KR102535505B1 - Non-invasive glucose sensor and method for measuring glucose - Google Patents

Abstract

The present invention relates to a non-invasive blood glucose meter, which includes a plurality of finger contact units for contacting fingers, and a blood glucose measurement unit for measuring blood glucose of a finger contacted with the finger contact unit using near-infrared rays; A display unit for displaying information such as blood glucose measurement values of a plurality of fingers, and a control unit for displaying on the display unit an average value of a plurality of verified blood sugar values after performing a verification algorithm of the blood glucose values measured by the blood glucose measurement unit. to be The display unit includes a touch screen on which a fingerprint recognition area is set, a fingerprint recognition sensor is installed in the fingerprint recognition area of the touch screen, and the control unit recognizes a fingerprint by contacting a finger on the fingerprint recognition area. User registration is performed by storing the fingerprint and user information input through the key input unit of the touch screen in the storage unit, and the verified blood glucose value is stored in the storage unit together with the user information or the fingerprint information. Accordingly, the accuracy of measured blood sugar is high and the reliability of measurement data can be improved by measuring by contacting a plurality of fingers. In addition, since the blood glucose value measured together with the fingerprint registered in advance by contacting the finger to the non-invasive blood glucose meter is stored, user convenience can be improved by easily reading and displaying the previously measured blood glucose value by simply touching the finger.

Description

Non-invasive blood glucose meter and blood glucose measurement method thereof

The present invention relates to a non-invasive blood glucose meter, and more particularly, to a non-invasive blood glucose meter that measures blood sugar by irradiating a finger with near-infrared rays and a method for measuring blood sugar thereof.

Recently, the prevalence of diabetes is rapidly increasing worldwide due to a lack of exercise due to eating habits and an aging society. As of 2013, the death rate due to diabetes among 34 OECD countries is at a serious level, ranking fifth. To prevent complications of diabetes, blood sugar levels must be continuously monitored.

For desirable control of diabetes, an appropriate blood glucose measurement system must be established.

Since the blood sampling type blood glucose meter is an invasive method of measuring the blood glucose level of the collected blood after drawing blood by passing a needle through the skin, the patient is afraid of piercing the skin with a needle and suffers from pain. There is a problem to avoid. Therefore, in recent years, a technique for measuring blood sugar in a bloodless manner has been developed.

As a conventional non-blood type blood glucose meter, a blood glucose meter that generates a blood sugar concentration signal using near infrared rays to measure blood glucose concentration, a blood glucose meter that has a correction function using near infrared rays and a red light emitting device, and a needle that penetrates a glucose measurement biosensor There are a blood glucose meter that measures transmitted light, a blood glucose meter that collects collected saliva and measures the transmitted light with a blood glucose test strip, and a blood glucose meter that measures blood glucose concentration by irradiating light to a vein on the back of a hand.

Although these blood glucose meters measure different parts of the human body, the method of measuring the concentration of sugar in the blood is a method using near-infrared rays. And, as disclosed in Patent Document 1, the blood glucose measurement principle uses an algorithm applying the Beer-Lambert Law. The wavelength of the near-infrared ray used may be within a narrow band of 490 nm to 590 nm and 1,300 nm to 1,800 nm in order to minimize interference of glucose measurement by moisture.

However, since a conventional blood glucose meter that measures blood sugar with a finger uses a single finger, as disclosed in Patent Document 2, there is a problem in that accuracy or reliability of blood glucose measurement values is low.

Patent Document 1: Patent Registration Publication No. 10-0775669 (Announced on November 16, 2007) Patent Document 2: Patent Registration Publication No. 10-2164926 (2020.10.13. Notice))

Therefore, the present invention has been devised to solve the above problems, and is a non-invasive method capable of measuring blood sugar in a non-invasive way by contacting a plurality of fingers to increase accuracy and improving reliability of measurement data through a measurement data validation algorithm. It is to provide a blood glucose meter and a blood glucose measuring method thereof.

In addition, the present invention provides a non-invasive blood glucose meter capable of easily displaying previous blood glucose data information on a screen using a finger print by registering finger fingerprints for each user and linking and storing measured blood glucose data together with the fingerprint, and a blood glucose measurement method thereof is to provide

The configuration according to the first aspect of the present invention for achieving the above object is a non-invasive blood glucose meter, which is provided with a plurality of finger contact parts for contacting fingers, and uses near-infrared rays for the fingers in contact with the finger contact parts to measure blood glucose levels. A blood glucose measurement unit that measures blood sugar, a display unit that displays information such as blood glucose measurement values of a plurality of fingers, and a plurality of verified average blood glucose values are displayed on the display unit after performing a verification algorithm of the blood sugar values measured by the blood glucose measurement unit. It is characterized in that it comprises a control unit to.

Here, the non-invasive blood glucose meter includes a storage unit, and the control unit selects two blood glucose values from among a plurality of blood glucose values in order to perform a blood glucose value verification algorithm using a T-test algorithm for a plurality of blood glucose values output from the blood glucose measurement unit. Among a plurality of groups consisting of dog blood glucose values, it is checked whether the difference between the average values of the two groups is equal to or less than a certain amount, and if both the difference between the mean values of the two groups are equal to or less than a certain amount, the average value of all blood glucose measurements is calculated and stored in the storage unit. , It is preferable to display on the display unit.

Meanwhile, the control unit may remeasure blood sugar if a difference between average values of two groups among a plurality of groups is greater than or equal to a predetermined level.

Here, each of the plurality of finger contact parts is provided with a blood glucose measurement circuit that irradiates near-infrared light to measure and output a blood sugar value, and the blood glucose measurement circuit detects a NIR LED that irradiates near-infrared light and a near-infrared light that has passed through the finger. a NIR photodiode, a current-to-voltage (I-V) converter that converts a current value output from the NIR photodiode into a voltage, a first LPF that first low-pass filters an output value of the current-to-voltage (I-V) converter, and the first LPF. It is preferable to include a signal amplifier for amplifying the output signal of the signal amplifier, and a second LPF for secondary low-pass filtering of the signal amplified by the signal amplifier.

The display unit includes a touch screen on which a fingerprint recognition area is set, a fingerprint recognition sensor is installed in the fingerprint recognition area of the touch screen, and the control unit recognizes a fingerprint by contacting a finger on the fingerprint recognition area, Preferably, user information input through a key input unit of the touch screen is stored in the storage unit to perform user registration, and the verified blood glucose value is stored in the storage unit together with the user information or the fingerprint information.

When a finger touches the fingerprint recognition area along with a blood glucose value history display request through the key input unit of the touch screen, the control unit recognizes the corresponding user by the fingerprint recognized by the fingerprint recognition sensor, and schedules the recognized user. It is preferable to display blood sugar value information measured within a period of time on the display unit.

The configuration according to the second aspect of the present invention for achieving the above object is a blood glucose measuring method of a non-invasive blood glucose meter, wherein the blood glucose measuring unit of the blood glucose meter measures blood glucose using near-infrared rays for fingers that are in contact with a plurality of finger contact units. measuring; It is preferable to include a step of displaying a plurality of verified average blood glucose values on a display unit after performing a verification algorithm of the blood glucose values measured by the blood glucose measuring unit.

Here, in order for the control unit to perform a blood glucose value verification algorithm using a T-test algorithm for a plurality of blood glucose values output from the blood glucose measurement unit, the difference between the average values of two groups among a plurality of groups consisting of two blood glucose values among the plurality of blood sugar values Checking whether all are smaller than a certain size; When the difference between the average values of the two groups is equal to or less than a predetermined value, calculating an average value of all blood glucose measurement values, storing the calculated value in the storage unit, and displaying the calculated average value on the display unit is preferable.

The display unit includes a touch screen on which a fingerprint recognition area is set, a fingerprint recognition sensor is installed in the fingerprint recognition area of the touch screen, and the control unit recognizes a fingerprint recognized by contacting a finger on the fingerprint recognition area, Storing the fingerprint in the storage unit along with user information input through the key input unit of the touch screen to perform user registration, and storing the verified blood glucose value in the storage unit together with the user information or the fingerprint information It is preferable to include steps.

According to the non-invasive blood glucose meter and the method for measuring blood glucose having the above configuration, since a plurality of fingers are contacted and measured, the accuracy of measured blood sugar is high and the reliability of measurement data can be improved. In addition, according to the non-invasive blood glucose meter and its blood glucose measurement method, the measured blood glucose value is stored together with a fingerprint registered in advance by contacting the finger to the non-invasive blood glucose meter, so that the previously measured blood glucose value can be easily measured by simply touching the finger. User convenience can be improved by deriving and displaying it.

1 is a front view of a non-invasive blood glucose meter according to the present invention;
2 is an internal block diagram of the non-invasive blood glucose meter of FIG. 1;
3 is a flowchart of a blood glucose measurement method of a non-invasive blood glucose meter according to an embodiment of the present invention;
4 is a flowchart of a method for storing and displaying blood glucose measurement data in a non-invasive blood glucose meter according to an embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will be explained in detail through the following detailed embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. However, the present embodiments are provided to explain in detail enough to easily implement the technical idea of the present invention to those skilled in the art to which the present invention belongs.

In the drawings, embodiments of the present invention are not limited to the specific form shown and are exaggerated for clarity. Also, parts denoted with the same reference numerals throughout the specification represent the same components. In this specification, the expression "and/or" is used to mean including at least one of the elements listed before and after. In addition, singular forms also include plural forms unless specifically stated otherwise in a phrase. In addition, components, steps, operations, and elements referred to as "comprising" or "comprising" used in the specification mean the presence or addition of one or more other components, steps, operations, elements, and devices.

As used throughout this specification, the terms "about", "substantially", and the like, are used at or approximating that value when manufacturing and material tolerances inherent in the stated meaning are given, and Exact or absolute figures are used as an aid to understanding and to prevent exploitation by unscrupulous infringers of the disclosed disclosure. The term "step of (doing)" or "step of" used throughout the specification of the present invention does not mean "step for".

In this specification, a "unit" includes a unit realized by hardware, a unit realized by software, and a unit realized using both.

Further, one unit may be realized using two or more hardware, and two or more units may be realized by one hardware. In this specification, some of the operations or functions described as being performed by a terminal, device, or device may be performed instead by a server connected to the terminal, device, or device. Likewise, some of the operations or functions described as being performed by the server may also be performed by a terminal, apparatus, or device connected to the server. Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The non-invasive blood glucose meter according to the present invention radiates near-infrared wavelength light to a plurality of fingers (for example, four fingers (4 channels) including index, middle, ring, and small fingers), and the light is scattered and absorbed by the fingers. Blood glucose is measured by detecting the amount of light that passes through and comes out.

In addition, the non-invasive blood glucose meter of the present invention uses near-infrared wavelengths of 900 nm to 1,700 nm and increases data reliability through a measurement data verification algorithm.

A method of measuring blood glucose using infrared light is based on IR spectroscopy. Specifically, molecules may absorb infrared rays of a specific wavelength depending on the molecular bonding structure, molecular shape, potential energy surface (PES), masses of atoms, vibration coupling, and the like. Accordingly, the patient's blood glucose level can be measured by analyzing transmittance or absorbance of wavelengths absorbed by glucose in the infrared spectrum of the examiner.

1 is a front view of a non-invasive blood glucose meter according to the present invention, and FIG. 2 is an internal block diagram of the non-invasive blood glucose meter of FIG. 1 .

As shown in FIG. 1 , the non-invasive blood glucose meter 1 includes a blood glucose measurement unit 10 provided with a plurality of finger contact units 10a for contacting fingers, and a display displaying information such as blood glucose measurement values of a plurality of fingers. It includes a unit 30, a blood glucose measurement start button, and a blood glucose measurement end button.

The blood glucose measuring unit 10 includes a blood glucose measuring circuit that measures blood sugar of a finger by irradiating a near-infrared ray (NIR LED) to the finger contact unit 10a.

According to the present invention, the display unit 30 includes a touch screen having a function of an input unit for inputting user information. A predetermined area of the touch screen is designated as a fingerprint recognition area, and a fingerprint recognition sensor (not shown) is installed in the fingerprint recognition area.

The display unit 30 may further include a blood glucose display unit that displays the measured blood glucose value with an LED.

FIG. 2 is a control block diagram of the non-invasive blood glucose meter 1 of FIG. 1 .

As shown in FIG. 2, the control configuration of the non-invasive blood glucose meter 1 includes a NIR LED 11 for irradiating near-infrared light to each finger contact portion 10a of the non-invasive blood glucose meter 1, A NIR photodiode 12 for detecting light, an I-V converter 13 for converting the current value output from the NIR photodiode 12 into a voltage, and a first LPF for first low-pass filtering the output value of the I-V converter 13 ( 14), a signal amplifier 15 for amplifying the output signal of the 1 LPF 14, a 2 LPF 16 for secondary low-pass filtering of the signal amplified by the signal amplifier 15, and an output from the 2 LPF 16 It includes a control unit 19 for receiving and storing the blood glucose value in the storage unit 17 and a communication unit 18 for transmitting the measured blood glucose value to an external device.

The control unit 19 receives the output values of the 2LPF 16 for each of the four fingers and performs a verification algorithm of the measured blood sugar. The control unit 19 displays the measured value as a result of performing the verification algorithm on the touch screen.

The NIR photodiode 12 generates an electrical signal corresponding to an image of NIR light projected onto the finger.

The non-invasive blood glucose meter according to the present invention uses a near-infrared 900 nm to 1,700 nm wavelength instead of the conventional narrowband 490 nm to 590 nm or 1,300 nm to 1,800 nm wavelength.

NIR photodiode (sensor) technology for blood glucose measurement uses detection light source technology for non-invasive blood wavelengths. The control unit 19 calculates the concentration of the output value of the second LPF by using a Beer-Lambert law-based blood glucose measurement algorithm.

The optical density (OD) of light passing through the medium may be attenuated based on an equation related to the Beer-Lambert law. In the present invention, it is possible to obtain the concentration of a material that absorbs or attenuates light from the optical density of reflected light based on a known equation, and since it is a known technique, a detailed description thereof will be omitted.

After measuring the blood sugar, the control unit 19 verifies blood glucose measurement values output from each blood sugar measurement circuit of the 4 channels. Further, the control unit 19 stores in the storage unit 17 an average value of blood glucose values output from the second LPF 16 for each of the four finger contact units.

In addition, the control unit 19 evaluates data validity by using a T-test and analysis of variance in order to perform a verification algorithm of the blood glucose value output from the second LPF 16 .

In addition, the T-test is for the average difference between the two groups among the groups of channel 1 and channel 2, the group of channel 2 and channel 3, the group of channel 3 and channel 4, and the group of channel 4 and channel 1. Test significance. That is, the T-test is to check whether there is a difference in the average value between the two groups.

Here, analysis of variance is a method of verifying the statistical significance of the difference between the means of two or more groups. In the present invention, the difference between the mean values of two groups among a plurality of groups of two channels among four channels is less than a certain size acknowledgment of each

More specifically, the control unit 19 compares the difference between the average values of the two groups, and if both are less than a certain size, “significance probability p value> significance level alpha value”, so the average value of all measured values of 4 channels is displayed on the display unit ( 30).

The control unit 19, when the difference between the average values of the two groups is greater than a certain size, remeasures blood sugar in 4 channels because it is the case of "significance probability p value < significance level alpha value".

Meanwhile, according to the present invention, as the display unit 30 of the non-invasive blood glucose meter 1, a fingerprint recognition sensor (not shown) is installed in a predetermined area of the touch screen. Since a fingerprint recognition technology using a fingerprint recognition sensor installed in the touch screen uses a known technology, a detailed description of the principle will be omitted.

The fingerprint recognition sensor may perform fingerprint sensing for a finger touched through a certain area of the blood glucose measurement device.

A fingerprint sensor not illustrated may include a light emitting unit capable of emitting light to be used as a light source for fingerprint authentication, and a light receiving unit capable of collecting reflected light of the irradiated light reflected by a user's body (eg, a finger). there is. When the light is collected, the fingerprint sensor may generate image information corresponding to the collected light and store the generated image information to be used by the controller.

The controller 19 processes user registration by bringing a finger into contact with the fingerprint recognition area of the touch screen. In addition, the controller 19 may display a key input screen on the touch screen so that user information (eg, name, etc.) may be registered along with fingerprint registration.

According to the present invention, the control unit 19 matches the fingerprint recognized by the fingerprint recognition sensor installed at the bottom of the fingerprint recognition area of the touch screen with the measured blood glucose value and stores it in the storage unit 17 together with user information.

Also, the control unit 19 stores and manages blood glucose values for a certain period of time together with user information in the storage unit 17 . Accordingly, the controller 19 can display the blood glucose values of a certain period in the form of a list or graph on the touch screen, or measure and display an average value on the touch screen, using the blood glucose values measured and stored for a certain period of time.

3 is a flow chart of a blood glucose measurement method of a non-invasive blood glucose meter according to the present invention.

A finger is placed on the finger contact part of the non-invasive blood glucose meter, and the blood glucose level of the four fingers is measured (S1).

The control unit 19 performs a verification process of a verification algorithm for verifying the blood sugar of 4 channels. A plurality of groups consisting of two channels among the four channels are formed, and an average value of each blood glucose measurement value of the channels of the blood sugar group is calculated (S2).

The control unit 19 determines whether the average difference between the two groups among the plurality of groups is within a predetermined reference value (S3).

The controller 19 displays the average blood glucose values of all four channels on the display unit 30 when the difference between the average values of the two groups is within a predetermined reference value.

If there is a case where the difference between the average values of the two groups is greater than a certain reference value, the blood glucose of the four fingers is measured again.

Here, the control unit 19 displays the measured value on the display unit 30 if there is no difference in the measured value between channels, that is, in the case of “significance probability p value > significance level alpha value”.

However, if there is a difference in the measured values between channels, that is, in the case of "significant probability p value<significant level alpha value", the control unit 19 measures the blood glucose of the four fingers again.

Here, the significance level (alpha value) is a standard value for determining whether a value is significant or not, and the significance probability (p value, p-value) is the probability that the value of the corresponding analysis result is significant. In other words, it is to determine whether the value of the result falls within the standard value for determining significance (ie, a value that can be considered significant = level of significance) (ie, whether the probability of significance falls within the value of the level of significance).

Here, it is preferable that those skilled in the art appropriately set the value of significance level and significance probability at the time of product design.

4 is a flowchart of a blood glucose display method of a non-invasive blood glucose meter according to an embodiment of the present invention.

A user is registered by contacting a finger to the fingerprint recognition unit on the display unit of the non-invasive blood glucose meter 1 (T1). At this time, the control unit 19 displays a key input unit on the touch screen, and when the user inputs user information including a user name through the key input unit of the touch screen, the control unit 19 recognizes the input user information and displays the fingerprint and You can register together.

When the user touches each of the four finger contact units 10a of the non-invasive blood glucose meter 1 and starts blood glucose measurement by pressing the blood glucose measurement button, blood glucose is measured for each finger, and the second LPF of the blood glucose measurement circuit The blood glucose value measured in (16) is input to the control unit 19 to verify the blood sugar value (T2).

After performing the blood glucose value verification, the control unit 19 stores the verified blood glucose value in the storage unit 17 together with user information including the user name and fingerprint (T3).

Thereafter, when a predetermined user wants to check his/her own blood glucose details, selects display of details of blood glucose measurement values through the display unit (T4), and touches a finger to the fingerprint recognition area of the display unit 30 (T5). The control unit 19 recognizes the user's fingerprint by the fingerprint recognition sensor (T6). The control unit derives blood glucose information stored in relation to the corresponding user from the storage unit and displays blood glucose value information measured within a certain period of time on the screen in the form of a list (T7).

As described above, in order to reduce the measurement error of the non-invasive blood glucose meter, reliability is increased by 4-channel blood glucose measurement using 4 fingers, and reliability is improved by verifying the significant difference in measured values of 2 channel groups among the 4 channels. can improve

According to another embodiment, a statistical method may be applied after measurement to improve measurement reliability. For example, data such as determining the number of measurements (period) for each channel of 4 channels, ignoring an outlier in the measured value for a specific channel, calculating the average of the remaining 3 channels, or replacing the average of the 3 values with an outlier You might be able to do a refinement. Thereafter, when the measured values of each channel are determined, the distribution of the measured values between channels is checked to determine whether the values of the four channels are significant.

In the above-described embodiment of the present invention, communication between the device and the system is performed through a communication network (not shown). The communication network may be configured regardless of communication types such as wired communication or wireless communication, and various communication networks such as a local area network (LAN), a metropolitan area network (MAN), and a wide area network (WAN). It can be configured as a communication network. Preferably, the communication network referred to in this specification may be the well-known Internet or the World Wide Web (WWW). However, the communication network may include, at least in part, a known wired/wireless data communication network, a known telephone network, or a known wire/wireless television communication network without being limited thereto.

For example, the communication network is a wireless data communication network, such as radio frequency (RF) communication, WiFi (WiFi) communication, cellular (LTE, etc.) communication, Bluetooth communication (more specifically, Bluetooth Low Energy (BLE)). )), infrared communication, ultrasonic communication, and the like may be implemented at least in part.

The above is an example of the present invention and should not be construed as limiting. Although several exemplary embodiments of the present invention have been described, those skilled in the art will readily understand that many changes are possible in the exemplary embodiments without significantly departing from the novel teachings and advantages of the present invention. Accordingly, all such modifications are intended to be included within the scope of the present invention as defined by the claims. Therefore, the above is an example of the present invention, and should not be construed as being limited to specific embodiments in the disclosed or disclosed invention, and changes to the disclosed embodiments and other embodiments are disclosed herein. It will be understood that it is included within the scope of the invention.

1: Non-invasive blood glucose meter
10: blood glucose measurement unit 10a: finger contact unit
11: NIR LED 12: NIR photodiode
13: IV converter 14: first LPF
15: signal amplifier 16: second LPF
17: storage unit 18: communication unit
19: control unit 30: display unit
31: fingerprint registration area

Claims (8)

As a non-invasive blood glucose meter,
A blood glucose measurement unit having a plurality of finger contact units for contacting fingers and measuring blood sugar levels of fingers contacting the finger contact units using near-infrared rays;
a display unit displaying information including blood glucose measurement values of a plurality of fingers;
a control unit that displays a plurality of verified average blood glucose values on the display unit after performing a verification algorithm of the blood glucose values measured by the blood glucose measuring unit; and
Including a storage unit,
The control unit, in order to perform a blood glucose value test using a T-test algorithm for a plurality of blood glucose values output from the blood glucose measurement unit, determines a difference in mean values between two groups among a plurality of groups consisting of two blood sugar values among a plurality of blood sugar values. It verifies whether or not it is less than a certain size, compares the difference between the average values of the two groups, and if both are less than a certain size, the average value of all blood glucose measurement values is calculated, stored in the storage unit, and displayed on the display unit. Wet blood glucose meter. delete According to claim 1,
Each of the plurality of finger contact units is provided with a blood glucose measurement circuit that irradiates near-infrared light to measure and output blood glucose values,
The blood glucose measurement circuit includes a NIR LED for irradiating near-infrared light, a NIR photodiode for detecting near-infrared light transmitted through a finger, a current-voltage (IV) converter for converting a current value output from the NIR photodiode into a voltage, and the A first LPF for first low-pass filtering the output value of the current-to-voltage (IV) converter, a signal amplifier for amplifying the output signal of the first LPF, and a second LPF for second low-pass filtering the signal amplified by the signal amplifier. That is, a non-invasive blood glucose meter. According to claim 1,
The display unit includes a touch screen on which a fingerprint recognition area is set,
A fingerprint recognition sensor is installed in the fingerprint recognition area of the touch screen,
The control unit recognizes a fingerprint by contacting a finger to the fingerprint recognition area, stores the recognized fingerprint and user information input through the key input unit of the touch screen in the storage unit, performs user registration, and verifies the blood glucose value. To store in the storage unit together with the user information or the fingerprint information, the non-invasive blood glucose meter. According to claim 4,
When a finger touches the fingerprint recognition area along with a blood glucose value history display request through the key input unit of the touch screen, the control unit recognizes the corresponding user by the fingerprint recognized by the fingerprint recognition sensor, and schedules the recognized user. A non-invasive blood glucose meter for displaying blood glucose value information measured within a period of time on the display unit. As a blood glucose measurement method of a non-invasive blood glucose meter,
measuring blood glucose levels of fingers that are in contact with a plurality of finger contact units by a blood glucose measurement unit of the blood glucose meter using near-infrared rays;
displaying a plurality of verified average blood glucose values on a display unit after performing a verification algorithm of the blood glucose values measured by the blood glucose measuring unit;
In order for the control unit to perform the blood glucose value test using the T-test algorithm on the plurality of blood glucose values output from the blood glucose measurement unit, the difference between the average values of the two groups among a plurality of groups consisting of two blood glucose values among the plurality of blood glucose values is constant. Checking whether the size is smaller than the size; and
and calculating an average value of all blood glucose measurement values, storing the average value in a storage unit, and displaying the average value on the display unit when the difference between the average values of the two groups is equal to or less than a predetermined size. delete According to claim 6,
The display unit includes a touch screen on which a fingerprint recognition area is set,
A fingerprint recognition sensor is installed in the fingerprint recognition area of the touch screen,
The control unit recognizes a fingerprint recognized by contacting a finger on the fingerprint recognition area, and stores the recognized fingerprint in a storage unit together with user information input through a key input unit of the touch screen to perform user registration;
and storing the verified blood glucose value together with the user information or the fingerprint information in the storage unit.

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