JP3873981B2 - Remote control monitoring system - Google Patents

Description

  The present invention relates to a remote control monitoring system that controls and monitors a load using network technology.

  Conventionally, a remote control monitoring system for controlling and monitoring a load using network technology has been proposed. In this type of remote control monitoring system, a control terminal for controlling a load and a monitoring terminal for receiving a monitoring input such as a switch are provided as network terminals. Further, a configuration has been proposed in which a transmission unit is interposed between the monitoring terminal and the control terminal, and the transmission unit transmits data from the transmission unit to the control terminal based on data received from the monitoring terminal.

  That is, as shown in FIG. 1, the monitoring terminal 11 and the control terminal 12 are connected to the transmission unit 10 via the signal line Ls serving as a transmission path. When the transmission unit 10 receives the monitoring data corresponding to the monitoring input to the monitoring terminal 11, the transmission unit 10 generates control data instructing the control content of the load according to the content of the monitoring data, and sends the control data to the control terminal 12. To transmit. The transmission unit 10 includes a control table that links monitoring data and control data according to an address relationship. In addition to linking addresses one-to-one, it is also possible to link addresses one-to-many.

  For example, if a monitoring input corresponding to the operation of the switch is obtained in the monitoring terminal 11 and the lighting and turning off (ON and OFF) of the luminaire as a load is controlled in the control terminal 12, the transmission unit 10. Then, individual control for turning on and off the lighting fixtures of one circuit with one switch and batch control for turning on and off lighting fixtures of a plurality of circuits at once with one switch can be performed. it can. In other words, individual control means that one load (lighting fixture) is controlled by one instruction, and collective control means that a plurality of loads are controlled by one instruction. In the collective control, the address range of the luminaire to be controlled is associated with the switch, and the group control for turning on or off the luminaire in the range by operating one switch and the control target A pattern in which lighting ranges corresponding to each address and lighting fixtures corresponding to each address are associated with switches, and each lighting fixture in the range is turned on or off by operating one switch. There is control.

  In order to perform group control or pattern control, in the control table provided in the transmission unit 10, the group number or pattern number corresponding to the switch that performs group control or pattern control corresponds to the address of the lighting fixture in the range to be controlled. In addition, when a switch for performing group control or pattern control is operated, the address of the lighting fixture to be controlled is expanded by collating with the control table in the transmission unit 10, and the lighting fixture is turned on and off. After the state is determined, an instruction is given to the control terminal 12 having an address obtained by referring to the control table. In the illustrated example, it is assumed that the monitor terminal 11 is provided with a switch operation unit, which is expressed as “SW” which means a switch, and the control terminal 12 has a built-in relay for turning on and off the power. It is written as “T / U” which means a terminal unit.

  For the sake of simplicity, the monitoring terminal 11 is described as having only one switch circuit, and the control terminal 12 is described as being provided with only one circuit of a lighting fixture. The addresses of the monitoring terminal 11 and the control terminal 12 do not have to correspond one-to-one with the switches and the lighting fixtures. One monitoring terminal 11 handles a plurality of switches, and one control terminal 12 When a plurality of circuits are provided in each of the monitoring terminal 11 and the control terminal 12 in order to handle a plurality of lighting fixtures, the addresses are hierarchized in order to individually recognize the switches and the lighting fixtures. A load number for individually identifying the circuit of each switch and each lighting fixture is set below the terminal address set in the control terminal unit 12, and the combination of the terminal address and the load number is increased. Used as an address (for example, see Patent Document 1).

  By the way, the addresses that can be managed by the transmission unit 10 (the combination of the terminal address and the load number is also the same) are relatively small (for example, 256). 10 may not be managed. Therefore, a technique has been proposed in which the network managed by the transmission unit 10 is the lower network NT1, NT2, and the lower network NT1, NT2 is managed by the upper network via the local interface unit 13 serving as a higher network terminal (for example, Patent Document 2).

  In the technique described in Patent Document 1, a local interface unit is connected to a signal line, and the local interface unit is handled as a terminal for a transmission unit. In the configuration example shown in FIG. 1, the local interface unit 13 is used as a terminal for the transmission unit 10 in the same manner as that described in Patent Document 1. The local interface unit 13 also functions as a terminal with respect to the network control unit 14 that constructs the host network, and the local interface unit 13 and the network control unit 14 are connected via, for example, a dedicated line Lt of the RS485 specification.

  As described above, in the remote control monitoring system including the local interface unit 13 and the network control unit 14, the monitoring terminal 11 in each of the lower networks NT 1 and NT 2 connected to each local interface unit 13 through the network control unit 14. It is possible to centrally monitor the operation of the control terminal 12, and the control terminal 12 provided in each lower network NT 1, NT 2 by giving an instruction from the network control unit 14 to each local interface unit 13. Can be given instructions.

  Here, the operation in each of the lower networks NT1 and NT2 will be described in more detail with reference to FIG. In the illustrated example, it is assumed that display for centralized monitoring is performed through the network control unit 14. The transmission unit 10 in each of the lower networks NT1 and NT2 always performs polling in which a multiplex transmission signal whose address is cyclically changed is periodically sent to the signal line Ls. The multiplexed transmission signal includes a start pulse indicating the start of signal transmission, mode data indicating the signal mode, page data for identifying the lower networks NT1 and NT2, and addresses for calling the monitoring terminal 11 and the control terminal 12 separately. Address data for transmitting (the addresses of the monitoring terminal 11 and the control terminal 12), control data for transmitting control data for controlling the load (including load number information), and a checksum for detecting a transmission error Bipolar (± 24V) signals including a signal return period, which is a time slot for receiving return signals from data, monitoring terminals and control terminals, are used. Data is transmitted by pulse width modulation. In the following description, the load number is not considered, and each monitoring terminal 11 generates a monitoring input by one switch, and each control terminal 12 controls the load of one circuit. It is assumed that the switch and the load correspond one-to-one to the address of the terminal device 11 or the control terminal device 12. In FIG. 4, a 4-character string starting with “MD” indicates the type of multiplex transmission signal transmitted by the transmission unit 10, and the next three hexadecimal numbers in the character string are page data and address, respectively. Data and control data.

  When any monitoring terminal 11 generates a monitoring input by operating a switch, the monitoring terminal 11 sends an interrupt signal synchronized with the start pulse of the multiplexed transmission signal to the signal line Ls (P1). The monitoring terminal 11 that has generated the interrupt signal enters a latch state in which the interrupt flag is set. On the other hand, when the transmission unit 10 detects the interrupt signal, it transmits a multiplex transmission signal (MDP2) with the mode data as the search mode (P2). When receiving the search mode multiplex transmission signal, the monitoring terminal 11 in the latched state returns an address during the signal return period (P3), and the transmission unit 10 receiving the address sends the address to the monitoring terminal 11 of the address. A multiplex transmission signal (MDM2) requesting the return of the latched state is transmitted (P4), and it is confirmed whether or not the monitoring terminal 11 has generated the interrupt signal by checking whether it is in the latched state (P5). When it is confirmed that the monitoring terminal 11 has generated the interrupt signal, a multiplex transmission signal (MDAC) for releasing the latched state is transmitted (P6), and the latched state of the monitoring terminal 11 is released (P7). ).

  When the transmission unit 10 receives a request from the monitoring terminal 11 by the above-described operation, the transmission unit 10 requests the control terminal 12 associated with the monitoring terminal 11 to control the load according to the control table. That is, a multiplex transmission signal (MDCT) for notifying the start of control is sent to the local interface unit 13 (P8), and subsequently, a multiplex transmission signal (MDM1) for confirming the operating state of the control terminal 12 that is the control target. ) Is sent (P9), and the operating state is returned from the control terminal 12 (P10). Here, the operating state of the control terminal 12 means an on / off state of a built-in relay, for example. The operation state received from the control terminal 12 is confirmed in the transmission unit 10. For example, if the current operation state of the relay built in the control terminal 12 is OFF, the multiplex transmission signal (the content of which reverses the operation state to ON). MDCT) is transmitted to the monitoring terminal 11 that has been operated by the switch (P11), and a multiplex transmission signal (MDCT) having the same content is also transmitted to the control terminal 12 (P12). Note that the fact that the multiplex transmission signal (MDCT) for controlling the control terminal 12 is also transmitted to the monitoring terminal 11 is reflected in the display state of the indicator lamp for on / off display provided in the monitoring terminal 11. This is to make it happen. The control terminal 12 that has received the multiplex transmission signal (MCCT) instructing the operation state in step P12 returns an echo back for confirmation of reception (P13).

  Thereafter, the transmission unit 10 sends out a multiplex transmission signal (MDDM) for notifying that the signal line Ls is waiting for stabilization as a transmission path (P14). When the transmission unit 10 transmits a multiplex transmission signal (MDDM) waiting for the stabilization of the transmission path after an appropriate time has elapsed or the stability of the transmission path is detected by an appropriate detection means, the transmission terminal 10 operates as a control terminal 11 A multiplex transmission signal (MDM1) for confirming the state is transmitted (P15), and the operation state is returned (P16). The result returned from the control terminal 12 is notified to the monitoring terminal 11 where the monitoring input by the operation of the switch is generated by the multiplex transmission signal (MDCT), and is reflected in the display state of the indicator lamp (P17). That is, the operation state of the control terminal 12 is confirmed, and the confirmed operation state is notified to the monitoring terminal 11.

After the series of operations described above is completed, a multiplex transmission signal (MDCT) for notifying that the control is completed is transmitted to the local interface unit 13.
JP 2000-10694 A JP 2002-101480 A

  In the above operation, when a monitoring input is generated by operating the switch in the monitoring terminal 11, the control table provided in the transmission unit 10 of the lower network NT1, NT2 including the monitoring terminal 11 is referred to, and the same lower network NT1, The operating state of the control terminal 12 included in NT2 can be changed. However, since there is no function for associating the monitoring terminal 11 and the control terminal 12 belonging to different lower networks NT1 and NT2, for example, the monitoring input generated in the monitoring terminal 11 included in the lower network NT1 is It cannot be used to control the control terminal 12 of the lower network NT2.

  In the above-described example, the example in which the local interface unit 13 is notified on the assumption that the start and end of control are centrally monitored through the network control unit 14 has been described. However, instead of the local interface unit 13, the control terminal 12 In the case of providing a centralized display terminal that centrally displays the operation state in one place, in the above configuration, the centralized display terminal needs to have the same number of addresses as the monitoring terminal 11; Address setting and association with the monitoring terminal 11 are troublesome.

  The present invention has been made in view of the above-mentioned reasons, and its purpose is not only to transmit an address and control contents by only one multiplex transmission signal, but also to divide and transmit a plurality of multiplex transmission signals. An object of the present invention is to provide a remote control monitoring system with improved convenience.

The invention of claim 1 includes a monitoring terminal that receives a monitoring input, a control terminal that controls a load, and a monitoring terminal and a control terminal that are connected to the monitoring terminal and the control terminal via a signal line. A transmission unit that has a control table associated with each address and controls a load by a control terminal associated with the control table when a monitoring input is generated in the monitoring terminal, a local interface unit connected to the signal line, and a local interface unit And a network control unit connected via a dedicated line. The network control unit constructs an upper network having the local interface unit as a terminal, and monitors and operates the operation of the lower network, which is a network managed by the transmission unit. Low instructions A configuration in which through the Le interface unit, transmission unit, first function of transmitting data to and from the monitoring terminal unit and the control terminal by using the multiplex transmission signal specifying an address in the lower network In addition, at least the address and control content for one control target of another lower network are divided into separate multiple transmission signals , transmitted to the local interface unit in the lower network, and transmitted to the other lower network via the upper network. And a second function to be provided.

  According to this configuration, not only the first function of transmitting the address and the control content using only one multiplexed transmission signal, but also the second function that enables transmission by dividing into a plurality of multiplexed transmission signals. By providing the above, the flexibility of the address and control content transmission method is increased, and it becomes possible to cope with various applications. For example, when a lower network having a transmission unit is managed by an upper network, a device that is a terminal device of the lower network is used, and a multiplexed transmission signal that specifies the address of the device is used. Thus, when a plurality of lower networks are provided below the upper network, it is possible to control the control terminals to be linked between the lower networks. In addition, when a centralized display terminal for centrally monitoring the operation state under the control of one transmission unit is provided, an address and control contents are individually transmitted to the terminal. If it is used for transmission, it becomes possible to monitor the operating state of a plurality of control terminals without setting a plurality of addresses in the terminal.

  In the invention of claim 2, in the invention of claim 1, the transmission unit includes a data memory in which execution range data is set for a set of the monitoring terminal and the control terminal, and is monitored by the monitoring terminal. When an input is generated, it has a function of collating with execution range data and determining whether or not it is necessary to use the second function for each control terminal corresponding to the monitoring terminal.

  According to this configuration, the execution range data can specify the case where the second function that requires a plurality of multiplexed transmission signals to transmit a set of information and the case where the second function is not used are used. When the second function is unnecessary, traffic can be reduced by not using the second function.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the transmission unit has a function of transmitting at least an address and a control result for one control object by using different multiplexed transmission signals. It is characterized by.

  According to this structure, the flexibility of the transmission method of an address and a control result becomes high, and it becomes possible to respond to various uses. That is, as in the first aspect of the invention, if there are a plurality of lower networks, it is possible to monitor the control results of the control terminals provided in the other lower networks. As a result, if control fails, it is possible to cope with retransmission of control contents.

  According to the configuration of the present invention, not only the first function of transmitting the address and the control content using only one multiplex transmission signal but also the second multiplex transmission signal can be divided and transmitted. By providing this function, there is an advantage that the flexibility of the transmission method of the address and control contents is increased, and it becomes possible to cope with various applications.

  The system configuration of this embodiment is the same as that of the conventional configuration as shown in FIG. 1, but the procedure for sending a multiplexed transmission signal from the transmission unit 10 to the signal line Ls is different from the conventional configuration. That is, in the illustrated example, two local interface units 13 are connected to the network control unit 14 via the dedicated line Lt, and two lower networks NT1 and NT2 including each local interface unit 13 are constructed. . In each of the lower networks NT1 and NT2, the monitoring terminal 11 and the control terminal 12 are connected to the transmission unit 10 via a signal line Ls serving as a transmission path. The monitoring terminal 11 is connected to a switch (or a sensor that can be handled in the same manner as the switch), and generates an interrupt signal when a monitoring input is generated by operating the switch, as described in the prior art. Further, a load such as a lighting fixture is connected to the control terminal 12. The control terminal 12 includes a relay that incorporates a relay and controls only on / off of a load, and a control terminal that enables dimming control of a lighting fixture by generating a dimming signal. In the local interface unit 13 in the configuration example shown in FIG. 1, a setting device 15 such as a personal computer can be detachably connected. The setting device 15 sets a control table in the transmission unit 10 through the local interface unit 13. It has a function.

  As shown in FIG. 2, the transmission unit 10 includes a signal processing unit 20 having a microprocessor (CPU) as a main component. The signal processing unit 20 includes a program memory 21 including a flash memory storing a program, and a multiplexing unit. A working memory 22 comprising a RAM for temporarily storing the transmission state of the transmission signal and the operation state of the monitoring terminal 11 and the control terminal 12 is connected. Further, a data memory 22 including a flash memory for storing the control table described as the conventional configuration is provided. The data memory 22 also stores control range data described later. The transmission unit 10 is provided with a driver circuit / receiver circuit 24 serving as an interface between the signal processing unit 20 and the signal line Ls. The driver circuit / receiver circuit 24 detects and displays a short circuit of the signal line Ls. Therefore, the signal line short circuit detection / display circuit 25 is connected. When the signal line short circuit detection / display circuit 25 detects a short circuit of the signal line Ls, the signal processing unit 20 notifies the signal processing unit 20, stops transmission of the multiplex transmission signal, and notifies the user of the occurrence of the short circuit through a not-illustrated notification unit. The power source of the transmission unit 10 is, for example, 100 V AC from a commercial power source, and is converted to a DC power source used in the internal circuit through the power circuit 26. The power supply state from the commercial power supply is monitored by the power supply monitoring circuit 27, and the power supply monitoring circuit 27 notifies the signal processing unit 20 of a power failure or power recovery. When the power failure is notified, the signal processing unit 20 performs necessary processing such as supplying power from a backup power source (not shown) to the built-in clock.

  The operation of this embodiment will be described below. As can be seen by comparing FIG. 3 with FIG. 4, steps P1 to P14 shown in FIG. 3 are the same as steps P1 to P14 of the conventional configuration shown in FIG. 4, and steps P18 to P20 are the same as those shown in FIG. Steps P15 to P18 of the configuration are the same, and step P24 shown in FIG. 3 is the same as step P19 of the conventional configuration shown in FIG. That is, only steps P15 to P18 and steps P21 to P23 in FIG. 3 are different from the conventional configuration. Steps P15 to P18 and Steps P21 to P23 have the same contents, and a multiplex transmission signal (MDCT) for transmitting control contents from the transmission unit 10 to the control terminal 12 is transmitted three times. That is, a normal multiplex transmission signal includes mode data, page data and address data, and control data, but these pieces of information are transmitted by being divided into three multiplex transmission signals.

  Steps P15 and P21 are used for transmission of control types corresponding to mode data, Steps P16 and 22 are used for transmission of page data and address data for designating a control target, and Steps P17 and P23 are used for transmission of control contents. . Therefore, the local interface unit 13 is notified by the mode data that it is a multiplex transmission signal (MDCT) for transmitting data to the other lower networks NT1 and NT2, and is transmitted to the other lower networks NT1 and NT2. The mode data, page data, address data, and control data can be inserted into the time slots for address data and control data in three multiplexed transmission signals transmitted to the local interface unit 13, respectively. Here, when the local interface unit 13 is requested to transmit information to the other lower networks NT1 and NT2, the mode data cannot be processed by the monitoring terminal 11 or the control terminal 12, so that the multiplexed transmission signal (MDCT) ) Is regarded as an access to the local interface unit 13, it is possible to access the local interface unit 13 without using address data.

  Incidentally, the control types described above include a control mode and a setting mode. As shown in Table 1, control modes include individual, old dimming, pattern, group, and all on / off control modes. Setting modes include total pattern setting, floor pattern setting, and group setting modes.

  “Individual” in Table 1 is control for associating the monitoring terminals 11 (switches) and the control terminals 12 (loads) on a one-to-one basis, and “On control” and “Off control” for turning the load on or off. In addition, “delayed extinction control” that turns off the load after a specified time from the switch operation, “temporary lighting control” that turns on the load for a specified time after the switch operation, and increased light output during dimming control There are “Up control”, “Down control”, and “Stop control” for selecting reduction and stop of change. That is, “individual” control also corresponds to dimming control. However, in the old transmission unit 10 sold in the past by the present applicant, the dimming control is managed as a separate circuit from the individual control. Therefore, in order to cope with this type of transmission unit 10, the control type is “ "Old dimming" can be specified. “Pattern” and “Group” are as described in the prior art. In “Pattern”, “ON” and “OFF” can be individually specified for the control terminal 12 that is the target of collective control. Then, the control terminal 12 which is the object of collective control is set to the same operation state. In other words, in the “pattern”, only “On control” for designating the load to be turned on is possible, but in “group”, the same control content as “individual” can be designated. “All on / off” can designate on or off for all connected control terminals 12.

  On the other hand, among the setting modes, “total pattern setting” is a mode for setting pattern control for all connected control terminals 12, and “floor pattern setting” is within the range of the lower networks NT1 and NT2. In this mode, the pattern control is set for the control terminal 12. “Group setting” is a mode for setting group control. “Conventional setting” means setting with the transmission unit 10 connected, and “global setting” means setting without connecting the transmission unit 10. Furthermore, “dedicated setting” means reading of the control table that is read-only and stored in the transmission unit 10. Furthermore, “Initial setting” means to delete the setting contents and newly set the control table, and “Change setting” means to add and set new contents while keeping the previous setting contents. To do. “Transition to normal mode” means transition from the setting mode to the control mode.

  In the following, a monitoring input is generated by operating a switch in the monitoring terminal 11 included in the lower network NT1, and the control terminal 12 included in the lower network NT1 and the control terminal 12 included in the lower network NT2 are linked to each other. The operation of this embodiment will be described by taking the case of control as an example. As described with reference to FIG. 3, when a monitoring input is generated in the monitoring terminal 11 in the lower network NT1 (P1 to P7), the control content is transmitted to the control terminal 12 included in the same lower network NT1. (P8 to P13). Thereafter, information to be given to the control terminal 12 of the other lower network NT2 is transmitted to the local interface unit 13 connected to the lower network NT1 (P15 to P17). The local interface unit 13 that has received this information transfers the information to the network control unit 14, and the network control unit 14 confirms the address and transfers the information to the local interface unit 13 of the lower level network NT2 that is the transfer destination. The local interface unit 13 of the lower network NT2 generates an interrupt signal in the same manner as when the switch is operated in the monitoring terminal 11 by confirming the control type, address, and control contents, and is transmitted from the transmission unit 2 of the lower network NT2. The control contents are transmitted to the control terminal 12. That is, it becomes possible to control the control terminals 12 included in the plurality of lower networks NT1 and NT2 in conjunction with each other by the monitoring input in the monitoring terminals 11 included in any of the lower networks NT1 and NT2.

  In the operation example shown in FIG. 3, the control content is transmitted to the control terminal 12 included in the same lower network NT1, NT2 as the monitoring terminal 11 where the monitoring input is generated, and then the control content is transmitted to the local interface 13. The reason for this is to suppress a delay in transmission of control contents to the control terminal 12 in the same lower network NT1, NT2.

  In the example shown in FIG. 3, after transmitting the control contents to the other lower network NT2 through the interface unit 13, the control result is received from the other lower network NT2, or the control result in the lower network NT1 is sent to the network control unit 14. It is possible to transmit. Steps P21 to P23 in FIG. 3 show an example of transferring the control result in the lower network NT1 to the network control unit 14 through the local interface unit 13. When a response from another lower network NT2 is returned to the local interface unit 13 in the lower network NT1 via the network control unit 14, the local interface unit 13 is accessed from the transmission unit 10 in the lower network NT1. As a result, it is possible to obtain the control result in the other lower network NT2. Therefore, the transmission unit 10 can know whether or not the control in the other lower network NT2 is successful, and when the control fails, it is possible to improve the reliability by retransmitting the control contents.

  When transmitting the control content to the other lower network NT2, it is necessary to specify not only the address of the transmission destination but also the type of control. Therefore, even when the control content is transmitted to the other lower network NT2, the lower network NT1 Is required to be associated with the control terminal 12 in the lower network NT2, and information on this association is stored in the data memory 23 as a control table. The control table is set by connecting the setting device 15 to the local interface 13.

  By the way, in the example shown in FIG. 3, the processing of the transmission unit 10 always includes steps P15 to P17 and P21 to P23, so the local interface can be used even when the linkage with the other lower networks NT1 and NT2 is unnecessary. 13, communication from the transmission unit 10 is performed. Since the network control unit 14 is notified of the start and end of control at steps P8 and P24, steps P15 to P17 and P21 to P23 are not necessary if there is no interlocking relationship with other lower networks NT1 and NT2. In spite of this, this information is transmitted to the network control unit 14, so if there is no interlocking relationship, it leads to processing delay due to traffic increase, and the network control 14 selects information depending on the presence or absence of the interlocking relationship Therefore, there is a problem that the processing load increases.

  Therefore, when the setting device 15 is connected to the local interface unit 13 to set the control table, the local interface unit 13 determines the presence or absence of the interlocking relationship between the lower networks NT1 and NT2 based on the contents of the control table. Information corresponding to the presence / absence is set in the data memory 23. Actually, the local interface unit 13 determines the contents of the types of control shown in Table 1 when setting the control table, and uses the multiplex transmission signal that passes through the signal line Ls only in the case of the type that causes the interlocking relationship. Set as execution range data in the data memory 23. When execution range data is set in the data memory 23, when a monitoring input is generated in the monitoring terminal 11 by operating the switch, the control content corresponding to the switch is read out from the control table. The corresponding execution range data is read from the data memory 23, and if they match, the processing of steps P15 to P17 and P21 to P23 in FIG. 3 is performed to transmit information to the network control unit 14, but if they do not match, Does not transmit information to the network control unit 14. In short, the execution range data is set for the set of the monitoring terminal 11 and the control terminal 12 set in the control table. If a monitoring input is generated, the execution range data is collated with Steps P15 to P15. The necessity of the processing of P17, P21 to P23 is determined. This operation can reduce traffic and also reduce the processing load on the network control unit 14.

  In the above example, the control result is transmitted in steps P21 to P23 in FIG. 3, but steps P21 to P23 can be omitted if the transmission of the control result is unnecessary. Further, in the above-described example, the processing of steps P15 to P17 and P21 to P23 of FIG. 3 is performed in order to link a plurality of lower networks NT1 and NT2, but a terminal for display in one lower network NT1 and NT2. If the information is transmitted to the display terminal by the processing of steps P15 to P17 in FIG. 3, the display terminal can be handled with one address as with the local interface unit 13. Thus, it becomes possible to monitor the operating state of the lower networks NT1, NT2.

It is a block diagram which shows the remote control monitoring system used for this invention. It is a block diagram which shows the transmission unit used for the same as the above. It is operation | movement explanatory drawing same as the above. It is operation | movement explanatory drawing which shows a prior art example.

Explanation of symbols

10 Transmission Unit 11 Monitoring Terminal 12 Control Terminal 13 Local Interface Unit 14 Network Control Unit 15 Setting Device Ls Signal Line Lt Dedicated Line NT1, NT2 Lower Network

Claims (3)

A monitoring terminal that receives a monitoring input, a control terminal that controls a load, a control table that is connected to the monitoring terminal and the control terminal via a signal line and associates the monitoring terminal and the control terminal with respective addresses. When a monitoring input occurs in the monitoring terminal, a transmission unit that controls the load by the control terminal associated with the control table, a local interface unit connected to the signal line, and a connection to the local interface unit via a dedicated line It has been a network control unit, a network control unit with building a higher level network to the terminal of the local interface unit, the local interface an indication of the monitoring and operation of the operation of the lower network is a network transmission unit manages A configuration in which through the unit, the transmission unit includes a first function of transmitting data to and from the monitoring terminal unit and the control terminal by using the multiplex transmission signal specifying an address in the lower network, At least an address and control contents for one control target of another lower network are divided into separate multiple transmission signals , transmitted to a local interface unit in the lower network, and transmitted to another lower network via the upper network . A remote control monitoring system comprising two functions.   The transmission unit includes a data memory in which execution range data is set for a set of the monitoring terminal and the control terminal. When a monitoring input is generated in the monitoring terminal, the transmission unit compares the execution range data with the monitoring terminal. The remote control monitoring system according to claim 1, further comprising a function for determining whether or not the second function is necessary for each corresponding control terminal.   The remote control monitoring system according to claim 1 or 2, wherein the transmission unit has a function of transmitting at least an address and a control result with respect to one control object using different multiplexed transmission signals.

Images