JP5672543B2 - Body composition meter - Google Patents

Description

  The present invention relates to a body composition meter for measuring an index relating to body composition such as the thickness of subcutaneous fat of a human body.

  2. Description of the Related Art Conventionally, a technique for measuring the subcutaneous fat thickness of a human body based on impedance measured by bringing a measurement electrode into contact with a hand or a foot is known (see, for example, Patent Document 1).

JP 2001-178697 A

However, in the measurement method as in Patent Document 1, since the subcutaneous fat is deformed by the force of pressing the measuring instrument, the impedance changes, and it is difficult to accurately measure the subcutaneous fat thickness. was there.
In view of the above circumstances, an object of the present invention is to solve the problem of accurately measuring an index relating to body composition such as subcutaneous fat thickness.

In order to solve the above-mentioned problems, each of the body composition meters according to the present invention is a measurement electrode (first measurement electrode 12 shown in FIG. 1) for making measurement by bringing it into contact with a human body. A voltage measuring electrode and a second voltage measuring electrode; a first current applying electrode and a second current applying electrode arranged between the first and second voltage measuring electrodes; A current generator (first current generator 28 shown in FIG. 2) that outputs an alternating current flowing between one current application electrode and the second current application electrode; and the first voltage measurement electrode And a voltage measuring unit (a first voltage measuring unit 30 shown in FIG. 2) for measuring a voltage between the first voltage measuring electrode and the second voltage measuring electrode, and the first current when the measuring electrode comes into contact with a human body. One of the application electrode and the second current application electrode from the other through the human body Between the first current application electrode and the second current application electrode based on the phase difference between the current flowing through the current path to the electrode and the voltage measured by the voltage measurement unit. A body composition measurement unit (a control unit 44 shown in FIG. 2) for obtaining an index relating to body composition, and the body composition measurement unit is configured to calculate a current flowing through the current path and a voltage measured by the voltage measurement unit. When at least one of the reactance calculated from the calculated impedance and the phase difference, or the resistance, or the ratio of the reactance and the resistance is determined to be in a state where all the electrodes are in contact with each other. set the measured value as a reference value (S 10 ~S20 shown in FIG. 10), the measurement is continued after setting the reference value, variation predetermined range from the reference value of the measurement values If it is (S22～S30 shown in FIG. 10), obtaining an index relating to the body composition (S31 shown in FIG. 10).

  In this aspect, paying attention to the difference in how the phase difference occurs between the fat layer and the muscle layer, when the measurement electrode comes into contact with the human body, the first current application electrode and the second current application electrode The measurement electrode contacts the human body based on the phase difference between the current flowing from one of the electrodes through the human body to the other electrode and the voltage measured by the voltage measurement unit. An index regarding body composition at the selected site is being sought. More specifically, the body composition measurement unit includes a reactance (imaginary part of impedance) calculated from an impedance calculated from a current flowing through the current path and a voltage measured by the voltage measurement unit, and a phase difference. Based on resistance (the real part of impedance), an index relating to body composition is obtained.

When it changes due to the pressing force of each electrode on the human body, the soft tissue of the living body changes, and the reactance and resistance change accordingly. However, the subcutaneous fat thickness measurement unit of the present invention provides a measured value when it is determined that all electrodes are in contact with respect to at least one of reactance, resistance, or a ratio of reactance and resistance. Set as reference value. Then, measurement is continuously performed after setting the reference value, and an index relating to body composition is obtained using the measured value when the variation from the reference value is within a predetermined appropriate value range. Therefore, the subcutaneous fat thickness is accurately measured while minimizing the tissue deformation caused by the pressing of the electrode.

  The body composition measurement unit determines that each electrode has contacted the human body when at least one of reactance, resistance, or a ratio of reactance and resistance is within a predetermined value. It is also possible to start measuring the indicator for

Moreover, body composition measurement unit, when it is determined that the state where the all the electrodes in contact, reactance, or resistance or is set as a reference value at least one of measured values of the ratio of the reactance and resistance The measurement continuously performed after setting the reference value and the determination whether the variation of the measurement value from the reference value is within a predetermined range are repeatedly performed a predetermined number of times, and the measurement value is determined by the predetermined value. When both are within the predetermined range within the number of times, an index relating to the body composition is obtained, and when the measured value exceeds the predetermined range even once within the predetermined number of times, the measurement and the determination are performed. It can also be repeated from the beginning for the predetermined number of times .

Body composition measurement unit determines that the electrodes are in contact with the human body, after starting the measurement of body composition indicators, reactance and resistance, as well, using the measurement values of the ratio of the reactance and resistance the An index related to body composition can also be obtained.

  The body composition measurement unit can also set one of the measured values of the reactance, the resistance, or the ratio of the reactance and the resistance as the reference value.

  The body composition measurement unit may set the average value of at least one of the reactance, the resistance, or the ratio between the reactance and the resistance as the reference value.

  The body composition measurement unit can also obtain an index relating to the body composition by using the measured value when the amount of variation from the reference value is within a predetermined appropriate value range.

  The body composition measurement unit can also obtain an index relating to the body composition using the measured value when the rate of change from the reference value is within a predetermined appropriate value range.

  The body composition measurement unit may obtain a subcutaneous fat thickness between the first current application electrode and the second current application electrode as an index relating to the body composition.

It is a figure which shows the external appearance of the subcutaneous fat thickness measuring apparatus which concerns on embodiment of this invention. It is a block diagram which shows the detailed structure of the subcutaneous fat thickness measuring apparatus which concerns on the same embodiment. It is a flowchart which shows operation | movement of the subcutaneous fat thickness measuring apparatus which concerns on the same embodiment. It is the schematic of the structure | tissue of a human body. It is a figure which shows the equivalent circuit of the structure | tissue of a human body. It is a schematic diagram which shows a mode when an alternating current flows through a human body. It is a figure which shows the equivalent circuit of a muscle layer and a fat layer. It is a figure which shows the fluctuation | variation of the change rate of subcutaneous fat thickness at the time of changing the pressing pressure of an ultrasonic device and a measurement electrode. It is a figure which shows the fluctuation | variation of the change rate of subcutaneous fat thickness at the time of changing the pressing pressure of an ultrasonic device and a measurement electrode. It is a flowchart which shows the subcutaneous fat thickness measuring method of this embodiment. It is a figure which shows the state from which a part of measurement electrode has left | separated from the biological soft tissue of the measuring object. It is a figure which shows the state which all the measurement electrodes are contacting the biological soft-tissue of measurement object. It is a flowchart which shows the subcutaneous fat thickness measuring method which concerns on the modification 1 of this invention. It is a flowchart which shows the subcutaneous fat thickness measuring method which concerns on the modification 4 of this invention.

<A: Configuration>
FIG. 1 is a diagram illustrating an appearance of a subcutaneous fat thickness measuring apparatus 100 according to the present embodiment. The subcutaneous fat thickness measuring apparatus 100 according to the present embodiment has not only a function of measuring the subcutaneous fat thickness of the measurement subject, but also information relating to obesity such as the measured subject's weight, body fat percentage, and body fat mass by a known method. It also has a function to measure. As shown in FIG. 1, the subcutaneous fat thickness measuring apparatus 100 includes a gripping unit 10 and a mounting unit 20. The gripping unit 10 is connected to the mounting unit 20 via a cable 200, and a first measurement electrode 12 (12a, 12b) for measuring the subcutaneous fat thickness by contacting the human body on the surface of the tip unit. , 12c, 12d) are arranged.

  The first measurement electrode 12 includes a first current application electrode 12a, a second current application electrode 12b, a first voltage measurement electrode 12c, and a second voltage measurement electrode 12d. The first current application electrode 12a and the second current application electrode 12b are disposed so as to be sandwiched between the first voltage measurement electrode 12c and the second voltage measurement electrode 12d. The first voltage measuring electrode 12c is disposed adjacent to the first current applying electrode 12a, and the second voltage measuring electrode 12d is adjacent to the second current applying electrode 12b. Be placed. More specifically, the first measurement electrodes 12 (12a, 12b, 12c, 12d) are arranged along the Y direction on the front end surface of the gripping unit 10, and the first voltage measurement electrode 12c is the first voltage measurement electrode 12c. The second voltage measurement electrode 12d is adjacent to the positive side in the Y direction when viewed from the second current application electrode 12b. Are arranged as follows.

  The distance L in the Y direction between the first current application electrode 12a and the second current application electrode 12b is equal to the width W in the Y direction of the first voltage measurement electrode 12c and the second voltage measurement electrode 12c. The value is set to be smaller than the sum of the width W of the electrode 12d in the Y direction. In this embodiment, the dimensions of the measurement electrodes are set to the same value, and the width W in the Y direction of the first voltage measurement electrode 12c and the width W in the Y direction of the second voltage measurement electrode 12d Are the same value (ie L <2W). In the present embodiment, the distances in the Y direction between the measurement electrodes are set to be equal, and the value is equal to the value of the width W in the Y direction of one measurement electrode (that is, L = W). . Here, the value of the width W in the Y direction in one measurement electrode is set to 5 mm.

  The mounting unit 20 includes a display unit 22, an input unit (26a, 26b, 26c, 26d), and a second measurement electrode 23 (23a, 23b, 23c, 23d) on the appearance. The second measurement electrode 23 is an electrode for measuring the body fat percentage of the measurement subject by contacting the measurement subject's foot. The second measurement electrode 23 includes a third current application electrode 23a, a fourth current application electrode 23b, a third voltage measurement electrode 23c, and a fourth voltage measurement electrode 23d. The third current application electrode 23a and the fourth current application electrode 23b are arranged at positions separated from each other in the X direction. More specifically, the third current application electrode 23a is arranged corresponding to the position on which the left foot of the person to be measured is placed, and the fourth current application electrode 23b is in a position on which the right foot of the person to be measured is placed. Correspondingly arranged. The third voltage measuring electrode 23c is arranged adjacent to the positive side in the Y direction when viewed from the third current applying electrode 23a, and is arranged corresponding to the position where the left foot of the measurement subject is placed. Is done. The fourth voltage measurement electrode 23d is arranged so as to be adjacent to the positive side in the Y direction when viewed from the fourth current application electrode 23b, and is arranged corresponding to the position where the right foot of the measurement subject is placed. .

  The input unit (26a, 26b, 26c, 26d) includes a setting key 26a, an up key 26b, a down key 26c, and a start key 26d. Here, the up key 26b and the down key 26c select information and switch numerical values, and the setting key 26a sets the selected information and switched numerical values. The start key 26d is a means for starting power supply to the mounting unit 20 for a series of measurements. The detailed configuration of the mounting unit 20 will be described later.

  FIG. 2 is a block diagram showing a detailed configuration of the subcutaneous fat thickness measuring apparatus 100 according to the present embodiment. As shown in FIG. 2, in addition to the display unit 22, the second measurement electrode 23, and the input unit 26, the mounting unit 20 includes a first current generation unit 28, a first voltage measurement unit 30, and a second current. The generator 32, the second voltage measurement unit 34, the weight measurement unit 36, the power supply unit 38, the memory 42, and the control unit 44 are provided.

  The first current generator 28 is a means for outputting an alternating current flowing between the first current application electrode 12 a and the second current application electrode 12 b in the gripping unit 10. In the present embodiment, the frequency of the alternating current output from the first current generator 28 is set to 50 kHz (the same applies to the alternating current output from the second current generator 32 described later). The first voltage measuring unit 30 is means for measuring a voltage between the first voltage measuring electrode 12c and the second voltage measuring electrode 12d. The second current generator 32 is a means for outputting an alternating current flowing between the third current application electrode 23a and the fourth current application electrode 23b. The second voltage measuring unit 34 is a means for measuring the voltage between the third voltage measuring electrode 23c and the fourth voltage measuring electrode 23d. The weight measuring unit 36 is a means for measuring the weight of the person on the mounting unit 20 and outputting weight data. The power supply unit 38 is means for supplying power to each part of the electrical system of the mounting unit 20. The memory 42 includes various calculation formulas for calculating the body fat percentage, body fat mass, subcutaneous fat thickness, visceral fat area, visceral fat mass, subcutaneous fat area, subcutaneous fat mass and the like of the measurement subject. It is means for storing inputted body specific information (gender, height, age, etc.), result information, and the like. The buzzer 43 is means for notifying completion of measurement preparation or occurrence of an error state when measuring subcutaneous fat thickness. The control unit 44 is means for executing various control processes.

<B: Operation of subcutaneous fat thickness measuring device>
Next, the operation of the subcutaneous fat thickness measuring apparatus 100 will be described. In the present embodiment, the measurement subject holds the grip unit 10 and rides on the second measurement electrode 23 of the mounting unit 20 with bare feet, and then places the grip unit on the part of his body where the subcutaneous fat thickness is to be measured. Press 10 tips. Various measurement results (such as subcutaneous fat thickness) are displayed on the display unit 22. The specific contents will be described below with reference to FIG. FIG. 3 is a flowchart showing a specific operation of the subcutaneous fat thickness measuring apparatus 100 according to the present embodiment.

  First, when the start key 26d is turned on by the person to be measured (step S1), power supply from the power supply unit 38 is started, and the subcutaneous fat thickness measuring apparatus 100 enters the measurement mode. When the setting key 26a is turned on in a state where the start key 26d is not turned on (when the power is off), the setting mode is set, and setting of the body identification information is possible. At this time, a cursor appears at any position of gender, height, and age displayed on the display unit 22, and the measurement subject operates these buttons by operating the up key 26b, the down key 26c, and the setting key 26a. Information and numerical values can be switched and set. The body specifying information set in this way is stored in the memory 42. If the body identification information has not been set in the past, new registration is performed. If the body identification information has been set in the past, update registration is performed.

  Next, when the person to be measured gets on the mounting unit 20, the control unit 44 measures the weight of the person to be measured (step S2).

  More specifically, it is as follows. When the person to be measured gets on the mounting unit 20, the weight measuring unit 36 outputs weight data corresponding to the weight of the person to be measured. The control unit 44 obtains the body weight of the person to be measured from the weight data output from the weight measurement unit 36 and stores the value in the memory 42.

  Subsequently, the control unit 44 measures the body fat percentage and the body fat amount of the measurement subject (step S3). More specifically, it is as follows. Now, the back of the subject's left foot is in contact with the third current application electrode 23a and the third voltage measurement electrode 23c. The back of the right foot is in contact with the fourth current application electrode 23b and the fourth voltage measurement electrode 23d. As a result, a current path is formed from one of the third current application electrode 23a and the fourth current application electrode 23b to the other electrode via the measurement subject. The alternating current output from the second current generator 32 flows through the current path. At this time, the control unit 44 obtains the impedance between the legs of the measurement subject from the value of the current flowing through the current path and the value of the voltage measured by the second voltage measurement unit 34, and stores the result in the memory 42. save.

And the control part 44 calculates | requires a body fat rate by substituting the to-be-measured person's weight, the impedance between both legs, sex, height, and age in the calculation formula of the body fat rate preserve | saved in the memory 42. The calculation formula of the body fat percentage is expressed by the following formula (1).
fp = α × Zle50 + β × weight + γ × height + δ × age + ε × sex + ζ (1)
In the above formula (1), fp is a body fat percentage, Zle50 is an impedance between both legs, and α to ζ are constants.

Further, the control unit 44 substitutes the body fat percentage fp obtained from the above formula (1) and the body weight of the person to be measured into the calculation formula for the body fat amount stored in the memory 42, thereby obtaining the body fat mass. Ask for. The calculation formula for the body fat mass is expressed by the following formula (2).
fa = fp × weight (2)
In the above formula (2), fa is the body fat mass.
As described above, the control unit 44 obtains the body weight of the person to be measured based on the weight data output from the weight measurement unit 36. Further, the control unit 44 calculates the body fat based on the body weight thus obtained and the impedance measured using the second measurement electrode 23, the second current generation unit 32, and the second voltage measurement unit 34. Find rate fp and body fat mass fa. In other words, the control unit 44, the weight measurement unit 36, the second measurement electrode 23, the second current generation unit 32, and the second voltage measurement unit 34 provide information related to the subject's obesity (for example, body weight, body fat percentage fp, and body fat. It functions as an obesity information measuring unit that measures the amount fa).

  Next, when the measurement subject presses the distal end portion of the grasping unit 10 against a portion of his / her body where the subcutaneous fat thickness is to be measured, the control unit 44 causes the first measurement electrode in the measurement subject's body. Subcutaneous fat thickness is measured at the site where 12 (12a, 12b, 12c, 12d) contacts (step S4). More specifically, when the first measurement electrode 12 (12a, 12b, 12c, 12d) comes into contact with the measurement subject, one of the first current application electrode 12a and the second current application electrode 12b is selected. A current path is formed from one electrode to the other electrode via the measurement subject. The alternating current output from the first current generator 28 flows through the current path. Based on the phase difference between the current flowing through the current path and the voltage measured by the first voltage measurement unit 30, the control unit 44 uses the first current application electrode 12a and the second current application electrode 12b. Subcutaneous fat thickness between is determined.

  Here, the difference between the phase difference that occurs when the alternating current output from the first current generator 28 flows through the muscle layer of the measurement subject and the phase difference that occurs when it flows through the fat layer will be described in detail. As shown in FIG. 4, a human tissue (muscle tissue and adipose tissue) has a plurality of cell membranes 52 each containing an intracellular fluid 50 and an extracellular fluid 54 interposed between the cell membranes 52. When the capacitive component of the cell membrane 52 is Cm, the resistance component of the intracellular fluid 50 is Ri, and the resistance component of the extracellular fluid 54 is Re, the muscle tissue and the adipose tissue can be represented by the equivalent circuit shown in FIG.

  In the adipose tissue, since the intracellular fluid 50 is hardly contained in the cell membrane 52, the value of the resistance Ri of the intracellular fluid 50 is much larger than the value of the resistance Re of the extracellular fluid 54. (Re << Ri). For this reason, when the alternating current output from the first current generation unit 28 flows through the adipose tissue, most of the current flows through the resistance component Re of the extracellular fluid. Therefore, the current and the first voltage measurement unit 30 There is almost no phase difference from the measured voltage. On the other hand, in the muscle tissue, since the intracellular fluid 50 is contained in the cell membrane 52, when the alternating current output from the first current generator 28 flows through the muscle tissue, the current is a resistance component of the extracellular fluid. Not only Re but also the capacitive component Cm of the cell membrane 52 and the resistance component Ri of the intracellular fluid 50 flow. Therefore, there is a phase difference between the alternating current output from the first current generator 28 and the voltage measured by the first voltage measurement unit 30.

  That is, the muscle layer has the property of easily causing a phase difference, while the fat layer has the property of hardly causing a phase difference. Therefore, as the subcutaneous fat thickness increases, the property of the fat layer becomes dominant and the phase difference is increased. On the other hand, the smaller the subcutaneous fat thickness, the more dominant the properties of the muscle layer and the greater the phase difference. In the present embodiment, this is used to measure the subcutaneous fat thickness.

  More specifically, it is as follows. The control unit 44 measures the current output from the first current generation unit 28 and the first voltage measurement unit 30 when the first measurement electrode 12 (12a, 12b, 12c, 12d) contacts the human body. In addition to obtaining the phase difference between the two, the impedance is calculated. Further, the control unit 44 obtains a resistance R that is a real part of the impedance and a reactance X that is an imaginary part of the impedance from the phase difference and the impedance, and then is a ratio R of the reactance X and the resistance R. Find / X. The smaller the phase difference, the smaller the ratio of reactance X to resistance R, while the larger the phase difference, the larger the ratio of reactance X to resistance R. And the control part 44 determines the subcutaneous fat thickness corresponding to the calculated | required value of R / X.

Here, the relationship between the above R / X and subcutaneous fat thickness will be described. FIG. 6 schematically shows a state in which the alternating current output from the first current generator 28 flows through the fat layer and muscle layer of the measurement subject when the first measurement electrode 12 contacts the measurement subject. FIG. The hatched portion shown in FIG. 6 indicates the current path of the alternating current. Further, Lf shown in FIG. 6 is the thickness of the fat layer (subcutaneous fat thickness). FIG. 7 is a diagram showing an equivalent circuit of the fat layer and the muscle layer at this time. Rf shown in FIG. 7 is a resistance component of the fat layer. As described above, in the fat layer, the capacity component can be almost ignored. Zm represents a portion corresponding to the muscle layer, Rj represents a resistance component of the extracellular fluid 54 in the muscle layer, Rk represents a resistance component of the intracellular fluid 50 in the muscle layer, and Cl represents a cell membrane 52 in the muscle layer. The capacity component of is shown. At this time, R / X, which is the ratio of reactance X and resistance R at the part of the body of the person to be measured that contacts the measurement electrode, is expressed by the following equation (3).
R / X = -ωClRk-{(ωClRk) ² +1} / (ωClRj)-{(ωClRk) ² +1} / (ωClRf) (3)
Further, since the resistance component Rf of the fat layer is inversely proportional to the subcutaneous fat thickness Lf, the relationship between them is expressed by the following equation (4).
Rf = k / Lf (4)
In the above formula (4), k is a constant.

From the above formulas (3) and (4), the subcutaneous fat thickness Lf is expressed by the following formula (5).
Lf = −ωClk / {(ωClRk) ² +1} × [(ωClRk) + {(ωClRk) ² +1} / (ωClRj) + R / X]
= -Ab × R / X (5)
In the above formula (5), a and b are constants. As understood from the above formula (5), the subcutaneous fat thickness Lf and R / X are in a proportional relationship. That is, the larger the subcutaneous fat thickness Lf, the more dominant the fat layer properties and the smaller the phase difference, so the ratio of reactance X to resistance R decreases (the value of R / X increases), and subcutaneous fat thickness It can be seen that the smaller the Lf, the more dominant the muscle layer properties and the greater the phase difference, so the ratio of reactance X to resistance R increases (R / X decreases).

  In the present embodiment, the above equation (5) is stored in the memory 42 in advance. And the control part 44 substitutes the value of R / X calculated | required previously to the calculation formula (above-mentioned Formula (5)) of the subcutaneous fat thickness preserve | saved in the memory 42, and is the subcutaneous fat thickness Lf. Determine the value.

  Next, the control unit 44 calculates an index related to the body composition of the measurement subject (step S5 in FIG. 3). In the present embodiment, the “index for body composition” corresponds to the visceral fat area, the visceral fat mass, the subcutaneous fat area, and the subcutaneous fat mass. The specific contents will be described below.

The control unit 44 obtains the visceral fat area by substituting each of the subcutaneous fat thickness Lf and the body fat mass fa of the measurement subject previously obtained for the calculation formula of the visceral fat area stored in the memory 42. . The calculation formula of the visceral fat area is expressed by the following formula (6).
Visceral fat area = −c + (d × fa) + (e × Lf) (6)
In the above formula (6), c to e are constants.

In addition, the control unit 44 converts the subcutaneous fat thickness Lf of the subject to be measured, the body fat mass fa, and the height of the subject to be saved in the memory 42 into a calculation formula for the built-in fat amount saved in the memory 42. By substituting, the amount of visceral fat is obtained. The calculation formula of the visceral fat mass is expressed by the following formula (7).
Visceral fat mass = f + (g x fa) + (h x height)-(i x Lf) (7)
In the above formula (7), f to i are constants.

Further, the control unit 44 obtains the subcutaneous fat area by substituting each of the subcutaneous fat thickness Lf and the body fat mass fa of the measurement subject into the calculation formula of the subcutaneous fat area stored in the memory 42. The calculation formula of the subcutaneous fat area is expressed by the following formula (8).
Subcutaneous fat area = j + (k x fa) + (l x Lf) (8)
In the above formula (7), j to l are constants.

Further, the control unit 44 obtains the subcutaneous fat mass by substituting the subcutaneous fat thickness Lf, the body fat mass fa, and the height of the measurement subject into the calculation formula of the subcutaneous fat mass stored in the memory 42. . The calculation formula of the subcutaneous fat mass is expressed by the following formula (9).
Subcutaneous fat mass = m + (n × fa) + (o × height) + (p × Lf) (9)
In the above formula (9), m to p are constants.

  When the process of step S5 in FIG. 3 is completed, the control unit 44 determines the various results obtained as described above (body fat percentage fp, body fat mass fa, subcutaneous fat thickness Lf, visceral fat area, visceral fat mass, subcutaneous The display unit 22 is controlled to display the fat area and the subcutaneous fat mass (step S6 in FIG. 3). Thereby, a series of operation | movement is complete | finished.

<C: Subcutaneous fat thickness measurement method in stable contact state of electrode>
In the subcutaneous fat measurement method described above, since the first measurement electrode 12 of the grasping unit 10 is pressed from the surface of the measurement site, the shape of the living soft tissue changes due to the pressing pressure, and the impedance also changes.

FIG. 8 and FIG. 9 are graphs showing how the change rate of the subcutaneous fat thickness changes depending on the pressing force of the ultrasonic measurement device and the first measurement electrode 12 for different subjects. 8 and 9, the case where the pressing pressure is 0 g / cm ^{2 is} a case where the ultrasonic measurement device and the first measurement electrode 12 are slightly in contact with the measurement site.

As is apparent from FIGS. 8 and 9, it can be seen that the subcutaneous fat thickness changes as the pressing force changes in both the ultrasonic measurement device and the first measurement electrode 12. This is because the impedance changes as the shape of the living soft tissue changes due to the pressing pressure. Therefore, in order to accurately measure the subcutaneous fat thickness, it is necessary to perform measurement in a state where the pressing pressure of the first measurement electrode 12 is within a predetermined range, that is, in a state where the amount of change in impedance is within the predetermined range. There is.
In this embodiment, subcutaneous fat thickness is exemplified as an index related to body composition. However, the impedance changes due to the change in the shape of the soft tissue of the living body due to the pressing force. There's a problem.

  In this embodiment, the amount of change from the reference value of resistance R and the amount of change from the reference value of reactance X are within a predetermined range, and the rate of change of R / X, which is the ratio of reactance X and resistance R Was measured a plurality of times in a state where the value was within a predetermined range, and the subcutaneous fat thickness was calculated from the above equation (5) using the average value of reactance X and resistance R. Hereinafter, the subcutaneous fat thickness measurement method of this embodiment will be described with reference to FIGS. The subcutaneous fat thickness is an example of an index related to body composition.

  When measurement is started, the value of counter n is set to 0 (step S10). Then, resistance R is measured (step S11), and reactance X is measured (step S12). Next, it is determined whether the resistance R is less than 100Ω (step S13). Further, it is determined whether or not reactance X is less than 15Ω (step S14). Furthermore, it is determined whether the ratio of reactance X and resistance R is less than 30 (step S15).

  This is to eliminate such a case because accurate measurement cannot be performed when all of the first measurement electrodes 12 are not in contact with the biological soft tissue to be measured as shown in FIG. When the measurement circuit is in an open state as shown in FIG. 11, both resistance R and reactance X become infinite. Therefore, in such a case, the process is repeated from the process of setting the value of the counter n to 0 without performing the measurement.

  However, as shown in FIG. 12, when all of the first measurement electrodes 12 are in contact with the soft tissue of the living body to be measured, the resistance R is less than 100Ω, the reactance X is less than 15Ω, and the ratio of the reactance X and the resistance R is 30. Less than. In the present embodiment, when such a state is confirmed three times, it is determined that preparation for measurement of subcutaneous fat thickness is completed, so the value of counter n is incremented (step S16).

  When the value of the counter n is 3 and the contact state of the first measurement electrode 12 as shown in FIG. 12 is confirmed three times, the measured value of the resistance R for the third time is used as the reference value of the resistance R. (Step S18). Further, the measured value of reactance X for the third time is set as a reference value for reactance X (step S19). Further, the third measurement value of the ratio R / X between the reactance X and the resistance R is set as a reference value for the ratio between the reactance X and the resistance R (step S20). In this way, the buzzer 43 is sounded assuming that preparation for measurement of subcutaneous fat thickness is completed when each reference value is obtained (step S21).

  Next, 0 is set to the value of the counter i for detecting the occurrence of an error condition (step S22), and the value of the counter m for measuring the resistance R and the reactance X for calculating the subcutaneous fat thickness is set to 0. Is set (step S23).

  Then, the resistance R is measured (step S24), the reactance X is measured (step S25), and the value of the counter m is incremented (step S26). As described above, even if the first measurement electrode 12 is in contact with the measurement site, accurate measurement cannot be performed if the pressing force changes greatly. Therefore, in the present embodiment, it is determined whether or not the change amount Rref-Rm of the resistance R from the reference value Rref is within the range of minus 2Ω to plus 2Ω (step S27). Further, it is determined whether or not the change amount Xref-Xm of the reactance X from the reference value Xref is in the range of minus 2Ω to plus 2Ω (step S28). Further, it is determined whether or not the ratio Rm / Xm between the reactance X and the resistance R is within the range of 0.8 to 1.2 times the reference value (step S29).

  In this embodiment, the amount of change from the reference value of resistance R is in the range of minus 2Ω to plus 2Ω, and the amount of change from the reference value of reactance X is in the range of minus 2Ω to plus 2Ω. Further, when the ratio R / X between the reactance X and the resistance R is in the range of 0.8 to 1.2 times the reference value, it is determined that the pressing force of the first measurement electrode 12 is an appropriate value. To do. Then, it is determined whether or not the value of the counter m has become 3 (step S30). That is, until each appropriate value is obtained three times, the above-described measurement of resistance R and reactance X and determination of the appropriate value are repeated.

  When the appropriate value is obtained three times, the average value of the measured values of resistance R and reactance X is calculated, and the subcutaneous fat thickness is calculated from the above equation (5) using these average values (step S31). ).

  However, in the above-described determination process of the appropriate value (steps S27 to S29), if it is determined that the value is not within the appropriate value range even once, the value of the counter i is incremented (step S32), and the value of the counter i is It is determined whether or not 10 has been reached (step S33). That is, there is a state in which the amount of change from the reference value of the resistance R, the amount of change from the reference value of the reactance X, and the rate of change of the ratio R / X of the reactance X and the resistance R to the reference value are not appropriate values. If it continues 10 times, it is determined that an error has occurred and a buzzer is sounded (step S34).

  As described above, according to the present embodiment, when measuring subcutaneous fat thickness, the amount of change from the reference value of resistance R, the amount of change from the reference value of reactance X, and the reactance X and resistance R Since the average value of the resistance R and the reactance X when the change rate with respect to the reference value of the ratio R / X is an appropriate value is used, the deformation of the soft tissue of the living body caused by pressing the first measurement electrode 12 is minimized. The subcutaneous fat thickness can be measured stably.

  In the present embodiment, the case where the resistance R is measured in both the subcutaneous fat measurement preparation process (step S10 to step S21) and the subcutaneous fat measurement process (step S22 to step S31) has been described. However, in the case of the measurement method of the present embodiment, since the values of resistance R and impedance Z are substantially equal, impedance Z may be used instead of resistance R.

  Further, although the case where the number of repetitions in the subcutaneous fat measurement preparation process (step S10 to step S21) is set to 3 has been described, the present invention is not limited to this and may be one or more times.

  Furthermore, although the case where the number of repetitions in the subcutaneous fat measurement process (step S22 to step S31) is set to three has been described, the present invention is not limited to this and may be one or more.

  Although the case where the number of repetitions in the detection of the error state is 10 has been described, the present invention is not limited to this and can be set to an appropriate number.

When calculating the subcutaneous fat thickness from the above equation (5), the case of using the average value of resistance R and reactance X will be described (step S31), but the present invention is not limited to this. Any one of the first to third measurement values may be used. Further, in the measurement preparation process of subcutaneous fat (step S10 to step S21), the measurement value for the third time is used as the reference value (step S18 to step S20), but the present invention is not limited to this. Any one of the first to third measurement values may be used as a reference value, or an average value of three times may be used as a reference value.

<D: Modification>
The present invention is not limited to the above-described embodiments, and for example, the following modifications are possible. Also, two or more of the modifications shown below can be combined.

(1) Modification 1
In the above-described embodiment, in the subcutaneous fat measurement process (steps S22 to S31), the amount of change from the reference value of resistance R, the amount of change from the reference value of reactance X, and the ratio of reactance X and resistance R It was judged whether the rate of change with respect to the reference value of R / X was an appropriate value.

  However, the present invention is not limited to such a case. As shown in FIG. 13, whether the rate of change Rref / Rm of the resistance R with respect to the reference value Rref is 0.8 or more and 1.2 or less ( Step S40), whether the rate of change Xref / Xm from the reference value Xref of the reactance X is 0.8 or more and 1.2 or less (Step S41), and the ratio Rm / Xm of the reactance X and the resistance R It may be determined whether the amount of change from the reference value Rate is minus 2 or more and within plus 2 (step S42).

(2) Modification 2
In the above-described embodiment, in the subcutaneous fat measurement preparation process, the resistance R is less than 100Ω (step S13), the reactance X is less than 15Ω (step S14), or the ratio R / X of the reactance X and the resistance R is 30. All the conditions of less than (step S15) were judged. However, the present invention is not limited to such a case, and may be determined based on any one condition, or may be determined as two conditions by appropriately combining three conditions.

(3) Modification 3
In the above-described embodiment, in the subcutaneous fat measurement process, whether or not the change amount Rref-Rm of the resistance R from the reference value Rref is in the range of minus 2Ω to plus 2Ω (step S27), and the reactance X Whether the amount of change Xref-Xm from the reference value Xref is within the range of minus 2Ω to plus 2Ω (step S28), and the ratio Rm / Xm of reactance X and resistance R is 0.8 times the reference value Judgment was made for all the conditions of whether or not it is within the range of 1.2 times (step S29). However, the present invention is not limited to such a case, and may be determined based on any one condition, or may be determined as two conditions by appropriately combining three conditions. Furthermore, Modification 2 and Modification 3 may be combined.

(4) Modification 4
In the above-described embodiment, the measurement preparation process of the subcutaneous fat (step S10 to step S10) is performed as the reference value Rref of the resistance R, the reference value Xref of the reactance X, and the reference value Rate of the ratio R / X of the reactance X and the resistance R. The measured value in S21) was used. However, the present invention is not limited to such a case. For example, as shown in FIG. 14, the first measured value of resistance R after the start of subcutaneous fat measurement processing is set as a reference value Rref (step S50), and the first measured value of reactance X is set as a reference value Xref (step S51). These reference values may be used as the reference value Rate of the ratio R / X between the reactance X and the resistance R (step S52).

(5) Modification 5
In the embodiment described above, the subcutaneous fat thickness was measured by contacting the human body on the tip surface of the gripping unit 10, but the present invention is not limited to this, and the bioelectrical impedance is measured using the gripping unit 10. A body composition meter that obtains an index related to body composition based on bioimpedance may be used. The index relating to the body composition includes not only the subcutaneous fat thickness but also the visceral fat area, visceral fat mass, subcutaneous fat area, subcutaneous fat mass, muscle mass, and body fat percentage described in the embodiment.

  In addition, you may make it use embodiment mentioned above and each modification in combination suitably.

DESCRIPTION OF SYMBOLS 10 ... Grasping unit, 12a ... 1st current application electrode, 12b ... 2nd current application electrode, 12c ... 1st voltage measurement electrode, 12d ... 2nd voltage measurement electrode, 20 …… Place unit, 22 …… Display section, 23a …… Third current applying electrode, 23b …… Fourth current applying electrode, 23c …… Third voltage measuring electrode, 23d …… First 4 voltage measuring electrodes, 26... Input section, 28... First current generating section, 30... First voltage measuring section, 32... Second current generating section, 34. …… Weight measuring unit, 38 …… Power supply unit, 42 …… Memory, 43 …… Memory, 44 …… Control unit, 100 …… Subcutaneous fat thickness measuring device.

Claims (3)

Each is a measurement electrode for making a measurement in contact with the human body, and is arranged between the first voltage measurement electrode and the second voltage measurement electrode, and the first and second voltage measurement electrodes. A first current application electrode and a second current application electrode,
A current generator that outputs an alternating current flowing between the first current application electrode and the second current application electrode;
A voltage measuring unit for measuring a voltage between the first voltage measuring electrode and the second voltage measuring electrode;
When the measurement electrode comes into contact with the human body, the current electrode flows from one of the first current application electrode and the second current application electrode through the human body to the other electrode. Body composition for obtaining an index relating to body composition between the first current application electrode and the second current application electrode based on a phase difference between a current and a voltage measured by the voltage measurement unit A measurement unit,
The body composition measuring unit is configured to reactance, resistance, or reactance calculated from an impedance calculated from a current flowing through the current path and a voltage measured by the voltage measuring unit, and the phase difference. For at least one of the ratios of the resistance and the resistance, set the measurement value when it is determined that all the electrodes are in contact as a reference value, and continuously measure after setting the reference value, When the variation of the measured value from the reference value is within a predetermined range, an index relating to the body composition is obtained.
A body composition meter characterized by that. When the body composition measuring unit determines that all the electrodes are in contact with each other, the reactance, the resistance, or the measured value of at least one of the reactance and the resistance is the reference value. The measurement is performed as a value, and the measurement is continuously performed after the reference value is set, and the determination whether the variation of the measurement value from the reference value is within a predetermined range is repeated a predetermined number of times, and the measurement is performed. When the values are all within the predetermined range within the predetermined number of times, an index relating to the body composition is obtained, and when the measured value exceeds the predetermined range even once within the predetermined number of times, the measurement and The determination is repeated from the beginning for the predetermined number of times.
The body composition meter according to claim 1 . The body composition measurement unit includes reactance, resistance, and reactance calculated from an impedance calculated from a current flowing through the current path and a voltage measured by the voltage measurement unit, and the phase difference. And determining an index relating to the body composition using a measured value of the ratio between the resistance and the resistance .
The body composition meter according to claim 1 or claim 2, wherein

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