KR101471598B1 - Pressure measurement method and pressure measurement apparatus - Google Patents

Abstract

A pressure measuring method according to the present invention includes: measuring first impedance; measuring second impedance by letting an external device approach an internal device; obtaining reflection impedance by subtracting the first impedance from the second impedance; obtaining at least one among capacitance and inductance of the internal device from a factor excluded from influence of mutual inductance; and finding out body pressure with a value obtained as the at least one among the capacitance and the inductance of the internal device. According to the present invention, the pressure measuring apparatus increases the accuracy of measured pressure, measuring the pressure regardless of time and place using the simplified pressure measuring method, thereby being used more widely. In addition, a patient who had a stenting procedure due to a cardiovascular problem can be free from fear of closing of blood vessels caused by failures of a stent.

Description

[0001] PRESSURE MEASUREMENT METHOD AND PRESSURE MEASUREMENT APPARATUS [0002]

The present invention relates to a pressure measuring method and a pressure measuring apparatus. Specifically, it is a device for measuring pressure in various places in the living body. More particularly, the present invention relates to a pressure measurement method and a pressure measurement device capable of measuring pressure changes of various liquids in a living body.

A basic form of a device for measuring a pressure in a living body includes an internal device capable of measuring a pressure inserted into a living body, an external device connected to the internal device through a predetermined electrical coupling, . The action approximates the external device to the internal device and senses a physical change in the internal device as the biological pressure changes. The external device then converts the physical change amount into a pressure change amount.

A typical application example of the pressure measuring device is a radio wave flow sensor structure for a living body and a flow sensor manufacturing method. According to the patent, the pressure measuring device is installed in the cardiovascular direction in the longitudinal direction, and then the pressure on the upstream side and the downstream side of the pressure measuring device are measured, and the blood flow amount is determined using the pressure difference.

As a method for measuring the pressure of the pressure measuring device, there is a contact type capacitance pressure sensor. In this pressure measuring device, the capacitance is changed according to the pressure change of the living body, and the change amount of the capacitance is measured to detect the pressure change of the living body.

However, when the external device approaches the internal device and measures the capacitance, the capacitance varies depending on the distance between the internal device and the external device. Accordingly, there is a problem that the pressure inside the living body to be measured varies from measurement to measurement. In more detail, the internal device and the external device are electromagnetically connected to each other by an inductance. The mutual inductance between the pair of inductors is changed according to the distance of the inductor, thereby causing a problem in the accurate measurement of the internal pressure of the living body do. These problems can cause serious problems in patients who require accurate measurement of the biomedical pressure.

In order to solve the above-described problems, it is inconvenient to make the capacitor of the internal device larger, or to perform measurement after placing the external device at a distance that is accurately given according to the user's manual of the product. Even if such a solution is taken, it is a reality that accurate measurement of the living body pressure is difficult because the human body and the blood vessel basically have a certain degree of movement and positional change.

1. Identification Nos. 16 and 17 of the radio-frequency flow sensor structure for a living body and the flow sensor manufacturing method and Fig. 1 2. Specialization of contact-type capacitive pressure sensors

SUMMARY OF THE INVENTION The present invention has been proposed in view of the above circumstances and proposes a pressure measuring device and a pressure measuring method capable of solving the problems proposed in the prior art and further increasing the accuracy of the measured biometric pressure value. In addition, a pressure measuring device and a pressure measuring method applicable to a case where a precise pressure measurement is required at any time, such as a patient with a vascular disease, is proposed. Also, a pressure measuring device and a pressure measuring method which are simple and convenient to use by the user without excessive restriction requirements on the measuring distance are proposed.

A pressure measuring method according to the present invention comprises: measuring a first impedance; Measuring the second impedance by accessing the external device to the internal device; Subtracting the first impedance from the second impedance to obtain a reflection impedance; Obtaining at least one of a capacitance or an inductance of the internal device from a factor excluding an influence of mutual inductance; And finding a living body pressure as a value obtained as at least one of a capacitance and an inductance of the internal device. According to this, an accurate pressure can be obtained irrespective of the distance between the internal device and the external device.

Here, the factor can be given as a ratio of the real value to the imaginary value of the reflection impedance, and at least one of the capacitance or the inductance of the internal device can be given as a capacitance. This is one preferable example, and can eliminate the influence of mutual inductance.

Further, at least one of the capacitance or the inductance of the internal device from the factor can be obtained by using at least one of the methods of obtaining a constant frequency and obtaining the factor constant. The first impedance may be a value measured at a position sufficiently distant from the internal device.

In the present invention, a pressure measuring apparatus using the above-mentioned pressure measuring method is claimed as the right. According to this, a person having a blood vessel disease such as a heart disease can confirm the current blood flow state anytime and anywhere without restriction of time, and the patient can be released from anxiety.

According to the present invention, it is possible to expect the advantages of improving the accuracy of measurement of the internal pressure of the living body, assuring an accurate measurement value regardless of place and time, and being easily usable without limitation on the measurement method.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining a configuration of a pressure measuring apparatus according to an embodiment. Fig.
2 is a flowchart of a pressure measurement method according to an embodiment.
3 is a diagram illustrating a method of obtaining a capacitance value in a state where the X factor is used and the frequency is constant.
4 is a diagram illustrating a method of obtaining a capacitance value with a frequency being used and a factor X being constant.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The spirit of the present invention is not limited to the following specific embodiments, and other embodiments can be easily created by adding, changing, deleting, and adding elements, Should be interpreted. For example, the spirit of the present invention can be interpreted based on the claims.

1 is a view for explaining a configuration of a pressure measuring apparatus according to an embodiment.

Referring to Fig. 1, a pressure measuring apparatus is provided with an internal apparatus 2 inserted into a living body and an external apparatus 1 interlocked with the internal apparatus 2. Fig.

An inductor Li is provided in the internal device 2, and an inductor Le is provided in the external device. When a current flows through the inductor Le in a state of approaching each other, a current flows to the inductor Li by mutual induction action. Therefore, energy supplied from the external device 1 may be used for the internal device 2 even if there is no separate power source.

The internal device (2) is provided with a capacitor (Cm) capable of measuring a pressure at a certain point in the living body, an inductor (Li), and a resistor (Ri). The capacitor Cm, the inductor Li and the resistor Ri constitute a circuit. The external device 1 has a configuration capable of being hand-held by a user, and includes a power supply Vs, a resistor Rs, and an inductor Le. The power source Vs, the resistor Rs and the inductor Le constitute a circuit. The inductor Li and the inductor Le approach each other and mutual inductive effect occurs when power is applied to the power supply Vs, that is, when the external device approaches the internal device for measurement.

The external device 1 presents only major components as hardware, and a display, a control CPU, an input / output device, a memory, and the like may be included in the same manner as other existing components. The capacitance of the capacitor Cm varies depending on the biomedical pressure by using the fact that the gap between the both electrodes of the capacitor is changed according to the pressure inside the living body and the capacitance is changed. The specific structure can be applied to the technique disclosed in Patent Document 2, and the use of other specific structures is not excluded. The configuration of the pressure measuring device not specifically provided may refer to various conventional products.

The embodiment is characterized in that the following pressure measuring method is used. The pressure measuring method according to the embodiment will be described. The pressure measuring method is a result of a long effort of the inventor contemplating a method of eliminating a measurement error that may occur in accordance with the difference between the distances between the external device 1 and the internal device 2 at the time of measuring pressure, It should not be judged only by seeing.

2 is a flowchart of a pressure measurement method according to an embodiment.

Referring to FIG. 2, first, power is applied to the external device ₁ to measure a free impedance Z _{in, 1 in} a free space free from any external interference (S1). At this time, the free impedance can be represented as Z _{in, and 1} can be expressed as jωLe. And, the environment as the free space can be assumed to be a position which is close to the place where the user is located and is sufficiently away from the internal device 2 so as not to be influenced by the internal device 2. [

Next, the external device 1 is approached to the internal device 2, and power is again applied to measure the impedance in the vicinity of the internal device 2 (S2). The impedance at this time can be expressed as Equation 1 as the sum of the free impedance and the reflection impedance.

Here, jωLe is a free impedance and Zr is a reflection impedance.

The reflection impedance caused by the internal device 2 is obtained (S3). The reflection impedance is expressed by the following equation (2) as the difference between the impedance measurement value in the free space and the impedance measurement value when the internal device and the external device are close to each other.

In Equation (2), M is a mutual inductance due to mutual inductive action, and is represented by Equation (3) below.

Where K is a coupling constant that is greater than or equal to 0 and less than or equal to 1 and varies with distance.

The present inventor has found that the mutual inductance is a major cause of a change in the capacitance measured according to the difference in distance between the external device and the internal device. Thus, the inventor confirmed that it is possible to present the X factor while canceling the mutual inductance M that varies with the distance. The X factor can be expressed by the following equation (4) as the ratio of the real number to the imaginary number of the reflection impedance.

Referring to Equation (4), it can be confirmed that mutual inductance M is in an erased state. Then, if it is rewritten around the capacitance value, it can be expressed as Equation (5).

Referring to Equations (4) and (4), a capacitance value can be obtained based on the value of the X factor that can be measured (S4).

Thereafter, the biomedical pressure can be measured in accordance with the change of the capacitance value of the capacitor provided in the internal device (2). At this time, the measured value of the living body pressure according to the measured value of the capacitor Cm may be stored in advance in the memory of the external device 1, may be tabulated according to a number of experiments, As shown in FIG.

Step S4 of obtaining the capacitance value will be described in more detail.

3 is a diagram illustrating a method of obtaining a capacitance value in a state where the X factor is used and the frequency is constant.

Referring to FIG. 3, the inductor Li is 600 nH and the resistor Ri is 1 ohm. When the frequency? Is set to 1 GHz, it can be known that the capacitance value is determined according to the value of the X factor. 3, the three curves shown by the downward-sloping curves show the change in the value of the X factor according to the change of the frequency when the impedance Li and the resistance Ri are constant and the capacitance value is constant. Therefore, when the frequency is 1 GHz, it can be seen that as the X factor increases, the capacitance value decreases. When the other conditions are constant, the relationship between the X factor and the capacitance value may be stored in advance in the memory as the experiential value, or may be stored in the memory as a strictly obtained function. It is clearly understood that the capacitance value can be obtained by obtaining the X factor in any case.

As a result, it is possible to obtain the capacitance value, and thereafter, it is possible to proceed to step S5 of finding the internal pressure of the living body.

4 is a diagram illustrating a method of obtaining a capacitance value in a state in which the frequency is used and the X factor is kept constant. In the following experiments and drawings, 0 is given as a constant value of X factor.

Referring to FIG. 4, the inductor Li is 600 nH, the resistor Ri is 1 ohm, and the format of the figure is the same as that of FIG. Describing the process of obtaining the capacitance value in more detail, the frequency ω at which the X factor becomes zero can be obtained. For example, after applying an arbitrary frequency, a current X factor value is obtained, and a method of tracing back the frequency? Can be performed. The frequency when the X factor value becomes 0 can be obtained and the capacitance value can be obtained from the table.

Meanwhile, the above embodiments propose a process of measuring a biomedical pressure value by measuring a change of a capacitance value by correlating a change value of a capacitance and a change value of a biomedical pressure. However, the present invention is not limited to such a case. For example, the in vivo pressure value can be measured even when the inductance changes according to the living body pressure or when the capacitance and the inductance change together.

For example, when a plate of the capacitor providing the capacitance in the embodiment is provided in the form of a spiral, the capacitance and the inductance may change together according to the biomedical pressure. Likewise. When winding around a blood vessel with an inductor, the shape of the inductor changes according to the biomedical pressure, and only the inductance can be changed. In either case, it is possible to measure the distance-independent value according to the X factor, and the change in the biomedical pressure according to the value of each passive element may be stored in advance in the memory in the form of experiential value or a strict function.

The idea of the present invention can further enlarge the spread of the pressure measuring device by improving the accuracy of the measuring pressure and simplifying the measuring method regardless of the place of time. In addition, patients who have already undergone stenting for cardiovascular disease may be completely free from the fear of clogging the stent.

1: External device
2: Internal device

Claims (6)

Measuring a first impedance;
Measuring the second impedance by accessing the external device to the internal device;
Subtracting the first impedance from the second impedance to obtain a reflection impedance;
Obtaining at least one of a capacitance or an inductance of the internal device from a factor excluding an influence of mutual inductance; And
And determining a living body pressure as a value obtained as at least one of capacitance and inductance of the internal device. The method according to claim 1,
Wherein said factor is given as a ratio of a real value to an imaginary value of said reflection impedance. The method according to claim 1,
Wherein at least one of the capacitance or inductance of the internal device is a capacitance. The method according to claim 1,
Determining at least one of a capacitance or an inductance of the internal device from the factor,
A method of measuring a pressure utilizing at least one of a method of obtaining a constant frequency and a method of constantly obtaining the factor. The method according to claim 1,
Wherein the first impedance is measured at a position away from the internal device. A pressure measuring device using the pressure measuring method according to any one of claims 1 to 5.

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