JP6736083B2 - Relay device, relay method, and relay system - Google Patents

Description

The present invention relates to a technique for relaying communication of a wired control system that controls a plurality of facilities connected via a wired transmission path.

Conventionally, there is a wired control system that connects a plurality of distributed equipments to an operation terminal via a wired transmission path and controls the plurality of equipments according to an operation from the operation terminal (for example, Patent Document 1). reference).

JP-A-5-150805

In the wired control system, the operation terminal and the installation position of the facility are often installed separately from each other. Therefore, when the operation terminal is operated, it may take time to move from the installation position of the operation terminal to the installation position of the equipment, for example, to confirm the operation of the equipment. Therefore, the operator of the operating terminal may not be able to directly confirm the operation of the equipment immediately after operating the operating terminal.

The present disclosure has been made in view of the above problems, and an object of the present disclosure is to provide a means that enables an operation by an operation terminal in the vicinity of equipment of a wired control system.

A relay device according to one aspect of the present disclosure is a relay device that relays communication between a wireless control device and a wired control system that controls a plurality of facilities connected via a wired transmission line, and is connected to the wired transmission line. Wired connection means, wireless communication means for performing wireless communication with a mobile terminal, and status signal acquisition processing for acquiring status signals indicating the operating status of each of a plurality of facilities from the wired transmission path via the wired connection means, acquired status signal A situation signal transmission process for transmitting via a wireless communication means during a predetermined period, and receiving an operation command for at least one of a plurality of equipments via a wireless communication means during a predetermined period, and an operation command, And a control unit that executes an operation command transmission process for transmitting to the wired transmission path via the wired connection unit.

ADVANTAGE OF THE INVENTION According to the relay apparatus of this indication, a signal can be transmitted to a facility via a wire transmission path, even if it is near the installation position of the equipment, if it is within the wireless communication range of the relay apparatus. It is possible to confirm whether or not the signal is properly transmitted in the road, whether the equipment is operating properly by the signal transmitted through the wire transmission line, and the like.

The figure which shows an example of the whole structure of a system. The figure which shows an example of the frame format of the signal transmitted by a cable transmission path. The figure which shows an example of a structure of a debug unit. 6 is a flowchart showing an example of the operation of the debug unit. The flowchart which shows an example of the wired side process of a debug unit. The flowchart which shows an example of the wireless side process of a debug unit. 6 is a flowchart showing an example of command standby processing of the debug unit. The figure which shows an example of the process which a debug unit performs according to the command received in command standby process. 6 is a flowchart showing an example of a transmission line monitoring process of the debug unit. The figure which shows an example of the process which a debug unit performs according to the command received in the transmission line monitoring process. The figure which shows an example of a structure of a wireless terminal. The flowchart which shows an example of operation|movement of the debug application of a wireless terminal. The figure which shows an example of the display screen of the debug application of a wireless terminal. The figure which shows an example of the display screen of the debug application of a wireless terminal. The figure which shows an example of the display screen of the debug application of a wireless terminal.

The embodiments described below each show a specific example of the present disclosure, and numerical values, shapes, constituent elements, steps, elements of steps, etc. are merely examples, and are not intended to limit the present disclosure.
(Embodiment 1)
In the first embodiment, as one aspect of the present disclosure, a debug system 10 and a wired control system 20 to be debugged will be described.
<1. Overview>
FIG. 1 is a diagram showing an example of a configuration of a debug system 10 and a wired control system 20 to be debugged.

First, the wired control system 20 to be debugged will be described. The wired control system 20 includes a wired transmission line system 120, one or more mechanical facilities 160, and a control device 170.
The control device 170 is, for example, a PLC (Programmable Logic Controller), and is connected to one or more mechanical equipments 160 via the wired transmission path system 120 to control the mechanical equipments 160.

The mechanical equipment 160 is, for example, mechanical equipment such as distributed sensors, switches, lamps, and motors, and operates based on signals received from the control device 170 via the wired transmission path system 120.
The wired transmission line system 120 transmits a signal from the control device 170 to the mechanical equipment 160 and a signal from the mechanical equipment 160 to the control device 170. The wired transmission line system 120 includes a master unit 150, a terminal unit 140, and a wired transmission line 130.

The master unit 150 generates a frame signal flowing on the wired transmission path 130 based on a signal for controlling the operation of the mechanical equipment 160 addressed to the mechanical equipment 160 input from the control device 170, and the generated frame signal is used for the wired transmission path. Output to 130. Alternatively, the master unit 150 acquires a signal addressed to the control device 170, which is multiplexed in the frame signal, from the frame signal transmitted through the wired transmission path 130, and outputs the signal to the control device 170.

The terminal unit 140 generates a frame signal flowing on the wired transmission path 130 based on a signal input from the corresponding mechanical equipment 160 to the control device 170 and notifying the operation of the mechanical equipment, and wire-transmits the generated frame signal. Output to path 130. Alternatively, the terminal unit 140 acquires a signal addressed to the corresponding mechanical equipment 160, which is multiplexed in the frame signal, from the frame signal transmitted through the wired transmission path 130, and outputs the signal to the mechanical equipment 160.

The wired transmission path 130 is a bidirectional wired serial transmission path that connects the master unit 150 and the terminal unit 140.
FIG. 2 is a diagram showing an example of a frame format of the frame signal 200 transmitted through the wired transmission path 130. As shown in the figure, the frame signal transmitted through the wired transmission path 130 includes a start unit 201, a data unit 202, and an end unit 203. The start unit 201 and the end unit 203 are signals with a fixed number of bits having a predetermined bit pattern for frame synchronization. The data unit 202 is a signal of a fixed bit number in which a signal addressed to one or more mechanical equipment 160 or a signal addressed to one or more control devices 170 is time-division multiplexed.

Next, returning to FIG. 1, the debug system 10 will be described. The debug system 10 includes a debug unit 100 connected to a wired transmission path 130 and a wireless terminal 110 that wirelessly communicates with the debug unit 100.
The debug unit 100 is a relay device that relays communication between the wired control system 20 and the wireless terminal 110. The debug unit 100 acquires a signal for controlling the operation of the mechanical equipment 160 or a signal for notifying the operating status of the mechanical equipment 160 from the frame signal transmitted through the wired transmission path 130, and wirelessly transmits the signal to the wireless terminal 110. The debug unit 100 also generates a frame signal based on the operation command for controlling the operation of the mechanical equipment 160 received from the wireless terminal 110, and outputs the frame signal to the wired transmission path 130. Details of the configuration and operation of the debug unit 100 will be described later.

The wireless terminal 110 displays the operating status of the mechanical equipment 160 to the user of the wireless terminal 110 based on the signal received from the debug unit 100 for controlling the operation of the mechanical equipment 160 and the signal notifying the operating status of the mechanical equipment 160. Further, the wireless terminal 110 transmits a command for controlling the operation of the mechanical equipment 160 to the debug unit 100 according to a user input.
<2. Debug unit 100>
Details of the configuration and operation of the debug unit 100 will be described.
<2-1. Configuration of debug unit 100>
FIG. 3 is a diagram showing an example of the configuration of the debug unit 100. As shown in the figure, the debug unit 100 includes a driver circuit 320, a wireless communication module 310, a central control unit 300, a display LED 340, and a reset switch 330.

The driver circuit 320 is connected to the wired transmission path 130. The driver circuit 320 is a transistor circuit that performs voltage conversion to absorb a difference in operating voltage between the wired transmission line 130 and the central control unit 300, and lowers the signal input from the wired transmission line 130 to the central control unit. The signal is output to 300, and the signal input from the central control unit 300 is boosted and output to the wired transmission path 130. Further, the driver circuit 320 detects a transmission line abnormality such as a voltage level drop in the wired transmission line 130, and notifies the central control unit 300 of the detected transmission line abnormality.

The wireless communication module 310 is a SoC (System-on-a-Chip) integrated circuit including an antenna element for wireless communication, a modulation circuit, and a demodulation circuit. A wireless setting information storage unit 311 is configured in a partial area of a nonvolatile memory built in the wireless communication module 310. The wireless setting information storage unit 311 stores setting information used in wireless communication such as SSID, password, IP address, security (encryption method), etc. The central control unit 300 is stored in a built-in memory. It is an SoC integrated circuit that realizes each operation described below by executing a program. A monitor data storage unit 301 for storing data input from the wired transmission line 130 and a wired output data storage unit for storing data to be output to the wired transmission line 130 are provided in a part of the internal memory of the central control unit 300. The unit 302 is configured. In addition, the reset flag, the transmission abnormality flag, the monitor data confirmation flag, the forced output flag, and the operation mode flag are managed using a partial area of the internal memory of the central control unit 300.

The display LED 340 includes a plurality of LEDs (Light Emitting Diodes), and lights up, goes out, or blinks according to a flag managed by the central control unit 300 to notify the state of the debug unit 100 to the outside. The reset switch 330 is a switch for setting a reset flag to ON.
<2-2. Operation of debug unit 100>
FIG. 4 is a flowchart showing an example of the operation of the debug unit 100.

After the power is turned on, the central control unit 300 of the debug unit 100 performs initialization processing such as loading a program and clearing a flag (step S401).
After the initialization process is completed, the central control unit 300 performs a wired side process (step S402) and a wireless side process (step S403) described later.
After completing the wired-side processing and the wireless-side processing, the central control unit 300 confirms whether or not the reset flag is set to ON. If it is set, the process returns to step S401, and if not set, the process proceeds to step S405 ( Step S404). The reset flag is set to ON when the reset switch 330 is operated.

The debug unit 100 ends the process when the power is off, and returns to step S402 unless the power is off (step S405).
FIG. 5 is a flowchart showing an example of the above-mentioned wired side processing.
The central control unit 300 confirms whether or not the transmission path abnormality is notified from the driver circuit 320, and if it is notified, the process proceeds to step S509, and if not, the process proceeds to step S502 (step S501).

If the transmission path abnormality is not notified from the driver circuit 320, the central control unit 300 clears the transmission abnormality flag to OFF (step S502).
When the transmission abnormality flag is cleared to OFF, the debug unit 100 confirms whether a signal for one refresh cycle has been input from the driver circuit 320 (step S503). Specifically, the central control unit 300 monitors the signal input from the driver circuit 320 and attempts to detect the start portion and the end portion of the frame signal. If the start portion and the end portion can be detected, the process proceeds to step S504, and if not detected, the process proceeds to step S507.

When the central control unit 300 detects the start portion and the end portion of the frame signal, the central control unit 300 performs error correction of the data portion (step S504). Specifically, the signal at each bit position in the data portion before error correction is compared with the signal at the same bit position before error correction in the previous frame, and when the signal is the same, that signal is regarded as the signal after error correction. If the signals are different, the signal after the error correction of the previous frame is set as the signal after the error correction of the current frame.

When the error correction of the data part is completed, the central control unit 300 fixes the monitor data, that is, stores the data part after the error correction in the monitor data storage unit 301 (step S505), and sets the monitor data determination flag to ON. (Step S506).
The processing of steps S503 to S506 is processing in which the central control unit 300 acquires a status signal indicating the operating status of each of the one or more mechanical facilities 160 from the wired transmission path 130 via the driver circuit 320. The processing is collectively called the status signal acquisition processing. The status signal is a signal input from the control device 170 to the wired transmission path 130 via the master unit 150 to control the operation of the mechanical equipment 160 addressed to the mechanical equipment 160, and the mechanical equipment 160 to the terminal unit. A signal notifying the operation of the mechanical equipment 160 addressed to the control device 170, which is input to the wired transmission path 130 via 140, is included.

When the status signal acquisition process is completed, the central control unit 300 confirms whether the forced output flag is set to ON. If it is set, the process proceeds to step S508, and if it is not set, the process ends (step S507). ).
If the forced output flag is set to ON, the central control unit 300 outputs the data stored in the wired output data storage unit 302 to the wired transmission path 130 via the driver circuit 320 (step S508).

When the driver circuit 320 detects the transmission abnormality, the central control unit 300 sets the transmission abnormality flag to ON (step S509) and ends the processing.
FIG. 6 is a flowchart showing an example of the above-mentioned wireless side processing.
The central control unit 300 confirms the operation mode flag. If a value indicating the command standby mode is set in the operation mode flag, the process proceeds to the command standby process described later in step S602, and if a value indicating the transmission line monitoring mode is set, the transmission described later in step S603. Proceed to the road monitoring process (step S601). The values set in the operation mode flag include a value indicating the command standby mode and a value indicating the transmission path monitoring mode, and the value indicating the command standby mode is set in the initialization processing.

FIG. 7 is a flowchart showing an example of the command standby process described above.
The central control unit 300 confirms whether or not a command signal is input via the wireless communication module 310, and if the command signal is input, the process proceeds to step S702, and if the command signal is not input, the process ends. (Step S701).
When the command signal is input through the wireless communication module 310, the central control unit 300 confirms whether the transmission abnormality flag is set, and if the transmission abnormality flag is set to ON, the process proceeds to step S704. If not set, the process proceeds to step S703 (step S702).

When the command signal is input via the wireless communication module 310 and the transmission abnormality flag is not set, the central control unit 300 executes the command processing according to the type of the command indicated by the input command signal (step). S703).
After executing the command processing, the central control unit 300 transmits a response signal according to the executed command processing to the wireless terminal 110 that is the transmission source of the command signal (step S704). When the transmission abnormality flag is set to ON in step S702, the central control unit 300 does not execute the command processing, and an abnormality occurs in the transmission path with respect to the wireless terminal 110 that is the transmission source of the command signal. A response signal indicating that the operation is being performed is transmitted.

A command signal input to the debug unit 100 via the wireless communication module and a response signal output from the debug unit 100 via the wireless communication module 310 will be described. The command signal is, for example, the type of command such as “participate”, “monitor start”, “wireless setting confirmation”, “wireless setting change”, “monitor end”, “forced output start”, and “forced output end”, and to execute the command. It is a signal for transmitting data and the like necessary for the. The response signal is a signal that transmits, as a response to the command signal, the type of response such as “normal response”, “command execution impossible”, “transmission path abnormality”, and data indicating the execution result of the command.

FIG. 8 is a diagram showing an example of the contents of command processing and response signals executed when the central control unit 300 is in the command standby mode.

A case where the command type of the received command signal is “participate” will be described.
In the debug system 10 according to the present embodiment, the wireless terminal 110 belonging to the debug group including one or more terminals is permitted to monitor the mechanical equipment 160 via the debug unit 100. The wireless terminal 110 transmits to the debug unit 100 a command signal designating “join” as the command type in order to request participation in the debug group.

When the central control unit 300 of the debug unit 100 receives the command signal whose command type is “join”, it determines whether or not the wireless terminal 110, which is the transmission source of the command signal, can join the debug group. In the debug system 10 according to the present embodiment, a predetermined number (for example, 5) of wireless terminals 110 are permitted to participate in a debug group in the order in which they receive a command signal in which “participation” is designated as the command type. After that, even if a command specifying "Join" as the command type is received, participation permission to the debug group is not granted.

The central control unit 300 determines whether or not the wireless terminal 110 permitted to participate in the debug group is a leader terminal. In the debug system 10 according to the present embodiment, when the command signal in which "participation" is designated as the command type is first received, the wireless terminal 110 that is the transmission source of the command signal is determined to be the leader terminal.
In the debug system 10 of the present exemplary embodiment, among the wireless terminals 110 belonging to the debug group, for the wireless terminal 110 determined to be the leader terminal, the command types are “monitor start”, “wireless setting confirmation”, and “wireless”. Transmission of command signals with "change settings", "end monitor", "start forced output", and "end forced output" is permitted. For the wireless terminal 110 that is not determined to be the leader terminal, the command types are “monitor start”, “wireless setting confirmation”, “wireless setting change”, “monitor end”, “forced output start”, and “forced output”. Transmission of command signal with "End" is not permitted.

The central control unit 300 generates, as a response signal, a response signal storing “normal response” as the type of response, data showing the result of participation in the debug group as a data content, and data indicating the result of determination as to the leader terminal. , To the wireless terminal 110 which is the transmission source of the command signal.
A case where the command type of the received command signal is “monitor start” will be described.

When the debug unit 100 receives a command signal whose command type is "monitor start", the debug unit 100 switches the operation mode to the transmission path monitoring mode. Specifically, the debug unit 100 sets a value indicating the transmission path monitoring mode in the operation mode flag.
The central control unit 300 generates, as the response signal, a response signal in which “normal response” is designated as the response type, and transmits the response signal to the wireless terminal 110 that is the transmission source of the command signal.

A case where the command type of the received command signal is “wireless setting confirmation” will be described.
Upon receiving the command signal whose command type is “wireless setting confirmation”, the central control unit 300 reads wireless setting information such as SSID, IP address, and security from the wireless setting information storage unit 311 of the wireless communication module 310.
The central control unit 300 generates, as the response signal, a response signal in which the response type is “normal response” and the read wireless setting information is stored as the data content, and transmits the response signal to the wireless terminal 110 that is the transmission source of the command signal.

A case where the type of the received command signal is “wireless setting change” will be described.
When the central control unit 300 receives a command signal whose command type is “wireless setting change”, the central control unit 300 acquires the wireless setting change information included in the data content of the command signal. The wireless setting change information includes, for example, the changed SSID, password, IP address, security, and the like. The central control unit 300 updates the content of the wireless setting information storage unit 311 of the wireless communication module 310 based on the wireless setting change information acquired from the command signal.

The central control unit 300 generates, as the response signal, a response signal in which “normal response” is designated as the response type, and transmits the response signal to the wireless terminal 110 that is the transmission source of the command signal.
When the operation mode of the central control unit 300 is the command standby mode and the command type of the received command signal is other than “participate”, “start monitor”, “wireless setting confirmation”, and “wireless setting change”, The control unit 300 discards the received command signal and does not execute the command processing. Then, the debug unit 100 generates, as a response signal, a response signal in which “command execution impossible” is specified in the response type, and transmits the response signal to the wireless terminal 110 that is the transmission source of the command signal.

When the transmission abnormality flag is set to ON in step S702, the central control unit 300 generates a response signal specifying "transmission path abnormality" as the response type, and transmits the command signal to the wireless source. It is transmitted to the terminal 110.
FIG. 9 is a flowchart showing an example of the above-mentioned transmission path monitoring processing.
The central control unit 300 confirms whether or not the transmission abnormality flag is set to ON. If it is set, the processing is ended, and if not set, the process proceeds to step S1002 (step S1001).

When the transmission abnormality flag is not set to ON, the central control unit 300 confirms whether or not a command signal is input via the wireless communication module 310, and if the command signal is input, the process proceeds to step S1003, If no command signal is input, the process proceeds to step S1004 (step S1002).
When the transmission abnormality flag is not set to ON and a command signal is input through the wireless communication module 310, the central control unit 300 performs command processing according to the type of command indicated by the input command signal. Execute (step S1003).

When the processes of steps S1002 to S1003 are completed, the central control unit 300 confirms whether the monitor data confirmation flag is set to ON. If it is set, the process proceeds to step S1005, and if it is not set, the process ends. Yes (step S1004).
When the monitor data confirmation flag is set to ON, the central control unit 300 causes the monitor data stored in the monitor data storage unit 301 via the wireless communication module 310 (the data portion of the frame signal of the wired transmission path 130). ) Is transmitted (step S1005). Specifically, the central control unit 300 generates a command signal in which the command type is “monitor data” and the monitor data of the monitor data storage unit 301 is stored as the data content, and the command signal is wirelessly transmitted via the wireless communication module 310. .. In the present embodiment, central control unit 300 specifies a broadcast address as a destination address in the distribution of monitor data.

When the transmission of the monitor data is completed, the central control unit 300 clears the monitor data confirmation flag to OFF (step S1006).
The processing of steps S1004 to S1006 is processing in which the debug unit 100 transmits a status signal indicating the operating status of each of the one or more mechanical equipment 160 acquired from the wired transmission path via the wireless communication module 310. The processing of is collectively referred to as the status signal transmission processing.

FIG. 10 is a diagram showing an example of the content of command processing executed when the central control unit 300 is in the transmission line monitoring mode.
A case where the command type of the received command signal is “monitor end” will be described.
When the central control unit 300 receives a command signal whose command type is “monitor end”, the central control unit 300 switches the operation mode to the command standby mode. Specifically, central control unit 300 sets a value indicating the command standby mode in the operation mode flag.

A case where the command type of the received command signal is “forced output start” will be described.
When the central control unit 300 receives the command signal whose command type is “forced output start”, the central control unit 300 acquires the forced output information included in the data content of the command signal. The forced output information is a signal or the like for controlling the operation of the mechanical equipment 160 connected to the wired transmission line system 120 and addressed to the mechanical equipment 160. The central control unit 300 updates the contents of the wired output data storage unit 302 based on the forced output information acquired from the command signal. Further, when the command signal of the command type “forced output start” is received, the central control unit 300 sets the forced output flag to ON. Then, the central control unit 300 outputs the forced output information of the wired output data storage unit 302 to the wired transmission path 130 through steps S507 and S508 of the wired processing shown in FIG. Note that the process of storing the forced output information in the wired output data storage unit 302 after receiving the command signal of which the command type is “forced output start” and outputting to the wired transmission path 130 in steps S507 and S508 is the central control The unit 300 receives an operation command for at least one of the one or more mechanical devices 160 via the wireless communication module 310, and transmits the received operation command to the wired transmission path 130 via the driver circuit 320. This is processing and is called operation command transmission processing.

A case where the command type of the received command signal is “compulsory output end” will be described.
When the central control unit 300 receives the command signal whose command type is “compulsory output end”, it clears the compulsory output flag to OFF.
When the operation mode of the central control unit 300 is the transmission path monitoring mode and the command type of the received command signal is other than “monitor end”, “forced output start”, and “forced output end”, the debug unit 100 Discard the received command signal and do not execute command processing.
<3. Wireless terminal>
Details of the configuration and operation of the wireless terminal 110 will be described.
<3-1. Configuration of Wireless Terminal 110>
FIG. 11 is a diagram showing an example of the configuration of the wireless terminal 110. The wireless terminal 110 is a portable information processing terminal having a wireless communication function, such as a smartphone, a tablet, and a laptop computer, and includes a CPU 1200, a memory 1210, a wireless communication module 1220, a display 1230, and an input unit 1240.

The CPU 1200 executes the program stored in the memory.
The memory 1210 includes, for example, a volatile storage device and a non-volatile storage device (for example, a flash memory or a hard disk), and the non-volatile storage device stores a debug application program described later.
The wireless communication module 1220 establishes wireless communication with the debug unit 100 under the control of the CPU 1200, and transmits a command signal and receives a response signal.

The display 1230 is a display device such as a liquid crystal display or an organic EL display, and displays various information under the control of the CPU 1200.
The input unit 1240 is a touch panel or a device such as a keyboard or a mouse that transmits an input from the user of the wireless terminal 110 to the CPU.
<3-2. Operation of Wireless Terminal 110>
FIG. 12 is a flowchart showing an example of the operation of the debug application program executed by the wireless terminal 110. Here, the case where the wireless terminal 110 is a smartphone and the input unit 1240 is a touch panel will be described. It is well known that the same input can be performed by using a keyboard or a mouse, and the description will be omitted.

When the user of the wireless terminal 110 performs a start operation of the debug application program, the wireless terminal 110 performs an initialization process of loading the debug application program stored in the non-volatile storage device into a predetermined position of the volatile storage device. (Step S1301).
When the wireless terminal 110 completes the initialization process of the debug application program, the wireless terminal 110 displays an initial screen 1400, an example of which is shown in FIG. 13 (step S1302). The wireless terminal 110 displays the initial screen 1400 until a touch operation on the join button 1401 is performed.

When the touch operation on the participation button 1401 is performed, the process proceeds to step S1304 (step S1303).
Upon detecting a touch operation on the participation button 1401, the wireless terminal 110 generates a command signal specifying “participation” as the command type, and sends the command signal to the debug unit 100 via the wireless communication module 1220 (step S1304).

The wireless terminal 110 receives the response signal after transmitting the command signal designating "join" as the command type, and refers to the data content of the response signal to confirm whether it is the leader terminal (step S1305). Although the case where participation in the debug group is permitted is described here, the process ends if participation in the debug group is not permitted. When the wireless terminal 110 is the leader terminal, the process proceeds to step S1306, and when the wireless terminal 110 is not the leader terminal, the process proceeds to step S1323.

In the case of the leader terminal, the wireless terminal 110 displays the top screen 1500, an example of which is shown in FIG. 14(A) (step S1306). The wireless terminal 110 displays the top screen 1500 until a touch operation on the setting button 1501 or the monitor start button 1502 is performed.
When the touch operation on the setting button 1501 is performed, the process proceeds to step S1308 (step S1307).

When the touch operation on the setting button 1501 is performed, the wireless terminal 110 generates a command signal specifying “wireless setting confirmation” as the command type, and transmits the command signal to the debug unit 100 via the wireless communication module 1220 (step S1308). ).
The wireless terminal 110 receives the response signal after transmitting the command signal designating “wireless setting confirmation” as the command type, acquires the wireless setting information of the debug unit 100 by referring to the data content of the response signal, and A setting screen 1510, an example of which is shown in FIG. 14(B), is displayed (step S1309). In the setting screen 1510, a display field 1511 that displays the current value of each item of the wireless setting information notified from the debug unit 100, and the changed value when changing the wireless setting information of the debug unit 100 are input. An input field 1512, a setting change button 1513, and a return to TOP button 1514 are displayed. When the input field 1512 is touched, a GUI (Graphical User Interface) for inputting each item of the wireless setting information is displayed, and each item of the wireless setting information can be input according to the GUI. The setting change button 1513 is displayed in a disabled state when the changed value of the wireless setting information is not input in the input field 1512, and does not respond to the touch operation. It is validated when the changed value of the wireless setting information is input in the input field 1512. The wireless terminal 110 displays the setting screen 1510 until a touch operation is performed on the setting change button 1513 or the TOP return button 1514.

If the touch operation is performed on the setting change button 1513 while the setting change button 1513 is enabled, the process proceeds to step S1311 (step S1310).
In the wireless terminal 110, when the setting change button 1513 is enabled and a touch operation is performed on the setting change button 1513, the command type is “wireless setting change” and the data content is input in the input field 1512. A command signal specifying the wireless setting information is generated and transmitted to the debug unit 100 via the wireless communication module 1220 (step S1311). The wireless terminal 110 transmits the command signal designating "wireless setting change" as the command type, receives the response signal having the "normal response" as the response type, and returns to step S1302 to continue the processing.

When a touch operation is performed on the return to TOP button 1514 while the setting screen 1510 is displayed, the process proceeds to step S1306 (step S1312).
When the touch operation is performed on the monitor start button 1502 while the top screen 1500 is displayed, the process proceeds to step S1314 (step S1313).
When the monitor start button 1502 is touched while the top screen 1500 is displayed, the wireless terminal 110 generates a command signal specifying “monitor start” as the command type, and the wireless communication module 1220 is used. And transmits it to the debug unit 100 (step S1314).

When the wireless terminal 110 receives the response signal of which the response type is “normal response” after transmitting the command signal in which “monitor start” is designated as the command type, the wireless terminal 110 displays a monitor screen 1520 as an example in FIG. 14C. It is displayed (step S1315). On the monitor screen 1520, a display field 1521 for displaying the current operation status (input/output state) of the mechanical equipment 160, an input field 1522 for forced output data indicating an operation command addressed to the mechanical equipment 160, and a forced output start button 1523. A monitor end button 1524 is displayed. In the display field 1521, every time a command signal, which is repeatedly transmitted from the debug unit 100 and specifies “monitor data” as a command type, is received, the input/output state is updated according to the data content. In the input field 1522, “ON” to be operated during forced output and “OFF” to be stopped during forced output are displayed for each of a plurality of machinery and equipment, and “ON” and “OFF” are displayed by a touch operation on a corresponding area. Can be reversed. The wireless terminal 110 displays the monitor screen 1520 until a touch operation is performed on the forced output start button 1523 or the monitor end button 1524.

When a touch operation on the forced output start button 1523 is performed while the monitor screen 1520 is displayed, the process proceeds to step S1317 (step S1316).
When the touch operation on the forced output start button 1523 is performed while the monitor screen 1520 is displayed, the wireless terminal 110 displays “forced output start” as the command type and the content entered in the input field 1522 as the data content. A command signal designating forced output data indicating an operation command addressed to the mechanical equipment 160 is generated and transmitted to the debug unit 100 via the wireless communication module 1220 (step S1317).

The wireless terminal 110 transmits a command signal specifying "forced output start" as the command type, and then displays a monitor screen 1530, an example of which is shown in FIG. 14D (step S1318). On the monitor screen 1530, a display field 1531 for displaying the current operation status (input/output state) of the mechanical equipment 160, a display field 1532 for forced output data indicating an operation command addressed to the mechanical equipment 160, and a forced output end button 1533. Is displayed. In the display column 1531, every time a command signal, which is repeatedly transmitted from the debug unit 100 and specifies “monitor data” as a command type, is received, the input/output state is updated according to the data content. In the display field 1532, the content indicating the forced output data designated in the data content of the command signal transmitted in step S1317 is displayed. The wireless terminal 110 displays the monitor screen 1530 until a touch operation on the forced output end button 1533 is performed.

When a touch operation on the forced output end button 1533 is performed while the monitor screen 1530 is displayed, the process proceeds to step S1320 (step S1319).
When the forcible output end button 1533 is touched while the monitor screen 1530 is displayed, the wireless terminal 110 generates a command signal specifying “compulsory output end” as the command type, and the wireless communication module 1220 is used. It transmits to the debug unit 100 (step S1320), returns to step S1315, and continues processing.

When the monitor end button 1524 is touched while the monitor screen 1520 is displayed, the process proceeds to step S1322 (step S1321).
When a touch operation is performed on the monitor end button 1524 while the monitor screen 1520 is displayed, the wireless terminal 110 generates a command signal in which “monitor end” is designated as the command type, and the debug unit is connected via the wireless communication module 1220. 100 (step S1322), the process returns to step S1306, and the process is continued.

After transmitting the command signal designating "participation" as the command type, when receiving the response signal designating the information indicating that the data content is not the leader terminal, the wireless terminal 110 shows an example in FIG. 15(A). The top screen 1600 is displayed (step S1323). The wireless terminal 110 displays the top screen 1600 until the monitor button 1601 is touched.

When the touch operation is performed on the monitor button 1601 while the top screen 1600 is displayed, the process proceeds to step S1325 (step S1324).
When the touch operation is performed on the monitor button 1601 while the top screen 1600 is displayed, the wireless terminal 110 displays a monitor screen 1610, an example of which is shown in FIG. 15B (step S1325). On the monitor screen 1610, a display field 1611 for displaying the current operating status (input/output status) of the mechanical equipment 160 and a return button 1612 are displayed. In the display field 1611, the input/output state is updated according to the data content each time a command signal, which is repeatedly transmitted from the debug unit 100 and specifies “monitor data” as a command type, is received. The wireless terminal 110 displays the monitor screen 1610 until the return button 1612 is touched.

When a touch operation is performed on the return button 1612 while the monitor screen 1610 is displayed, the process returns to step S1323 (step S1326).
<4. Effect>
The debug unit 100 transmits the status signal acquired from the wired transmission path 130 via the wireless communication module 310. As a result, if the user of the wireless terminal 110 is within the wireless communication range of the debug unit 100, whether the signal is properly transmitted in the wired transmission path 130 while being near the installation position of the mechanical equipment 160, It is possible to confirm whether or not the mechanical equipment 160 is operating properly by the signal transmitted through the wired transmission path 130.

The debug unit 100 outputs an operation command for controlling the mechanical equipment 160 acquired via the wireless communication module 310 to the wired transmission path 130. As a result, the user of the wireless terminal 110 can transmit a signal to the equipment via the wired transmission path 130, while being near the installation position of the mechanical equipment 160, within the wireless communication range of the debug unit 100. it can.

The debug unit 100 transmits the status signal acquired from the wired transmission path 130 to the plurality of wireless terminals 110 via the wireless communication module 310. Thereby, a plurality of users can participate in the debugging work and monitor whether the signal is properly transmitted in the wired transmission path 130.
The debug unit 100 defines a leader terminal, and for only the leader terminal, command types “monitor start”, “monitor end”, “forced output start”, “forced output end”, “wireless setting confirmation”, The transmission of command signals that specify "change wireless settings" is permitted. This can prevent simultaneous reception of inconsistent command signals from a plurality of wireless terminals 110.
(Supplement)
Although the debug system according to one aspect of the present disclosure has been described above based on the embodiment, the present invention can be modified as below and the present disclosure is not limited to the one described in the above embodiment.

(1) In the above-described embodiment, a predetermined number of wireless terminals 110 are allowed to participate in a debug group in the order in which a command signal in which “participation” is specified as a command type is received, and thereafter the command type is Even though the command that specifies "join" is received, the permission to join the debug group is not given, but the command is not limited to this. For example, the terminal IDs of a plurality of wireless terminals 110 are stored in advance in the built-in memory of the central control unit 300 of the debug unit 100, and only the wireless terminals 110 having the terminal IDs stored in the built-in memory enter the debug group. May be allowed to participate. The MAC address or IP address of the wireless terminal 110 may be used as the terminal ID.

(2) In the above-described embodiment, when the command signal that specifies “participation” as the command type is first received, the wireless terminal 110 that is the transmission source of the command signal is determined to be the leader terminal. Not limited to For example, the terminal ID of the wireless terminal 110 may be stored in advance in the built-in memory of the central control unit 300 of the debug unit 100, and the wireless terminal 110 having the terminal ID stored in the built-in memory may be determined as the reader terminal. .. The MAC address or IP address of the wireless terminal 110 may be used as the terminal ID.

(3) In the above embodiment, only the wireless terminal 110 determined to be the leader terminal has the command types “monitor start”, “wireless setting confirmation”, “wireless setting change”, “monitor end”, It is assumed that the transmission of the command signal designating “forced output start” and “forced output end” is permitted, but the present invention is not limited to this. For example, one wireless terminal 110 of the plurality of wireless terminals 110 belonging to the debug group is determined to be the first leader terminal, and the command types of the first leader terminal are “wireless setting confirmation” and “wireless setting confirmation”. The transmission of the command signal specifying “change” may be permitted. Further, one of the plurality of wireless terminals 110 belonging to the debug group, which is different from the first leader terminal, is determined to be the second leader terminal, and the second leader terminal is given a command type “monitor”. The transmission of the command signal specifying "start", "monitor end", "forced output start", and "forced output end" may be permitted.

(4) The debug unit 100 may be used as a relay device that relays communication between the wired control system 20 and the wireless terminal 110 during normal operation of the wired control system other than during debugging work.
(Supplement 2)
Hereinafter, the configuration of the present disclosure will be further described.

(1) A relay device according to a first aspect of the present disclosure is a relay device that relays communication between a mobile terminal and a wired control system that controls a plurality of facilities connected via a wired transmission path, Wired connection means for connecting to the wired transmission path, wireless communication means for wirelessly communicating with a mobile terminal, and status signals indicating the operating status of each of the plurality of facilities are acquired from the wired transmission path via the wired connection means. Status signal acquisition processing, status signal transmission processing for transmitting the acquired status signal via the wireless communication means during a predetermined period, and among the plurality of facilities via the wireless communication means during the predetermined period. A control unit that receives an operation command for at least one piece of equipment, and executes an operation command transmission process of transmitting the operation command to the wired transmission line via the wired connection unit.

(2) The relay device according to the second aspect of the present disclosure is, in the relay device according to the first aspect, monitoring the plurality of facilities wirelessly with respect to mobile terminals belonging to a group including one or more mobile terminals. Is permitted, the control means further receives a participation instruction requesting participation in the group via the wireless communication unit, and determines whether or not the portable terminal of the transmission source of the participation instruction can participate in the group. Then, a participation acceptance process for notifying the mobile terminal of the transmission source of the determination result is executed.

(3) In the relay device according to the third aspect of the present disclosure, in the relay device according to the second aspect, the control unit may further include a mobile terminal that is permitted to participate in the group. It is characterized in that it is determined whether or not it is a leader terminal, and when it is determined to be the leader terminal, an authorization process for giving the transmission authority of the operation command to the mobile terminal of the transmission source is executed.

(4) In the relay device according to the fourth aspect of the present disclosure, in the relay device according to the third aspect, the authorization processing is performed on the mobile terminal determined to be the leader terminal, and further from the relay device. This is a process of giving a transmission authority of a start command and an end command of wireless transmission of the status signal, and the predetermined period is a period from the reception of the start command through the wireless communication unit to the reception of the end command. Is characterized in that.

(5) In the relay device according to the fifth aspect of the present disclosure, in the relay device according to the fourth aspect, the control unit waits for the start command from after power-on until it receives the start command. When the start command is received in the standby mode, the standby mode is ended, and when the participation command is received in the standby mode, the participation acceptance process is executed, and when the standby mode is not set, the participation command is executed. Is received, the participation acceptance process is not executed.

(6) A relay method according to a sixth aspect of the present disclosure is a relay device that relays communication between a mobile terminal and a wired control system that controls a plurality of facilities connected via a wired transmission path. A relay method executed by a relay device comprising a wireless communication means for performing wireless communication with a terminal and a wired connection means for connecting to the wired transmission path, wherein an operation status of each of the plurality of facilities is determined via the wired connection means. A status signal acquisition process for acquiring the status signal shown from the bidirectional wired transmission path, a status signal transmission process for transmitting the acquired status signal via the wireless communication means during a predetermined period, and via the wireless communication means. And receiving an operation command for at least one of the plurality of facilities, and transmitting the received operation command to the bidirectional wired transmission path via the wired connection means. Is characterized by.

(7) A system according to a seventh aspect of the present disclosure is a relay system that relays communication between a mobile terminal and a wired control system that controls a plurality of facilities connected via a wired transmission path. The relay device includes a terminal and a relay device, and the relay device includes a wired connection unit that connects to the wired transmission path, a wireless communication unit that wirelessly communicates with the mobile terminal, and the plurality of facilities via the wired connection unit. A status signal acquisition process of acquiring a status signal indicating each operation status from the wired transmission path, a status signal transmission process of transmitting the acquired status signal via the wireless communication unit during a predetermined period, and the predetermined period of time. An operation command transmission process for receiving an operation command for at least one of the plurality of facilities via the wireless communication means, and transmitting the operation command to the wired transmission path via the wired connection means. And a control means for executing.

According to the debug system of the present disclosure, there is a possibility that the debug work of the wired control system can be efficiently executed.

100 debug unit 110 wireless terminal 300 central control unit 310 wireless communication module 320 driver circuit

Claims (4)

A relay device for relaying communication between a mobile terminal and a wired control system for controlling a plurality of facilities connected via a wired transmission path,
Wired connection means for connecting to the wired transmission path,
Wireless communication means for performing wireless communication with the mobile terminal,
Status signal acquisition processing for acquiring status signals indicating the operating status of each of the plurality of facilities from the wired transmission path via the wired connection means, and transmitting the acquired status signals via the wireless communication means within a predetermined period. Situation signal transmission processing, and receives an operation command to at least one of the plurality of equipment via the wireless communication means during the predetermined period, the operation instruction, via the wired connection means, A control means for executing an operation command transmission process for transmitting to the wired transmission path ,
Mobile terminals belonging to a group consisting of one or more mobile terminals are allowed to monitor the plurality of facilities wirelessly,
The control means further comprises
A participation command requesting participation in the group is received via the wireless communication unit, the mobile terminal of the transmission source of the participation command determines whether or not the mobile terminal can participate in the group, and the determination result is the mobile terminal of the transmission source. Acceptance processing to notify
For the mobile terminal permitted to participate in the group, it is determined whether or not the mobile terminal is a leader terminal, and if it is determined that the mobile terminal is the leader terminal, the mobile terminal of the transmission source is determined as described above. Execute the authorization process that gives the operation command transmission authorization,
The authorization process is further performed on the mobile terminal determined to be the leader terminal,
Process for giving authority to transmit start command and end command of wireless transmission of the status signal from the relay device
And
During the predetermined period, the end command is received after the start command is received via the wireless communication unit.
A relay device that is the period until reception . The control means is in a standby mode waiting for the start command until the start command is received after the power is turned on, and when the start command is received in the standby mode, the standby mode is ended and the standby mode is set. When the participation command is received, the participation reception process is executed, and when the participation command is received when the standby mode is not set, the participation reception process is not executed.
The relay device according to claim 1 . A relay device that relays communication between a mobile terminal and a wired control system that controls a plurality of facilities connected via a wired transmission path, and wireless communication means for performing wireless communication with the mobile terminal and the wired transmission path. A relay method executed by a relay device comprising a wired connection means for connection,
Mobile terminals belonging to a group consisting of one or more mobile terminals are allowed to monitor the plurality of facilities wirelessly,
Status signal acquisition processing for acquiring status signals indicating the operating status of each of the plurality of facilities from the bidirectional wired transmission path via the wired connection means,
A status signal transmission process of transmitting the acquired status signal via the wireless communication means during a predetermined period;
Operation command transmission for receiving an operation command for at least one of the plurality of facilities via the wireless communication means, and transmitting the received operation command to the two-way wired transmission path via the wired connection means. and processing,
A participation command requesting participation in the group is received via the wireless communication unit, the mobile terminal of the transmission source of the participation command determines whether or not the mobile terminal can participate in the group, and the determination result is the mobile terminal of the transmission source. Acceptance processing to notify
For the mobile terminal permitted to participate in the group, it is determined whether or not the mobile terminal is a leader terminal, and if it is determined that the mobile terminal is the leader terminal, the mobile terminal of the transmission source is determined as described above. And an authorization process that gives the authorization to send operation commands,
The authorization process is further performed on the mobile terminal determined to be the leader terminal,
Process for giving authority to transmit start command and end command of wireless transmission of the status signal from the relay device
And
During the predetermined period, the end command is received after the start command is received via the wireless communication unit.
The relay method that is the period until receiving . A relay system that relays communication between a mobile terminal and a wired control system that controls a plurality of facilities connected via a wired transmission path,
A mobile terminal and a relay device are provided,
The relay device is
Wired connection means for connecting to the wired transmission path,
Wireless communication means for performing wireless communication with the mobile terminal,
Status signal acquisition processing for acquiring status signals indicating the operating status of each of the plurality of facilities from the wired transmission path via the wired connection means, and transmitting the acquired status signals via the wireless communication means within a predetermined period. Situation signal transmission processing, and receives an operation command to at least one of the plurality of equipment via the wireless communication means during the predetermined period, the operation instruction, via the wired connection means, A control means for executing an operation command transmission process for transmitting to the wired transmission path,
Mobile terminals belonging to a group consisting of one or more mobile terminals are allowed to monitor the plurality of facilities wirelessly,
The control means further comprises
A participation command requesting participation in the group is received via the wireless communication unit, the mobile terminal of the transmission source of the participation command determines whether or not the mobile terminal can participate in the group, and the determination result is the mobile terminal of the transmission source. Acceptance processing to notify
For the mobile terminal permitted to participate in the group, it is determined whether or not the mobile terminal is a leader terminal, and if it is determined that the mobile terminal is the leader terminal, the mobile terminal of the transmission source is determined as described above. Execute the authorization process that gives the operation command transmission authorization,
The authorization process is further performed on the mobile terminal determined to be the leader terminal,
Process for giving authority to transmit start command and end command of wireless transmission of the status signal from the relay device
And
During the predetermined period, the end command is received after the start command is received via the wireless communication unit.
The relay system, which is the period until reception .

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