KR20130134867A - Glucose measuring device for automatically percepting a code signal of senser strip - Google Patents

Abstract

The present invention provides a sensor strip including a carbon electrode having a plurality of code combination values selectively printed on an electrode port; When the sensor strip is inserted, it automatically reads various code combination values of the corresponding sensor strip according to the shape of the carbon electrode printed on the electrode port of the sensor strip, corrects the sensing measurement deviation of the corresponding sensor strip, and calculates a blood glucose measurement value. Provided is a blood sugar measuring apparatus for automatically recognizing a code signal of a sensor strip including a blood sugar measuring apparatus.
As described above, the present invention selects and prints a carbon electrode having a plurality of code combination values at the electrode port of the sensor strip without having to separately provide an external circuit in the blood glucose measurement apparatus in order to recognize the code value of the sensor strip, and sends the blood sugar Since the measuring device is a simple read processing method, since an expensive code recognition circuit is not used, the manufacturing cost of the blood glucose measuring device is significantly reduced.

Description

    Glucose measuring device for automatically percepting a code signal of senser strip}

The present invention relates to a blood glucose measurement apparatus for automatically recognizing the code signal of the sensor strip, and in particular, a plurality of codes on the electrode port of the sensor strip without having to separately provide an external circuit in the blood glucose measurement apparatus to recognize the code value of the sensor strip. The present invention relates to a blood glucose measurement apparatus for automatically recognizing a code signal of a sensor strip that significantly reduces the manufacturing cost of a glucose measurement apparatus since the structure in which a carbon electrode having a combination value is selected and printed and shipped and the blood glucose measurement apparatus is easily read and processed. .

In general, a blood glucose measurement device inserts a test strip, ie, a sensor strip (biosensor strip), into an inlet of a blood glucose measurement device, and collects a small amount of blood collected at a fingertip by collecting a fingertip. It is automatically sucked into the sensor strip opening and the resulting value is displayed on the screen of the glucose measuring device. Such a sensor strip is used to quantitatively or qualitatively analyze a sample taken from a human body, and apply an electrically conductive material on a predetermined size of an insulator, or deposit it, to cause an electrochemical reaction with the sample. It contains a built-in electrode. However, since the sensor strip has a sensing measurement deviation due to the characteristics of the sensor strip manufacturing process, the sensor strip has a slightly different characteristic for each manufacturing process. Therefore, in order to compensate for the sensing measurement deviation in the characteristics of the sensor strip manufacturing process, a unique code that can represent the sensing measurement deviation is provided in every production of the sensor strip, and the blood glucose measurement device recognizes the code of the sensor strip. By compensating for the sensing measurement deviation according to the unique code, more accurate results are output.

      As the code recognition method of the sensor strip as described above, there is a method using a code chip and a method of manually inputting a code into a blood glucose measurement apparatus.

Here, the prior art related to the blood glucose measurement apparatus using the conventional sensor strip as described above is disclosed in Korean Patent Application Publication No. 10-2008-0064705 (Invention: Biostrip management system and the application filed by Health and Life Company Limited) Method; publication date: July 09, 2008).

     Then, the blood glucose measurement apparatus for recognizing the code of the conventional sensor strip as described above, as shown in Figure 1, the blood glucose measurement biosensor 70 (hereinafter, the sensor strip) is inserted and fixed to the connector;

      An analog switch (73) for supplying a voltage signal set by the voltage source unit (72) to the sensor strip (70) inserted into the strip connector (71);

      An OP amplifier unit 74 for amplifying and outputting an analog blood glucose measurement current measured by the sensor strip 70 to a predetermined level;

      After analyzing the blood sugar measurement current output from the OP amplifier unit 74, the current blood sugar measurement value is calculated and displayed on the display 75, and the code signal of the sensor strip 70 input through the key input unit 76. After identifying the and includes the MCU 76 for supplying the operating voltage of the sensor strip 70 through the voltage source unit 72.

      In addition, the MCU 76 is connected to a memory unit 78 for storing information to be operated in the blood glucose measurement device 77.

     Meanwhile, the operation of the blood glucose measurement apparatus recognizing the code of the conventional sensor strip as described above, first, the measurer inserts and fixes the sensor strip 70 into the strip connector 71 for measurement. When the user manually inputs a code signal of the sensor strip 70 through the key input unit 76 of the blood sugar measuring device 77, the MCU 76 of the blood sugar measuring device 77 may detect the sensor strip ( Recognizing the code signal of the 70 to determine the operating voltage of the corresponding sensor strip 70 stored in the memory unit 78, and generates an operating voltage of the corresponding sensor strip 70 through the voltage source unit 72 to the analog switch ( 73). Then, the analog switch 73 supplies the voltage signal set to the corresponding sensor strip 70 inserted into the strip connector 71, so that ordinary measurement is performed.

      In this process, the sensor strip 70 measures blood glucose through a blood collection of a measurer, and then amplifies the measured blood glucose measurement current to a predetermined level through the OP amplifier unit 74 and inputs it to the MCU 76. Then, the MCU 76 analyzes the blood sugar measurement current output from the OP amplifier unit 74, compensates for the sensing measurement deviation according to the code of the sensor strip 70, calculates the current blood sugar measurement value, and displays the display 75. ), The meter checks his current blood sugar level.

      In addition, the blood glucose measurement apparatus for recognizing the code of the sensor strip as described above, there is an optical processing method for printing a specific color on the back of the sensor strip (reading it through an optical sensor), and another device for blood glucose measurement A device having a memory chip that sleeps lot characteristic information of a sensor strip separately and using the same to recognize a code of the sensor strip is also used.

However, the blood glucose measurement apparatus for recognizing the code of the conventional sensor strip as described above is equipped with a separate memory chip that sleeps the external circuit, for example, lot characteristic information of the sensor strip, in order to recognize the code value of the sensor strip. It is possible to increase the manufacturing cost of the blood glucose measurement device because it is equipped with a recognition processing module that can recognize the code of the sensor strip, and also to detect the code value of the sensor strip. In addition, since the external circuit that separately recognizes the code value of the sensor strip has to be complicatedly designed and implemented, there is a problem in that the substrate design of the blood glucose measurement device is considerably degraded.

Therefore, the present invention was invented to solve the above-mentioned problems of the prior art, and the carbon electrode having a plurality of code combination values is printed and shipped to the electrode port of the sensor strip, and the blood glucose measurement apparatus is easily read and processed. It is an object of the present invention to provide a blood glucose measurement apparatus and a control method for automatically recognizing a code signal of a sensor strip, which does not require the use of an expensive code recognition circuit.

Another object of the present invention is because it is not necessary to complexly design and implement an external circuit for recognizing the code value of the sensor strip separately on the internal substrate or the outside of the blood glucose measurement device to recognize the code value of the sensor strip. The present invention provides a blood glucose measurement apparatus for automatically recognizing a code signal of a sensor strip and a control method thereof, because the substrate design can be easily executed, thereby significantly improving the substrate design of the blood glucose measurement apparatus.

The present invention for achieving the above object is a sensor strip that is shipped with a carbon electrode having a plurality of code combination values selectively printed on the electrode port;

When the sensor strip is inserted, it automatically reads various code combination values of the corresponding sensor strip according to the shape of the carbon electrode printed on the electrode port of the sensor strip, corrects the sensing measurement deviation of the corresponding sensor strip, and calculates a blood glucose measurement value. Provided is a blood sugar measuring apparatus for automatically recognizing a code signal of a sensor strip including a blood sugar measuring apparatus.

According to the present invention as described above, in the manufacture of the sensor strip, the carbon electrode having a plurality of code combination values are selected and printed on the electrode port of the sensor strip and shipped, and all the various types of code combination values implemented by the carbon electrode are mounted. By automatically reading and processing the code combination value of the sensor strip with the blood glucose measurement device, the code combination of the sensor strip with the blood glucose measurement device does not have to be provided with an external circuit separately to recognize the code value of the sensor strip. Since the value is simply read-processed, expensive code recognition circuits are not used, thereby significantly reducing the manufacturing cost of the blood glucose measurement apparatus.

As described above, the present invention also does not need to complexly design and implement an external circuit for recognizing the code value of the sensor strip separately on the internal substrate of the blood glucose measurement device or the outside to recognize the code value of the sensor strip. Since the substrate design can be easily executed, the substrate design of the blood glucose measurement apparatus is also significantly improved.

1 is an explanatory diagram illustrating a blood glucose measurement apparatus for recognizing a code of a conventional sensor strip.
2 is an explanatory diagram illustrating a blood glucose measurement apparatus for automatically recognizing a code signal of a sensor strip according to the present invention.
Figure 3 (ad) is an explanatory diagram for explaining an experimental example for obtaining a code using four input / output ports provided in the microcomputer of the present invention.
FIG. 4 (ad) is an explanatory diagram illustrating truth values corresponding to FIG. 3 (ad). FIG.
(e) is explanatory drawing explaining the table | surface which summarized the code value based on the result of the sum of the truth values of (ad) of FIG.
FIG. 5A is an explanatory diagram illustrating an embodiment in which various code combination values of a sensor strip are implemented using the truth values of FIG. 4E. FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the present invention includes a sensor strip 3 in which carbon electrodes 1 having a plurality of code combination values are selectively printed on the electrode ports 2 and shipped;

When the sensor strip 3 is inserted, various code combination values of the corresponding sensor strip 3 are automatically read according to the shape of the carbon electrode 1 printed on the electrode port 2 of the sensor strip 3. And a blood glucose measurement apparatus main body 4 for correcting a sensing measurement deviation of the sensor strip 3 and calculating a blood glucose measurement value.

In addition, the blood glucose measurement apparatus main body 4 is equipped with all the code combination values of various types implemented by the carbon electrode 1.

Next, the operation and effects of the present invention as described above will be described.

Here, the code combination values of the above-described various types of code combination values are calculated through the processes as shown in FIGS. 3A and 3A.

That is, the above code combination value is 1) P1 is an output port as shown in (a) of FIG. 3 of four input / output ports of a microprocessor (not shown) provided in the blood glucose measuring apparatus 4. The other three ports are set to input ports with the microprocessor's internal software pull-up resistor. After the Low (GND) output is sent to the P1 port, the remaining three port states are read to store the port state.

  2) As shown in (b) of FIG. 3 of the four input / output ports of the microprocessor, P2 is set as an output port and the other three ports are set as input ports having a microprocessor internal software pull-up resistor. . After the Low (GND) output is sent to the P2 port, the remaining three port states are read to store the port state.

  3) As shown in (c) of FIG. 3 of the four input / output ports of the microprocessor, P3 is set as an output port and the other three ports are set as input ports having a microprocessor internal software pull-up resistor. After the Low (GND) output is sent to the P3 port, the remaining three port states are read to store the port state.

  4) Of the four microprocessor input / output ports, P4 is set as an output port and the remaining three ports are set as input ports having a microprocessor internal software pull-up resistor as shown in (d) of FIG. After the Low (GND) output is sent to the P4 port, the remaining three port states are read to store the port state.

 5) As described above, P1, P2, P3, and P4 are sequentially read as the GND outputs, and the state of the four ports is read and connected to each other to distinguish the total of 11 cases.

 6) The code number of the biosensor (strip) is determined according to the 11 types recognized through the above process.

4 (ad), various types of code combination values as shown in (ad) of FIG. 4 can be obtained. For example, in the case of FIG. 3 (a) The truth value as shown in (a) of FIG. 3, the truth value as shown in (b) of FIG. 3 in the case of FIG. 3 (b) The truth value is obtained as shown in FIG. 3 (d), and the truth value as shown in FIG. 4 (d) is obtained. 4E is a table summarizing the code values according to the sum of the truth values of FIGS. 4A through 4D.

5 (a-k) shows an embodiment in which various code combination values of the sensor strip 3 are implemented using the truth values of FIG. 4 (e) calculated as described above.

That is, the sensor strip 3 of the present invention uses the truth values of FIG. 4E in the manufacturing of the sensor strip 3, for example, to form a carbon electrode 1 corresponding to eleven code combination values. It is optionally printed on the port 2 and shipped.

And, if any sensor strip (3) shipped by the manufacturer as described above is mounted on the strip connector 5 of the blood sugar measuring device main body 4, the blood sugar measuring device main body (4) is the electrode port of the sensor strip (3) (2) Automatically read various code combination values of the sensor strip (3) according to the shape of the carbon electrode (1), correct the sensing measurement deviation of the sensor strip (3) and display the blood glucose measurement value ( 7) Calculate the phase.

Therefore, when using the sensor strip (3) of the present invention as described above, even if the manufacturers are different, since the sensor strip (3) is shipped with the code combination value is selected and printed for each manufacturer as described above, the blood glucose measurement apparatus main body (4) Since the code combination value by the carbon electrode 1 of the sensor strip 3 can be read regardless of the manufacturer, an external circuit is separately provided to the blood glucose measurement apparatus 4 in order to recognize the code of the sensor strip 3. No need to install

That is, according to the present invention as described above, in the manufacture of the sensor strip, the carbon electrode having a plurality of code combination values are selected and printed on the electrode port of the sensor strip and shipped and the various types of code combination values implemented by the carbon electrode By reading and processing the code combination value of the sensor strip automatically with all the blood glucose measurement devices installed, the blood glucose measurement device does not need an external circuit to recognize the code value of the sensor strip. It is not necessary to use expensive code recognition circuit because it simply reads and processes the code combination value.

As described above, the present invention also does not need to complexly design and implement an external circuit for recognizing the code value of the sensor strip separately on the internal substrate of the blood glucose measurement device or the outside to recognize the code value of the sensor strip. Board design can be easily performed.

1: carbon electrode 2: electrode port
3: sensor strip 4: blood glucose measurement apparatus
5: strip connector 6: key input
7: display

Claims (2)

A sensor strip in which carbon electrodes having a plurality of code combination values are selectively printed on the electrode ports and shipped;
When the sensor strip is inserted, it automatically reads various code combination values of the corresponding sensor strip according to the shape of the carbon electrode printed on the electrode port of the sensor strip, corrects the sensing measurement deviation of the corresponding sensor strip, and calculates a blood glucose measurement value. Blood glucose measurement apparatus for automatically recognizing the code signal of the sensor strip including the body. The blood glucose measurement apparatus of claim 1, wherein the main body of the blood glucose measurement apparatus includes all the code combination values of various types implemented by a carbon electrode.

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