JP2021149205A - Automatic test device for monitoring and controlling system - Google Patents

Abstract

To further facilitate a test for a monitoring and controlling system.SOLUTION: An automatic test device for a monitoring and controlling system according to this embodiment includes: a control device which monitors and controls an objective device in accordance with the input and output of a signal relative to such an objective device; and a display device that displays a monitoring and controlling screen for monitoring and controlling the objective device. This automatic test device includes a simulation signal transmitting unit, a screen obtaining unit, a corresponding relation obtaining unit, and an abnormality detecting unit. The simulation signal transmitting unit transmits, to the control device, a simulation signal simulating the signal subjected to the test and input from the objective device to the control device. The screen obtaining unit obtains the monitoring and controlling screen from the display device. The corresponding relation obtaining unit obtains the corresponding relation stored in a first storing unit between the signal and the displayed state of the monitoring and controlling screen corresponding to such a signal. The abnormality detecting unit determines whether or not the simulation signal corresponds to the obtained displayed state of the monitoring and controlling screen, thereby detecting the abnormality of the monitoring and controlling system.SELECTED DRAWING: Figure 2

Description

An embodiment of the present invention relates to an automatic test device for a monitoring and control system.

In water and sewage facilities, electrical facilities, etc., a monitoring and control system for monitoring the status of equipment and controlling the equipment is provided. For such a monitoring and control system, a test is performed as to whether or not the equipment can be normally monitored and controlled. For example, there is known a method of inputting a generated simulated signal to a monitoring control system and confirming a change in the monitoring screen due to the simulated signal.

However, when the above method is performed manually, a lot of time and effort is required. In addition, two or more personnel are required for signal input and screen confirmation.

Japanese Unexamined Patent Publication No. 2011-75824

It is an object of the present invention to provide an automatic test device for a monitoring and control system, which can facilitate the testing of the monitoring and control system.

The automatic test device of the monitoring control system according to the present embodiment is a control device that monitors and controls the target device by inputting and receiving signals to and from the target device, and a display device that displays a monitoring control screen for monitoring and controlling the target device. It is an automatic test device of a monitoring control system for testing a monitoring control system having the above, and includes a simulated signal transmission unit, a screen acquisition unit, a correspondence acquisition unit, and an abnormality detection unit. The simulated signal transmission unit transmits a simulated signal simulating the signal of the test target input from the target device to the control device to the control device. The screen acquisition unit acquires the monitoring control screen from the display device. The correspondence acquisition unit acquires the correspondence between the signal stored in the first storage unit in advance and the display state of the monitoring control screen corresponding to the signal. The abnormality detection unit detects an abnormality in the monitoring control system by determining whether or not the simulated signal and the acquired display state of the monitoring control screen correspond to each other.

The block diagram which shows the structure of the monitoring control system and the automatic test apparatus by 1st Embodiment. The block diagram which shows the structure of the automatic test terminal by 1st Embodiment. The figure which shows an example of the monitoring control screen of the monitoring LCD. The figure which shows an example of the monitoring control screen of the monitoring LCD. The flow chart which shows the operation of the automatic test apparatus by 1st Embodiment. The block diagram which shows the structure of the terminal for automatic test by the modification 1. The block diagram which shows the structure of the automatic test terminal by 2nd Embodiment. The figure which shows an example of the monitoring control screen of the monitoring LCD. The figure which shows an example of the monitoring control screen of the monitoring LCD. The flow chart which shows the operation of the automatic test apparatus by 2nd Embodiment. The block diagram which shows the structure of the terminal for automatic test by the modification 2.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings. The present embodiment is not limited to the present invention. The drawings are schematic or conceptual, and the ratio of each part is not always the same as the actual one. In the specification and the drawings, the same elements as those described above with respect to the existing drawings are designated by the same reference numerals, and detailed description thereof will be omitted as appropriate.

(First Embodiment)
FIG. 1 is a block diagram showing a configuration of a monitoring control system 100 and an automatic test device 200 according to the first embodiment. The monitoring and control system 100 monitors and controls the target device 101, for example. The target device 101 is, for example, a device used for water and sewage facilities. However, the present invention is not limited to this, and the target device 101 may be a device used for infrastructure equipment such as electrical equipment. The automatic test device 200 of the monitoring and control system 100 tests the monitoring and control system 100. The test may be performed while the monitoring and control system 100 is in operation or stopped. The automatic test device 200 is portable.

The monitoring control system 100 includes a controller 11, a HUB 12, a monitoring PC (Personal Computer) 13, and a monitoring LCD (Liquid Crystal Display) 14. In the monitoring control system 100, the controller 11, the monitoring PC 13, and the monitoring LCD 14 are provided separately. The HUB 12 may be provided on the controller 11 side, or may be provided on the monitoring PC 13 and the monitoring LCD 14 side.

The controller 11 as a control device monitors and controls the target device 101 by inputting and outputting signals to and from the target device 101. The controller 11 is connected to the target device 101. Further, the controller 11 receives, for example, a signal (monitoring signal) for monitoring the target device 101 from the target device 101. The controller 11 transmits, for example, a signal (control signal) for controlling the target device 101 to the target device 101.

The HUB 12 relays the data transmitted and received by the controller 11 and the monitoring PC 13. Further, the HUB 12 transmits / receives data to / from the automatic test terminal 21 in the automatic test device 200.

The monitoring PC 13 controls to display information and the like necessary for monitoring and controlling the target device 101 on the monitoring LCD 14. Further, the monitoring PC 13 transmits / receives data via the HUB 12.

The monitoring LCD 14 as a display device displays a monitoring control screen for monitoring and controlling the target device 101. The user can check the status of the target device 101 and control the target device 101 through the monitoring control screen. The "display device" may include not only the monitoring LCD 14 but also the monitoring PC 13.

The automatic test device 200 includes an automatic test terminal 21, an automatic test controller 22, and a signal input / output terminal 23. The automatic test device 200 is provided near the controller 11 in the monitoring and control system 100. That is, the automatic test device 200 is separated from the monitoring PC 13 and the monitoring LCD 14.

The automatic test terminal 21 diagnoses the state of the monitoring control system 100, for example. The automatic test terminal 21 is, for example, a personal computer such as a notebook PC. Further, the automatic test terminal 21 is connected to the HUB 12 by a transmission cable. The details of the automatic test terminal 21 will be described later with reference to FIG.

The automatic test controller 22 inputs / outputs a signal to / from the controller 11. The automatic test controller 22 is connected to the signal input / output terminal 23 by a signal input / output cable. Further, the automatic test controller 22 is connected to the automatic test terminal 21 by a transmission cable.

The signal input / output terminal 23 can be connected to a terminal portion such as a controller 11 or a terminal block portion of a panel. This enables input / output of signals between the automatic test controller 22 and the controller 11.

FIG. 2 is a block diagram showing the configuration of the automatic test terminal 21 according to the first embodiment.

The automatic test terminal 21 includes a simulated signal generation unit 211, a simulated signal transmission unit 212, a screen acquisition unit 213, a determination database 214, a correspondence acquisition unit 215, an abnormality detection unit 216, and a result storage control unit 217. A test result storage unit 217a, a display control unit 218, and a display unit 218a are provided.

Each unit 211 to 213 and 215 to 218 in the automatic test terminal 21 may be realized by one CPU (Central Processing Unit) or may be realized by individual CPUs.

The simulated signal generation unit 211 generates a simulated signal that simulates a test target signal (monitoring signal) input from the target device 101 to the controller 11. The monitoring signal is a signal to be tested. The simulated signal generation unit 211 transmits the generated simulated signal to the simulated signal transmission unit 212 and the abnormality detection unit 216.

The simulated signal transmission unit 212 transmits the simulated signal to the controller 11. The simulated signal transmission unit 212 transmits the simulated signal to the controller 11 via, for example, the automatic test controller 22.

The screen acquisition unit 213 acquires the monitoring control screen from the monitoring LCD 14. The screen acquisition unit 213 acquires the monitoring control screen from the monitoring LCD 14 via, for example, the HUB 12. The screen acquisition unit 213 may acquire the monitoring control screen from the monitoring PC 13. The screen acquisition unit 213 transmits the acquired monitoring control screen to the abnormality detection unit 216.

Further, the screen acquisition unit 213 is provided apart from the monitoring PC 13 and the monitoring LCD 14 in the monitoring control system 100. Therefore, the screen acquisition unit 213 remotely acquires the monitoring control screen. Therefore, the automatic test terminal 21 (automatic test device 200) can remotely test the monitoring control system 100.

The determination database 214 as the first storage unit stores in advance the correspondence between the signal and the display state of the monitoring control screen corresponding to the signal. The determination database 214 stores the display state for each signal type (name), for example. The display state includes, for example, symbols, characters, arrangements, messages, and the like. The message is, for example, a message indicating a failure or the like. Further, the display state may include a change in the monitoring control screen due to signal input / output. In this case, the display state includes a change in the shape and color of the symbol, a change in the displayed numerical value, and the like. The correspondence is, for example, a comparison table between the signal content and the display state.

The correspondence acquisition unit 215 acquires the correspondence stored in the determination database 214 in advance. The correspondence acquisition unit 215 transmits the acquired correspondence to the abnormality detection unit 216.

The abnormality detection unit 216 detects an abnormality in the monitoring control system 100 by determining whether or not the simulated signal and the acquired display state of the monitoring control screen correspond to each other based on the correspondence relationship. As a result, the test for determining the abnormality can be automatically performed. As a result, the test of the monitoring control system 100 can be facilitated.

More specifically, the abnormality detection unit 216 monitors the display state corresponding to the simulated signal based on the device information regarding the target device 101 in the monitoring control screen and at least one of the display positions of the device information. Identify from the control screen. The device information includes, for example, characters and figures related to the target device 101. The device information includes, for example, a plant flow display indicating the operation process of the target device 101, a character position, a symbol shape, a message, and the like. For example, when a number is displayed next to a symbol indicating a flow meter in the image, the abnormality detection unit 216 identifies that the displayed number is a flow rate value by, for example, pattern matching or the like. Further, the abnormality detection unit 216 determines whether or not the simulated signal and the specified display state correspond to each other based on the correspondence relationship. The details of abnormality detection will be described later with reference to FIGS. 3 and 4.

Results as a storage control unit The storage control unit 217 stores the detection result of the abnormality detection unit 216 and at least one of the displayed images of the monitoring control screen during the test so as to store the second storage unit (test result storage unit 217a). ) Is controlled. In the following, the detection result of the abnormality detection unit 216 may also be referred to as an “abnormality detection result”. The test result storage unit 217a is provided in, for example, the automatic test terminal 21. The test result storage unit 217a may be provided outside the automatic test terminal 21.

The display control unit 218 controls the display unit 218a so as to display at least one of the abnormality detection result and the display image stored in the test result storage unit 217a. As a result, the content of the test can be reconfirmed after the test is completed. The display unit 218a is provided in, for example, the automatic test terminal 21. The display unit 218a may be provided outside the automatic test terminal 21. Further, the display control unit 218 may display the same contents as the display of the monitoring LCD 14 on the display unit 218a during the test of the monitoring control system 100. That is, the display control unit 218 may display the name of the signal related to the test, the contents such as the type, and the display image on the display unit 218a in real time.

Next, the abnormality determination will be described with reference to FIGS. 3 and 4. Further, the simulated signal includes, for example, a digital input (status display), an analog input (measured value), and a pulse input (integrated value). FIG. 3 shows an abnormality determination regarding digital input and analog input. FIG. 4 shows an abnormality determination regarding the pulse input.

FIG. 3 is a diagram showing an example of a monitoring control screen of the monitoring LCD 14. FIG. 3 shows a monitoring control screen related to the pumping station. N1, N2, N3, N4 indicate a numerical display box. On the monitoring and control screen, symbols indicating the pumping station and the water supply pump are displayed. In addition, characters that explain symbols and the like are described. In addition, the flow of water is shown on the monitoring control screen. The numerical display boxes N1 and N2 indicate the water levels of the second pumping station and the first pumping station, respectively. P1 and P2 represent a pump (water supply pump) symbol. The pump symbol changes color, for example, depending on whether the pump is running or stopped. In the example shown in FIG. 3, the symbol P1 has hatching and indicates a stopped state. The symbol P2 has no hatching and indicates an operating state. Numerical value display boxes N3 and N4 indicate the pump rotation speed of each pump.

First, a case where the simulated signal is a digital input will be described. The name of the simulated signal is, for example, "No. 1 water supply pump operation". In the state shown in FIG. 3, No. 1 The water pump is stopped. Therefore, the simulated signal is used to display the No. 1 on the monitoring control screen. 1 The water supply pump goes from a stopped state to an operating state. As a result, the color of the symbol P1 on the monitoring control screen changes. In the example shown in FIG. 3, the symbol P1 changes from with hatching to without hatching.

The determination database 214 stores a correspondence relationship in which each signal content is associated with a symbol and an operation. For example, when the name of the signal is "No. 1 water pump operation", the symbol of the water pump and the change contents between the operating state and the stopped state are included in the correspondence relationship. When there are a plurality of display patterns, they can be selected by the user at the time of the test. For example, the user can select not only changing the color of the symbol but also lighting or blinking the symbol.

The abnormality detection unit 216 identifies the corresponding symbol to be determined by the characters on the monitoring control screen, the symbol content, the display position, and the like. In the example shown in FIG. 3, the abnormality detection unit 216 identifies the hatched symbol P1 from the characters “No. 1” and “water supply pump” and the display position. Further, the abnormality detection unit 216 compares the signal name with the change of the symbol on the monitoring control screen. Further, the abnormality detection unit 216 may compare the signal name with a message such as a failure content displayed on the monitoring control screen.

For example, when the symbol P1 has no hatching after the input of the simulated signal, the abnormality detection unit 216 determines that the monitoring control system 100 is in the normal state. On the other hand, if the symbol P1 is hatched after the input of the simulated signal, the abnormality detection unit 216 determines that the monitoring control system 100 is in an abnormal state.

Next, a case where the simulated signal is analog input / output will be described. The name of the simulated signal is, for example, "No. 1 water pump rotation speed". In the state shown in FIG. 3, No. 1 Water pump rotation speed is 1350 min ^-1 . The analog input / output range corresponds to the input / output current or input / output voltage to the controller 11. For example, the input / output current of 4 to 20 mADC corresponds to the full range, and the input / output voltage of 1 to 5 VDC corresponds to the full range. For example, when an input / output current (4 to 20 mADC) is used, 1350 min ^{-1 in} the range of ^{rotation speeds 0 to 1500 min -1} corresponds to a current value of 18.4 mADC according to Equation 1.
4+ (20-4) × (1350-0) / (1500-0) = 18.4mADC (Equation 1)
For example, the automatic test controller 22 inputs a current of 18.4 mADC to the controller 11. The controller 11 converts the current value into a signal having a certain count number and transmits it to the monitoring PC 13. The monitoring PC 13 stores the rotation speed range in advance, converts the signal transmitted from the controller 11 into the rotation speed value, and displays the converted rotation speed value on the monitoring LCD 14.

The abnormality detection unit 216 identifies the corresponding number or character to be determined by the character, the symbol content, the display position, or the like on the monitoring control screen. In the example shown in FIG. 3, the abnormality detection unit 216 identifies the numerical display box N3 from the characters “No. 1” and “water supply pump” and the display position. Further, the abnormality detection unit 216 compares and determines the result calculated from the signal range and the screen display with respect to the input of several levels of the analog signal. The abnormality detection unit 216 makes the above determination based on the correspondence stored in the determination database 214. The determination database 214, for example, the signal content of the pump speed 1350Min ^-1, an image that contains a number 1350Min ^-1 near the water pumps letters, correspondence of stored.

FIG. 4 is a diagram showing an example of a monitoring control screen of the monitoring LCD 14. FIG. 4 shows, for example, a form relating to water intake at a water source. The water intake amounts of Nos. 1 and 4 indicate, for example, the amount of water taken by the water source No. 1 intake pump and the water source No. 4 intake pump. The water intake amount of No. 2.5 indicates, for example, the amount of water taken by the water source No. 2 intake pump and the water source No. 5 intake pump.

A case where the simulated signal is a pulse input will be described. The name of the simulated signal is, for example, "No. 2.5 water intake integration". In the state shown in FIG. 3, for example, at time 22:00, the water intake amount of No. 2.5 is 34 m ³ . For example, when the count is 34 pulses and the pulse rate is 1 (m ³ / pulse), the water intake amount becomes 34 m ³ by the product of the count and the pulse rate. The value of the water intake varies depending on, for example, the pulse rate.

The abnormality detection unit 216 identifies the corresponding number or character to be determined by the character, the symbol content, the display position, or the like on the monitoring control screen (or form). In the example shown in FIG. 4, the abnormality detection unit 216 identifies ^{34 m 3} , which is the amount of water taken in No. 2.5 at 22:00, from the “water intake amount of No. 2.5”, the characters of the time, and the display position. Further, the abnormality detection unit 216 compares and determines the result calculated from the pulse rate and the display of the monitoring control screen (or form) with respect to the input of the pulse signal. The abnormality detection unit 216 makes the above determination based on the correspondence stored in the determination database 214. In the determination database 214, for example ^{, the correspondence between the signal content of "No. 2.5 water intake integrated 34 m 3} " and the image including the ^{numerical value 34 m 3} in the No. 2.5 water intake is stored.

FIG. 5 is a flow chart showing the operation of the automatic test device 200 according to the first embodiment.

First, the simulated signal generation unit 211 generates a simulated signal (S110). Next, the simulated signal transmitting unit 212 inputs the simulated signal to the controller 11, and the monitoring LCD 14 displays the display change due to the simulated signal on the monitoring control screen (S120). Further, the screen acquisition unit 213 acquires the monitoring control screen from the monitoring LCD 14 (monitoring PC 13). Next, the abnormality detection unit 216 compares the monitoring screen display with the signal content, and determines an abnormality in the monitoring control system 100 (S130). Next, the result storage control unit 217 saves the test results such as the abnormality detection result and the display image in the test result storage unit 217a, and the display control unit 218 displays the test result on the display unit 218a (S140).

Next, the abnormality detection unit 216 determines whether or not the test has been completed for all the test target signals (S150). If all the test target signals have not been tested (NO in S150), step S110 is executed again. Therefore, steps S110 to S140 are executed for all the test target signals. On the other hand, when the tests of all the test target signals are completed (YES in S150), the display control unit 218 reproduces and displays the test results on the display unit 218a (S160).

As described above, according to the first embodiment, the correspondence relationship acquisition unit 215 acquires the correspondence relationship between the signal stored in the determination database 214 in advance and the display state of the monitoring control screen corresponding to the signal. do. Further, the abnormality detection unit 216 detects an abnormality in the monitoring control system 100 by determining whether or not the simulated signal and the received display state of the monitoring control screen correspond to each other based on the correspondence relationship. As a result, the monitoring and control system 100 can be automatically tested. As a result, the test of the monitoring control system 100 can be facilitated.

In addition, since the judgment is automatically performed, the test period can be shortened. Further, the screen acquisition unit 213 (automatic test device 200) is provided away from the monitoring LCD 14. As a result, the number of personnel for confirming the monitoring LCD 14 during the test can be reduced, and the signal input and the confirmation of the monitoring screen can be performed by one examiner. Therefore, it leads to labor saving.

In addition, the abnormality detection unit 216 identifies the display state from the monitoring control screen by image recognition. This eliminates the need for pre-settings for automated testing, such as assigning a symbol on the screen to a signal. As a result, it is possible to suppress the labor of setting, and further, it is possible to suppress erroneous detection of an abnormality due to a setting error. Further, the abnormality detection unit 216 is not limited to specific characters, figures (including pipes, etc.), symbols, etc., and specifies the display state from the entire screen.

In addition, the display control unit 218 controls the display unit 218a so as to display the abnormality detection result and the display image stored in the test result storage unit 217a. As a result, the examiner can immediately reconfirm the completed test result by playing back the video. As a result, errors in the automatic test such as determination errors can be confirmed, and oversight of errors in the automatic test can be suppressed. Moreover, since the results are automatically and continuously displayed, the test results can be confirmed at high speed. In addition, confirmation by reproduction can be performed by one examiner.

Further, the automatic test device 200 can be applied to different monitoring and control systems, and can be applied to both factory tests and field tests in common. Therefore, it leads to cost reduction for conducting the test.

(Modification example 1)
FIG. 6 is a block diagram showing the configuration of the automatic test terminal 21 according to the first modification. The first embodiment is different from the first embodiment in that machine learning is used for image recognition by the abnormality detection unit 216.

The automatic test terminal 21 further includes a learning model generation unit 219 and a learning model storage unit 219a.

In addition, each part 211-213 and 215-219 in the automatic test terminal 21 may be realized by one CPU, or may be realized by each individual CPU.

The learning model generation unit 219 generates a learning model that inputs the monitoring control screen and outputs the display state. The learning model generation unit 219, for example, associates the monitoring control screen with the display state and generates a learning model by machine learning. Further, the learning model generation unit 219 may generate a learning model by, for example, deep learning using a neural network. The learning model storage unit 219a may be provided outside the automatic test terminal 21.

The learning model storage unit 219a stores the learning model generated by the learning model generation unit 219. The learning model storage unit 219a may be provided outside the automatic test terminal 21.

The abnormality detection unit 216 identifies the display state corresponding to the simulated signal from the monitoring control screen by applying the monitoring control screen to the learning model that inputs the monitoring control screen and outputs the display state. By using machine learning, the accuracy of image recognition can be improved and the accuracy of specifying the display state can be improved. As a result, the accuracy of abnormality detection of the monitoring control system 100 can be improved. The abnormality detection unit 216 acquires a learning model stored in advance in the learning model storage unit 219a. Further, the learning model generation unit 219 learns image patterns of various monitoring control screens by using a large number of general monitoring control screens. Thereby, the display state can be more appropriately specified even for different monitoring and control systems 100 and different monitoring and control screens. Further, the abnormality detection unit 216 determines whether or not the simulated signal and the specified display state correspond to each other based on the correspondence relationship.

Since the other configurations of the automatic test device 200 according to the first modification are the same as the corresponding configurations of the automatic test device 200 according to the first embodiment, detailed description thereof will be omitted.

The automatic test device 200 according to the first modification can obtain the same effect as that of the first embodiment.

(Second Embodiment)
FIG. 7 is a block diagram showing the configuration of the automatic test terminal 21 according to the second embodiment. The second embodiment is different from the first embodiment in that a test is performed on an output signal output from the monitoring control system 100.

The test may be performed while the monitoring and control system 100 is in operation or stopped. When the test is performed while the monitoring control system 100 is in operation, the connection between the controller 11 and the target device 101 may be disconnected. As a result, the malfunction of the target device 101 can be suppressed.

The automatic test terminal 21 further includes a screen operation unit 213a and an output signal reception unit 212a.

In addition, each part 211-213, 215-218, 212a, 213a in the automatic test terminal 21 may be realized by one CPU, or may be realized by each individual CPU.

The screen operation unit 213a operates the monitoring control screen based on the correspondence so that the controller 11 outputs the output signal corresponding to the test target signal (control signal) output from the controller 11 to the target device 101. .. The control signal is a signal to be tested. In addition, the screen operation unit 213a automatically operates the monitoring control screen.

More specifically, the screen operation unit 213a corresponds to the signal to be tested (control signal) based on the device information regarding the target device 101 in the monitoring control screen and at least one of the display positions of the device information. The display state obtained by applying the relationship is specified from the monitoring control screen. The identification of the display state by the screen operation unit 213a may be the same as that of the abnormality detection unit 216 according to the first embodiment. Further, the screen operation unit 213a operates the monitoring control screen based on the specified display state.

More specifically, the screen operation unit 213a is provided apart from the monitoring PC 13 and the monitoring LCD 14 in the monitoring control system 100. Therefore, the screen operation unit 213a remotely operates the monitoring control screen. Therefore, the automatic test terminal 21 (automatic test device 200) can remotely test the monitoring control system 100.

The output signal receiving unit 212a receives the output signal.

The abnormality detection unit 216 detects an abnormality in the monitoring control system 100 based on a comparison between the signal to be tested (control signal) and the output signal. As a result, the test for determining the abnormality can be automatically performed. As a result, the test of the monitoring control system 100 can be facilitated.

Since the other configurations of the automatic test device 200 according to the second embodiment are the same as the corresponding configurations of the automatic test device 200 according to the first embodiment, detailed description thereof will be omitted.

Next, the abnormality determination will be described with reference to FIGS. 8 and 9. Further, the control signal includes, for example, a digital input (operation) and an analog input (set value). FIG. 8 shows an abnormality determination regarding digital output. FIG. 9 shows an abnormality determination regarding the analog output.

FIG. 8 is a diagram showing an example of a monitoring control screen of the monitoring LCD 14. FIG. 8 shows a monitoring control screen relating to the operation of the intake pump. P3 represents the symbol of the intake pump. Further, W1 indicates a window that appears on the screen when the symbol P3 is selected. B1 and B2 indicate operation buttons. The window W1 may be displayed in advance around the symbol P3.

A case where the control signal is a digital output will be described. The name of the control signal is, for example, "Water source No. 1 intake pump operation operation". The screen operation unit 213a identifies the corresponding symbol to be determined by the characters on the monitoring control screen, the symbol content, the display position, and the like. In the example shown in FIG. 8, the screen operation unit 213a identifies the water intake pump from the symbol P3 and the characters and display positions of the “water intake pump”. Further, since the symbol P3 has no hatching, the screen operation unit 213a specifies that the water intake pump is in the stopped state.

The screen operation unit 213a selects the symbol P3 on the monitoring control screen from the name of the control signal. Similarly, the screen operation unit 213a reads the character information and the position information in the window W1 and selects the operation operation button B1. The screen operation unit 213a performs the above operation based on the correspondence relationship stored in the determination database 214. In the determination database 214, for example, the correspondence between the signal content of "water source No. 1 intake pump operation operation" and the operation image including the operation buttons B1 and B2 in the window W1 near the characters of the intake pump is stored. Has been done. The operation image may also include a screen change due to the operation. As a result, the output signal is output from the controller 11 of the monitoring control system 100 to the target device 101.

The abnormality detection unit 216 compares the content of the signal output from the controller 11 with the content of the control signal. For example, when the signal contents substantially match, the abnormality detection unit 216 determines that the monitoring control system 100 is in a normal state. On the other hand, when the signal contents do not match, the abnormality detection unit 216 determines that the monitoring control system 100 is in an abnormal state. The abnormality detection unit 216 is not limited to whether or not they match substantially, and may determine the abnormality by, for example, comparing the similarity between the signal names and the threshold value.

FIG. 9 is a diagram showing an example of a monitoring control screen of the monitoring LCD 14. FIG. 9 shows a monitoring control screen relating to the operation of the water level of the distribution reservoir. P4 represents the symbol of the water pump. N5 indicates a numerical display box of the pump rotation speed. W1 indicates a window that appears on the screen when the numerical display box N5 is selected. S indicates a numerical value setting box. B3 indicates an operation button. The window W2 may be displayed in advance around the numerical display box N5.

A case where the control signal is an analog output will be described. The name of the control signal is, for example, "pump rotation speed operation". The screen operation unit 213a identifies the corresponding symbol to be determined by the characters on the monitoring control screen, the symbol content, the display position, and the like. In the example shown in FIG. 9, the screen operation unit 213a specifies that the numerical display box N5 indicates the pump rotation speed of the water supply pump from the figure, the characters ^{“water supply pump”, “500min -1” and the display position.} ..

The screen operation unit 213a selects the numerical display box N5 on the monitoring control screen from the name of the control signal. Similarly, the screen operation unit 213a reads the character information and the position information in the window W2, sets the numerical value in the numerical value setting box S, and selects the setting button B3. The screen operation unit 213a performs the above operation based on the correspondence relationship stored in the determination database 214. In the determination database 214, for example, the correspondence between the signal content of "pump rotation speed operation" and the operation image including the numerical value setting box S in the window W2 near the character of the water supply pump is stored. The operation image may also include a screen change due to the operation. As a result, the output signal is output from the controller 11 of the monitoring control system 100 to the target device 101. In the example shown in FIG. 9, the monitoring LCD 14 ^{is operated so that the pump rotation speed becomes 1350min -1,} and the monitoring PC 13 converts the pump rotation speed into a signal of a certain count number with reference to the range and transmits it to the controller 11. do. Contrary to the analog input, the controller 11 converts the signal received from the monitoring PC 13 into a current value, and outputs a current of 18.4 mADC converted from ^{1350 min -1 to the automatic test controller 22.}

The abnormality detection unit 216 compares the content of the signal output from the controller 11 with the content of the control signal. For example, when the signal contents substantially match, the abnormality detection unit 216 determines that the monitoring control system 100 is in a normal state. On the other hand, when the signal contents do not match, the abnormality detection unit 216 determines that the monitoring control system 100 is in an abnormal state. The abnormality detection unit 216 is not limited to whether or not they match substantially, and may determine the abnormality by, for example, comparing the similarity between the signal names and the threshold value.

FIG. 10 is a flow chart showing the operation of the automatic test device 200 according to the second embodiment.

First, the screen operation unit 213a remotely controls the monitoring control screen (S210). Next, the output signal receiving unit 212a receives the signal output from the controller 11 (S220). Next, the abnormality detection unit 216 compares the received output signal with the signal content, and determines an abnormality in the monitoring control system 100 (S230). Next, the result storage control unit 217 saves the test results such as the abnormality detection result and the display image in the test result storage unit 217a, and the display control unit 218 displays the test result on the display unit 218a (S240).

Next, the abnormality detection unit 216 determines whether or not the test has been completed for all the test target signals (S250). If all the test target signals have not been tested (NO in S250), step S210 is executed again. Therefore, steps S210 to S240 are executed for all the test target signals. On the other hand, when the tests of all the test target signals are completed (YES in S250), the display control unit 218 reproduces and displays the test results on the display unit 218a (S260).

As described above, according to the second embodiment, the correspondence relationship acquisition unit 215 acquires the correspondence relationship between the signal stored in the determination database 214 in advance and the display state of the monitoring control screen corresponding to the signal. do. Further, the screen operation unit 213a operates the monitoring control screen based on the correspondence so that the controller 11 outputs the output signal corresponding to the control signal output from the controller 11 to the target device 101. Further, the abnormality detection unit 216 detects an abnormality in the monitoring control system 100 based on the comparison between the control signal and the output signal. As a result, the monitoring and control system 100 can be automatically tested. As a result, the test of the monitoring control system 100 can be facilitated.

The automatic test device 200 according to the second embodiment can obtain the same effect as that of the first embodiment. Further, in the second embodiment, not only the signal input test but also the signal output test can be performed.

Further, the screen operation unit 213a identifies the display state from the monitoring control screen by image recognition. This eliminates the need for pre-settings for automated testing, such as assigning a symbol on the screen to a signal. As a result, it is possible to suppress the labor of setting, and further, it is possible to suppress erroneous detection of an abnormality due to a setting error. Further, the screen operation unit 213a is not limited to specific characters, figures (including pipes, etc.), symbols, and the like, and specifies a display state from the entire screen.

(Modification 2)
FIG. 11 is a block diagram showing the configuration of the automatic test terminal 21 according to the modified example 2. The second embodiment is different from the second embodiment in that machine learning is used for image recognition by the screen operation unit 213a.

The automatic test terminal 21 further includes a learning model generation unit 219 and a learning model storage unit 219a. The learning model generation unit 219 and the learning model storage unit 219a may be the same as those in the first modification.

In addition, each part 211-213, 215-219, 212a, 213a in the automatic test terminal 21 may be realized by one CPU, or may be realized by each individual CPU.

The screen operation unit 213a applies the monitoring control screen to the learning model that inputs the monitoring control screen and outputs the display state, so that the display obtained by applying the correspondence to the signal to be tested (control signal). Identify the status from the monitoring control screen. By using machine learning, the accuracy of image recognition can be improved and the accuracy of specifying the display state can be improved. As a result, the accuracy of abnormality detection of the monitoring control system 100 can be improved. In addition, erroneous operation of the screen operation unit 213a can be suppressed. The screen operation unit 213a acquires a learning model stored in advance in the learning model storage unit 219a. Further, the learning model generation unit 219 learns image patterns of various monitoring control screens by using a large number of general monitoring control screens. Thereby, the display state can be more appropriately specified even for different monitoring and control systems 100 and different monitoring and control screens. Further, the screen operation unit 213a operates the monitoring control screen based on the specified display state.

Since the other configurations of the automatic test device 200 according to the second modification are the same as the corresponding configurations of the automatic test device 200 according to the second embodiment, detailed description thereof will be omitted.

The automatic test device 200 according to the second modification can obtain the same effect as that of the second embodiment.

At least a part of the data processing method in the automatic test apparatus 200 according to the present embodiment may be configured by hardware or software. When configured by software, a program that realizes at least a part of the functions of the automatic test device 200 may be stored in a recording medium such as a flexible disk or a CD-ROM, read by a computer, and executed. The recording medium is not limited to a removable one such as a magnetic disk or an optical disk, and may be a fixed recording medium such as a hard disk device or a memory. Further, a program that realizes at least a part of the functions of the automatic test device 200 may be distributed via a communication line (including wireless communication) such as the Internet. Further, the program may be encrypted, modulated, compressed, and distributed via a wired line or wireless line such as the Internet, or stored in a recording medium.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

100 Surveillance control system, 14 Surveillance LCD, 101 Target device, 200 Automatic test equipment, 212 Simulated signal transmitter, 212a Output signal receiver, 213 Screen acquisition unit, 213a Screen operation unit, 214 Judgment database, 215 Correspondence acquisition unit, 216 Abnormality detection unit, 217 Result storage control unit, 217a Test result storage unit, 218 Display control unit, 218a Display unit

Claims (10)

Testing and monitoring a monitoring control system having a control device that monitors and controls the target device by inputting and receiving signals to and from the target device and a display device that displays a monitoring control screen for monitoring and controlling the target device. It is an automatic test device for control systems.
A simulated signal transmission unit that transmits a simulated signal that simulates the signal of the test target input from the target device to the control device to the control device.
A screen acquisition unit that acquires the monitoring control screen from the display device, and
A correspondence relationship acquisition unit that acquires a correspondence relationship between the signal and the display state of the monitoring control screen corresponding to the signal, which is stored in the first storage unit in advance.
Based on the correspondence relationship, the abnormality detection unit that detects an abnormality in the monitoring control system by determining whether or not the simulated signal and the acquired display state of the monitoring control screen correspond to each other. An automatic test device for monitoring and control systems. The abnormality detection unit
Based on the device information related to the target device in the monitoring control screen and at least one of the display positions of the device information, the display state corresponding to the simulated signal is specified from the monitoring control screen.
The automatic test device for a monitoring control system according to claim 1, wherein it is determined whether or not the simulated signal and the specified display state correspond to each other based on the correspondence relationship. The abnormality detection unit
By applying the monitoring control screen to a learning model that inputs the monitoring control screen and outputs the display state, the display state corresponding to the simulated signal is specified from the monitoring control screen.
The automatic test device for a monitoring control system according to claim 1 or 2, wherein it is determined whether or not the simulated signal and the specified display state correspond to each other based on the correspondence. A storage control unit that controls the second storage unit so as to store the detection result of the abnormality detection unit and at least one of the display images of the monitoring control screen under test.
Any one of claims 1 to 3, further comprising a display control unit that controls the display unit so as to display at least one of the detection result and the display image, which is stored in the second storage unit. The automatic test equipment for the monitoring and control system according to the first paragraph. The automatic test device for a monitoring and control system according to any one of claims 1 to 4, wherein the screen acquisition unit is provided apart from the display device of the monitoring and control system. Testing and monitoring a monitoring control system having a control device that monitors and controls the target device by inputting and receiving signals to and from the target device and a display device that displays a monitoring control screen for monitoring and controlling the target device. It is an automatic test device for control systems.
A correspondence relationship acquisition unit that acquires a correspondence relationship between the signal and the display state of the monitoring control screen corresponding to the signal, which is stored in the first storage unit in advance.
A screen operation unit that operates the monitoring control screen based on the correspondence relationship so that the output signal corresponding to the signal of the test target output from the control device to the target device is output from the control device.
An output signal receiving unit that receives the output signal and
An automatic test device for a monitoring and control system, comprising an abnormality detection unit that detects an abnormality in the monitoring and control system based on a comparison between the signal to be tested and the output signal. The screen operation unit is
The monitoring of the display state obtained by applying the correspondence to the signal to be tested based on the device information about the target device in the monitoring control screen and at least one of the display positions of the device information. Identify from the control screen,
The automatic test device for a monitoring control system according to claim 6, wherein the monitoring control screen is operated based on the specified display state. The screen operation unit is
By applying the monitoring control screen to a learning model that inputs the monitoring control screen and outputs the display state, the monitoring control controls the display state obtained by applying the correspondence to the signal to be tested. Identify from the screen
The automatic test device for a monitoring control system according to claim 6 or 7, wherein the monitoring control screen is operated based on the specified display state. A storage control unit that controls the second storage unit so as to store the detection result of the abnormality detection unit and at least one of the display images of the monitoring control screen under test.
Any of claims 6 to 8, further comprising a display control unit that controls the display unit so as to display at least one of the detection result and the display image, which is stored in the second storage unit. The automatic test equipment for the monitoring and control system according to the first paragraph. The automatic test device for a monitoring and control system according to any one of claims 6 to 9, wherein the screen operation unit is provided apart from the display device of the monitoring and control system.

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