KR20120019940A - Apparatus for analyzing of biosensor - Google Patents

Abstract

PURPOSE: A biosensor measuring device is provided to enable a user to add only the desirable functional module by combining various functional modules with the biosensor measuring device. CONSTITUTION: A biosensor measuring device includes a bio information measuring unit(110), a module identifying unit(120), a memory(130), a controller(140), and an output unit(150). The bio information measuring unit extracts bio information from a bio sensor inserted into the bio sensor measuring device. The bio information measuring unit stores the bio information in the memory. The module identifying unit is comprised of an electrode which recognizes the attachment and detachment of the module. The memory stores information for recognizing a kind of a module according to a variation range of a set voltage. The controller compares inputted barcode information with barcode information according to the module in the memory.

Description

Biosensor measuring device {APPARATUS FOR ANALYZING OF BIOSENSOR}

The present invention relates to a biosensor measuring device, and more particularly, to a biosensor measuring device to which various external modules are coupled.

Recently, as interest in health has increased, biosensor measuring devices have been developed that can test their own blood without going directly to the hospital. Such a biosensor measuring device has a limited function because the production cost is produced in a low price. However, with the development of technology, consumers are demanding more functions for biosensor measuring devices.

In the case of embedding a module having multiple functions in the biosensor measuring device, there is a problem in that the production cost increases and the size of the product increases, thereby reducing portability. Accordingly, the present inventors have studied the technology of combining the biosensor measuring device and various modules without significantly increasing the production cost of the biosensor measuring device.

Various functional modules can be combined in a biosensor measuring instrument. In addition, it is possible to effectively recognize the type of module coupled to the biosensor measuring device. In addition, different information processing algorithms may be executed depending on the type of modules combined in the biosensor measuring device.

The biosensor measuring apparatus according to an embodiment recognizes a module coupled to a biometric information measuring unit for measuring biometric information from a biosensor, and controls a module identification unit and a biometric information measuring unit and the module identification unit to identify the type thereof. It includes.

The biosensor measuring apparatus according to an embodiment may determine the type of module by using the resistance value of the module to be coupled or by using optical information displayed on the module to be coupled. In this case, the optical information displayed on the module to be combined may include at least one of color information, barcode information, and perforation arrangement information.

The biosensor measuring device according to an embodiment further includes a memory in which one or more algorithms are stored, and the controller outputs the measured biometric information to the identified module or inputs information associated with the biometric information therefrom using the algorithm stored in the memory. Control the modules identified to receive.

By combining the various functional modules in the biosensor measuring device, the consumer can add and use only the functional modules he / she wants. In addition, it is possible to execute various functions without increasing the size of the biosensor measuring device. In addition, various functions can be executed without increasing the production cost of the biosensor measuring device itself.

1 is a block diagram of a biosensor measuring device according to an embodiment;
2A is an exemplary view in which color information is displayed as identification information on a module coupled to a biosensor measuring device according to an embodiment;
2B is an exemplary diagram in which barcode information is displayed as identification information on a module coupled to a biosensor measuring apparatus according to an embodiment;
2C is an exemplary view in which puncture information is displayed as identification information on a module coupled to a biosensor measuring device according to an embodiment;
2D is an exemplary view in which a module identification unit is formed on a front surface of a biosensor measuring device according to an embodiment;
2E is an exemplary view in which a connector is connected to a biosensor measuring device according to an embodiment;
2F is an exemplary view in which a cable is connected to a biosensor measuring device according to an embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of functions in the embodiments, and the meaning of the terms may vary depending on the intention or precedent of the user or operator. Therefore, the meaning of the terms used in the embodiments to be described later, according to the definition if specifically defined herein, and if there is no specific definition should be interpreted to mean generally recognized by those skilled in the art.

1 is a block diagram of a biosensor measuring device according to an embodiment.

Referring to FIG. 1, the biosensor measuring device 100 includes a biometric information measuring unit 110, a module identification unit 120, a memory 130, a control unit 140, and an output unit 150. The biometric information measuring unit 110 extracts biometric information from the biosensor inserted into the biosensor measuring apparatus 100. The biometric information measuring unit 110 may obtain an electrical signal, an optical signal, a magnetic signal, or the like from a biosensor using chemistry, optics, fluorescence, surface plasmon resonance (SPR), color development, magnetism, or the like. The biometric information measuring unit 110 may store the extracted biometric information in the memory 130.

In addition, the biometric information measuring unit 110 may extract identification information such as the type, manufacturer, correction code, and unique number of the biosensor. The calibration code is for correcting the test results because the test results are different when the same biosensor is tested under the same conditions. The biometric information measuring unit 110 may scan a barcode or color tag printed on the biosensor and extract identification information of the biosensor.

The module identification unit 120 may be configured as an electrode that recognizes whether the module 200 is attached or detached. For example, a reference voltage is applied to the reference electrode of the module identification unit 120. When the module 200 is inserted, the voltage applied to the reference electrode is changed by the internal impedance of the inserted module 200. In this case, the module identification unit 120 monitors whether the voltage of the reference electrode changes. When the voltage applied to the reference electrode fluctuates, it is recognized that the module 200 is coupled to the biosensor measuring device 100, and when the voltage of the reference electrode is maintained at the reference voltage, the module 200 is separated. Recognize.

On the other hand, the module 200 coupled to the biosensor measuring device 100 is, for example, Bluetooth, Zigbee, USB, scanner, printer, keypad, voice output device, memory card, mouse, pedometer, calorie measuring device, hearing aid, etc. Other input and output devices may be, but are not limited thereto. For example, the module identification unit 120 may be a card type slot 210, a USB port type terminal, or an earphone terminal according to the module 200 to be coupled thereto, but is not limited thereto. Accordingly, the external module 200 may be attached to or detached from the biosensor measuring device 100.

The module identification unit 120 may determine the type of the module 200 by using the resistance of the coupled module 200. For example, when the module 200 is coupled, a change in voltage may be set according to the type of the coupled module 200. The memory 130 may store information necessary for recognizing the type of the module 200 according to the variation range of the set voltage. Accordingly, the module identification unit 120 may obtain a voltage variation range and find out the type of the module 200 corresponding to the voltage variation range by referring to the information of the memory 130. The module information signal thus identified is output to the controller 140.

The module identification unit 120 may include a power terminal, a communication terminal, a ground terminal, and the like. The power supply terminal may supply power to the connected module 200 or identify the type of the module 200. The communication terminal is used to transmit data from the biosensor measuring device 100 to the module 200 or to receive data from the module 200. Accordingly, when the module 200 is connected to the biosensor measuring device 100, it is possible to determine whether the module 200 is connected and the type of the module 200 by using the ground terminal and the power terminal. In addition, the module 200 may transmit and receive data.

In addition, the module identification unit 120 may include two or more power terminals. When the module 200 having the internal power source is coupled, the type of the module 200 may be determined using the potential difference of the inserted module 200. The memory 130 may store information regarding the type of the module 200 according to the potential difference range of the module 200. Accordingly, the module identification unit 120 may acquire the potential difference of the inserted module 200 and determine the type of the module 200 by using the module identification information stored in the memory 130. The grasped module information signal is output to the controller 140.

According to a further aspect of the present invention, the module identification unit 120 of the biosensor measuring device 100 may include an optical scanner capable of reading the optical information 300. This scans the optical information 300 displayed on the surface of the module 200 with an optical scanner to identify the information of the module 200. The module 200 information according to each optical information 300 may be stored in the memory 130. An embodiment in which the module identification unit 120 uses the optical information 300 of the module 200 will be described later with reference to FIGS. 2A to 2C.

2A is an exemplary diagram in which color information is displayed as identification information on a module 200 coupled to the biosensor measuring apparatus 100 according to an embodiment.

Referring to FIG. 2A, color information such as color tags may be displayed on the surface of the functional module 200 coupled to the biosensor measuring device 100. The module identification unit 120 may obtain an optical signal from the module 200 using optics, fluorescence, color development, and the like. The measured color information may be output to the controller 140 and stored in the memory 130. Color information for each module 200 may be stored in the memory 130. Therefore, the type of the module 200 coupled through the color information can be identified.

In addition, the color information displayed on one surface of the module 200 to be coupled may be modified in various forms such as a stripe shape or a circle by the user's setting. Accordingly, the color information may be displayed in a plurality of colors, and the displayed position may be formed differently for each module 200.

On the other hand, the electrode 400 may be formed on the other surface of the module 200 to be coupled. The biosensor measuring device 100 of the present invention may identify the type of the module 200 by using a resistance value through the electrode 400, but basically supplies power through the electrode 400, and performs data communication. can do. When the type of the module 200 is identified using the optical information 300, the type of the module 200 may not be identified using the resistance of the electrode 400, and the module through the electrode 400 may be identified. The first recognition may be performed using the internal resistance value 200, and the second recognition may be performed through the optical information 300.

2B is an exemplary diagram in which barcode information is displayed as identification information on the module 200 coupled to the biosensor measuring apparatus 100 according to an embodiment.

Referring to FIG. 2B, barcode information may be displayed on one surface of the functional module 200 coupled to the biosensor measuring device 100. The barcode may be in the form of a QR code as well as a linear barcode. The barcode information includes identification information of the module 200 to be coupled, and the module identification unit 120 may find out the type of the module 200 from the corresponding barcode information with an optical scanner.

The module identification unit 120 outputs the barcode information to the controller 140 when the barcode information is confirmed. The controller 140 may check the type of the combined module 200 by comparing and analyzing the input barcode information with barcode information for each module 200 stored in the memory 130.

In addition, the electrode 400 is formed on the surface where the bar code information is not displayed, and may be supplied with power or supply power from the biosensor measuring device 100, and may perform data communication with the biosensor measuring device 100. The module identification unit 120 may detect the resistance value inside the module 200 through the electrode 400 to first recognize the module 200 and to recognize the barcode information to perform secondary recognition.

2C is an exemplary view in which punching information is displayed as identification information on the module 200 coupled to the biosensor measuring apparatus 100 according to an embodiment.

Referring to FIG. 2C, perforation information in which a hole is drilled in a predetermined pattern may be displayed on one surface of the module 200 coupled to the biosensor measuring device 100. The fabric process beam may be formed differently in size or position by a user's setting. When the module 200 displaying the puncturing information is combined, the module identification unit 120 scans the position and size of the puncturing by using the optical scanner and outputs it to the controller 140. The controller 140 finds module information corresponding to the puncturing information stored in the memory 130. Accordingly, it is possible to more accurately grasp the type of the module 200 to be coupled.

In addition, the electrode 400 is formed on the surface where the puncture information is not displayed, and may be supplied with power or supply power from the biosensor measuring device 100, and may perform data communication with the biosensor measuring device 100. The module identification unit 120 finds the resistance value inside the module 200 through the electrode 400 and primarily recognizes the module 200, and finds out the puncture information to secondarily recognize the information of the module 200. I can recognize it.

Meanwhile, the electrode 400 formed on the other surface of the module 200 to be coupled may be a protruding electrode 400. This is a form where a part of the surface protrudes in a predetermined pattern. In this case, when coupled to the biosensor measuring device 100, only the protruding portion contacts the electrode 400 of the module identification unit 120. Accordingly, the identification information of the module 200 may be transmitted as well as the power supply through the position of the contacting electrode 400.

On the other hand, the position where the module identification unit 120 is formed may be one side of the biosensor measuring device 100, but is not limited thereto. However, the module identification unit 120 is preferably formed in only one place in the biosensor measuring device 100 as shown in Figure 2a to 2c. This is to simplify the design of the biosensor measuring device 100, 100 by limiting the coupling position of the module 200. The module identification unit 120 may be a USB port or an ear jack port. USB and ear jacks are widely used as connection pins for keyboards and headphones.

2A to 2C, the module identification unit 120 may be formed on the side of the biosensor measuring apparatus 100, and the external module 200 may be integrally inserted into the biosensor measuring apparatus 100. The module identification unit 120 may insert, for example, a communication module 200 such as a memory 130 card or a USB dongle, but is not limited thereto. The inserted module 200 may store biometric information of the biosensor measured by the biosensor measuring device 100 or transmit information to an external server.

In addition, one module identification unit 120 is preferably formed on the side of the biosensor measuring device 100, but is not necessarily limited thereto. If necessary, a plurality of module identification units 120 may be formed on the side of the main body. Other aspects of the shape and position of the module identification unit 120 will be described later with reference to FIGS. 2D to 2F.

FIG. 2D illustrates an example in which a module identification unit 120 is formed on a front surface of the biosensor measuring apparatus 100, and FIG. 2E illustrates a connector 230 of the biosensor measuring apparatus 100 according to an exemplary embodiment. 2f is an exemplary diagram in which the cable 240 is connected to the biosensor measuring apparatus 100 according to an embodiment.

Referring to FIG. 2D, the module identification unit 120 may be a slot 210 formed at the front of the biosensor measuring device 100. The module identification unit 120 may be positioned at the front of the main body, and a slot 210 may be formed at a bottom thereof, and may include a cover 220 that opens and closes the slot 210. However, it is not necessary to include the cover 220. For example, the functional module 200 may be mounted in the slot 210 such as a keypad. In this case, the cover 220 for opening and closing the slot 210 may have a different shape depending on the external module 200.

In the above example, since the functional module 200 is a keypad, it must be able to operate by touching the keypad as an input device. Therefore, the cover 220 for opening and closing the slot 210 may have a hole formed at a position corresponding to the button so that the keypad can be displayed on the outside. Accordingly, even when the user mounts the keypad, which is an input device, into the slot 210 and closes the cover 220, the button portion can still be touched and can be easily operated.

Meanwhile, as another embodiment, the speaker module 200, which is one of the output devices, may be mounted to the module identification unit 120. When the chip-shaped speaker module 200 is mounted in the slot 210 of the module identification unit 120, the slot 210 is closed by the cover 220. In this case, the shape of the cover 220 may be changed in order to hear the sound output from the speaker module 200 well. When the cover 220 is closed, a mesh is formed at a position facing the speaker so that the sound can be heard well from the outside even when the sound is output from the speaker.

In addition, the module identification unit 120 may be formed around the slot 210 in which the battery is mounted on the rear surface of the biosensor measuring device 100. When the functional module 200 is a small module 200 such as a mini SD card, a module identification unit 120 may be formed around the battery to be integrally combined with the biosensor measuring device 100.

2E, the connector 230 may be connected to the module identification unit 120. As described above, it is preferable that a single module identification unit 120 is formed in the biosensor measuring device 100 of the present invention in order to prevent easy design and increase in appearance of the measuring device 100. To this end, one module identification unit 120 may be formed, but there is a limit in that it is used universally according to the type of the functional module 200 to be connected. Therefore, one end may be connected to the module identification unit 120 of the biosensor measuring device 100, and the other end may use a connector 230 connected to the external module 200.

Accordingly, the biosensor measuring apparatus 100 may form one module identification unit 120 to combine various types of functional modules 200. Therefore, the user can purchase only the module 200 desired by the user, and use it by connecting the connector 230. The type of connector 230 may vary, and it is not necessary to form the module identification unit 120 in various places because the connector 230 may be used by connecting several connectors 230 additionally.

Referring to FIG. 2F, the module 200 coupled to the module identification unit 120 may be contacted using the connection cable 240. As described above, the module 200, which may be connected to the biosensor measuring device 100, may be a keyboard, a mouse, etc. having a relatively large size. Therefore, when it is directly connected to the biosensor measuring device 100 may be inconvenient to use. In this case, as shown in FIG. 2D, the connection cable 240 may be used. One end of the connection cable 240 may be connected to the module identification unit 120 to enable power supply and data communication between the module 200 and the biosensor measuring device 100.

The controller 140 may be a microprocessor that controls the overall operation of the biosensor measuring device 100. The controller 140 receives biometric information through the biometric information measuring unit 110 or the memory 130. The value calculated by analyzing the input biometric information may be controlled to be displayed on the display as a numerical value. The controller 140 may receive the information of the connected module 200 from the module identification unit 120. When the corresponding module 200 is the communication module 200, it may be controlled to output the biometric information to the communication module 200 and transmit it to the server. Accordingly, the biometric information can be wirelessly transmitted to a server or the like without connecting the biosensor measuring device 100 to a computer or the like.

Meanwhile, the controller 140 may execute an algorithm capable of processing the biometric information extracted by the biometric information measuring unit 110 according to the type of the module 200 identified by the module identification unit 120. In the memory 130, an execution algorithm of the biosensor measuring device 100 according to the type of the module 200 may be stored. For example, when the keyboard module 200 is connected to the biosensor measuring device 100, the controller 140 may select and execute an algorithm for executing information input from the memory 130. In this case, the information input from the keyboard module 200 may be stored in the memory 130 together with the biometric information.

When the identified module 200 is an input device, the controller 140 may control measurement of biometric information by executing one of algorithms stored in the memory 130 according to the type of the module 200. The input execution algorithm according to each module 200 may be stored in the memory 130, which may be added or deleted by the user.

For example, when the connected module 200 is an optical scanner or an input interface such as a keyboard, additional information about the biosensor unique number, the biosensor manufacturing information, the measurement information, and the like may be obtained therefrom. In this case, the controller 140 may store it in the memory 130 together with the biometric information. Accordingly, the biosensor measuring apparatus 100 may manage information related thereto without connecting the computer.

On the other hand, if the identified module 200 is an output device, the controller 140 executes one of algorithms stored in the memory 130 according to the type of the module 200 to determine the measured biometric information. ) Can be controlled to output. For example, when a speaker is connected to the external module 200, the controller 140 converts the text into voice or selects an algorithm such as generating a notification sound from the output signal generation algorithm stored in the memory 130. Can be output to

On the other hand, if the identified module 200 is connected to a communication module 200, such as a USB mini dongle (dongle), the controller 140 extracts an algorithm for transmitting information from the memory 130 to an external device, the biometric information Can be output to the module 200 together with the transmission signal. When the voice output module 200 is connected, the controller 140 may output the biometric information numerically calculated to the outside through a prestored voice or effect sound. In addition, when the external power supply is connected, it may be controlled to operate the biosensor measuring device 100 by charging the internal battery or by using an external power source.

The output unit 150 basically outputs the biometric information measured by the biometric information measuring unit 110 to be displayed on the display. When the functional module 200 is combined, the type of the combined module 200 is recognized and the information is output. If the module 200 is not recognized, an error message may be output. When the functional module 200 is the output device module 200, the biometric information may be output to the corresponding module 200.

As such, in the biosensor measuring apparatus 100 of the present invention, various functional modules 200 may be mounted in the biosensor measuring apparatus 100. In addition, the type of the module 200 may be recognized and an algorithm associated therewith may be executed. Accordingly, the biosensor measuring device 100 itself may be kept small in size without mounting the module 200 therein. In addition, a user of the portable measuring device 100 may selectively connect various interfaces to the biosensor measuring device 100 to select and use a desired function.

The present invention has been described above with reference to the preferred embodiments described with reference to the drawings, but is not limited thereto. Accordingly, the invention should be construed by the description of the claims, which are intended to cover obvious variations that can be derived from the described embodiments.

100: biosensor measuring device
110: biometric information measuring unit
120: module identification unit
130: memory
140: control unit
150: output unit
200: module
210: slot
220: cover
230: Connector
240: connection cable
300: optical information
400 electrode

Claims (7)

In the biosensor measuring device that can be combined with various functional modules,
A biometric information measuring unit measuring biometric information from the biosensor;
A module identification unit for recognizing a combination of the modules and identifying the type thereof;
And a controller for controlling the biometric information measuring unit and the module identification unit. The method of claim 1,
The module identification unit,
A biosensor measuring device for identifying the type of the module by using the resistance value of the coupled module. The method of claim 1,
The module identification unit,
A biosensor measuring device for identifying the type of the module using the optical information of the module to be combined. The method of claim 3,
The optical information,
Biosensor measuring device comprising at least one of color information, bar code information, perforation arrangement information displayed on the module to be coupled. According to claim 1, wherein the biosensor measuring device
A memory in which one or more algorithms are stored;
And the controller controls the identified module to output the measured biometric information to the identified module or to receive information associated with the biometric information therefrom using an algorithm stored in the memory. The method of claim 1,
The control unit,
If the identified module is an input device, one of the algorithms stored in the memory is executed to control measurement of the biometric information, or if the identified module is an output device, the measured biometric is executed by executing one of the algorithms stored in the memory. Biosensor for controlling output to the identified module or generating a transmission signal for transmitting the measured biometric information to an external device by executing one of algorithms stored in the memory when the identified module is a communication device. Measuring instrument. The method according to any one of claims 1 to 6,
The biosensor measuring device,
A slot formed on a bottom surface of the main body of the biosensor measuring device to accommodate an external module; And
And an opening formed in correspondence to an input / output portion of an external module accommodated in the slot, and a cover configured to open and close the slot.

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