JP2004356955A - Communication control unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To synchronize a clocking counter to reference time by a single reference pulse generation section in an environment in which an input device and a plurality of information processors are connected to a single line. <P>SOLUTION: In a communication controlling device, the input device 14 having the clocking counter 38 and the plurality of information processors 10, 12 are connected to the single communication line 18; the plurality of information processors 10, 12 acquire a preset token for communicating with the input apparatus 14; one information processor 10 of the plurality of information processors 10, 12 has a synchronization counter 21 that is reset and clocked by the reference pulse from a reference pulse generator 22; and the contents of the clocking counter 38 of the input device are synchronized with a reference time by writing the contents of the synchronization counter 21 to the clocking counter of the input apparatus when the token is acquired, in case that the token is not acquired when the reference pulse is outputted from the reference pulse generator 22. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a communication control device, and for example, relates to a communication control device suitable for a monitoring control system that monitors or controls a device to be controlled.
[0002]
[Prior art]
The communication control device includes an input device that captures device data of a device to be controlled, and a plurality of information processing devices that monitor or control the device based on the device data. Used in the system. The monitoring and control system of the power plant detects an event that has occurred in the controlled device, for example, a change in the opening / closing state of the valve, measures the time of occurrence of the event by a time counter, and attaches the event occurrence time to the event content. The data is temporarily stored in the input device as state data (hereinafter, SOE data: Sequence of Event Data). Then, based on the SOE data from the input device, the monitoring and control device having the information processing device executes operation monitoring of the power plant, analysis of the cause at the time of occurrence of a failure, operation of equipment, and the like.
[0003]
In such a monitoring and control system, in order to accurately measure the event occurrence time, a reference pulse generator, for example, a GPS receiver is installed for each input device, and each of the input devices is used by using a reference pulse from the GPS receiver. 2. Description of the Related Art Synchronizing a time counter of an input device with a reference time, for example, a world standard time, is performed.
[0004]
In this case, since the number of GPS receivers installed increases in accordance with the number of input devices installed, a single GPS receiver is monitored by a plurality of monitoring devices via a communication line in order to suppress an increase in the number of GPS receivers installed. It is connected to a control device, and the event occurrence time of SOE data is synchronized with the reference time using the reference pulse of the GPS receiver (for example, Patent Document 1).
[0005]
[Patent Document 1]
JP 2003-58240 A
[0006]
[Problems to be solved by the invention]
By the way, in order to suppress the increase in the number of GPS receivers to be installed and to reduce the number of communication lines between the supervisory control device and the input device, a single supervisory control device among a plurality of supervisory control devices is used. It is conceivable to connect the GPS receiving device and connect each monitoring control device and each input device to a single communication line (hereinafter, multi-drop connection).
[0007]
In the case of this multi-drop connection, generally, in order to prevent frame data from each monitoring and control device from colliding in the communication line and being discarded, a transmission right for permitting communication between the monitoring and control device and the input device is generally used. Is set, and the frame data can be transmitted to the input device only for the monitoring control device that has acquired the transmission right, thereby ensuring the reliability of communication.
[0008]
In a monitoring and control system employing such a multi-drop connection, when a time counter of each input device is synchronized with a reference time using a single GPS receiver, a signal is transmitted when a reference pulse is generated by the GPS receiver. Without the right, the supervisory control device cannot adjust the time counter of the input device to the reference time. As a result, a deviation from the reference time occurs in the clock counter, and there is a possibility that an accurate event occurrence time cannot be measured.
[0009]
An object of the present invention is to provide a single reference pulse generator to set a time counter of an input device to a reference time in an environment in which an input device that captures device data and a plurality of information processing devices are connected to a single line. To synchronize.
[0010]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, a communication control device according to the present invention has a time counter for measuring time, an input device that takes in state information of a device to be controlled, attaches the time measured by the time counter, and temporarily accumulates it as state data. And a plurality of information processing apparatuses for monitoring or controlling devices by capturing state data of the input apparatus, wherein the input apparatus and the plurality of information processing apparatuses are connected to a single communication line, and Is a communication counter that acquires a preset transmission right and communicates with the input device, and one of the plurality of information processing devices is a synchronous counter that is reset and clocked by a reference pulse from a reference pulse generator. If the transmission right cannot be acquired when the reference pulse is output from the reference pulse generation unit, the content of the synchronization counter is counted by the input device when the transmission right is acquired. And writes to.
[0011]
That is, since the synchronization counter of the information processing device is always synchronized with the reference time according to the reference pulse, the time measured while the transmission right cannot be acquired is also synchronized with the reference time. Therefore, if the content of the synchronization counter is written as it is to the clock counter of the input device, the clock counter can be synchronized with the reference time.
[0012]
In this case, it is desirable that the content of the event (for example, a change in the opening / closing state of the valve) generated in the controlled device and the event occurrence time be stored in the input device as state data, that is, SOE data. . Thus, if the state data is analyzed, the occurrence of an event can be grasped in a time-series manner. For example, even when a failure occurs in a device, the cause of the failure can be grasped accurately.
[0013]
The communication control device according to the present invention includes a plurality of monitoring control devices that obtain device data of devices such as a power plant (for example, a valve, a temperature sensor, and a pressure sensor) using an input device, and monitor and control the devices based on the device data. And a plurality of monitoring control devices and input devices can be applied to a monitoring control system connected to a single communication line. In this case, a monitoring control system is configured by using the above information processing device as a monitoring control measure.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
Hereinafter, a first embodiment of a monitoring control system using a communication control device of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of the monitoring and control system, and FIG. 2 is a time chart showing the operation of the monitoring and control system.
[0015]
First, the overall configuration of the monitoring control system will be described with reference to FIG. The monitoring control system 1 monitors or controls devices such as the power plant 2. The monitoring control system is configured from monitoring control devices 10 and 12 having information processing devices, input devices 14 and 16, and the like, and is installed in a building. The monitoring control devices 10 and 12 and the input devices 14 and 16 are connected to a single communication line 18 by multi-drop connection.
[0016]
The monitoring and control device 10 includes a central processing unit (hereinafter, CPU) 18 and a process communication device (hereinafter, PIOP) 20 having a synchronous counter 21, and analyzes the cause of failure of the equipment of the power plant 2. Is what you do. The monitoring control device 12 includes a CPU 19 and a PIOP 23, and generates a command for operating the equipment of the power plant 2. One of the supervisory control devices 10 and 12 that has acquired a preset transmission right communicates with the input devices 14 and 16 as a master, and the other device stands by as a slave.
[0017]
A single GPS receiver 22 is connected to only the monitoring control device 10 among the monitoring control devices 10 and 12. The GPS receiving device 22 is connected via a GPS cable 24 to a synchronization counter 21 provided in the PIOP 20 of the monitoring control device 10. The GPS receiver 22 functions as a reference pulse generator, and generates a reference pulse synchronized with a world standard time (hereinafter referred to as a reference time) every one minute (60000 ms), for example, by receiving a signal from a satellite. It is.
[0018]
The input device 14 includes a station (hereinafter, ST) 27 having a relay counter 26, and input modules (hereinafter, DI) 28, 30. The DI 28 has a time counter 38 and is connected to the valve 32 which is one of the process input groups of the power plant 2. The DI 30 has a time counter 39 and is connected to the temperature sensor 34. The input device 16 includes ST31, ST31, DI33 connected to the pressure sensor 36, DI35 connected to the flow rate sensor 37, and the like. The input devices 14 and 16 are set to always wait as slaves, and transmit response data only when receiving frame data from the monitoring control devices 10 and 12.
[0019]
Each of the counters, for example, the synchronous counter 21, the relay counter 26, and the time counters 38 and 39 is composed of a 60000 decimal counter. The 60000-base counter periodically counts up from 0 to 59999.
[0020]
The operation of the monitoring and control system 1 configured as described above will be described by taking as an example a case where SOE data of the valve 35 is acquired. When it is determined by the DI 28 that an event has occurred in the valve 32, for example, that the valve 32 has been closed, the status data, ie, SOE data is stored in the DI 28 by adding the event occurrence time to the generated status information, ie, the event content. You.
[0021]
On the other hand, when the monitoring control device 10 acquires the transmission right and communicates with the input device 14, the SOE data of the DI 28 is captured by the monitoring control device 10 via ST27. The captured SOE data is analyzed by the monitoring control device 10. Therefore, the content of the event that has occurred in the valve 32 is grasped in chronological order. Similarly, when the monitoring control device 12 acquires the transmission right, the SOE data of the DI 28 is captured by the monitoring control device 12.
[0022]
The communication control of such a monitoring control system will be described with reference to a time chart shown in FIG. As shown in FIG. 2, the horizontal axis indicates the passage of time. The upper part of the vertical axis shows a time chart of the line output a of PIOP20, the line output b of PIOP23, the line output c of ST27, and the line output d of ST31 in order from the highest level. Also, in the lower part thereof, in order, the time e of the output e of the GPS receiver, the counter value f of the synchronous counter 21, the counter value g of the relay counter 26, the counter value h of the clock counter 38, and the count value i of the clock counter 39 are shown. The chart is shown.
[0023]
First, with reference to time charts a to d in FIG. 2, communication control in which the monitoring control device 10 acquires SOE data from the input device 14 will be described. When the monitoring control apparatus 10 acquires the transmission right, the PIOP 20 transmits a command frame 40 requesting acquisition of SOE data to ST27, and receives a response frame 41 to which SOE data is added from ST27. Next, PIOP 20 transmits command frame 42 to ST31, and receives a response frame from ST31. Thereby, the monitoring control device 10 acquires the SOE data from the input device 14. When the acquisition of the SOE data is completed, the PIOP 20 transmits the transmission right release frame 44 to the PIOP 23, that is, the monitoring control device 12.
[0024]
Since the monitoring control device 12 that has received the transmission right release frame 44 acquires the transmission right, the PIOP 23 transmits the command frame 45 to ST27 and receives the response frame 46 from ST27. Next, PIOP 23 transmits command frame 47 to ST31, and receives response frame 48 from ST31. Thereby, the monitoring control device 12 acquires SOE data from the input device 14. When the acquisition of the SOE data is completed, the acquisition of the SOE data is repeated by the PIOP 23 transmitting the transmission right release frame 47 to the PIOP 20. It should be noted that the monitoring control devices 10 and 12 also obtain SOE data from the input device 16 by the same control procedure.
[0025]
By the way, if the monitoring control device 10 has acquired the transmission right when the reference pulse 5 is generated by the GPS receiver 22, the time counters 38 and 39 are reset every time the reference pulse 5 is generated, and the reference time is reset. Sync to. However, if the monitoring control device 10 has not acquired the transmission right when the GPS receiver 22 generates the reference pulse, the clock counters 38 and 39 cannot be synchronized. For example, as shown in the time charts e to i in FIG. 2, when the reference pulse 5 is generated, the PIOP 20 has not acquired the transmission right release frame. Therefore, although the synchronization counter 21 is reset by the reference pulse 5 and synchronizes with the reference time, the relay counter 26 and the synchronization counters 38 and 39 are not reset, so that a deviation from the reference time occurs.
[0026]
Therefore, a control procedure for synchronizing the relay counter 26 and the synchronization counters 38 and 39 with the reference time will be described with reference to FIG. As shown in FIG. 2, when the supervisory control device 10 does not acquire the transmission right when the GPS receiver 22 generates the reference pulse 5, only the synchronization counter 21 is reset according to the reference pulse 5, and the synchronization counter 21 is reset. To count up. Then, at the same time when the monitoring control device 10 acquires the transmission right, the PIOP 20 transmits the counter synchronization frame 50 to which the counter value 55 of the synchronization counter 21 is added to ST27 and ST31. As a result, the counter value 55 of the synchronous counter 21 is written to the contents of the relay counter 26. Next, the counter value 57 of the relay counter 26 is overwritten on the content of the time counter 38, and the counter value 61 is overwritten on the content of the time counter 39. As a result, the counter values of the synchronization counter 21, the relay counter 26, and the time counters 38 and 39 are all the same.
[0027]
That is, according to the present embodiment, the synchronization counter 21 of the monitoring and control device 10 is always synchronized with the reference time according to the reference pulse 5, so that the counter value during which the transmission right cannot be acquired is also synchronized with the reference time. I have. Therefore, if the counter value of the synchronous counter 21 is written to the relay counter 26 as it is and the written contents of the relay counter 26 are written to the time counters 38 and 39, the time counters 38 and 39 become the same as the contents of the synchronous counter 21. It will be. As a result, the time counters 38 and 39 can be synchronized with the reference time.
[0028]
The monitoring control system to which the present invention is applied based on the first embodiment has been described above. Here, the frame configuration of the frame data used in the present embodiment and the detailed configuration of the PIOPs 20, ST27, and DI28 will be described. This will be described with reference to FIGS. The PIOP 23 has the same configuration as the PIOP 20 except for the synchronization counter 21, the ST31 has the same configuration as the ST27, and the DIs 30, 33, and 35 have the same configuration as the DI 28.
[0029]
The frame configuration of the frame data will be described with reference to FIG. The frame data 4 is transmitted in the communication line 18 and is used for, for example, a command frame, a response frame, a master right release frame, a counter synchronization frame, and the like. As shown in FIG. 3, the frame data 4 includes, in order from the beginning, a flag area 200, a source node area 202, a destination node area 203, an address area 204, a control data area 205, a data length area 206, a data area 208, and the like. It is composed of The flag area 200 stores a flag indicating the start of a frame. The source node area 202 stores a source node number. The node number is a number for specifying a device connected to the communication line 18. For example, in the present embodiment, the node number is set as 0 for PIOP20, 1 for PIOP23, 2 for ST27, and 3 for ST31. ing. The transmission destination node area 203 stores a transmission destination node number. The address area 204 stores the address of the destination node in the case of a command frame, and stores the address of the source node in the case of a response frame. The control data area 205 stores identification data indicating a frame type. The data length area 206 stores a data length, and the data area 208 stores data, for example, a counter value.
[0030]
The detailed configuration of the PIOP 20 will be described with reference to FIG. As shown in FIG. 4, the PIOP 20 includes a synchronization counter 21, a transmission controller 56, a transmission buffer 58 of a dual-port RAM, a reception controller 60, a reception buffer 62 of a dual-port RAM, an MPU 64 operating independently of the CPU 18, a ROM 68, It comprises a port RAM 80, a transmission / reception driver 74 and the like.
[0031]
First, a procedure for transmitting a command frame by the PIOP 20 will be described. First, a command frame is written into the transmission buffer 58 by the MPU 62, and a transmission request is written into a transmission activation register 56a provided in the transmission controller 56. Next, the transmission controller 56 selects the selector 72 to the transmission buffer 58 side, and outputs a transmission permission command to the transmission / reception driver 74. Then, the command frame in the transmission buffer 58 is input to the conversion unit 73 via the selector 72 and is converted from parallel data to serial data. The converted command frame is transmitted by the transmission / reception driver 74 to the input devices 14 and 16 via the communication line 18.
[0032]
Next, a procedure for receiving a command frame by the PIOP 20 will be described. First, the response frames transmitted from the input devices 14 and 16 are received by the transmission / reception driver 74 via the communication line. Next, the reception frame synchronized with the received response frame is converted from serial data to parallel data by the conversion unit 76 based on the reception clock generated by the clock generation unit 78. The flag of the converted response frame is identified by the reception controller 60 and written into the reception buffer 62. When the reception of the response frame is completed, the reception controller 60 issues an interrupt request to the MPU 64. The MPU 64 compares the node number of the response frame with the node number 68a of the ROM 68. When the compared node numbers match, the response frame is written to the RAM 80. The latest written response frame is read out in a last-in first-out manner in response to a request from the CPU 18.
[0033]
Further, a transmission procedure of the counter synchronization frame by the PIOP 20 will be described. The counter synchronization frame is output only from the monitoring control device 10 to which the GPS receiving device 22 is connected. First, a reference pulse is generated at one-minute intervals by the GPS receiver 22 and input to the synchronization counter 21 and the transmission controller 56. The synchronous counter 21 is reset by the input reference pulse, and counts up in accordance with a clock generated from the clock generator 59 at 1 ms intervals. Further, when the reference pulse is input, the transmission controller 56 determines whether or not the monitoring control device 10 is in a transmittable state. The state in which transmission is possible means a state in which the transmission right has been acquired and the period from the start of command frame transmission to the completion of response frame reception is excluded. When it is determined that the transmission is possible, the selector 72 is selected by the transmission controller 56 on the synchronization counter 21 side, and the content (counter value) of the synchronization counter 21 is stored in the data area 208 of the counter synchronization frame. Then, the counter synchronization frame is transmitted to ST27 and ST31 via selector 72, conversion unit 73, and transmission / reception driver 74. On the other hand, when it is determined that the transmission is not possible, the transmission controller 56 causes the transmission of the counter synchronization frame to wait, and the synchronization counter 21 continues to count up. Thereafter, when the transmission becomes possible, the counter value of the synchronization counter 21 is added to the counter synchronization frame, and the added counter synchronization frame is output to ST27 and ST31.
[0034]
The detailed configuration of ST27 will be described with reference to FIG. As shown in FIG. 5, ST27 includes a relay counter 26, a transmission controller 84, a transmission buffer 86 of a dual port RAM, a reception controller 88, a reception buffer 90 of a dual port RAM, an MPU 90, a ROM 92, a dual port RAM 94, a transmission and reception driver 95. , A bus control master 96 and the like.
[0035]
First, the procedure for receiving a command frame by ST27 will be described. First, a command frame transmitted from the PIOP 20 or the like is received by the transmission / reception driver 95 via the communication line 18. The received command frame is converted from serial data to parallel data by the conversion unit 100 based on the reception clock generated by the clock generation unit 98. The flag of the converted response frame is identified by the reception controller 88 and written to the reception buffer 90. When the reception of the response frame is completed, the reception controller 88 issues an interrupt request to the MPU. When the node number of the response frame matches the node number 92a of the ROM 92, the MPU 90 reads the SOE data from the DI 28 or DI 30 corresponding to the address of the command frame via the bus, and attaches the read SOE data. To generate a response frame.
[0036]
Next, the transmission procedure of the response frame in ST27 will be described. First, a response frame is generated by the MPU 90, and the generated response frame is written in the transmission buffer 86, and a transmission request is written in the transmission activation register 84 a of the transmission controller 84. When the transmission permission command is output from the transmission controller 84 to the transmission / reception driver 95, the response frame of the transmission buffer 86 is converted from parallel data to serial data by the conversion unit 97, and then transmitted / received by the transmission / reception driver 95 to the communication line 18. Is transmitted to the PIOP 20 or the like.
[0037]
Further, the receiving procedure of the counter synchronization frame by ST27 will be described. First, the counter synchronization frame transmitted from the PIOP 20 is received by the transmission / reception driver 95 via the communication line 18 and then identified and received by the reception controller 88. After the counter value of the received counter synchronization frame is determined by the counter value determination unit 88a provided in the reception controller 88, it is written into the relay counter 26. The written relay counter 26 counts up from the written value based on the clock generated from the clock generation unit 102 at intervals of 1 ms. The count value of the relay counter 26 is transmitted to the DI 28 and DI 30 via the bus 104 by the bus controller master 96 in response to a command from the MPU 90.
[0038]
The detailed configuration of the DI 28 will be described with reference to FIG. As shown in FIG. 6, the DI 28 includes a time counter 38, a DI input unit 106, latches (FFs) 108 and 110 functioning as storage devices, a change determination unit 112, a bus controller slave 116, and the like.
[0039]
First, the procedure for acquiring SOE data using the DI 28 will be described. First, the state information of the valve 32 is input to the DI input unit 106 at predetermined intervals. The change in the input state information, that is, the occurrence of an event is detected by the change determination unit 112. For example, the change determination unit 112 detects that the valve 32 has changed from the open state to the closed state. When the occurrence of an event is detected, the change determination unit 112 outputs a latch pulse to the latches 108 and 110. The latch pulse latches the counter value of the time counter 38 by the latch 108, and the state information from the DI input unit 106, that is, the event content is latched by the latch 110. Then, when there is a read request from ST27, the counter value of latch 108 and the contents of the event of latch 110 are respectively read by bus control section 116 and transmitted to ST27 as state data, that is, SOE data.
[0040]
Next, an operation procedure in which the time counter 38 of the DI 28 is synchronized with the reference time will be described. The counter value of the relay counter 26 output from ST27 is input to the bus controller slave 116 via the bus 104, and then written to the time counter 38 by the bus controller slave 116. Then, the clock counter 38 counts up at 1 ms intervals from the written value according to the clock of the clock generation unit 114. Therefore, since the content of the time counter 38 is the same as that of the relay counter 26, the time counter 38 is synchronized with the reference time.
(Embodiment 2)
A second embodiment of the monitoring control system using the communication control device of the present invention will be described with reference to FIGS. FIG. 7 is another block diagram of the station (ST), FIG. 8 is another block diagram of the input module (DI), and FIG. 9 is a time chart showing another operation of the monitoring control system. This embodiment is different from the first embodiment in that, when a counter synchronization frame is received in ST27, the counter value of the relay counter 26 in ST27 is reset and timed, and the counted counter value returns to zero. Sometimes, the time counter 38 is reset.
[0041]
As shown in FIG. 7, the difference from ST27 in FIG. 5 is that a reset pulse line 124 is wired in addition to a bus 104 connecting ST27 and DIs 28 and 30, and furthermore, the relay counter 26 is connected to the reset pulse line 124 with zero. That is, the connection is established via the determination unit 122. As shown in FIG. 8, the difference from the DI 28 of FIG. 6 is that the wiring connecting the bus controller slave 116 and the clock counter 38 is removed, and the clock counter 38 is connected to the reset pulse line 24. It is in.
[0042]
The operation of the ST 27a and DI 28a thus configured will be described with reference to FIG. When the count value of the relay counter 26 is determined to be zero by the zero determination unit 122, the reset pulse is input from the zero determination unit 122 to the time counter 38 via the reset pulse line 124, and the counter value of the time counter 38 Reset 130.
[0043]
That is, since the relay counter 26 in ST27 is synchronized with the reference time by the count synchronization frame 50, if the timer 38 is reset at the same time as the relay counter 26 becomes zero, the counting of the timer 38 starts when This can be adjusted when the reference pulse 51 is generated by the GPS receiver 22.
[0044]
As described above, the example in which the communication control device according to the present invention is used in the monitoring control system based on the first and second embodiments has been described. However, the communication control device according to the present invention is applicable to various industries and information fields. can do.
[0045]
Although the example in which the GPS receiver 22 is used as the reference pulse generator has been described, an internal clock built in the computer of the monitoring control device 10 may be used instead of the GPS receiver 22. According to this, although the occurrence time of the event determined by the DIs 28 and 30 cannot be measured in accordance with the world standard time, the time difference between the event occurrence times between the DIs can still be grasped, and the event occurrence time can be grasped. Can be simplified in the configuration of the monitoring control system for analyzing time series.
[0046]
Further, for convenience of explanation, an example in which two monitoring control devices and two input devices are connected to a communication line has been described, but the number of monitoring control devices and input devices can be increased as appropriate.
[0047]
【The invention's effect】
According to the present invention, in an environment in which an input device that captures device data and a plurality of information processing devices are connected to a single line, the time counter of the input device is set to a reference time using a single reference pulse generation unit. Can be synchronized.
[0048]
[Brief description of the drawings]
FIG. 1 shows a configuration diagram of a monitoring control system using a communication control device of the present invention.
FIG. 2 shows an example of a time chart illustrating an operation of the monitoring control system.
FIG. 3 shows an example of a data configuration of a frame.
FIG. 4 is a configuration diagram of a process communication device (PIOP) of the monitoring control device.
FIG. 5 shows a configuration diagram of a station (ST) of the input device.
FIG. 6 shows a configuration diagram of an input module (DI) of the input device.
FIG. 7 shows another configuration diagram of the station (ST) of the input device.
FIG. 8 shows another configuration diagram of the input module (DI) of the input device.
FIG. 9 shows another example of a time chart illustrating the operation of the monitoring control system.
[Explanation of symbols]
1 supervisory control system
2 Power station
10, 12 monitoring and control equipment
14, 16 input device
18 Communication line
20 Process communication device (PIOP)
21 Synchronous counter
22 GPS receiver
26 Relay counter
38, 39 time counter
32 valves
34 temperature sensor

Claims (2)

An input device that has a time counter that counts time, takes in status information of the controlled device, temporarily accumulates it as status data with the time counted by the time counter, A communication control device comprising a plurality of information processing devices for monitoring or controlling, wherein the input device and the plurality of information processing devices are connected to a single communication line,
The plurality of information processing devices acquire a transmission right set in advance and communicate with the input device, and one of the plurality of information processing devices includes a reference pulse from a reference pulse generation unit. Has a synchronous counter that is reset and timed, and when the transmission right cannot be acquired when the reference pulse is output from the reference pulse generation unit, the content of the synchronous counter is acquired when the transmission right is acquired. A communication control device for writing to a time counter of an input device. The communication control device according to claim 1, wherein the status data is obtained by associating the content of an event that has occurred in a control target device with the time of occurrence of the event.

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