KR20240171770A - Apparatus, method and program for measuring of narrowband minimum shielding - Google Patents

Abstract

An inspection device for automatically performing measurement of a narrowband minimum shielding according to the present invention comprises: a processor for setting an inspection sound intensity of an inspection sound outputted to a subject and an inspection sound frequency of the inspection sound; and an input part for input-receiving shielding information indicating whether a tinnitus sound is shielded from the subject listening to the inspection sound, wherein the processor may set by changing at least one or more among the inspection sound intensity and the inspection sound frequency in response to the shielding information, and generate minimum shielding data by determining a minimum shielding intensity of the tinnitus sound corresponding to each of one or more reference frequency ranges based on the shielding information, the inspection sound intensity, and the inspection sound frequency.

Description

{Apparatus, method and program for measuring narrowband minimum shielding}

The present invention relates to a testing device, method and computer program for automatically performing the measurement of narrowband minimum shielding, and more specifically, to a testing device, method and computer program for automatically performing the measurement of narrowband minimum shielding, which can automatically measure the minimum shielding strength of a masking sound that masks tinnitus of a subject for each of one or more reference frequency ranges.

Generally, tinnitus is the sensation of sound without external stimulation, and is one of the most common symptoms of auditory system abnormalities. More than 95% of normal people experience tinnitus at least once in their lives, and 17% of the entire population suffers from tinnitus, and about 5% of them experience tinnitus severe enough to visit a hospital.

Treatment methods for tinnitus include medication, tinnitus retraining therapy, counseling and biofeedback, surgery, and transcranial magnetic stimulation.

In the case of objective tinnitus, the cause can be identified through an appropriate diagnostic process and the tinnitus can be treated.

However, in most cases of tinnitus, hearing loss and abnormalities in outer hair cells are observed in tests, but there are also subjective tinnitus cases where there are no specific findings in tests. Among the treatments for subjective tinnitus, the most effective and widely used is tinnitus retraining therapy (TRT).

Tinnitus retraining therapy is a method of reorganizing and restructuring the neural circuits that transmit tinnitus from the auditory nerve to the cerebral cortex so that the brain does not recognize it or feel discomfort. This tinnitus treatment method, which was advocated by Jastreboff and Hazell in 1990, is currently widely used in many tinnitus clinics around the world and has shown a high treatment effect of over 80%.

Tinnitus retraining treatment is largely composed of guidance counseling and sound therapy. Appropriate follow-up observation and counseling are important during tinnitus retraining treatment.

Many people who suffer from tinnitus report that their tinnitus is more intense in quiet environments, but they do not hear it or are unaware of it in noisy environments or environments with various sounds. Using this, a method of using sound as a method of treating tinnitus has been developed.

This type of sound therapy increases the stimulation of background sounds, thereby reducing the contrast with the tinnitus signal and reducing the abnormal gain in the auditory system, so that the brain perceives tinnitus less. It is important to use this type of sound therapy consistently for more than 6 hours a day, and use it bilaterally. Or, you can give interesting sounds to reduce attention to tinnitus.

In tinnitus retraining treatment, follow-up is as important as tinnitus counseling. Tinnitus retraining treatment often takes more than 6 months and is a process that requires considerable patience from the patient, so careful counseling and appropriate follow-up are important parts of tinnitus retraining treatment.

Accordingly, in performing patient follow-up and tinnitus counseling, a technology is required to observe and monitor the characteristics of tinnitus, such as the intensity and frequency range of tinnitus, and how they change. To this end, a technology that can automatically measure the minimum masking strength for extracting tinnitus characteristics while minimizing the influence of the examiner is also required.

Korean Patent Registration No. 10-2011-0079846

The purpose of the present invention is to provide a test device, method and computer program that automatically performs measurement of narrowband minimum shielding capable of automatically measuring the minimum shielding strength of a masking sound that masks tinnitus of a subject for each of one or more reference frequency ranges.

The purposes of the present invention are not limited to the purposes mentioned above, and other purposes and advantages of the present invention which are not mentioned can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. In addition, it will be easily understood that the purposes and advantages of the present invention can be realized by the means and combinations thereof indicated in the claims.

A test device for automatically performing measurement of narrowband minimum shielding according to the present invention may include a processor for setting the test sound intensity and the test sound frequency of a test sound output to a subject; an input unit for receiving shielding information indicating whether tinnitus is shielded from the subject who listened to the test sound.

The processor may change and set at least one of the test sound intensity and the test sound frequency in response to the shielding information, and determine a minimum shielding strength of the tinnitus corresponding to each of at least one reference frequency range based on the shielding information, the test sound intensity, and the test sound frequency, thereby generating minimum shielding data.

The above processor can set the test sound intensity to increase by a first reference intensity if the shielding information input to the input unit indicates that the tinnitus is not shielded.

If the shielding information input to the input unit indicates that the tinnitus is shielded, the processor can check previous shielding information, which is shielding information input to the input unit before the shielding information indicating that the tinnitus is shielded, is input to the input unit.

The processor may set the test sound intensity to be reduced by a first reference intensity if the previous shielding information indicates that the tinnitus is shielded or if the previous shielding information does not exist as a result of checking the previous shielding information.

The processor, if the previous shielding information indicates that the tinnitus is not shielded as a result of checking the previous shielding information, may check the test sound intensity and the test sound frequency of the test sound corresponding to the shielding information indicating that the tinnitus is shielded, and determine the checked test sound intensity as the minimum shielding strength corresponding to a reference frequency range in which the checked test sound frequency is included among the one or more reference frequency ranges.

A test method for automatically performing measurement of narrowband minimum shielding according to the present invention may include a step of a processor setting a test sound intensity and a test sound frequency of a test sound output to a subject; a step of an input unit receiving, from the subject who has heard the test sound, shielding information indicating whether tinnitus is shielded; a step of the processor changing and setting at least one of the test sound intensity and the test sound frequency in response to the shielding information; and a step of the processor determining a minimum shielding strength of the tinnitus corresponding to each of at least one reference frequency range based on the shielding information, the test sound intensity, and the test sound frequency to generate minimum shielding data.

The step of changing and setting the above may include a step of increasing and setting the test sound intensity by a first reference intensity when the shielding information input to the input unit indicates that the tinnitus is not shielded.

The step of changing and setting the above may include a step of checking, by the processor, previous shielding information that is shielding information input into the input unit before the shielding information indicating that the tinnitus is shielded is input into the input unit, if the shielding information input into the input unit indicates that the tinnitus is shielded.

The step of changing and setting the above may include a step of reducing and setting the test sound intensity by a first reference intensity if the processor verifies the previous shielding information and the previous shielding information indicates that the tinnitus is shielded or the previous shielding information does not exist.

The step of changing and setting the above may include the step of: if the processor verifies the previous shielding information and the previous shielding information indicates that the tinnitus is not shielded, verifying the test sound intensity and the test sound frequency of the test sound corresponding to the shielding information indicating that the tinnitus is shielded, and determining the verified test sound intensity as the minimum shielding intensity corresponding to a reference frequency range in which the verified test sound frequency is included among the one or more reference frequency ranges.

A computer program according to the present invention can be stored in a computer-readable recording medium so as to perform the inspection method for automatically performing measurement of narrowband minimum shielding according to the present invention described above.

The testing device, method and computer program for automatically performing the measurement of narrowband minimum shielding according to the present invention can accurately and quickly test the characteristics of the tinnitus of the subject without intervention of the ability of the tester by automatically measuring the minimum shielding strength of the masking sound that masks the tinnitus of the subject for each of one or more reference frequency ranges.

FIG. 1 is a block diagram of a testing device that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention.
FIG. 2 is a block diagram of a testing device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating a situation in which a subject performs an examination using an examination device that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention.
FIG. 4 is a drawing illustrating a first inspection screen output by a display unit of an inspection device that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention.
FIG. 5 is a diagram showing minimum shielding data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention.
FIG. 6 is a drawing illustrating a second inspection screen output by a display unit of an inspection device that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention.
FIG. 7 is a diagram showing tinnitus characteristic data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.
FIG. 8 is a diagram showing first minimum shielding data, first tinnitus characteristic data, second minimum shielding data, and second tinnitus characteristic data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.
FIG. 9 is a diagram showing an example of tinnitus change data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.
FIG. 10 is a diagram showing another example of tinnitus change data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.
FIG. 11 is a flowchart of an inspection method for automatically performing measurement of narrowband minimum shielding according to one embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described with reference to the accompanying drawings. However, this is not intended to limit the present invention to specific embodiments, but should be understood to include various modifications, equivalents, and/or alternatives of the embodiments of the present invention. In connection with the description of the drawings, similar reference numerals may be used for similar components.

In this document, the expressions "have", "can have", "include", or "may include" indicate the presence of a feature (e.g., a numerical value, function, operation, or component such as a part), but do not exclude the presence of additional features.

In this document, the expressions "A or B", "at least one of A and/or B", or "one or more of A or/and B" can include all possible combinations of the items listed together. For example, "A or B", "at least one of A and B", or "at least one of A or B" can all refer to cases where (1) at least one A is included, (2) at least one B is included, or (3) both at least one A and at least one B are included.

The expressions "first", "second", "first", or "second" used in this document can describe various components, regardless of order and/or importance, and are only used to distinguish one component from another, but do not limit the components. For example, a first user device and a second user device can represent different user devices, regardless of order or importance. For example, without departing from the scope of the rights set forth in this document, a first component can be named a second component, and similarly, a second component can also be renamed as a first component.

When it is stated that a component (e.g., a first component) is "(operatively or communicatively) coupled with/to" or "connected to" another component (e.g., a second component), it should be understood that the component can be directly coupled to the other component, or can be connected via another component (e.g., a third component). Conversely, when it is stated that a component (e.g., a first component) is "directly coupled to" or "directly connected" to another component (e.g., a second component), it should be understood that no other component (e.g., a third component) exists between the component and the other component.

The expression "configured to" as used herein can be used interchangeably with, for example, "suitable for", "having the capacity to", "designed to", "adapted to", "made to", or "capable of". The term "configured to" does not necessarily mean only that which is "specifically designed to" in terms of hardware. Instead, in some contexts, the expression "a device configured to" can mean that the device is "capable of" doing something together with other devices or components. For example, the phrase "a control unit configured (or set) to perform A, B, and C" can mean a dedicated processor (e.g., an embedded processor) to perform those operations, or a generic-purpose processor (e.g., a CPU or an application processor) that can perform those operations by executing one or more software programs stored in memory.

In particular, in this specification, “~device” may include one or more of a Central Processing Unit (CPU), an Application Processor (AP), and a Communication Processor (CP).

In this specification, “~device” means any kind of hardware device including at least one processor, and may be understood to encompass software configurations operating on the hardware device according to an embodiment. For example, “~device” may be understood to encompass, but is not limited to, smartphones, tablet PCs, desktops, laptops, and user clients and applications running on each device.

The terms used in this document are used only to describe specific embodiments and may not be intended to limit the scope of other embodiments. The singular expression may include the plural expression unless the context clearly indicates otherwise. The terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by a person of ordinary skill in the art described in this document. Among the terms used in this document, terms defined in general dictionaries may be interpreted as having the same or similar meaning in the context of the related technology, and shall not be interpreted in an ideal or excessively formal meaning unless explicitly defined in this document. In some cases, even if a term is defined in this document, it cannot be interpreted to exclude the embodiments of this document.

FIG. 1 is a block diagram of a testing device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention, and FIG. 2 is a block diagram of a testing device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, a test device (100) that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention outputs a test sound to a subject, receives shielding information indicating whether the subject's tinnitus is shielded by the test sound from the subject who has heard the test sound, and determines the minimum shielding strength of the tinnitus based on the shielding information, the test sound intensity of the test sound, and the test sound frequency of the test sound, thereby generating minimum shielding data.

The test device (100) that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention may be configured by combining a laptop, a hearing tester, headphones, and a monitor; however, this is only an example, and the combination of the configuration may be changed as long as it generates minimum shielding data, tinnitus characteristic data and tinnitus change data described below, and can perform the test for this purpose.

Here, the hearing tester may be a device that can output a test sound, which is a masking sound for a hearing test, while preserving the intensity and frequency of the test sound.

To this end, an inspection device (100) that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention may include a processor (110), an output unit (120), a display unit (130), an input unit (140), a communication unit (150), and a storage unit (160).

The processor (110) can set the test sound intensity and test sound frequency of the test sound output to the subject.

At this time, the processor (110) can set the test sound frequency to one of one or more reference frequency ranges.

For example, the one or more reference frequency ranges may be a frequency range from 250 Hz to 12,000 Hz.

For another example, the one or more reference frequency ranges can be a frequency range of 250 Hz to 750 Hz (center frequency: 500 Hz), a frequency range of 750 Hz to 1500 Hz (center frequency: 1000 Hz), a frequency range of 1500 Hz to 3000 Hz (center frequency: 2000 Hz), a frequency range of 3000 Hz to 6000 Hz (center frequency: 4000 Hz), or a frequency range of 6000 Hz to 12000 Hz (center frequency: 8000 Hz).

As another example, the one or more reference frequency ranges may be a frequency range having a center frequency of 500 Hz, a frequency range having a center frequency of 750 Hz, a frequency range having a center frequency of 1000 Hz, a frequency range having a center frequency of 1500 Hz, a frequency range having a center frequency of 2000 Hz, a frequency range having a center frequency of 3000 Hz, a frequency range having a center frequency of 4000 Hz, a frequency range having a center frequency of 6000 Hz, or a frequency range having a center frequency of 8000 Hz, wherein the individual frequency ranges may not overlap.

In this specification, the center frequency of each of one or more reference frequency ranges is 1,000 Hz, 2,000 Hz, 4,000 Hz, and 8,000 Hz, and the frequency ranges do not overlap.

Meanwhile, the processor (110) can change and set the test sound intensity of the test sound output to the subject by increasing or decreasing it by a first reference intensity. Here, the first reference intensity can be 5 dB. In addition, the processor (110) can change and set the test sound intensity of the test sound output to the subject by increasing or decreasing it by a second reference intensity. Here, the second reference intensity can be lower than the first reference intensity, for example, 2 dB.

The process of changing and setting the test sound intensity by the processor (110) will be described later.

Meanwhile, the processor (110) can generate a test sound signal corresponding to a test sound having a set test sound intensity and test sound frequency and output it to the output unit (120).

The output unit (120) can output a test sound corresponding to a test sound signal when a test sound signal corresponding to a test sound for which a test sound intensity and a test sound frequency are set by the processor (110) is input.

The output unit (120) may be equipped with an audio module capable of outputting sound.

For example, the output unit (120) can be implemented as a shielding headset that blocks external noise.

The display unit (130) can display information that should be provided to the subject during the examination.

For example, the display unit (130) can display inspection instructions on the screen.

Additionally, the display unit (130) can display an input button on the screen for receiving shielding information from the subject.

At this time, the input unit (140) can receive shielding information indicating whether tinnitus is shielded from the subject who heard the test sound.

For this purpose, the input unit (140) may be equipped with one or more of a mouse device, a keyboard device, a tablet device, and a touch module.

Specifically, when a user input is entered into an input button displayed on the screen by the display unit (130), the input unit (140) can receive shielding information corresponding to the entered user input.

Hereinafter, a process of generating minimum shielding data by an inspection device (100) that automatically performs measurement of narrowband minimum shielding according to one embodiment of the present invention will be specifically described.

FIG. 3 is a diagram illustrating a situation in which a subject performs a test using a test device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention, FIG. 4 is a diagram illustrating a first test screen output by a display unit of a test device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention, FIG. 5 is a diagram illustrating minimum shielding data generated by a test device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention, and FIG. 6 is a diagram illustrating a second test screen output by a display unit of a test device that automatically performs measurement of narrowband minimum shielding according to an embodiment of the present invention.

Referring further to FIGS. 3 to 6, when the inspection starts, the processor (110) can set the inspection sound intensity and the inspection sound frequency to initial values.

For example, the initial value of the test sound intensity may be 30 dB, and the initial value of the test sound frequency may be a reference frequency range having a center frequency as low as possible among one or more reference frequency ranges (a frequency range having a center frequency of 1,000 Hz according to the example described above).

The processor (110) outputs a test sound signal of a test sound with the test sound intensity and test sound frequency set as initial values to the output unit (120), and the output unit (120) can output a test sound to the subject in response to the test sound signal.

At this time, the processor (110) can control the output unit (120) so that the output unit (120) outputs the inspection sound for a predetermined period of time (e.g., 3 seconds).

Thereafter, the processor (110) can control the display unit (130) to display a first test screen that prompts the subject who has heard the test sound to input shielding information indicating whether the tinnitus is shielded by the test sound.

Accordingly, the subject can input shielding information into the input unit (140) while looking at the first examination screen.

At this time, the processor (110) can determine that when the shield button (B1) is selected and input by the subject, shielding information indicating that tinnitus is shielded by the test sound is input, and when the non-shielding button (B2) is selected and input by the subject, shielding information indicating that tinnitus is not shielded by the test sound is input.

Next, the processor (110) can change and set at least one of the test sound intensity and the test sound frequency of the test sound in response to the input shielding information.

Specifically, if the shielding information input to the input unit (140) indicates that the tinnitus is not shielded, the processor (110) can set the test sound intensity to increase by the first reference intensity.

Thereafter, the processor (110) controls the output unit (120) so that the test sound intensity is increased by the first reference intensity and the set test sound is output, and the input unit (140) can receive shielding information again from the subject who has heard the test sound intensity is increased by the first reference intensity and the set test sound.

Meanwhile, if the shielding information input into the input unit (140) indicates that tinnitus is shielded, the processor (110) can check the previous shielding information, which is the shielding information input into the input unit (140) before the shielding information (currently input shielding information) indicating that tinnitus is shielded is input into the input unit (140).

The processor (110) can set the test sound intensity to be reduced by the first reference intensity if the previous shielding information indicates that tinnitus is shielded or if the previous shielding information does not exist as a result of checking the previous shielding information.

Thereafter, the processor (110) controls the output unit (120) so that the test sound intensity is reduced by the first reference intensity and the set test sound is output, and the input unit (140) can receive shielding information again from the subject who has heard the test sound intensity reduced by the first reference intensity and the set test sound.

Conversely, if the processor (110) checks the previous shielding information and determines that the previous shielding information indicates that the tinnitus is not shielded, it can check the test sound intensity and test sound frequency of the test sound corresponding to the shielding information (currently input shielding information) indicating that the tinnitus is shielded.

That is, the processor (110) can check the test sound intensity and test sound frequency of the test sound recently heard by the subject who input the shielding information indicating that the tinnitus is shielded and the previous shielding information indicating that the tinnitus is not shielded.

Thereafter, the processor (110) can determine the confirmed test sound intensity as the minimum shielding strength corresponding to a reference frequency range that includes the confirmed test sound frequency among one or more reference frequency ranges (R1, R2, R3, R4).

For example, if the confirmed test sound intensity is 50 dB and the confirmed test sound frequency is a frequency range with a center frequency of 1,000 Hz, the processor (110) may determine the minimum shielding strength corresponding to the reference frequency range R1, which is a frequency range with a center frequency of 1,000 Hz, which is the same as the confirmed test sound frequency among one or more reference frequency ranges (R1, R2, R3, R4), as the confirmed test sound intensity of 50 dB.

Thereafter, the processor (110) determines the minimum shielding strength through a process of increasing or decreasing the test sound intensity by the first reference intensity, and then sets the test sound intensity by increasing or decreasing it by the second reference intensity, while determining the minimum shielding strength again based on the input shielding information.

Specifically, the processor (110) sets the test sound intensity by increasing or decreasing it by a first reference intensity, and when the minimum shielding intensity corresponding to a reference frequency range including the test sound frequency among one or more reference frequency ranges (R1, R2, R3, R4) is determined, the test sound frequency can be set to a reference frequency range corresponding to the previously determined minimum shielding intensity, and the test sound intensity can be set to the previously determined minimum shielding intensity.

Here, the test sound frequency is set to a reference frequency range corresponding to the previously determined minimum shielding strength, and the test sound intensity is set to the previously determined minimum shielding strength, and is called a reset test sound.

The processor (110) controls the output unit (120) to output a reset test sound, and the input unit (140) can receive shielding information from a subject who has heard the reset test sound.

Thereafter, if the shielding information input to the input unit (140) indicates that the tinnitus is not shielded, the processor (110) can set the test sound intensity to increase by the second reference intensity.

Here, the second reference intensity may be a lower intensity than the first reference intensity, as described above, for example, 2 dB.

Thereafter, the processor (110) controls the output unit (120) so that the reset test sound is output with the test sound intensity increased by the second reference intensity, and the input unit (140) can receive shielding information again from the subject who has heard the reset test sound with the test sound intensity increased by the second reference intensity.

Meanwhile, if the shielding information input into the input unit (140) indicates that tinnitus is shielded, the processor (110) can check the previous shielding information, which is the shielding information input into the input unit (140) before the shielding information (currently input shielding information) indicating that tinnitus is shielded is input into the input unit (140).

The processor (110) can set the test sound intensity to be reduced by the second reference intensity if the previous shielding information indicates that tinnitus is shielded or if the previous shielding information does not exist as a result of checking the previous shielding information.

Thereafter, the processor (110) controls the output unit (120) so that the reset test sound is output with the test sound intensity reduced by the second reference intensity, and the input unit (140) can receive shielding information again from the subject who has heard the reset test sound with the test sound intensity reduced by the second reference intensity.

Conversely, if the processor (110) checks the previous shielding information and determines that the previous shielding information indicates that the tinnitus is not shielded, it can check the test sound intensity and test sound frequency of the reset test sound corresponding to the shielding information (currently input shielding information) indicating that the tinnitus is shielded.

That is, the processor (110) can check the test sound intensity and test sound frequency of the reset test sound recently heard by the examinee who input the shielding information indicating that the tinnitus is shielded and the previous shielding information indicating that the tinnitus is not shielded.

Thereafter, the processor (110) can determine the identified test sound intensity as a minimum shielding strength candidate corresponding to a reference frequency range that includes the identified test sound frequency among one or more reference frequency ranges (R1, R2, R3, R4).

Next, the processor (110) may perform the process of determining a minimum shielding strength candidate using a reset test sound multiple times, and determine an average of a plurality of minimum shielding strengths determined by performing the process multiple times as a minimum shielding strength corresponding to a reference frequency range that includes the identified test sound frequency among one or more reference frequency ranges (R1, R2, R3, R4).

That is, the processor (110) first determines the minimum shielding strength of the reference frequency range (R1) including the test sound frequency of the initial value through a process of increasing or decreasing the test sound strength of the test sound whose test sound strength is set as the initial value by a first reference strength, and then determines the minimum shielding strength candidate of the reference frequency range (R1) including the test sound frequency of the initial value through a process of increasing or decreasing the test sound strength of the reset test sound whose test sound strength is set as the previously determined minimum shielding strength by a second reference strength, and then determines the average of the minimum shielding strength candidates as the minimum shielding strength (MML1) of the reference frequency range (R1) including the test sound frequency of the initial value.

Thereafter, the processor (110) can determine the minimum shielding strengths (MML2, MML3, MML4) respectively through a process of increasing or decreasing the test sound intensity of the above-described test sound by the first reference intensity and setting the test sound intensity of the above-described reset test sound by the second reference intensity for each of the reference frequency ranges (R2, R3, R4) for which the minimum shielding strength is not determined among one or more reference frequency ranges (R1, R2, R3, R4).

That is, the processor (110) can determine the minimum shielding strength (MML1, MML2, MML3, MML4) for each of one or more reference frequency ranges (R1, R2, R3, R4) and generate the determined result as the minimum shielding data of the subject.

Meanwhile, a processor (110) according to another embodiment may control the display unit (130) to display an unpleasant intensity button (B3) in addition to the shield button (B1) and the unshielded button (B2).

According to another embodiment, when the unpleasant intensity button (B3) is selected and input by the subject, the processor (110) may determine that unpleasant intensity information indicating that the intensity of the test sound or reset test sound output before the unpleasant intensity button (B3) is selected and input by the subject is an intensity that causes discomfort to the subject has been input.

At this time, if the processor (110) according to another embodiment is input with the discomfort intensity information before the minimum shielding intensity is determined for the reference frequency range including the test sound frequency of the test sound or the reset test sound, the processor may divide the reference frequency range including the test sound frequency of the test sound or the reset test sound into a plurality of detailed reference frequency ranges, set the test sound frequency of the test sound or the reset test sound to one of the detailed reference frequency ranges, and then increase or decrease the test sound intensity of the test sound by the first reference intensity and set it, or increase or decrease the test sound intensity of the reset test sound by the second reference intensity and set it, thereby determining the minimum shielding intensity corresponding to the set detailed reference frequency range.

Through this, the present invention can accurately test the minimum masking strength of tinnitus even for subjects with hearing loss.

Hereinafter, a test device (100) that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention will be described.

FIG. 7 is a diagram showing tinnitus characteristic data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.

Referring further to FIG. 7, an inspection device (100) that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention can generate tinnitus characteristic data representing the characteristics of tinnitus based on minimum shielding data.

In addition, the test device (100) that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention can generate tinnitus change data representing changes in tinnitus felt by the subject.

First, the process of generating tinnitus characteristic data by a test device (100) that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention will be described.

According to another embodiment of the present invention, a processor (110) of a test device (100) that automatically performs measurement of narrowband minimum shielding can generate tinnitus characteristic data representing the characteristics of tinnitus based on minimum shielding data generated by determining minimum shielding strengths (MML1, MML2, MML3, MML4) for tinnitus of a subject for each of one or more reference frequency ranges (R1, R2, R3, R4) through the above-described test.

To this end, the processor (110) may identify the smallest minimum shielding strength (MML3) among the minimum shielding strengths (MML1, MML2, MML3, MML4) for each of one or more reference frequency ranges (R1, R2, R3, R4) as the tinnitus shielding strength (MML3), and identify the reference frequency range (R3) corresponding to the tinnitus shielding strength (MML3) among one or more reference frequency ranges (R1, R2, R3, R4) as the tinnitus frequency range (R3).

Next, the processor (110) can determine the tinnitus intensity (T) of the tinnitus in the tinnitus frequency range (R3) in response to the tinnitus masking strength (MML3).

At this time, the processor (110) can determine the tinnitus intensity (T) of the tinnitus in the tinnitus frequency range (R3) to be less than the tinnitus masking strength (MML3).

Specifically, the processor (110) can determine the tinnitus sound intensity (T) of the tinnitus in the tinnitus frequency range (R3) by reducing the tinnitus sound masking strength (MML3) by a reduction ratio. For example, the reduction ratio can be 90%, but can be within a range exceeding 0% and less than 100%.

Additionally, the processor (110) may determine the tinnitus intensity (T) of the tinnitus in the tinnitus frequency range (R3) by reducing the amount of reduction in the tinnitus masking strength (MML3). For example, the reduction strength may be 5 dB, but may be within a range that exceeds 0 dB and is less than the tinnitus masking strength (MML3).

At this time, the processor (110) can generate tinnitus characteristic data by including the tinnitus intensity (T) and tinnitus frequency range (R3) of the tinnitus determined in the tinnitus characteristic data.

Meanwhile, the processor (110) calculates the difference between the smallest minimum shielding strength (MML3) and the next largest minimum shielding strength (MML2) among the minimum shielding strengths (MML1, MML2, MML3, MML4) for one or more reference frequency ranges (R1, R2, R3, R4), as the minimum shielding strength difference, and if the minimum shielding strength difference is less than the preset reference strength, the smallest minimum shielding strength (MML3) and the next largest minimum shielding strength (MML2) among the minimum shielding strengths (MML1, MML2, MML3, MML4) for one or more reference frequency ranges (R1, R2, R3, R4) can be identified as the tinnitus shielding strengths (MML2, MML3).

Accordingly, the tinnitus intensity and tinnitus frequency range of the tinnitus can be accurately determined even when the tinnitus frequency of the tinnitus is a wideband frequency that is not included in just one of the reference frequency ranges (R1, R2, R3, R4) but is included in multiple reference frequency ranges.

Hereinafter, a process of generating tinnitus change data by a test device (100) that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention will be described.

FIG. 8 is a diagram showing first minimum shielding data, first tinnitus characteristic data, second minimum shielding data, and second tinnitus characteristic data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention, FIG. 9 is a diagram showing an example of tinnitus change data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention, and FIG. 10 is a diagram showing another example of tinnitus change data generated by a testing device that automatically performs measurement of narrowband minimum shielding according to another embodiment of the present invention.

Referring further to FIGS. 8 to 10, the processor (110) may generate tinnitus change data indicating a change in tinnitus based on at least one of first minimum shielding data generated from a test performed at a first test time point (t1), second minimum shielding data generated from a test performed at a second test time point (t2) prior to the first test time point (t1), first tinnitus characteristic data generated based on the first minimum shielding data, and second tinnitus characteristic data generated based on the second minimum shielding data.

Here, the change in tinnitus can mean the change in the tinnitus intensity and tinnitus frequency range measured in the recent test compared to the previous test.

To this end, the processor (110) may calculate a sum between a plurality of minimum shielding strengths (MMML1, MML2, MML3, MML4) of the first minimum shielding data as a first minimum shielding strength sum, and may calculate a sum between a plurality of minimum shielding strengths (MMML1', MML2', MML3', MML4) of the second minimum shielding data as a second minimum shielding strength sum.

Thereafter, the processor (110) can calculate the difference between the first minimum shielding strength sum and the second minimum shielding strength sum as the first shielding strength change for the tinnitus.

Meanwhile, a processor (110) according to another embodiment may generate tinnitus reduction information indicating that the tinnitus of the subject has been reduced at the first examination time point (t1) compared to the second examination time point (t2) when the first shielding intensity change exceeds the reference intensity change, and control the display unit (130) so that the display unit (130) displays the tinnitus reduction information.

At this time, the processor (110) according to another embodiment can set the reference intensity change based on MCID (Minimal Clinical Important Different).

This MCID may be information collected from external sources.

Meanwhile, the processor (110) can calculate the difference between the tinnitus masking strength (MML3) confirmed based on the first minimum shielding data and the tinnitus masking strength (MML3') confirmed based on the second minimum shielding data as a change in the second shielding strength for the tinnitus.

At this time, the processor (110) can generate tinnitus change data by including at least one of the first shielding strength change and the second shielding strength change in the tinnitus change data.

Meanwhile, a processor (110) according to another embodiment can calculate the difference between the tinnitus intensity (T) included in the first tinnitus characteristic data and the tinnitus intensity (T') included in the second tinnitus characteristic data as a tinnitus intensity change for the tinnitus.

Additionally, a processor (110) according to another embodiment can calculate the difference between the tinnitus frequency range (R3 of t1) included in the first tinnitus characteristic data and the tinnitus frequency range (R3 of t2) included in the second tinnitus characteristic data as a tinnitus frequency change for the tinnitus.

Through this, the processor (110) according to another embodiment can generate tinnitus change data including not only changes in tinnitus intensity but also changes in tinnitus frequency.

At this time, a processor (110) according to another embodiment may generate tinnitus change data by including at least one of tinnitus sound intensity change and tinnitus sound frequency change in the tinnitus change data.

The processor (110) can perform the operations of each component described above, and may include one or more cores (not shown) and a graphics processing unit (not shown) and/or a connection path (e.g., a bus, etc.) for transmitting and receiving signals with other components.

The processor (110) may be configured to perform the operations of each component described above by executing one or more instructions stored in the storage unit (160).

The storage unit (160) can store programs (one or more instructions) for processing and controlling the processor (110). The programs stored in the storage unit (160) can be divided into multiple modules according to function.

The communication unit (150) can transmit and receive data, information, and signals to perform the functions described above.

The storage unit (160) can store data, information and signals to perform the functions described above.

FIG. 11 is a flowchart of an inspection method for automatically performing measurement of narrowband minimum shielding according to one embodiment of the present invention.

Referring to FIG. 11, in step S1, the processor can set the test sound intensity and the test sound frequency of the test sound output to the subject.

Afterwards, in step S2, the input unit can receive masking information from the subject who heard the test sound, indicating whether the tinnitus is masked.

Next, at step S3, the processor can change and set one or more of the test sound intensity and the test sound frequency in response to the shielding information.

Finally, at step S4, the processor can determine a minimum masking strength of the tinnitus corresponding to each of one or more reference frequency ranges based on the masking information, the test sound intensity, and the test sound frequency, thereby generating minimum masking data.

The present invention has been described with reference to preferred embodiments. Those skilled in the art will understand that the present invention can be implemented in modified forms without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered from an illustrative rather than a restrictive perspective. The scope of the present invention is indicated by the claims, not the foregoing description, and all differences within the scope equivalent thereto should be interpreted as being included in the present invention.

As described above, although the present invention has been described by means of limited embodiments and drawings, the present invention is not limited thereto, and various modifications and variations are possible by those skilled in the art within the technical idea of the present invention and the scope of equivalents of the patent claims to be described below.

100: Test device that automatically performs measurement of narrowband minimum shielding
110 : Processor
120 : Output section
130 : Display section
140 : Input section
150 : Communication Department
160 : Storage

Claims (11)

A processor that sets the test sound intensity and the test sound frequency of the test sound output to the subject;
An input unit for receiving shielding information indicating whether tinnitus is shielded from the subject who heard the test sound;
The above processor
In response to the above shielding information, at least one of the above test sound intensity and the above test sound frequency is changed and set,
A method for generating minimum shielding data, characterized in that the minimum shielding strength of the tinnitus corresponding to each of one or more reference frequency ranges is determined based on the shielding information, the test sound intensity, and the test sound frequency.
A test device that automatically performs measurements of narrowband minimum shielding.
In the first paragraph,
The above processor
If the shielding information entered into the input section indicates that the tinnitus sound is not shielded, the test sound intensity is set to increase by the first reference intensity.
A test device that automatically performs measurements of narrowband minimum shielding.
In the first paragraph,
The above processor
If the shielding information entered into the input unit indicates that the tinnitus is shielded, the previous shielding information, which is shielding information entered into the input unit before the shielding information indicating that the tinnitus is shielded is input into the input unit, is checked.
A test device that automatically performs measurements of narrowband minimum shielding.
In the third paragraph,
The above processor
As a result of checking the above previous shielding information, if the above previous shielding information indicates that the tinnitus sound is shielded or the above previous shielding information does not exist, the test sound intensity is set to be reduced by the first reference intensity.
A test device that automatically performs measurements of narrowband minimum shielding.
In the third paragraph,
The above processor
As a result of checking the previous shielding information, if the previous shielding information indicates that the tinnitus is not shielded, the test sound intensity and the test sound frequency of the test sound corresponding to the shielding information indicating that the tinnitus is shielded are checked, and the checked test sound intensity is determined as the minimum shielding intensity corresponding to a reference frequency range in which the checked test sound frequency is included among the one or more reference frequency ranges.
A test device that automatically performs measurements of narrowband minimum shielding.
A step for setting the test sound intensity and the test sound frequency of the test sound output to the subject by the processor;
A step in which the input unit receives shielding information indicating whether tinnitus is shielded from the subject who heard the test sound;
The step of the above processor changing and setting at least one of the test sound intensity and the test sound frequency in response to the shielding information; and
The step of generating minimum shielding data by determining the minimum shielding strength of the tinnitus corresponding to each of one or more reference frequency ranges based on the shielding information, the test sound intensity, and the test sound frequency by the processor; characterized in that it includes;
A test method for automatically performing measurements of narrowband minimum shielding.
In Article 6,
The steps to change and set the above are:
The above processor comprises a step of setting the test sound intensity by increasing it by a first reference intensity if the shielding information input into the input unit indicates that the tinnitus is not shielded.
A test method for automatically performing measurements of narrowband minimum shielding.
In Article 6,
The steps to change and set the above are:
The above processor comprises a step of checking previous shielding information, which is shielding information input to the input unit before the shielding information indicating that the tinnitus is shielded, is input to the input unit, if the shielding information input to the input unit indicates that the tinnitus is shielded.
A test method for automatically performing measurements of narrowband minimum shielding.
In Article 8,
The steps to change and set the above are:
A step of reducing and setting the test sound intensity by a first reference intensity when the processor verifies the previous shielding information and the previous shielding information indicates that the tinnitus is shielded or the previous shielding information does not exist; characterized in that it includes;
A test method for automatically performing measurements of narrowband minimum shielding.
In Article 8,
The steps to change and set the above are:
A method for controlling a sound masking apparatus, comprising: a step of: checking the test sound intensity and the test sound frequency of the test sound corresponding to the shielding information indicating that the tinnitus is masked, if the previous shielding information indicates that the tinnitus is not masked as a result of the processor checking the previous shielding information; and determining the checked test sound intensity as the minimum shielding intensity corresponding to a reference frequency range in which the checked test sound frequency is included among the one or more reference frequency ranges;
A test method for automatically performing measurements of narrowband minimum shielding.
A computer program stored on a computer-readable recording medium, which is combined with a computer as hardware and enables the method of claim 6 to be performed.