JP2012223509A - Stethoscopic sound analyzer, and stethoscopic sound analyzing program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stethoscopic sound analyzer for eliminating the effect of individual difference of user's stethoscopic characteristics and enhancing diagnostic precision based on stethoscopy.SOLUTION: The auditory sense examination part 10 of the stethoscopic sound analyzer includes an auditory sense determination part 12. This auditory sense determination part 12 outputs an examination signal sound for deciding stethoscopy of a user 101 such as a doctor or a nurse from an auditory sense examination signal output part 11. The auditory sense determination part 12 decides the audible sound pressure level of the user 101 in the frequency of the examination signal sound when the audible state of the examination signal sound is input to an operation part 14 by the user 101, to determine the stethoscopic characteristics of the user 101. On the other hand, a stethoscopic sound processing part 20 receives stethoscopic sound of an examinee 102 in a stethoscopic sound receiving part 21 to output the stethoscopic sound signal. A stethoscopic sound correction part 22 corrects the stethoscopic sound signal on the basis of the auditory sense characteristics of the user 101 calculated in the auditory sense determination part 12 to output a corrected stethoscopic sound signal. A stethoscopic sound output part 23 outputs the corrected stethoscopic sound by the corrected stethoscopic sound signal.

Description

  The present invention relates to an auscultation sound analysis apparatus and an auscultation sound analysis program that receive auscultation sounds generated by a living body (subject), correct the auscultation sounds, and output the auscultation sounds. The present invention relates to an auscultatory sound analyzing apparatus and an auscultatory sound analyzing program for outputting sound.

  The act of grasping the state of the living body using the sound generated by the living body is generally performed. For example, in medical examinations and the like, a stethoscope is used to auscultate respiratory sounds, heart sounds, and other various organ sounds, which are used for diagnosis of respiratory diseases, heart diseases, digestive organ diseases, and the like.

  Conventionally, analog type stethoscopes have been the mainstream, but in recent years, electronic stethoscopes using digital technology have been developed by various companies, volume adjustment, frequency characteristic adjustment (for respiratory, heart sounds, etc.) Etc. have been implemented, and usability has also improved.

  Also, instead of simply outputting the sound generated by the living body (subject), an attempt has been made to use it for diagnosis by outputting the result of visualization (visualization) of the body sound (patent) Reference 1 (Japanese Patent No. 3625294).

  According to the visual stethoscope disclosed in Patent Document 1, auscultation sounds can be displayed as three-dimensional information having frequency, time, and amplitude information, and information on sounds that tend to rely on subjective judgment is objective. It can be output as information.

  However, the visual stethoscope disclosed in Patent Document 1 has problems in the following points.

  In general, an inspector who uses a stethoscope for diagnosis determines a suspicion of a disease based on sound information obtained from his / her ear and comparing it with past experiences. Auscultation sounds for various diseases have frequency characteristics, and the signal intensity at each frequency differs between normal auscultation sounds and auscultation sounds at the time of disease. The examiner determines the frequency characteristics of the auscultation sound information obtained from the ear by applying it to his / her experience, but it is specified when the frequency of the auscultation sound due to various diseases is specifically at what frequency. When the auscultation sound is another frequency (Hz) and the disease is another disease B, the disease is not diagnosed in association with the specific frequency of the auscultation sound. Therefore, no matter how much the frequency, time, and amplitude information of the auscultation sound is visualized, in order for the examiner to make a diagnosis based on the visual information of the auscultation sound, the examiner needs to retrain. It is not easy for an inspector who conducts a diagnostic action at a clinical site to take a busy time and perform the new training as described above.

Patent No. 3625294

  Accordingly, an object of the present invention is to provide an auscultation sound analysis apparatus and an auscultation sound analysis program capable of avoiding the influence of individual differences in the user's auditory characteristics and improving the diagnosis accuracy by auscultation.

In order to solve the above problems, the auscultatory sound analyzing apparatus of the present invention outputs a test signal sound having a predetermined frequency and sound pressure level, and inputs whether or not the test signal sound is audible. An auditory test unit that determines the user's auditory characteristics based on the input;
It comprises an auscultation sound processing unit that corrects the auscultation sound of the subject based on the auditory characteristics obtained by the auditory examination unit and outputs the corrected corrected auscultation sound.

  According to the auscultatory sound analyzing apparatus of the present invention, the auditory examination unit detects the audible sound pressure level of a user such as a doctor or a nurse to determine the user's auditory characteristics, and the auscultatory sound processing unit Based on the auditory characteristics, the auscultation sound is corrected and a corrected auscultation sound is output. Therefore, the influence of individual differences in the user's auditory characteristics can be avoided, and diagnostic accuracy by auscultation can be improved.

Moreover, in the auscultatory sound analyzer of one embodiment, the auditory examination unit is
A test signal output unit capable of outputting a plurality of test signal sounds having different sound pressure levels at at least one predetermined frequency;
An input unit capable of inputting that the test signal sound output by the test signal output unit is audible;
Auditory characteristic derivation for determining the audible sound pressure level of the user by determining the audible sound pressure level of the user at the frequency of the inspection signal sound when an input indicating that the inspection signal sound is audible is input to the input unit And
An auditory characteristic storage unit that stores the auditory characteristic obtained by the auditory characteristic deriving unit.

  According to the auscultatory sound analyzing apparatus of this embodiment, a user such as a doctor or a nurse can confirm that the test signal sound output from the test signal output unit is audible to the input unit. input. Thereby, the auditory characteristic deriving unit determines the audible sound pressure level of the user at the frequency of the inspection signal sound, and obtains the auditory characteristic of the user. In addition, since the auditory characteristic storage unit stores the auditory characteristic obtained by the auditory characteristic deriving unit, the auscultatory sound processing unit can obtain the auditory characteristic of the user from the auditory characteristic storage unit.

Moreover, in the auscultation sound analyzer of one embodiment, the auscultation sound processing unit is
An auscultation sound receiver that receives the auscultation sound of the subject and outputs an auscultation sound signal;
A signal correction unit that corrects the auscultatory sound signal based on the auditory characteristics obtained by the auditory examination unit and outputs a corrected auscultatory sound signal;
An auscultatory sound output unit for outputting a corrected auscultatory sound based on the corrected auscultatory sound signal.

  According to the auscultatory sound analyzing apparatus of this embodiment, the auscultatory sound receiving unit receives the auscultatory sound of the subject, and the auscultatory sound signal correcting unit is based on the auditory characteristics of the user obtained from the auditory examination unit. The auscultation sound signal is corrected, and the auscultation sound output unit outputs a corrected auscultation sound based on the corrected auscultation sound signal. Thus, the user can listen to the corrected auscultatory sound corrected by his / her auditory characteristics from the auscultatory sound output unit, can avoid the influence of individual differences in the user's auditory characteristics, and the diagnostic accuracy by auscultation Can be improved.

Further, the auscultatory sound analysis program of the present invention includes an auditory test function for obtaining a user's auditory characteristics based on an audible sound pressure level at at least one predetermined frequency;
The computer implements an auscultatory sound processing function that corrects the auscultatory sound signal based on the auscultatory sound of the subject based on the auditory characteristics obtained by the auditory examination function and outputs the corrected auscultatory sound based on the corrected auscultatory sound signal from the output unit. It is characterized by that.

  According to the auscultatory sound analysis program of the present invention, the auditory test function determines the user's auditory characteristics based on the user's audible sound pressure level, and the auscultatory sound processing function is based on the auditory characteristics. Then, a corrected auscultatory sound based on the auscultatory sound signal obtained by correcting the auscultatory sound signal is output from the output unit. Thereby, the influence of individual differences in the user's auditory characteristics can be avoided, and the diagnostic accuracy by auscultation can be improved.

In the auscultatory sound analysis program of one embodiment, the auditory test function is
A test signal output function for outputting test signal sounds of a plurality of different sound pressure levels at at least one predetermined frequency from the output unit;
An auditory characteristic deriving function for determining an auditory characteristic by determining an audible sound pressure level of the user at a frequency of the test signal sound when the test signal sound is input from an input unit;
An auditory characteristic storage function for storing the auditory characteristic obtained by the auditory characteristic derivation function in a storage unit;

  According to the auscultatory sound analysis program of this embodiment, when the test signal sound output from the output unit with the test signal output function is audible to a user such as a doctor or a nurse, the user When the fact that the test signal sound is audible is input to the input unit, the auditory characteristic derivation function determines the audible sound pressure level of the user at the frequency of the test signal sound and determines the user's audible sound pressure level. Find hearing characteristics. The auditory characteristic storage function stores the user's auditory characteristic obtained by the auditory characteristic derivation function in the storage unit, so that the user's auditory characteristic used in the auscultatory sound processing function is stored in the storage unit. Obtainable.

In the auscultatory sound analysis program of one embodiment, the auscultatory sound processing function is:
A signal correction function for correcting the auscultatory sound signal based on the auditory characteristics obtained by the auditory examination function and outputting a corrected auscultatory sound signal;
An auscultatory sound output function for outputting a corrected auscultatory sound based on the corrected auscultatory sound signal from an auscultatory sound output unit;

  According to the auscultatory sound analysis program of this embodiment, the signal correction function corrects the auscultation sound signal based on the auditory characteristics obtained by the auditory examination function, outputs a corrected auscultation sound signal, and outputs the auscultation sound signal. By the function, the corrected auscultatory sound based on the corrected auscultatory sound signal is output from the auscultatory sound output unit. As a result, the user can listen to the corrected auscultatory sound corrected by his / her own auditory characteristics, can avoid the influence of individual differences in the user's auditory characteristics, and can improve the diagnostic accuracy by auscultation.

  According to the auscultatory sound analyzing apparatus of the present invention, the auditory examination unit obtains the auditory characteristics of the user (doctor, nurse, etc.), and the auscultatory sound processing unit corrects the auscultatory sound based on the auditory characteristics and corrects it. Auscultation sound is output. Therefore, the user can diagnose the auscultatory sound acquired from the subject with the same reference by the corrected auscultatory sound regardless of the auditory characteristics that are different for each user.

It is a block diagram which shows the structure of embodiment of the auscultation sound analyzer of this invention. It is a graph which shows an example of a human auditory characteristic. It is a figure which shows typically the spectrogram of the breathing sound at the time of normal. It is a figure which shows typically the spectrogram of the respiratory sound at the time of pneumonia. It is a figure which shows typically the spectrogram of the respiratory sound at the time of asthma. It is a flowchart explaining operation | movement of the auditory test part with which the said embodiment is provided. It is a flowchart explaining operation | movement of the auscultation sound process part with which the said embodiment is provided.

  Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration example of an embodiment of an auscultatory sound analyzing apparatus according to the present invention. This auscultation sound analyzer is composed of two main functional units. One is an auditory inspection unit 10 for examining the hearing of the user 101, and the other is an auscultation sound analysis processing unit 20 for analyzing the auscultation sound of the subject 102. The auditory examination unit 10 acquires the auditory characteristics of the user 101 such as a doctor or a nurse. The auscultatory sound processing unit 20 corrects the auscultatory sound obtained by correcting the auscultatory sound acquired by the user 101 from the subject 102 based on the auditory characteristics of the user 101 when the user 101 performs a diagnostic action. Is output to the user 101.

  In general, human auditory characteristics include a loudness characteristic shown in FIG. 2, which is frequency dependent. In FIG. 2, the horizontal axis represents frequency (Hz) and the vertical axis represents sound pressure level (dB SPL). The graph of FIG. 2 shows the sound pressure level necessary to obtain the same loudness (sound auditory strength). For each curve, the higher the sound pressure level, the greater the sound required, that is, the harder it is to hear. A characteristic K1 shown in FIG. 2 is a frequency characteristic of a sound pressure level indicating 100 phon. The characteristics K2, K3, K4, and K5 are frequency characteristics of sound pressure levels indicating 80 phones, 60 phones, 40 phones, and 20 phones, respectively. A characteristic K6 indicates a minimum audible sound pressure level. A characteristic K7 is a frequency characteristic of a sound pressure level indicating 40 phones in the old standard. Note that phon is a unit of the level of loudness (audible intensity of sound). As can be seen from FIG. 2, the lower the frequency, the more difficult it is to hear. In addition, this loudness characteristic varies from person to person. In other words, it is not uncommon for some people to hear sounds that are easy to hear, but difficult for others to hear.

  The auditory inspection unit 10 determines and stores different auditory characteristics for each person. As shown in FIG. 1, the auditory examination unit 10 includes an auditory determination unit 12. The auditory determination unit 12 constitutes an auditory characteristic deriving unit, and the auditory determination unit 12 controls the auditory test signal output unit 11 to determine the hearing of the user 101 from the auditory test signal output unit 11. The inspection signal sound is output. This inspection signal sound is a sound (Fi, Pi) indicating a certain sound pressure Pi at a certain frequency Fi. The certain frequency Fi is selected from a frequency range from 20 Hz to 20 kHz, for example. The auditory test signal output unit 11 can generate test signal sounds based on the sound (Fi, Pi) by the number of combinations of a plurality of different frequencies and a plurality of different sound pressures.

  The auditory examination unit 10 includes an operation unit 14. The operation unit 14 serves as an input unit through which the user 101 can input that the test signal sound output from the auditory test signal unit 11 is audible. The hearing determination unit 12 sets the audible sound pressure level of the user 101 at the frequency of the test signal sound when the user 101 inputs to the operation unit 14 that the test signal sound is audible. The auditory characteristic of the user 101 is obtained by determination. This auditory characteristic represents the distribution of the audible sound pressure level of the user 101 at each frequency.

  The auditory examination unit 10 includes an auditory storage unit 13 as an auditory characteristic storage unit. The auditory storage unit 13 stores the auditory characteristics of the user 101 obtained by the auditory determination unit 12 constituting the auditory characteristic deriving unit. In addition, the operation | movement which calculates | requires the auditory characteristic of the user 101 by this auditory test part 10 is later mentioned with reference to the flowchart of FIG.

  By the way, in the auscultatory sound analyzing apparatus of this embodiment, the frequency range of the inspection signal sound for inspecting the hearing of the user 101 is set to 20 Hz to 20 kHz which is a general audible range. However, taking into account that the audible range itself varies from person to person and that the frequency of sounds (breathing sounds, heart sounds, digestive organ sounds) emitted by living bodies is at most a few kHz, etc. You may set a range suitably according to a use condition.

  Further, in the auscultatory sound analyzing apparatus of this embodiment, although detailed description is omitted, when a plurality of users share the auscultatory sound analyzing apparatus, an ID input unit for identifying each user is provided. The auditory characteristics for each user may be stored in the auditory storage unit 13 and the auditory characteristics may be called from the storage unit 13 according to the user.

  Further, in the auscultatory sound analyzing apparatus of this embodiment, at the time of actual auscultation examination, the auscultation sound obtained from the subject 102 by the auscultation sound processing unit 20 is used as described later with reference to the flowchart of FIG. The correction processing is performed so that the auscultatory sound is easy to hear at 101. The auscultation sound processing unit 20 includes an auscultation sound receiving unit 21, and the auscultation sound receiving unit 21 receives auscultation sound from the subject 102. This auscultation sound receiving unit 21 has the same thing as a chestpiece used in a conventional stethoscope, and applies a microphone, vibration sensor, etc. to the examination unit (chest, back, abdomen, etc.) of the subject 102. By that, auscultation sounds are obtained. The auscultation sound receiving unit 21 outputs an auscultation sound signal based on the auscultation sound. The auscultation sound processing unit 20 includes an auscultation sound correction unit 22 as a signal correction unit. The auscultation sound correction unit 22 converts the auscultation sound signal input from the auscultation sound reception unit 21 into the auditory examination unit 10. Is corrected on the basis of the auditory characteristics obtained by and outputs a corrected auscultatory sound signal. The auscultation sound processing unit 20 includes an auscultation sound output unit 23, and the auscultation sound output unit 23 outputs a corrected auscultation sound based on the corrected auscultation sound signal input from the auscultation sound correction unit 22.

  FIG. 3A is a graph schematically showing an example of a spectrogram of a normal breathing sound, and FIG. 3B is a graph schematically showing an example of a spectrogram of a breathing sound in the case of pneumonia, FIG. 3C is a graph schematically showing an example of a spectrogram of respiratory sound in the case of asthma. 3A to 3C correspond to what is generally called a spectrogram in which time is plotted on the horizontal axis, frequency is plotted on the vertical axis, and the intensity of sound at each time and frequency is expressed by color intensity. However, in FIGS. 3A to 3C, the intensity of the sound is shown with black and white shading. As can be seen from FIG. 3A to FIG. 3C, the spectrogram of respiratory sound varies depending on the disease. Doctors and nurses who use stethoscopes receive visual information corresponding to the spectrograms of normal respiratory sounds, pneumonia respiratory sounds, and asthma respiratory sounds shown in FIGS. 3A to 3C in the head (brain). The auscultation sound obtained from the stethoscope is normal or abnormal, and if it is abnormal, it is determined what kind of disease it is. For example, as shown in FIG. 3A, the spectrogram of breathing sound in a normal case periodically shows peaks with energy up to a high frequency (that is, coincident with the breathing cycle). On the other hand, in the spectrogram of the respiratory sound in the case of asthma, as shown in FIG. In addition, regarding any of the normal breath sounds, pneumonia breath sounds, and asthma breath sounds, it can also be seen that there is a large amount of energy in the low frequency region of 300 Hz or less as shown in FIGS. 3A to 3C.

  Therefore, it can be said that the user 101 such as a doctor or a nurse is evaluating how much energy is included in each frequency of the breathing sound. However, the problem is that the auditory characteristics differ depending on the user. For example, a certain disease A is characterized by having energy at a certain frequency B (Hz) of a breathing sound. In this case, it is assumed that the frequency B (Hz) is a frequency that is sensitive to a certain user X but is not sensitive to another user Y. Then, this another user Y may give a diagnosis different from the user X. As will be described later, the auscultatory sound analyzing apparatus according to the present embodiment includes the aural examination unit 10 and the auscultatory sound processing unit 20 to solve the above-described problems.

  As shown in FIG. 1, the auscultation sound receiving unit 21 of the auscultation sound processing unit 20 obtains a raw auscultation sound from the subject 102 and inputs an auscultation sound signal representing this auscultation sound to the auscultation sound correction unit 22. The auscultatory sound correcting unit 22 corrects the auscultatory sound signal using the auditory characteristics of the user 101 stored in the auditory storage unit 13 of the auditory examination unit 10.

  In a more specific example, the auscultation sound correction unit 22 first frequency-converts the auscultation sound signal of the auscultation sound obtained from the auscultation sound receiving unit 21. The frequency conversion of the auscultatory sound signal is performed by, for example, converting the time signal of the auscultatory sound into a frequency signal using a fast Fourier transformer realized by software on a digital circuit or a microcomputer.

  Next, the auscultatory sound correcting unit 22 obtains the auditory characteristic of the user 101 from the auditory storage unit 13 and calculates a correction coefficient at each frequency of the auditory characteristic of the user 101 with respect to a predetermined standard auditory characteristic. Ask. The correction coefficient is obtained as a ratio of the audible sound pressure level at each frequency of the user's auditory characteristics to the audible sound pressure level at each frequency of the standard auditory characteristics. Further, the auscultatory sound correcting unit 22 multiplies the correction coefficient at each frequency by the sound pressure level of each frequency component of the frequency-converted auscultatory sound signal. Thereby, the auscultatory sound correcting unit 22 corrects the auscultatory sound signal of the auscultatory sound obtained from the subject 102. A corrected auscultatory sound based on the corrected auscultatory sound signal is output from the auscultatory sound output unit 23.

  Thereby, the corrected auscultatory sound matched with the auditory characteristic of the user 101 can be output from the auscultatory sound output unit 23. For example, the auscultatory sound correction unit 22 enhances an auscultatory sound component in a frequency band in which the auditory characteristic of the user 101 is higher (that is, difficult to hear) than the standard auditory characteristic. On the other hand, the auscultatory sound correction unit 22 weakens the auscultatory sound component in the frequency band where the auditory characteristic of the user 101 is lower than the standard auditory characteristic (that is, easy to hear). This will be described later with reference to the flowchart of FIG.

  As described above, energy is present in the low frequency band of 300 Hz or less in any of the normal breath sounds, pneumonia breath sounds, and asthma breath sounds shown in FIGS. 3A, 3B, and 3C. Yes. However, due to the loudness characteristics shown in FIG. 2 described above, the human ear is less sensitive in the low frequency band than in the high frequency band. Therefore, the auscultatory sound correction unit 22 corrects the auscultatory sound signal according to the auditory characteristics that are different for each user, and also performs a correction to increase a low frequency component that is generally difficult to hear in the auscultatory sound signal. It may be. Thereby, the low frequency sound of the auscultation sound can be corrected easily. Alternatively, as another idea, if energy is present at 300 Hz or lower in the same manner for any auscultatory sound, the energy of the frequency band of 300 Hz or lower is for the user to diagnose respiratory sounds. The information may be meaningless and may be corrected so that the user can diagnose various respiratory sounds from the energy of the frequency band of 300 Hz or higher by performing correction that weakens the low frequency component.

  Next, the operation of the hearing test unit 10 will be described with reference to the flowchart of FIG. First, in step S11, the auditory test signal for grasping the auditory characteristics of the user 101 is initialized. Here, the frequency and sound pressure of the auditory test signal are initially set to the lowest test frequency and the lowest test sound pressure level. For example, when the user 101 presses an initialization button (not shown) provided on the operation unit 14, for example, the auditory determination unit 12 initializes the auditory test signal. The The minimum test frequency and minimum test sound pressure level are, for example, 20 Hz and −10 dB SPL.

  Next, it progresses to step S12 and the test | inspection signal sound by the auditory test signal output part 11 set by the auditory test signal output part 11 by the control by the said auditory determination part 12 is output.

  Next, the process proceeds to step S13, where the auditory determination unit 12 performs a predetermined input operation (for example, an operation unit) to be performed on the operation unit 14 when the user 101 hears the inspection signal sound. It is determined whether or not an operation of pressing the confirmation button attached to 14 has been performed. As an example, whether or not the input operation has been performed is determined based on whether or not the input operation has been performed within a predetermined period after outputting the inspection signal sound.

  In step S13, when the auditory determination unit 12 determines that a signal indicating that the input operation has been performed from the operation unit 14 within the predetermined period, the process proceeds to step S15 and the predetermined determination is performed. If it is determined that a signal indicating that the input operation has been performed is not input from the operation unit 14 within the specified period, the process proceeds to step S14. In step S14, the auditory determination unit 12 changes the auditory test signal so that the sound pressure level of the test signal sound increases by a predetermined level, returns to step S12, and the changed auditory test signal. Is output from the auditory test signal output unit 11. The one stage of the sound pressure level is, for example, 3 dB SPL.

  On the other hand, in step S15, it is determined that the user's audible sound pressure level at the frequency of the test signal sound based on the currently set auditory test signal is the currently set sound pressure level of the test signal sound. Thereby, one point (frequency, audible sound pressure level) of the auditory characteristic of the user 101 is obtained. Next, the process proceeds to step S16, where the sound pressure of the test signal sound based on the auditory test signal is set to the lowest test sound pressure, and the process proceeds to step S17, where the frequency of the auditory test signal is changed. In changing the frequency, for example, the frequency is increased by one step. Increasing this frequency by one step is, for example, increasing the current frequency by 1.5 times.

  Next, proceeding to step S18, the auditory determination unit 12 determines whether or not the frequency of the test signal sound by the auditory test signal is within a predetermined frequency range to be tested. In step S18, when it is determined that the frequency of the test signal sound based on the auditory test signal is within a predetermined frequency range to be tested, the process returns to step S12 and described in steps S12 to S15 described above. Similarly, the audible sound pressure level of the user 101 at the changed frequency is obtained.

  On the other hand, if it is determined in step S18 that the frequency of the auditory test signal is not within a predetermined frequency range to be inspected, the process proceeds to step S19 and a predetermined frequency range (as an example, 20 Hz to 20 kHz). The audible sound pressure level is determined, the auditory characteristic of the user 101 is determined, and this auditory characteristic is stored in the auditory storage unit 13.

  As a result, the auditory characteristics of a certain user 101 are stored in the auditory storage unit 13, and different auditory characteristics for each user are stored in the auditory sense by executing the same operation as described above for another user. It can be stored in the unit 13.

  Next, the operation of the auscultatory sound processing unit 20 of the auscultatory sound analyzing apparatus of this embodiment will be described with reference to the flowchart of FIG.

  First, in step S21, when the user 101 performs an actual auscultation action, the auscultatory sound of the subject 102 is received by the auscultation sound receiving unit 21, and the auscultation sound receiving unit 21 generates an auscultation sound signal based on the auscultation sound. Input to the auscultation sound correction unit 22. Next, in step S22, the auscultation sound correction unit 22 corrects the input auscultation sound signal using the auditory characteristics of the user 101 input from the auditory storage unit 13 of the auditory test unit 10. To do.

  As a specific example, as described above, the auscultation sound correction unit 22 first frequency-converts the auscultation sound signal of the auscultation sound obtained from the auscultation sound reception unit 21, and then performs a predetermined standard auditory signal. A correction coefficient at each frequency of the auditory characteristic of the user 101 with respect to the characteristic is obtained. The correction coefficient is obtained as a ratio of the audible sound pressure level at each frequency of the user's 101 auditory characteristic to the audible sound pressure level at each frequency of the standard auditory characteristic. Further, the auscultation sound correction unit 22 multiplies the sound pressure level of each frequency component of the frequency-converted auscultation sound signal by the correction coefficient at each frequency. Thereby, the auscultatory sound correcting unit 22 corrects the auscultatory sound signal of the auscultatory sound obtained from the subject 102. Thereby, when the audible sound pressure level in the user's 101 auditory characteristic indicates that the sensitivity is worse than the standard auditory characteristic, the auscultatory sound signal is strengthened, and the audible sound pressure level in the user 101's auditory characteristic is increased. If the sensitivity is better than the standard auditory characteristic, correction is performed to weaken the auscultatory sound signal.

  Next, in step S23, the corrected auscultation sound signal derived as described above is input from the auscultation sound correction unit 22 to the auscultation sound output unit 23, and the auscultation sound output unit 23 performs the correction auscultation sound signal based on the correction auscultation sound signal. Output sound.

  Thus, the corrected auscultatory sound output from the auscultatory sound output unit 23 is obtained by correcting the auscultatory sound of the subject 102 so as to compensate for the deviation of the auditory characteristic of the user 101 from the standard auditory characteristic. Therefore, according to the auscultatory sound analysis apparatus of the present embodiment, the sound (auscultation sound) generated by the subject 102 is different for each user even when a user (doctor, nurse, etc.) with different hearing characteristics auscultates. By storing the auditory characteristic in the auditory storage unit 13 by the auditory inspection unit 10 in advance, it is possible to link to a diagnosis act with less judgment variation caused by the variation of the auditory characteristic.

  In addition, as described above, the auditory determination unit 12 controls the auditory test signal output unit 11 to output a test signal sound for determining the hearing of the user 101, and the test signal sound. When the operation unit 14 inputs that the inspection signal sound is audible from the user 101 who has received the sound, the audible sound pressure level of the user 101 at the frequency of the inspection signal sound is determined. The auditory characteristic deriving function for obtaining the auditory characteristic and the auditory characteristic storing function for storing the auditory characteristic obtained by the auditory characteristic deriving function in the auditory storage unit 13 may be realized by a computer by an auscultatory sound analysis program.

  In addition, as described above, the auscultatory sound correcting unit 22 corrects the auscultatory sound signal input from the auscultatory sound receiving unit 21 based on the auditory characteristics obtained by the auditory examination unit 10 to generate a corrected auscultatory sound signal. A signal correction function to be output and an auscultation sound output function for outputting the corrected auscultation sound based on the corrected auscultation sound signal from the auscultation sound output unit 23 may be realized by a computer using an auscultation sound analysis program.

DESCRIPTION OF SYMBOLS 10 Auditory test part 11 Auditory test signal output part 12 Auditory determination part 13 Auditory memory part 14 Operation part 20 Auscultation sound processing part 21 Auscultation sound receiving part 22 Auscultation sound correction part 23 Auscultation sound output part 101 User 102 Subject

Claims (6)

An auditory test unit that outputs a test signal sound having a predetermined frequency and sound pressure level and obtains a user's auditory characteristics based on an input indicating whether the test signal sound is determined to be audible,
An auscultatory sound analyzing apparatus comprising: an auscultatory sound processing unit that corrects the auscultatory sound of a subject based on auditory characteristics obtained by the auditory examination unit and outputs the corrected corrected auscultatory sound. In the auscultatory sound analyzer according to claim 1,
The auditory test section
A test signal output unit capable of outputting a plurality of test signal sounds having different sound pressure levels at at least one predetermined frequency;
An input unit capable of inputting that the test signal sound output by the test signal output unit is audible;
An auditory characteristic deriving unit that determines an audible sound pressure level at a frequency of the test signal sound when an input indicating that the test signal sound is audible is input to the input unit;
An auscultation sound analyzing apparatus comprising: an auditory characteristic storage unit that stores the auditory characteristic obtained by the auditory characteristic deriving unit. In the auscultatory sound analyzing apparatus according to claim 1 or 2,
The auscultation sound processing unit is
An auscultation sound receiver that receives the auscultation sound of the subject and outputs an auscultation sound signal;
A signal correction unit that corrects the auscultatory sound signal based on the auditory characteristics obtained by the auditory examination unit and outputs a corrected auscultatory sound signal;
An auscultatory sound analyzing apparatus comprising: an auscultatory sound output unit that outputs a corrected auscultatory sound based on the corrected auscultatory sound signal. An auditory test function that determines a user's auditory characteristics based on an audible sound pressure level at at least one predetermined frequency;
The computer implements an auscultatory sound processing function that corrects the auscultatory sound signal based on the auscultatory sound of the subject based on the auditory characteristics obtained by the auditory examination function and outputs the corrected auscultatory sound based on the corrected auscultatory sound signal from the output unit. An auscultatory sound analysis program characterized by this. In the auscultatory sound analysis program according to claim 4,
The auditory test function
A test signal output function for outputting test signal sounds of a plurality of different sound pressure levels at at least one predetermined frequency from the output unit;
An auditory characteristic derivation function for determining the audible sound pressure level at the frequency of the test signal sound when the test signal sound is audible is input from the input unit;
An auscultatory sound analysis program characterized by having an auditory characteristic storage function for storing the auditory characteristic obtained by the auditory characteristic derivation function in a storage unit. In the auscultatory sound analysis program according to claim 4 or 5,
The auscultation sound processing function is
A signal correction function for correcting the auscultatory sound signal based on the auditory characteristics obtained by the auditory examination function and outputting a corrected auscultatory sound signal;
An auscultatory sound analysis program comprising an auscultatory sound output function for outputting a corrected auscultatory sound based on the corrected auscultatory sound signal from an auscultatory sound output unit.

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