JP2015125661A - Matrix test device and matrix test control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a matrix test device capable of realizing power saving and improving test efficiency by automatically executing a test and evaluating a test result.SOLUTION: A matrix test device includes: a signal generator 12 outputting a simulation signal for testing to an input point of a test target provided in a plant monitoring system 1; a measuring instrument 13 measuring an output value from the input point of the test target; a signal switcher 11 for connecting the signal generator 12 and the measuring instrument 13 to an input/output points of the test target; and a test control device 14 controlling the signal generator 12, the measuring instrument 13, and the signal switcher 11. The test control device 14 includes an information table 25, a dialog control unit 26, a switch instruction unit 27, a signal generation reader 28, a signal recording unit 29, and an engineering value output unit 30.

Description

  Embodiments described herein relate generally to a matrix testing apparatus for confirming soundness of data delivery in a plant monitoring system.

  In a plant monitoring system for monitoring and controlling a plant such as a power plant, there are a process signal typified by an analog input input from the plant and a process signal typified by an analog output output to the plant, both of which are process input / output (PIO) Data is exchanged via a process input / output device equipped with a substrate.

  When constructing the system, it is necessary to ensure the reliability of the process signal, and a test (generally referred to as a matrix test) is performed to confirm the soundness of data transfer at all input / output points.

  The plant monitoring system is provided with an operating device for control (generally called an operation device) and a process input / output device that exchanges process signals. In the case of an input-side test, a test simulation signal is input from the signal generator to the process input / output device, and the count value output from the process input / output device corresponding to the input simulation signal is calculated. Save it to a maintenance tool built into a personal computer.

  Thereafter, the count value displayed on the maintenance tool is read, and further the EU value (value converted from the count value into the engineering value which is a physical value) displayed on the operation device is read, and this count value, engineering value and signal are read. The input values (voltage values) input from the generator were compared and judged visually, and the test report was edited manually.

  In the case of a test on the output side, an output value (engineering value) as a simulation signal is generated in the operation device, and based on the output value simulated by a measuring instrument typified by a digital multimeter via a process input / output device Outputs the voltage value. Then, the voltage value input to the measuring instrument and the count value displayed on the maintenance tool connected to the process input / output device are read, and the voltage value, count value, and engineering value input from the operation device are compared visually. Judgment was made and the test report was edited manually.

JP 2008-191821 A JP 2010-020603 A Japanese Patent Application Laid-Open No. 08-202442

  Visually compare and judge the output value (voltage value) of the simulated signal as described above, the count value from the process input / output device, and the engineering value detected by the operation device and measuring instrument, and the test report by hand. Editing has been very labor intensive, leading to problems such as misidentification and misoperation.

  In addition, the number of input / output points provided in the plant varies from system to system, but it is very large, thousands of points. Connections between signal generators and measuring instruments and process input / output devices require the connection of numerous connectors and terminal blocks. Is done. Conventionally, these connection portions are manually switched at each input / output measurement point, and a person performs processing such as signal simulation, measurement, and pass / fail judgment. For this reason, it takes a lot of time and personnel to prepare for the test, to collect the test and results, etc., and there is a possibility of reversal due to misoperation, misjudgment, misediting, etc.

  An object of the present embodiment is to provide a matrix testing apparatus that can save labor and improve test accuracy by automatically performing tests and evaluating test results.

The matrix test apparatus of this embodiment has the following configuration.
(1) A signal generator that outputs a test simulation signal to an input point to be tested provided in a plant monitoring system.
(2) A measuring instrument that measures an output value from the input point to be tested.
(3) A signal switching device for connecting the signal generator and the measuring device to an input / output point to be tested.
(4) A test control apparatus for controlling the signal generator, measuring instrument, and signal switcher.

In the present embodiment, the test control apparatus has the following configuration.
(5) An information table in which data relating to input / output points of the plant monitoring system and test conditions for each input / output point are recorded.
(6) An interactive control unit that acquires information from the information table, controls each part of the test control apparatus, and records the test result in the information table.
(7) A switching command unit that outputs a switching command to the signal switch according to an instruction from the dialogue control unit.
(8) A signal generation reading unit that outputs a simulation signal output command to the signal generator in response to an instruction from the dialog control unit, and that reads an output value from the measuring device and notifies the dialog control unit.
(9) An engineering value output unit that outputs a simulated engineering value to an input / output point to be tested in accordance with an instruction from the dialogue control unit.
(10) A signal recording unit that receives the count value and the engineering value output from the input / output point of the test object, and records them in the information table.

The test control apparatus used for the matrix test apparatus as described above is also an aspect of this embodiment.

The block diagram which shows the structure at the time of performing the matrix test of the plant monitoring system by the matrix test apparatus of 1st Embodiment. The block diagram which shows the structure of the matrix test apparatus of 1st Embodiment. The block diagram which shows the flow of the simulation signal in a matrix test. The block diagram which shows the structure of the matrix test apparatus of 2nd Embodiment. The figure which shows an example of the test result book of 2nd Embodiment. The block diagram which shows the structure of the matrix test apparatus of 3rd Embodiment.

[1. First Embodiment]
[1-1. Constitution]
FIG. 1 shows a basic configuration example of a matrix test apparatus 2 according to the first embodiment and a plant monitoring system 1 that is a test target thereof.

(A) Plant monitoring system 1
As shown in FIG. 1, the plant monitoring system 1 includes an operation device 3 responsible for system control and operation, a process input / output device 5, and an Ethernet ( A transmission device 4 representing a registered trademark (hereinafter the same). The transmission device 4 includes connection cables 18 and 19 represented by Ethernet cables.

  The process input / output device 5 mounts process input / output boards (PIO boards) 6 to 9 and performs input / output processing of process input / output signals, and converts an input voltage value into a count value or an engineering value. The CPU is provided for converting the count value and the engineering value into a voltage value. The process input / output device 5 includes a transmission board, and is connected to the transmission apparatus 4 via the transmission board.

  The process input / output boards 6 to 9 are provided with board connection cables 10 using connectors represented by Elko (registered trademark) and MDR. A connector 10a on the plant monitoring apparatus side is provided at the end of the board connecting cable, and a converter 22 is provided in the connector 10a.

  In this embodiment, the process input / output board 6 is used for analog input, the process input / output board 7 is used for digital input, the process input / output board 8 is used for analog output, and the process input / output board 9 is used for digital output.

(B) Matrix test device 2
As shown in FIGS. 1 and 2, the matrix test apparatus 2 includes a signal switch 11, a signal generator 12, a measuring instrument 13, and a test control apparatus 14.

  The signal switch 11 switches test points of process input / output signals in accordance with a switching command from a switching command unit 27 provided in the test control device 14. The signal switch 11 includes a connection terminal for the signal generator 12 and the measuring device 13 and a large number of connection portions for connectors 10b provided on a large number of boards to be tested. A desired board | substrate which a tester desires is selected from many connection parts.

  The signal switch 11 and the process input / output boards 6 to 9 mounted on the plant monitoring system 1 are connected by a test connection cable 10 ′ having a connector 10 b. When the connector 10b of the test connection cable 10 'and the connector 10a provided on the connection cable 10 on the plant monitoring system 1 side are connected, the converter 22 is used when there is a difference in connector type.

  The signal generator 12 is a device typified by a voltage / current generator, and generates a simulation signal (voltage value) for testing in accordance with a command from a signal generation reading unit 28 provided in the test control device 14. The simulation signal is output to the signal switch 11. The measuring device 13 is a device typified by a digital multimeter, and measures an output value (voltage value) from the signal switching device 11 in accordance with a command from the signal generation reading unit 28.

  The signal generator 12, the measuring device 13, and the test control device 14 are switched by a test connection cable 15, and the test control device 14 and the signal switching device 11 are switched by a connection cable 16, respectively. The device 11 is connected by a connection cable 17.

  The test control device 14 is a device mounted on a computer such as a personal computer or a portable terminal, and includes an information table 25, a dialogue control unit 26, a switching command unit 27, a simulation signal generation reading unit 28, a signal recording unit 29, and an engineering value. An output unit 30 is included.

  The information table 25 is created based on an input / output database or the like that the plant monitoring system 1 has. Specifically, as shown in FIG. 5, the information table 25 includes an input / output database 25a and a test information database 25b. Input / output data such as an IO list / I / O summary is recorded in the input / output database 25a. For example, the input / output board ID, input point name, instrument number, input upper / lower limit / unit, output upper / lower limit / unit, sensor type, classification, and the like are recorded in the IO list. In the IO summary, the ID of the input / output board, the name of the engineering value to be measured, the board type, the unit number, the slot number, the relay housing, and the like are recorded.

  The test information database 25b records test conditions at the time of signal input and test conditions at the time of output. The test conditions at the time of signal input (test to input a simulation signal to the PIO board) are the number indicating the board to be tested and the value of the output value to be output from the transmitter. At the time of signal output (output a signal from the PIO board) As the test conditions, the test condition is a number indicating the substrate to be tested and an output value output from the operation device 3 during the output test. Specifically, EU range, terminal, simulated signal (0%) (50%) (100%) value, count value (simulated signal converted into count value in advance when creating database), count value The judgment value is stored.

  The dialogue control unit 26 includes an input device such as a keyboard and a touch panel, and an output device such as a display and a printer. Based on data and commands displayed on the output device, the tester gives a predetermined command to the input device. Based on the command, each part of the matrix test apparatus 2 is controlled.

For example, the dialogue control unit 26 acquires information from the information table 25, and
-Perform various interactive operations, automatic matrix test start processing, signal switching control, signal output control, and the like, and store test results in the information table 25.

More specifically, the dialogue control unit 26 performs the following (1) and (2).
(1) Control of the switching command unit 27, the signal generation reading unit 28, and the signal recording unit 29 based on the input test condition data.
(2) Control of the engineering value output unit 30, the switching command unit 27, the signal generation / reading unit 28, and the signal recording unit 29 based on the output test condition data.

  The switching command unit 27 outputs a switching command for selecting a PIO board to be a test point to the signal switch 11 in response to an instruction from the dialogue control unit 26. In response to an instruction from the dialogue control unit 26, the signal generation reading unit 28 transmits a simulation signal output command to the signal generator 12, or reads the value of the measuring device 13 and notifies the dialogue control unit 26. The signal recording unit 29 records the engineering value and the count value obtained via the transmission device 4 in accordance with a command from the dialogue control unit 26 and notifies the dialogue control unit 26 of them.

  The engineering value output unit 30 generates simulated engineering values for testing and outputs them to the operation device 3 of the plant monitoring system 1. During the output test, the simulated engineering value input to the operation device 3 is stored in the input / output value storage unit 24 of the operation device 3 and output to the process input / output device 5. It is also possible to output the simulated engineering value directly from the engineering value output unit 30 to the process input / output device 5, and the operation device 3 can simply display the simulated engineering value.

[1-2. Action]
The operation of the present embodiment configured as described above will be described with reference to FIGS.

  The matrix test by the apparatus of this embodiment is started when the tester makes a matrix test start request by the dialogue control unit 26 of the test control apparatus 14. As a specific start operation example, it is performed by clicking and selecting a “start” button on the screen with a mouse by an interactive operation. Hereinafter, the input test and the output test will be described separately.

(1) Input test In the input test, the simulation signal output from the signal generator 12 is input to the PIO board. When the PIO board is a volt (V) input, the simulation signal is a voltage value. When there is a range in the engineering value range, the voltage of the simulation signal can be output in three stages of 0%, 50%, and 100% according to the engineering value. The simulation signal voltage of 0% is a simulation signal that will output the lower limit of the engineering value range, and the simulation signal voltage of 100% is a simulation signal that will output the upper limit of the engineering value range.

  When the “input test start” command is input from the examiner to the dialog control unit 26, the dialog control unit 26 extracts data on the conditions of the input test from the information table 25. Next, the dialogue control unit 26 transmits a number indicating the board to be tested regarding the extracted input test condition to the switching command unit 27. The switching command unit 27 outputs a command to the signal switcher 11 to switch the input / output destination of the test signal to the board to be tested. In response to the switching command, the signal switch 11 switches the test point connection of the test connection cable 10 ′.

  After the signal switching is completed, the dialogue control unit 26 transmits a value (for example, a voltage value) of the simulated signal used for the extracted input test to the signal generation reading unit 28. The signal generation / reading unit 28 outputs a command to the signal generator 12 to output the value of the transmitted simulation signal. The signal generator 12 receives the signal output command from the signal generation reading unit 28 and outputs the commanded voltage value as a simulation signal to the test point to which the test connection cable 10 ′ is connected. .

  The simulated signal of the voltage value output from the signal generator 12 is supplied to the process input / output device in which the boards 6 and 7 are mounted, for example, as shown in FIG. 3 via the test connection cable 10 ′ and the board connection cable 10. 5 is input. The simulation signal input to the process input / output device 5 is converted from a voltage value to a count value and an engineering value in the substrates 6 and 7 and transmitted to the operation device 3 via the transmission device 4 to store the input / output value. Stored in area 24.

  That is, since the substrates 6 and 7 operate with the count value, the voltage value input as the simulation signal is converted into the count value by the conversion unit inside the substrate. The converted count value is converted into an engineering value in the process input / output device 5 and output to the operation device 3 and the signal recording unit 29 via the transmission device 4. In this case, the input simulation signal (voltage value) is converted by the CPU of the process input / output device 5 on which the substrates 6 and 7 are mounted, instead of being converted into count values and EU values by the substrates 6 and 7. You can also.

  In this state, the dialogue control unit 26 outputs a command for recording the engineering value and the count value input to the signal recording unit 29 in the signal recording unit 29. In response to this command, the signal recording unit 29 reads the count value acquired from the process input / output device 5 via the transmission device 4 and the engineering value transmitted from the process input / output device 5 to the operation device 3. It is recorded on itself and transmitted to the dialogue control unit 26. The dialogue control unit 26 reflects the transmitted count value, engineering value, and simulated signal value received from the signal generator 12 in the information table 25.

(2) Output test In the output test, an engineering value is output from the operation device 3 to the substrates 8 and 9, and a voltage value generated as a result is measured by the measuring device 13 and read by the signal generation reading unit 28. The count values from 8, 9 are received by the signal recording unit 29, and the test result is determined. In the present embodiment, the engineering value is transmitted from the engineering value output unit 30 provided in the test control device 14 to the operation device 3 of the plant monitoring system 1.

  When the “output test start” command is input to the dialog control unit 26, the dialog control unit 26 extracts data on the conditions of the output test from the information table 25. Next, the dialogue control unit 26 transmits to the switching command unit 27 a number indicating a board for which an output test is performed according to the extracted conditions. The switching command unit 27 outputs a command to the signal switcher 11 to switch the input / output destination of the test signal to the board to be tested. In response to the switching command, the signal switch 11 switches the connection of the test points of the test connection cable 10 ′.

  After the signal switching is completed, the dialogue control unit 26 transmits the extracted engineering value for the output test to the engineering value output unit 30. The engineering value output unit 30 transmits a simulated engineering value to the operation device 3. The simulated engineering value output from the engineering value output unit 30 is stored in the input / output value storage area 24 of the operation device 3 via the transmission device 4 and then the process input / output device on which the process output boards 8 and 9 are mounted. 5 is input. The process input / output device 5 generates a count value based on the received simulated engineering value, and outputs these signals to the signal recording unit 29 of the test control device 14 via the transmission device 4.

  The dialogue control unit 26 outputs a command for recording the engineering value and the count value input to the signal recording unit 29. When the engineering value and the count value are input, the signal recording unit 29 transmits the values to the dialogue control unit 26. The dialogue control unit 26 records the engineering value and the count value transmitted from the signal recording unit 29 in the information table 25.

  At the same time, after the count value generated by the process input / output device 5 is converted into a voltage value, the board connection cable 10, the test connection cable 10 ′ and the signal switch connected to the process output boards 8 and 9 in FIG. 11 to the measuring device 13. When the dialogue control unit 26 instructs the signal generation reading unit 28 to read the signal, the signal generation reading unit 28 receives the instruction, reads the voltage value from the measuring device 13, and notifies the dialogue control unit 26 of the voltage value. The dialogue control unit 26 records the acquired voltage value in the information table 25.

[1-3. effect]
As described above, according to the present embodiment, based on data such as test conditions recorded in the information table 25, the signal switch 11 can be switched to easily select a substrate to be tested. The dialogue control unit 26 can easily output the simulation signal and the engineering value from the signal generator 12 and the engineering value output unit 30 to the PIO board to be tested.

  According to the present embodiment, test results such as count values and engineering values obtained from the plant monitoring system 1 based on the simulation signal output from the test control device 14 are output by the simulation signal generation reading unit 28 and the signal recording unit 29. The data can be read and reflected in the information table 25, and a test at each point of the plant monitoring system can be automatically performed.

  As a result, according to the present embodiment, only the start operation of the automatic matrix test is performed, and the test is automatically performed without any additional human intervention, thereby minimizing personnel and erroneous connection of operators. This eliminates backtracking due to human error such as misjudgment and misediting, and can greatly reduce test time.

  In particular, by controlling the input signal switch 11 according to a command from the switching command unit 27 of the test control device 14, the connection between the signal generator 12 and the measuring device 13 and each board to be tested is switched by remote control. This eliminates the need for a tester to manually switch a large number of test points, greatly improving test efficiency.

  Furthermore, in the present embodiment, since the simulated engineering value is output from the engineering value output unit 30 provided in the test control device 14, an operation for generating the engineering value on the plant monitoring system side during the test becomes unnecessary. There is an advantage that the matrix test can be performed only on the test controller 14 side.

[2. Second Embodiment]
A second embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

[2-1. Constitution]
FIG. 4 shows an example of the configuration of the matrix test apparatus 2 according to the second embodiment of the present invention. In the configuration of the first embodiment shown in FIG. A certificate printing unit 31 for acquiring, determining, editing, and printing the certificate information and a printer 20 for printing the test certificate are added.

[2-2. Action]
In the embodiment of the present embodiment configured as described above, the report printing unit 29 performs a test based on the data in the information table 25 reflecting the result of the matrix test in response to a test report printing request from the dialogue control unit 26. The certificate information is acquired, edited according to the format stored in advance in the score printing unit 29, and automatically output to the printer device 20.

  FIG. 5 is an example of a test result document output as described above. This test report includes the IO unit number, slot number, arrangement line, ID, name of the tested signal, EU range, simulated input signal content (voltage value), and count value (determination value and actual measurement value). ), EU values (actually measured values), determination results, test dates, etc. are output as a list.

  In the present embodiment, it is also possible to output a test report to the plant monitoring system 1 or the printer 20 provided at another location at the request of the operator. In addition, when printing a test report, a data file created in the form of a document creation or spreadsheet software can be read by an electronic file that cannot be altered, such as PDF or TIF, or an electronic file that can be read by general-purpose software. It can be converted into a file and stored in the test controller 14.

[2-3. effect]
In the present embodiment, test report information is automatically collected, determined, edited, and printed in accordance with a format preset in the grade printing unit 29, so that misjudgment, misediting, and the like are compared with manual operations. It eliminates the backtrack due to human error, greatly shortens the test time, and prevents inconsistencies in the test report format by the editor, making it possible to unify.

[3. Third Embodiment]
A third embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment and the second embodiment are denoted by the same reference numerals, and redundant description is omitted.

[3-1. Constitution]
FIG. 6 shows an example of the configuration of the matrix test apparatus 2 according to the third embodiment of the present invention. In order to notify the operator of the completion of the matrix test to the configuration of the second embodiment shown in FIG. A completion notifying unit 30 is added in the control device 14.

[3-2. Action]
As described in the second embodiment, the matrix test is completed when the test of all input / output points is completed and the test report is automatically printed. In the present embodiment, the completion notification unit 30 is completed. Receives a completion notification from the dialogue control unit 26, and notifies the operator of the completion of the matrix test by a completion message or voice. Further, the completion notification unit 30 can display a matrix test result log display, a test report, and the like according to an instruction from the dialogue control unit 26.

[3-3. effect]
According to the present embodiment, notification of the completion of the matrix test or the immediate confirmation of the matrix test result log, the test report, and the like can eliminate the time loss between the next work and shorten the test time.

[4. Other Embodiments]
The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  For example, in the embodiment, the engineering value is input from the engineering value output unit 30 of the test control device 14 to the operation device 3 or the process input / output device 5. It is also possible to store a simulated engineering value for testing in the input / output value storage unit 24 and use it in accordance with an instruction from the matrix testing apparatus 2 to perform an output test.

In the matrix test apparatus 2 according to the present embodiment, as shown in FIG. Is what you do. You may further provide the test apparatus which performs the test about the precision of this matrix test apparatus 2. FIG. That is, an apparatus for performing the following test may be provided.
(a) A test for confirming whether the engineering value instructed by the dialogue control unit 26 is input to the operation device 3.
(b) A test for confirming whether the value of the simulation signal instructed by the dialogue control unit 26 is output from the signal generator 12.
(c) A test for confirming whether or not switching is performed by the signal switch 11 as instructed by the dialogue control unit 26.
By further including a device for testing the accuracy of the matrix test device 2 as described above, the operation device 3, the transmission device 4, the process input / output device 5, and the process input / output substrate 6 which are the test targets of the matrix test device 2 are provided. To 9, the reliability of the test result on the accuracy between the board connection cables 10 is high.

1: plant monitoring system, 2: matrix test device, 3: operation device, 4: transmission device, 5: process input / output device, 6: process input / output substrate (analog input), 7: process input / output substrate (digital input) 8: process input / output board (analog output), 9: process input / output board (digital output), 10: board connection cable, 10 ′: test connection cable, 11: signal switcher, 12: signal generator, 13: Measuring device, 14: Test control device, 15-19: Connection cable for test, 20: Printer device, 22: Converter, 24: Input / output value storage area, 25: Information table, 26: Dialog control unit, 27 : Switching command section, 28: signal generation reading section, 29: signal recording section, 30: engineering value output section, 31: report printing section, 32: completion notification section

Claims (6)

A signal generator that outputs a test simulation signal to an input point to be tested provided in the plant monitoring system;
A measuring instrument for measuring an output value from the input point of the test object;
A signal switch for connecting the signal generator and the measuring device to an input / output point to be tested;
A test control device for controlling the signal generator, measuring instrument and signal switch;
The test control device includes:
Data on input / output points of the plant monitoring system, information table recording test conditions for each input / output point,
An interactive control unit that obtains information from the information table, controls each part of the test control device, and records a test result in the information table;
In response to an instruction from the dialogue control unit, a switching command unit that outputs a switching command to the signal switcher,
In response to an instruction from the dialogue control unit, a signal generation reading unit that outputs an output command of a simulation signal to the signal generator and reads an output value from the measuring device and notifies the dialogue control unit;
According to an instruction from the dialogue control unit, an engineering value output unit that outputs a simulated engineering value to an input / output point to be tested,
A matrix test apparatus comprising: a signal recording unit that receives a count value and an engineering value output from the input / output point to be tested and records the received value in the information table.   The test control device includes an engineering value output unit therein, and the simulated engineering value output from the engineering value output unit of the test control device is input to an operation device or a process input / output device provided in the plant monitoring system. The matrix test apparatus according to claim 1, wherein   The matrix test apparatus according to claim 1, wherein the engineering value output unit provided in the test control apparatus causes the operation apparatus provided in the plant monitoring system to output a simulated engineering value.   The said test control apparatus has a report printing part which prints a test report based on the information recorded on the information table by the test report printing request from a dialogue control part. 4. The matrix test apparatus according to any one of 3 above.     5. The matrix test apparatus according to claim 1, wherein the test control apparatus includes a completion notification unit for notifying an operator of completion of the matrix test. Data on input / output points of the plant monitoring system, information table recording test conditions for each input / output point,
An interactive control unit that acquires information from the information table, controls each part of the test control device, and records a test result in the information table;
In response to an instruction from the dialog control unit, a simulation signal output command is output to a signal generator that outputs a test simulation signal to the test target input point, and an output value from the test target input point is set. A signal generation reading unit that reads the output value of the measuring instrument to be measured and notifies the dialogue control unit;
In response to an instruction from the dialogue control unit, a switching command unit that outputs a switching command to the signal switch for connecting the signal generator and the measuring device to an input / output point to be tested,
In accordance with an instruction from the dialogue control unit, an engineering value output unit that outputs an engineering value to an input / output point to be tested,
A test control apparatus for a matrix test apparatus, comprising: a signal recording unit that receives a count value and an engineering value output from the input / output point to be tested and records the received value in the information table.

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