WO2023113051A1 - Measuring device stand that can be combined, and control method therefor - Google Patents

Abstract

The present specification discloses a measuring device stand and a control method therefor, which enable a single communication terminal to efficiently control a plurality of measuring devices. The measuring device stand according to the present specification may generate a communication identifier corresponding to the physical location thereof through a physical connection. When a plurality of measuring device stands are connected, one measuring device stand operates in a master mode, with the remaining measuring device stand(s) operating in a slave mode.

Description

Combinable measuring instrument stand and its control method

The present invention relates to a measuring instrument cradle, and more particularly, to a method for controlling a combinable measuring instrument cradle.

The content described in this section merely provides background information on the embodiments described herein and does not necessarily constitute prior art.

With the spread of smart phones, various devices connected to the smart phone through wireless communication are being developed and sold. As a representative example, various devices equipped with a short-range communication module using Bluetooth have been developed.

Depending on the version of the Bluetooth communication module, simultaneous connection is possible up to 1:7 or 1:15. However, if all devices that can actually be connected to one communication terminal are simultaneously connected, communication between the device and the communication terminal may be disconnected. In addition, when a situation requiring additional connection occurs, the existing connection must be released, making efficient wireless connection difficult.

An object of the present specification is to provide a measuring instrument cradle and a control method for controlling a plurality of measuring instruments by one communication terminal.

This specification is not limited to the above-mentioned tasks, and other tasks not mentioned will be clearly understood by those skilled in the art from the description below.

The measuring instrument cradle according to the present specification for solving the above problems is a main body having a first side and a second side facing each other, and a third side and a fourth side facing each other;

at least one communication terminal and a pair of power terminals respectively formed on the first to fourth side surfaces; A pair of power terminals respectively formed on the first side to the fourth side are wired inside the body so that they have the same potential, and a wireless communication module for transmitting and receiving data with an external communication terminal; And when the communication terminals formed on the first side and the third side are not connected to the communication terminals of other measuring instrument holders (hereinafter referred to as 'master mode'), data can be transmitted and received wirelessly with an external communication terminal through the wireless communication module. A cradle control unit that establishes a connection and deactivates the wireless communication module when the communication terminal formed on the first side or the third side is connected to the communication terminal of another measuring instrument cradle (hereinafter referred to as 'slave mode').

According to one embodiment of the present specification, the first side and the second side of the body have a shape corresponding to each other capable of mechanical coupling, and the third side and the fourth side of the body have a shape corresponding to each other capable of mechanical coupling. can have

According to one embodiment of the present specification, a pair of male power terminals and a male communication terminal are formed on the first and third sides, and a pair of female power terminals and female communication are formed on the second and fourth sides. Terminals can be formed.

The measuring device cradle according to the present specification may further include a measuring device connection unit for coupling for data transmission and reception between the measuring device mounted on the main body and the cradle control unit.

The measuring instrument holder according to the present specification may further include a wired communication module that transmits and receives data to and from other measuring instrument holders through at least one communication terminal formed on each of the first to fourth side surfaces.

According to one embodiment of the present specification, the cradle control unit generates a wired communication identifier including a first sub-identifier and a second sub-identifier and allocates it to the wired communication module, and in the master mode, a first reference sub-identifier and a second reference sub-identifier, and in the slave mode, a value of the first sub-identifier is obtained from a wired communication identifier received from another measuring instrument cradle connected through a communication terminal formed on the first side surface in the slave mode. The wired communication identifier is generated by changing the value by a preset difference value, and the value of the second sub-identifier in the wired communication identifier received from the other measuring instrument holder connected through the communication terminal formed on the third side is equal to the preset difference value. The wired communication identifier may be generated by changing.

According to one embodiment of the present specification, the cradle control unit transmits its own wired communication identifier to the connected other measuring device through the wired communication terminal when another measuring instrument cradle is connected to the second side or the fourth side, and When a wired communication identifier is received from another measuring instrument cradle connected to the second or fourth side, in the slave mode, the wired communication identifier is transmitted to another measuring instrument cradle connected to the first or third side through the wired communication terminal. In the master mode, the wired communication identifier may be transmitted to the external communication terminal through the wireless communication terminal.

According to one embodiment of the present specification, when the cradle controller is in the slave mode, the unique identification information of the measuring instrument mounted on the main body is transmitted to another measuring cradle through the wired communication module, and the other measuring instrument cradle through the wired communication module. When there is the unique identification information of another measuring instrument received from the measuring instrument cradle, the unique identification information of the other measuring instrument is controlled to be transmitted to another measuring instrument cradle, and in the master mode, the unique identification information of the measuring instrument mounted on the main body is transmitted. When there is unique identification information of another measuring instrument transmitted to an external communication terminal through the wireless communication module and received from another measuring instrument holder through the wired communication module, the unique identification information of the other measuring instrument is transmitted through the wireless communication module. It can be controlled to be transmitted to an external communication terminal.

According to one embodiment of the present specification, when the cradle controller is in the master mode, it directly processes the received data according to receiver identification information included in the data received from an external communication terminal through the wireless communication module, or Control transmission of the data to another measuring instrument holder through the wire communication module, and in the slave mode, directly process the received data according to receiver identification information included in the data received from the other measuring instrument holder through the wire communication module, or Alternatively, it can be controlled to be transmitted to another measuring instrument holder through the wired communication module.

According to one embodiment of the present specification, when the cradle controller is in the slave mode, the data output from the measuring device mounted on the main body is transmitted to another measuring cradle through the wired communication module, and the other through the wired communication module. When there is data output from another measuring device received from the measuring device cradle, the data output from the other measuring device is controlled to be transmitted to another measuring device cradle, and in the master mode, the data output from the measuring device mounted on the main body is transmitted. When there is data output from another measuring device transmitted to an external communication terminal through the wireless communication module and received from another measuring device holder through the wired communication module, the data output from the other measuring device is transmitted through the wireless communication module. It can be controlled to be transmitted to an external communication terminal.

A measuring instrument cradle control method according to the present specification for solving the above problems is to transmit and receive data with at least one communication terminal and a pair of power terminals respectively formed on the first to fourth sides of the main body, and an external communication terminal. A method for controlling a measuring instrument cradle including a wireless communication module and a cradle control unit, comprising: (a) determining whether the cradle control unit connects communication terminals formed on the first side and the third side with communication terminals of other measuring instrument cradle; (b) executing the master mode when the communication terminal is not connected in the step (a), and executing the slave mode when the communication terminal is connected in the step (a); and (c) when the cradle controller is in the master mode, establishing a connection to wirelessly transmit/receive data with an external communication terminal through the wireless communication module, and deactivating the wireless communication module when in the slave mode; can include

The method for controlling the measuring instrument cradle according to the present specification may further include: (d) generating, by the cradle controller, a wired communication identifier including a first sub-identifier and a second sub-identifier and allocating the wired communication identifier to the wired communication module. .

According to one embodiment of the present specification, when the cradle controller is in the master mode, the step (d) is the step of generating a wired communication identifier including a first reference sub-identifier and a second reference sub-identifier by the cradle controller. and, when the cradle control unit is in the slave mode, in the step (d), the value of the first sub-identifier in the wired communication identifier received by the cradle control unit from another measuring instrument cradle connected through a communication terminal formed on the first side surface. is changed by a preset difference value to generate the wired communication identifier, and the value of the second sub-identifier is set in advance in the wired communication identifier received from another measuring instrument holder connected through the communication terminal formed on the third side. It may be a step of generating the wired communication identifier by changing the wired communication identifier as much as possible.

In the method for controlling the measuring instrument cradle according to the present specification, (e) when the cradle controller connects another measuring instrument cradle to the second side or the fourth side, the wired communication identifier of the cradle controller is transmitted to the other connected measuring device cradle through the wired communication terminal. Transmitting; may further include.

According to one embodiment of the present specification, when the cradle controller is in the master mode, in step (e), when the cradle controller receives a wire communication identifier from another measuring instrument cradle connected to the second side or the fourth side, A step of transmitting a wired communication identifier received from another measuring instrument cradle through the wireless communication module to the external communication terminal, and when the cradle controller is in a slave mode, in the step (e), the cradle controller controls the cradle controller When a wired communication identifier is received from another measuring instrument holder connected to the second or fourth side, the wired communication identifier of the other measuring instrument is sent to another measuring instrument holder connected to the first or third side through the wired communication terminal. It may be a step of transmitting.

In the method for controlling the measuring instrument cradle according to the present specification, when the cradle control unit is in the master mode, (f) the cradle control unit transmits unique identification information of the measuring instrument mounted on the main body to an external communication terminal through the wireless communication module, , controlling to transmit the unique identification information of the other measuring device to an external communication terminal through the wireless communication module when there is the unique identification information of the other measuring device received from the other measuring device holder through the wired communication module; and, when the cradle controller is in the slave mode, (f) the cradle controller transmits unique identification information of the measuring device mounted on the main body to another measuring device cradle through the wired communication module, and the wired communication module The method may further include a step of controlling transmission of the unique identification information of another measuring device to another measuring device cradle when there is unique identification information of another measuring device received from another measuring device cradle through .

In the method for controlling the measuring instrument cradle according to the present specification, when the cradle controller is in the master mode, (g) the cradle controller receives the received data according to receiver identification information included in data received from an external communication terminal through the wireless communication module. Directly processing the measured data or controlling the data to be transmitted to another measuring instrument cradle through the wired communication module, and when the cradle controller is in the slave mode, (g) the cradle controller transmits the wired communication module. It may further include a step of directly processing the received data according to receiver identification information included in data received from other measuring device holders or controlling transmission of the received data to other measuring device holders through the wired communication module.

In the method for controlling the meter cradle according to the present specification, when the cradle control unit is in the master mode, (g') the cradle control unit transmits data output from the meter mounted on the main body to an external communication terminal through the wireless communication module. and controlling to transmit the data output from the other measuring device to an external communication terminal through the wireless communication module when there is data output from another measuring device received from another measuring device holder through the wired communication module. Further comprising, when the cradle controller is in a slave mode, (g') the cradle controller transmits data output from the measuring device mounted on the main body to another measuring device cradle through the wired communication module, and the wired communication module The method may further include a step of controlling transmission of the data output from the other measuring device to another measuring device cradle when there is data output from another measuring device received from another measuring device cradle.

The measuring instrument cradle control method according to the present specification may be implemented in the form of a computer program written to perform each step of the control method in a computer and recorded on a computer-readable recording medium.

Other specific details of the invention are included in the detailed description and drawings.

According to the present specification, it is possible to obtain the same effect as a wireless connection with a plurality of measuring instruments through a wireless connection with one measuring instrument cradle. Accordingly, it is possible to control a plurality of measuring devices through one wireless connection, and to receive measurement values output from the plurality of measuring devices through one wireless connection.

According to another aspect of the present specification, since only one wireless connection is required regardless of the number of measuring devices, there is room for forming another wireless connection in the communication terminal.

According to another aspect of the present specification, various types of connection and expansion are possible to suit the environment of the work site through physical coupling of the measuring instrument cradle.

According to another aspect of the present specification, since the physical location of the measuring device and the logical location in the communication terminal coincide, the possibility of confusion when a user uses multiple measuring devices is reduced.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a reference diagram to aid understanding of a diagnosis system according to the present specification.

2 is a schematic block diagram of a measuring device according to the present specification.

3 is an exemplary view in which the color of the tube is changed.

4 is an exemplary table of interpretation of results according to tube color.

5 is a schematic illustration of a measuring instrument holder according to an embodiment of the present specification.

6 is a block diagram schematically showing the configuration of a measuring instrument holder according to an embodiment of the present specification.

7 is an exemplary view of various combinations of a measuring instrument holder according to an embodiment of the present specification.

8 is an exemplary view of coupling a measuring instrument cradle according to another embodiment of the present specification.

9 is a schematic block diagram of a 3x3 connected measuring device cradle according to an embodiment of the present specification.

10 is an exemplary view of information related to a measuring instrument holder displayed on a display of a communication terminal.

11 is an exemplary view of measuring instrument related information displayed on a display of a communication terminal.

12 is a flowchart related to operation mode selection of a method for controlling a measuring instrument cradle according to the present specification.

13 is a flowchart illustrating the operation of the cradle control unit in the master mode according to the present specification.

14 is a flowchart illustrating the operation of a cradle control unit in a slave mode according to the present specification.

Advantages and features of the invention disclosed herein, and methods for achieving them, will become clear with reference to the detailed description of the following embodiments in conjunction with the accompanying drawings. However, the present specification is not limited to the embodiments disclosed below and may be implemented in a variety of different forms, and only the present embodiments make the disclosure of the present specification complete, and are common in the art to which the present specification belongs. It is provided to fully inform the technical person (hereinafter referred to as 'one skilled in the art') of the scope of the present specification, and the scope of rights of the present specification is only defined by the scope of the claims.

Terms used in this specification are for describing the embodiments and are not intended to limit the scope of the present specification. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" and/or "comprising" does not exclude the presence or addition of one or more other elements other than the recited elements.

Like reference numerals throughout the specification refer to like elements, and “and/or” includes each and every combination of one or more of the recited elements. Although "first", "second", etc. are used to describe various components, these components are not limited by these terms, of course. These terms are only used to distinguish one component from another. Accordingly, it goes without saying that the first element mentioned below may also be the second element within the technical spirit of the present invention.

An element is said to be "connected to" or "coupled to" another element when it is directly connected or coupled to another element or through another element in the middle. Including all cases

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings commonly understood by those skilled in the art to which this specification belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a reference diagram to aid understanding of a diagnosis system according to the present specification.

Referring to FIG. 1 , a diagnosis system 10 according to the present specification may include a measuring device 200 and a communication terminal 300 .

The measuring device 200 is a testing device capable of performing a test on a sample collected from the respiratory tract. The measuring device 200 may be a molecular diagnostic device or an antigen diagnostic device. In this specification, as an example of the measuring device 200, an amplifier capable of performing a test on a sample through a molecular diagnosis method is presented. Molecular diagnosis refers to a method of extracting DNA or RNA from a sample (saliva, blood, etc.) of a person infected with a virus or bacteria through gene amplification technology and then amplifying it to confirm whether or not there is a disease infection. Depending on the gene amplification method, there are various methods such as PCR, RT-PCR, and loop-mediated isothermal amplification (LAMP). In this specification, a novel coronavirus (SARS-CoV-2) gene (S gene, N gene) is sampled from the nasopharynx or nasal cavity of a patient suspected of being infected by a loop-mediated isothermal amplification method (LAMP) will be described as an example of the measuring device 200 that measures whether or not the infection is detected. However, the measuring instrument is not limited to molecular diagnosis or LAMP method by the above example.

A test kit may be required to perform a test on a sample using the measuring device 200 according to the present specification. The test kit refers to tools, reagents, and consumables required for the test, and may be sealed and provided in the pouch 100 .

Referring to FIG. 1 , a swab 110 , a sample tube 120 , a test tube 130 and a control tube 140 can be identified. The swab 110, the sample tube 120, the test tube 130, and the control tube 140 may be manufactured for one-time use by one person. Therefore, for additional inspection and repeated inspection, the swap 110, sample tube 120, test tube 130, and control tube 140 may be provided as new components for each inspection. In addition, the swab 110, the sample tube 120, the test tube 130, and the control tube 140 may be manufactured in a sterile state, sealed in the pouch 100, and distributed.

The swab 110 is a tool (sample collection tool) for a test subject to collect a sample. The length and thickness of the swab 110 may have values suitable for taking samples.

The sample tube 120 may contain a solution for extracting nucleic acids. Specifically, the nucleic acid extraction solution may include a buffer solution, a nonionic surfactant, a cosmotropic salt, and an indicator.

In the nucleic acid extraction solution, the buffer solution may be a Tris-buffer solution. Specifically, the buffer solution may be Tris-HCl of pH 8 to pH 9, or pH 8.3 to pH 8.6. The concentration of the buffer solution may be 1.0 mM to 2 mM.

In the nucleic acid extraction solution, the nonionic surfactant may be a Tween type surfactant. Specifically, the nonionic surfactant may be Tween 20. The concentration of the nonionic surfactant may be 0.05 vol% to 0.5 vol% or 0.07 vol% to 0.2 vol%.

In the nucleic acid extraction solution, the cosmotropic salt may include at least one selected from the group consisting of ammonium sulfate, potassium chloride, and magnesium sulfate. Specifically, the cosmotropic salt may include all of ammonium sulfate, potassium chloride, and magnesium sulfate. At this time, the concentration of the ammonium sulfate may be 5 mM to 20 mM, or 7.5 mM to 15 mM. In addition, the concentration of the potassium chloride may be 20 mM to 100 mM, or 40 mM to 60 mM. Furthermore, the concentration of the magnesium sulfate may be 3 mM to 10 mM, or 4 mM to 8 mM.

In the nucleic acid extraction solution, the indicator may include at least one selected from the group consisting of Cresol RED and Phenol RED, but is not limited thereto, and an appropriate indicator may be used depending on the purpose.

In addition, the nucleic acid extraction solution may further include an additive such as guanidine. When the nucleic acid extraction solution further includes guanidine, its concentration may be 10 mM to 80 mM, or 30 mM to 50 mM.

The test tube 130 and the control tube 140 may include primers for loop-mediated isothermal amplification (LAMP). The primers included in the test tube 130 and the primers included in the control tube 140 are different from each other. The primers included in the test tube 130 are primers capable of amplifying the nucleic acid of a virus to be confirmed for infection, and the primers included in the control tube 140 can amplify nucleic acids that can be collected from a normal person. is a primer

In addition, 0.1 ~ 1uM Primer mix, 32KU / T Bst polymerase, 12.5mU / T RNase inhibitor, 20 ~ 200uM dNTPs, 20ug / T BSA, 1.2ug / T Trehalose , 1.6ug Sample buffer, etc. may be further included.

The measuring instrument 200 communicates with the communication terminal 300 and can perform a test on a specimen. The meter 200 may have a structure in which a lid can be opened and closed, and when the lid is opened, a space capable of accommodating the test tube 130 and the control tube 140 may be formed therein. According to one embodiment of the present specification, the test tube 130 and the control tube 140 may have different shapes (eg, a cylindrical shape and a rectangular cylinder shape) for easy distinction, and the inside of the measuring device 200 Spaces may also be formed to correspond to the shapes of the test tube 130 and the control tube 140 .

Meanwhile, the measuring device 200 may perform a test on a sample using a loop-mediated isothermal amplification (LAMP), and may include components required for the loop-mediated isothermal amplification (LAMP).

2 is a schematic block diagram of a measuring device according to the present specification.

Referring to FIG. 2 , the meter 200 according to the present specification includes a meter control unit 210, a measurement unit 220, a communication unit 230, a display unit 240, a heating unit 250, and a power supply unit 260. can do.

The meter control unit 210 may control a process necessary for performing a test on a specimen using loop-mediated isothermal amplification (LAMP). If the meter control unit 210 can output a signal to control each component included in the meter 200, it is possible to receive a signal from each component and perform necessary processing such as calculation, storage, and processing. .

The measurement unit 220 may serve to measure the test tube 130 and the control tube 140 according to a test procedure for a specimen. As will be described in more detail later, the color of the solution included in the test tube 130 and the control tube 140 may change as the nucleic acid is amplified depending on the presence or absence of the nucleic acid. The measurement unit 220 may measure the colors of the test tube 130 and the control tube 140 and output them as signals to the controller 210 . To this end, the measuring unit 220 may include a spectrum sensor 221 and/or a light source 222 .

The communication unit 230 may serve to transmit and receive data between the measuring device 200 and the communication terminal 300 . The communication unit 230 can perform wired communication and/or wireless communication, and can transmit and receive data according to a preset communication protocol. Preferably, the communication unit 230 may be a short range communication module for short range communication. The short-range communication module includes Bluetooth™, Radio Frequency Identification (RFID), Infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee, Near Field Communication (NFC), and Wireless-Fidelity (Wi-Fi). , Wi-Fi Direct, and wireless USB (Wireless Universal Serial Bus) technology may be used to support short-distance communication.

The display unit 240 may serve to display state information and operation information of the measuring device 200 . The display unit 240 may be two LEDs installed on the outer front of the measuring device 200 . A first LED may display a communication connection state between the measuring instrument 200 and the communication terminal 300. A second LED may display a charging state and a normal operating state of the measuring instrument 200.

The heating unit 250 may serve to heat the test tube 130 and the control tube 140 . The heating unit 250 may be configured as a coil to receive power from the power supply unit 260 by a control signal of the meter control unit 210 and convert it into thermal energy. The coil may have a length and resistance to heat the test tube 130 and the control tube 140 to a preset temperature. According to one embodiment of the present specification, the heating unit 250 may further include a temperature sensor (not shown). The meter control unit 210 may output a signal for controlling the operation of the heating unit 250 according to the temperature signal output from the temperature sensor.

The power supply unit 260 may serve to supply power necessary for the operation of components included in the measuring instrument 200 according to the present specification. To this end, the power supply unit 260 may include a connection terminal 261 and a battery 262 . The battery 262 may be both a primary battery and a secondary battery, and preferably, the battery 262 is a secondary battery. The connection terminal 261 is an interface for connection with an external power supply source (eg, a commercial power grid, a rechargeable battery, etc.). For example, the connection terminal may be configured as a USB input/output terminal. The power supply unit 260 may charge the battery 262 with power applied through the connection terminal 261 . The power charged in the battery 262 may be used to perform the test on the specimen, or power may be received directly from the connection terminal 261 and used.

The communication terminal 300 according to the present specification is a communication terminal capable of transmitting and receiving data, for example, a smart phone, a laptop computer, a digital broadcasting terminal, a PDA (personal digital assistants), a PMP (portable multimedia player) ), navigation, slate PC, tablet PC, ultrabook, wearable device (eg, watch type terminal (smartwatch), glass type terminal (smart glass), HMD) (head mounted display)), etc. The communication terminal 300 according to the present specification may be installed with applications necessary for performing a test on a specimen.

The communication terminal 300 may also include a communication unit for transmitting and receiving data with the communication unit 230 of the measuring instrument 200, and at this time, the communication protocol included in the communication terminal 300 is the communication unit of the measuring instrument 200 ( 230) is the same as the communication protocol. In the present specification, as an example, it will be described that data communication is possible between the measuring device 200 and the communication terminal 300 using Bluetooth™, which is a short-range communication module. Meanwhile, the communication terminal 300 may transmit/receive data between other communication terminals other than the measuring instrument 200 and/or a wireless communication system and/or an external server. The communication unit of the communication terminal 300 may further include a mobile communication module, a wireless Internet module, or a short-distance communication module.

A method for diagnosing whether or not a virus is infected using the measuring device 200 according to the present specification will be described. At this time, it is assumed that the battery included in the measuring instrument 200 is fully charged, and the communication terminal 300 is installed with an application program necessary for performing a test on a specimen.

First, the power can be turned on by pressing the (power) button located on the front of the meter 200. In addition, the measuring device 200 and the communication terminal 300 may be connected by executing an application installed in the communication terminal 300 . At this time, connection refers to a state in which control signals can be transmitted and received or measurement values can be transmitted and received through wireless communication.

Next, the examinee may collect a sample by pushing the swab 110 to the nasopharynx inside the nose. The sampled swab 110 may be put into the sample tube 120 and sufficiently shaken about 20 to 30 times to mix.

Next, the sample tube 120 may be sufficiently shaken to put the mixed sample in a predetermined amount (eg, 50ul) into the test tube 130 and the control tube 140. The test tube 130 and the control tube 140 are installed in the measuring instrument 200, respectively, and the lid of the measuring instrument 200 is closed. When the lid of the measuring instrument 200 is closed, operation may be started at a preset temperature and for a preset time. At this time, the remaining time out of the total time may be displayed on the display screen of the communication terminal 300 .

When a constant preset time elapses, the screen of the communication terminal 300 is switched to a drive completion screen, and a reading result may be displayed on the screen. At this time, the measuring unit 220 of the measuring device 200 may output a signal for color change of the test tube 130 and the control tube 140 . If the signal output from the measuring unit 220 can be stored in the memory 211 of the meter control unit 210, the meter control unit 210 transmits data on the signal stored in the memory 211 to the communication unit ( It can be transmitted to the communication terminal 300 through 230).

The communication terminal 300 may determine the result of infection by using data on the color change of the test tube 130 and the control tube 140 and display the result on the screen.

3 is an exemplary view in which the color of the tube is changed.

Referring to (a) of FIG. 3, the solution in the tube is yellow, and referring to (b) of FIG. 3, it can be seen that the solution in the tube is red. The test tube 130 and the control tube 140 may contain a reagent whose color changes according to pH, and in the example shown in FIG. 3, "yellow" means "positive" containing a nucleic acid to be detected, "Red" may mean "negative" that does not contain a nucleic acid to be detected.

4 is an exemplary table of interpretation of results according to tube color.

Referring to the table of FIG. 4 , when the color of the control tube is measured as yellow, sample extraction was successful, and the LAMP reaction was also performed well, which means that the measurement result is reliable. On the other hand, if the control tube is measured in red, it means that the sample was not extracted well or the LAMP reaction was successful, and the measurement result is unreliable. In this case, a re-inspection may be recommended as an invalid inspection.

On the other hand, if the control tube is yellow and the test tube is yellow, the COVID-19 virus has been detected. That is, the subject may be determined to be infected with the COVID-19 virus. On the other hand, if the control tube is yellow and the test tube is red, no COVID-19 virus has been detected. That is, the subject may be determined to be non-infected with the Corona 19 virus. It is obvious that the color may be variously changed according to the type of reagent included in the test tube 130 and the control tube 140.

In order to measure infection using the diagnosis system according to the present specification, a wireless connection between the measuring device 200 and the communication terminal 300 is required. However, the example described with reference to FIGS. 1 to 4 is a case in which the measuring instrument 200 and the communication terminal 300 exist in a ratio of 1:1. Depending on the use environment, a plurality of measuring instruments 200 may be connected to one communication terminal 300 and used. For example, when testing multiple patients through one communication terminal 300 at a hospital, when testing multiple test subjects through one communication terminal 300 at a company/school/restaurant, etc. am. In this case, a plurality of measuring devices 200 must be wirelessly connected to one communication terminal 300 at the same time. As described above, in this case, the number of simultaneously connectable measuring devices 200 is determined according to the connection specifications of the wireless communication module. In particular, as an expected problem, in a situation where a plurality of measuring devices 200 are connected, a situation in which a user (or a manager of a communication terminal) may be confused as to which tester's sample was put into which measuring device 200 is connected. For example, it is a case where the sample of the second subject is put into the first measuring device and the sample of the first subject is put into the second measuring device. This phenomenon can easily occur when the location of the physical measuring device 200 and the logical location of the measuring device displayed through the application of the communication terminal 300 are different from each other. In such a situation where one communication terminal 300 and a plurality of measuring devices 200 exist, it is difficult to think about how to form a wireless communication connection with the plurality of measuring devices 200 and efficiently control them and prevent the problem of changing samples. need. In order to solve these problems, a measuring instrument holder and a control method thereof according to the present specification will be described with reference to the accompanying drawings.

5 is a schematic illustration of a measuring instrument holder according to an embodiment of the present specification.

Referring to FIG. 5 , a measuring instrument holder 400 and a measuring instrument 200 according to an embodiment of the present specification can be confirmed. Although the body of the measuring instrument holder 400 is illustrated as a rectangle, the shape of the body of the measuring instrument holder 400 according to the present specification is not necessarily limited to a rectangular shape. In addition, although the measuring instrument 200 is shown mounted on the upper surface of the main body, the mounting method is not limited to the illustrated example. The measuring device cradle 400 according to the present specification may include a measuring device connector (not shown) that couples for data transmission and reception between the measuring device 200 mounted on the main body and the cradle control unit. The measuring device connection unit may be a wired connection or a wireless connection. As an example of a wired connection, a connection for data transmission and reception between the measuring instrument cradle 400 and the measuring instrument 200 may be established through the connection terminal 261 of the measuring instrument 200 . As an example of wireless connection, coils for near field communication (NFC) may be formed under the lower surface of the measuring instrument 200 and the upper surface of the measuring instrument cradle 400, respectively. Preferably, power may be supplied to the meter 200 through the meter connection part. Meanwhile, in the present specification, the measuring instrument cradle 400 and the measuring instrument 200 are connected 1:1 through the measuring instrument connection part.

6 is a block diagram schematically showing the configuration of a measuring instrument holder according to an embodiment of the present specification.

Referring to FIG. 6 , the measuring instrument holder 400 according to an embodiment of the present specification may have first and second side surfaces facing each other, and third and fourth side surfaces facing each other. In the present specification, the upper side of the quadrangle is described as the "first side", the lower side as the "second side", the left side as the "third side", and the right side as the "fourth side". At least one communication terminal 412 and 413 and a pair of power terminals 411 and 414 may be formed on the first to fourth side surfaces, respectively. At this time, a wire may be formed inside the main body so that the pair of power terminals respectively formed on the first to fourth side surfaces have the same potential.

According to one embodiment of the present specification, the first side and the second side of the body have a shape corresponding to each other capable of mechanical coupling, and the third side and the fourth side of the body have a shape corresponding to each other capable of mechanical coupling. can have In addition, a pair of male power terminals and a male communication terminal may be formed on the first and third sides, and a pair of female power terminals and a female communication terminal may be formed on the second and fourth sides. In the example shown in FIG. 6 , male terminals are represented by solid lines and female terminals are represented by dotted lines. Therefore, when the plurality of meter holders 400 according to the present specification are physically coupled through the side, power terminals can be connected to enable power supply, and communication terminals can be coupled to enable data communication at the same time.

7 is an exemplary view of various combinations of a measuring instrument holder according to an embodiment of the present specification.

Figure 7 (a) is an example of combining the measuring instrument holder in the horizontal direction through the second side and the fourth side, Figure 7 (b) is an example of combining the measuring instrument holder in the vertical direction through the first side and the third side 7(c) is an example of combining the measuring instrument holder in a “T” shape. As such, the measuring instrument cradle according to the present specification may be arranged in various forms through mechanical coupling of the side.

8 is an exemplary view of coupling a measuring instrument cradle according to another embodiment of the present specification.

Referring to FIG. 8 , it can be seen that nine measuring instrument holders 400 are combined in a 3x3 shape. Hereinafter, in this specification, the operation and control method of the measuring instrument holder 400 will be described through the example shown in FIG. 8 .

Referring back to FIG. 6 , the measuring instrument cradle 400 according to the present specification may include a wireless communication module 420 and a cradle control unit 440 .

The wireless communication module 420 may serve to transmit/receive data with an external communication terminal. The wireless communication module 420 may transmit data according to a control signal of the cradle control unit 440 and transmit the received data to the cradle control unit 440 . Meanwhile, the wireless communication module 420 may be operated by power supplied from the outside through a pair of power terminals formed on the first side or the third side.

The wireless communication module 420 may be a short range communication module for short range communication. The short-range communication module includes Bluetooth™, Radio Frequency Identification (RFID), Infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee, Near Field Communication (NFC), and Wireless-Fidelity (Wi-Fi). , Wi-Fi Direct, and wireless USB (Wireless Universal Serial Bus) technology may be used to support short-distance communication. In the present specification, as an example, it will be described that data communication is possible between the measuring instrument holder 400 and the communication terminal 300 using Bluetooth™, which is a short-range communication module.

The cradle controller 440 may execute the measuring instrument cradle control method according to the present specification through a master mode and a slave mode. The cradle control unit 440 is a processor known in the art to which the present invention pertains, an application-specific integrated circuit (ASIC), other chipsets, logic circuits, registers, communication modems, and data to execute control logic related to a method for controlling a cradle for a measuring instrument. A processing device and the like may be included. In addition, when the above-described control logic is implemented as software, the cradle control unit 440 may be implemented as a set of program modules. At this time, the program module may be stored in the memory and executed by the processor. Meanwhile, the cradle control unit 440 may be operated by power supplied from the outside through a pair of power terminals formed on the first side or the third side.

The measuring instrument holder 400 according to the present specification may further include a wired communication module 430 that transmits and receives data to and from other measuring instrument holders through at least one communication terminal formed on each of the first to fourth side surfaces. The wired communication module 430 may transmit data according to a control signal of the cradle control unit 440 and transmit the received data to the cradle control unit 440 . Meanwhile, the wired communication module 430 may be operated by power supplied from the outside through a pair of power terminals formed on the first side or the third side.

The wired communication module 430 may be a serial communication module or a parallel communication module. The serial communication module may use one of various serial communication protocols known to those skilled in the art, such as Universal Asynchrounous serial Receiver and Transmitter (UART), Inter-Intergrated Circuit (I2C), and Serial Peripheral Interface Bus (SPI). The parallel communication module may use one of a variety of parallel communication protocols known to those skilled in the art, such as RS-232C, RS-422, and RS-458.

The cradle controller 440 may operate in a master mode or a slave mode depending on whether there is another measuring instrument cradle connected thereto. At this time, a method of determining whether the cradle controller 440 should operate in the master mode or the slave mode will be described.

9 is a schematic block diagram of a 3x3 connected measuring device cradle according to an embodiment of the present specification.

Referring to FIG. 9 , as in the embodiment shown in FIG. 8 , it can be seen that nine measuring instrument holders are connected in a 3x3 fashion. And nine measuring instrument holders 400 are (1,1), (1,2), (1,3), (2,1), (2,2), (2,3) according to the position of each measuring instrument holder. ), (3,1), (3,2), and (3,3).

The cradle control unit 440 according to the present specification may operate in the 'master mode' according to the present specification when the communication terminals formed on the first side and the third side are not connected to communication terminals of other measuring instrument cradle. On the other hand, the cradle control unit 440 according to the present specification may operate in a 'slave mode' according to the present specification when the communication terminal formed on the first side or the third side is connected to the communication terminal of another measuring instrument cradle. In the example shown in FIG. 9 , an example in which the power supply 450 is connected to the third side of the measuring instrument holder 400 located at (1,1) is shown. Therefore, the measuring instrument holder 400 located at (1,1) operates in the master mode, and the remaining eight measuring instrument holders 400 operate in the slave mode.

Meanwhile, in the example shown in FIG. 9, in order to describe the measuring instrument holder 400 located at (1,1) as the measuring instrument holder 400 operating in the master mode, the holder control unit 440 has the first side and the second side. 3 When the communication terminal formed on the side is not connected to the communication terminal of the other measuring instrument holder, it has been described as operating in the 'master mode' according to the present specification. However, according to another embodiment, the cradle control unit 440 according to the present specification, when the communication terminals formed on the second side and the fourth side are not connected to the communication terminals of other measuring instrument cradle, 'master mode' according to the present specification may work as In this case, the cradle control unit 440 according to the present specification may operate in a 'slave mode' according to the present specification when the communication terminal formed on the second side or the fourth side is connected to the communication terminal of another measuring instrument cradle.

When in the master mode, the cradle controller 440 may establish a connection through the wireless communication module 420 to wirelessly transmit/receive data with the external communication terminal 300 . On the other hand, the cradle controller 440 may deactivate the wireless communication module 420 in the master mode. Through this, only the (1, 1) measuring instrument holder 400 operating in the master mode among the nine measuring instrument holders establishes a wireless communication connection with the communication terminal 300, and the remaining eight measuring instrument holders 400 have a wireless communication connection. not formed On the other hand, since power terminals of other adjacent meter holders are connected to each other in the nine meter holders 400, power can be supplied to all meter holders 400 through the power supply 450. In addition, on the other hand, since the communication terminals of the other measuring instrument holders adjacent to each other of the nine measuring instrument holders 400 are connected to each other, data can be transmitted and received through the wired communication module 430. That is, the communication terminal 300 can transmit a signal for controlling nine measuring instrument holders 400 through the (1,1) measuring instrument holder 400 operating in master mode, and the control signal is the It can be transmitted through the wired communication module 430. In addition, the measurement value generated by any one measuring device 200 passes through the measuring device cradle 400 connected to the corresponding measuring device 200 to the (1,1) measuring device cradle 400 through the wired communication module of the measuring device cradle 400. and may be transmitted to the communication terminal 300 through the wireless communication module 420 of the (1,1) measuring instrument holder 400.

In order for this operation to be performed smoothly, an identifier for wired communication must be generated when the measuring instrument holders 400 are connected to each other. According to an embodiment of the present specification, the wired communication module 430 may receive and store a unique identifier in advance. According to another embodiment of the present specification, the cradle controller 440 may generate a random value through a random number generator and assign it to the wired communication module 430 as a wired communication identifier. According to another embodiment of the present specification, the cradle controller 440 may generate its own wired communication identifier by referring to the wired communication identifier of another measuring instrument cradle 400 connected therewith.

More specifically, the cradle controller 440 may generate and allocate a wired communication identifier including a first sub-identifier and a second sub-identifier to the wired communication module 430 . In the master mode, the cradle controller 440 may generate a wired communication identifier including a first reference sub-identifier and a second reference sub-identifier. In this example, it is assumed that the first and second reference sub-identifier values are "1" and "1", respectively. Accordingly, the wired communication identifier of the measuring instrument holder 400 located at (1,1) may be “11”. The cradle controller 440 assigns the generated wired communication identifier to the wired communication module 430 and controls the wired communication module 430 to transmit the wired communication identifier through the second or fourth communication terminal. can In the slave mode, the cradle controller 440 may not generate its own wired communication identifier until receiving the wired communication identifier of another measuring instrument cradle 400 through the first or third communication terminal. When in the slave mode, the cradle control unit 440 changes the value of the first sub-identifier in the wired communication identifier received from another measuring instrument cradle connected through the communication terminal formed on the first side by a preset difference value, thereby changing the wired communication identifier. The wired communication identifier may be generated by generating a communication identifier and changing the value of the second sub-identifier by a preset difference value in the wired communication identifier received from the other measuring instrument holder connected through the communication terminal formed on the third side. there is. For example, the measuring instrument cradle 400 located at (2,1) operates in a slave mode, and from the measuring instrument cradle 400 located at (1,1) through a communication terminal formed on the second side surface, a signal of “11” is provided. A wired communication identifier may be received. The cradle controller 440 of the measuring instrument cradle 400 located at (2, 1) may generate a wire communication identifier of "21" by changing the value of the first sub-identifier by a value of "+1". For example, the measuring instrument cradle 400 located at (1,2) operates in a slave mode, and a wired communication identifier of “11” is formed on the fourth side from the measuring instrument cradle 400 located at (1,1). It can be received through the communication terminal. The cradle controller 440 of the measuring instrument cradle 400 located at (1, 2) can generate a wired communication identifier of “12” by changing the value of the second sub-identifier by a preset value of “+1”. The remaining measuring device cradle 400 also operates in slave mode, the measuring device cradle located at (1,3) is "13", the measuring device cradle located at (2,2) is "22", the measuring device cradle located at (2,3) is "23", the measuring device cradle located at (3,1) is "31", the measuring device cradle located at (3,2) is "32", and the measuring device cradle located at (3,3) is "33", respectively wired communication You can create and assign identifiers. In this case, each measuring instrument holder 400 may generate and allocate a wired communication identifier corresponding to a location to which it is physically connected.

Meanwhile, whenever the meter holder 400 is physically connected, a wired communication identifier must be generated, and information on the connected state must be updated in the communication terminal 300 . To this end, the cradle controller 440 may transmit its wired communication identifier to the other connected measuring device through the wired communication terminal when another measuring device cradle is connected to the second side or the fourth side. To this end, for example, the cradle controller 440 may periodically determine whether another measuring instrument cradle is connected to the second side or the fourth side. As another example, the cradle controller 440 is turned on when a power terminal is connected and power is supplied, and transmits wired communication identifier information to another measuring instrument cradle 400 connected to the first side or the third side. can request Thereafter, the cradle controller 440 of the newly connected measuring instrument cradle 400 may transmit the wired communication identifier it generated to the other measuring instrument cradle 400 connected to the first side or the third side. When the cradle controller 440 receives a wired communication identifier from another measuring instrument cradle connected to the second or fourth side in slave mode, the wired communication terminal is sent to another measuring instrument cradle connected to the first or third side. The wired communication identifier may be transmitted through the When the cradle controller 440 receives a wired communication identifier from another measuring instrument cradle connected to the second side or the fourth side in the master mode, the wired communication identifier is sent to the external communication terminal 300 through the wireless communication terminal. can transmit. At this time, the communication terminal 300 can recognize that the new measuring instrument holder 400 is connected through the new wired communication identifier, and can further check the physically connected location through the wired communication identifier.

10 is an exemplary view of information related to a measuring instrument holder displayed on a display of a communication terminal.

Referring to FIG. 10 , it can be seen that information on the measuring instrument holder is displayed on the display of the communication terminal 300 . The measuring device 200 displayed on the screen is related to the example shown in FIG. 9 and may be displayed to coincide with the physical location of each measuring device holder 400 . However, the current state is a state in which the communication terminal 300 receives only information about each measuring instrument holder 400, and information about the measuring instrument 200 mounted on each measuring instrument holder 400 is not yet received. Then, information on which measuring device 200 is mounted on each measuring device holder 400 is required.

To this end, the cradle control unit 440 transmits unique identification information of the measuring instrument 200 mounted on the main body through the communication terminal formed on the first or third side surface through the wired communication module 430 in the slave mode. It can be transferred to other measuring instruments. In addition, when the cradle controller 440 is in the slave mode, when there is unique identification information of another measuring instrument received from another measuring instrument cradle through the wired communication module 430 via a communication terminal formed on the second or fourth side surface , The unique identification information of the other measuring device can be controlled to be transmitted to another measuring device cradle via the communication terminal formed on the first or third side through the wired communication module 430. Through this process, the unique identification information of the measuring instrument 200 can be transmitted to the measuring instrument holder 400 operating in the master mode.

When the cradle controller 440 is in the master mode, it may transmit unique identification information of the measuring device mounted on the main body to the external communication terminal 300 through the wireless communication module 420 . In addition, when the cradle controller 440 is in the master mode, when there is unique identification information of another measuring instrument received from another measuring instrument cradle through the wired communication module 430 via a communication terminal formed on the second or fourth side surface. , The unique identification information of the other measuring device can be controlled to be transmitted to an external communication terminal through the wireless communication module 420. Through this process, unique identification information of all the measuring devices 200 mounted on the interconnected measuring device holder 400 can be transmitted to the communication terminal 300 . Meanwhile, in the process of transmitting the unique identification information of the measuring device, the wired communication identifier of the measuring device cradle is also transmitted, so it is possible to check which measuring device 200 is mounted on which measuring device cradle 400 .

11 is an exemplary diagram of measuring device related information displayed on a display of a communication terminal.

Referring to FIG. 11 , it can be seen that information on a plurality of measuring devices 200 is displayed on the display of the communication terminal 300 . The measuring device 200 displayed on the screen is related to the example shown in FIG. 8 , and may be displayed to coincide with the physical location of each measuring device 200 . Through this, the user can match the physical location with the logical location to prevent accidents in which different samples are put into different measuring devices, and intuitively understand which measuring device is in operation and which is not being used.

From then on, the communication terminal 300 can transmit a control signal for controlling each measuring device 200 through the measuring instrument cradle 400 operating in the master mode, and each measuring device 200 transmits the measured values and the like in the master mode. It can be transmitted to the communication terminal 300 through the operating measuring instrument holder 400.

More specifically, when the cradle control unit 440 is in the master mode, the receiver identification information included in the data received from the external communication terminal 300 through the wireless communication module 420 (wired communication identifier or meter unique identification) information), the received data may be directly processed or controlled to be transmitted to another measuring instrument holder through the wired communication module 430. When the cradle controller 440 is in the slave mode, the received data is determined according to receiver identification information (wired communication identifier or unique identification information of the measuring instrument) included in the data received from other measuring instrument cradle via the wired communication module 430. It can be directly processed or controlled to be transmitted to other measuring instrument holders through the wired communication module 430. In addition, when the cradle controller is in a slave mode, it may transmit data output from the measuring device 200 mounted on the main body to another measuring cradle through the wired communication module 430 . In addition, when the cradle controller is in slave mode and there is data output from another measuring instrument received from another measuring instrument cradle through the wire communication module 430, the data output from the other measuring instrument is transmitted to another measuring instrument cradle. can be controlled to In addition, when the cradle controller is in the master mode, it can transmit data output from the measuring instrument 200 mounted on the main body to an external communication terminal through the wireless communication module 420 . In addition, when the cradle controller is in the master mode, when there is data output from another measuring instrument received from another measuring instrument cradle through the wired communication module 430, the data output from the other measuring instrument is transmitted to the wireless communication module 420. ), it can be controlled to be transmitted to the external communication terminal 300.

Hereinafter, a method for controlling a measuring instrument cradle according to the present specification will be described. The measuring instrument cradle control method according to the present specification corresponds to the control method of the measuring instrument cradle 400 according to the present specification described above. Therefore, in describing the method for controlling the measuring instrument holder according to the present specification, repetitive description of the measuring instrument holder 400 will be omitted.

12 is a flowchart related to operation mode selection of a method for controlling a measuring instrument cradle according to the present specification.

Referring to FIG. 12 , in step S100 , the cradle controller 440 may determine whether the communication terminals formed on the first and third lateral sides are connected to communication terminals of other measuring instrument holders. If other measuring device holders are connected to the first side and the third side ('NO' in S100), the holder controller 440 may execute the master mode (step S200). In step S210, the cradle control unit 440 may establish a connection so that data can be transmitted and received wirelessly with the external communication terminal 300 through the wireless communication module 420. On the other hand, when other measuring device holders are connected to the first side and the third side ('YES' in S100), the holder controller 440 may execute the slave mode (step S300). In step S310, the cradle controller 440 may deactivate the wireless communication module 420. Thereafter, the cradle control unit 440 of each measuring instrument cradle 400 may operate differently according to the master mode or the slave mode.

13 is a flowchart illustrating the operation of the cradle control unit in the master mode according to the present specification.

Referring to FIG. 13 , in step S220, the cradle controller 440 may generate and allocate a wired communication identifier including a first sub-identifier and a second sub-identifier to the wired communication module 430. At this time, since the cradle controller 440 is in master mode, it can generate a wired communication identifier including a first reference sub-identifier and a second reference sub-identifier. In the next step S221, the cradle controller 440 may transmit its wired communication identifier to the external communication terminal 300 through the wireless communication module 420.

In the next step S222, the cradle controller 440 may monitor whether another measuring instrument cradle is connected to the second side or the fourth side. If another measuring device cradle is connected to the second side or the fourth side (“YES” in step S222), the cradle controller 440 may transmit its wired communication identifier to the other connected measuring device through the wired communication terminal. Yes (step S223). In the next step S224, the cradle controller 440 may monitor whether a wired communication identifier is received from another measuring instrument cradle connected to the second side or the fourth side. If the wired communication identifier of the other measuring device cradle is received (“YES” in step S224), the cradle controller 440 transmits the wired communication identifier of the other measuring device to the external communication terminal through the wireless communication module 420. It can be transmitted (step S225).

In the next step S226, the cradle controller 440 may transmit unique identification information of the measuring instrument 200 mounted on the main body to an external communication terminal through the wireless communication module 420. In the next step S227, the cradle controller 440 may monitor whether unique identification information of another measuring device is received from another measuring device cradle through the wired communication module 430. If the unique identification information of the other measuring device is received (“YES” in step S227), the cradle control unit 440 transmits the unique identification information of the other measuring device to the external communication terminal through the wireless communication module 420. It can (step S228).

Thereafter, the cradle control unit 440 directly processes the received data according to the receiver identification information included in the data received from the external communication terminal through the wireless communication module 420 or uses another measuring device through the wired communication module. It can be controlled to transmit to the cradle. In addition, the cradle control unit 440 may transmit data output from a measuring device mounted on the main body to an external communication terminal 300 through the wireless communication module 420 . In addition, when there is data output from another measuring device received from another measuring device cradle through the wired communication module 430, the cradle controller 440 transfers the data output from the other measuring device to the wireless communication module 420. Through this, it can be controlled to be transmitted to the external communication terminal 300.

14 is a flowchart illustrating the operation of a cradle control unit in a slave mode according to the present specification.

Referring to FIG. 14 , in step S320, the cradle controller 440 may generate a wired communication identifier including a first sub-identifier and a second sub-identifier and allocate it to the wired communication module 430. At this time, the cradle controller 440 changes the value of the first sub-identifier in the wired communication identifier received from the other measuring instrument cradle connected through the communication terminal formed on the first side by a preset difference value to obtain the wired communication identifier. The wired communication identifier may be generated by changing the value of the second sub-identifier by a preset difference value in the wired communication identifier received from the other measuring instrument holder connected through the communication terminal formed on the third side. In the next step S321, the cradle control unit 440 may transmit its own wired communication identifier to another measuring instrument cradle 400 through the wired communication module 430 through a communication terminal formed on the first side or the third side.

In the next step S322, the cradle controller 440 may monitor whether another measuring instrument cradle is connected to the second side or the fourth side. If another measuring device cradle is connected to the second side or the fourth side (“YES” in step S322), the cradle controller 440 may transmit its wired communication identifier to the other connected measuring device through the wired communication terminal. Yes (step S323). In the next step S324, the cradle controller 440 may monitor whether a wired communication identifier is received from another measuring instrument cradle connected to the second side or the fourth side. If a wired communication identifier of another measuring instrument holder is received (“YES” in step S324), the holder control unit 440 sends another measuring instrument holder connected to the first side or the third side through the wired communication terminal. A wired communication identifier of another measuring instrument stand may be transmitted (step S325).

In the next step S326, the cradle controller 440 may transmit unique identification information of the measuring instrument 200 mounted on the main body to another measuring instrument cradle through the wired communication module 430. In the next step S327, the cradle controller 440 may monitor whether unique identification information of another measuring device is received from another measuring device cradle through the wired communication module 430. If the unique identification information of another measuring device is received (“YES” in step S327), the cradle controller 440 may transmit the unique identification information of the other measuring device to another measuring device cradle (step S328).

Thereafter, the cradle controller 440 directly processes the received data according to the recipient identification information included in the data received from other measuring instrument cradle through the wire communication module 430 or through the wire communication module 430. It can be transmitted to other measuring devices. In addition, the cradle controller 440 may transmit data output from the measuring device mounted on the main body to another measuring cradle through the wired communication module 430 . In addition, the cradle control unit 440 can transmit the data output from the other measuring device to another measuring device cradle when there is data output from another measuring device received from another measuring device cradle through the wired communication module 430. .

The measuring instrument cradle control method according to the present specification may be implemented in the form of a computer program written in a computer to perform each step of the control method and recorded on a computer-readable recording medium.

The computer program is C / C ++, C #, JAVA, Python, which can be read by a processor (CPU) of the computer through a device interface of the computer so that the computer reads the program and executes the methods implemented in the program. , and may include codes coded in computer languages such as machine language. These codes may include functional codes related to functions defining necessary functions for executing the methods, and include control codes related to execution procedures necessary for the processor of the computer to execute the functions according to a predetermined procedure. can do. In addition, these codes may further include memory reference related code for determining where (address address) of the computer's internal or external memory the additional information or media required for the computer's processor to execute the functions should be referenced. there is. In addition, when the processor of the computer needs to communicate with any other remote computer or server in order to execute the functions, the code uses the computer's communication module to determine how to communicate with any other remote computer or server. It may further include communication-related codes for whether to communicate, what kind of information or media to transmit/receive during communication, and the like.

The storage medium is not a medium that stores data for a short moment, such as a register, cache, or memory, but a medium that stores data semi-permanently and is readable by a device. Specifically, examples of the storage medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, etc., but are not limited thereto. That is, the program may be stored in various recording media on various servers accessible by the computer or various recording media on the user's computer. In addition, the medium may be distributed to computer systems connected through a network, and computer readable codes may be stored in a distributed manner.

Although the embodiments of the present specification have been described with reference to the accompanying drawings, those skilled in the art to which the present specification pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

<Description of codes>

10: Molecular Diagnosis System

100: pouch

110: Swap, sampling tool

120: sample tube

130: test tube

140: control tube

200: meter

210: control unit

211: memory

220: measuring unit

221: camera

222: light source

230: Ministry of Communication

240: display unit

250: heating unit

260: power supply

261: power terminal

262: battery

300: communication terminal

400: measuring instrument stand

420: wireless communication module

430: wired communication module

440: cradle control unit

450: power supply

Claims (20)

1. a main body having first and second side surfaces facing each other, and third and fourth side surfaces facing each other;

   at least one communication terminal and a pair of power terminals respectively formed on the first to fourth side surfaces; A pair of power terminals respectively formed on the first side to the fourth side are wired inside the main body so that they have the same potential,

   A wireless communication module for transmitting and receiving data with an external communication terminal; and

   When the communication terminals formed on the first side and the third side are not connected to the communication terminals of other measuring instrument holders (hereinafter referred to as 'master mode'), they are connected so that data can be transmitted and received wirelessly with an external communication terminal through the wireless communication module. and a cradle control unit for setting and inactivating the wireless communication module when a communication terminal formed on the first side or the third side is connected to a communication terminal of another measuring instrument cradle (hereinafter referred to as 'slave mode').
2. The method of claim 1,

   The first side and the second side of the main body have mutually corresponding shapes capable of mechanical coupling,

   The third side and the fourth side of the body have a measuring instrument holder having a mutually corresponding shape capable of mechanical coupling.
3. The method of claim 1,

   A pair of male power terminals and a male communication terminal are formed on the first side and the third side,

   A meter cradle having a pair of female power terminals and a female communication terminal formed on the second side and the fourth side.
4. The method of claim 1,

   A measuring instrument cradle further comprising: a measuring instrument connection unit for coupling for data transmission and reception between a measuring instrument mounted on the main body and the cradle control unit.
5. The method of claim 1,

   The measuring instrument holder further comprising a wired communication module for transmitting and receiving data to and from other measuring instrument holders through at least one communication terminal formed on each of the first to fourth side surfaces.
6. The method of claim 5,

   The cradle controller generates a wired communication identifier including a first sub-identifier and a second sub-identifier and assigns it to the wired communication module;

   In the master mode, generating a wired communication identifier including a first reference sub-identifier and a second reference sub-identifier;

   In the slave mode, the wire communication identifier is generated by changing a value of a first sub identifier in a wire communication identifier received from another measuring instrument holder connected through a communication terminal formed on the first side by a preset difference value, The measuring instrument cradle for generating the wired communication identifier by changing the value of the second sub-identifier by a preset difference value in the wired communication identifier received from another measuring instrument cradle connected through the communication terminal formed on the third side.
7. The method of claim 6,

   The cradle control unit

   When another meter holder is connected to the second side or the fourth side, transmits its wired communication identifier to the other connected meter through the wired communication terminal;

   When a wired communication identifier is received from another meter cradle connected to the second side or the fourth side,

   In the slave mode, the wired communication identifier is transmitted to another measuring instrument holder connected to the first side or the third side through the wired communication terminal;

   In the master mode, the measuring instrument cradle transmits the wired communication identifier to the external communication terminal through the wireless communication terminal.
8. The method of claim 5,

   The cradle control unit

   In the slave mode, the unique identification information of the measuring device installed in the main body is transmitted to another measuring device cradle through the wired communication module, and there is unique identification information of another measuring device received from the other measuring device cradle through the wired communication module. At this time, control to transmit the unique identification information of the other measuring device to another measuring device holder,

   In the master mode, the unique identification information of the measuring device installed in the main body is transmitted to an external communication terminal through the wireless communication module, and the unique identification information of the other measuring device received from the other measuring device holder through the wired communication module When there is, the measuring instrument cradle controls to transmit the unique identification information of the other measuring instrument to an external communication terminal through the wireless communication module.
9. The method of claim 5,

   The cradle control unit

   In the master mode, the received data is directly processed according to the receiver identification information included in the data received from the external communication terminal through the wireless communication module or controlled to be transmitted to another measuring device holder through the wired communication module. do,

   In the slave mode, the received data is directly processed according to the receiver identification information included in the data received from the other measuring device holder through the wire communication module, or controlled to be transmitted to another measuring device holder through the wire communication module. meter stand.
10. The method of claim 5,

    The cradle control unit

    In the slave mode, the data output from the meter installed in the main body is transmitted to another meter cradle through the wired communication module, and there is data output from another meter received from the other meter cradle through the wired communication module. At this time, control to transmit the data output from the other measuring device to another measuring device holder,

    In the master mode, the data output from the meter installed in the main body is transmitted to an external communication terminal through the wireless communication module, and the data output from another meter received from another meter holder through the wired communication module When present, the measuring instrument cradle controls to transmit the data output from the other measuring instrument to an external communication terminal through the wireless communication module.
11. At least one communication terminal and a pair of power terminals respectively formed on the first to fourth sides of the main body, a wireless communication module for transmitting and receiving data to and from an external communication terminal, and a cradle control unit A method for controlling a measuring instrument cradle,

    (a) determining whether the communication terminals formed on the first side and the third side are connected to communication terminals of other measuring instrument holders by the cradle control unit;

    (b) executing the master mode when the communication terminal is not connected in the step (a), and executing the slave mode when the communication terminal is connected in the step (a); and

    (c) when the cradle controller is in the master mode, establishing a connection to wirelessly transmit/receive data with an external communication terminal through the wireless communication module, and deactivating the wireless communication module when in the slave mode; Measuring instrument cradle control method including.
12. The method of claim 11,

    The meter cradle,

    a meter connection unit for coupling for data transmission and reception between the meter mounted on the main body and the cradle control unit; and

    The method for controlling the measuring instrument holder further comprising a wired communication module for transmitting and receiving data to and from other measuring instrument holders through at least one communication terminal formed on each of the first to fourth side surfaces.
13. The method of claim 12,

    (d) generating, by the cradle controller, a wired communication identifier including a first sub-identifier and a second sub-identifier and allocating the wired communication identifier to the wired communication module;
14. The method of claim 13,

    When the cradle control unit is in master mode,

    In the step (d), the cradle controller generates a wired communication identifier including a first reference sub-identifier and a second reference sub-identifier, and

    When the cradle control unit is in the slave mode,

    In the step (d), the cradle control unit changes the value of the first sub-identifier in the wired communication identifier received from the other measuring instrument cradle connected through the communication terminal formed on the first side by a preset difference value, so that the wired communication Generating an identifier, and generating the wired communication identifier by changing a value of a second sub-identifier in a wired communication identifier received from another measuring instrument holder connected through a communication terminal formed on the third side by a preset difference value. How to control the measuring stand.
15. The method of claim 13,

    (e) the step of the cradle controller transmitting its own wired communication identifier to the connected other measuring cradle through the wired communication terminal when another measuring cradle is connected to the second side or the fourth side; control method.
16. The method of claim 15

    When the cradle control unit is in master mode,

    In the step (e), when the cradle controller receives a wired communication identifier from another measuring instrument cradle connected to the second side or the fourth side, the external communication terminal receives the identifier from another measuring instrument cradle through the wireless communication module. Transmitting a wired communication identifier;

    When the cradle control unit is in slave mode,

    In the step (e), when the cradle controller receives a wired communication identifier from another measuring instrument cradle connected to the second or fourth side, the cradle controller receives another measuring instrument cradle connected to the first or third side. The step of transmitting the wired communication identifier of the other measuring device through the wired communication terminal to the measuring instrument cradle control method.
17. The method of claim 15

    When the cradle control unit is in master mode,

    (f) The cradle controller transmits the unique identification information of the measuring instrument mounted on the main body to an external communication terminal through the wireless communication module, and the unique identification information of the other measuring instrument received from the other measuring instrument cradle through the wired communication module. When there is, controlling to transmit the unique identification information of the other measuring device to an external communication terminal through the wireless communication module; further comprising,

    When the cradle control unit is in the slave mode,

    (f) The cradle controller transmits the unique identification information of the measuring instrument mounted on the main body to another measuring instrument cradle through the wired communication module, and the unique identification information of the other measuring instrument received from the other measuring instrument cradle through the wired communication module When present, controlling the unique identification information of the other measuring device to be transmitted to another measuring device cradle;
18. The method of claim 17

    When the cradle control unit is in master mode,

    (g) The cradle controller directly processes the received data according to the receiver identification information included in the data received from the external communication terminal through the wireless communication module or transmits the received data to another measuring instrument cradle through the wired communication module. Controlling; further comprising,

    When the cradle control unit is in the slave mode,

    (g) Controls the cradle controller to directly process the received data according to the receiver identification information included in the data received from the other measuring cradle through the wired communication module or to transmit the data to another measuring cradle through the wired communication module. A method for controlling a measuring instrument cradle further comprising the step of:
19. The method of claim 17

    When the cradle control unit is in master mode,

    (g') The cradle control unit transmits the data output from the measuring device mounted on the main body to an external communication terminal through the wireless communication module, and outputs data from another measuring device received from another measuring device cradle through the wired communication module. When there is data, controlling to transmit the data output from the other measuring device to an external communication terminal through the wireless communication module; further comprising,

    When the cradle control unit is in slave mode,

    (g') The cradle control unit transmits the data output from the measuring device mounted on the main body to another measuring device cradle through the wired communication module, and the data output from the other measuring device received from the other measuring device cradle through the wired communication module. When there is, controlling the data output from the other measuring device to be transmitted to another measuring device cradle;
20. A computer program written in a computer to perform each step of the control method according to any one of claims 11 to 19 and recorded on a computer-readable recording medium.

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