KR100742697B1 - Biological active points measuring system and method thereof - Google Patents

Abstract

A system and a method for measuring acupoints are provided to improve the reliability of the system by simply finding out a place measuring the acupoints through an acupoint display unit. A system for measuring acupoints includes an acupoint measuring unit(100), an acupoint analyzing unit, and an acupoint displaying unit(120). The acupoint measuring unit(100) has a measuring electrode, a standard electrode, and a grounding electrode. The acupoint analyzing unit analyzes an acupoint measuring signal supplied from the acupoint measuring unit(100) to generate an acupoint position display control signal and includes an AC(alternating current) supply unit(110), an amplifying unit(112), an analog/digital converting unit(114), and a control unit(116). The acupoint displaying unit(120) inputs the acupoint position display control signal supplied through the acupoint analyzing unit to display on a screen.

Description

Acupoint measurement system and method {BIOLOGICAL ACTIVE POINTS MEASURING SYSTEM AND METHOD THEREOF}

1 is a block diagram showing the configuration of a menstrual blood measurement system according to an embodiment of the present invention.

2A and 2B are graphs showing a measurement circuit for measuring in the skin of the present invention and a measurement relationship through the skin.

Figure 3a is a graph showing the results of measuring the characteristic frequency and reactance when supplying acupuncture points (inner tube) and non-acupuncture points below 10 Hz.

Figure 3b is a graph showing the results of measuring the characteristic frequency and reactance when supplying acupuncture points (secretary) and non-acupuncture points below 10 Hz.

Figure 3c is a graph showing the results of measuring the characteristic frequency and reactance when supplying menstrual blood (foot samri) and non-acupuncture points less than 10 Hz.

4 is an electrical equivalent circuit diagram illustrating a skin electrical model of acupuncture points.

5 is a graph illustrating a Z-view simulation analysis result using the electric circuit model of the present invention.

6 is a table showing the resistance and capacitor values of acupuncture points and acupuncture points using the electric circuit model of the present invention.

Figure 7a is a graph showing the impedance results in the equivalent circuit calculation of the present invention.

7B is a graph showing the resistance result in the equivalent circuit calculation of the present invention.

7C is a graph showing the characteristic frequency of reactance when the R ₂ register is changed in the equivalent circuit calculation of the present invention.

Figure 7d is a graph showing the characteristic frequency of the reactance when varying the C ₂ capacitor in the equivalent circuit calculation of the present invention.

8 is a graph showing the characteristic frequency and reactance when the variable resistance is set to 20 Hz, 10 Hz, and 5 Hz in the circuit experiment of the present invention.

9A is a diagram illustrating a model in which a skin model of the human body is designed in three layers (epidermis, dermis, and subcutaneous tissue).

FIG. 9B is a graph illustrating results of analyzing impedance characteristics by supplying a current to a Maxwell 2-D simulation tool.

Figure 9c is a graph showing the results of analyzing the measurement value according to the location of the menstrual blood using the Maxwell 2-D simulation tool as an electrical characteristic.

9D is a graph illustrating results of measuring impedance characteristics of a human body according to a measurement distance using a Maxwell 2-D simulation tool.

10 is a view showing a result of comparing the measurement results of acupuncture points and non-acupuncture points.

The present invention relates to measurement of acupuncture points, and more particularly, to acupoint measurement system and method in which reactance and characteristic frequency analysis are performed in real time.

Typically, acupuncture points and meridians are one of the fundamental principles of oriental medicine, and they play a role in expressing and controlling the human state.

In oriental medicine, this meridians is understood as a circulatory passage that connects each part of the body's books and limbs. Inside the human body, the meridians belong to the books and spread all over the body surface. In particular, acupuncture points act as a passage through which the meridians communicate with the outside, and are recognized as a response point that indicates the condition of the book and a treatment point that controls the book by saliva or moxibustion.

Recently, with the recognition of the limit of western medicine and interest in oriental medicine, various researches are being conducted in the West to understand the reality of Meridian research, which remained only in the scope of oriental science.

The mainstream of this Western scientific approach is electrical analysis. Among them, many studies have been conducted on the characteristic difference of impedance which is a typical characteristic of acupuncture points. For example, in 1950, Nakatnani, Japan, who discovered the relationship between a transfer point and acupuncture points, founded the concept of Electro-Acupuncture according to Voll (EAV), an apparatus that diagnoses the functional state of each book by an electrophysiological approach. Yamamoto's relationship between acupuncture points and low-resistance points using a German poll and roll type dry electrode, and capacitor and resistance A variety of studies have been published, including Prokhorove, which makes the difference.

However, the above studies only have an understanding of the phenomena, but there is a problem that the objective and reproducible results of meridians or acupuncture points are not obtained yet.

It is an object of the present invention to provide a non-invasive and stable measurement of acupuncture points and non-acupuncture points and characteristic frequencies in real time and simultaneously provide an acupoint measurement system and method capable of reproducing and objectively interpreting meridians or acupuncture points. .

In order to achieve the above object, the present invention provides a closed circuit by i) supplying an alternating current, an alternating current supply unit for varying the frequency of the alternating current, ii) a current supplied in contact with the body of the acupoint measurement subject, Acupuncture point measuring unit for measuring the voltage and current generated at two points of acupuncture points and non-acupuncture points respectively to generate acupoint measurement signals. The value is converted into an impedance value, the characteristic frequency, which is the frequency of the AC current at which the reactance value and the reactance value is maximized, is analyzed by acupuncture points, and acupuncture points analyzing part generating acupuncture points indicating control signal. It includes a menstrual blood display unit for receiving the supplied menstrual blood position display control signal on the screen.

In addition, the present invention provides a method of connecting a measurement electrode (V +) and a current supply electrode (I +) to one electrode in common at a measurement point of menstrual blood, and respectively, a reference electrode (V−) and a ground electrode at a point separated from the measurement electrode. Attaching to form a closed circuit, ii) measuring the potential difference between the measurement electrode and the reference electrode by supplying a current having a constant magnitude regardless of the magnitude of the load impedance to the acupoint measurement point to detect the acupuncture point at the acupoint measurement point Iii) calculating the impedance between the measurement electrode and the reference electrode and analyzing the acupuncture points through characteristic frequencies and reactances of the acupuncture points and the non-acupuncture points; and v) displaying the analyzed acupuncture points.
Here, the characteristic frequency means the frequency of the input current at which the reactance resistance at the measurement point is maximum.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Although many details are set forth in order to provide a more thorough understanding of the invention, such as the description and the accompanying drawings, these specific details are illustrated for the purpose of illustrating the invention and are not meant to limit the invention thereto. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a block diagram showing the configuration of a menstrual blood measurement system according to an embodiment of the present invention, Figures 2a and 2b is a graph showing a measurement circuit for measuring in the skin of the present invention and the measurement relationship through the skin. 3A to 3C are graphs showing the results of measuring characteristic frequencies and reactances when supplying menstrual blood (inner tube, hepatic salivary gland) and non-acupuncture points 10 Pa or less, respectively.

The configuration of the menstrual blood measurement system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3C.

Embodiment of the present invention includes acupuncture points measuring unit 100, acupuncture points analysis unit, acupuncture points display unit 120.

The acupuncture point measuring unit 100 includes measurement electrodes 102 and V +, reference electrodes 104 and V−, and a ground electrode 106, and forms a closed circuit by a current supplied to and contacted with a body of the acupuncture points. In addition, the acupuncture points are generated by measuring the voltage value generated at the acupuncture points.

The measurement electrode 102 is divided into a measurement electrode 102a attached to the menstrual point and a measurement electrode 102b attached to the non- menstrual point, as shown in FIG. 2B, and silver / silver chloride attached to the menstrual point (Ag / Agcl). ) Electrode and metal electrode (Biopac electrode (EL258H), 8mm electrode). The current supply electrode I + for supplying a measurement current is commonly connected to the measurement electrode 102. Measurement electrode 102 for measuring acupuncture points is composed of a floating electrode (Floating Electrode) can reduce the relative movement of the electrode and the electrolyte has the advantage that the noise (Artifact) does not occur. The measuring electrode 102 functions to measure the voltage value generated at the menstrual blood point by forming a closed circuit by the supplied current when the measuring electrode 102 contacts the body of the menstrual blood measurement subject.

For example, as shown in FIG. 2B, when the measurement electrode 102 is connected to the arm of the menstrual blood measurement subject, the voltage value measured at the measurement electrode 102a located at the menstrual point is measured at the menstrual point 102b. ) Outputs the voltage value of) by converting the impedance value. Therefore, when the measuring electrode 102 is mounted, any one of the measuring electrodes 102 is positioned at the acupuncture point even though the acupuncture point is not known to the position of the acupuncture point, and the difference in voltage value according to the skin electrical resistance of the meridians flows. The impedance value of the menstrual point can be measured accurately.

The reference electrode 104 is circuit-connected at points spaced from the measurement electrode 102 at set intervals, and the ground electrode 106 is circuit-connected at points spaced from the reference electrode 104. The reference electrode 104 and the ground electrode 106 may be composed of an electrocardiogram (ECG: Electropac EL 503) electrode and a metal electrode.

The menstrual blood analyzer receives the menstrual blood measurement signal supplied from the menstrual blood measuring unit 100 to analyze and generate a menstrual blood position display control signal.

The menstrual blood analyzer includes an AC supply unit 110, an amplifier 112, an analog / digital converter 114, and a controller 116. The acupuncture point analyzer analyzes the acupuncture points by comparing the magnitudes of voltage and current values input from two points (acupuncture points, non-acupuncture points) through the acupuncture point measuring unit 100. In addition, the acupuncture points analyzing unit compares the reactance value according to the frequency of the input AC current, and calculates a characteristic frequency at which the reactance value is maximum.

The AC supply unit 110 supplies AC power to the menstrual blood measuring unit 100, supplies a frequency to the menstrual blood measuring site through a constant microcurrent, and may vary a frequency to be supplied. The AC supply unit 110 may include an AC current source (Kesley 6221).

The amplifier 112 amplifies the analog signal of the voltage value for the menstrual blood point measured by the menstrual blood measurement unit 100. That is, the amplification unit 112 amplifies the voltage and current values for the acupoints measured through the acupuncture points measuring unit 100 to a predetermined size. In this case, the measured voltage and current values may be stored and managed in a memory provided separately after being amplified. The amplifier 112 may be configured as an amplifier (amplifier system) for converting the impedance from the voltage and current value measured by the menstrual blood measurement unit 100. For example, it may be configured as a lock-in amplifier (RS830 Stanford Research System).

The analog / digital converter 114 converts the analog signal amplified by the amplifier 112 into a digital signal. That is, the analog / digital converter 114 converts the analog voltage and current values amplified by the amplifier 112 into digital voltage and current values.

The controller 116 is configured as a personal computer (PC) including a system for analyzing a digital output signal supplied from the analog / digital converter 114 and controlling various data flows such as measured voltage and current values of acupuncture points. It can be, and generates the acupoint position display control signal of the impedance value of the acupoints converted into digital form.

The control unit 116 may be configured as a system for automatically measuring the acupuncture points by controlling the AC supply unit 110 and the amplification unit 112. Here, the measuring system is mainly used as an interface between a computer and a measuring device in a laboratory, and is a powerful and flexible device operating in a personal computer (PC). The measurement system eliminates many of the grammatical points and creates a program using a flow diagram called a block diagram, called graphical programming, or simply G language. The controller 116 may be configured as a laboratory system (LabVIEW; Laboratory Virtual Instrument Engineering Workbench, PXI).

The menstrual blood display unit 120 receives a menstrual blood position display control signal supplied through the menstrual blood analyzer and displays it on the screen. Acupoint display unit 120 may be configured as a monitor constituting a personal computer (PC).

Acupoint measurement method according to an embodiment of the present invention using a menstrual blood measurement system of the above configuration will be described.

Acupoint measurement method according to an embodiment of the present invention includes the acupoint measurement preparation step, the closed circuit forming step, acupuncture point measurement step, acupuncture point location analysis step.

The acupoint measurement preparation step includes maintaining a resting state of the acupuncture points subject for a predetermined time (about 20 minutes) before measuring the acupuncture points, and washing the acupuncture points with a washing solution and drying for a predetermined time period. The method may further include maintaining a temperature of the menstrual blood measurement space at a set temperature. Here, the set temperature of the menstrual blood measurement space is maintained within 23 ° C to 25 ° C.

As described above, a closed circuit is formed in a state in which acupoint measurement preparation step is completed. In the closed circuit formation, the measurement electrode 102 and the current supply electrode I + are commonly connected to one electrode at the measurement point of the menstrual blood, and the reference electrode 104 and the ground electrode 106 are separated from the measurement electrode 102. Attach to each other to form a closed circuit.

As described above, when a closed circuit for measuring menstrual blood is formed, menstrual blood is measured. In the embodiment of the present invention, the menstrual blood of the penis rock on the arm of the human body and the limbs of the leg is measured relatively easily.

Acupuncture point measurement measures a potential difference between the measurement electrode 102 and the reference electrode 104 by supplying a current having a constant magnitude regardless of the magnitude of the load impedance to detect the acupuncture point at the acupuncture point. Acupuncture points are measured by dividing them into acupuncture points and non-acupuncture points. Here, the non-acupuncture points are points spaced apart by a distance set from the acupuncture points, and the points are spaced apart from the reference electrode 104 by a distance equal to the distance from the points. That is, the selection of the non-acupuncture points is a point away from the acupuncture points by fixing a common reference position at a constant position, and selects a point at which the distance from the reference electrode 104 is the same.

The measurement principle of acupuncture points of the present invention is to inject a constant current into a living body irrespective of the magnitude of the load impedance to the skin, measure the potential of the site to be measured, and obtain the impedance between the two measurement electrodes.

In this case, two electrodes for supplying voltage and current and two measurement electrodes for measuring voltage are required.

The four electrodes can be used to measure the impedance of the living body, and by adjusting the number of electrodes attached to the skin, various biological impedances can be measured by dividing into two-electrode, three-electrode, and four-electrode methods.

Typically, the skin impedance is measured to measure the skin impedance at a specific point. If two electrodes are used, the skin impedance at the two points to which the electrode is attached is measured. It cannot be measured.

Due to this problem, skin impedance is measured by connecting the measurement electrode 102 and the current supply electrode to one electrode at the measurement point and attaching the reference electrode 104 at a predetermined distance from the measurement point.

Using this method, skin impedance (acupuncture point) at one point can be measured more accurately than the two-electrode method.

When the acupuncture points of the acupuncture points are detected, the acupuncture points are interpreted.

Acupuncture points can be interpreted by calculating impedance between the measurement electrode 102 and the reference electrode 104 and analyzing characteristic frequencies and reactances of the acupuncture points and the non-acupuncture points. That is, the characteristics of the menstrual blood can be determined by observing the characteristic frequency and the reactance of the bioimpedance at the same time and comparing the difference with the surrounding skin.

By using the measurement method as described above, reproducible measurement of acupuncture points is possible, and the reliability according to the distance between the acupuncture points and the non-acupuncture points can be improved to obtain more reliability.

Therefore, when the measurement electrode 102 is placed on the menstrual blood, the potential difference with the reference electrode 104 can be measured more accurately, and an objective analysis of the menstrual blood body can be achieved by simultaneously observing characteristic frequencies and reactances of the menstrual blood and the non-acupuncture blood. Do.

With reference to the accompanying drawings will be described a method of measuring acupuncture points according to an embodiment of the present invention.

First, referring to Figures 2a and 2 ', it can be seen the configuration principle and acupuncture points measuring method of the acupuncture points measuring unit 100 for measuring acupuncture points of the present invention.

It is assumed that the potential of the part to be measured is measured after supplying a constant current to the skin of the human body regardless of the magnitude of the load impedance. In this case, the purpose is to measure the skin impedance of a specific point. If two electrodes are used, the skin impedance of the two points to which the electrode is attached is measured, and thus the skin impedance of the desired specific point cannot be measured.

Due to this problem, the measurement electrode 102 and the current supply electrode I + are connected to one electrode at the measurement point for measuring acupuncture points, and the reference electrode 104 is connected to the electrode at a predetermined distance from the measurement electrode 102 as shown in FIG. Attach and measure skin impedance. For example, referring to FIG. 2B, the impedance of the voltage value measured at the measurement electrode 102a located at the menstrual point is lower than the impedance of the voltage value of the measurement electrode 102b not located at the menstrual point. Therefore, when the measuring electrode 102 is mounted, any one of the measuring electrodes 102 is positioned at the acupuncture point even though the acupuncture point is not known to the acupuncture point, and the difference in current value according to the skin electrical resistance of the meridians flows. Can accurately measure the voltage value of acupuncture points.

This method can measure skin impedance at one point more accurately than the two-electrode method. For reference, the experiment of FIG. 2B is preferably conducted in a clinically normal adult, and it is preferable to repeat the experiment about 10 times in 30 adult males. In addition, it is desirable to use a system that can measure the electrical impedance in real time to accurately identify the location of acupuncture points and non-acupuncture points.In order to ensure the reproducibility and accuracy of the measurement, electrical circuit model experiments, Z-View simulation and Maxwell 2D FEM It is desirable to test the accuracy by experimenting with a system similar to the biological model through finite element method analysis.

Acupoint measurement method according to an embodiment of the present invention is a three-electrode system to measure the current supply electrode and the measurement electrode 102 together, the reference electrode 104 and the ground electrode 106 separately.

The measurement electrode 102 is measured with a silver / silver chloride (Ag / Agcl) electrode (or a metal electrode) as described above, and the reference electrode 104 and the ground electrode 106 are made of a disposable electrocardiogram (ECG) electrode ( Or metal electrodes). Electrocardiogram electrodes are used by attaching an adhesive tape to the skin and connecting impedance measuring instruments to these electrodes.

Acupoints measured in accordance with an embodiment of the present invention is determined by the inner tube, hepatic and foot sansori, and the acupuncture points and non-acupuncture points are measured with the non-acupuncture points as appropriate.

In order to ensure the accuracy of the measurement of menstrual blood, the test subject is allowed to rest for 20 minutes before the measurement, wipes the measurement area clean with alcohol, and dries for several minutes before starting the measurement.

The frequency range for measuring menstrual blood is 1-3 kHz and the input sine wave current is less than 10 kHz. The measurement frequency measures impedance for 90 different frequencies. In addition, when measuring menstrual blood, the total measurement time shall be within about 15 minutes.

The measurement method of FIG. 2B has the advantage of accurately finding the acupuncture points as a method of measuring the potential difference with the reference electrode 104 most accurately when the electrode V + is positioned directly above the acupuncture points with three electrodes.

Figure 3a is a result of measuring the inner tube (B) acupuncture points and non-acupuncture points when a current of 10 Hz or less is supplied to the test subject, and the characteristic frequency is 30 Hz or more and the reactance resistance is about 75 Hz.

Figure 3b is a graph showing the results of measuring the characteristic frequency and reactance when supplying menstrual blood (secretary) and non-acupuncture points below 10 Hz, Figure 3c is a characteristic frequency and reactance when supplying menstrual blood (foot sam) and non-acupuncture points below 10 Hz Is a graph showing the results of the measurement.

Referring to FIG. 3B, when the measured values of hepatic (B) acupuncture points and non-acupuncture points are compared, the characteristic frequency is 20 Hz, and the reactance resistance is 30 Hz.

Referring to Figure 3c, when comparing the measured values of the foot and foot acupuncture points and non-acupuncture points in the leg portion can be seen that the characteristic frequency difference is about 20Hz difference, the reactance resistance is 35㏀ difference.

FIG. 4 is a diagram illustrating an electric equivalent circuit for analyzing acupoint characteristics according to an embodiment of the present invention, and illustrates the change in resistance value in the presence of acupuncture points by configuring a variable resistor in a circuit.

In each circuit equation [Equation 1] is the equivalent circuit impedance value of the skin model, [Equation 2] and [Equation 3] represents the resistance and reactance.

In the equivalent circuit of R ₁ and R ₂ of Figure 4 is very large form than R _3, R ₃ is an important part of the real part of the skin impedance when the high frequency (High Frequency). In the present embodiment, when acupuncture points are present in R ₂ and C ₂ of the equivalent circuit, R ₂ is set as a variable resistor.

5 is a graph illustrating a Z-view simulation analysis result using the electric circuit model of the present invention.

Referring to FIG. 5, simulation results using a Z-view using an electric circuit model according to an exemplary embodiment of the present invention can be seen.

Referring to this test result, this circuit experiment analyzes how the characteristic frequency and reactance value change when the variable resistance part is changed. The characteristic frequency and reactance characteristic is similar to the actual measured value when each resistance is changed. Able to know.

6 shows the resistance and capacitor values for the skin model and the resistance and capacitor values when acupuncture points are present.

7A to 7C show calculation results of an equivalent circuit using the electric circuit of the present invention. FIG. 7A is a graph showing impedance results in the circuit calculation of the present invention, and FIG. 7B is a circuit calculation of the present invention. 7C is a graph showing the result of resistance, FIG. 7C is a graph showing characteristic frequency and reactance when the R ₂ resistance is variable in the circuit calculation of the present invention, and FIG. 7D is characteristic frequency and reactance when the C ₂ capacitor value is changed. It is a graph showing the characteristics of.

From this calculation, we can see the change of characteristic frequency and reactance in calculating each variable resistance.

Referring to the calculation result, as each resistance is less than 10KΩ, the characteristic frequency varies by about 50Hz, and the reactance is slightly reduced.

8 is a circuit experiment result using the electric circuit of the present invention, Figure 8 is a graph showing the characteristic frequency and reactance when the variable resistance is set to 20 Hz, 10 Hz, 5 Hz in the circuit experiment of the present invention In this experiment, it can be seen from the experiment whether the characteristic frequency and reactance change when each variable resistor is changed to 20㏀, 10㏀, 5㏀.

Referring to the experimental results, the lower the resistance, the characteristic frequency is different by about 10Hz, the reactance is slightly less.

Therefore, it can be seen that the impedance characteristic with respect to frequency is changed by using the skin skin model.

9A and 9B illustrate the design and current flow process using the Maxwell 2-D simulation apparatus, and FIG. 9A illustrates a model in which the human skin model is designed in three layers (epidermis, dermis, and subcutaneous tissue). 9B is a graph showing the results of analyzing the impedance characteristics by supplying a current to the Maxwell 2-D simulation tool. That is, FIG. 9A illustrates a skin model, in which skin layers are divided into three layers, and electrical conductivity of each skin layer is changed. In addition, referring to FIG. 9B, when the current is supplied to the skin of the three layers, the current density supplied to each layer may be known, and the impedance characteristic of each skin depth may be measured in detail.

9A and 9B, it can be seen that in the present invention, each tissue layer is assumed to be homogeneous, and each other tissue layer has a different conductivity. The change in conductivity of the measuring organization is predicted based on the organizational structure. When the conductivity of each tissue layer is evaluated, the depth of the tissue layer can be evaluated according to the position of the current supply electrode.

9C and 9D show measurement results using the Maxwell 2-D model as shown, and FIG. 9C shows the results of analyzing the measured values according to the location of menstrual blood using the Maxwell 2-D simulation tool as electrical characteristics. FIG. 9D is a graph illustrating results of measuring impedance characteristics of a human body according to a measurement distance using a Maxwell 2-D simulation tool.

Figure 9c is the result of measuring the impedance value of the portion of the acupuncture points in the skin model, (1) of Figure 9c shows that the measurement impedance is large because the current density is low when the acupuncture points are directly below the electrode.

9C shows the measurement result when the menstrual blood is present in front of the measuring electrode, and has a low impedance characteristic when the menstrual blood is present in front of the measuring electrode 102 because the current density of the edge portion of the electrode is high.

FIG. 9D shows the impedance characteristics of the Maxwell 2-D skin model according to the present invention, which are measured according to the impedance and the skin depth according to the distance of each measurement point. The longer the distance, the higher the impedance, and the deeper the low impedance characteristic. Has

10 is a comparison of the average reactance and characteristic frequency of the acupuncture points and the non-acupuncture points.

As described above, it can be seen that the difference between the characteristic frequencies in the electrical properties as a result of measurement of acupuncture points and non-acupuncture points remains between about 20 to 30 Hz. In addition, it can be seen that in the reactance characteristic, the menstrual blood exhibits a low resistance of 35 to 75 kPa compared with the non-acupuncture blood. In addition, it can be seen that the characteristic frequency of acupuncture points varies from one acupuncture point to another.

Therefore, when measuring acupuncture points using this Acupuncture Point Measuring System, acupuncture points can be accurately found with characteristic frequency and reactance value when supplying current of 10㎂ or less, and by measuring both reactance and characteristic frequency at the same time, It can reduce the time to find acupuncture points, so it has reliability and objectivity.

As described above, the acupoint measurement system and method according to the present invention can more easily distinguish acupuncture points from non-acupuncture points by simultaneously measuring reactance and characteristic frequency.

In addition, it is possible to shorten the menstrual blood measurement time and easily find a point to measure the menstrual blood to have the reliability of the menstrual blood measurement system.

In addition, accurate acupoints can be measured in real time, and there is an effect that can be interpreted more objectively acupuncture properties.

Claims (20)

An AC supply unit supplying an AC current and varying a frequency of the AC current; Acupuncture point measuring unit for contacting the body of the acupuncture points to form a closed circuit by the supplied alternating current, and measuring the voltage and current values generated at the two points of the acupuncture points and the non-acupuncture points to generate acupuncture measurement signal; Receives the acupuncture point measurement signal supplied from the acupuncture point measuring unit to convert the magnitude of the voltage and current values input from the acupuncture points and the non-acupuncture points, respectively, into impedance values; Acupuncture point analysis unit for analyzing the acupuncture points by calculating the frequency, generating acupuncture points display control signal; Acupuncture points measuring system including acupuncture points display unit for receiving the acupuncture points display control signal supplied through the acupuncture points analyzer to display on the screen. The method of claim 1, The acupuncture point measuring unit A measurement electrode V + attached to the acupoint measurement point; A reference electrode (V−) connected to the circuit at points spaced from the measuring electrode at a predetermined interval; A ground electrode connected to a circuit spaced apart from the reference electrode; The acupoint measurement system in which the current supply electrode (I +) for supplying an alternating current is commonly connected to the measurement electrode. The method of claim 2, The measurement electrode is a menstrual blood measurement system consisting of a metal electrode. delete delete delete delete The method of claim 1, The menstrual blood analysis unit An amplifying unit for amplifying an analog signal of a current value for the acupoints measured by the acupuncture points; An analog / digital converter converting the analog signal amplified by the amplifier into a digital signal; Analyze the digital output signal supplied from the analog / digital converter, control the flow of data such as the measured current value of acupuncture points, and compare the current value of the acupuncture points converted to digital form with a pre-stored set value to locate the acupuncture points. Acupoint measurement system including a control unit for generating a menstrual blood position display control signal corresponding to. The method of claim 8, The AC supply unit is an acupuncture point measuring system consisting of an AC constant current source for flowing a current of a constant magnitude. The method of claim 8, The amplification unit is an acupuncture point measuring system consisting of an amplifier for converting the impedance from the voltage and current value measured by the acupuncture point measuring unit. The method of claim 10, The control unit includes a system for measuring the acupuncture points by controlling the AC supply unit and the amplification unit. At the point of measurement of acupuncture points, a measurement circuit (V +) and a current supply electrode (I +) are commonly connected to one electrode, and a reference electrode (V−) and a ground electrode are attached to a point separated from the measurement electrode to form a closed circuit. step; Acupuncture point measuring step of detecting acupuncture points at the point of measurement of acupuncture points by measuring a potential difference between the measuring electrode and the reference electrode by supplying a current of a constant magnitude regardless of the magnitude of the load impedance to the point of measurement of acupuncture points; Calculating an impedance between the measurement electrode and the reference electrode and analyzing the acupoint characteristics and positions through characteristic frequencies and reactances of the acupuncture points and the non-acupuncture points; Acupoint measurement method comprising the step of indicating the analyzed acupuncture points. The method of claim 12, Acupoint measurement method further comprising the step of preparing acupoints before the step of forming a closed circuit. The acupoint measurement preparation step Maintaining a rest state of the acupoint measurement subject for a predetermined time before the acupoint measurement; Washing the menstrual blood measurement site with a cleaning solution and drying for a set time; Maintaining the temperature of the menstrual blood measurement space at the set temperature. The method of claim 12, The menstrual blood measurement step is acupuncture point measuring method for measuring each by dividing the acupoints and non-acupuncture points. The method of claim 14, Acupuncture point measuring method for measuring the acupuncture points and the non-acupuncture points by moving the measurement electrode. The method of claim 15, Acupuncture point measuring method for measuring the points of the acupuncture points and the non-acupuncture points by dividing the characteristic frequency and reactance values, respectively, and setting the acupuncture points as the difference between the points of the acupuncture points and the non-acupuncture points. The method of claim 16, When the acupoints and the non-acupuncture points are set to the difference value of the characteristic frequency, the acupuncture points are set to a point having a frequency value larger than the non-acupuncture points. The method of claim 16, When the acupoints and the non-acupuncture points are set to the difference value of the reactance, the acupuncture points are set to a point having a smaller resistance value than the non-acupuncture points. The method of claim 1, Said alternating current is a microcurrent in the 1-3KHz frequency range. 20. The system of claim 19, wherein the alternating current is a microcurrent of 10 mA or less.

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