KR20110018829A - Portable sound source playing apparatus for testing hearing ability and method for performing thereof - Google Patents

Abstract

PURPOSE: A portable sound source playing apparatus is provided to improve the reliability of a hearing ability test by outputting a signal displaying one or more phonemics. CONSTITUTION: A portable sound source playing apparatus(100) includes a phonemic signal outputting process, a response acquiring process, and a hearing ability testing process. One or more phonemic signals are outputted. The response of a person to be tested is acquired with respect to the outputted phonemic signals. The hearing ability testing process is based on the hearing property of a hearing degree with respect to a frequency band forming the phonemics of the phonemic signals.

Description

Portable sound source playing apparatus for testing hearing ability and method for performing

The present invention relates to a portable sound source reproducing apparatus for examining hearing and a method of performing the same.

Recently, the hearing loss population is increasing due to the use of sound equipment, an increase in the proportion of the elderly population, and an increase in the noise environment. Hearing tests may be performed by varying the frequency and magnitude of the pure tone and presenting it to the subject and observing the subject's response.

The present invention provides a method for inspecting the hearing of a subject in a portable sound source reproducing apparatus and a portable sound source reproducing apparatus for inspecting the hearing of a subject. Further, the present invention provides a computer-readable recording medium having recorded thereon a program for executing the method on a computer. The technical problem to be achieved by the portable sound source reproducing apparatus for inspecting the hearing of the subject is not limited to the technical problems as described above, there may be another technical problem.

In the portable sound source reproducing apparatus, a method for checking a hearing ability of a subject may include: outputting a signal representing at least one phoneme; Obtaining a response of the examinee to an audible degree of the output signal; And examining the hearing of the examinee based on an auditory characteristic indicating an audible degree to a frequency band including a frequency constituting the phoneme according to the obtained response.

Provided is a computer readable recording medium having recorded thereon a program for executing a method of testing a hearing ability of a subject in a portable sound source reproducing apparatus.

The sound source playback apparatus includes an output unit for outputting a signal representing at least one phoneme; A user interface unit configured to receive a response of a test subject to an audible degree of the output signal; And a processor that checks the hearing of the examinee based on an auditory characteristic indicating an audible degree to a frequency band including a frequency constituting the phoneme according to the received response.

As described above, the hearing test may be conveniently performed by using a portable sound source reproducing apparatus that performs a hearing test using a sound familiar to the subject. In addition, the portable sound source reproducing apparatus can improve the reliability of the test while reducing the time required to test hearing because the test is not performed by repeatedly listening to the pure sound.

1 is a configuration diagram of a sound source reproducing apparatus.
2 is a diagram illustrating frequency characteristics of Korean phonemes.
3 is a diagram illustrating frequency characteristics of English phonemes.
4 is a diagram illustrating an example of a phonetically balanced word.
5 is a diagram illustrating an example of amplification gain versus frequency.
6 is a flowchart illustrating a method of checking a hearing of a subject in a sound source reproducing apparatus.

Hereinafter, a sound source reproducing apparatus will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a sound source reproducing apparatus 100. Referring to FIG. 1, the sound source reproducing apparatus 100 includes an output unit 110, a memory 120, a user interface unit 130, a processor 140, an input / output interface 150, and a communication interface 160. do. The sound source reproducing apparatus 100 of FIG. 1 describes only the components related to the sound source reproducing apparatus 100 that inspects the hearing, displays the test result, or applies the test result to reproduce the sound source. Therefore, it will be understood by those skilled in the art that the sound source reproducing apparatus 100 may further include other general purpose components in addition to the components shown in FIG. 1.

The sound source reproducing apparatus 100 is portable by a subject who examines the hearing and outputs a signal for reproducing a sound source or reproducing a sound source. In this case, being portable means that there is no inconvenience in carrying or holding the sound source reproducing apparatus 100 in the hand. In addition, the apparatus for reproducing a sound source refers to an apparatus for generating a sound that can be heard by the examinee from data stored in the form of a digital or analog signal, or outputting a signal for generating a sound that can be heard by the examinee. Examples of the sound source playback apparatus 100 include a mobile phone, a personal digital assistant, an MP3 player, a compact disc player, a portable media player. Media player) and the like, and the sound source reproducing apparatus 100 is not limited thereto, and includes a sound generating apparatus capable of generating a sound that can be heard by the examinee or outputting a signal that generates a sound that can be heard by the examinee. .

The sound source reproducing apparatus 100 is a device in which a function of inspecting hearing is added to a device for reproducing a sound that can be heard by an examinee or outputting a signal representing a sound that can be heard by the examinee. Hearing ability means the ability to hear sounds with the ear, and a hearing test is a test that measures the degree of hearing. That is, the sound source reproducing apparatus 100 refers to a device for reproducing a sound source having a function of measuring the degree of the ability to hear sound by the ear or outputting a signal for reproducing the sound source.

In this case, the signal for reproducing the sound source is a signal for generating sound. That is, the output unit 110 outputs a signal for generating sound. The signal for generating sound is configured in the form of a waveform having an amplitude and a frequency phase. The signal is amplified through an amplifier to generate sound, or the sound is generated by an earphone or the like, which is another kind of device for reproducing another sound source connected to the sound source reproducing apparatus 100 through the input / output interface 150. do. The sound source reproducing apparatus 100 may test the hearing ability of the subject by referring to the degree of listening to the sound generated in this manner.

The output unit 110 outputs a signal representing at least one phoneme. In this case, one or more phonemes according to the present exemplary embodiment may be syllables or words (word sounds), and accordingly, the output unit 110 may output a signal representing at least one syllable, and also, the output unit 110. ) May output a signal representing at least one note.

For example, syllables consist of at least one phoneme. Also, a speech sound is composed of at least one syllable, and in the case of only one syllable according to the number of syllables composed of a single syllable, a speech composed of two syllables is composed of two syllables and three syllables. The syllables are called three syllables, and in this way, a syllable consisting of a plurality of syllables may be represented. Syllable is a phonetics term that refers to the smallest unit of pronounciation. Syllables consist of consonant-vowel-consonants (for example, a force composed of "ㅎ -l- ㅁ"), or consonant-vowels (for example, a key composed of "key-l") Or vowels (eg, a).

The user may operate the user interface 130 of the sound source reproducing apparatus 100 to generate a sound represented by the signal output from the output unit 110. The sound generated by reproducing the signal output from the sound source reproducing apparatus 100 stimulates the auditory organ of the subject so that the subject can listen to the sound. The output unit 110 outputs an audio signal for generating sound, and the user interface 130 (for example, a speaker, etc.) generates a sound directly from the sound source reproducing apparatus 100 using the output audio signal. can do. In addition, the output unit 110 outputs an audio signal for generating sound, and the input / output interface 150 reproduces another sound source connected to the sound source playback device 100 (for example, earphone, Bluetooth earphone, speaker, etc.) Transmits an audio signal to a device for reproducing the another sound source connected to the sound source reproducing apparatus 100, and generates a sound represented by the output signal by the device for reproducing the another sound source. do.

Therefore, the output unit 110 generates a sound directly in the sound source playback apparatus 100 through the user interface 130 or reproduces another sound source connected to the sound source playback apparatus 100 through the input / output interface 150. Sound is generated by the device. The signal output from the output unit 110 may be generated by the processor 140 based on the data read from the memory 130. The output unit 110 may be included in the processor 140 or may exist in a unique chip form.

The memory 120 stores at least one phoneme group classified based on the frequency indicated by the phoneme. In addition, the memory 120 according to the present exemplary embodiment may store groups of syllables classified based on frequencies represented by phonemes constituting syllables.

In this case, the group of phonemes or the group of syllables include phonemes or syllables included in each frequency band for a plurality of frequency bands within an audible frequency range. The audible frequency range is a frequency range of sound waves that a human ear can feel as a sound and means a frequency band of about 15 Hz to 20 KHz. That is, the audio frequency range may be classified into a plurality of frequency bands, and syllables composed of phonemes included in the classified frequency bands may be grouped.

If the memory 120 is a person having ordinary skill in the art related to the sound source reproducing apparatus 100 for checking hearing as a conventional storage medium, the memory 120 may be a hard disk drive (HDD), a ROM. (Read Only Memory), RAM (Random Access Memory), Flash Memory (Flash Memory) and Memory Card (Memory Card) are all included.

As described above, a syllable refers to a minimum unit of pronunciation, and one syllable is composed of at least one phoneme. Phoneme means the smallest unit of phonology in phonology. In this case, phonology means a unit of sound that distinguishes the meaning of words. In other words, phonemes are the smallest unit of sound that distinguishes the meaning of words. The phoneme in Korean is / ah /, / yi /, / woo /, / oh /, / uh /, / yes /, / b /, / ㅁ /, / ㄹ /, / ㄱ /, / ㄲ /, / ㅋ /, / ㅂ /, / ㅃ /, / ㅍ /, / ㅎ /, / ㄷ /, / ㄸ /, / ㅌ /, / ㅈ /, / ㅉ /, / ㅊ /, / ㅅ /, / ㅆ / It consists of.

2 is a diagram illustrating frequency characteristics of Korean phonemes. Referring to FIG. 2, a range of frequencies constituting consonants and vowels by classifying phonemes into consonants and vowels for Korean phonemes is illustrated, and each consonant and vowels are divided into a plurality of groups according to a range of peak frequencies. Are classified as

Referring to FIG. 2, the list of consonants 201 indicates a frequency range constituting consonants, and the consonants are classified into three groups according to the frequency ranges. Group 1 (2011) means consonants belonging to a frequency range of about 250 Hz to less than 500 Hz, group 2 (2012) refers to consonants belonging to a frequency range of about 650 Hz to less than 3000 Hz, and group 3 (2013) refers to about 3000 Hz Consonants belonging to the frequency range of less than 7000Hz.

Consonants belonging to group 1 (2011) include / b /, / ㅁ /, / ㄹ /, and consonants belonging to group 2 (2012) are / ㄱ /, / ㄲ /, / ㅋ /, / ㅂ /, / ㅃ /, / ㅍ /, / ㅎ /, and consonants belonging to Group 3 (2013) are / ㄷ /, / ㄸ /, / ㅌ /, / ㅈ /, / ㅉ /, / ㅊ /, / ㅅ / , / ㅆ / and so on.

In addition, the list of vowels 202 represents the frequency ranges that make up the vowels. Referring to the list of vowels 202, one vowel consists of three formant frequencies. In this case, the formant frequency refers to peak frequencies of which energy is relatively high in a frequency spectrum obtained by integrating a loudness (dB) of a time representing a vowel to the frequency axis. Referring to the list of collections 202, three formant frequencies constituting one collection may be represented as a first formant, a second formant, and a third formant, respectively, in order from the low frequency band. As shown in the list of vowels 202, since the frequency bands of the first and third formants are similar in most vowels, the vowels can be classified into three groups around the second formant band. have. Group 2-1 2021 according to this classification means the vowels in which the second formant is in the frequency range of about 600 Hz to less than 800 Hz, and group 2-2 2022 indicates that the second formant is about 1000 Hz to 1300 Hz. Vowels belonging to a frequency range of less than, and group 2-3 (2023) refers to vowels belonging to a frequency range of about 2000 Hz or more and less than 3000 Hz.

Vowels belonging to group 2-1 (2021) include / right /, / oh /, etc. Vowels belonging to group 2-2 (2022) include / ah /, / uh /, etc., group 2-3 (2023) ) Vowels are / / / / / /

For example, referring to FIG. 2, the hearing test result group 3 (2013) of the subject has low audibility for consonants, and also has a vowel / right / and / a / (or vowel / oh / wa If the subject is not well distinguished, the subject may have a frequency range of about 1000 Hz to less than 1300 Hz in the frequency range of Group 2-2 (2022) and a frequency band of about 2000 Hz to less than 3000 Hz in the frequency range of Group 3 (2013). It can be seen that there is a hearing loss.

2 is a diagram illustrating a frequency characteristic of a Korean phoneme, and the frequency characteristic of the phoneme is applicable to other languages as well as Korean.

3 is a diagram illustrating frequency characteristics of English phonemes. Referring to FIG. 3, a range of frequencies constituting English phonemes is illustrated, and each phoneme is classified into a plurality of groups according to the range of frequencies.

Referring to FIG. 3, the list of phonemes 301 represents a frequency range constituting the phonemes, and the phonemes are classified into three groups according to the frequency ranges. Group 1 3011 refers to phonemes belonging to a frequency range of about 300 Hz to less than 1200 Hz, group 2 3012 refers to phonemes belonging to a frequency range of about 1200 Hz to less than 4000 Hz, and group 3 3013 is about 4000 Hz. Phonemes belonging to the frequency range of less than 8000Hz.

Phonemes belonging to group 1 3011 are / m /, / d /, / b /, / i /, / o /, / a /, / n /, / e /, / l /. / u /, / r /, etc., and the phonemes belonging to group 2 3012 include / p /, / h /, / g /, / k /, / ch /, / sh /, and the like. Phonemes belonging to 3013) are / f /, / s / and / th /.

Therefore, referring to the frequency characteristics of the phonemes of Korean and English illustrated in FIGS. 2 and 3, the hearing characteristics of the examinee may be determined according to the hearing test result of the examinee.

Referring back to FIG. 1, the memory 120 stores a group of phonemes or groups of syllables composed of at least one phoneme classified based on a peak frequency indicated by the phonemes constituting the syllable. At this time, the phonemes or syllables constituting the groups may be extracted from the "Phonetically Balanced Word". The term "Phonetically Balanced Word" is composed of a group of syllables in which the phonemes are generally balanced because the sound pressures generated when the syllables are pronounced are similar.

4 is a diagram illustrating an example of a phonetically balanced word. Referring to FIG. 4, FIG. 4 shows a phonetic equivalent sound pressure word list 401, and the phonetic equivalent sound pressure word list 401 includes four groups, each of which has syllables having equivalent intelligibility. It is configured to include. The phonetic equivalent sound pressure word list 401 may be composed of group 1 4011, group 2 4012, group 3 4013, and group 4 4014. In FIG. 4, single syllables included in the groups Presented. The phonologically identical sound pressure word list 401 illustrated in FIG. 4 corresponds to an example of a group of syllables in which phonemes are generally balanced due to similar sound pressures generated when a syllable is pronounced. It is not limited to the phonologically identical sound pressure word list 401 illustrated in FIG. 4, and the hearing ability of the examinee is examined using another list of syllables in which the phoneme is generally balanced due to the similar sound pressure generated when the syllable is pronounced. Can be.

Referring back to FIG. 1, the memory 120 stores the phonologically identical sound pressure word list 401 illustrated in FIG. 4, and also classifies syllables classified based on peak frequencies represented by phonemes constituting the syllables. Groups may be stored. In this case, in the group of syllables, the syllables may be extracted from the phonetic identical sound pressure word list 401, but are not limited thereto.

In addition, the memory 120 may store groups of phonemes including at least one phoneme classified based on a frequency indicated by the phoneme.

The output unit 110 reads at least one phoneme or syllable stored in the memory 120, and outputs a signal representing the read phoneme or syllable. For example, on the assumption that the phonetic equivalent sound pressure word list 401 illustrated in FIG. 4 is stored in the memory 120, the output unit 110 may store the phonetic equivalent sound pressure word list stored in the memory 120 ( A signal representing a plurality of syllables randomly extracted from the syllables in 401 is output. Alternatively, a signal representing a syllable extracted by extracting at least one syllable from each group of syllables classified based on the peak frequency represented by the phonemes constituting the syllable among the syllables of the same phonetic pressure word list 401 Output According to the test subject's response to the sound generated by the output signal, the auditory characteristic of the test subject may be determined.

For example, if the subject's response to the syllables included in the group for about 1000 Hz or more and less than 1300 Hz is 20%, the auditory characteristics of the subject may be determined that the subject's audibility is low in the frequency band. In addition, the amplification gain for the frequency band corresponding to the group may be set to 40 dB to compensate for a signal for reproducing a sound source. Alternatively, the hearing test result according to the hearing characteristics of the test subject may be displayed to the test subject through the user interface 130. For example, the sentence “Difficult to hear the sound of the high frequency band” to the examinee may be notified to the examinee through the user interface 130, or a graph indicating the degree of hearing loss of the examinee may be displayed. Therefore, the sound source reproducing apparatus 100 may conveniently determine the auditory characteristics of the subject and the correction may be reflected in the sound source reproducing apparatus 100.

The output signal is reproduced as sound through the user interface unit 130 or the input / output interface 150. The sound source reproducing apparatus 100 shown in FIG. 1 may examine a subject's hearing for a plurality of frequency bands using only one test using at least one phoneme or syllable, and thus the subject's response using a pure tone. The measurement time can be reduced compared to the method of measuring, and the case where the pure tone is not constant can be prevented from decreasing the reliability of the test.

Although a speech hearing test can be performed using a speech familiar to a subject, the conventional speech hearing test requires a lot of test time and requires visits to places where the test is performed. The inspection may be conveniently performed using the apparatus 100.

The user interface 130 receives a response of the examinee to an audible degree of the sound reproduced by the signal output by the output unit 110. The user interface 130 provided in the sound source reproducing apparatus 100 receives an input signal from the subject and displays output information to the subject. For example, the user interface 130 includes all input / output devices such as a display panel, a mouse, a keyboard, an input button, a touch screen, an LCD screen, a monitor, and a speaker provided in the sound source playback apparatus 100. Therefore, the user interface 130 may display a hearing test result of the testee according to the hearing characteristics of the testee, and receive volume information from the testee. In addition, the sound source reproducing apparatus 100 may recognize the voice of the examinee or may receive an input signal input by the examinee and obtain a response of the examinee to the sound represented by the signal output by the output unit 110. .

The examinee listens to the sound generated by the output unit 110 and inputs a response to the degree of audibility through the user interface 130. For example, the sound represented by the syllable "force" is reproduced through the sound source reproducing apparatus 100, and the user responds to whether the user listens to the sound indicated by the syllable as the "force". Through). At this time, the audible degree means the degree to which the examinee listens well. Accordingly, the audible degree according to the present embodiment may mean whether the subject listened to the syllable as a result of listening to the sound representing the syllable generated by the sound source reproducing apparatus 100.

As another example, the sound represented by the phoneme “b” is reproduced through the sound source reproducing apparatus 100, and the examinee responds to whether the user has listened to the sound indicated by the phoneme by “b”. 130). Accordingly, the audible degree according to the present embodiment may mean whether the testee listened to the sound as the phoneme as a result of listening to the sound representing the phoneme generated in the sound source playback apparatus 100.

As another example, the sound represented by the phoneme "b" is reproduced through the sound source reproducing apparatus 100, and the user responds to whether the user has listened to the sound indicated by the phoneme as "b". Input through 130. Accordingly, the audible degree according to the present embodiment may mean whether the testee listened to the sound as the phoneme as a result of listening to the sound representing the phoneme generated in the sound source playback apparatus 100.

The user interface unit 130 may obtain a response to an audible degree from the subject using various user interfaces. For example, in order to measure the understanding of phonemes or syllables, by directly inputting a phoneme or syllable heard by the examinee, whether the input phoneme or syllable is the same as the phoneme or syllable reproduced through the sound source reproducing apparatus 100. The audible level of the subject can be measured by judging. Alternatively, the examinee may measure an audible degree of the examinee by selecting one phoneme or syllable corresponding to the phonemes or syllables reproduced through the sound source reproducing apparatus 100 among examples of the plurality of phonemes or syllables. Alternatively, the examinee may select whether to listen to the phoneme or the syllable in response to "yes" or "no".

Since the above-described methods are not possible as an example of acquiring a response from the subject, the method of acquiring a response to the audible level of the subject through the sound source reproducing apparatus 100 is not limited thereto, and various methods are possible. Able to know.

The processor 140 controls the overall functions of the sound source playback apparatus 100. The processor 140 controls the output unit 110, the memory 120, the user interface unit 130, the input / output interface 150, and the communication interface 160. The processor 140 checks the hearing of the examinee based on an auditory characteristic indicating an audible degree for the frequency band including the peak frequency constituting the syllable according to the response received from the examinee.

For example, the processor 140 causes the output unit 110 to output a signal representing at least one phoneme or syllable, and the examinee listens to the sound generated by the output signal and listens to the sound. The response to the degree of audibility is input through the user interface 130. The processor 140 determines an auditory characteristic of the examinee by referring to the received response.

As described above, the examinee inputs a response to an audible degree of a plurality of phonemes or syllables through the user interface unit 130, and the processor 140 analyzes the input responses to examine the input response of the sound source. Determine the auditory characteristics of the subject indicating the degree of audibility for frequency. That is, the processor 140 determines an auditory characteristic of the examinee with respect to the frequency domain including the frequency indicated by the phoneme or syllable with reference to the examinee's response. For example, if the subject has a low audibility for the phonemes or syllables included in the frequency band of about 600 Hz to less than 800 Hz, that is, the accuracy of the response to the phonemes or syllables included in the frequency band is low. In a low case, the subject may determine that it is difficult to listen to a frequency band of about 600 Hz to less than 800 Hz. The hearing test of the examinee may be performed by determining the hearing characteristics of the examinee based on the determination result.

In addition, the processor 140 corrects a signal for reproducing a sound source by applying an auditory characteristic of the examinee. The processor 140 may perform a correction by compensating a signal for reproducing a sound source by increasing a gain for a frequency range in which the subject feels difficult to hear by reflecting the auditory characteristics of the subject. The corrected signal is output by the output unit 110 and can be listened to by the examinee. In addition, the processor 140 calculates an algorithm for adjusting an output signal by adjusting an amplification gain with respect to a frequency of a sound source according to the hearing characteristics of the examinee. In this case, the algorithm includes all methods used for converting between an electrical signal and a sound, and a codec or the like corresponds to such an algorithm. The memory 120 stores the calculated algorithm, and the sound source reproducing apparatus 100 may read the stored algorithm and use the same to reproduce the sound source.

That is, the processor 140 stores, in the memory 120, an algorithm for correcting a signal for reproducing a sound source according to a hearing test result of the subject, and corrects the corrected sound for all sound sources reproduced through the sound source reproducing apparatus 100. By applying an algorithm, the sound source can be reproduced.

In the case of using the existing test methods using the hearing test device, it is difficult to reflect the test results in the sound source playback apparatus 100, but the hearing test is performed using the sound source playback apparatus 100, and the test results are directly applied to the sound source playback apparatus. 100 can be reflected. Therefore, the hearing test may be performed by the portable sound source reproducing apparatus 100, and the result of the test may be directly reflected so that the result of performing the test may be reflected on all sound sources reproduced through the portable sound source reproducing apparatus 100 later. .

5 is a diagram illustrating an example of amplification gain versus frequency. 5, the amplification gain graph 501 shows a change in amplification gain as the signal increases from the low frequency band to the high frequency band. FIG. 5 is a graph illustrating amplification gain graph 501 for a subject having difficulty hearing high frequency bands. That is, the amplification gain for the sound composed of the low frequency band is low, and the amplification gain for the sound composed of the high frequency band is high, so that the subject can hear the sound of the high frequency band that is difficult to hear.

Referring back to FIG. 1, the processor 140 calculates an algorithm for correcting a signal for reproducing a sound source by applying an auditory characteristic of a subject, and stores the calculated algorithm in the memory 120. In this case, the algorithm means the amplification gain of the signal as compared to the frequency as shown in Figure 5 above the amplification gain graph 501. The processor 140 may modify the frequency-to-amplification gain graph stored as a default setting, or generate a new frequency-to-amplification gain graph according to the auditory characteristic of the examinee and store it in the memory 120.

For example, if the subject has low audibility for phonemes or syllables in the frequency range of about 2000 Hz to less than 3000 Hz, the processor 140 sets the reason for amplifying the signal to 40 dB at a frequency of about 2000 Hz to less than 3000 Hz. Calculate the algorithm However, if the person skilled in the art related to the portable sound source playback apparatus 100 having a hearing test function, the above-described method is merely one example of an algorithm for correcting a signal reproduced as a sound source. It can be seen that. Therefore, the method of correcting the signal reproduced by the sound source is not limited to this, and there are various methods according to the hearing characteristics of the examinee.

The input / output interface 150 reproduces the sound source reproducing apparatus 100 and the another sound source so that the signal output from the output unit 110 is reproduced by another device that reproduces the sound source connected to the sound source reproducing apparatus 100. Functions as an interface for connecting devices. That is, the input / output interface 150 transmits a signal output from the output unit 110 to a device for reproducing a sound source connected to the sound source reproducing apparatus 100, and the device for reproducing the sound source reproduces the sound indicated by the signal. . For example, the user interface 150 may include a headset jack, a USB module, and the like provided in a mobile phone, an MP3 player, or the like corresponding to the sound source playback apparatus 100.

In the case of the hearing test, it is common to perform a hearing test on both the right ear and the left ear, so that another sound source such as an earphone may be reproduced in order to simultaneously perform the hearing test on both ears. Use the device. Accordingly, the input / output interface 150 may be connected to the sound source playback apparatus 100 to perform an interface with all accessories for reproducing the signal generated by the sound source playback apparatus 100 with sound.

The communication interface 160 transmits and receives data between the sound source playback apparatus 100 and an external device. The communication interface 160 may not exist in the sound source playback apparatus 100 according to the use environment of the sound source playback apparatus 100.

When the sound source reproducing apparatus 100 is a mobile phone, by transmitting and receiving data through the communication interface 160, it is possible to perform overall functions such as a mobile phone call, text message transmission, the Internet and the like.

Therefore, the examinee can conveniently perform the hearing test using the sound source reproducing apparatus 100 and immediately know the result of the hearing test. In addition, by immediately applying the result of the hearing test to the portable sound source reproducing apparatus 100, it is possible to improve the sound listening of the subject by directly using the result of the hearing test.

In addition, the sound source reproducing apparatus 100 receives volume information from the subject through the user interface unit 130, and uses the signal representing at least one phoneme or syllable at a set volume based on the input information to hear the subject's hearing. Check it. That is, the sound source reproducing apparatus 100 receives the volume information preferred by the subject through the user interface 130 and uses the signal representing at least one phoneme or syllable at a volume set based on the input information. Determine the auditory properties of the At this time, the volume information preferred by the subject is the size of the Most Comfortable Level, which is the sound pressure that the subject feels most comfortable, and the subject uses the user interface unit 130 to control the volume of the portable sound source reproducing apparatus 100. Set.

However, since the portable sound source reproducing apparatus 100 is carried by the examinee and reproduces the sound source from time to time, the sound source reproducing apparatus 100 may have a predetermined volume level set by the examinee. Alternatively, the sound source reproducing apparatus 100 may grasp the volume of the volume preferred by the subject, thereby performing a hearing test using the volume preferred by the subject.

Also, the sound source reproducing apparatus 100 outputs a signal indicating a sentence to which at least one sound source is amplified through the output unit 110, and the examinee displays a user's preference for the sentence represented by the reproduced sound. Input through the interface unit 130, the processor 140 may determine a method of amplifying a sound source preferred by the examinee with reference to the acquired preference of the examinee. In this case, the method of amplifying the sound source means different times at which compression starts.

That is, when the subject has a low audible degree for a certain frequency band, the subject is less likely to listen to the speech for the frequency band, and further, the ability of time analysis is deteriorated. High-energy sounds in the low frequency band mask small sounds located before and after the high-energy sounds. Thus, a small sound can quickly increase the gain and a loud sound can reduce the gain so that the small sound can be heard well in the presence of the loud sound. The method of amplifying the sound source is a kind of non-linear method, and may improve the intelligibility of speech.

In addition, in the method of amplifying the sound source, the sound source is linearly amplified according to the size of the sound source (dB SPL), and when the size is reached, the size of the sound source can be compressed. This is to prevent the sound of the reproduced sound source from becoming too loud, and any size can be arbitrarily set. When the size of a sound source input from such a nonlinear amplification system suddenly changes from a small sound to a loud sound of a predetermined level or more, a loud sound is gradually outputted by the compression function. At this time, the output of the loud sound becomes a stable state after a certain time, the time required for this stable state is called an attack time (attack time), it is possible to amplify the sound source by applying such a compression time differently.

Accordingly, the sound source reproducing apparatus 100 outputs a signal indicating a sentence to which a method of amplifying a sound source is applied to one sentence at a different compression time, and the examinee listens to the output sentences to find a sentence judged to be optimal. Choose. In this case, a sentence to which at least one sound source is amplified may be stored in the memory 120, or the processor 140 may generate a sentence to which at least one sound source is amplified. The processor 140 may determine the amplification scheme preferred by the subject according to the selection of the subject, and correct the signal for reproducing the sound source using the determined amplification scheme. In addition, in the algorithm for correcting the output signal, the algorithm may be calculated by applying the amplification method determined as well as the auditory characteristics of the subject, and the calculated algorithm may be stored in the memory 120.

Therefore, the sound source reproducing apparatus 100 may test the hearing while the subject is carrying it, display the test result, and apply the test result to the sound source reproduced by the sound source reproducing apparatus 100. May reflect the auditory characteristics of the subject. As a result, the examinee can conveniently listen to the sound source in which the auditory characteristics are reflected without equipment for supplementing the additional auditory ability.

6 is a flowchart illustrating a method of inspecting a hearing of a subject in the sound source reproducing apparatus 100. Referring to FIG. 6, a flowchart of a method of examining a hearing of a subject includes steps performed in time series in the sound source reproducing apparatus 100 illustrated in FIG. 1. Therefore, even if omitted below, the contents described above with respect to the sound source reproducing apparatus 100 shown in FIG. 1 are also applied to a method for examining a hearing of a subject.

In operation 601, the user interface 130 receives volume information from the subject. That is, the subject inputs the volume information of the lowest stable threshold, which is the sound pressure that is most comfortable. In this case, the examinee may input preferred volume information by using the volume setting button of the user interface 130.

In step 602, the output unit 110 outputs a signal representing at least one phoneme. The output signal may be reproduced as a sound through the user interface unit 130, or may be reproduced as a sound by a device for reproducing another sound source through the input / output interface 150.

In operation 603, the user interface 130 obtains a response of the examinee to an audible degree of the output signal. The user interface unit 130 may be applied to both a method of pressing a button or a method of inputting using a voice of a subject.

In step 604, the processor 140 checks the hearing of the subject based on an auditory characteristic indicating an audible degree for the frequency band including the frequency constituting the phoneme according to the response obtained from the subject. In this case, the auditory characteristic may be applied to the sound source reproducing apparatus 100 to correct a signal for reproducing the sound source. In addition, the hearing test result of the examinee based on the hearing characteristics of the examinee may be displayed on the user interface unit 130.

In operation 605, the output unit 110 outputs a signal representing a sentence to which at least one sound source is amplified. In this case, the method of amplifying at least one sound source means a time point at which compression starts.

In operation 606, the user interface 130 obtains a preference for the sentence represented by the signal from the examinee. This can be obtained in a variety of ways, as described in step 603.

In operation 607, the processor 140 determines an amplification scheme preferred by the subject with reference to the acquired subject's preference. In this case, the amplification method preferred by the determined subject may be applied to the sound source reproducing apparatus 100.

Steps 602 to 604 may be repeated a plurality of times. Testing may be performed on various frequency bands to improve the reliability of the hearing ability test. In addition, it can be appreciated by those skilled in the art related to the present embodiment that the test for the hearing ability of the subject may be terminated after the step 604 according to the use environment.

The sound source playback apparatus 100 may further include one or a plurality of processors 140. In addition, each component of the sound source reproducing apparatus 100 may correspond to one or a plurality of processors 140. The processor 140 may be implemented as an array of multiple logic gates, or it may be appreciated that the processor 140 may be implemented as a combination of a general purpose microprocessor and a memory in which a program that can be executed in the microprocessor is stored.

As described above, it is possible to conveniently test the auditory characteristics of the subject using the portable sound source reproducing apparatus 100, and may also display or reflect the test result to the sound source reproducing apparatus 100.

On the other hand, the above-described method can be written as a program that can be executed in a computer, it can be implemented in a general-purpose digital computer to operate the program using a computer-readable recording medium. In addition, the structure of the data used in the above-described method can be recorded on the computer-readable recording medium through various means. The computer-readable recording medium includes a storage medium such as a magnetic storage medium (e.g., ROM, floppy disk, hard disk, etc.), optical reading medium (e.g., CD ROM,

Those skilled in the art of the portable sound source reproducing apparatus 100 for checking hearing ability may understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the above-described substrate. Therefore, the disclosed methods should be considered in descriptive sense only and not for purposes of limitation. The scope of the sound source reproducing apparatus 100 is shown in the claims rather than the foregoing description, and all differences within the equivalent range should be interpreted as being included in the sound source reproducing apparatus 100.

100 ... sound source playback device
110 ... output
120 ... memory
130 ... User Interface
140 ... Processor
150 ... I / O interface
160 ... communication interface

Claims (20)

In the method of testing the hearing (hearing ability) of the subject in a portable sound source playback device,
Outputting a signal indicative of at least one phoneme;
Obtaining a response of the examinee to an audible degree of the output signal; And
And examining the subject's hearing based on an auditory characteristic indicative of an audible degree to a frequency band comprising frequencies constituting the phoneme according to the obtained response. The method of claim 1,
The outputting may include extracting at least one phoneme from each of groups of at least one phoneme classified based on a frequency represented by a phoneme to output a signal representing the extracted phoneme,
The inspecting step may be performed based on an auditory characteristic indicating an audible level of the test subject for each of the frequency bands by referring to the testee's response to phonemes included in frequency bands corresponding to each of the plurality of groups. And testing the hearing of the subject. The method of claim 1,
The outputting may include outputting a signal representing a sentence to which at least one sound source is amplified, and
The acquiring may include acquiring a preference for the signal from the subject,
And determining the amplification scheme preferred by the subject from among the at least one amplification scheme with reference to the acquired subject's preferences. The method of claim 3, wherein
The method of amplifying the at least one or more sound sources is characterized in that the time point at which compression is started. The method of claim 1,
Obtaining volume information from the subject;
And examining the hearing of the examinee using a signal representing the at least one phoneme at a volume set based on the obtained information. The method of claim 1,
And displaying a hearing test result of the test subject according to the hearing characteristics of the test subject. The method according to any one of claims 1, 3 or 5,
Correcting a signal for reproducing a sound source by applying the auditory characteristic of the examinee;
And wherein said outputting outputs said corrected signal. The method of claim 7, wherein
The correcting may be performed by applying an amplification gain for the frequency of the sound source according to the auditory characteristics of the examinee and an amplification scheme preferred by the examinee.
And wherein said outputting outputs said corrected signal. The method of claim 1,
The acquiring of the response of the examinee may include acquiring the response by recognizing the voice of the examinee or obtaining an input signal input by the examinee. The method of claim 1,
The acquiring of the response of the examinee may include obtaining a response of the examinee to an audible degree of the sound played by the device for reproducing the sound source connected to the sound source reproducing apparatus.
And wherein the inspecting comprises examining the hearing of the subject based on hearing characteristics of the subject according to the obtained response. A computer-readable recording medium having recorded thereon a program for executing the method of claim 1 on a computer. An output unit for outputting a signal representing at least one phoneme;
A user interface unit configured to receive a response of a test subject to an audible degree of the output signal; And
And a processor for inspecting the hearing of the examinee based on an auditory characteristic indicating an audible degree for a frequency band including a frequency constituting the phoneme according to the received response. The method of claim 12,
A memory for storing groups of at least one phoneme classified based on the peak frequency represented by the phoneme,
The output unit extracts at least one phoneme from each of the groups read from the memory and outputs a signal representing the extracted phoneme,
The processor refers to the examinee based on an auditory characteristic indicating an audible degree of the examinee for each of the frequency bands by referring to the examinee's response to a phoneme included in frequency bands corresponding to each of the plurality of groups. Sound source playback device characterized in that for checking the hearing of the. The method of claim 12,
The output unit outputs a signal representing a sentence to which at least one sound source amplification method is applied,
The user interface unit receives a preference for the signal from the subject,
And the processor determines an amplification scheme preferred by the subject from among the at least one amplification scheme with reference to the input subject's preference. The method of claim 14,
The method of amplifying the at least one sound source is a sound source playback device, characterized in that different times at which compression starts. The method of claim 12,
The user interface unit receives the volume information from the subject,
And the processor inspects the hearing of the examinee using a signal representing the at least one phoneme at a volume set based on the input information. The method of claim 12,
And the user interface unit displays a hearing test result of the testee according to the hearing characteristics of the testee. The method according to any one of claims 12, 14 or 16,
The processor corrects a signal for reproducing a sound source by applying the auditory characteristics of the subject,
And the output unit outputs the corrected signal. The method of claim 18,
The processor calculates an algorithm for correcting the signal by applying an amplification gain for the frequency of the sound source according to the auditory characteristics of the subject and a method of amplifying the sound source preferred by the subject,
The memory stores the calculated algorithm,
And the output unit outputs a signal corrected using the stored algorithm. The method of claim 12,
And an input / output interface for transmitting the output signal to a device for reproducing a sound source connected to the sound source reproducing apparatus.
The user interface unit obtains the response of the examinee to the audible degree of the sound reproduced by the device for reproducing the sound source,
And the processor checks the hearing of the examinee based on the hearing characteristics of the examinee according to the obtained response.

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