JP3818189B2 - Inter-system interface of remote control system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an inter-system interface of a remote control system.
[0002]
[Prior art]
Conventionally, a plurality of terminals and one transmission unit are connected via a signal line, and the transmission unit accesses each terminal by a time division transmission method using an address assigned to each terminal. There has been proposed a polling (centralized control) remote control system (hereinafter referred to as “polling system”) in which a transmission unit mediates data exchange between terminals. In this type of remote control system, in order to control the load according to the operation of the switch, a terminal device that accepts a binary monitoring input such as a switch operation and a terminal device that controls the load are provided. . In the transmission unit, the addresses of the switch-side terminal and the load-side terminal are associated with each other. When the transmission unit detects that the switch-side terminal has been operated, the switch is switched from the transmission unit to the load-side terminal. The operation of the load is transmitted to the terminal on the switch side via the transmission unit at the terminal on the load side, and the operation status of the load can be displayed on an indicator light provided on the terminal on the switch side. It is.
[0003]
In addition, by providing each terminal with a microcomputer for communication, each terminal operates independently, and a contention method (distributed control method) in which terminals communicate directly with each other without using a transmission unit Remote control systems (hereinafter referred to as “contention-type systems”) have also become widespread. In this type of remote control system, communication is performed directly between a terminal that monitors the operation of the switch and a terminal that controls the load.
[0004]
[Problems to be solved by the invention]
Among the remote control systems described above, the polling system is currently mainly used for lighting load control, and the contention system is currently mainly used for air conditioning control. That is, in the polling system, terminals with various functions are commercialized for controlling the lighting load, and the contention system can be expected to have high reliability in the field of air conditioning control.
[0005]
By the way, an interface is required to connect the polling system and the contention system. Some polling systems have a function to control the lighting load dimming, but basically the lighting load is controlled on / off. Can be said to be transmitted. In other words, in a system for sending information, the contacts are turned on and off through a terminal, and in a system for receiving information, on / off of the contacts may be monitored by the terminal. In other words, each system requires two terminals: a terminal that sends contact output for control to the other system and a terminal that receives contact output from the other system. A total of 4 terminals are required for each 2 systems. Normally, two terminals are required to transmit information from one system to the other system, and two more terminals are required to receive an operation check in the other system. Thus, four terminals must be added to exchange information between systems.
[0006]
As described above, four terminals are required to control one load of the other switch with respect to the switch operated in one system, and if the number of combinations of switches and loads increases. The number of terminals will also increase significantly. As a result, there arises a problem that the connection relationship becomes complicated.
[0007]
The present invention has been made in view of the above reasons, and its purpose is to enable control and monitoring of the load of the other system between the polling system and the contention system, and to control the input and load. An object of the present invention is to provide an inter-system interface of a remote control system that can cope with a simple connection relationship even when the number of combinations increases.
[0008]
[Means for Solving the Problems]
  According to the first aspect of the present invention, a plurality of terminals each having an address and a transmission unit are connected via a first signal line, and a terminal that monitors a first input and a terminal that controls a first load. The first remote control system of the polling system in which the first load is controlled according to the first input by transmitting the transmission signal in which the transmission unit designates the address to the transmitter by the time division multiplex transmission system And a plurality of node devices each having an address are connected via a second signal line, and the transmission is performed by designating an address between the node device that monitors the second input and the node device that controls the second load. By transmitting the signal, the first signal line and the second signal are interposed between the contention-type second remote control system in which the second load is controlled according to the second input. Tangent to line A first signal processing unit capable of transmitting and receiving a transmission signal transmitted through the first signal line and a transmission signal transmitted through the second signal line; A signal processing unit; an address storage unit storing a plurality of addresses equivalent to the terminal used in the first signal processing unit; and a state storage unit storing a plurality of addresses of the node device used in the second signal processing unit; Information transmission for associating addresses of the address storage unit and the state storage unit and controlling the second load by the first input and information transmission for controlling the first load by the second inputAnd outat leastInformation transmission to control the first load by the second inputA control unit that enablesIn the control unit, when the first load is controlled by the second input, the first load is forcibly controlled by the instruction content by the second input regardless of the control state of the first load.It is characterized by that.
[0009]
According to a second aspect of the present invention, in the first aspect of the present invention, the control unit includes information transmission for controlling the second load by a first input and information transmission for controlling the first load by a second input. A function that notifies both of the node device associated with the address when the state change in the first load is recognized and the state associated with the address when the state change in the second load is recognized. It has both the function to notify to a terminal device, It is characterized by the above-mentioned.
[0011]
  Claim 3In the invention of claim 1, in the invention of claim 1, only when the control unit performs information transmission for controlling the first load by the second input and recognizes a change in the state in the first load, the address is used. Is provided with a function of notifying the associated node device.
[0012]
  The invention of claim 4 is the invention of claim 1 or claim 2,Transmission direction setting means for setting the direction of information transmission in the control unit for each set of addresses associated with each other in the address storage unit and the state storage unit is provided.
[0014]
  The invention of claim 5 is the invention of any one of claims 1 to 4,The address storage unit can set an address regardless of the operation state of the second remote control system and the stored contents of the state storage unit. The state storage unit stores the operation state of the first remote control system and the storage of the address storage unit. An address can be set regardless of the contents.
[0015]
  The invention of claim 6 is the invention according to any one of claims 1 to 5,The address stored in the address storage unit is equivalent to the address of the terminal that monitors the first input in the first remote control system, and is an address for individual control associated with the first load one-to-one. A group control address for simultaneously controlling a plurality of first loads to the same control state, a pattern control address for simultaneously controlling a plurality of first loads to a preset control state, It is selected from the address for dimming control set when one load is a dimmable load.
[0016]
  The invention of claim 7 is the invention of claim 6,When the address stored in the address storage unit is a dimming control address, the first signal processing unit controls the first load that is controlled by the dimming level instructed by the second input. When the light level is different from the light level, the dimming level is controlled so as to approach, and when the stop of increase / decrease of the dimming level is instructed, the change of the dimming level is controlled to stop.
[0017]
  The invention of claim 8 is the invention of claim 6,When the address stored in the address storage unit is a dimming control address, the first signal processing unit is instructed to adjust the dimming level when the second input is instructed to increase or decrease the dimming level. The direction is controlled, and when the stop of the increase / decrease of the light control level is instructed, the control is performed to stop the change of the light control level.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
In this embodiment, between the polling system (assuming the “full two-wire remote control system” proposed by the applicant) and the contention system (assuming the “LonWorks system” proposed by Echelon) An example of an interface between systems that enables mutual exchange of information. The inter-system interface used in the present invention is basically used in the form shown in FIG. 2, and is provided between the signal line Ls 1 of the polling system 1 and the signal line Ls 2 of the contention system 2. The inter-system interface 3 is connected.
[0019]
In the polling system 1, a plurality of terminals 11 with addresses set are connected to the transmission unit 10 via a signal line Ls1. The transmission unit 10 sends a transmission signal of a time division multiplex transmission system designating the address of the terminal 11 to the signal line Ls1, and the transmission signal is transmitted in the terminal 11 in which an address matching the address selected by the transmission signal is set. The operation of the content instructed by the transmission signal is performed. The transmission signal includes at least the address of the terminal 11 as a transmission destination from the transmission unit 10, control data for instructing control contents, and a signal return period for receiving information from the terminal 11. For example, the terminal device 11 that monitors the operation of a switch (in the following, a switch is basically assumed, but may be another input such as a sensor (wireless switch, card switch, contact input, heat ray sensor, etc.)). For example, when the address is selected by the transmission signal, the operation content of the switch is returned. In the case of the terminal 11 that controls the load, when the address is selected by the transmission signal, the load is controlled according to the control content included in the transmission signal. To do. The fact that the load is controlled is transmitted during the signal return period of the transmission signal, and is used to confirm that the load is controlled.
[0020]
On the other hand, in the contention system 2, a plurality of node devices 21 are connected to the signal line Ls2, and each node device 21 monitors whether or not carriers from other node devices 21 exist in the signal line Ls2. The node device 21 is configured to send a desired transmission signal to the signal line Ls2 as necessary during a period in which no carrier from the other node device 21 is detected. The transmission signal includes at least a transmission source address that is an address of the transmission source node device 21, a transmission destination address that is an address of the transmission destination node device 21, and a network variable that indicates control contents. For example, in the node device 21 having a switch, when the switch is operated, it is confirmed that there is no carrier on the signal line Ls2, and a transmission destination address is designated to transmit a transmission signal to the signal line Ls2. The node device 21 having an address that matches the destination address specified by the transmission signal receives the transmission signal and operates according to the contents of the network variable. In this case, a confirmation transmission signal is sent from the transmission destination node device 21 to the transmission source node device 21.
[0021]
The intersystem interface 3 interposed between the polling system 1 and the contention system 2 as described above is connected to the signal line Ls1 of the polling system 1 via a signal terminal T1, as shown in FIG. The first signal processing unit 31 for transmitting and receiving signals transmitted by the time division transmission method to and from the transmission unit 10 in the same manner as the terminal unit 11, and the signal terminal T3 and the transceiver on the signal line Ls2 of the contention system 2 And a second signal processing unit 32 that transmits and receives signals to and from another node device 21 in the same manner as the node device 21. Between the first signal processing unit 31 and the second signal processing unit 32, there is provided a control unit 30 mainly composed of a microcomputer, and the first signal processing unit 31 and the second signal processing unit 32 are mutually connected. Convert the signal format. The intersystem interface 3 is supplied with power through a power supply unit 34 having a power supply terminal T2, and a power indicator 34 is attached to the power supply unit 34. For example, an AC voltage obtained by stepping down a commercial power supply using a transformer is applied to the power supply terminal T2.
[0022]
By the way, the control unit 30 includes an address setting unit 12 and an address storage unit 13 for setting addresses used in the polling system 1 in order to support both the polling system 1 and the contention system 2. Prepare. The address setting unit 12 has a function of transmitting and receiving a wireless signal to and from the setting unit 4 that sets an address. The address transmitted from the setting device 4 using a wireless signal is written in the address storage unit 13 formed of a nonvolatile memory such as an EEPROM. A maximum of 16 addresses can be set in the address storage unit 13 in this embodiment, and the control unit 10 functions equivalently to 16 terminals 11. Here, a reception indicator lamp 14 that blinks when a signal from the polling system 1 is received or when a wireless signal transmitted from the setting device 4 is received is attached to the control unit 30. Further, in this embodiment, a combination of a plurality of addresses stored in the address storage unit 13 can be selected from a plurality of types (four types in the embodiment), and which combination is used is a combination changeover switch provided in the control unit 30. 15 is selected.
[0023]
On the other hand, in order to support the contention system 2, a state storage unit 22 in which the relationship between the network variable and the address for instructing the control contents to the node device 21 is provided is provided. Sixteen addresses corresponding to the device 21 are stored in association with network variables. The state storage unit 22 includes a nonvolatile memory such as an EEPROM, and basically the contents of the state storage unit 22 are set through the signal line Ls2. The control unit 30 has a signal lamp 23 that is turned on when a transmission signal is transmitted through the signal line Ls2, and a signal that is turned on when a transmission signal that matches the address stored in the state storage unit 22 is received from the signal line Ls2. A reception lamp 24 is provided. Further, the second signal processing unit 32 is provided with a service pin (switch) 25 and a service lamp 26. When the service pin 25 is turned on, the contents of the state storage unit 22 are transmitted to the signal line Ls2, and the service lamp 26 is Whether or not the network variable and the address are registered in the state storage unit 22 is notified by the lighting state.
[0024]
By the way, the address setting in the address storage unit 13 can be set regardless of the operation state of the contention system 2 and the stored contents of the state storage unit 22. That is, when the signal line Ls2 of the contention system 2 is not connected, or there is an abnormality such as a power failure or a failure in the contention system 2, or the address or network variable is set in the state storage unit 22. Even in the absence, the address related to the polling system 1 can be set in the address storage unit 13 using the setting device 4. Further, since power is supplied through the power supply terminal T2 in the inter-system interface 3 of the present embodiment, even when the signal line Ls of the polling system 1 is not connected, the setting device 4 using a wireless signal is used. An address can be set in the address storage unit 13. If the polling system 1 is constructed, the polling system 1 can be operated normally regardless of whether the contention system 2 is abnormal.
[0025]
Similarly, the setting of the network variable and the address in the state storage unit 22 can be set irrespective of the operation state of the polling system 1 and the stored contents of the address storage unit 13. For example, when the signal line Ls1 of the polling system 1 is not connected, or there is an abnormality such as a power failure or failure in the polling system 1, or the address storage unit 13 has no address set. In addition, network variables and addresses related to the contention system 2 can be set in the state storage unit 22. In the state storage unit 22, network variables and addresses are set by a setting device (not shown) connected to the signal line Ls2. This type of work is generally called binding, and in this embodiment, the binding work can be performed regardless of the state of the polling system 1. Moreover, if the contention type system 2 is constructed, the contention type system 2 can be operated normally regardless of whether the polling type system 1 is abnormal.
[0026]
In this embodiment, as described above, 16 addresses corresponding to the polling system 1 and the contention system 2 are provided, and the addresses are associated with each other. Here, it is assumed that each address is associated with one to one. In the present invention, information is exchanged between the polling system 1 and the contention system 2, but information can be transmitted in only one direction for each address. Therefore, in order to set the transmission direction of information, as a transmission direction setting means for defining the transmission direction of information for each pair of addresses associated in the polling system 1 and the contention system 2 A direction selection switch 36 is attached to the control unit 30.
[0027]
The direction selection switch 36 is composed of, for example, a dip switch having 16 contact points associated with addresses, and the direction in which information is transmitted between the polling system 1 and the contention system 2 is determined by turning each contact point on and off. It is done. For example, for each contact point, ON means information transmission from the polling system 1 to the contention system 2, and OFF means information transmission from the contention system 2 to the polling system 1. In short, this embodiment is equivalent to providing a 16-point interface, and the direction of information transmission can be specified for each point. For example, in the example shown in FIG. 3, numbers are assigned to 16 points, only numbers 2 and 4 are turned on (transmission from polling system 1 to contention type system 2), and the rest are all turned off. . The direction of information transmission may be instructed through the signal line Ls2 of the contention system 2 instead of the direction selection switch 36, and the content of the instruction may be registered in a non-volatile memory provided in the intersystem interface 3.
[0028]
An example of the control content of each point is shown in FIG. Each column in FIG. 4 means an address of the polling system 1, and “individual”, “group”, and “pattern” mean address setting methods. That is, since an address is set in the terminal device 11 of the polling system 1, not only one load is controlled by one switch (such control is called “individual” control). It is possible to control a plurality of loads all at once with a single switch. For simultaneous control, a “group” control that controls a plurality of loads to be controlled in the same state and a plurality of loads to be controlled There is a “pattern” control in which a load control pattern is registered in advance and the load is controlled by the control pattern registered when the switch is operated. The left column of FIG. 4 shows the types of these control methods. In addition to these addresses, the polling system 1 also has addresses used for “dimming” control of the lighting load. In addition, the arrow-like symbol shown in the right column of FIG. 4 indicates the flow of instructions (network variables) in the contention system 2. “Control” indicates an instruction from the contention system 2 to the polling system 1, “Operation” indicates an instruction from the polling system 1 to the contention system 2, and “State change reply” indicates a response to the instruction. “Name registration” means that the node device 21 of the contention system 2 associated with the address of the polling system 1 is given a name and registered in the inter-system interface 3.
[0029]
First, the case where the load (mainly lighting load) connected to the terminal device 11 of the polling system 1 is controlled by an instruction from the node device 21 having a switch in the contention system 2 will be described. At this time, the first signal processing unit 31 operates with the same function as the terminal device 11 that monitors the operation of the switch with respect to the signal line Ls1 of the polling system 1. As described above, the address of this type of terminal device 11 is set to any one of “individual”, “group”, “pattern”, and “dimming”. Therefore, in the present embodiment, the processing of the inter-system interface 3 is different depending on whether the address is “individual”, “dimming”, “group” or “pattern”.
[0030]
When the address is “individual”, “dimming”, or “group”, the operation is as follows. First, a description will be given of a case where an instruction to turn on the lighting load connected to the terminal 11 of the polling system 1 is made by operating a switch provided in the node device 21 of the contention system 2 (the uppermost stage in FIG. 4 and the like). ).
[0031]
In this case, the first signal processing unit 31 confirms the state of the corresponding address (switch) of the polling system 1, and if it is off, performs an interrupt process on the polling system 1 and corresponds to the polling system 1. Instruct the address to turn on. That is, the terminal 11 that monitors the operation of the switch operates in the same manner as when the switch is turned on. When the load is controlled in the terminal 11 to which the load is connected according to this instruction, the load state is returned to the first signal processing unit 31 via the transmission unit 10. The status is returned to the node device 21 in which the switch is operated in the contention system 2 (status change response).
[0032]
Further, when the state of the corresponding address (switch) of the polling system 1 is confirmed, if it is on, the node device 21 in which the switch is operated in the contention system 2 without performing processing for the polling system 1. In response, the status is returned (status change response).
[0033]
  However, when the state of the corresponding address (switch) of the polling system 1 is confirmed, the processing for the polling system 1 can be selected even if it is on.is there.In other words, even when it is considered that when the load control system 2 instructs the polling system 1 to control the load, the control state of the load to be controlled is considered to match the specified content. By controlling the load according to the instruction content from the tension system 2, the load can be reliably controlled. For example, even if the specification is such that individual control cannot be performed in the polling system 1 when group control is performed in the polling system 1, if the control of the load to be controlled is instructed from the contention system 2 It becomes possible to control to a target state.In other words, it is possible to forcibly control the load of the polling system 1 by instructing the load control from the contention system 2.
[0034]
Next, a case where an instruction to turn off the lighting load connected to the terminal device 11 of the polling system 1 is made by operating a switch provided in the node device 21 of the contention system 2 will be described.
[0035]
In this case, the first signal processing unit 31 confirms the state of the corresponding address (switch) of the polling system 1, and if it is on, interrupt processing is performed on the polling system 1, and the polling system 1 corresponds. Instruct the address to turn off. That is, the terminal 11 that monitors the operation of the switch operates in the same manner as when the switch is turned off. When the load is controlled in the terminal 11 to which the load is connected according to this instruction, the load state is returned to the first signal processing unit 31 via the transmission unit 10. The status is returned to the node device 21 in which the switch is operated in the contention system 2 (status change response).
[0036]
Further, when the state of the corresponding address (switch) of the polling system 1 is confirmed, if it is OFF, the node device 21 in which the switch is operated in the contention system 2 without performing the process for the polling system 1. In response, the status is returned (status change response).
[0037]
The node device 21 of the contention system 2 can instruct not only the on / off instruction, but also the inter-system interface 3 to confirm the state of the switch provided in the polling system 1, and in this case First, the state of the corresponding address (switch) of the polling system 1 is confirmed through the first signal processing unit 31, and the state information is returned to the node device 21 of the contention system 2 (state change reply). Further, when the load state in the polling system 1 changes, the node device 21 of the contention system 2 is connected to the system when the address (switch) of the polling system 1 recognizes the state change by the state check. Status information is transmitted from the interface 3 (status change reply).
[0038]
By the way, when the address of the polling system 1 is “pattern”, the operation is as follows. First, a case where an instruction to enable (turn on) “pattern” control of the polling system 11 is performed by operating a switch provided in the node device 21 of the contention system 2 will be described.
[0039]
In this case, the first signal processing unit 31 checks the state of the corresponding address (switch) of the polling system 1, and performs interrupt processing for the polling system 1 if the “pattern” control is invalid (off). The “pattern” control is enabled (turned on) at the corresponding address of the polling system 1. When the load is “pattern” controlled in this way, the fact that the “pattern” control is enabled is returned to the first signal processing unit 31 via the transmission unit 10, and is therefore returned by the inter-system interface 3. Is returned to the node device 21 whose switch is operated in the contention system 2 (status change reply).
[0040]
Also, when the status of the corresponding address (switch) of the polling system 1 is confirmed, if the “pattern” control is already valid (ON), the process is not performed on the polling system 1 and the control is performed. The state is returned to the node device 21 in which the switch is operated in the tension system 2 (state change reply).
[0041]
However, when the state of the corresponding address (switch) of the polling system 1 is confirmed, even if the “pattern” control is already valid (ON), it is possible to select to perform processing for the polling system 1. Good. In other words, as in the case of “individual” control or “group” control, “pattern” control is a control target when the contention system 2 instructs the polling system 1 to control the load. Even if it is considered that the control state of the load coincides with the instructed content, the load can be reliably controlled by controlling the load with the instructed content from the contention system 2.
[0042]
By the way, when an instruction to disable (turn off) the “pattern” control of the polling system 1 is made by operating a switch provided in the node device 21 of the contention system 2, the corresponding address of the polling system 1 is set. The status of (switch) is confirmed, and status information is returned to the node device 21 that operated the switch in the contention system 2 (status change response). However, the instruction to invalidate the “pattern” control is not executed in the polling system 1 and is ignored.
[0043]
Also during the “pattern” control, the node device 21 of the contention system 2 can instruct the inter-system interface 3 to check the status of the “pattern” control provided in the polling system 1. In this case, the state of the corresponding address (switch) of the polling system 1 is confirmed through the first signal processing unit 31, and the state information is returned to the node device 21 of the contention system 2 (state change reply). Further, when the load state in the polling system 1 changes, the node device 21 of the contention system 2 is connected to the system when the address (switch) of the polling system 1 recognizes the state change by the state check. Status information is transmitted from the interface 3 (status change reply).
[0044]
By the way, when “dimming” control is instructed from the contention system 2 to the polling system 1, the system operates as shown in FIG. 5 or FIG. The “dimming” control instruction is valid only for the dimming control address stored in the address storage unit 13. The operation in FIG. 5 is an operation in the case of instructing the dimming level from the node device 21 of the contention type system 2 to the terminal device 11 of the polling type system 1, depending on the content of the instruction from the contention type system 2. The control unit 30 operates as follows. First, when the control unit 30 receives an instruction (control signal) (S1), it identifies the content of the instruction. If the instruction is to turn on or off the load (S2, S3), the load to be controlled is controlled to be on (S4) or off (S5). In addition, since the dimming level of the load is registered in the transmission unit 10, when the instruction content indicates the dimming level, the dimming level at the time (current level) is received from the transmission unit 10, Compared to the dimming level (instruction level) of the instruction content (S6, S7), the dimming level is controlled in a direction to bring the current level closer to the instruction level (S8, S9). That is, when the current level is higher than the instruction level (S6), the current level is decreased (S8), and when the current level is lower than the instruction level (S7), the current level is increased (S9). Here, when the increase / decrease of the dimming level is stopped, an instruction to stop is issued (S10), and when the stop of the increase / decrease of the dimming level is instructed, the change of the dimming level is stopped (S11).
[0045]
The operation shown in FIG. 6 is an operation when the node device 21 of the contention system 2 instructs the terminal device 11 of the polling system 1 to increase or decrease the dimming level. The control unit 30 operates as follows according to the contents. First, when the control unit 30 receives an instruction (control signal) (S1), it identifies the content of the instruction. Here, if it is an instruction to turn on or off the load (S2, S3), the load to be controlled is controlled to be on (S4) or off (S5), similarly to the operation shown in FIG. On the other hand, when the instruction content indicates an increase or decrease in the dimming level (S6, S7), the dimming level is controlled in the instructed direction (S8, S9). That is, if the instruction content is a decrease in the dimming level (S6), the dimming level of the load to be controlled is decreased (S8), and if the instruction content is an increase in the dimming level (S7), the control object The dimming level of the load is increased (S9). When stopping the increase / decrease of the dimming level, an instruction to stop is given (S10), and when the stop of increasing / decreasing the dimming level is instructed, the change of the dimming level is stopped (S11).
[0046]
In the above-described example, the operation in which the load of the polling system 1 is controlled by an instruction from the contention system 2 has been described. Conversely, the load of the contention system 2 is controlled by an instruction from the polling system 1. The operation performed will be described below.
[0047]
That is, if the lighting load provided in the node device 21 of the contention system 2 is controlled by the operation of the switch provided in the terminal device 11 of the polling system 1 (see the second stage in FIG. 4), the polling is performed. When an instruction to turn on or off the lighting load is given from the terminal 11 that monitors the operation of the switch in the system 1, the intersystem interface 3 passes the second signal processing unit 32 to the node device 21 of the contention system 2. Give a command to turn on or off the lighting load ("Operation"). The node device 21 that has received the “operation” controls the lighting load and returns the state (“state change reply”). When the inter-system interface 3 receives the “state change reply”, the inter-system interface 3 associates this with the state of the corresponding address of the polling system 1, and loads the terminal 11 that is monitoring the switch operation in the polling system 1 to the load state. Is changed (that is, the lighting state of the indicator lamp provided in the terminal 11 is changed).
[0048]
Here, when the function of returning the load state change is not set in the node device 21 of the contention system 2, the polling system 1 is output when “operation” is output to the node device 21 of the contention system 2. Is notified of a change in the load state. Further, when the state of the lighting load provided in the node device 21 of the contention system 2 is changed except for an instruction from the polling system 1, the terminal device 11 associated with the node device 21 is connected to the polling system 1. Is present, the corresponding information is transmitted to the terminal 11 through the transmission unit 10 of the polling system 1 when the inter-system interface 3 receives the “status change reply”.
[0049]
Even when the lighting load is controlled by operating the switch in the system of the polling system 1 or when the lighting load is controlled by operating the switch in the system of the contention system 2, the state of the lighting load changes. As described above, when the control unit 30 recognizes a change in the state of the lighting load in one system, if there is a switch associated with the address in the other system, the terminal 11 or node corresponding to the switch The device 21 is notified of a change in the lighting load state. That is, even when the lighting load state changes without going through the inter-system interface 3, the control side provided with the inter-system interface 3 interposed therebetween can recognize the lighting load state change, and the control side recognition It is possible to prevent a discrepancy between the actual lighting load state and the actual lighting load.
[0050]
The operation related to the “state change reply” from the node device 21 of the contention system 2 will be briefly described with reference to FIG. If there is a “state change reply” from the node device 21 (S1), it is confirmed whether or not the polling system 1 is operating normally (S2). If control is possible, an address is stored in the address storage unit 13. It is confirmed whether it is set (S3). If an address is set, it is checked whether the address is under simultaneous control ("pattern" control, "group" control) or not (S4). If it is not under simultaneous control, it corresponds to the address of the polling system 1 The terminal 11 to be instructed to control the load (S5). If simultaneous control is being performed in step S4, the control is stopped (S9).
[0051]
As described above, in the present embodiment, since the terminal function 11 of the polling type system 1 and the node device 21 of the contention type system 2 are provided with 16 functions of an interface, Compared with the case where the interfaces are individually configured, the system configuration is simple and the connection with the signal lines Ls1, Ls2 is easy.
[0052]
  (Reference example)
  This exampleAs shown in FIG. 8, the “operation” function from the contention system 2 to the polling system 1 is omitted from the first embodiment. Therefore, the direction selection switch 36 is omitted, and only the combination switch 15, the service pin 25, and the service light 26 are disposed at a portion covered with the door 43 on the front surface of the body 40 as shown in FIG. 9. Since only the “operation” from the polling system 1 to the contention system 2 is performed, the function of the “lamp actuator” in FIG. 4 is as shown in FIG.This exampleIs omitted. Other configurations and operations are the same as those of the first embodiment.
[0053]
In this configuration, since it is dedicated to “operation” from the polling system 1 to the contention system 2, the address of the polling system 1 is always the address of the terminal 11 that controls the load, and the address setting becomes easy. Further, when viewed from the contention system 2, the inter-system interface 3 can always be regarded as the node device 21 having a switch, and the system construction becomes easy.
[0054]
  (SecondEmbodiment)
  This embodimentThe secondIn the first embodiment, the “control” function from the polling system 1 to the contention system 2 is omitted. Therefore, the direction selection switch 36 (see FIG. 1) is not necessary in this embodiment. Further, since only “control” from the contention system 2 to the polling system 1 is performed, as shown in FIG. 11, the function of the “switch” in FIG. 4 is omitted in this embodiment. Other configurations and operations are the same as those of the first embodiment.
[0055]
  In this configuration, since it is dedicated to “control” from the contention system 2 to the polling system 1, the address of the polling system 1 is always the address of the terminal 11 that monitors the operation of the switch, and the address setting is easy. Become. Further, when viewed from the contention system 2, the inter-system interface 3 can always be regarded as a node device 21 having a load, and the system construction is facilitated. Note that the inter-system interface 3 of the present embodiment andReference exampleIn combination with the inter-system interface 3 in FIG. 1, “control” and “operation” can be performed between the polling system 1 and the contention system 2, and a system similar to that of the first embodiment is used. In this case, each inter-system interface 3 can only be “controlled” or “operated”. Therefore, it is more convenient than the first embodiment in that it is easy to set an address. Increases nature.
[0056]
【The invention's effect】
  According to the configuration of the present invention, the poIt is possible to associate the other load with one input of the first ring-type remote control system and the second contention-type remote control system, and more than one for the first remote control system. Since it functions equivalently to a terminal device and functions equivalent to a node device for the second remote control system, it can be simply connected to the first signal line and the second signal line. It becomes possible to cope with a plurality of inputs and loads.In addition, when the first load is controlled by the second input in the control unit, the first load is forcibly controlled according to the instruction content by the second input regardless of the control state of the first load. Even if there is a discrepancy with the control state recognized by the node device of the second remote control system, the load of 1 is controlled in the first remote control system. When the control of one load is instructed, the content of the instruction is reliably transmitted to the first load, so that the discrepancy in recognition at the node device on the control side is eliminated. For example, when group control is performed in the first remote control system, the control state of the first load under group control cannot be changed by individual control in the first remote control system. However, by using the node device in the second remote control system, the first load included in the group control can be controlled to a target state.
[0057]
According to the configuration of the invention of claim 2, the firstWhen the load state is changed by controlling the load in the system of the first remote control system and the second remote control system, the terminal associated with the load in the other system or The load status change is notified to the node device, and even if the load status changes without going through the inter-system interface, the control status provided across the inter-system interface can recognize the load status change. It is possible to prevent a discrepancy between the recognition on the control side and the actual load state.
[0058]
Moreover, the secondInput and load between the first remote control system and the second remote control system with a simple configuration in which only one inter-system interface is connected between one signal line and the second signal line. Can be related.
[0060]
  Claim 3InventionAccording to the configuration ofOnly the address of the terminal that monitors the input needs to be set in the address storage unit, and the second signal processing unit only needs to function as a node device on the load side. .
[0061]
  Claim 4InventionLikeTransmission direction setting means for setting the direction of information transmission in the control unit for each set of addresses associated with each other in the dress storage unit and the state storage unitIn preparation,Since the direction of control can be arbitrarily distributed in units of circuits (units of addresses), when multiple circuits in each direction are required, there is no need to provide an inter-system interface for each direction and the occupied space is relatively small. Can be small.
[0063]
  Claim 5InventionAccording to the configuration ofDress storageThenThe address can be set regardless of the operation state of the second remote control system and the storage contents of the state storage unit.ThenThe address can be set regardless of the operating state of the first remote control system and the stored contents of the address storage unit.So secondConstruction and setting of the first remote control system and the second remote control system can be performed individually, and even if the contractors managing each system are different, adjustment of the timing of construction and setting becomes unnecessary.
[0064]
  Claim 6InventionAccording to the configurationSince various control types that can be controlled by one remote control system can be selected, various controls are possible.
[0065]
  Claim 7InventionAccording to the configurationIn the 1 signal processing unit, when the dimming level instructed by the second input is different from the dimming level of the first load to be controlled, the dimming level is controlled to approach, and the increase / decrease of the dimming level is stopped. Since the control is performed so as to stop the change of the light control level when the light is instructed, the light control by the light control level instruction becomes possible.
[0066]
  Claim 8InventionAccording to the configurationThe one-signal processing unit controls the dimming level in the instructed direction when an increase / decrease in dimming level is instructed by the second input, and changes in the dimming level when instructed to stop increasing / decreasing the dimming level. Therefore, dimming control based on an instruction to increase or decrease the dimming level becomes possible.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of the present invention.
FIG. 2 is a block diagram showing the usage pattern of the above.
FIG. 3 is a front view of the main part of the above.
FIG. 4 is an operation explanatory view of the above.
FIG. 5 is an operation explanatory diagram of the above.
FIG. 6 is an operation explanatory view of the above.
FIG. 7 is an operation explanatory diagram of the above.
[Fig. 8]Reference exampleFIG.
FIG. 9 is a front view of the main part of the above.
FIG. 10 is an operation explanatory diagram of the above.
FIG. 11 shows the present invention.SecondIt is operation | movement explanatory drawing which shows this embodiment.
[Explanation of symbols]
  1 Polling system
  2 Contention system
  10 Transmission unit
  11 Terminal
  13 Address storage
  16 Corresponding selection switch
  17 Calculation selection switch
  21 node equipment
  22 State storage
  30 Control unit
  31 1st signal processing part
  32 Second signal processing unit
  Ls1 signal line
  Ls2 signal line

Claims (8)

A plurality of terminals each having an address and a transmission unit are connected via a first signal line, and a transmission unit is connected to a terminal that monitors the first input and a terminal that controls the first load. Transmits a transmission signal in which an address is specified by a time division multiplex transmission method, and a first remote control system of a polling method in which a first load is controlled according to a first input, and a plurality of addresses each having an address By transmitting a transmission signal specifying an address between the node device connected to the second node device via the second signal line and monitoring the second input and the node device controlling the second load, A remote connected to the first signal line and the second signal line so as to be interposed between the contention-type second remote control system in which the second load is controlled in response to the second input. Control system A first signal processing unit and a second signal processing unit capable of transmitting and receiving a transmission signal transmitted through the first signal line and a transmission signal transmitted through the second signal line, respectively, An address storage unit storing a plurality of addresses equivalent to the terminal used in the first signal processing unit, a state storage unit storing a plurality of addresses of the node device used in the second signal processing unit, and an address storage unit at least a second input of the information transmission to control the first load by the first information for controlling the second load by the input of the transmission and a second input with associating each other's addresses and state storage unit and And a control unit that enables information transmission for controlling the first load. When the control unit controls the first load by the second input, the second load is controlled regardless of the control state of the first load. By input Intersystem interface of a remote control system, characterized by forcibly controlling the first load instruction content.   The control unit performs both information transmission for controlling the second load by the first input and information transmission for controlling the first load by the second input, and changes the state in the first load. It has both a function of notifying a node device associated with an address when recognized and a function of notifying a terminal device associated with an address when recognizing a change in state in the second load. The inter-system interface of the remote control system according to claim 1. A function in which the control unit only performs information transmission for controlling the first load by the second input, and notifies the associated node device by the address only when a change in state in the first load is recognized. The inter-system interface of the remote control system according to claim 1, further comprising: 3. A transmission direction setting means for setting a direction of information transmission in the control unit for each set of addresses associated with each other in the address storage unit and the state storage unit. Intersystem interface of the described remote control system. The address storage unit can set an address regardless of the operation state of the second remote control system and the storage contents of the state storage unit, and the state storage unit can operate the address and address of the first remote control system. The inter-system interface of the remote control system according to any one of claims 1 to 4, wherein an address can be set regardless of the storage contents of the storage unit . The address stored in the address storage unit is equivalent to the address of a terminal that monitors the first input in the first remote control system, and is for one-to-one correspondence with the first load. Address, group control address for simultaneously controlling a plurality of first loads to the same control state, and pattern control address for simultaneously controlling a plurality of first loads to a preset control state 6. And a dimming control address set when the first load is a dimmable load. 6. Inter-system interface for remote control systems. When the address stored in the address storage unit is a dimming control address, the first signal processing unit controls the first load that is controlled by the dimming level instructed by the second input. when the light level different from controls in the direction to approach the dimming level, according to claim 6, wherein the characterized that you control to stop the change of the dimming level when the stop of the increase or decrease in the dimming level is instructed Inter-system interface for remote control systems. When the address stored in the address storage unit is a dimming control address, the first signal processing unit is instructed to adjust the dimming level when the second input is instructed to increase or decrease the dimming level. 6. intersystem interface of a remote control system, wherein the controller controls to stop the change of the dimming level when the control direction, stopping the increase or decrease in the dimming level is instructed.

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