with the main body case 4 attached to the ear 3. Alternatively, the electrode 13a, the electrode 13b, and the electrode 13c may be provided on the main body case 4 so that the electrode 13c contacts a part of the human body of the hearing aid wearer 2.

  In this way, the hearing aid 1 in the present embodiment measures the brain wave of the hearing aid wearer 2 by the sensor 13, and the brain wave detection of the state in which the hearing aid 1 is worn on the ear 3 of the hearing aid wearer 2 by the measured brain wave. Since it can be determined by the unit 14, it can be determined whether or not the hearing aid 1 is appropriately worn on the ear 3 of the hearing aid wearer 2.

  That is, the electroencephalogram detection unit 14 determines that the hearing aid 1 is not properly attached to the ear 3 of the hearing aid wearer when the electroencephalogram is not detected via the sensor 13, that is, there is a gap in the ear hole. It is. Then, the brain wave detection unit 14 determines whether or not the hearing aid 1 is mounted in the ear hole without any gap depending on whether or not an electroencephalogram is detected via the sensor 13, and is mounted in a state in which there is a gap in the ear hole. In such a case, the degree of amplification of the hearing aid processing unit 10 of the hearing aid 1 is reduced or the operation of the hearing aid processing unit is stopped.

  Therefore, in the state where the hearing aid 1 is attached to the ear hole, when the brain wave is not detected via the sensor 13, that is, when a gap is generated in the ear hole, the amplification degree of the hearing aid processing unit 10 of the hearing aid 1 is increased. Decreasing or stopping the operation of the hearing aid processing unit 10 can reduce howling. As a result, it is extremely easy to use.

  That is, in a state where howling is likely to occur, such as a state where a gap is generated in the ear hole of the hearing aid wearer 2, the amplification degree of the hearing aid processing unit 10 of the hearing aid 1 is reduced or the operation of the hearing aid processing unit 10 is performed. Is stopped.

  In the above configuration, in the present embodiment, when the hearing aid processing is started using the hearing aid 1 shown in FIG. 1, the following procedure is executed.

  First, the body case 4 of the hearing aid 1 is attached near the entrance of the ear 3 of the hearing aid wearer 2, and the insertion portion 12 of the hearing aid 1 is inserted into the ear hole of the hearing aid wearer 2.

  At this time, the electrode 13a, the electrode 13b, and the electrode 13c provided in the sensor 13 provided in the insertion portion 12 of the hearing aid 1 are brought into contact with a part of the human body of the hearing aid wearer 2.

  Then, the hearing aid wearer 2 switches the switch (not shown) of the body case 4 of the hearing aid 1 to ON (S1 in FIG. 3).

  When the switch of the main body case 4 is switched to ON, the hearing aid processing unit 10 starts operation, and the hearing aid 1 is in a state where the hearing aid processing can be executed (S2 in FIG. 3).

  As described above, the hearing aid processing performed in the hearing aid processing unit 10 of the hearing aid 1 is the same as that of widely known hearing aids, and thus description thereof is omitted.

  When the electrode 13a, the electrode 13b, and the electrode 13c are in proper contact with a part of the human body of the hearing aid wearer 2, a message that informs the hearing aid 1 that the electrode 13a, the electrode 13b, and the electrode 13c are in proper contact May be output from the earphone 5 of the hearing aid 1. This message is output as, for example, “Sensor is correctly attached” by voice.

  On the other hand, when the electrode 13a, the electrode 13b, and the electrode 13c are not in proper contact with a part of the human body of the hearing aid wearer 2, the electrode 13a, the electrode 13b, and the electrode 13c are in proper contact with the hearing aid 1. Since there is no such message, a message prompting confirmation of the wearing state may be output from the earphone 5 of the hearing aid 1. This message is output, for example, as “Please check sensor mounting state” by voice.

  At this time, the function of the microphone 6 of the hearing aid 1 may be stopped. That is, when a message is output from the earphone 5 with a gap in the ear hole of the hearing aid wearer 2, a loop is formed in which the message is input from the microphone 6, amplified, and output again from the earphone 5. It prevents the occurrence of howling.

  When the electrodes 13a, 13b, and 13c of the sensor 13 are in proper contact with a part of the human body of the hearing aid wearer 2, the brain waves of the hearing aid wearer 2 are measured by the sensor 13 (S3 in FIG. 3).

  That is, the bioelectric potential of the hearing aid wearer 2 is measured.

  The measured bioelectric potential is determined by the electroencephalogram detection unit 14 of the hearing aid 1 based on, for example, its stability or the like (S4 in FIG. 3).

  For example, in a state where the hearing aid 1 is attached to the ear 3 of the hearing aid wearer 2, it is determined whether or not there is a gap in the ear hole of the hearing aid wearer 2.

  Then, when it is determined that no electroencephalogram is detected by the electroencephalogram detection unit 14 and a gap is generated in the ear hole of the hearing aid wearer 2, the amplification degree of the hearing aid processing unit 10 is reduced or the hearing aid processing unit 10 The operation is stopped (S5 in FIG. 3).

  At this time, since there is a gap in the ear hole of the hearing aid wearer 2 from the hearing aid 1, a message prompting confirmation of the wearing state may be output from the earphone 5 of the hearing aid 1. This message is output, for example, as “Please check the wearing state of the earphone” by voice.

  At this time, the microphone 6 may be stopped so that howling does not occur due to a message output from the earphone 5.

  On the other hand, when the electroencephalogram is detected by the electroencephalogram detection unit 14 and it is determined that there is no gap in the ear hole of the hearing aid wearer 2, the process returns to step S <b> 2 in FIG. The process is continuously performed with a predetermined amplification degree.

  At this time, a message may be output from the earphone 5 informing the hearing aid wearer 2 that the hearing aid 1 has been worn in an appropriate state where no gap is generated in the ear hole of the hearing aid wearer 2. For example, a sound such as “A hearing aid is correctly attached” is output.

  In FIG. 4, (a) is a figure which shows the state of the electroencephalogram measured by the sensor 13, and (b) is a figure which shows the operation state of the hearing aid 1 corresponding to it.

  4A and 4B, for example, shows a state in which the hearing aid 1 is not properly worn on the ear 3 of the hearing aid wearer 2, and the amplitude C of the bioelectric potential is When the value is larger than the predetermined value, the hearing aid processing unit 10 of the hearing aid 1 reduces the amplification degree of the hearing aid processing or stops the operation of the hearing aid processing unit 10.

  On the other hand, in the section B, for example, when the hearing aid 1 is appropriately attached to the ear 3 of the hearing aid wearer 2 and the amplitude D of the bioelectric potential is smaller than a predetermined value for a certain time, the section B of the hearing aid 1 The hearing aid processing unit 10 continuously performs the hearing aid processing with a predetermined amplification degree.

  As described above, in the present embodiment, the electroencephalogram detection unit 14 determines whether or not the hearing aid 1 is appropriately attached to the ear hole of the hearing aid wearer 2 according to the state of the electroencephalogram measured by the sensor 13 and is appropriately attached. In this case, the amplification degree of the hearing aid processing unit 10 of the hearing aid 1 is reduced or the operation of the hearing aid processing unit 10 is stopped.

  That is, in the state where the hearing aid 1 is attached to the ear hole of the hearing aid wearer 2, if the brain wave detection unit 14 does not detect the brain wave via the sensor 13, the hearing aid 1 is appropriately attached to the ear hole of the hearing aid wearer 2. It is determined that there is a gap in the ear hole. Then, the degree of amplification of the hearing aid processing unit 10 of the hearing aid 1 is reduced or the operation of the hearing aid processing unit 10 is stopped so that the hearing aid processing is not continued.

  Therefore, sound that is input to the microphone 6 is amplified by the hearing aid process and output from the earphone 5, and the sound leaks from the gap of the ear hole to reduce the howling caused by forming a loop input to the microphone 6 again. As a result, it becomes extremely easy to use.

  In the present embodiment, the brain wave is measured using only the sensor 13 that measures the brain wave as the sensor 13, and the wearing state of the hearing aid 1 is determined by the brain wave detection unit 14 according to the measurement result. However, the present invention is not limited to this. It is not a thing.

  For example, in combination with the measurement results of various sensors that measure other biological information, the electroencephalogram detection unit 14 may determine whether or not the hearing aid 1 is appropriately attached to the ear hole of the hearing aid wearer 2. Thereby, the precision which determines the mounting state of the hearing aid 1 can further be improved.

  Specifically, for example, a sensor for measuring the sound pressure inside the ear hole may be further provided, and the wearing state of the hearing aid 1 may be determined by combining the measurement results of the sound pressure.

  The hearing aid 1 is further equipped with an acceleration sensor, a gyro sensor, and a proximity sensor, and the wearing state of the hearing aid 1 is determined by combining the change in acceleration of the sensor, the orientation at the wearing position of the sensor, and whether or not there is something near the sensor. Also good.

  Furthermore, in this embodiment, the result determined by the electroencephalogram detection unit 14 is used to determine whether or not there is a gap in the ear hole when the hearing aid 1 is attached to the ear hole of the hearing aid wearer 2. However, the present invention is not limited to this.

  For example, you may utilize for determining whether the hearing aid 1 is driven. In that case, forgetting to cut can be prevented by turning off the power when not driven, and the consumption of the battery 11 of the hearing aid 1 can be suppressed.

  Moreover, you may utilize for determining whether the hearing aid wearer 2 is in a sleep state. In that case, the consumption of the battery 11 of the hearing aid 1 can be suppressed by turning off the power supply in the sleep state.

  As described above, in the hearing aid of the present invention, when the brain wave is not detected through the sensor in a state where the hearing aid is attached to the ear hole, that is, when a gap is generated in the ear hole, the hearing aid processing of the hearing aid is performed. Since the degree of amplification of the unit is reduced or the operation of the hearing aid processing unit is stopped, occurrence of howling can be reduced, and as a result, it becomes extremely easy to use.

  Therefore, utilization as a hearing aid with improved convenience is greatly expected.

1 Hearing Aid 2 Hearing Aid Wearer 3 Ear 4 Body Case 5 Earphone 6 Microphone 7 AD Converter 8 Control Unit 9 DA Converter 10 Hearing Aid Processing Unit 11 Battery 12 Insertion Unit 13 Sensor 13a Electrode 13b Electrode 13c Electrode 14 Electroencephalogram Detection Unit

Claims (8)

A microphone and a hearing aid processing unit that amplifies the sound input from the microphone;
A hearing aid comprising: an earphone that outputs the sound amplified by the hearing aid processing unit;
A main body having the microphone, the hearing aid processing unit, and the earphone;
A power supply unit for supplying power to the microphone, the hearing aid processing unit, and the earphone of the main body unit;
When a hearing aid wearer wears the main body, the sensor is brought into contact with the human body and measures brain waves,
An electroencephalogram detection unit to which this sensor is connected,
The electroencephalogram detection unit is configured to reduce the amplification degree of the hearing aid processing unit or stop the operation of the hearing aid processing unit when no electroencephalogram is detected through the sensor ,
The electroencephalogram detection unit determines that there is no gap in the ear hole of the hearing aid wearer when the main body is worn by the hearing aid wearer, and operates the power supply according to the determination result. hearing aid. The hearing aid according to claim 1 , further comprising a holding portion that attaches the main body portion to an ear hole of the hearing aid wearer, and the holding portion is provided with the sensor. The hearing aid according to claim 2 , wherein the holding portion is configured to contact the ear canal and attach the main body portion to the ear hole of the hearing aid wearer. The hearing aid according to any one of claims 1 to 3 , wherein the sensor is elastically in contact with the human body of the hearing aid wearer while being biased. The hearing aid according to any one of claims 1 to 4 , wherein the sensor is made of an electrode. The hearing aid according to claim 5 , wherein at least three electrodes are provided, which are a ground electrode, a reference electrode, and a measurement electrode, respectively. The hearing aid according to claim 6 , wherein a plurality of the measurement electrodes are provided. The hearing aid according to any one of claims 5 to 7 , wherein the electrode is arranged at a portion corresponding to the first curve or between the first curve and the second curve.

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