KR20080042303A - Apparatus for measuring blood sugar level and method of the same - Google Patents

Abstract

An apparatus and a method for measuring a blood sugar level are provided to improve accuracy by directly installing a dielectric resonator with a sensor tip in a source unit to reduce error factors. An apparatus for measuring a blood sugar level includes a source unit(100), a detecting unit(300), a central processing unit(400), and a display unit(500). The source unit generates a predetermined frequency and has a sensor unit(140) interacting with a subject(0). The detecting unit measures a waveform change of a wave generated from the source unit before and after interaction with the subject. The central processing unit controls the source unit to determine a central frequency and a bandwidth of the generated wave and outputs blood sugar level data of the subject based on measured data of the detecting unit. The display unit displays the blood sugar level data generated by the central processing unit.

Description

Apparatus for measuring blood sugar level and method of the same}

1 is a view showing a conventional blood glucose measurement apparatus.

2 is a block diagram showing the configuration of a blood glucose measurement apparatus according to an embodiment of the present invention.

3 is a view showing an exemplary structure of a dielectric resonator employed in a blood glucose measurement apparatus according to an embodiment of the present invention.

4 is a graph showing a change in frequency characteristics according to blood glucose levels.

5 is a graph illustrating an example of a waveform change pattern of a wave depending on whether or not it interacts with an object to be measured.

6 is a graph illustrating an example of a waveform change pattern when a modulator is provided.

7 is a graph showing the voltage change according to the blood glucose level.

8 is a flowchart illustrating a blood glucose measurement method according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100.Source part 120 ... Variable capacity part

140 ... sensor 200 ... modulator

150 ... Dielectric resonator 300 ... detector

400 ... central processing unit 500 ... display unit

The present invention relates to a blood glucose measurement apparatus and method of the non-blood collection method, and more specifically, a blood glucose measurement apparatus and method for improving the measurement sensitivity by including a dielectric resonator having a sensor tip interacting with the object to be measured. It is about.

Blood glucose measurement apparatus can be divided into blood glucose measurement device and blood glucose measurement device of non-blood collection method through blood collection.

1 shows a conventional blood glucose measurement apparatus for measuring blood glucose by blood collected from a patient. Such a blood glucose measurement apparatus is a device that can measure blood glucose through blood collection and is a device that can manage diabetes that can easily know blood glucose levels in the home. However, blood glucose measurement has to be taken every time, disinfection is required to prevent infection of the blood collection section, and there is an unsanitary disadvantage in that a needle must be used for blood collection.

In the non-blood collection blood glucose measurement apparatus, the source unit generates microwaves of a predetermined frequency, irradiates the microwaves generated from the source unit to the measurement site of the human body, and then, from the characteristic change of the dielectric resonator due to the interaction of the sensor tip and blood glucose, There is a device that measures. Microwave having a peak value at the center frequency changes both the center frequency and the peak value due to the interaction between the blood sugar and the sensor tip, and the method of measuring blood glucose by detecting the change of the peak value among them. On the other hand, the error factors in the measurement include the error generated in the source portion in the microwave generation step, the loss until the dielectric resonator receives the sensing and the like. Therefore, it is necessary to reduce the error factor and improve sensitivity or accuracy.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a blood glucose measurement apparatus and method which can measure blood sugar safely and accurately without blood collection, and improve measurement sensitivity.

Blood glucose measurement apparatus according to an embodiment of the present invention for achieving the above object to generate a wave of a predetermined frequency, the source unit having a sensor unit for interacting with the object to be measured; A detector for measuring a waveform change of a wave generated before and after interaction with an object under measurement with respect to the wave generated by the source unit; A central processor configured to determine a center frequency and a bandwidth of the wave generated by controlling the source unit, and calculate data on a blood glucose level of an object under measurement based on the data measured by the detector; And a display unit displaying data on blood glucose levels generated by the central processing unit.

In addition, the blood glucose measurement method according to an embodiment of the present invention comprises the steps of generating a wave according to the presence or absence of the interaction from the source unit including a sensor unit for interacting with blood sugar; Measuring data on a wave pattern change of a wave according to the presence or absence of the interaction; Calculating data on blood glucose levels of an object under measurement based on the measured data; And converting and displaying the data on the blood glucose level into visual data.

Hereinafter, a blood glucose measurement apparatus and method according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail. However, the examples exemplified below are not intended to limit the scope of the present invention, but are provided to fully explain the present invention to those skilled in the art. In the drawings, like reference numerals refer to like elements, and the size of each element in the drawings may be exaggerated for clarity and convenience of description.

2 is a block diagram showing the configuration of a blood glucose measurement apparatus according to a preferred embodiment of the present invention, Figure 3 is a view showing the structure of a dielectric resonator employed as a sensor unit in the blood glucose measurement apparatus according to an embodiment of the present invention. Referring to the drawings, the blood glucose measurement apparatus includes a source unit 100, a detector 300, a central processing unit 400 and a display unit 500 for generating a wave of a predetermined frequency, the source unit 100 is the object to be measured It is provided with a sensor unit 150 to interact with (O). As the sensor unit 150, a dielectric resonator having a sensor tip may be employed. In addition, the modulator 200 may further include a modulator 200 that modulates a wave generated by the source unit 100.

The source unit 100 generates a wave of a predetermined frequency. For example, generate microwaves. In order to generate a wave having an arbitrary frequency, a voltage controlled oscillator (VCO) is generally used. The voltage controlled oscillator is composed of a resonator and a resonant circuit including a variable inductor or a variable capacitor to generate waves of various frequencies by varying inductance or capacitance. In the present invention, the source unit 100 is characterized in that the resonator serves as a sensor for blood glucose. To this end, the source unit 100 employs a dielectric resonator 150 having a sensor tip as the sensor unit 140 interacting with the object to be measured O. The dielectric resonator 150 interacts with the object O by the sensor tip and has a different oscillation frequency due to the change in permittivity depending on the amount of glucose contained in the blood of the object O. In this way, the blood glucose of the object under measurement is measured from the difference in the waveform of the wave generated according to the interaction with the object under measurement. The source unit 100 includes a variable capacitance unit 120 whose capacitance varies according to an applied voltage, and for example, a varactor diode may be employed. The frequency of the wave generated by the source unit 100 is determined according to the control signal input from the central processing unit 400. For example, the voltage applied to the varistor diode is changed according to the control signal input from the central processing unit 400, thereby adjusting the resonant frequency to generate a wave having a predetermined frequency.

The dielectric resonator 150 constitutes a resonant circuit together with the variable capacitor 140 in the source unit 100. The waveform of the wave generated in the source unit 200 varies according to the characteristics of the dielectric resonator 150. In particular, the present invention intends to use a characteristic change caused by the interaction between the dielectric resonator 150 and the object to be measured O. The dielectric resonator 150 includes a sensor tip 160 that interacts with the object under measurement. do. The dielectric resonator 150 may include, for example, a dielectric 157, a metal resonator 511 surrounding the dielectric 150, an input line 154, and a sensor tip 160 that interacts with the object under test O. And a tuning screw 152 installed through the output line 156 and the top surface of the metal resonator 154 to face the top surface of the dielectric 152. Here, the type of dielectric 152 is not particularly limited. A cylindrical hollow 159 is formed inside the metal resonator 134, and a dielectric 152 is provided in the hollow. The metal resonator 152 preferably uses a metal having excellent conductivity such as silver (Ag), and may be manufactured by plating silver (Ag) on the metal frame surface. The input line 154, the output line 156, and the sensor tip 160 are installed through the metal resonator 151. One side of the input line 154, the output line 156, and the sensor tip 160 is provided. End portions are located in the space 159 between the inner wall of the metal resonator 151 and the dielectric 157 so as to face the dielectric 157, respectively. In addition, the end portions of the input line 154, the output line 156, and the sensor tip 160 positioned between the metal resonator 151 and the dielectric 157 may be in the form of a straight line. It is good to form a coupling loop bent at an angle of. This is because the characteristics of the dielectric resonator 150 can be appropriately adjusted by adjusting the relative angle of the coupling loop.

The modulator 200 modulates the wave generated by the source unit 100 in a form having a bandwidth around a center frequency having a peak value. For example, it performs functions such as noise generation or mode generation.

The detection unit 300 measures the waveform change pattern of the microwaves changed by the interaction between the sensor tip 160 and the object under test (O). When there is no interaction with the object O under measurement, the detector 300 measures a wave generated by the source unit 200 and a wave changed by the interaction with the object under measurement O and calculates a waveform change pattern therefrom. Measure The detector 300 includes a power meter 320 for measuring the size of the wave and a spectrum analyzer 340 for measuring the frequency of the microwave. The apparatus may further include a network analyzer 360 for measuring insertion loss and matching of the dielectric resonator 150.

The central processing unit 400 controls the source unit 100 and the modulator 200 to determine the center frequency and the bandwidth. In addition, the central processing unit 4000 generates data on the blood glucose level of the object to be measured O based on the data measured by the detection unit 300. The display unit 500 displays data on blood glucose levels generated by the central processing unit 400.

Hereinafter, the principle that the blood glucose measurement apparatus measures the blood sugar of the object to be measured O will be described. First, the characteristic of the dielectric resonator 150 is changed by interaction with the object to be measured O with reference to FIGS. 4 to 6.

Figure 4 shows the change in the reflection coefficient (S11) according to the blood glucose by way of example, showing a graph of the glucose change amount based on the glass having a dielectric constant of 6. Referring to the graph, the dielectric constant is changed according to the equivalent amount contained in the blood of the object to be measured O, which indicates that both the center frequency and the peak value of the reflection coefficient S11 are changed. The waveform of the wave generated in the source unit 200 also varies according to the characteristic change of the dielectric resonator 150.

FIG. 5 exemplarily shows a change in waveform generated according to the interaction with the object under test (O). Wave, which had a peak value at the center frequency f _o , is changed to the center frequency f _o 'by changing the resonance characteristics of the dielectric resonator due to the effect of blood glucose.

Meanwhile, when the modulator 200 is further provided, the modulator 200 generates noise around the center frequency f ₀ to modulate the wave generated in the source unit 100 into a bandwidth having a bandwidth. In this case, the change in the wave waveform due to the interaction with the object to be measured O is represented as an amount A of changing the area of the graph in the frequency versus amplitude graph as shown in FIG.

The above-described waveform change is measured in the detection unit 300, and the central processing unit 400 calculates data on blood glucose level from this data. At this time, the blood glucose level is calculated from a database on the relationship between the measured waveform change pattern, the waveform change pattern prepared in advance, and the blood sugar level. The measurement of the waveform change pattern may be, for example, by measuring the area (A) in which the graph is shifted in the graph represented by the amplitude of the frequency versus the microwave, from which the power change of the microwave is measured. It can be converted into.

 7 is a graph illustrating the relationship between voltage and blood glucose level. This graph depends on the specific configuration of the blood glucose measurement apparatus, for example, the specific shape material of the dielectric resonator, and FIG. 8 is an example of a database on the relationship between the blood glucose level and the waveform change pattern. When a database such as the graph of FIG. 8 is provided, a corresponding blood glucose level can be known by referring to the calculated voltage to the database.

8 is a flowchart illustrating the steps of the blood glucose measurement method according to an embodiment of the present invention. Referring to the drawing, the source unit including the sensor unit interacting with the object to be generated generates a wave according to the interaction (610). As the sensor unit, a dielectric resonator having a sensor tip is employed, as described above. The detector measures data about a waveform change pattern of a wave according to the presence or absence of the interaction (630). On the other hand, the step of measuring the waveform change pattern may further include modulating the wave generated in the source unit to have a predetermined bandwidth (620). In this case, measuring the data of the waveform pattern change is a method of measuring the change in power from the amount of change in the area of the graph represented by the frequency and amplitude in the frequency versus amplitude graph for the wave. The central processor calculates data on blood glucose from the data on the waveform change pattern (640). At this time, reference is made to a previously prepared database on the relationship between blood glucose levels and waveform change patterns. The display converts and displays the data on the blood glucose level into visual data (650).

The invention can also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like, and may also be implemented in the form of a carrier wave (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

According to the blood glucose measurement apparatus and method according to the present invention it is possible to measure the blood sugar safely and quickly in a non-blood collection method. In addition, by directly employing a dielectric resonator having a sensor tip interacting with an object under test, the conventional resonator may have an error such as an error occurring in the source in the wave generation step or a loss of the dielectric resonator from sensing it. There is an advantage that the accuracy is further improved by reducing the error factor.

The above embodiments are merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Therefore, the true technical protection scope of the present invention should be defined within the following claims.

Claims (11)

Generating a wave of a predetermined frequency, the source having a sensor portion interacting with the object under test; A detector for measuring a waveform change of a wave generated before and after interaction with an object under measurement with respect to the wave generated by the source unit; A central processor configured to determine a center frequency and a bandwidth of the wave generated by controlling the source unit, and calculate data on a blood glucose level of an object under measurement based on the data measured by the detector; And a display unit for displaying data on the blood glucose level generated by the central processor. The method of claim 1, The sensor unit is a glucose measuring apparatus, characterized in that the dielectric resonator having a sensor tip. The method of claim 2, wherein the dielectric resonator, dielectric; A metal resonator surrounding the dielectric; Input line; And Output line; blood glucose measurement device comprising a. The method of claim 1, And the source unit includes a varistor diode whose capacitance changes according to an applied voltage. The method of claim 1, Wave generated in the source unit is a blood glucose measurement device, characterized in that the microwave. The method according to any one of claims 1 to 5, And a modulation unit for modulating the wave generated by the source unit to have a predetermined bandwidth. The method of claim 6, And the detector measures a change in power from an amount of change in an area consisting of frequency and amplitude in a frequency versus amplitude graph with respect to the microwave. Generating a wave according to the presence or absence of the interaction from a source unit including a sensor unit interacting with the object under test; Measuring data on a wave pattern change of a wave according to the presence or absence of the interaction; Calculating data on blood glucose levels of an object under measurement based on the measured data; And converting the blood glucose data into visual data and displaying the data. The method of claim 8, The sensor unit is a glucose measuring method, characterized in that the dielectric resonator having a sensor tip. The method according to claim 8 or 9, And modulating the wave generated by the source unit to have a predetermined bandwidth. The method of claim 10, Measuring the data on the waveform pattern change is a method for measuring glucose, characterized in that by measuring the change in power from the amount of change in the area of the graph represented by frequency and amplitude in the frequency versus amplitude graph for the microwave .

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