JP2007051879A - Component concentration measuring instrument, and control method for same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a measuring error caused by a temperature change of a specimen or measured objective body in measurement to accurately measure a component concentration of a measuring object in the specimen or measured objective body. <P>SOLUTION: This component concentration measuring instrument includes a mixed light emitting means for intensity-modulating different wavelengths of dual lights electrically by signals of the same frequency and reverse phases to be emitted toward the measured objective body, a temperature control means for changing a temperature of the measured objective body, a single light emitting means for intensity-modulating the one wavelength light out of the dual lights electrically to be emitted toward the measured objective body, and an acoustic wave intensity measuring means for measuring a level of a sound wave generated from the measured objective body. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a non-invasive component concentration measuring apparatus and component concentration measuring apparatus control method for a human or animal subject, or a component concentration measuring apparatus and component concentration measuring apparatus control method for an object collected from a human or animal.

  With the aging of society, dealing with adult diseases is becoming a major issue. In blood glucose level and other tests, blood collection is necessary, which places a heavy burden on the patient. Therefore, a non-invasive component concentration measurement apparatus that does not collect blood has attracted attention. As a non-invasive component concentration measuring device that has been developed so far, the skin is irradiated with electromagnetic waves and absorbed by blood molecules to be measured, for example, glucose molecules in the case of blood glucose levels, and heated locally. A photoacoustic method that observes a sound wave generated from a living body due to thermal expansion has attracted attention.

  However, the interaction between glucose and electromagnetic waves is small, and there is a limit to the intensity of electromagnetic waves that can be safely irradiated to a living body, so that a sufficient effect has not been achieved in measuring blood glucose levels in the living body.

  FIG. 9 and FIG. 10 are diagrams showing a configuration example of a conventional blood component concentration measuring apparatus using a photoacoustic method as a conventional example. FIG. 9 shows a first conventional example in which a light pulse is used as an electromagnetic wave (see, for example, Non-Patent Document 1). In this example, blood glucose, that is, glucose is the measurement target as the blood component. In FIG. 9, a driving power supply 102 supplies a pulsed excitation current to a pulsed light source 103, the pulsed light source 103 generates a light pulse having a sub-microsecond duration, and the generated light pulse is applied to the subject 101. The The light pulse generates a sound wave called a pulsed photoacoustic signal inside the subject 101, and the generated sound wave is detected by the ultrasonic detector 104 and further converted into an electric signal proportional to the sound pressure.

  The waveform of the converted electric signal is observed by the waveform observer 105. The waveform observer 105 is triggered by a signal synchronized with the excitation current, the converted electric signal is displayed at a fixed position on the tube surface of the waveform observer 105, and the converted electric signal is measured by integrating and averaging. can do. By analyzing the amplitude of the electrical signal thus obtained, the blood glucose level inside the subject 101, that is, the amount of glucose is measured. In the case of the example shown in FIG. 9, an optical pulse having a sub-microsecond pulse width is repeatedly generated at a maximum of 1 kHz, and 1024 optical pulses are averaged to measure the electrical signal. However, sufficient accuracy is obtained. It is not done.

  Therefore, a second conventional example using a light source that is continuously intensity-modulated has been disclosed for the purpose of improving accuracy. FIG. 10 shows a configuration of a second conventional apparatus (see, for example, Patent Document 1). In this example as well, blood sugar is the main measurement target, and high accuracy is attempted using a plurality of light sources having different wavelengths. In order to avoid complicated description, the operation when the number of light sources is 2 will be described with reference to FIG. In FIG. 10, light sources having different wavelengths, that is, a first light source 201 and a second light source 202 are driven by a driving power source 203 and a driving power source 204, respectively, and output continuous light.

  The light output from the first light source 201 and the second light source 202 is intermittently driven by a chopper plate 213 that is driven by a motor 214 and rotates at a constant rotational speed. Here, the chopper plate 213 is formed of an opaque material, and a relatively small number of openings are formed on the circumference through which the light of the first light source 201 and the second light source 202 passes around the axis of the motor 214. Is formed.

With the above configuration, the light output from each of the first light source 201 and the second light source 202 is intensity-modulated with the relatively prime modulation frequency f ₁ and modulation frequency f ₂ , and then multiplexed by the multiplexer 211. Then, the subject 101 is irradiated as one light beam.

The inside of the subject 101 photoacoustic signal having the frequency f ₁ is generated by the light of the first light source 201, the photoacoustic signal having the frequency f ₂ is generated by the light of the second light source 202, these photoacoustic signal Is detected by the acoustic sensor 212 and converted into an electrical signal proportional to the sound pressure, and its frequency spectrum is observed by the frequency analyzer 215. In this example, the wavelengths of the plurality of light sources are all set to the absorption wavelength of glucose, and the intensity of the photoacoustic signal corresponding to each wavelength is measured as an electrical signal corresponding to the amount of glucose contained in the blood. The

Here, the relationship between the intensity of the measured value of the photoacoustic signal and the value obtained by measuring the glucose content by separately collected blood is stored in advance, and the amount of glucose is measured from the measured value of the photoacoustic signal. ing.
JP-A-10-189 University of Oulu (University of Oulu, Finland) thesis “Pulse photoacoustic technique and glucodesis in human blood and tissue” (IBS 951-42-6690-0, ul./200.

  The conventional example described above has the following problems. The temperature of a subject such as a human or an animal varies depending on individual differences or the temperature and humidity of the outside air. In addition, the temperature of an object to be measured collected from a human or an animal varies depending on the measurement environment. Such a change in temperature changes the thermal expansion coefficient of the subject or the object to be measured, the sound velocity in the object or the object to be measured, and the absorbance characteristics of the component to be measured of the object or the object to be measured. It varies as follows depending on the temperature.

  The sound pressure s of the sound wave generated from the subject or the object to be measured by the light irradiation is expressed as the following Equation 1.

Here, I is an irradiation light intensity, β is a thermal expansion coefficient of the subject or the object to be measured, c is a sound velocity in the object or the object to be measured, and C _p is a specific heat of the object or the object to be measured. Among the above parameters, since β and c change with temperature, the thermal expansion coefficient changes by Δβ due to temperature change, and the change in sound pressure when the sound speed changes by Δc, Δs is expressed as equation (2). Is done.

  Here, the thermal expansion coefficient β changes by 3% per 1 ° C. temperature change. From equation (2), it can be seen that, for example, when the temperature changes by 0.1 ° C., the photoacoustic signal changes by about 0.3%. The rate of change of the photoacoustic signal due to the temperature change of 0.1 ° C. is 0.3%, the rate of change of the photoacoustic signal when the glucose concentration changes by 5 mg / dL, about 20 times the rate of 0.017%. The change in temperature greatly affects the measurement of glucose concentration.

  As described above, the conventional method for measuring the concentration of a component of a subject or a measurement object has a problem that a measurement error becomes very large due to a temperature change of the sample or the measurement object during measurement.

  In order to solve the above problems, the present invention emits light of two different wavelengths set from the absorbance characteristics of the component to be measured and water at a predetermined temperature, and sets the temperature of the subject or the object to be measured to the predetermined temperature. The component concentration measuring device and the component concentration measurement that accurately measure the component concentration by detecting the sound wave generated from the subject or the measured object in accordance with the temperature, eliminating the error due to the temperature change of the sample or the measured object. It is an apparatus control method. Here, the subject is a measurement target human or animal, and the measurement target is a measurement target collected from the measurement target human or animal, and the same applies to the following description.

  First, the case where the component concentration of a subject is measured will be described as an example of the basic principle of the component concentration measuring device and the component concentration measuring device control method of the present invention.

  In the present invention, the wavelength of the first light among the two different wavelengths of light is set to a wavelength that is significantly different from the absorbance due to water, for example, where the absorbance due to the measurement target component of the subject occupies most of the subject. The wavelength of the second light is set to a wavelength that exhibits an absorbance equal to that of water at the wavelength of the first light. The above-described wavelength setting method will be described with reference to FIG. 1, taking as an example the case of measuring the concentration of glucose in blood.

FIG. 1 shows the absorbance characteristics of water and an aqueous glucose solution at room temperature. In FIG. 1, the vertical axis indicates the absorbance, and the horizontal axis indicates the wavelength of light. In FIG. 1, the solid line indicates the absorbance characteristic of water, and the broken line indicates the absorbance characteristic of the glucose aqueous solution. The wavelength λ ₁ shown in FIG. 1 is a wavelength at which the absorbance due to glucose is significantly different from the absorbance due to water, and the wavelength λ ₂ is a wavelength at which water has the same absorbance as that at λ ₁ . Thus, for example, the wavelength of the first light can be set to λ ₁ and the wavelength of the second light can be set to λ ₂ .

In the following description, as an example, the wavelength of the first light is set to a wavelength λ ₁ where the absorbance of the component to be measured is significantly different from the absorbance of water, and the wavelength of the second light is set to the first light. The case where the wavelength λ ₂ is set to be equal to that at the wavelength λ ₁ will be described.

  Each of the two different wavelengths of light set as described above is intensity-modulated with a signal of the opposite phase at the same frequency and emitted as pulsed light, and the emitted two different wavelengths of light are absorbed by the component of the subject. Then, the generated sound wave is detected, and the concentration of the component to be measured of the subject is measured from the magnitude of the detected sound wave. When light of two different wavelengths whose intensity is modulated as described above is emitted, the first sound wave generated from the subject by the absorption of the first light by both the component to be measured and water, and the second light The second sound wave generated from the subject by absorbing water occupying most of the subject has the same frequency and an opposite phase. Therefore, the first sound wave and the second sound wave are superimposed in the subject, and only the magnitude of the sound wave generated from the subject due to absorption of the component to be measured in the first sound wave is obtained as the difference between the sound waves. Remains. Therefore, only the sound wave generated from the subject by the first light being absorbed by the component to be measured can be measured by the remaining sound wave. In the above measurement, the measurement target component absorbs rather than the difference between the sound wave generated by the absorption of both the measurement target component and water and the sound wave generated by the water absorption. Thus, the sound wave generated from the subject can be accurately measured.

Furthermore, a method for measuring with high accuracy, excluding the cause of errors in the sound wave measurement system such as the contact state between the subject and the sound wave detection element, will be described below. For each of the light of wavelength λ _{1 and} the light of wavelength λ ₂ , the absorption coefficient of water occupying most of the subject is α ₁ ^(w) and α ₂ ^(w) , and the molar absorption of the component to be measured of the subject If the coefficients are α ₁ ^(g) and α ₂ ^(g) , the simultaneous equations including the magnitudes s ₁ and s ₂ of sound waves generated from the subject by the light of wavelength λ _{1 and} the light of wavelength λ ₂ are It is expressed by Equation (3).

By solving Equation (3), the component concentration M of the subject to be measured can be obtained. Here, C is a coefficient that is difficult to control or predict, that is, the coupling state between the subject and the sound wave detection element, the sensitivity of the sound wave detection element, and the distance between the position where the sound wave is generated by light in the subject and the sound wave detection element. , specific heat and thermal expansion coefficient of the object, the speed of the internal wave of the subject, the wavelength lambda ₁ of light and the wavelength lambda ₂ of the light modulation frequencies, the molar absorption coefficient of the component of the absorption coefficient and the subject of water, etc. It depends on the unknown constant. Further, when C is eliminated by Expression (3), the following Expression (4) is obtained.

Here, the absorption coefficients α ₁ ^(w) and α ₂ ^{(w) of} water occupying most of the subject for each of the light of wavelength λ _{1 and} the light of wavelength λ ₂ are selected to be equal. , Α ₁ ^(w) = α ₂ ^(w) is satisfied, and further, if it is used that s ₁ ≈s ₂ , the component concentration M is expressed by Equation (5).

Substituting α ₁ ^(w) , α ₁ ^(g), and α ₂ ^(g) as known coefficients into the above equation (5), and further by each of light of wavelength λ ₁ and light of wavelength λ ₂ The component concentration M of the subject can be calculated by measuring and substituting the magnitudes s ₁ and s ₂ of the sound waves generated from the subject. In the above formula (5), rather than separately measuring the _two sound wave sizes s ₁ and s ₂ , the difference s ₁ -s ₂ is measured and the sound wave size s ₂ measured separately is measured. The component concentration of the subject can be measured with high accuracy.

Therefore, in the component concentration measuring apparatus and the component concentration measuring apparatus control method of the present invention, first, the light of wavelength λ _{1 and} the light of wavelength λ ₂ are intensity-modulated by the modulation signals having opposite phases to each other to form one light beam. By combining and emitting, a difference (s ₁ −s ₂ ) between sound waves generated by superimposing the sound wave magnitude s ₁ and the sound wave magnitude s ₂ generated from the subject is measured. Next, light of wavelength λ ₂ is emitted, and the magnitude s _{2 of the} sound wave generated from the subject is measured. From (s ₁ −s ₂ ) and s ₂ measured as described above, (s ₁ −s ₂ ) ÷ s ₂ is calculated according to Equation (5), and the concentration of the measurement target component of the subject can be calculated with high accuracy. Can be measured.

  The influence of the temperature change of the subject in the component concentration measuring apparatus and the component concentration measuring apparatus control method of the present invention is as follows.

  In the present invention, the component concentration is measured by Equation (5), so that it is not affected by the fluctuation of the sound wave due to the temperature change shown by Equation (2), but when the absorbance characteristic is changed by the temperature change, to be influenced.

When the absorbance characteristic of the component to be measured changes due to the temperature change of the subject, the difference between the water absorption coefficients α ₁ ^(w) and α ₂ ^(w) increases, and the approximation accuracy of Equation (5) deteriorates. , May cause errors. That is, if the change in the absorption coefficient of water is α ₂ ^(w) = α ₁ ^(w) and + Δα ^(w) , Equation (4) is as follows.

  Here, since the second term of the formula (6) changes with temperature, it causes an error. When measuring the concentration of a component of a subject based on the above measurement principle, the absorbance characteristics of water and an aqueous glucose solution shown in FIG. 1 change depending on the temperature. For example, when the temperature rises, the absorbance characteristics are shifted in the shorter wavelength direction. Thus, the measured value changes as described above. Therefore, in the measurement of the component concentration of the subject, it is necessary to appropriately select and set the wavelength of the first light and the wavelength of the second light that meet the above-described conditions according to the temperature of the subject. Alternatively, when the wavelength of the first light and the wavelength of the second light are selected and set at a predetermined temperature, it is necessary to make the temperature of the subject coincide with the predetermined temperature.

In the present invention, the wavelength of the first light is set to a wavelength λ ₁ where the absorbance of the component to be measured of the subject at a predetermined temperature is significantly different from the absorbance of water occupying most of the subject. Is set to a wavelength λ ₂ that exhibits the same absorbance as water at a predetermined temperature at the wavelength λ ₁ of the _first light. Furthermore, by matching the temperature of the subject to a predetermined temperature, the wavelength of the component to be measured of the subject is significantly different from the absorbance of water to the wavelength of the first light, and the water of the subject is The wavelength showing the same absorbance as that at the wavelength of one light is matched with the wavelength of the second light. By the above method, the present invention prevents the occurrence of an error due to a change in the temperature of the subject.

  The above is the basic principle of the component concentration measuring apparatus and the component concentration measuring apparatus control method of the present invention.

  Next, specific means for solving the problems according to the present invention will be described. The present invention provides a mixed light emitting means for electrically modulating the intensity of two different wavelengths of light with signals having the same frequency and opposite phase, and emitting the light to the object to be measured, and temperature control for changing the temperature of the object to be measured. Means, a single light emitting means for electrically intensity-modulating light of one of the two wavelengths and emitting it to the object to be measured, and a sound wave for measuring the magnitude of the sound wave generated from the object to be measured And an intensity measuring means.

In the present invention, the mixed light emitting means converts two different wavelengths of light, i.e., the wavelength of the first light and the wavelength of the second light, into the component to be measured of the object to be measured at a predetermined temperature according to the measurement principle described above, and The wavelength λ ₁ and the wavelength λ ₂ selected from the absorbance characteristics of water are set. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and opposite phase, and outputs the combined light to the object to be measured. As described above, the first light and the second light are emitted to the object to be measured, and the sound wave intensity measuring means measures the sound wave generated from the object to be measured. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

The sound intensity measuring means measures the magnitude of the sound wave generated from the object to be measured, and the temperature control means changes the temperature of the object to be measured within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When detecting the sonic minimum temperature, the temperature control means stops the operation of changing the temperature of the object to be measured, keeps the temperature of the object to be measured constant, and minimizes the minimum value of the sound wave measured by the sound intensity measuring means. The sound wave intensity is measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the object to be measured is significantly different from the absorbance of water matches the wavelength of the first light, and the water of the object to be measured is the first light. The wavelength showing the same absorbance as that at the wavelength corresponds to the wavelength of the second light.

Further, the single light emitting means modulates the intensity of the light having the same wavelength as that of the second light in the same manner as the second light, and the second light is applied to the object to be measured which is maintained at the sonic minimum temperature by the temperature control means. The sound wave emitted from the same intensity as the light and generated from the object to be measured is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Further, based on the measured (s ₁ -s ₂ ) and s ₂ , the concentration of the component to be measured is calculated according to the principle described above.

  By matching the temperature of the object to be measured to the sonic minimum temperature, that is, a predetermined temperature, the wavelength of the measurement target component of the object to be measured is significantly different from the absorbance of water to the wavelength of the first light, The wavelength at which the water of the object to be measured exhibits the same absorbance as that at the wavelength of the first light can be matched with the wavelength of the second light. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the measurement target of the object to be measured.

  In the component concentration measuring apparatus of the present invention, the temperature control means changes the temperature of the object to be measured, and the magnitude of the sound wave generated from the object to be measured by the light of the two different wavelengths emitted from the mixed light emitting means. The single light emitting means may emit the intensity-modulated light to the object to be measured at the minimum acoustic wave temperature.

In the present invention, the mixed light emitting means converts two different wavelengths of light, i.e., the wavelength of the first light and the wavelength of the second light, into the component to be measured of the object to be measured at a predetermined temperature according to the measurement principle described above, and The wavelength λ ₁ and the wavelength λ ₂ selected from the absorbance characteristics of water are set. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and opposite phase, and outputs the combined light to the object to be measured. As described above, the first light and the second light are emitted to the object to be measured, and the sound wave intensity measuring means measures the sound wave generated from the object to be measured. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

As described above, the sound intensity measuring means measures the magnitude of the sound wave generated from the object to be measured, and the temperature control means changes the temperature of the object to be measured within a predetermined range including the predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When the minimum temperature of the sound wave is detected, the temperature control means stops the operation of changing the temperature of the object to be measured, keeps the temperature of the object to be measured constant, and minimizes the minimum value of the sound wave measured by the sound wave intensity measuring means. The sound wave intensity is measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the object to be measured is significantly different from the absorbance of water matches the wavelength of the first light, and the water of the object to be measured is the first light. The wavelength showing the same absorbance as that at the wavelength corresponds to the wavelength of the second light.

Further, the single light emitting means modulates the intensity of the light having the same wavelength as that of the second light in the same manner as the second light, and the second light is applied to the object to be measured which is maintained at the sonic minimum temperature by the temperature control means. The sound wave emitted from the same intensity as the light and generated from the object to be measured is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Based on the measured (s ₁ -s ₂ ) and s ₂ , the component concentration of the measurement target can be calculated according to the principle described above.

  By adjusting the temperature of the object to be measured to the minimum acoustic wave temperature, that is, a predetermined temperature by the temperature control means, the wavelength of the first light is changed so that the absorbance of the component to be measured of the object to be measured is significantly different from the absorbance of water. And the wavelength of the light to be measured which is equal to that of the first light at the wavelength of the first light can be matched with the wavelength of the second light. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the measurement target of the object to be measured.

  The component concentration measuring apparatus according to the present invention includes a magnitude of a sound wave generated from the object to be measured by light of the two different wavelengths emitted from the mixed light emitting means and one of the two wavelengths emitted from the single light emitting means. You may further provide the component density | concentration calculation means which calculates the component density | concentration of the said to-be-measured object from the magnitude | size of the sound wave which generate | occur | produces from the to-be-measured object by the light of a wavelength.

In the present invention, the component concentration measuring device further includes the component concentration calculating means, so that the magnitude of the sound wave (s ₁ -s ₂ ) generated from the object to be measured by the light emitted from the mixed light emitting means and the single light emission. Based on the measurement result of the intensity s ₂ of the sound wave generated from the measured object by the light emitted from the means by the sound intensity measuring means, the calculation of (s ₁ −s ₂ ) ÷ s ₂ is executed according to the measurement principle described above. Thus, the concentration of the component to be measured can be calculated. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the measurement target of the object to be measured.

  In the component concentration measuring apparatus of the present invention, the single light emitting means electrically modulates the intensity of one wavelength of the two different wavelengths of light from the mixed light emitting means and emits it to the object to be measured. May be.

  In the present invention, in the component concentration measuring device, the light having a predetermined wavelength out of the two different wavelengths emitted from the mixed light emitting means, that is, the second light described above is electrically intensity-modulated and emitted to the object to be measured. By making the portion a single light emitting means, one wave of light can be emitted to the object to be measured with a simple configuration. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the measurement target of the object to be measured with a simple configuration.

  The present invention provides a mixed light emitting means for electrically intensity-modulating two different wavelengths of light with signals having the same frequency and opposite phase, and emitting them to a subject, and a temperature control means for changing the temperature of the subject. A single light emitting means for electrically modulating the intensity of one of the two wavelengths and emitting it to the subject; and a sound intensity measuring means for measuring the magnitude of a sound wave generated from the subject; , A component concentration measuring device.

In the present invention, the mixed light emitting means converts two different wavelengths of light, i.e., the wavelength of the first light and the wavelength of the second light, into the component to be measured and the water at a predetermined temperature according to the measurement principle described above. Are set to the wavelength λ ₁ and the wavelength λ ₂ selected from the absorbance characteristics. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and opposite phase, and outputs the combined light to the subject. As described above, the first light and the second light are emitted to the subject, and the sound wave generated from the subject is measured by the sound intensity measuring means. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

As described above, the sound intensity measuring means measures the magnitude of the sound wave generated from the subject, and the temperature control means changes the temperature of the subject within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When the minimum sound wave temperature is detected, the temperature control unit stops the operation of changing the temperature of the subject, keeps the temperature of the subject constant, and the minimum sound wave intensity as the minimum value of the sound wave measured by the sound wave intensity measuring unit. Is measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the subject is significantly different from the absorbance of water coincides with the wavelength of the first light, and the water of the subject is at the wavelength of the first light. The wavelength showing the same absorbance as that of the second light coincides with the wavelength of the second light.

In addition, the single light emitting means modulates the intensity of the light having the same wavelength as that of the second light in the same manner as the second light, and the second light The sound wave emitted from the subject and emitted from the subject is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Further, based on the measured (s ₁ -s ₂ ) and s ₂ , the concentration of the component to be measured is calculated according to the principle described above.

  By matching the temperature of the subject to the minimum temperature of the sound wave, that is, a predetermined temperature, the wavelength where the absorbance of the component to be measured is significantly different from the absorbance of water matches the wavelength of the first light. The wavelength at which the water of the first water has the same absorbance as that at the first light wavelength can be matched to the second light wavelength. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the analyte of the object to be measured.

  In the component concentration measuring apparatus according to the present invention, the temperature control means changes the temperature of the subject, and the magnitude of the sound wave generated from the subject by the light of the two different wavelengths emitted from the mixed light emitting means is minimized. The single light emitting means may emit the intensity-modulated light to the subject at the minimum acoustic wave temperature.

In the present invention, the mixed light emitting means converts two different wavelengths of light, i.e., the wavelength of the first light and the wavelength of the second light, into the component to be measured and the water at a predetermined temperature according to the measurement principle described above. Are set to the wavelength λ ₁ and the wavelength λ ₂ selected from the absorbance characteristics. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and opposite phase, and outputs the combined light to the subject. As described above, the first light and the second light are emitted to the subject, and the sound wave intensity measurement means measures the sound wave generated from the subject. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

As described above, the sound intensity measuring means measures the magnitude of the sound wave generated from the subject, and the temperature control means changes the temperature of the subject within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When the minimum sound wave temperature is detected, the temperature control unit stops the operation of changing the temperature of the subject, keeps the temperature of the subject constant, and sets the minimum sound wave intensity as the minimum value of the sound wave measured by the sound wave intensity measuring unit. Measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the subject is significantly different from the absorbance of water coincides with the wavelength of the first light, and the water of the subject is at the wavelength of the first light. The wavelength showing the same absorbance as that of the second light coincides with the wavelength of the second light.

In addition, the single light emitting means modulates the intensity of the light having the same wavelength as that of the second light in the same manner as the second light, and the second light The sound wave emitted from the subject and emitted from the subject is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Furthermore, based on the measured (s ₁ -s ₂ ) and s ₂ , the concentration of the component to be measured can be calculated according to the principle described above.

  By matching the temperature of the subject to the minimum temperature of the sound wave, that is, the predetermined temperature, by means of the temperature control means, the wavelength at which the absorbance of the analyte is significantly different from the absorbance of water matches the wavelength of the first light. Thus, the wavelength at which the water of the subject shows the same absorbance as that at the wavelength of the first light can be matched with the wavelength of the second light. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the subject to be measured.

  In the component concentration measuring apparatus of the present invention, the size of the sound wave generated from the subject by the light of the two different wavelengths emitted by the mixed light emitting means and one wavelength of the two wavelengths emitted by the single light emitting means There may be further provided a component concentration calculating means for calculating the component concentration of the subject from the magnitude of the sound wave generated from the subject by the light of.

In the present invention, since the component concentration measuring device further includes the component concentration calculating means, the magnitude (s ₁ -s ₂ ) of the sound wave generated from the subject by the light emitted from the mixed light emitting means and the single light emitting means From the measurement result of the sound wave intensity s ₂ generated from the subject by the light emitted by the sound wave intensity measuring means, the calculation of (s ₁ −s ₂ ) ÷ s ₂ is executed according to the measurement principle described above, The concentration of the component to be measured can be calculated. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the subject to be measured with a simple configuration.

  In the component concentration measuring apparatus according to the present invention, the single light emitting unit electrically modulates the intensity of one wavelength of the two different wavelengths of light from the mixed light emitting unit, and emits the light to the subject. Also good.

  In the present invention, in the component concentration measuring device, a portion of the light having a predetermined wavelength out of two different wavelengths emitted from the mixed light emitting means, that is, a portion that electrically modulates the intensity of the second light and emits it to the subject. By using a single light emitting means, it is possible to emit one wave of light to the subject with a simple configuration. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the subject to be measured.

  The component concentration measuring apparatus according to the present invention is configured to cause the mixed light emitting means to emit light of two different wavelengths, which is electrically intensity-modulated by a signal having the same frequency and opposite phase, and emitted to water, and to the sound intensity measuring means. The apparatus may further include a wavelength adjusting unit that measures the size of the sound wave generated from the light source and adjusts the wavelengths of the two different wavelengths so that the measured sound wave size becomes zero.

In the present invention, the wavelength adjusting means of the component concentration measuring device allows the mixed light emitting means to set the wavelength of the first light and the wavelength of the second light emitted by the mixed light emitting means at a predetermined temperature in accordance with the measurement principle described above. The wavelength λ ₁ and the wavelength λ ₂ are selected from the components to be measured of the subject or the object to be measured and the absorbance characteristics of water. Further, the wavelength adjusting means is a calibration light device that is produced by using the water that is maintained at a predetermined temperature by causing the mixed light emitting means to electrically modulate the intensity of the first light and the second light with a signal having the same frequency and opposite phase. The sample is emitted to the sample, and the sound intensity generated from the calibration sample is measured by the sound intensity measuring means. The wavelength adjusting means adjusts the wavelength of the first light generated by the mixed light emitting means, the wavelength of the second light, or both so that the magnitude of the sound wave generated from the measured calibration sample becomes zero. To do. When the magnitude of the sound wave generated from the calibration sample is zero, the first sound wave generated by the first light and the second sound wave generated by the second light are in opposite phase and in magnitude. Are equal to each other and cancel each other in a superimposed manner in the calibration sample. Therefore, each of the wavelength of the first light and the wavelength of the second light adjusted as described above is a wavelength at which water exhibits the same absorbance, and corresponds to the wavelength λ ₁ and the wavelength λ ₂ , respectively.

The wavelength of the first light and the wavelength of the second light are adjusted by adjusting either the wavelength of the first light and the wavelength of the second light emitted by the mixed light emitting means by the wavelength adjusting means, or both, According to the measurement principle described above, it is possible to accurately match the wavelength λ ₁ and the wavelength λ ₂ selected from the components to be measured and the absorbance characteristics of water at a predetermined temperature. Therefore, the component concentration measuring apparatus of the present invention can accurately measure the component concentration of the measurement target of the subject or the object to be measured.

  In the present invention, the mixed light emitting means for emitting light of two different wavelengths that are electrically intensity-modulated with signals having the same frequency and opposite phase is set to two different wavelengths at which water at a predetermined temperature exhibits the same absorbance. The mixed light emission procedure for emitting light to the object to be measured and the temperature control means for changing the temperature change the temperature of the object to be measured, and the sound wave intensity measuring means for measuring the size of the sound wave is generated from the object to be measured. A minimum sound intensity measurement procedure for measuring the minimum sound wave intensity at which the magnitude of the sound wave is minimized, and the temperature control means maintaining the minimum sound wave temperature of the object to be measured at which the minimum sound wave intensity is obtained, A single light emitting means that emits light with modulated intensity and emits light of one wavelength out of the two different wavelengths to the object to be measured, and the sound intensity measuring means determines the magnitude of the sound wave generated from the object to be measured. Single sound intensity measuring hand to measure When a constituent concentration measuring apparatus controlling method characterized by having in sequence.

In the present invention, as the mixed light emitting procedure, the mixed light emitting means uses two different wavelengths of light, that is, the wavelength of the first light and the wavelength of the second light to be measured at a predetermined temperature in accordance with the measurement principle described above. The wavelength λ ₁ and the wavelength λ ₂ selected from the components to be measured and the absorbance characteristics of water are set. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and opposite phase, and outputs the combined light to the object to be measured. As described above, the first light and the second light are emitted to the object to be measured, and the sound wave intensity measuring means measures the sound wave generated from the object to be measured. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

Thereafter, as the minimum sound intensity measurement procedure, the sound intensity measuring means measures the magnitude of the sound wave generated from the object to be measured as described above, and the temperature control means sets the temperature of the object to be measured to a predetermined value including a predetermined temperature. Change in range. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When the minimum temperature of the sound wave is detected, the temperature control means stops the operation of changing the temperature of the object to be measured, keeps the temperature of the object to be measured constant, and minimizes the minimum value of the sound wave measured by the sound wave intensity measuring means. The sound wave intensity is measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the object to be measured is significantly different from the absorbance of water matches the wavelength of the first light, and the water of the object to be measured is the first light. The wavelength showing the same absorbance as that at the wavelength corresponds to the wavelength of the second light.

After that, as a single sound intensity measurement procedure, the single light emitting means applies light having the same wavelength as that of the second light to the object to be measured which is maintained at the minimum sound wave temperature by the temperature control means. The intensity of the sound is modulated and emitted with the same intensity as the second light, and the sound wave generated from the object to be measured is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Furthermore, the component concentration of the measurement target is calculated according to the above-described principle from (s ₁ -s ₂ ) and s ₂ measured as described above.

  As described above, by adjusting the temperature of the object to be measured to the minimum temperature of the sound wave, that is, a predetermined temperature by the temperature control means, the wavelength at which the absorbance of the component to be measured of the object to be measured is significantly different from the absorbance of water is set. The wavelength of the light to be measured can be matched with the wavelength of the second light, and the wavelength of the light to be measured can be matched with the wavelength of the second light. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the object to be measured.

  In the present invention, the mixed light emitting means for emitting light of two different wavelengths that are electrically intensity-modulated with signals having the same frequency and opposite phase is set to two different wavelengths at which water at a predetermined temperature exhibits the same absorbance. The minimum sound intensity at which the intensity of sound waves generated from the object is minimized by the sound intensity measurement means for measuring the intensity of sound waves by the temperature control means for changing the temperature, and the sound intensity measurement means for measuring the sound wave intensity. The minimum sound intensity measurement procedure in which the temperature control means maintains the minimum sound wave temperature at which the temperature control means becomes the minimum sound intensity, and the single light emitting means for emitting light of one wavelength by electrically modulating the intensity are different. A component concentration measurement comprising: sequentially emitting a light of one wavelength out of two wavelengths, and the sound intensity measuring means measuring the intensity of the sound wave generated from the subject. Device control method It is.

In the present invention, as the mixed light emission procedure, the mixed light emission means uses two different wavelengths of light, that is, the wavelength of the first light and the wavelength of the second light of the subject at a predetermined temperature according to the measurement principle described above. The wavelength λ ₁ and the wavelength λ ₂ are selected from the component to be measured and the absorbance characteristics of water. Further, the mixed light emitting means electrically modulates the intensity of each of the first light and the second light with a signal having the same frequency and an opposite phase, and combines and emits the light. As described above, the sound intensity measuring means measures the sound wave generated from the subject by emitting the first light and the second light. Here, the sound wave measured by the sound intensity measuring means is a difference sound wave between the first sound wave generated by the first light and the second sound wave generated by the second light.

Thereafter, as the minimum sound intensity measurement procedure, the sound intensity measuring means measures the magnitude of the sound wave generated from the subject as described above, and the temperature control means sets the temperature of the holding body holding the subject to a predetermined temperature. It is changed within a predetermined range. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. When detecting the sonic minimum temperature, the temperature control means stops the operation of changing the temperature of the holding body, keeps the temperature of the holding body constant, and sets the minimum sound wave intensity as the minimum value of the sound wave measured by the sound wave intensity measuring means. Measured as (s ₁ -s ₂ ) described in the above measurement principle. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the subject is significantly different from the absorbance of water coincides with the wavelength of the first light, and the water of the subject is at the wavelength of the first light. The wavelength showing the same absorbance as that of the second light coincides with the wavelength of the second light.

After that, as a procedure for measuring the intensity of the single sound wave, the temperature control means keeps the temperature of the holding body at the minimum sound wave temperature, and the single light emitting means emits light having the same wavelength as the second light, similar to the second light. The sound wave intensity is modulated and emitted with the same intensity as the second light, and the sound wave generated from the subject is measured by the sound wave intensity measuring means as s ₂ described in the above measurement principle. Furthermore, the component concentration of the measurement target is calculated according to the above-described principle from (s ₁ -s ₂ ) and s ₂ measured as described above.

  As described above, by adjusting the temperature of the holding body to the minimum acoustic wave temperature, that is, a predetermined temperature by the temperature control means, the wavelength at which the absorbance of the measurement target component of the subject is significantly different from the absorbance of water is set to the first wavelength. It is possible to match the wavelength of light with the wavelength of the second light so that the wavelength of the subject water is equal to the wavelength of the first light. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the subject.

  In the component concentration measuring apparatus control method of the present invention, the component concentration calculating means for calculating the component concentration from the sound wave size after the single sound wave intensity measuring procedure is the same as the sound wave size measured by the minimum sound wave intensity measuring procedure. You may further have the component density | concentration calculation procedure which calculates the said component density | concentration from the magnitude | size of the sound wave measured by the said single sound wave intensity | strength measurement procedure.

In the present invention, the component concentration measuring device control method includes a component concentration calculation procedure after the single sound intensity measurement procedure, whereby the minimum sound intensity (s ₁ -s ₂ ) measured by the minimum sound measurement procedure and the single sound intensity measurement procedure. The calculation of (s ₁ −s ₂ ) ÷ s ₂ is performed according to the above-described measurement principle, and the component concentration of the measurement target of the object to be measured or the subject is determined by the sound wave size s ₂ measured in the sound wave intensity measurement procedure. Can be calculated. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the object to be measured or the subject.

  In the component concentration measuring apparatus control method of the present invention, the single sound intensity measuring procedure is such that the mixed light emitting means emits light of one wavelength out of two different wavelengths, and the sound intensity measuring means measures the magnitude of the sound wave. The thickness may be measured.

  In the present invention, as a single sound wave intensity measurement procedure of the component concentration measuring device control method, light of a predetermined wavelength, that is, the second light described above is electrically intensified among two different wavelengths of light from the mixed light emitting means. By making the portion to be modulated and emitted be a single light emitting means, one wave of light can be easily emitted. Therefore, the component concentration measuring device control method of the present invention can easily and accurately measure the component concentration of the measurement target of the object to be measured or the subject.

  In the component concentration measuring apparatus control method according to the present invention, the wavelength adjusting unit that adjusts the wavelength of the two light beams of the mixed light emitting unit outputs light of two different wavelengths to the mixed light emitting unit at the same frequency and in opposite phase. The mixed light emitting means has two different wavelengths so that the intensity of the sound wave generated from the water measured by the sound wave intensity measuring means is zero. A wavelength adjusting procedure for adjusting the wavelength of the light may be provided before the mixed light emitting procedure.

In the present invention, before the mixed light emission procedure of the component concentration measuring device control method, as the wavelength adjustment procedure, the wavelength adjustment means sends the mixed light emission means the wavelength of the first light emitted from the mixed light emission means and the second light. Are set to the wavelength λ ₁ and the wavelength λ ₂ selected from the components to be measured of the subject or the object to be measured at a predetermined temperature and the absorbance characteristics of water in accordance with the measurement principle described above. Further, the wavelength adjusting means electrically calibrates the mixed light emitting means with the first light and the second light that are electrically modulated with the same frequency and opposite phase signals, and is made of water kept at a predetermined temperature. The sample is emitted to the sample for measurement, and the sound intensity generated by the sample for calibration is measured by the sound intensity measuring means. The wavelength adjusting means adjusts the wavelength of the first light generated by the mixed light emitting means, the wavelength of the second light, or both so that the magnitude of the sound wave generated from the measured calibration sample becomes zero. To do. When the magnitude of the sound wave generated from the calibration sample is zero, the first sound wave generated by the first light and the second sound wave generated by the second light are in opposite phase and in magnitude. Are equal to each other and cancel each other in a superimposed manner in the calibration sample. Therefore, each of the wavelength of the first light and the wavelength of the second light adjusted as described above is a wavelength at which water exhibits the same absorbance, and corresponds to the wavelength λ ₁ and the wavelength λ ₂ , respectively. Here, since the wavelength of the first light and the wavelength of the second light emitted from the mixed light emitting means are set and adjusted in the wavelength adjustment procedure, the mixed light emitting means emits the first light emitted from the mixed light emitting procedure. The wavelength of one light and the wavelength of the second light are set to the wavelengths adjusted in the wavelength adjustment procedure.

As described above, in the wavelength adjustment procedure, the wavelength adjustment unit adjusts either or both of the wavelength of the first light and the wavelength of the second light emitted by the mixed light emission unit, thereby The wavelength and the wavelength of the second light can be made to coincide with the wavelength λ ₁ and the wavelength λ ₂ selected from the absorbance characteristics of the component to be measured and the water at a predetermined temperature according to the measurement principle described above. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the subject or the object to be measured.

  The component concentration measurement apparatus control method of the present invention has a temperature measurement procedure in which the temperature measurement means for measuring the temperature measures the temperature of the object to be measured before the mixed light emission procedure. The predetermined temperature may be equal to or higher than the temperature of the object to be measured.

In the present invention, the temperature measurement means measures the temperature of the object to be measured as a temperature measurement procedure before the mixed light emission procedure of the component concentration measurement device control method. Thereafter, in the mixed light emission procedure, the mixed light emission means sets the wavelength of the first light to be emitted and the wavelength of the second light to a predetermined value higher than the temperature of the object measured by the temperature measurement means in the temperature measurement procedure. The wavelength λ ₁ and the wavelength λ ₂ are set according to the measurement principle described above based on the component to be measured of the object to be measured and the absorbance characteristics of water at the temperature. The mixed light emitting means emits the first light and the second light whose wavelengths are set as described above to the object to be measured, and the sound intensity measuring means measures the magnitude of the sound wave generated from the object to be measured. On the other hand, the temperature control means changes the temperature of the object to be measured within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. Thus, the temperature control means can change the temperature of the object to be measured within a predetermined range including the predetermined temperature only by heating in the operation of searching for the minimum acoustic wave temperature. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the object to be measured with a simple configuration.

  The component concentration measuring apparatus control method of the present invention has a temperature measuring procedure in which a temperature measuring means for measuring a temperature measures the temperature of the object to be measured before the wavelength adjusting procedure, and the predetermined wavelength in the wavelength adjusting procedure is determined. The temperature may be equal to or higher than the temperature of the object to be measured.

In the present invention, prior to the wavelength adjustment procedure of the component concentration measurement device control method, the temperature measurement means measures the temperature of the object to be measured as a temperature measurement procedure. After that, in the wavelength adjustment procedure, the wavelength adjustment means sends the wavelength of the first light and the wavelength of the second light emitted by the mixed light emission means to the mixed light emission means. The wavelength λ ₁ and the wavelength λ ₂ selected according to the above-described measurement principle are set and adjusted from the absorbance characteristics of the component to be measured and the water at a predetermined temperature higher than the temperature of the measurement object. Thereafter, in the mixed light emission procedure, the mixed light emission means sets the wavelength of the first light to be emitted and the wavelength of the second light to the wavelengths adjusted by the wavelength adjustment means. The mixed light emitting means emits the first light and the second light whose wavelengths are set as described above to the object to be measured, and the sound intensity measuring means measures the magnitude of the sound wave generated from the object to be measured. On the other hand, the temperature control means changes the temperature of the object to be measured within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. As described above, the temperature control means can change the temperature of the object to be measured within a range including a predetermined temperature only by heating in the operation of searching for the minimum acoustic wave temperature. Therefore, the component concentration measuring apparatus control method of the present invention can accurately measure the component concentration of the measurement target of the object to be measured with a simple configuration.

  The component concentration measurement apparatus control method of the present invention includes a temperature measurement procedure in which a temperature measurement unit that measures temperature measures the temperature of the subject before the mixed light emission procedure, and the temperature measurement unit in the mixed light emission procedure The predetermined temperature may be equal to or higher than the temperature of the subject.

In the present invention, the temperature measurement means measures the temperature of the subject as the temperature measurement procedure before the mixed light emission procedure of the component concentration measurement device control method. Thereafter, in the mixed light output procedure, the mixed light output means sets the wavelength of the first light and the second light emitted to a predetermined temperature higher than the temperature of the subject measured by the temperature measurement means in the temperature measurement procedure. Are set to the wavelength λ ₁ and the wavelength λ ₂ selected according to the above-described measurement principle from the components to be measured of the subject and the absorbance characteristics of water. The mixed light emitting means emits the first light and the second light whose wavelengths are set as described above, and the sound intensity measuring means measures the magnitude of the sound wave generated from the subject, while the temperature control means Changes the temperature of the holding body within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. Thus, in the operation in which the temperature control unit searches for the minimum acoustic wave temperature, the temperature of the holding body can be changed within a predetermined range including the predetermined temperature only by heating. Therefore, the component concentration measuring apparatus control method of the present invention can easily and accurately measure the component concentration of the measurement target of the object to be measured.

  The component concentration measurement apparatus control method of the present invention includes a temperature measurement procedure in which a temperature measurement unit that measures temperature measures the temperature of the subject before the wavelength adjustment procedure, and the predetermined wavelength in the wavelength adjustment procedure The temperature may be equal to or higher than the temperature of the subject.

In the present invention, the temperature measurement means measures the temperature of the subject as a temperature measurement procedure before the wavelength adjustment procedure of the component concentration measurement device control method. After that, in the wavelength adjustment procedure, the wavelength adjustment means sends the wavelength of the first light and the wavelength of the second light emitted by the mixed light emission means to the mixed light emission means. The wavelength λ ₁ and the wavelength λ ₂ selected according to the aforementioned measurement principle are set and adjusted based on the absorbance characteristics of the component to be measured and the water at a predetermined temperature higher than the temperature of the sample. Thereafter, in the mixed light emission procedure, the mixed light emission means sets the wavelength of the first light to be emitted and the wavelength of the second light to the wavelengths adjusted by the wavelength adjustment means. The mixed light emitting means emits the first light and the second light whose wavelengths are set as described above, and the sound intensity measuring means measures the magnitude of the sound wave generated from the subject, while the temperature control means Changes the temperature of the holding body within a predetermined range including a predetermined temperature. Then, the temperature control means searches for the minimum sound wave temperature at which the sound wave measured by the sound wave intensity measuring means is minimized. As described above, the temperature control means can change the temperature of the holding body within a range including the predetermined temperature only by heating in the operation of searching for the minimum acoustic wave temperature. Therefore, the component concentration measurement apparatus control method of the present invention can easily and accurately measure the component concentration of the subject to be measured.

  The component concentration measuring apparatus and the component concentration apparatus control method of the present invention emit light of two different wavelengths set to wavelengths selected from the absorbance characteristics of the component to be measured at a predetermined temperature, and are maintained at the predetermined temperature. By measuring the sound wave generated from the object to be measured or the object, the component concentration can be accurately measured without error due to temperature change.

  Embodiments of the present invention will be described with reference to the accompanying drawings.

  The embodiment described below is an example of the configuration of the present invention, and the present invention is not limited to the following embodiment. In the following, embodiments of measuring the component concentration of the subject will be described for the component concentration measuring apparatus and the component concentration measuring apparatus control method of the present invention. This corresponds to the embodiment for measuring the component concentration of the measurement object.

(First embodiment)
The component concentration measuring apparatus according to the first embodiment of the present invention will be described. The component concentration measurement apparatus according to the first embodiment of the present invention includes a mixed light emitting unit that electrically modulates intensity of two different wavelengths of light with signals having the same frequency and opposite phase, and emits the light to a measurement object. A temperature control means for changing the temperature of the object to be measured; a single light emitting means for electrically modulating the intensity of one of the two wavelengths and emitting the light to the object to be measured; and the object to be measured A component concentration measuring device comprising: a sound intensity measuring means for measuring the magnitude of a sound wave generated from an object. Furthermore, the component concentration measuring apparatus of the present embodiment preferably includes a component concentration calculating means for the subject.

  FIG. 2 shows the configuration of the component concentration measuring apparatus according to the first embodiment of the present invention. In FIG. 2, parts that can be realized by a normal technique such as a power source or a control unit for controlling the entire operation are not shown.

  In FIG. 2, the component concentration measuring apparatus 10 of the present embodiment includes a first light source 11, a second light source 12, a modulation signal generating unit 21, a 180 ° phase shift unit 22 as a part of the mixed light emitting unit, Multiplexer 31, wavelength controller 41, third light source 13 as part of single light emitting means, multiplexer 31, temperature detector 61 as part of temperature controller, heating part 62, cooling part 63, a temperature control unit 65, a heat conducting material 93, a sound wave detection unit 71 as a part of the sound wave intensity measurement unit, a sound wave intensity display unit 72, an adhesive rubber 73, and a component concentration calculation unit 81 as a component concentration calculation unit. The The multiplexing unit 31 is included in the mixed light emitting unit and the single light emitting unit. Here, the heat conducting material 93 is the holding body that holds the subject 1 stably.

  The output terminal of the modulation signal generation unit 21 is connected to the modulation signal input terminal of the first light source 11 and the input terminal of the 180 ° phase shift unit 22 by signal transmission means.

  The output terminal of the 180 ° phase shifter 22 is connected to the modulation signal input terminal of the second light source 12 and the modulation signal input terminal of the third light source 13 by signal transmission means.

  The output terminal of the first light source 11 is connected to the first optical input terminal of the multiplexing unit 31 by light transmission means. The output terminal of the second light source 12 is connected to the second optical input terminal of the multiplexing unit 31 by light transmission means. The output terminal of the third light source 13 is connected to the third optical input terminal of the multiplexing unit 31 by light transmission means.

  The first output terminal of the wavelength control unit 41 is connected to the wavelength control signal input terminal of the first light source 11 by signal transmission means. The second output terminal of the wavelength control unit 41 is connected to the wavelength control signal input terminal of the second light source 12 by signal transmission means. The third output terminal of the wavelength control unit 41 is connected to the wavelength control signal input terminal of the third light source 13 by signal transmission means. The emitted light 32 emitted from the light output terminal of the multiplexing unit 31 is absorbed by the subject 1.

  The output terminal of the temperature detector 61 is connected to the temperature signal input terminal of the temperature controller 65 by signal transmission means. The input terminal of the heating unit 62 is connected to the heating power output terminal of the temperature control unit 65 by signal transmission means. The input terminal of the cooling unit 63 is connected to the cooling power output terminal of the temperature control unit 65 by signal transmission means.

  The temperature detection unit 61, the heating unit 62, and the cooling unit 63 are in contact with the subject 1 through the heat conducting material 93 in the vicinity of the position where the sound wave is generated by the emitted light 32 in the subject 1 as in the mounting example described later. Although shown in FIG. 2, the heat conducting material 93 is shown in a conceptual shape in order to avoid the complexity of the drawing.

  The output terminal of the sound wave detection unit 71 is connected to the input terminal of the component concentration calculation unit 81 and the input terminal of the sound wave intensity display unit 72 by signal transmission means. The sound wave detection unit 71 is provided in contact with the subject 1 via an adhesive rubber 73 in the vicinity of the position where the sound wave is generated by the emitted light 32 in the subject 1.

  Here, an implementation example of the component concentration measuring apparatus 10 of the present embodiment will be described. FIG. 3A and FIG. 3B show an implementation example of the component concentration measuring apparatus 10 of the present embodiment. FIG. 3A is a diagram showing a state in which the component concentration of the index finger of the left hand as the subject 1 is measured from the fingertip direction by the component concentration measuring apparatus 10 of the present embodiment, and FIG. It is a conceptual diagram of the cross section in the broken line Y shown to). However, in order to facilitate understanding of the drawing, the subject 1 is shown on the outside. On the other hand, FIG. 3B is a conceptual diagram of the component concentration measuring apparatus 10 as viewed from the left direction of FIG. 3A in the cross section taken along the broken line X shown in FIG. However, in order to facilitate understanding of the drawing, the subject 1 is shown on the outside.

  In FIG. 3A, the sound wave detection unit 71 provided in the sound wave detection unit housing 91 is in contact with the subject 1 through the adhesive rubber 73. On the other hand, a temperature detection unit 61, a heating unit 62, and a cooling unit 63 are provided inside the semi-cylindrical protective casing 92, and the temperature detection unit 61, the heating unit 62, and the cooling unit 63 are semi-cylindrical and flexible. It is in contact with the subject 1 through a heat conducting material 93 made of the material. Further, a buffer material may be provided between the heat conducting material 93 and the subject 1. In addition, the light emitting unit 51 including the first light source 11, the second light source 12, the third light source 13, the modulation signal generation unit 21, the 180 ° phase shift unit 22, and the multiplexing unit 31 is the top of the protective casing 92. The emitted light 32 is emitted through the heat conducting material holes 94 of the heat conducting material 93.

Next, the function of each part which comprises the component concentration measuring apparatus 10 of this Embodiment is demonstrated with reference to FIG. In the following, as an example, the wavelengths of the first light generated by the first light source 11 and the second light generated by the second light source 12 are the wavelengths λ ₁ and λ ₂ described in the above-described measurement principle. The case will be described.

  The modulation signal generation unit 21 has a function of generating a modulation signal having a predetermined frequency and transmitting it to the first light source 11 and the 180 ° phase shift unit 22.

  The 180 ° phase shift unit 22 has a function of shifting the phase of the modulation signal received from the modulation signal generation unit 21 by 180 ° and transmitting the phase to the second light source 12 and the third light source 13.

  The first light source 11 has a function of generating the first light intensity-modulated by the modulation signal transmitted from the modulation signal generation unit 21 and transmitting the first light to the first optical input terminal of the multiplexing unit 31. Further, the first light source 11 has a function of setting and further adjusting the wavelength by a control signal transmitted from the wavelength control unit 41. Here, the 1st light source 11 can be comprised by a semiconductor laser and a drive circuit, for example. The semiconductor laser can change the wavelength of light generated by heating or cooling with a heater or a Peltier element.

  The second light source 12 generates the second light generated by the modulation signal generation unit 21 and the 180 ° phase shift unit 22 intensity-modulated by the modulation signal phase-shifted by 180 °. It has a function to transmit to the optical input terminal. Further, the second light source 12 has a function of setting and further adjusting the wavelength by a control signal transmitted from the wavelength control unit 41. Here, the second light source 12 can be constituted by, for example, a semiconductor laser and a drive circuit.

The first light and the second light are lights obtained by modulating light of wavelength λ ₁ and light of wavelength λ ₂ with signals having the same frequency and opposite phases.

  The third light source 13 generates the third light generated by the modulation signal generation unit 21 and the intensity-modulated signal by the 180 ° phase shift unit 22 by 180 ° phase shift. It has a function to transmit to the optical input terminal. Further, the third light source 13 has a function of setting and further adjusting the wavelength by a control signal transmitted from the wavelength control unit 41. Here, the third light source 13 can be constituted by, for example, a semiconductor laser and a drive circuit.

  The wavelength control unit 41 transmits the control signal from the first output terminal, the second output terminal, and the third output terminal to the first light source 11, the second light source 12, and the third light source 13, respectively. The first light source 11, the second light source 12, and the third light source 13 each have a function of setting and further adjusting the wavelength of light generated.

  The combining unit 31 has a function of combining the first light generated by the first light source 11 and the second light generated by the second light source 12 and outputting the combined light as an output light 32. Furthermore, it has a function of emitting the third light generated by the third light source 13 as the outgoing light 32. The multiplexing unit 31 can be realized by an optical coupler, for example.

  The temperature detection unit 61 has a function of detecting the temperature of the heat conducting material 93 near the position where the sound wave is generated by the emitted light 32 in the subject 1 and transmitting a signal indicating the detected temperature to the temperature control unit 65. Here, the temperature of the heat conducting material 93 can be matched with the temperature of the subject 1 by making the heat conducting material 93 from a material having high thermal conductivity. The temperature detector 61 can be realized by a thermistor, for example.

  The heating unit 62 has a function of heating the heat conducting material 93 with the heating power supplied from the temperature control unit 65. The heating unit 62 can be realized by a heater, for example.

  The cooling unit 63 has a function of cooling the heat conducting material 93 by the cooling power supplied from the temperature control unit 65. The cooling unit 63 can be realized by a Peltier element, for example.

  The temperature control unit 65 monitors the temperature of the heat conducting material 93 by the temperature detecting unit 61, supplies the heating power to the heating unit 62 to heat the heat conducting material 93, or supplies the cooling power to the cooling unit 63 to supply the heat conducting material 93. By cooling, the temperature of the heat conducting material 93 is changed within a predetermined range, or has a function of maintaining a predetermined constant temperature.

  The heat conducting material 93 has a function of flexibly contacting the subject 1 and holding it stably, and conducting heat between the temperature detection unit 61, the heating unit 62 and the cooling unit 63 and the subject 1. The heat conducting material 93 is made of, for example, rubber that is flexible and has high thermal conductivity, so that the heat conducting material 93 is appropriately brought into contact with the subject 1 and held, and the temperature of the heat conducting material 93 can be matched with the temperature of the subject 1. it can.

  The sound wave detection unit 71 detects sound waves generated from the subject 1 by the emitted light 32 through the adhesive rubber 73, and a signal indicating the magnitude of the detected sound waves is a component concentration calculation unit 81 and a sound wave intensity display unit 72. It has a function to transmit to.

  The sound wave intensity display unit 72 receives a signal indicating the magnitude of the sound wave generated from the object 1 detected by the sound wave detection unit 71 and transmitted from the sound wave detection unit 71, and is detected by the sound wave detection unit 71. 1 has a function of displaying the magnitude of the sound wave generated from 1.

  The adhesive rubber 73 has a function of contacting the subject 1 and transmitting sound waves generated from the subject 1 to the sound wave detection unit 71. The adhesive rubber 73 is made of, for example, a flexible rubber that can easily transmit sound waves.

  The component concentration calculation unit 81 has a function of calculating and displaying the concentration of the measurement target component contained in the subject 1 from the signal indicating the magnitude of the sound wave generated from the subject 1 received from the sound wave detection unit 71. Here, the method by which the component concentration calculation unit 81 calculates the concentration of the component to be measured is the same as the method described in the above-described measurement principle.

Next, the component concentration measurement operation of the component concentration measuring apparatus 10 of the present embodiment will be described with reference to FIG. The component concentration measuring apparatus 10 performs the following operation as the mixed light emission procedure. The wavelength control unit 41 selects the wavelength of the light generated by the first light source 11 and the second light source 12 from the component to be measured of the subject 1 and the absorbance characteristics of water at a predetermined temperature according to the above-described measurement principle. The wavelength λ ₁ and the wavelength λ ₂ are set. Here, the predetermined temperature may be a temperature at which the absorbance characteristics of the component to be measured are acquired in detail, for example, in the vicinity of the normal temperature of the subject 1.

  The first light source 11 generates first light that is intensity-modulated by the modulation signal generated by the modulation signal generator 21. The second light source 12 generates the second light generated by the modulation signal generator 21 and intensity-modulated by the modulation signal shifted by 180 ° by the 180 ° phase shifter 22. Therefore, the first light and the second light are two waves of light having the same frequency and intensity-modulated with signals of opposite phases.

  Each of the first light source 11 and the second light source 12 transmits the generated first light and second light to the multiplexing unit 31.

  The combining unit 31 combines the first light received from the first light source 11 and the second light received from the second light source 12 and outputs the combined light as outgoing light 32.

  Next, the component concentration measuring apparatus 10 performs the following operation as a minimum sound intensity measurement procedure.

The first sound wave is generated from the subject 1 by the first light emitted from the multiplexing unit 31, and the second sound wave is generated and superimposed from the subject 1 by the second light. The sound wave detecting unit 71 detects (s ₁ -s ₂ ) as a sound wave of the difference between the first sound wave and the second sound wave, and the detected sound wave size is displayed on the sound wave intensity display part 72.

As described above, the component concentration measuring apparatus 10 controls the temperature control unit 65 while monitoring the magnitude of the difference between the first sound wave and the second sound wave displayed on the sound wave intensity display unit 72. Then, the temperature of the heat conducting material 93 is changed within a predetermined range including the predetermined temperature, and the sound wave minimum temperature at which the sound wave detected by the sound wave detecting unit 71 is minimized is searched. When detecting the sonic minimum temperature, the component concentration measuring apparatus 10 controls the temperature control unit 65 to stop the operation of changing the temperature of the heat conducting material 93 at the sonic minimum temperature, thereby keeping the temperature of the heat conducting material 93 constant. To keep. Furthermore, the component concentration measuring apparatus 10 indicates the sound wave detected by the sound wave detecting unit 71 at the minimum sound wave temperature, that is, the minimum sound wave intensity, from the signal indicating the sound wave transmitted from the sound wave detecting unit 71 to the component concentration calculating unit 81. Get a signal. Here, at the sonic minimum temperature, the wavelength at which the absorbance of the component to be measured of the subject 1 is significantly different from the absorbance of water coincides with the wavelength of the first light, and the water of the subject 1 is the first wavelength. The wavelength showing the same absorbance as that at the wavelength of the light coincides with the wavelength of the second light. Accordingly, the minimum sound wave intensity measured at the sound wave minimum temperature corresponds to the difference between the first sound wave and the second sound wave, that is, (s ₁ −s ₂ ) described in the above measurement principle.

Next, the component concentration measuring apparatus 10 performs the following operation as a single sound intensity measurement procedure. The temperature controller 65 continues the operation of keeping the temperature of the heat conducting material 93 at the sonic minimum temperature. The first light source 11 and the second light source 12 stop generating the first light and the second light, and the third light source 13 generates the third light. The emitted light 32 is emitted. Here, the wavelength of the third light generated by the third light source 13 is set by the wavelength control unit 41 to the same wavelength λ ₂ as that of the second light generated by the second light source 12. Further, the intensity of the third light is modulated by the modulation signal transmitted from the 180 ° phase shifter 22 in the same manner as the second light. Further, the intensity of the third light generated and emitted by the third light source 13 is adjusted to be equal to the intensity of the second light generated and emitted by the second light source 12.

The sound wave detection unit 71 detects a sound wave generated from the subject 1, that is, a single sound wave intensity, and transmits a signal indicating the detected single sound wave intensity to the component concentration calculation unit 81. The single sound wave intensity detected as described above corresponds to the s ₂ described in the above measurement principle.

Next, the component concentration measuring apparatus 10 performs the following operation as a component concentration calculation procedure. The component concentration calculation unit 81 calculates and displays the component concentration from the (s ₁ -s ₂ ) and s ₂ received from the sound wave detection unit 71 according to the measurement principle described above.

  As described above, the component concentration measuring apparatus 10 according to the present embodiment makes the absorbance of the component to be measured of the subject 1 significantly different from the absorbance of water by matching the temperature of the heat conducting material 93 with the predetermined temperature. The wavelength of the first light is matched with the wavelength of the first light, and the wavelength indicating the same absorbance as the water of the subject 1 at the wavelength of the first light is matched with the wavelength of the second light. The component concentration of the specimen 1 can be accurately measured.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject.

(Second embodiment)
The component concentration measuring apparatus according to the second embodiment of the present invention will be described. The component concentration measuring apparatus according to the present embodiment is the same as the component concentration measuring apparatus according to the first embodiment of the present invention, wherein the single light emitting means is a predetermined light of two different wavelengths of the mixed light emitting means. This is a case where the light of one wavelength is configured by a portion that is electrically intensity-modulated and emitted to the subject.

  FIG. 4 shows the configuration of the component concentration measuring apparatus according to the present embodiment. In FIG. 4, the component concentration measuring apparatus 10 of the present embodiment is the same as the component concentration measuring apparatus 10 of the first embodiment of the present invention described with reference to FIG. In the case where the light emitting means is a portion that emits light having a predetermined wavelength out of the two different wavelengths of the mixed light emitting means, that is, the second light source 12 and the combining portion 31. is there. Since the other parts of the component concentration measuring apparatus 10 of the present embodiment are the same as the component concentration measuring apparatus 10 of the first embodiment of the present invention, the component concentration measuring apparatus 10 of the present embodiment is here. About a different part from the component concentration measuring apparatus 10 of 1st embodiment of this invention is demonstrated.

  The configuration of the component concentration measuring apparatus 10 of the present embodiment is a configuration in which the third light source 13 of the component concentration measuring apparatus 10 of the first embodiment of the present invention is removed, and the single light emitting means is the first one. The second light source 12 and the multiplexing unit 31 are included. Therefore, in the component concentration measuring apparatus 10 of the present embodiment, the multiplexing unit 31 is configured to use the third light generated by the third light source 13 described in the component concentration measuring apparatus 10 of the first embodiment of the present invention. Does not have a function of emitting the light as the outgoing light 32.

  The wavelength control unit 41 transmits control signals from the first output terminal and the second output terminal to the first light source 11 and the second light source 12, respectively, and the first light source 11 and the second light source 12 are transmitted. The wavelength of each generated light is set and further adjusted.

  Next, the operation of the component concentration measuring apparatus 10 of the present embodiment will be described with respect to differences from the operation of the component concentration measuring apparatus 10 of the first embodiment of the present invention.

  In the operation as the single light emitting means of the component concentration measuring apparatus 10 of the present embodiment, the first light source 11 stops generating the first light, and the second light source 12 emits the second light. The second light is emitted from the multiplexing unit 31. Here, the intensity of the second light generated and emitted by the second light source 12 is adjusted to be equal to the state where the minimum sound wave intensity is measured in the mixed light emission procedure.

The sound wave detection unit 71 detects a sound wave generated from the subject 1 held at the sound wave minimum temperature by the temperature control unit 65, that is, the single sound wave intensity, and outputs a signal indicating the detected single sound wave intensity as a component concentration It transmits to the calculation part 81. It said single wave intensity detected as described above corresponds to the s _2.

The component concentration calculation unit 81 calculates and displays the component concentration based on the s ₂ received from the sound wave detection unit 71 in the same manner as the component concentration measurement apparatus 10 of the first embodiment.

  As described above, the component concentration measuring apparatus 10 according to the present embodiment emits the single light emitting means by electrically modulating the intensity of one wavelength of two different wavelengths of light from the mixed light emitting means. By configuring with the portion to perform, the component concentration of the subject 1 can be accurately measured with a simple configuration.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject.

(Third embodiment)
A component concentration measuring apparatus according to a third embodiment of the present invention will be described. The component concentration measuring apparatus according to the present embodiment is a case where the temperature control unit has a function of searching for the minimum acoustic wave temperature in the component concentration measuring apparatuses according to the first and second embodiments of the present invention. In the following, as an example of the component concentration measuring device of the present embodiment, the case where the temperature control unit of the component concentration measuring device of the second embodiment of the present invention further has a function of searching for the sonic minimum temperature. A different part from the component concentration measuring apparatus of 2nd embodiment of this invention is demonstrated.

  FIG. 5 shows the configuration of the component concentration measuring apparatus according to the present embodiment. Regarding the configuration of the component concentration measuring apparatus 10 of the present embodiment shown in FIG. 5, portions different from the configuration of the component concentration measuring apparatus of the second embodiment of the present invention will be described.

  The component concentration measuring apparatus 10 according to the present embodiment removes the sound wave intensity display unit 72 of the component concentration measuring apparatus 10 according to the second embodiment of the present invention, and the output terminal of the sound wave detecting unit 71 is connected to the temperature control unit 65. The configuration is connected to the sound wave intensity input terminal. Further, the control signal output terminal of the temperature control unit 65 is connected to the control signal input terminal of the component concentration calculation unit 81.

  Next, the function of each part constituting the component concentration measuring apparatus 10 of the present embodiment will be described with respect to the part different from the function of each part constituting the component concentration measuring apparatus 10 of the second embodiment of the present invention.

  The sound wave detection unit 71 further has a function of detecting a sound wave generated from the subject 1 and transmitting a signal indicating the magnitude of the detected sound wave to the temperature control unit 65.

  The temperature control unit 65 receives a signal indicating the size of the sound wave detected by the sound wave detection unit 71 and monitors the size of the sound wave detected by the sound wave detection unit 71, while controlling the temperature of the heat conducting material 93. It further has a function of searching for the sound wave minimum temperature at which the magnitude of the sound wave detected by the sound wave detection unit 71 is minimized by changing in a predetermined range including a predetermined temperature. Further, when the temperature control unit 65 detects the minimum sound wave temperature, the temperature control unit 65 maintains a temperature of the heat conducting material 93 at the minimum sound wave temperature, and a signal indicating that the heat conducting material 93 is maintained at the minimum sound wave temperature. It also has a function of transmitting to the calculation unit 81.

  The component concentration calculation unit 81 receives a signal indicating that the heat conducting material 93 is maintained at the sonic minimum temperature from the temperature control unit 65, and acquires the minimum sonic intensity from the signal received from the sonic detection unit 71. It has the function to do.

  Next, the operation of the component concentration measuring apparatus 10 of the present embodiment will be described with respect to differences from the operation of the component concentration measuring apparatus of the second embodiment of the present invention.

  The component concentration measuring apparatus 10 according to the present embodiment is configured such that the difference between the first sound wave and the second sound wave generated from the subject 1 by the emitted light 32 emitted by the mixed light emitting means in the minimum sound intensity measurement procedure. Is detected by the sound wave detection unit 71 and a signal indicating the magnitude of the detected sound wave is transmitted to the temperature control unit 65. The temperature control unit 65 receives a signal indicating the magnitude of the sound wave detected by the sound wave detection unit 71 and monitors the magnitude of the sound wave detected by the sound wave detection unit 71 while heating the heating unit 62 or the cooling unit 63. Electric power or cooling power is supplied, the temperature of the heat conducting material 93 is changed within a predetermined range including the predetermined temperature, and the sound wave minimum temperature at which the sound wave detected by the sound wave detection unit 71 is minimized is searched. When the temperature controller 65 detects the sonic minimum temperature, the temperature control unit 65 stops the operation of changing the temperature of the heat conducting material 93 at the sonic minimum temperature, and keeps the temperature of the heat conducting material 93 constant. Is transmitted to the component concentration calculation unit 81. The component concentration calculation unit 81 receives the signal indicating that the heat conducting material 93 is maintained at the sonic minimum temperature from the temperature control unit 65, and selects the minimum sonic intensity from the signals received from the sonic detection unit 71. To get. The operation other than the above is the same as the operation of the component concentration measuring apparatus according to the second embodiment of the present invention.

  As described above, in the component concentration measuring apparatus 10 of the present embodiment, the temperature control unit 65 causes the temperature of the heat conducting material 93 to coincide with the predetermined temperature, whereby the absorbance of the measurement target component of the subject 1 is increased. A wavelength that is significantly different from the absorbance of water is made to coincide with the wavelength of the first light, and the wavelength that shows the same absorbance as the water of the subject 1 is the wavelength of the second light. By matching, the component concentration of the subject 1 can be accurately measured.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject.

(Fourth embodiment)
A component concentration measuring apparatus according to a fourth embodiment of the present invention will be described. The component concentration measuring apparatus according to the present embodiment is the same as the component concentration measuring apparatus according to the first to third embodiments of the present invention. Then, the intensity of the sound wave is electrically modulated and emitted to water, and the sound intensity measuring means measures the magnitude of the sound wave generated from the water, and the light of the two different wavelengths so that the magnitude of the measured sound wave becomes zero. It is a case where the wavelength adjustment means which adjusts the wavelength of is further provided. Further, the present embodiment is an example in which the wavelength adjusting unit uses the functions of the mixed light emitting unit and the sound wave intensity measuring unit.

  In the following, as an example of the component concentration measuring apparatus of the present embodiment, the case where the component concentration measuring apparatus of the third embodiment of the present invention further includes the wavelength adjusting means will be described. A different part from the component concentration measuring apparatus of a form is demonstrated.

  FIG. 6 shows a configuration of a component concentration measuring apparatus according to the fourth embodiment. Regarding the configuration of the component concentration measuring apparatus according to the present embodiment shown in FIG. 6, portions different from the configuration of the component concentration measuring apparatus according to the third embodiment of the present invention will be described.

  In the component concentration measuring apparatus 10 of the present embodiment shown in FIG. 6, the output terminal of the sound wave detection unit 71 is further connected to the sound wave signal input terminal of the wavelength control unit 41 by signal transmission means. Furthermore, the component concentration measuring apparatus 10 of the present embodiment includes a calibration sample 5 as a part of the wavelength adjusting means. Here, the wavelength adjusting means includes a wavelength control unit 41 and a calibration sample 5.

  Regarding the function of each part constituting the component concentration measuring apparatus 10 of the present embodiment, a part different from the function of each part constituting the component concentration measuring apparatus of the third embodiment of the present invention will be described.

  The wavelength control unit 41 further has a function of adjusting the wavelength of the first light and the wavelength of the second light generated by the first light source 11 and the second light source 12 as follows. That is, the first light source 11 and the second light source 12 emit the first light and the second light to the calibration sample 5 as the emitted light 32 through the multiplexing unit 31, and from the calibration sample 5. The sound wave detection unit 71 detects the generated sound wave, and transmits a signal indicating the magnitude of the sound wave to be detected to the wavelength control unit 41. The wavelength control unit 41 receives a signal indicating the size of the sound wave detected by the sound wave detection unit 71, and the wavelength of the first light so that the size of the sound wave detected by the sound wave detection unit 71 is zero. The wavelength of the second light is adjusted.

  For example, the calibration sample 5 has a configuration in which water is sealed in an elliptical cylindrical glass container simulating the cross section of a human finger, and is installed instead of the subject 1 of the component concentration measuring apparatus 10 shown in FIG. It is used for adjusting the wavelength generated by the first light source 11 and the second light source 12.

  Next, the operation of the component concentration measuring apparatus 10 according to the present embodiment will be described with respect to differences from the operation of the component concentration measuring apparatus 10 according to the third embodiment of the present invention.

  The component concentration measuring apparatus 10 of the present embodiment performs the following operation as the wavelength adjustment procedure before the mixed light emission procedure.

  As shown in FIG. 6, the calibration sample 5 is installed at the position where the subject 1 is installed in FIG. 5, that is, at the position where the heat conducting material 93 and the adhesive rubber 73 are in contact.

  The temperature control unit 65 maintains the temperature of the calibration sample 5 at the predetermined temperature.

The wavelength control unit 41 determines the wavelength of the first light and the wavelength of the second light generated by the first light source 11 and the second light source 12 according to the measurement principle described above. The wavelength λ ₁ and the wavelength λ ₂ selected from the component to be measured and the water absorbance characteristics are set.

  The first light source 11 generates the first light intensity-modulated by the modulation signal generated by the modulation signal generator 21. The second light source 12 generates the second light generated by the modulation signal generation unit 21 and intensity-modulated by the modulation signal shifted by 180 ° by the 180 ° phase shift unit 22.

  Each of the first light source 11 and the second light source 12 transmits the generated first light and the second light to the multiplexing unit 31.

  The multiplexing unit 31 multiplexes the first light received from the first light source 11 and the second light received from the second light source 12, and the emitted light 32 is output by the temperature control unit 65 as the predetermined light. The light is emitted in the direction of a predetermined position of the calibration sample 5 held at the temperature.

  In the calibration sample 5, the first sound wave generated by the first light and the second sound wave generated by the second light emitted as the emitted light 32 from the multiplexing unit 31 are generated. Since the first sound wave and the second sound wave are in opposite phases, the sound wave detection unit 71 detects and detects the sound wave of the difference between the first sound wave and the second sound wave. A signal indicating the magnitude of the sound wave is transmitted to the wavelength control unit 41.

The wavelength control unit 41 monitors the magnitude of the difference between the first sound wave and the second sound wave according to the signal received from the sound wave detection unit 71, while the first sound wave and the second sound wave. A control signal is transmitted to the first light source 11 and the second light source 12 so that the magnitude of the sound wave of the difference becomes zero, the wavelength of the first light and the wavelength of the second light, or the first light source The wavelength of one light or the wavelength of the second light is adjusted. The state in which the magnitude of the sound wave generated from the calibration sample 5 is zero is a state in which the first sound wave and the second sound wave have opposite phases, are equal in magnitude, and cancel each other. Each of the wavelength of the first light and the wavelength of the second light corresponds to a wavelength at which water exhibits the same absorbance, that is, the wavelength λ ₁ and the wavelength λ ₂ . By adjusting as described above, the wavelength of the first light and the wavelength of the second light are selected from the components to be measured of the subject 1 and the absorbance characteristics of water at a predetermined temperature according to the measurement principle described above. The wavelength λ ₁ and the wavelength λ ₂ can be matched.

  After the above operation, the calibration sample 5 is removed and the subject 1 is installed.

  In the next mixed light emission procedure, the wavelength controller 41 sets the wavelength of the light generated by the first light source 11 and the second light source 12 to the wavelength adjusted in the wavelength adjustment procedure.

  As described above, the component concentration measuring apparatus 10 according to the present embodiment selects two different wavelengths of light from the components to be measured of the subject 1 and the absorbance characteristics of water at a predetermined temperature according to the measurement principle described above. By adjusting the wavelength of the two different wavelengths so that the generated sound wave becomes zero, the light is emitted to the calibration sample 5 made of water kept at the predetermined temperature. Thus, the component concentration of the subject 1 can be accurately measured.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject.

(Fifth embodiment)
A component concentration measuring apparatus according to a fifth embodiment of the present invention will be described. The component concentration measuring apparatus according to the present embodiment is a case where the component concentration measuring apparatus according to the third embodiment of the present invention further includes a temperature measuring means. Here, with respect to the component concentration measuring apparatus according to the present embodiment, portions different from the component concentration measuring apparatus according to the third embodiment of the present invention will be described.

  FIG. 7 shows the configuration of the component concentration measuring apparatus according to the present embodiment. In FIG. 7, the component concentration measuring apparatus 10 of the present embodiment is similar to the component concentration measuring apparatus 10 of the third embodiment of the present invention described with reference to FIG. And a heat conducting material 43.

  In the subject 1, the temperature measurement unit 42 is installed in contact with the subject 1 through a heat conducting material 43 in the vicinity of a position where a sound wave is generated by the emitted light 32. Here, the heat-conducting material 43 is made of, for example, rubber that is flexible and has high thermal conductivity, so that the heat-conducting material 43 appropriately contacts the subject 1, and the temperature of the heat-conducting material 43 matches the temperature of the subject 1. it can. The temperature measuring unit 42 can be realized by, for example, a thermistor.

  The output terminal of the temperature measurement unit 42 is connected to the temperature signal input terminal of the wavelength control unit 41 by signal transmission means.

  The temperature control signal output terminal of the wavelength control unit 41 is connected to the wavelength setting signal input terminal of the temperature control unit 65 by signal transmission means.

  Next, the function of each part constituting the component concentration measuring apparatus 10 of the present embodiment will be described with respect to parts different from the component concentration measuring apparatus of the third embodiment of the present invention.

  The temperature measuring unit 42 has a function of measuring the temperature of the heat conducting material 43 and transmitting a signal indicating the measured temperature to the wavelength control unit 41.

The wavelength control unit 41 receives a signal indicating the temperature of the heat conducting material 43 from the temperature measuring unit 42, and the light generated by the first light source 11 and the second light source 12 at a predetermined temperature higher than the temperature of the heat conducting material 43. And a function of transmitting a signal indicating the predetermined temperature to the temperature control unit 65. Here, the wavelength control unit 41 preliminarily sets a plurality of predetermined temperatures for setting a wavelength in the vicinity of the normal temperature of the subject 1, and the components to be measured and water of the subject 1 at each of the predetermined temperatures. The wavelength λ ₁ and the wavelength λ ₂ selected according to the aforementioned measurement principle from the absorbance characteristics are stored.

  The temperature controller 65 further has a function of receiving a signal indicating the predetermined temperature from the wavelength controller 41 and changing the temperature of the heat conducting material 93 within a predetermined range including the predetermined temperature.

  Next, the operation of the component concentration measuring apparatus 10 according to the present embodiment will be described with respect to differences from the operation of the component concentration measuring apparatus 10 according to the third embodiment of the present invention.

  In the component concentration measuring apparatus 10 of the present embodiment, the temperature measuring unit 42 measures the temperature of the heat conducting material 43 as a temperature measuring procedure before the mixed light emission procedure, and a signal indicating the measured temperature is sent to the wavelength control unit. 41.

Thereafter, in the mixed light emission procedure, the wavelength control unit 41 receives a signal indicating the temperature of the heat conducting material 43 from the temperature measurement unit 42, and determines the wavelength of light generated by the first light source 11 and the second light source 12. The wavelength λ ₁ and the wavelength λ ₂ selected in accordance with the measurement principle described above are set based on the component to be measured of the subject 1 and the absorbance characteristics of water at a predetermined temperature higher than the temperature of the heat conducting material 43. Further, the wavelength control unit 41 transmits a signal indicating the predetermined temperature to the temperature control unit 65.

  The temperature control unit 65 receives a signal indicating the predetermined temperature higher than the temperature of the heat conducting material 43 from the wavelength control unit 41, and conducts heat conduction in the predetermined range including the predetermined temperature higher than the temperature of the heat conducting material 43. The temperature of the material 93 is changed, and the sound wave minimum temperature is searched. Operations other than those described above are the same as those of the component concentration measuring apparatus 10 according to the third embodiment of the present invention.

  As described above, the component concentration measuring apparatus 10 according to the present embodiment is configured to measure the wavelength of the first light and the wavelength of the second light at the predetermined temperature higher than the temperature of the subject 1 as described above. Therefore, the temperature control means can change the temperature of the heat conducting material 93 in the predetermined range including the predetermined temperature and search for the minimum acoustic wave temperature only by heating. A device configuration can be obtained.

  In addition, the component concentration measuring apparatus 10 of the present embodiment can be configured to have the function of the temperature measuring unit 42 in the temperature detecting unit 61. That is, the temperature controller 41 and the heat conductor 43 are removed, and the temperature controller 65 transmits a signal indicating the temperature of the heat conductor 93 detected by the temperature detector 61 to the wavelength controller 41, so that the wavelength controller 41 is It is possible to perform the same operation as.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject with a simple configuration.

(Sixth embodiment)
A component concentration measuring apparatus according to the sixth embodiment of the present invention will be described. The component concentration measuring apparatus according to the present embodiment is a case where the component concentration measuring apparatus according to the fourth embodiment of the present invention further includes a temperature measuring means. Here, the difference between the component concentration measuring apparatus of the present embodiment and the component concentration measuring apparatus of the fourth embodiment of the present invention will be described.

  FIG. 8 shows the configuration of the component concentration measuring apparatus according to the present embodiment. In FIG. 8, the component concentration measuring apparatus 10 of the present embodiment is similar to the component concentration measuring apparatus 10 of the fourth embodiment of the present invention described with reference to FIG. And a heat conducting material 43. FIG. 8 shows a case where the calibration sample 5 is placed in contact with the adhesive rubber 73 and the heat conducting material 93 at the position of the subject 1 in FIG.

  In the subject 1, the temperature measurement unit 42 is installed in contact with the subject 1 through a heat conducting material 43 in the vicinity of a position where a sound wave is generated by the emitted light 32. Here, the heat-conducting material 43 is made of, for example, rubber that is flexible and has high thermal conductivity, so that the heat-conducting material 43 appropriately contacts the subject 1, and the temperature of the heat-conducting material 43 matches the temperature of the subject 1. it can. The temperature measuring unit 42 can be realized by, for example, a thermistor.

  The output terminal of the temperature measurement unit 42 is connected to the temperature signal input terminal of the wavelength control unit 41 by signal transmission means.

  The temperature control signal output terminal of the wavelength control unit 41 is connected to the wavelength setting signal input terminal of the temperature control unit 65 by signal transmission means.

  Next, the function of each part constituting the component concentration measuring apparatus 10 of the present embodiment will be described with respect to differences from the component concentration measuring apparatus of the fourth embodiment of the present invention.

  The temperature measuring unit 42 has a function of measuring the temperature of the heat conducting material 43 and transmitting a signal indicating the measured temperature to the wavelength control unit 41.

The wavelength control unit 41 receives a signal indicating the temperature of the heat conducting material 43 from the temperature measuring unit 42 and generates the first light source 11 and the second light source 12 at a predetermined temperature higher than the temperature of the heat conducting material 43. It has a function of setting a wavelength of light and further transmitting a signal indicating the predetermined temperature to the temperature controller 65. Here, the wavelength control unit 41 has a plurality of predetermined temperatures for setting wavelengths in the vicinity of the normal temperature of the subject 1 in advance, and the components to be measured and the absorbance of water at each predetermined temperature. The wavelength λ ₁ and the wavelength λ ₂ selected from the characteristics according to the above-described measurement principle are stored.

  The temperature controller 65 further has a function of receiving a signal indicating the predetermined temperature from the wavelength controller 41 and changing the temperature of the heat conducting material 93 within a predetermined range including the predetermined temperature.

  Next, the operation of the component concentration measuring apparatus 10 of the present embodiment will be described with respect to differences from the operation of the component concentration measuring apparatus 10 of the fourth embodiment.

  In the component concentration measuring apparatus 10 of the present embodiment, the temperature measuring unit 42 measures the temperature of the heat conducting material 43 as a temperature measuring procedure before the wavelength adjusting procedure, and a signal indicating the measured temperature is sent to the wavelength controlling unit. 41.

Thereafter, in the wavelength adjustment procedure, the wavelength control unit 41 receives a signal indicating the temperature of the heat conducting material 43 from the temperature measurement unit 42, and determines the wavelength of light generated by the first light source 11 and the second light source 12. The wavelength λ ₁ and the wavelength λ ₂ selected in accordance with the measurement principle described above are set based on the component to be measured of the subject 1 and the absorbance characteristics of water at a predetermined temperature higher than the temperature of the heat conducting material 43. Further, the wavelength control unit 41 transmits a signal indicating the predetermined temperature to the temperature control unit 65. The operation of the wavelength adjustment procedure other than the above is the same as that of the component concentration measuring apparatus according to the fourth embodiment of the present invention.

  Thereafter, in the mixed light emission procedure, the wavelength controller 41 sets the wavelength of the light generated by the first light source 11 and the second light source 12 to the wavelength set in the wavelength adjustment procedure. The temperature control unit 65 receives a signal indicating the predetermined temperature higher than the temperature of the heat conducting material 43 received from the wavelength control unit 41 and includes the predetermined temperature higher than the temperature of the heat conducting material 43. In the range, the temperature of the heat conducting material 93 is changed, and the sound wave minimum temperature is searched. Operations other than those described above are the same as those of the component concentration measuring apparatus 10 according to the third embodiment of the present invention.

  As described above, the component concentration measuring apparatus 10 according to the present embodiment is configured to measure the wavelength of the first light and the wavelength of the second light at the predetermined temperature higher than the temperature of the subject 1 as described above. Therefore, the temperature control means can change the temperature of the heat conducting material 93 within the predetermined range including the predetermined temperature only by heating, and a simple apparatus configuration can be obtained. .

  Further, as a configuration in which the temperature detection unit 61 has the function of the temperature measurement unit 42 described above, the temperature measurement unit 42 is removed, and the temperature control unit 65 outputs a signal indicating the temperature of the heat conducting material 43 detected by the temperature detection unit 61. It is good also as composition which transmits to control part 41.

  As described above, the component concentration measuring apparatus of the present invention can provide a component concentration measuring apparatus that can accurately measure the component concentration of a subject with a simple configuration.

  The component concentration measuring apparatus and the component concentration apparatus control method of the present invention can be applied to the field of measuring the component concentration in a liquid, for example, sugar content measurement of fruits.

  The component concentration measuring apparatus and the component concentration apparatus control method of the present invention can be used for daily health care and cosmetic checks. Moreover, not only humans but also animals can be used for health management.

It is a figure explaining the setting method of the wavelength of the component concentration measuring apparatus and component concentration measuring apparatus control method of this invention. It is a figure explaining the structure of the component concentration measuring apparatus of 1st embodiment. It is a figure explaining the example of mounting of the component concentration measuring apparatus of a 1st embodiment. It is a figure explaining the structure of the component concentration measuring apparatus of 2nd embodiment. It is a figure explaining the structure of the component concentration measuring apparatus of 3rd embodiment. It is a figure explaining the structure of the component concentration measuring apparatus of 4th embodiment. It is a figure explaining the structure of the component density | concentration measuring apparatus of 5th embodiment. It is a figure explaining the structure of the component concentration measuring apparatus of 6th Embodiment. It is a figure explaining the structure of the conventional blood component concentration measuring apparatus. It is a figure explaining the structure of the conventional blood component concentration measuring apparatus.

Explanation of symbols

1 Subject 5 Calibration Sample 10 Component Concentration Measuring Device 11 First Light Source 12 Second Light Source 13 Third Light Source 21 Modulation Signal Generating Unit 22 180 ° Phase Shifting Unit 31 Multiplexing Unit 32 Emission Light 41 Wavelength Control Unit 42 Temperature measurement unit 43 Heat conducting material 51 Light emitting unit 61 Temperature detection unit 62 Heating unit 63 Cooling unit 65 Temperature control unit 71 Sound wave detection unit 72 Sound wave intensity display unit 73 Adhesive rubber 81 Component concentration calculation unit 91 Sound wave detection unit housing 92 Protection Case 93 Heat-conducting material 94 Heat-conducting material hole 101 Subject 102 Driving power source 103 Pulse light source 104 Ultrasonic detector 105 Waveform detector 201 First light source 202 Second light source 203 Driving power source 204 Driving power source 211 Multiplexer 212 Sound Sensor 213 Chopper plate 214 Motor 215 Frequency analyzer

Claims (18)

Mixed light emitting means for electrically modulating the intensity of two different wavelengths of light with signals having the same frequency and opposite phase, and emitting the light to the object to be measured;
Temperature control means for changing the temperature of the object to be measured;
A single light emitting means for electrically modulating the intensity of one of the two wavelengths and emitting it to the object to be measured;
A component concentration measuring device comprising: a sound intensity measuring means for measuring the magnitude of sound waves generated from the object to be measured. The temperature control means changes the temperature of the object to be measured, and keeps the sound wave minimum temperature at which the magnitude of the sound wave generated from the object to be measured is minimized by the light of the two different wavelengths emitted from the mixed light emitting means. And
The component concentration measuring apparatus according to claim 1, wherein the single light emitting unit emits intensity-modulated light to the object to be measured at a minimum sound wave temperature.   The size of the sound wave generated from the object to be measured by the light of the two different wavelengths emitted from the mixed light emitting means and the light of one wavelength out of the two wavelengths emitted from the single light emitting means from the object to be measured. The component concentration measuring apparatus according to claim 1, further comprising a component concentration calculating unit that calculates a component concentration of the object to be measured from the magnitude of the generated sound wave.   The single light emitting means electrically modulates the intensity of one wavelength of two different wavelengths of light from the mixed light emitting means and emits the light to the object to be measured. 4. The component concentration measuring apparatus according to any one of 3 above. Mixed light emitting means for electrically modulating the intensity of two different wavelengths of light with signals having the same frequency and opposite phase, and emitting the light to a subject;
Temperature control means for changing the temperature of the subject;
Single light emitting means for electrically modulating the intensity of one of the two wavelengths and emitting the light to the subject;
A component concentration measuring device comprising: a sound intensity measuring means for measuring a magnitude of a sound wave generated from the subject. The temperature control means changes the temperature of the subject and maintains the sound wave minimum temperature at which the magnitude of the sound wave generated from the subject is minimized by the light of the two different wavelengths emitted from the mixed light emitting means,
6. The component concentration measuring apparatus according to claim 5, wherein the single light emitting means emits intensity-modulated light to the subject at a minimum sound wave temperature.   Generated from the subject by the light of one wavelength out of the magnitude of the sound wave generated from the subject by the light of the two different wavelengths emitted by the mixed light emitting means and the two wavelengths emitted by the single light emitting means. The component concentration measuring apparatus according to claim 5, further comprising: a component concentration calculating unit that calculates a component concentration of the subject from the magnitude of the sound wave.   The single light emitting means electrically modulates the intensity of one wavelength of two different wavelengths of light from the mixed light emitting means and emits the light to the subject. The component concentration measuring apparatus according to any one of the above   The mixed light emitting means emits light of two different wavelengths with the same frequency and an opposite phase signal at the same frequency and emits it to water, and the sound intensity measuring means measures the size of the sound wave generated from the water. 9. The component concentration measurement according to claim 1, further comprising: a wavelength adjusting unit that adjusts the wavelengths of the two different wavelengths so that the magnitude of the measured sound wave becomes zero. apparatus. A mixed-light emitting means for emitting light of two different wavelengths that is electrically intensity-modulated with signals having the same frequency and opposite phase is set to two different wavelengths at which water at a predetermined temperature exhibits the same absorbance. A mixed light exit procedure for exiting to
The temperature control means for changing the temperature changes the temperature of the object to be measured, and the sound intensity measuring means for measuring the magnitude of the sound wave measures the minimum sound intensity that minimizes the magnitude of the sound wave generated from the object to be measured. A minimum sound intensity measurement procedure for holding the minimum sound wave temperature of the object to be measured by which the temperature control means has the minimum sound wave intensity;
A single light emitting means that emits light having one wavelength that is electrically modulated in intensity emits light of one wavelength out of the two different wavelengths to the object to be measured, and the sound intensity measuring means is generated from the object to be measured. And a single sound intensity measuring procedure for measuring the magnitude of the sound wave to be performed in order. Mixing light emitting means for emitting light of two different wavelengths with the same frequency being electrically modulated by an opposite phase signal at the same frequency is set to two different wavelengths at which water at a predetermined temperature exhibits the same absorbance and emitted. A light exit procedure;
The temperature control means for changing the temperature changes the temperature, the sound intensity measuring means for measuring the magnitude of the sound wave measures the minimum sound intensity that minimizes the magnitude of the sound wave generated from the subject, and the temperature control means A minimum sound intensity measurement procedure for maintaining a minimum sound wave temperature that is the minimum sound intensity;
A single light emitting means that emits light with one wavelength modulated with electric intensity is emitted with one of the two different wavelengths, and the sound intensity measurement means generates a sound wave generated from the subject. And a single sound intensity measuring procedure for measuring the component concentration measuring device control method.   After the single sound intensity measurement procedure, the component concentration calculation means for calculating the component concentration from the sound wave size and the sound wave measured by the minimum sound intensity measurement procedure and the sound wave measured by the single sound intensity measurement procedure. The component concentration measuring device control method according to claim 10 or 11, further comprising a component concentration calculating procedure for calculating the component concentration from the size of the component.   The single sound wave intensity measuring procedure is characterized in that the mixed light emitting means emits light of one wavelength out of two different wavelengths, and the sound intensity measuring means measures the size of the sound wave. 13. The component concentration measuring device control method according to any one of 10 to 12.   Wavelength adjusting means for adjusting the wavelength of the two wavelengths of light from the mixed light emitting means electrically modulates the intensity of two different wavelengths of light with the same frequency and opposite phase signals to the mixed light emitting means, A wavelength adjustment procedure for adjusting the wavelength of two different wavelengths of light from the mixed light emitting means so that the sound wave generated from the water measured by the sound intensity measuring means is zero. The component concentration measuring device control method according to claim 10, wherein the component concentration measuring device control method is provided before the mixed light emission procedure.   The temperature measuring means for measuring the temperature has a temperature measuring procedure for measuring the temperature of the object to be measured before the mixed light emitting procedure, and the predetermined temperature in the mixed light emitting procedure is the temperature of the object to be measured. The component concentration measuring device control method according to claim 10, wherein the temperature is equal to or higher than a temperature.   The temperature measuring means for measuring the temperature has a temperature measuring procedure for measuring the temperature of the object to be measured before the wavelength adjusting procedure, and the predetermined temperature in the wavelength adjusting procedure is equal to or higher than the temperature of the object to be measured. The component concentration measuring device control method according to claim 14, wherein:   The temperature measuring means for measuring the temperature has a temperature measuring procedure for measuring the temperature of the subject before the mixed light emitting procedure, and the predetermined temperature in the mixed light emitting procedure is equal to or higher than the temperature of the subject. The component concentration measuring device control method according to claim 11, wherein: A temperature measuring means for measuring temperature has a temperature measuring procedure for measuring the temperature of the subject before the wavelength adjusting procedure, and the predetermined temperature in the wavelength adjusting procedure is equal to or higher than the temperature of the subject. The component concentration measuring device control method according to claim 14.

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