KR101146288B1 - Automatic calibration device, automatic calibration method and recording medium recording program of automatic calibrating method - Google Patents

Abstract

The present invention automatically establishes a connection between a standard to be calibrated with a measuring instrument and a standard signal that is delivered to the measuring instrument according to a communication method provided by the measuring instrument and the standard, and the standard is used in a standard using a procedure composed of control commands. Automatic calibration device, automatic calibration method, and automatic calibration to automatically control the standard signals generated, to receive measurement results from the instrument and to automatically store or pass calibration results including the measurement results to a connected server and to output the calibration results A program recording medium recording the method.
According to the present invention as described above, there is an advantage to secure the objective data reliable the calibration results, and to significantly shorten the calibration time and has the advantage of efficient management of information for each instrument or calibrator

Description

AUTOMATIC CALIBRATION DEVICE, AUTOMATIC CALIBRATION METHOD AND RECORDING MEDIUM RECORDING PROGRAM OF AUTOMATIC CALIBRATING METHOD}

The present invention relates to an automatic calibration apparatus, a program recording medium recording an automatic calibration method and an automatic calibration method. More particularly, the measuring instrument and the standard apparatus provide a standard for generating a measurement target and a verified standard signal and transmitting the same to a measurement instrument. It automatically establishes the connection according to the communication method, automatically controls the standard signal generated by the standard using a procedure consisting of control commands, receives measurement results from the instrument, and automatically calibrates the results including the measurement results. The present invention relates to an automatic calibration apparatus, an automatic calibration method, and an automatic calibration method for storing the data, or for transmitting the result of the calibration to a connected server and outputting the calibration result.

In general, a measuring instrument refers to a device in the industrial field that measures (measures) all physical quantities and chemical components such as weight, temperature, electricity, and displacement amount, shape, angle, or position of materials, parts, and products. As an example in the field of electrical and electronics, digital multimeters, oscilloscopes and logic analyzers are examples of instruments.

The instrument uses a standard to generate a verified signal to ensure the accuracy of the information being measured to verify that the information measured by the instrument is accurate, commonly referred to as calibration. Calibration of the instrument may be carried out by the user of the instrument to ensure the accuracy of the instrument, or may be calibrated in accordance with the regulations of the country or relevant organization, and may continue to be used if it is within the scope of the calibration rule. In the case of external use, repair or disposal is common.

FIG. 1 is a diagram illustrating a connection configuration and a calibration method of an existing calibration target measuring instrument and a standard apparatus. Referring to FIG. 1, a cable is connected to a terminal for receiving a measurement signal from a meter and a terminal for outputting a standard signal, which is a signal verified by the standard, by a cable and a calibrator using a button of the standard. When the standard signal is generated and transmitted through the cable, the instrument measures the standard signal and displays the measured result through the display of the instrument. The calibrated results are recorded manually on the record sheet or by using the calibrator's notebook and the records are synthesized to determine whether the calibration is successful.

There are some problems in the existing calibration method as shown in FIG. First, the calibration result may vary according to the skill of the calibrator. For example, if the calibrator is a beginner, the cabling or the operation of the instrument and the standard may be immature, there may be factors that may cause mistakes when writing on the record sheet, and some of the measurement items that must be measured by the instrument. It may miss the device and it may not be possible to correct it correctly. Second, as specified in the international standard ISO 17025, there is a problem that the calibration process takes a long time as the calibration item needs to be measured per instrument, the number of measurements per measurement item becomes complicated, and the calculation method of the calibration result is complicated. . Third, it is necessary to manage objective information such as calibration results for each measuring instrument, but there is a problem that an error occurs or cannot be managed due to manual management.

It is an object of the present invention to solve the problems of the background art as described above. The present invention has been made to solve the above problems, an object of the present invention is to automatically connect to the standard and the communication method provided by the measuring instrument and the standard to generate and deliver the standard signal verified to the measuring instrument and the measurement target Set up the standard, automatically control the standard signal generated by the standard using a procedure consisting of control commands, receive measurement results from the instrument, and automatically store calibration results including the measurement results or forward them to a connected server Program recording media recording the automatic calibration device, automatic calibration method, and automatic calibration method for printing or outputting the data, thereby obtaining reliable objective data of calibration results, reducing calibration time, and managing the calibration results efficiently. There is an object of the invention.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned above can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The present invention for achieving the above object is a standard communication unit for transmitting and receiving standard data including a standard and a control command for generating a standard signal in the standard and the standard signal output to the measurement target instrument and the measuring instrument according to the standard signal Local for storing the instrument communication unit for transmitting and receiving the measurement data including the measurement result from the measuring instrument and the instrument information including the communication method information classified by the instrument type and the standard information including the communication method information classified by the standard type An automatic calibration device including a database and a control unit controlling the automatic calibration device, wherein the control unit sets the communication method of the standard communication unit according to the communication method information of the standard information corresponding to the standard identified by identifying the standard. The instrument And a communication method of the meter communication unit is set according to the communication method information of the meter information corresponding to the meter identified and identified.

In addition, the present invention for achieving the above object, as a measurement object, the step of identifying a measuring instrument for outputting the measurement result and the step of identifying a calibrator for generating a standard signal and output to the measuring instrument and the identified Setting a communication method corresponding to each of the calibrator; transmitting a control command for generating a standard signal to the calibrator; receiving a measurement result measured by the instrument; and receiving a calibration result including the received measurement result. An automatic calibration method is achieved that includes storing and transmitting the calibration results to a server.

Moreover, this invention for achieving the said objective is achieved by the program recording medium which recorded the said automatic calibration method.

According to the present invention as described above, since the calibrator records the calibration result based on the automatically received measurement result without recording the calibration result by manual operation, and has the advantage of ensuring reliable objective data for the calibration result. As the time required for manual operation such as the device operation or recording of the calibrator is reduced, the calibration time can be drastically reduced, and the calibration results can be stored in the server, thereby efficiently managing information by instrument or calibrator. There is an advantage.

In addition, by using the present invention, it is easy to integrate various instruments and various standards in one automatic calibration device, thereby providing an efficient automatic calibration device that does not require a separate program and equipment.

1 is a diagram illustrating a connection configuration and a calibration method between an existing measuring instrument and a standard apparatus.
2 is a diagram illustrating an embodiment of an automatic calibration system in which a meter, a standard, and an automatic calibration device are connected.
3 is a diagram illustrating an example of a block diagram for an automatic calibration device.
4 is a diagram illustrating an example of a configuration module for a control unit in an automatic calibration apparatus.
5 is a flow-chart illustrating the automatic calibration method.
6 is a diagram illustrating an example of a block diagram for a server.

The above objects, features, and advantages will become more apparent from the detailed description given hereinafter with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains may share the technical idea of the present invention. It will be easy to implement. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating an embodiment of an automatic calibration system to which the meter 100, the standard 300, and the automatic calibration device 500 are connected. According to FIG. 2, the automatic calibration system includes an instrument 100, a standard instrument 300, an automatic calibration apparatus 500, and a server 400, and transmits a standard signal output from the standard instrument 300 to the instrument 100. Instrument data transmission / reception means 730 and a standard apparatus for transmitting to or from the instrument 100 between the standard signal transmission means 710 and the instrument 100 and the automatic calibration device 500 or receiving and receiving instrument data received from the instrument 100. Standard data transmission and reception means 750 and automatic calibration device 500 and server 400 for transmitting and receiving the standard data received from the standard 300 or the standard 300 between the 300 and the automatic calibration device 500 And a communication network 770 for transmitting information transmitted and received between the terminals.

In order to configure the automatic calibration system according to FIG. 2, the calibrator 900 uses a standard signal transmission means 710 as an output terminal for outputting a standard signal from the standard apparatus 300 to a signal input terminal of the instrument 100 to be calibrated. To connect. If there are two or more measurement items of the measurement object 100 to be calibrated, the signal input terminals of the measurement device 100 may be the same or different for each measurement item. In other cases, the calibrator 900 may set the input terminal of the meter 100 differently for each measurement item. In addition, the standard signal output from the standard 300 may also use a different output terminal for each measurement item. If the output terminals are different for each measurement item, the calibrator 900 will need to change the connection settings of other output terminals of the standard 300 for each measurement item. In addition, the standard signal transmission means 710 may be a wired or wireless form such as a coaxial cable (eg, BNC cable). When the wireless form is used, it is obvious that the standard signal transmitting means 710 is wireless if the measuring object 100 to be calibrated is a wireless related instrument 100 such as CDMA, Bluetooth, binary CDMA, DMB, or the like. something to do.

The calibrator 900 also sets up a standard data transmission / reception means 750 for connecting between the standard 300 and the automatic calibration device 500. The standard data transmission / reception means 750 is a wired form conforming to standards such as RS232, RS422, RS485, General Purpose Interface Bus (GPIB), Universal Serial Bus (USB), IEEE1394, Wi-Fi, and Bluetooth. Wireless, such as CDMA, binary CDMA, etc. may take the form, which may take various forms according to the communication method of the communication interface provided by the standard 300. If the standard 300 provides various communication schemes, the calibrator 900 may of course select one of them. Connection settings by the calibrator 900 may be set in a specific communication method using a menu of a program provided on an output screen of the automatic calibration device 500. The standard data transmitted / received through the standard data transmitting / receiving means 750 includes a control command transmitted from the automatic calibration device 500 to the standard 300 and standard identification data transmitted from the standard 300 to the automatic calibration device 500. do. The control command conforms to the communication method of the standard data transmission / reception means 750 in the automatic calibration device 500 and is recognized by the standard 300, and outputs a standard signal which is a signal to be measured by the instrument in the standard 300. Or instructions for placing the standard 300 in a particular state. The control command may include information, for example, how many volts of power should be output with an AC power output command that the standard can identify when the standard 300 outputs AC power as a standard signal. Or, for example, through a communication method of the standard data transmission / reception means 750 in the central processing unit (CPU) of the standard 300, such as an initialization command, a waiting command, or a command for canceling the immediately preceding command of the standard 300. It will be provided in one standardized format (e.g., a packet containing OPCODE + OPERAND) that can be recognized in the promised format from the transmitted data. In addition, the standard identification data is identification data for the standard 300 that is transmitted from the standard 300 to the automatic calibration device 500, for example, information stored in the storage device (FLASH, HDD, Register, etc.) of the standard 300 There may be a kind, a model name, a serial number, or a measurement item that the standard 300 can generate as a standard signal. The automatic calibration device 500 may transmit the identification command to the standard 300 by using the same identification command to obtain identification data. If the automatic calibration device 500 uses a different type of command for each standard, the automatic calibration device 500 may be used. Transmits commands of different formats sequentially using different types of commands recognizable for all recognizable standards 300 and receives results from standard 300 and identifies data from standard 300 if valid information is present. You can also get. The type of the standard 300 may mean that it is classified based on the manufacturer producing the standard 300, or classified according to the function of the standard 300, or classified according to the model name, or the standard 300 ) May mean classified according to objective criteria that can be classified.

The calibrator 900 also connects and sets the instrument data transmission / reception means 730 that connects the instrument 100 and the automatic calibration device 500. The instrument data transmission / reception means 730 is a wired form conforming to standards such as RS232, RS422, RS485, General Purpose Interface Bus (GPIB), Universal Serial Bus (USB), IEEE1394, Wi-Fi, and Bluetooth. Wireless, such as CDMA, binary CDMA, etc. may take the form, which may take a variety of forms depending on the communication method provided by the instrument (100). If the instrument 100 provides more than one communication scheme, the calibrator 900 may of course select one of them. Connection settings by the calibrator 900 may be set in a specific communication method using a menu of a program provided on an output screen of the automatic calibration device 500. Data transmitted and received through the instrument data transmission / reception means 730 includes measurement results for standard signals transmitted from the instrument 100 to the automatic calibration device 500 and identification of the instrument transmitted from the instrument 100 to the automatic calibration device 500. Contains data. The measurement result indicates that the measurement instrument 100 that received the standard signal output from the standard instrument 300 measures the standard signal in the instrument 100 and measures the result. For example, the measurement results vary depending on the items that can be measured by the measuring instrument 100. When the measuring apparatus 100 is a multimeter, the measuring result includes an AC power measuring result, a DC power measuring result, a resistance measuring result, and the like. Will be. In addition, the instrument identification data is identification data for the instrument 100 transmitted from the instrument 100 to the automatic calibration device 500, and is, for example, information stored in storage devices (FLASH, HDD, Register, etc.) of the instrument 100. There may be a kind, a model name, a serial number, a measurement item that the measurement device 100 can measure, or the like. In order to obtain the instrument identification data, the automatic calibration device 500 uses the same identification command that all the instruments 100 can recognize using the communication method of the instrument data transmission / reception means 730 to identify the instrument 100 with the identification command. If a different type of command is used for each of the instruments 100, the automatic calibration device 500 may sequentially use different types of commands recognizable for all the instruments 100 that can be recognized. It is also possible to send a command of and receive results from the instrument 100 and obtain identification data if valid information is present. The type of the measuring instrument 100 may mean classified based on the manufacturer producing the measuring instrument 100 or classified according to the role of the measuring instrument 100 or classified according to a model name or measuring instrument ( 100 may be classified according to the objective criteria for classifying.

The instrument 100 to be calibrated receives the standard signal output from the standard machine 300, measures the corresponding standard signal, and transmits the measured result to the automatic calibration device 500 as a measurement result. The meter 100 includes an input terminal for receiving a standard signal from the standard 300, and may include one or more input terminals according to the number (type) of the measurement items of the meter 100, and also the meter 100 ) Includes a communication interface that supports a particular communication scheme and is coupled to the instrument data transmission and reception means 730. The meter 100 may measure one or more measurement items. In the case of a digital multimeter, an example of a measuring instrument, six measurement items, for example, AC power, DC power, AC current, DC current, resistance value, and frequency can be measured. For the AC power supply, for example, within the range of 100 mV to 1000 V, for example, six power sources, which are predetermined in the range of 100 mV to 1000 V, are output to the digital multimeter as standard signals, and the digital multimeter is inputted from the input terminal. The measured power is measured and the measurement result is output through, for example, the RS232C port, which is the instrument data transmission / reception means 730. In addition, the measurement may be performed several times for the same power supply, and the measurement result measured several times may be transmitted to the automatic calibration device 500. The meter 100 may also include a register in a central processing unit that controls the meter 100, a type of the meter 100 stored in a storage unit such as a flash or a hard disk mounted on the meter 100, The model name, serial number, measurement item information, etc. are automatically sent to the automatic calibration apparatus 500 according to an identification command received from the automatic calibration apparatus 500 through the instrument data transmission / reception means 730 or when the instrument 100 is booted. I can deliver it.

The standard 300 receives a control command from the automatic calibration device 500 through the standard data transmission / reception means 750, and outputs an output terminal of the standard signal of the standard 300 according to the received control command, for example, DC 10. In the case of the V application command, a 10 V DC power supply is output as a standard signal to the output terminal. The control command received from the automatic calibration device 500 is a command for controlling functions that the standard 300 can perform. For example, when the automatic calibration device 500 can output AC power and DC power as a standard signal, Command related to the standard signal output by the standard 300 such as an AC power level setting command, an AC power supply command, an AC power supply stop command and a DC power level setting command, a DC power supply command, or a DC power supply stop command. And, it may include commands related to the setting and confirmation of the state of the standard 300, such as standard initialization command, standard standby command, standard status check command. The control command of the standard 300 is in a promised format between the standard 300 and the automatic calibration device 500. This promised format may be of the same promised format regardless of the type or model of the standard 300, or may be a format defined differently according to the type or model of the standard 300. For example, when the standard 300 and the automatic calibration device 500 use the RS232C communication method, the first 8 bits are allocated as the OPCODE in the format in which the promised format is 16 bits and the two 8 bits are transmitted. The eighth bit may be allocated as OPERAND. In addition, the standard 300 may include a type, model name, and the like of the standard 300 stored in a storage unit such as a register, a flash, or a hard disk in a central processing unit (for example, a CPU) that controls the standard 300. Serial number, measurable item information, etc. are automatically transmitted to the automatic calibration device 500 according to an identification command received from the automatic calibration device 500 through the standard data transmission / reception means 750 or at the time of booting up of the standard 300. Can be.

The server 400 is connected to the automatic calibration device 500 through the communication network 770. The communication network 770 is a communication network accessible through the Internet including a wired communication network or a wireless communication network. The communication network 770 includes a communication network such as a LAN, a WAN, and a PSTN, and the wireless communication network includes a Wi-Fi, The server 400 and the automatic calibration device 500 are connected to each other, including CDMA, 3G, binary-CDMA, Bluetooth, and the like. It is common to have a client-server structure between the server 400 and the automatic calibration device 500 with one or more automatic calibration devices 500 that simultaneously access a server 400 having a fixed IP address. It is also possible to have a structure in which the 400 is dispersed in one or more processes. The server 400 separately configures a DB for each of the types of the measuring instruments 100, the types of the standard instruments, the calibrator or the calibrated inspection instruments 100, and the specific measuring instrument 100 or the specific standard 300 from the connected automatic calibration apparatus 500. In case of receiving a request for information on the information), information about the corresponding measuring device 100 or the standard device 300 is transferred to the automatic calibration device 500, and the measuring device 100 or the standard device 300 is provided to the automatic calibration device 500. Even if there is no direct related information about), it is automatically downloaded and can be calibrated. Also, by calibrator DB 450, after calibrator 900 performs the work, the calibrator 900 It stores the related history, calibration performance, etc., and when the calibration work is completed by the calibrator 900, the automatic calibration device 500 is automatically transferred to the server 400, and the instrument-specific DB 460 is calibrated. Interchange with calibration results for the instrument It contains detailed information, including a history. The server 400 will be described in detail with reference to FIG. 6.

The automatic calibration device 500 is connected to the instrument 100, the standard 300, and the server 400 to generate a standard signal output from the standard 300 by using a control command to the standard 300, and the standard 300. ) And store the calibration result in the automatic calibration device 500 including the measurement result by receiving the measurement result of the standard signal generated by the standard 300 and input to the instrument 100 from the meter 100. Stored in the unit 570 or transmitted to the server 400, and also generates a calibration result from the measurement result and plays a role of outputting so that the calibrator 900 or other users can check. Detailed description of the automatic calibration device 500 will be described in detail below with reference to FIGS. 3 to 5.

3 is a diagram illustrating an example of a block diagram of an automatic calibration device 500. According to FIG. 3, the automatic calibration device 500 includes a standard communication unit 510, a measurement unit communication unit 530, an input unit 560, a server communication unit 540, a display unit 550, a storage unit 570, and a local DB 580. And a controller 520. The control unit 520 controls each of the other blocks, and may be configured from the CPU to the software SW, the hardware, or a combination of hardware and software.

The standard communication unit 510 is a block for communicating in a communication scheme provided by a standard to be used, and is composed of hardware or software or a combination of hardware and software. The standard communication unit 510 may provide a variety of communication methods, and the communication method may include, for example, a wireless method such as Wi-Fi, Bluetooth, CDMA, 3G, GSM, binary CDMA, Zigbee, or RS232. And at least one of wired communication methods such as RS422, RS485, GPIB, USB, and IEEE1394. Of course, other wired and wireless methods besides the wired and wireless examples are included. The standard communication unit 510 transmits a control command to the standard 300 under the control of the controller 520, and receives the standard identification data from the standard 300. In addition to the transmission and reception of the control command and the identification data, the standard communication unit 510 also generates a control signal specific to a communication method such as an ACK signal or a NO-ACK signal corresponding to the communication method to communicate with the standard 300. Will be done. The standard communication unit 510 selects hardware and software for controlling the corresponding hardware according to the communication method selected by the control unit 520. The hardware is generally provided in the form of a chipset, and the software is a device driver capable of driving the chipset and an application program executed on the device driver, and may include, for example, a control program related to UDP or TCP / IP. have. The control unit 520 may manage the control program related to the device driver, and the control unit 520 may communicate with the standard 300 using the control program related to the device driver.

The meter communication unit 530 is a block that communicates by a communication method provided by the meter 100 to be calibrated, and is composed of hardware or software or a combination of hardware and software. The instrument communication unit 530 may provide various communication methods, and the communication method may include, for example, a wireless method such as Wi-Fi, Bluetooth, CDMA, 3G, GSM, binary CDMA, Zigbee, or RS232. And at least one of wired communication methods such as RS422, RS485, GPIB, USB, and IEEE1394. Of course, other wired and wireless systems other than the exemplary wired and wireless systems are included. The instrument communication unit 530 may transmit an identification command to the instrument 100 according to an identification command of the controller 520, receive the instrument identification data from the instrument 100, and measure a standard signal generated by the standard 300. The measurement result is received from the measuring instrument 100. In addition to the transmission and reception of measurement results and identification data, the instrument communication unit 530 may also generate a control signal such as, for example, an ACK signal or a NO-ACK signal, which is specialized according to a communication method, to communicate with the instrument 100. The instrument communication unit 530 selects hardware and software for controlling the hardware according to the communication method of the instrument 100 selected by the controller 520. The hardware is generally provided in the form of a chipset, and the software is a device driver capable of driving the chipset and an application program executed on the device driver, and may include, for example, a control program related to UDP or TCP / IP. have. The control unit 520 may manage the control program related to the device driver, and the control unit 520 may communicate with the instrument 100 using the control program related to the device driver.

The input unit 560 is a block for receiving a command for controlling the automatic calibration apparatus 500 by the calibrator 900 and includes wired or wireless input means such as a keyboard, a mouse, a remote controller, a touch panel, and the like. The command input to the input unit 560 is transmitted to the control unit 520, and the control unit 520 controls the automatic calibration device 500 according to the input command. Examples of the input command include a selection command for selecting a standard to be used by a calibrator, a selection command for selecting a measuring instrument to be calibrated, an output command of a measurement result, and the like, and the controller 520 according to the command presented as an example. Will control the automatic calibration device 500. The input unit 560 may also receive information such as environmental factors such as humidity or temperature at which the automatic calibration device 500 is executed.

The server communication unit 540 is a block provided for communication with the server 400 and performs communication with the server 400 according to a communication method of the communication network 770. The communication method may be wired or wireless, and includes hardware and software capable of controlling the hardware according to the wired or wireless method. For example, if the communication with the server 400 is performed using Ethernet as a wired method, it is possible to control the Ethernet chipset and the Ethernet chipset that can generate Ethernet packets, monitor Ethernet collisions, and send and receive data from the Ethernet. Device drivers, and middleware that can generate TCP packets and UDP packets running on Ethernet. Data transmitted / received by the server communication unit 540 includes standard communication information and standard data including identification data and a communication scheme for the standard 300 that generates a standard signal that can be received from the server 400 at the request of the control unit 520, and calibration. One example would be a communication scheme for a target instrument and an identification data or a calibration result including a measurement result of the instrument 100 to be transmitted to the server 400.

The display unit 550 plays a role of outputting a calibration result including a measurement result received from the measuring instrument 100 to a screen or a file, and a calibration including a measurement result by a calibrator 900 or a user such as an LCD, a CRT monitor, and a TV. It includes a screen for confirming the result or at least one of a file or a form that can be recognized by the server 400 converted to the specific formatted result and other output means.

The storage unit 570 is a program used in the standard communication unit 510, the instrument communication unit 530, the input unit 560, the server communication unit 540, the display unit 550, and the control unit 520 or a temporary process generated in a program execution process. The storage space for storing the information may be at least one of a hard disk, a volatile memory, a nonvolatile memory, and a register. The driving of the controller 520 may be performed by loading and executing a program stored in the storage unit 570 by a central processing unit (eg, a CPU), and the associated program of the selected standard device 300 and the measurement device 100 (for example, The device driver may be stored in the storage unit 570, and may be accessed and driven under the control of the controller 520 in the central processing unit.

The local DB 580 includes a DB 430 classified by an instrument type or a DB 440 classified by an instrument type, and includes other information related to the calibrator 900 and measurement results related to the instrument 100 being calibrated. can do. The local DB 580 may be stored in the storage unit 570, and the method of constructing the DB may be configured by a database management system (DBMS), or classifying a file access method or other information, according to the classification. You can configure it in an accessible way. The DB 430 classified according to the type of meter may be classified according to the function of the meter 100 or according to the model name of the meter 100. The information used for classification may be used as an index to access the corresponding DB and extract stored information or to download and store the DB 430 classified according to the type of instrument from the server 400. The DB 430 classified by the instrument type includes instrument information related to the instrument for each instrument, and includes, for example, a communication method of the instrument, identification data for the instrument, device driver information / software information used in the instrument, and an instrument. It may include information on the measurement item to be measured in the. In addition, the DB 440 classified by the standard type is classified according to the function of the standard 300 or according to the model name of each manufacturer of the standard 300, and accesses the corresponding DB to extract the stored information or the server 400 It is also possible to download and store DB classified by standard type from. The DB 440 classified by standard type includes standard information related to the standard for each standard classified by the type of standard, and the standard information is used in the standard communication method, identification data for the standard, and the standard. It may include a procedure including a device driver information / software information and the measurement items that can be provided by the standard and a control command for controlling the standard.

The controller 520 is configured in the form of a program driven by a central processing unit (eg, a CPU, etc.), or in the form of a hardware or a combination thereof, and includes a standard communication unit 510, a meter communication unit 530, an input unit 560, The server communication unit 540 and the display unit 550 are responsible for controlling each block. A detailed embodiment of the controller 520 will be described in detail with reference to FIGS. 4 and 5.

4 is a diagram illustrating an example of a configuration module for the control unit 520 in the automatic calibration device 500. According to FIG. 4, the controller 520 may include a standard / meter mapping module 521, a procedure receiving module 522, a procedure proceeding module 523, a procedure changing module 524, a measurement result output module 525, and The measurement result transmission module 526 is included.

When the calibrator 900 selects the classification of the standard 300 or the meter 100 through the input unit 560 from the menu displayed on the screen, the standard / meter mapping module 521 selects the corresponding standard or the meter 100. Search the DB 430 by the instrument type or the DB 440 by the standard type of the local DB 580 to extract the standard information or the instrument information corresponding to the selected standard 300 or the instrument 100, and according to the extracted information. The standard communication unit 510 and the measurement unit communication unit 530 are set. In order to set the standard communication unit 510 or the instrument communication unit 530, the communication method included in the standard information or the instrument information is checked, and the device driver or the middleware corresponding to the communication method is extracted and configured to communicate with the standard or the instrument. do. Of course, if necessary in this process, the standard communication unit 510 or the instrument communication unit 530 may be set to communicate with each other, and valid identification data may be further confirmed whether the standard 300 or the meter 100 is received. In addition, the input unit 560 may be automatically selected without selecting the specific standard 300 or the measuring instrument 100. In the case of automatic selection, for example, use of standard data transmission / reception means 750 or instrument data transmission / reception means 730 connected by the calibrator 900 with identification data of all classified standards or instruments in the local DB 580. By transmitting an identification command to the standard 300 or the instrument 100 and comparing the received identification data with the identification data stored in the local DB 580, the standard 300 or the instrument 100 is automatically mapped. You may. If the information of the standard or instrument selected in the local DB 580 does not exist, the controller 520 may of course receive the standard or instrument information from the server 400 and store the information in the local DB 580 and store the stored information. May be used to map the standard 300 or instrument 100.

The procedure receiving module 522 receives a procedure including a control command for controlling the standard 300 from the standard information of the selected standard 300 of the local DB 580. If there is no standard information selected in the local DB 580, the procedure may be received from the standard information of the selected standard 300 from the server 400. The procedure may vary depending on the items to be measured by the measuring instrument 100 and the measuring items of the standard signals that can be generated by the standard 300, and the items to be measured by the standard signals and the measuring instruments provided by the standard 300. In this other case, the procedure stored in the standard information may be configured to have a separate procedure for each instrument, or use the same procedure, provided that the control unit 520 is a measurement target item from the instrument 100. It can also be configured to process the measurement results only for.

The procedure proceeding module 523 controls the standard 300 according to the procedure of proceeding based on the procedure received by the procedure receiving module 522. The procedure may be in the form of a text file, in a standard format such as XML, or in a form recognized by other software. The procedure may include, for example, a control command that can be recognized by the standard 300, a command for the purpose of controlling the progress order of the control unit 520, and the like. The control command for controlling the standard 300 may include, for example, a command for generating or stopping a standard signal that may be generated by the standard 300, or an initialization command that may be recognized by the standard 300. And the like. Commands for the purpose of controlling the order of progress in the control unit 520 include a command to receive measurement results from the instrument 100, a delay command to delay a predetermined time, a condition command (eg, if-else), a notification command ( For example, Sound or display output). The procedure proceeding module 523 determines whether the command is a command for the standard 300 or a command for the controller 520 according to the received procedure by using a parser or the like. In the case of a command, the command is transmitted to the standard 300 through the standard communication unit 510, and a command of a form that can be recognized by the standard 300 is transmitted. Will be in control.

The procedure change module 524 is a module that can change a procedure to be used in a specific standard 300, and can change a procedure from a calibrator 900 or a user input received from the input unit 560. For example, after reading the procedure from the standard information stored in the local DB 580, the control command available in the standard 300 and the command available in the control unit 520 can be calibrated using a pull-down menu or the like. (900) or the like so that the procedure can delete or add unnecessary control commands according to the instrument 100 or the standard 300 in the procedure, or the procedure is a standard 300 or instrument ( Can be tuned to reflect the dependencies of 100). The changed procedure may be stored in the local DB 580 or the server 400.

The measurement result output module 525 outputs a calibration result including the measurement result received from the meter 100. The output calibration result may include a determination result according to a specific rule from the measurement result, such as a pass failure. The calibration result may be output through the display unit 550, or the calibration result may be stored in the local DB 580 or transmitted to the server 400 for storage. The determination result may be determined according to the regulations, for example, according to ISO 17025, a plurality of measurement results of a single measurement item received from the measuring device 100 or including an environmental factor input from the input unit 560. Therefore, the determination result may be determined by averaging a plurality of measurement results for the same measurement item, or may be determined in consideration of environmental factors such as temperature or humidity.

The measurement result transmission module 526 transmits the calibration result to the server 400. In addition to the calibration result, the information transmitted to the server 400 may include the calibrator information or the information on the measurement target.

5 is a flow-chart illustrating the automatic calibration method. Hereinafter, a digital multimeter will be described as an example of a measuring instrument. Digital multimeters generally have six measurement items, which of course may vary from model to model, but the six measurement items will be AC power, DC power, AC current, DC current, resistance values and frequency measurements. . The automatic calibration method goes from S100 (start) to S200 (end). First, the calibrator 900 connects between the automatic calibration device 500, the meter 100, and the standard 300 as necessary. For example, the calibrator 900 connects an input terminal for measuring the AC power of the digital multimeter and an output terminal for the output of the standard signal of the AC power of the standard 300 to measure the AC power. And the communication interface of the standard 300 is connected to the automatic calibration device 500, and also the communication interface of the instrument 100 is connected to the automatic calibration device 500. Of course, it may be physically connected by the calibrator 900, and sometimes the connection operation may be a job through a menu displayed on a screen or the like. Afterwards, the calibrator 900 determines, via the input unit 560, which type of measuring instrument 100 and standard 300, which is the measuring apparatus 100 and the standard 300, by type (classification information-model or function) (S110). )do. Alternatively, instead of determining by the input of the calibrator 900, the measuring apparatus 100 and the standard apparatus 300 may be determined (S110). After the determination of the connected measuring device 100 and the standard 300 is completed, the controller 520 determines whether information related to the determined measuring device 100 exists in the local DB 580. If it exists in the local DB 580, the instrument information including the identification data, the measurement item or communication method, and related software associated with the determined instrument 100 is extracted from the local DB 580 (S120). If it does not exist in the local DB 580, the instrument information is requested to the server 400 and the instrument information is received from the server 400 (S130). Of course, the instrument information received in this process may be stored in the local DB (580).

It also determines whether the determined standard information is in the local DB 580. If it exists in the local DB 580, the standard information including the identification data, the procedure or communication method and the related software related to the determined standard is extracted from the local DB 580 (S140). If it does not exist in the local DB 580, it requests the standard information to the server 400 and receives the standard information from the server 400 (S150). Of course, the standard information received in this process may be stored in the local DB (580). It will be apparent to those skilled in the art that the steps S120 to S150 may be configured to proceed to a flow different from that of FIG. 5.

After determining the standard unit 300 and the measuring unit 100, the controller 100 sets the determined measuring unit 100 and the standard unit 300 to control the standard communication unit 510 and the measuring unit communication unit 530 (S160). . In this step, the control unit 520 loads the software determined in S120 to S150, for example, the device driver and the middleware other than the device driver, from the storage unit 570 so as to control the standard communication unit 510 and the instrument communication unit 530. The controller 520 is set to communicate with the meter 100 and the standard 300 through the meter communication unit 530 and the standard communication unit 510. After setting the meter 100 and the standard 300, it may also be checked by comparing the identification data received through the communication between the meter 100 and the standard 300 to determine whether it is normally set using the determined identification data.

After setting the standard 300 and the measuring instrument 100, the controller 520 loads the procedure determined in S140 or S150 to be used by the controller 520 to control the standard 300 according to the procedure and to measure the measuring instrument ( The calibration result including the measurement result received at 100 is stored in the storage unit 570 or the local DB 580. In the case of a digital multimeter, six items can be measured, and the procedure for the digital multimeter is configured to measure six items. For example, each item includes a control command that can be recognized by the standard 300, and each item is selected between 100 mV and 1000 V, for example, when measuring AC power. For example, it is possible to measure more than once for six specific power sources (eg 100mV, 1V, 10V, 100V, 500V, 1000V). An example of the control command is a standard signal output command for an AC power source in the OPCODE to generate a command form recognizable by the standard 300 through the standard communication unit 510, for example, an OPCODE and an OPERAND command. And OPERAND can be configured with specific power values. The control command in the procedure may provide for the user to select from the form of pseudo code or the form of a menu that the calibrator 900 can identify.

After setting the communication method between the measuring instrument 100 and the standard apparatus 300, the procedure proceeds (S170). For example, in the case of a digital multimeter, a control command to control the standard 300 can be sequentially measured so that six measurement items can be measured sequentially, and a standard signal outputted according to the control command to control the standard 300 is measured. The calibration result, which is input to the 100 and reads the measurement result using a read command for reading the measurement result measured by the measuring instrument 100 through the measuring instrument data transmission / reception means 730, It is stored in the storage unit 570 or the local DB 580. If the standard signal transmission means 710 for the six measurement items is different, that is, if the input terminal of the measuring instrument 100 and the standard signal output terminal of the standard instrument 300 differ by measurement items, the input terminal of the measuring instrument in the procedure And a command to change the standard signal output terminal of the standard device 300 to another terminal may be notified to the calibrator 900. In accordance with this command, the proofer 900 may be notified of the change instruction through a screen or the like, and the change result may be received from the proofer 900 and the subsequent process may be performed according to the procedure.

The controller 520 generates a calibration result based on the received measurement result for each measurement item and transmits the calibration result to the server 400 (S180). Of course, instead of transmitting to the server 400 may be stored only in the local DB 580 or the storage unit 570. The calibration result includes the measurement result and may also include the determination result. The determination result may include information such as a passing rejection to the measuring instrument 100, and the determination result may be determined according to a specific rule or standard from the measurement result measured for each measurement item. In addition, in order to determine the determination result, the determination result may be derived in consideration of environmental factors inputted from the input unit 560, for example, temperature or humidity.

In addition, the controller 520 may output a calibration result including the measurement result according to an instruction through the input unit 560 of the calibrator 900 (S190). It will be apparent to those skilled in the art that the order of S190 and S180 may be changed. According to the format of the output unit, in S190, for example, when the output format is Word / Excel / PowerPoint, etc. of MS, PDF, or HWP of Hangul, the user or proofreader 900 may be selected according to the output format. Is output to be formatted to identify the calibration result.

6 is a diagram illustrating an example of a block diagram for the server 400. According to FIG. 6, the server 400 includes a communication unit 420 for communicating with the automatic calibration device 500, a control unit 410 for controlling the server 400, and DBs 430 ˜ 460. The server 400 may be configured in the form of a server in a client-server structure or a server in a distributed server structure between the automatic proofing apparatus 500, and the request from the automatic proofing apparatus 500 and the connection. Process and store the calibration results in the automatic calibration device 500. In order to enable the connection from the automatic proofing device 500, the format of a program configured to allow access through the web from the automatic proofing device 500 in a format such as HTTP or to use a Java applet or the like. It may be configured to be accessible to the server (400). The communication unit 420 may be configured as a block for communicating with the automatic calibration device 500 through the communication network 770 in one of a wired method and a wireless method. The controller 410 is configured in the form of a program or a hardware form that can be driven by a central processing unit (eg, a CPU) mounted on the server 400 to process a request from the automatic proofing apparatus 500 and to automatically process a request result. It transmits to the calibration device 500, and manages the DB on the server 400. The DB on the server 400 includes a DB by instrument type 430, a DB by standard type 440, a DB by calibrator 450 or a DB by instrument 460.

The meter type DB 430 stores the meter 100 as related information about the instruments classified by the meter function or the model, respectively. Related information about the instrument 100 includes the communication method that can be used in the instrument 100, identification data for identifying the instrument 100, information on measurement items that can be measured in the instrument 100, and the instrument 100 Contains instrument information, including software (eg device drivers, middleware, etc.) When the server 400 receives the instrument information for the specific instrument 100 from the automatic calibration device 500, the server 400 is classified by function or model in the request information received from the DB 430 for each instrument type. Using the information as an index, the instrument 100 will be searched in the instrument type DB 430, and the indexed instrument information will be delivered to the requesting automatic calibration device 500.

The standard type-specific DB 440 stores the standard information 300 and related information about standard standards classified by the standard function or model. Relevant information about the standard 300 includes information on the communication method that can be used in the standard 300, identification data for identifying the standard 300, measurement items for generating a standard signal in the standard 300 and , A procedure including a control command for controlling the standard 300, and standard information including software related to the standard 300. When the server 400 receives the standard information for the specific standard 300 from the automatic calibration device 500, the classification information classified by function or model in the request information received from the DB 440 for each standard type is used as an index. By searching the DB (440) according to the type of standard standard and whether there is the same standard 300, and transmits the standard information for the same standard 300 to the requesting automatic calibration device 500.

The calibrator-specific DB 450 includes calibrator-specific calibration information. The individual calibration information for each calibrator includes identification information and processing status of the calibrator 100 calibrated by each calibrator 900, information such as the number of calibrated instruments for each period, work hours, and the like, and is logged in through the automatic calibration device 500. In such a manner, the server 400 may identify the calibrator 900 and configure the calibrator-specific DB 450 using the login time, the time information on which the calibration result is received, and the calibration result information.

The meter-specific DB 460 is classified and stored for each instrument including the calibration result for the instrument 100 having a calibrated history and a calibration history for which there is no calibration history but registered and subjected to calibration. DB for each instrument 460 stores the calibration result, the calibration cycle, and the next calibration date for each instrument 100, can be configured to facilitate the management of the instrument 100 in the future, automatic calibration device 500 Receive the information including the calibration result generated and forwarded in the), retrieve the instrument 100 from the instrument-specific DB 460 using the identification data as the received information and store the results for the instrument 100 Can be.

 It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings.

100: measuring instrument 300: standard
400: server 410: control unit
420: communication unit 430: DB by type of instrument
440: DB by standard type 450: DB by calibrator (450)
460: DB 500 by measuring instrument: Automatic calibration device
510: standard communication unit 520: control unit
521: standard / instrument mapping module 522: procedure receiving module
523: procedure progress module 524: procedure change module
525: measurement result output module 526: measurement result transmission module
530: instrument communication unit 540: server communication unit
550: display unit 560: input unit
570: storage unit 580: local DB
710: standard signal transmission means 730: instrument data transmission and reception means
750: standard data transmission and reception means 770: communication network
900: Corrector

Claims (11)

As an automatic calibration device,
A standard communication unit for transmitting and receiving standard data including a standard outputting a standard signal to a measuring instrument to be calibrated, and a control command for generating a standard signal in the standard;
An instrument communication unit for transmitting and receiving instrument data including the measurement result in the instrument according to the standard signal with the instrument;
A local database storing standard information including communication method information classified by standard type and measuring device information including communication method information classified by type of instrument; And
It includes a control unit for controlling the automatic calibration device,
The control unit sets the communication method of the standard communication unit according to the communication method information of the standard information corresponding to the standard identified by identifying the standard, and the communication method of the instrument information corresponding to the measuring device identified by identifying the measuring instrument The automatic calibration device, characterized in that for setting the communication method of the measuring instrument communication unit in accordance with the information. The method of claim 1,
The standard data further includes standard equipment identification data generated and transmitted by the standard, the controller identifies the standard according to the standard equipment identification data, and the instrument data further includes instrument identification data generated and transmitted by the instrument. And the control unit identifies the meter in accordance with the meter identification data. The method of claim 1,
Further comprising a server communication unit for communicating with the server,
If the standard information corresponding to the identified standard is present in the local database, the controller extracts communication method information from the standard information of the local database to set the communication method of the standard communication unit, and does not exist in the local database. If not set the communication method from the communication method information of the identified standard received from the server communication unit,
If there is instrument information corresponding to the identified instrument in the local database, communication method information is extracted from instrument information of the local database to set a communication method of the instrument communication unit, and if it is not present in the local database, And a communication method is set from the communication method information of the identified instrument received from the server communication unit. The method of claim 1,
The standard information further includes a procedure including control instructions for controlling the standard, which may perform one or more measurement items with respect to the instrument, or may perform a plurality of measurement items, wherein the controller is configured to perform the procedure. Automated calibration device, characterized in that for controlling the standard in accordance with. The apparatus of claim 4, wherein the control instructions of the procedure are addable or deleteable from the procedure. The method of claim 1,
And a display unit for outputting a calibration result including the measurement result received from the measuring instrument, wherein the control unit outputs the calibration result to the display unit according to the output format of the display unit. , Automatic calibration device. As an automatic calibration method,
Identifying a measuring instrument for outputting the measuring result;
Identifying a calibrator that generates a standard signal and outputs it to the meter;
Establishing a communication scheme corresponding to each of the identified instrument and the identified calibrator;
Sending a control command to the calibrator to generate a standard signal;
Receiving a measurement result measured by the measuring instrument;
Storing a calibration result including the received measurement result; And
And transmitting the calibration result to a server. The method of claim 7, wherein
Identifying the instrument includes receiving instrument identification data from the instrument, and identifying the calibrator includes receiving calibrator identification data from the calibrator, and setting the communication scheme And a communication scheme is set according to the instrument identification data and the calibrator identification data. The method of claim 7, wherein
And the control command is extracted from a procedure comprising control commands to control a standard that can perform one or more measurement items or a plurality of measurement items. The method of claim 7, wherein
The setting of the communication scheme may include receiving communication scheme information corresponding to each of the identified measuring instrument and the identified calibrator from a server. A program recording medium recording an automatic calibration method,
The program
Identifying, as a measurement object, a measuring instrument which outputs the measuring result;
Identifying a calibrator that generates a standard signal and outputs it to the meter;
Establishing a communication scheme corresponding to each of the identified instrument and the identified calibrator;
Sending a control command to the calibrator to generate a standard signal;
Receiving a measurement result measured by the measuring instrument;
Storing a calibration result including the received measurement result; And
And a program recording medium recording the automatic calibration method, the method comprising transmitting the calibration result to a server.

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