KR101149457B1 - Load control system - Google Patents

Abstract

The operation terminal controls the current state of the load when the control receiving unit (store command) receives a control command (storage command) to register the state of the load after the control terminal controls the load L to be operated at a desired light quantity adjustment level. Configured to obtain. Similarly, the control unit of the operation terminal stores in a memory the relationship between each load and the state of each load. Therefore, it becomes possible for an inexperienced user to easily register a relationship for performing bulk control (pattern control).

Description

Load control system {LOAD CONTROL SYSTEM}

The present invention relates to a load control system for controlling a load, and more particularly, to a load control system configured to control a load by an operation of an operation switch.

Japanese Laid-Open Patent Publication No. 2003-037879A discloses a prior art load control system configured to control a load via a time division multiplex transmission signal (TDM transmission signal).

As shown in FIG. 12, the load control system includes a transmission control unit 100, a plurality of operation terminals 102, and a plurality of control terminals 103. The plurality of operation terminals 102 are configured to communicate with the transmission control unit 100 via the two-wire signal line Ls. The operation terminal 102 has operation switches S1, ..., respectively. The control terminals 103 are each configured to control the lighting load. The lighting load is hereinafter referred to as the load.

Each operation terminal 102 has an individual operation terminal address, and likewise each control terminal 103 has an individual control terminal address. The transmission control unit is configured to communicate with the operation terminal 102 and the control terminal 103 using the individual operation terminal addresses and the individual control terminal addresses.

The transmission control unit 100 is configured to transmit a transmission signal Vs having the format shown in FIG. 13A to the signal line Ls. The transmission signal Vs includes a synchronization signal SY, mode data MD, address data AD, control data CD, checksum data CS, and a signal return period WT. The synchronization signal SY indicates the start of signal transmission. The mode data MD indicates the mode of the transmission signal Vs. The address data AD is provided for selecting the operation terminal 102 or the control terminal 103. Control data CD is provided for controlling the load 104. Checksum data CS is used to detect errors in signal transmission. The signal return period WT is a time slot for receiving a return signal (monitor signal) from the operation terminal 102 and the control terminal 103. The transmission signal Vs corresponds to a TDM transmission signal. The transmission signal Vs is pulse width modulated and then transmitted to the signal line Ls as shown in Fig. 13B. In the operation terminal 102, when the operation terminal 102 recognizes address data AD of the same transmission signal Vs as its operation terminal address, the operation terminal 102 receives the control data CD. . Thereafter, the operation terminal 102 transmits a current mode signal representing the monitor data to the transmission control unit 100. In the same way, when the control terminal 103 recognizes the address data AD of the transmission signal Vs that is the same as its control terminal address, the control terminal 103 receives the control data CD. Thereafter, the control terminal 103 transmits a current mode signal representing the monitor data to the transmission control unit 100. It should be noted that the current mode signal is the same as the signal transmitted by the means for electrically shorting the signal line Ls via low impedance.

When the transmission control unit 100 transmits data to the desired operation terminal 102 and the control terminal 103, the transmission control unit 100 generates a transmission signal. This transmission signal includes "mode data MD indicating control mode " and " address data AD indicating control terminal address of desired control terminal or control terminal address of desired control terminal ". When the transmission control unit 100 transmits the transmission signal Vs to the signal line Ls, the operation terminal 102 and the control terminal 103 check whether the address data AD is the same as its address. When the operation terminal 102 or the control terminal 103 recognizes that the address data AD is the same as its own address, the operation terminal 102 or the control terminal 103 receives the control data CD. Subsequently, the operation terminal 102 or the control terminal 103 transmits the monitor data within the signal return period. The transmission control unit 100 compares "monitor data received within the signal return period" with "control data CD transmitted from the transmission control unit 100". When the "monitor data received within the signal return period" is the same as the "control data CD transmitted from the transmission control unit 100", the transmission control unit 100 recognizes that the transmission of the control data CD is completed. do. In the control terminal 103, the control terminal 103 generates a load control signal based on the control data CD transmitted from the transmission control unit 100. The load control signal is provided to control the load 104. Subsequently, the control terminal 103 outputs a load control signal. In the operation terminal 102, in accordance with the control data CD, the operation terminal 102 outputs a display signal for controlling the display such that the display indicates the state of the load 104. FIG.

On the other hand, the transmission control unit 100 in the normal state is configured to transmit the transmission signal having the mode data MD at regular intervals in the dummy mode. This is called constant polling. In this case, the transmission control unit 100 accesses the control terminal 103 to request the return of the monitor data indicating the state of the load. On the other hand, the specific control terminal 103 accessed by the transmission control unit 100 transmits the "state of the load connected to the specific control terminal 103" to the transmission control unit 100. When the transmission control unit 100 receives the state of the load from the specific control terminal 103, the transmission control unit 100 accesses the specific operation terminal 102 corresponding to the specific control terminal 103, The control data CD is transmitted to display the state of the load connected to the control terminal 103.

In this way, the transmission control unit 100 periodically accesses both the control terminal 103 and the operation terminal 102 corresponding to the control terminal 103 through constant polling.

When the operation terminal 102 or the control terminal 103 transmits specific information to the transmission control unit 100 under constant polling, the operation terminal 102 or the control terminal 103 is shown in (c) of FIG. 13. In the dummy mode, an interrupt signal synchronized with the sync signal SY of the transmission signal Vs is generated. Subsequently, the operation terminal 102 sets an interrupt flag for the transmission control unit 100 to prepare for transmission and reception of information. When the transmission control unit 100 receives the interrupt signal, the transmission control unit 100 generates a transmission signal. This transmission signal has mode data MD indicating an interrupting polling mode. The transmission signal also has address data AD. The transmission control unit 100 gradually increases the upper half bit of the address data AD (that is, when the address data AD has 8 bits, the upper four bits are gradually increased). Subsequently, the transmission control unit 100 continuously transmits the transmission signal while increasing the upper half bit of the address data AD. The operation terminal 102 for generating the interrupt signal checks the upper four bits of the address data AD in the transmission signal of the interrupting polling mode. When the operation terminal 102 recognizes that the upper four bits of the address data AD in the transmission signal are the same as the upper four bits of the operation terminal address of the operation terminal 102, the operation terminal 102 generates an operation terminal address ( The lower 4 bits of the operation terminal address of 102 are transmitted to the transmission control unit 100. In this way, the transmission control unit 100 is configured to search the operation terminal 102 for generating an interrupt signal every 16 operation terminals 102. Therefore, it is possible to find the operation terminal 102 which generates the interrupt signal in a short time.

When the transmission control unit 100 obtains the address of the operation terminal 102 generating the interrupt signal, the transmission control unit 100 generates a transmission signal having the mode data MD in the monitor mode, and subsequently The transmission signal Vs including the address data AD representing the obtained address is transmitted to the signal line Ls. In response to the transmission signal Vs, the operation terminal 102 transmits the information in the signal return period WT to the transmission control unit 100. Finally, the transmission control unit 100 transmits a signal for canceling the interrupt to the operation terminal 102 generating an interrupt signal, whereby the transmission control unit 100 frees the interrupt flag of the operation terminal 102. Unlock As described above, the transmission of information from the operation terminal 102 to the transmission control unit 100 is completed by four signal transmissions from the transmission control unit 100 to the operation terminal 102 (that is, the first Corresponds to dummy mode, the second corresponds to the interrupting polling mode, the third corresponds to the monitor mode, and the fourth corresponds to the signal to cancel the interrupt). When the transmission control unit 100 needs to recognize the operation state of the desired control terminal 103, only the transmission control unit 100 transmits a transmission signal having the mode data MD in the monitoring data.

As a result, when operation data is generated in accordance with the operation of the switches S1, ..., the operation terminal 102 transmits the operation data to the transmission control unit 100 as monitor data. Based on the operation data, the transmission control unit 100 generates a transmission signal Vs having control data, and transmits the transmission signal Vs to the control terminal 103. When the control terminal 103 receives the transmission signal, the control terminal 103 controls the load 104. Specifically, when the control terminal 103 receives the transmission signal, the control terminal 103 turns on or off the load according to the control data. Subsequently, the control terminal 103 returns the monitor data to the transmission control unit 100. Then, the transmission control unit 100 transmits the transmission signal Vs having the control data CD generated based on the returned monitoring data. The operation terminal 102 turns on or off the display light indicating the operation state of the load whether the load emits light or not. The display light is generated by, for example, a light emitting diode or the like.

On the other hand, the transmission control unit 100 in this type of load control system stores the relationship of the switch and the address of the load. Thus, it is possible to control the plurality of loads 104 by one switch when one switch is associated with the addresses of the plurality of loads 104. In other words, when one switch is associated with the addresses of the plurality of loads 104, it is possible to perform bulk control of controlling the plurality of loads 104 by one switch. Examples of bulk control are group control and pattern control. When the transmission control unit 100 performs group control, the transmission control unit 100 controls the plurality of loads 104 so that all the loads have the same control state. On the other hand, when the transmission control unit 100 performs group control, the transmission control unit 100 controls the plurality of loads 104 so that each load has a predetermined control state. An operation terminal (not shown) for performing bulk control such as pattern control and group control has a switch related to an address determined for bulk control. Examples of addresses determined for bulk control are group addresses and pattern addresses. However, the configuration other than the function of the bulk control of the operation terminal is the same as that of the operation terminal which does not perform the bulk control.

In addition, when the switch for bulk control of the operation terminal is operated, the transmission control unit 100 obtains an address (e.g., a group address) assigned to the switch. Subsequently, the transmission control unit 100 generates control data for controlling a plurality of loads related to the group address. Then, the transmission control unit 100 transmits the control data to the control terminal 103 in order. In this way, the transmission control unit 100 controls the loads grouped in the same group.

However, in the conventional load control system, the control terminal 103 is not configured to transmit the transmission signal Vs directly to the operation terminal 102 and receive it directly from the operation terminal 102. That is, the control terminal 103 is configured to transmit the transmission signal Vs to the operation terminal 102 through the transmission control unit 100 and to receive the transmission signal Vs from the operation terminal 102. Thus, this is referred to as a load control system of the central control type. In the load control system of the central control type, the transmission control unit 100 performs integrated management of addresses for performing bulk control (pattern control and group control). In other words, it is necessary to register the relationship for the transmission control unit 100 to perform bulk control. However, since the registration operation requires a special setter (not shown), it is difficult to register a relationship for performing bulk transfer. Therefore, only a professional operator can register an address. That is, there is a problem that it is difficult for an inexperienced user to register an address.

The present invention is to solve the above problems. It is an object of the present invention to provide a load control system in which an inexperienced user can easily register a relationship of bulk control.

In order to solve the above problems, the present invention provides a load control system for controlling one or more loads. The load control system includes one or more control terminals and one or more operation terminals. The control terminal is connected to the one or more loads. The operation terminal is connected to at least one of the control terminals via a signal line. Each said control terminal has a control terminal identification code individually, and each said operation terminal has an operation terminal identification code individually. The control terminal comprises a first input receiving means, a first control means, and a first communication means. The first input receiving means has at least one first operating switch for inputting a first control command. The first control means is configured to control a predetermined load in response to the first control command when the first input receiving means receives the first control command. The predetermined load corresponds to the first control command and is controlled by the first control means. In other words, the predetermined load is under the control of the first control means. The operation terminal has a second input receiving means, a memory, a second control means, and a second communication means. The second input receiving means has one or more second operation switches for inputting a second control command. The memory stores a relationship between the second control command and one or more control terminal identification codes in relation to control information. That is, the memory stores a relationship between a second control command and one or more control terminal identification codes, and a relationship between the second control command and control information, whereby the second control command includes one or more control terminal identification codes and control information. Is related. The control information indicates a predetermined state and causes one or more loads to be controlled by the control terminal to be in a predetermined state. The second communication means communicates with the first communication means. The second control means is configured to recognize the second control command received by the second input receiving means. Further, the second control means is configured to access the memory to obtain a control terminal identification code and control information associated with the second control command. The second control means also generates a control command for controlling the load to be in a predetermined state based on the obtained control information, and sends a "command signal including a control command and acquired control terminal identification information" to the second. And transmit from the communication means to the control terminal via a signal line. The control terminal is configured to receive the command signal transmitted from the second communication means via the signal line via the first communication means. The control terminal is configured to control a predetermined load to be in a predetermined state according to the control command when the control terminal identification code of the command signal is the same as the control terminal identification code of the control terminal itself. The first control means is configured to transmit a status signal to the operation terminal at a predetermined timing. The status signal indicates the current state of a predetermined load controlled by the control terminal. The second control means is configured to recognize a present state of a predetermined load and determine the present state as a predetermined state of the load. The second control means is configured to store a relationship between the current state and the control terminal identification code in the memory when the second input receiving means receives a storage command by the second input receiving means.

In this case, an inexperienced user can easily register a relationship for bulk control. Specifically, an inexperienced user can easily register a relationship for bulk control through the following steps. First, the user manipulates the control terminal to control the load to a desired state. Subsequently, the second input receiving means of the operation terminal receives a control command for registering the state of the load. As a result, the relationship between each load and the state of each load can be registered. Thus, an inexperienced user can also easily register a relationship for bulk control.

The first control means is configured to transmit a status signal indicative of the current state of the predetermined load when the first control means controls the load. The second control means is configured to store the state of the load included in the state signal when the second control means receives the state signal. The second control means is configured to access the memory to obtain a state of the load controlled by the control terminal when the second input receiving means receives a storage command. The second control means is configured to generate and store a relationship between the load and the state of the load obtained from the memory in the memory.

This configuration can reduce the traffic between the control terminal and the operation terminal.

The second control means is configured to cause the second communication means to transmit a request signal to the first communication means when the second input receiving means receives the storage command. The first control means is configured to cause the first communication means to transmit the status signal to the second communication means when the first communication means receives the request signal. The second control means is configured to recognize a current state of the load from the state signal and to create a relationship between the load and the state of the load. The second control means is configured to store the relationship in a memory.

In this case, it is not necessary to necessarily store the state of the load connected to the control terminal. Thus, this configuration can reduce the consumption of space in the memory.

The second control means is configured to detect a first operation input when the second operation switch is operated for a first period of time. The second control means is configured to detect a second operation input when the second operation switch is operated for a second period longer than the first period. The control means is configured to obtain a control terminal identification code corresponding to the first operation input by accessing the memory, and is configured to generate a control command for controlling the load, wherein the control means is configured to control the control command and the And generate a control signal having a control terminal identification code obtained from the memory. The control means is configured to transmit the control signal to the control terminal via a signal line. The second control means is configured to recognize a state of the load controlled by the control terminal when the control terminal receives the second operation input. The second control means is configured to generate a relationship between the load and the state of the load, and the second control means is configured to store the relationship in the memory.

According to this configuration, the operation switch has a function of controlling a load and a function of registering a load. In addition, registration and control can be prevented from occurring at the same time.

The operation terminal is connected to one or more of the loads controlled by the operation terminal. The second control means is configured to control the load controlled by the operation terminal when the second input receiving means receives the second control command.

According to this structure, the load connected to the operation terminal can be directly controlled through the operation of the operation terminal.

1 is a conceptual diagram of a load control system of a first embodiment.
2 is a block diagram of a control terminal in the first embodiment.
3 is a block diagram of an operation terminal in the first embodiment.
4A and 4B are diagrams showing a packet in the first embodiment.
Fig. 5 is a diagram showing a procedure for explaining the operation in the first embodiment.
Fig. 6 is a diagram showing a procedure for explaining the operation in the first embodiment.
Fig. 7 is a diagram showing a procedure for explaining the operation under the registration mode in the first embodiment.
8 is a diagram showing a procedure for explaining the operation under the registration mode in the first embodiment.
9 is a conceptual diagram of the load control system of the second embodiment.
10 is a diagram showing a procedure for explaining the operation in the second embodiment.
Fig. 11 is a diagram showing a procedure for explaining the operation in the second embodiment.
12 is a conceptual diagram of a load control system of the prior art.
13 is an exemplary diagram of a transmission signal in a load control system of the prior art.

Hereinafter, a load control system will be described with reference to the accompanying drawings. The following embodiments are described using packet transmission as a transmission system for transmitting a transmission signal. However, the transmission system for transmitting the transmission signal is not limited to being packet transmission. Therefore, the load control system may employ a transmission system other than packet transmission.

(First embodiment)

1 shows a load control system of this embodiment. The load control system of this embodiment includes a plurality of control terminals 1 and a plurality of operation terminals 2. Specifically, the load control system of this embodiment includes four control terminals and two operation terminals. Each control terminal is connected to a load L. The control terminal 1 is configured to communicate with the operation terminal 2 via a signal line. In this embodiment, an example of a load L is an illumination load that is electrically connected to a commercial AC source (AC current source). However, the load control system in the present invention can control not only the lighting load L but also other devices such as air conditioners, fans, and electric curtains.

The load control system of the present embodiment includes a plurality of control terminals 1. Specifically, the load control system of this embodiment includes control terminals 1A, 1B, 1C, and 1D. The control terminal 1A has an operation switch S11. The operation switch S11 is used for input of the control command. The control command is defined as the first control command. The control terminal 1A is configured to control the load L directly connected to the control terminal 1A. Therefore, the load L directly connected to the control terminal 1A will be controlled by the control terminal 1A. The control terminal 1A has an individual lighting function of turning on or off the load L when the operation switch S11 is operated. The control terminal 1B is configured to control the load L directly connected to the control terminal 1B. Therefore, the load L directly connected to the control terminal 1B will be controlled by the control terminal 1B. The control terminal 1B has a plurality of (specifically, two) operation switches S21 and S22. The control terminal 1B is connected to a plurality of (specifically, two) loads L corresponding to the operation switches S21 and S22. The control terminal 1B also has a lighting function for individually turning on or off the lighting device when the operation switches S21 and S22 are operated. The control terminal 1C has operation switches S31, S32, S33. The control terminal 1C is configured to control the load L directly connected to the control terminal 1C. Therefore, the load L directly connected to the control terminal 1C will be controlled by the control terminal 1C. The control terminal 1C is configured to turn on the load when the operation switch S31 is operated. The control terminal 1C is configured to change the light output of the load L when the operation switch S32 is operated. On the contrary, the control terminal 1C is configured to change the light output of the load L when the operation switch S33 is operated. That is, the control terminal 1C has a light amount control control function for changing the light output of the load when the operation switch S32 or S33 is operated. The control terminal 1D has operation switches S41, S42, S43. The control terminal 1D is configured to control the load L directly connected to the control terminal 1D. Therefore, the load L directly connected to the control terminal 1D is controlled by the control terminal 1D. The control terminal 1D is configured to turn on the load when the operation switch S41 is operated. The control terminal 1D is configured to change the light output of the load L when the operation switch S42 is operated. On the contrary, the control terminal 1D is configured to change the light output of the load L when the operation switch S43 is operated. That is, the control terminal 1D has a light amount adjustment control function that changes the light output of the load when the operation switch S42 or S43 is operated. Note that the control terminals 1A to 1D are collectively referred to as the control terminal 1 if necessary. In addition, the operation switch of the control terminal 1 becomes equivalent to a 1st operation switch.

In contrast, the operation terminal 2 is not connected to the load. The operation terminal has a plurality of operation buttons S51 to S53 or S61 to S62, respectively. The operation terminal 2 is configured to transmit a packet containing a control command to at least one of the control terminals 1 via the signal line Ls. When the control terminal 1 receives a packet, the control terminal 1 controls the load to be controlled by the control terminal 1. That is, when the control terminal 1 receives a packet, the control terminal 1 controls the load under the control of the control terminal 1. That is, the operation terminal 2 has a remote control function such that at least one of the control terminals 1 for controlling the load is controlled by the control terminal 1.

Both the control terminal 1 and the operation terminal 2 are installed on a wall of a building or the like through a frame and a face plate.

2 shows a circuit block diagram of the control terminal 1. The signal communication unit 12 is configured to convert a packet having the format of FIG. 4A into a code, and then modulate the encoded packet into a digitally encoded packet. The signal communication unit 12 then sends a digitally coded packet to the signal line Ls. Further, when the signal communication unit 12 receives the digitally encoded packet from the signal line Ls, the signal communication unit 12 is configured to modulate and decode the digitally encoded packet. Subsequently, the signal communication unit 12 recognizes a source and a destination based on a control terminal identification code individually assigned to each control terminal 1. A physical address unique to the hardware may be used as the control terminal identification code. An example of a unique physical address for the hardware is a MAC address assigned by the manufacturer of the hardware. It is also possible to use an address arbitrarily assigned by the user as the control terminal identification code. That is, it is only required that each of the control terminal identification code and the operation terminal identification code is not the same as the other control terminal identification code and the operation terminal identification code. Packets transmitted from the control terminal 1 and the operation terminal 2 are data such as a preamble for achieving synchronization, control bits for setting the type of data, a destination address, a source address, a control command, and Has a checksum The load control system utilizes multiple transmissions through carrier sense multiple access / collision detection (CSMA / CD). Note that the communication unit 12 is the same as the first communication means. The communication unit 12 is configured to communicate with the communication unit 22 as described below.

The input receiving unit 11 is configured to monitor the operation state of the operation switch S11,... When the operation switch S11 is operated, the input receiving unit 11 receives the first control command. Subsequently, the input receiving unit 11 outputs an operation signal corresponding to the first control command. Note that the operation switches S11, ... are realized by a push button switch and an operation lever (not shown) provided for pushing the push button switch. The push button switch, for example, has a contact that is normally open. When the push button switch is not pushed, the contact is opened, whereby the switch is on. When the push button switch is pushed, the contact is closed, whereby the switch is in the off state. That is, in response to the switching on or off of the push button switch, the input receiving unit 11 recognizes the operation input via the operation switch S11. Note that the input receiving unit 11 is the same as the first input receiving unit.

The control unit 10 has a CPU that operates as a main component of the control unit 10. The control unit 10 generates a control signal corresponding to the received operation signal after receiving the operation signal output from the input receiving unit 11. Then, the control unit 11 transmits a control signal to the load operation unit 14. The load operating unit 14 of the control terminals 1A and 1B is configured to start or stop supplying electrical power to the load from commercial AC power in accordance with the control signal. The load manipulation unit 14 of the control terminals 1C, 1D is configured to start or stop supplying electrical power to the load from a commercial AC power source in accordance with the control signal. The load operation unit 14 of the control terminals 1C, 1D is also configured to adjust the amount of electric power supplied to the load L per unit time according to the control signal. As a result, the load operating unit 14 of the control terminals 1C and 1D is configured to increase and decrease the amount of light output from the load L. As shown in FIG. The ability to start or stop supplying electrical power is realized through well-known relays. Likewise, the function of adjusting the amount of electrical power supplied to the load per unit time is realized through a phase control system realized by the well-known triacs. Therefore, detailed description of the configuration of the relay and the triac is omitted. Note that the control unit 10 is the same as the first control means. Thus, the control unit 10 forms the first control means.

The memory 13 is realized by a nonvolatile semiconductor memory configured to be electrically rewritable. Examples of the memory 13 are an EEPROM and a flash memory. The memory 13 stores information such as a multicast address, a load identification code for identifying the plurality of loads L, and the like. However, when each control terminal 1 has an individual control terminal identification code assigned thereto, each memory 13 stores its own control terminal identification code. A display 15 is provided for displaying the operation status of the load L to be controlled by the control terminal 1. The display 15 has a light emitting element LD11, ... (for example, LED) and a driving circuit (not shown) for driving the light emitting element. The display 15 is configured to turn on or off the light emitting element based on the control signal transmitted from the control unit 10. As shown in Fig. 1, it should be noted that the light emitting elements are disposed adjacent to each operation switch, whereby it is easily realized that the operation switch S11 corresponds to the adjacent light emitting element LD11. The electrical power source 16 receives AC power from a commercial AC power source and converts AC power into DC power for operation of each unit.

After this, the operation of the control terminal 1 for controlling the load to be controlled by the control terminal itself will be described. When the operation switch S1 is operated, the input receiving unit 11 receives the first control command. Immediately after receiving the first control command, the input receiving unit 11 generates an operation signal and transmits it to the control unit 10. When the control unit 10 receives the operation signal, the control unit 10 generates a control signal based on the operation signal and transmits it to the load operation unit 14. The load signal inverts the state of the load L. When the load operation unit 14 receives the control signal from the control unit 10, the load operation unit 14 closes or opens the relay based on the control signal so that the operation state of the load L is inverted (load When (L) is in the on state, the load operation unit 14 opens the relay to turn off the load L when receiving the control signal, on the contrary, when the load L is in the off state, the load operation is performed. The unit 14 closes the relay to turn on the load L when receiving the control signal). In addition, the control unit 10 is displayed after the control unit 10 transmits a control signal to the load operation unit 14 so that the display 15 reverses the state of the light emitting element LD11 as soon as the control signal is received. Sends a control signal to 15 (the display turns off the light emitting element LD11 when the light emitting element LD11 is on. On the contrary, when the light emitting element LD11 is off, the display emits light. The element LD11 is turned on). In the control terminal 1B, when one switch S21 is operated, the states of one of the light emitting element and the load L corresponding to the switch S21 are reversed. On the contrary, when one switch S22 is operated, the state of one of the light emitting element and the load L corresponding to the switch S22 is reversed.

In the control terminals 1C and 1D, when the operation switches S31 and S41 are operated, the states of the light emitting elements LD31 and LD41 and the load L corresponding to the operation switches S31 and S41 are reversed. In addition, when the operation switches S32 and S42 are operated while the load L is in the on state, an operation signal is transmitted from the input receiving unit 11 to the control unit 10. When the control unit 10 receives the operation signal, the control unit 10 outputs a control signal to increase the light output of the load L. In accordance with a control signal for increasing the light output of the load L, the load operation unit 14 controls the drive circuit to increase the amount of electrical power supplied to the load L per unit time. In addition, when the operation switch S33 or S43 is operated while the load L is in the on state, the input receiving unit 11 transmits an operation signal to the control unit 10. When the control unit 10 receives the operation signal, the control unit 10 outputs the control signal to reduce the amount of electric power supplied to the load L per unit time. In accordance with a control signal for reducing the amount of electrical power supplied to the load L, the load operation unit 14 controls the drive circuit to reduce the amount of electrical power supplied to the load L per unit time. This operation is performed when the load L is on. However, it is not limited to this. That is, these operations can be performed when the load L is in the off state. In this case, when one of the operation switches S32, S42, S33, S43 is operated while the load L is in the off state, the load operation unit 14 increases the electric power supplied to the load L per unit time. Reduce or decrease. In addition, the control unit 10 is configured to store a light amount adjusting level of the load L in the memory when the operation switch S31 or S41 is operated to turn off the load L. FIG. In this case, the control unit 10 is configured to read the light amount adjustment level from the memory, and controls the load operation unit 14 so that the load L outputs light at the light amount adjustment level stored in the memory. In this case, it is possible to immediately resume the load L to the final light quantity adjustment level.

3 shows a circuit block diagram of the operation terminal 2. As shown in FIG. 3, the operation terminal 2 includes a control unit 20, an input receiving unit 21, a signal communication unit 22, a memory 23, a display 24, and a power source 25. It includes. The signal communication unit 22 is configured to convert the packet (shown in Fig. 4A) into a code, and is subsequently configured to modulate the encoded packet into a digitally encoded packet. The signal communication unit 22 then transmits the digitally encoded packet via the signal line Ls. Further, when the signal communication unit 22 receives the digitally encoded packet, the signal communication unit 22 decodes the digitally encoded packet to recognize the identification code in the digitally encoded packet, whereby the signal communication unit 22 Recognize source and destination. Note that the communication unit 22 is the same as the second communication means. Thus, the communication unit 22 forms the second communication means.

The input receiving unit 21 is configured to monitor the operation state of the operation switches S51, S52, S53, S61, and S62. When the operation switch S51 is operated, the input reception unit 21 receives a control command. When the operation switch S51 is operated, a control command is generated. The control command generated when the operation switch S51 is operated forms a second control command. In accordance with the operation of the operation switch S51, the input receiving unit 21 receives the second control command. Subsequently, the input receiving unit 21 outputs an operation signal corresponding to the control command. Note that the operation switches S51, ... are realized by a push button switch and an operation lever (not shown) provided for pushing the push button switch. The push button switch, for example, has a contact that is normally open. When the push button switch is not pushed, the contact is opened, whereby the switch is on. When the push button switch is pushed, the contact is closed, whereby the switch is in the off state. That is, in response to the switching on or off of the push button switch, the input receiving unit 21 recognizes the operation input via the operation switches S51,... Note that the input receiving unit 21 corresponds to the second input receiving means. Thus, the input receiving unit 21 forms the second input receiving means.

The control unit 20 has a CPU that operates as a main component of the control unit 20. When the input receiving unit 21 receives the second control command, the input receiving unit 21 transmits an operation signal corresponding to the second control command. The control unit 20 generates the control command corresponding to the received operation signal after receiving the operation signal output from the input receiving unit 21. The memory 23 is realized by a nonvolatile semiconductor memory configured to be electrically rewritable. Examples of the memory 23 are EEPROM and flash memory. The memory 23 stores information on the control terminal identification code, the multicast address, the operation terminal identification code other than its own, and the state of the load L operated in accordance with the bulk control. Information on the "control terminal identification code", the "multicast address", and the "operation terminal identification code other than its own" belonging to the group or pattern (described below) corresponding to the operation switch S51 is provided in the control terminal ( It is to be controlled by 1) and is used to perform bulk control to control the load L belonging to the control terminal 1. Note that the control unit 20 corresponds to the second control means. Thus, the control unit 20 forms the second control means.

A display 24 is provided for displaying the operation state of the load L, which is controlled by the control terminal 1, belongs to the control terminal 1, and corresponds to the operation switch S51. The display 24 includes light emitting elements LD51, LD52, LD53, LD61, LD62 (e.g., LEDs) and a driving circuit (not shown) for driving the light emitting elements. When all the loads L to be controlled according to the bulk control (such as group control and pattern control) are on, the driving circuit turns off the load L immediately after receiving the control signal transmitted from the control unit 20. Let's do it. When at least one of the loads L to be controlled in accordance with bulk control (such as group control and pattern control) is in an on state, the driving circuit turns on the light emitting elements LD51,... As shown in Fig. 1, the light emitting element is disposed adjacent to the operation switch, whereby it is easily realized that the operation switch S51 corresponds to the adjacent light emitting element LD51. The electrical power source 25 receives AC power from a commercial AC power source and converts AC power into DC power for operation of each unit.

The bulk control will now be described. Bulk control is in the category of group control and pattern control. When the load L is realized by the lighting load L, the pattern control is also referred to as scene control. Group control is a control system which collectively controls loads L in the same group to be in the same operation state. Pattern control is a control system for controlling the load L in the same pattern group to be in a predetermined state for each load. In this embodiment, the operation switches S51 to S53 of the operation terminal 2A correspond to group control. The operation switches S61 and S62 of the operation terminal 2B correspond to pattern control.

For example, the group control corresponding to the operation switch S51 groups all the control terminals 1A to 1D connected to the signal line Ls. The group control corresponding to the operation switch S51 is connected to the control terminals 1A to 1D in the same group to perform the control of turning on or off all the loads L controlled by this terminal. The memory 23 of the operation terminal 2A stores the relationship between the "operation switch S51" and the "control terminal identification code of the control terminals 1A to 1D belonging to the same group".

Pattern control corresponding to the operation switch S61 groups the control terminals 1A to 1D as a first pattern group. The pattern control corresponding to the operation switch S61 turns on the load L under the control of the control terminals 1A to 1D to perform the control of adjusting the light amount adjustment level. In the present embodiment, when pattern control is performed, the load L under control of the control terminal 1A and the control terminal 1B is turned on and operated. The load L under the control of the control terminal 1C is turned on to the 50% light amount adjustment level, and operated at the 50% light amount adjustment level. The load L under the control of the control terminal 1D is turned on at a light quantity adjustment level of 70%, and operated at a 70% light quantity adjustment level. The memory 23 of the operation terminal 2B is the control terminal 1A associated with the "operation switch S61" and the control information (light quantity control level) of each load under the control of the "control terminals 1A to 1D. To 1D) " control terminal identification code ".

In addition, the pattern control corresponding to the operation switch S62 groups the control terminals 1C and 1D as a second pattern group. The pattern control corresponding to the operation switch S62 turns on the load L belonging to the control terminal 1C, adjusts the load to 70% light amount control level, and adjusts the light amount to the load terminal L belonging to the control terminal 1D. Control to turn on and adjust the load to 30% light intensity control level. The memory 23 of the operation terminal 2B stores the relationship between the "operation switch S62" and the "control information of each load L associated with the control terminal identification codes of the control terminals 1C and 1D". do. Note that it is possible for the load L to be grouped into an arbitrarily selected group or pattern group. In addition, as described below, the control terminals 1A to 1D transmit the state of the load L to the operation terminal 2. The operation terminal 2 stores the state of the load in the memory 23.

Next, the operation of the bulk control (group control and pattern control) performed by the operation terminal 2 will be described.

First, the operation of group control by the operation terminal 2A will be described with reference to the procedure shown in FIG. 5. When the operation switch S51 of the input receiving unit 21 is operated, the input receiving unit 21 receives a control command. According to the control command, the input receiving unit 21 transmits an operation signal to the control unit 20. The control unit 20 that receives the operation signal accesses the memory 23 to obtain their relationship. The control unit 20 is provided with the most recent state of the load L (controlled by the control terminals 1A to 1D) corresponding to all of the operation signals (generated by the operation of the operation switch S51). Acquire a control terminal identification code (of control terminals 1A to 1D). If all of the states of the load L obtained from the memory 23 are the same, the control unit 20 instructs to invert the state of the load L relative to the current state of the load L obtained from the memory 23. Generates a control command (specifically, if all the loads L have the ON state, the control unit 20 generates a control command instructing to turn off the load L. In contrast, all the loads L ) Has an off state, the control unit 20 generates a control command instructing to turn on the load L). In addition, the control unit 20 stores data (set as a control command generated by the control unit 20), a destination address (set as a multicast address), and a source address (set as its own operation terminal identification code). Create a packet with In other words, the control unit 20 generates a packet corresponding to the command signal. Thereafter, the control unit 20 transmits a packet (command signal) from the communication unit 22 to the signal line Ls. The control command includes command information (load control as shown in FIG. 4B in this embodiment), control terminal identification code (of control terminals 1A to 1D to be controlled by the operation terminal 2), and Note that it has control information (for controlling the load to be turned on or off in this embodiment). Further, a packet (command signal) having a destination address corresponding to the multicast address is received by all control terminals 1 and operation terminals 2 constituting the load control system.

Each control terminal 1A to 1D receives a packet (command signal) through the communication unit 12 and transmits this packet to the control unit 10. The control unit 10 receives the packet (command signal) and subsequently checks whether the "identification code in the control command of the packet (command signal)" includes "own control terminal identification code of the control terminal". . If the control unit 10 identifies that the identification code in the control command of the packet includes the identification code of the control terminal itself, the control unit 10 generates a control signal. The control signal is developed based on the control information associated with the identification code. In addition, a control signal is provided to turn on or off the load (L). Then, the control unit 10 transmits a control signal to the load operation unit 14. The load operation unit 14 closes or opens the relay to turn on or turn off the load L as indicated by the control signal. Also, after a predetermined period following the operation of the relay, the control unit 10 generates a packet (formed as a status signal). The packet (status signal) has a destination address, a source address, and a state of the load (L). The destination address is set as the source address in the packet (command signal) received by the control terminal 1A, whereby the destination address is set as the operation terminal 2A. The source address is set as the control terminal identification code of the control terminal itself. The state of the load L represents the state of the load L after the load L is controlled. Specifically, the state of the load L represents the state of the load L after the load L is turned on or turned off. Subsequently, the control unit 10 transmits a packet (status signal) from the communication unit 12 to the signal line Ls. In addition, the control unit 10 operates the display 15 to display the state of the load L after the load L is controlled.

On the other hand, the operation terminal 2A receives the packet (status signal) via the communication unit 22 and subsequently transmits the packet (status signal) to the control unit 20. The control unit 20 stores the state of the load L in the packet (status signal) in the memory 23. Then, when the control unit 20 receives a packet (status signal) indicating the state of the load L under the control of the control terminals 1A to 1D corresponding to the operation switch S51, the control unit 20 Activates display 24 to display the state of load L after load L is controlled. For example, when all the loads L are turned on and turned on, the light emitting element LD is turned off and turned off. On the contrary, when all the loads L are turned off and turned off, the light emitting element LD is turned on and turned on. In this way, the display 24 shows the states of all the loads L through the state of the light emitting element LD51 (when the light emitting element LD51 is in the on state, the light emitting element LD51 is connected to all the loads L). Indicates that the light emitting element LD51 is in the off state, the light emitting element LD51 indicates that all the loads L are in the on state. With such a configuration, since the light emitting element shows the states of all the loads L, the necessity of bulk control can be easily realized. Therefore, it is not necessary to necessarily provide display light which respectively shows the state of the load L to an operation terminal.

If the operation terminal 2 does not receive a packet (status signal) from at least one of the control terminals 1A to 1D, the control unit 20 of the operation terminal 2A generates a packet (retry signal). Hereinafter, the case where the operation terminal 2A cannot receive the packet (status signal) which shows the state of the load L from the control terminal 1D is demonstrated. When the operation terminal 2A cannot receive a packet (status signal) indicating the state of the load L from the control terminal 1D, the operation terminal 2A receives a packet (retry signal) having a destination address and a control command. ) The destination address corresponds to the control terminal identification code of the control terminal 1D in which the operation terminal 2A cannot receive a packet (status signal), whereby the destination address in this description identifies the control terminal of the control terminal 1D. Will be identical to the code. The control command includes a command that allows the control terminal 1D to transmit the state of the load to the operation terminal 2A. Subsequently, the control unit 20 of the operation terminal 2A transmits a packet (retry signal) from the communication unit 22 to the signal line. As a result, when the control terminal 1D receives the packet (retry signal), the control terminal 1D sends the packet (status signal) having the state of the load L back to the operation terminal 2A. Therefore, the control unit 20 of the operation terminal 2A stores the state of the load in the memory 23. On the other hand, although the operation terminal 2A transmits a packet (retry signal) having a command to transmit the state of the load L, the operation terminal 2A is in the state of the load L from the control terminal 1D. When it is not possible to receive a packet (status signal) having a, the operation terminal 2A identifies an error of the control terminal 1D. Thereafter, the operation terminal 2A informs the error of the control terminal 1D by blinking the light emitting element LD51 of the display 24. In addition, when the control unit 20 receives a packet (status signal) indicating the status of the load L from all the control terminals 1A to 1D, the control unit 20 loads acquired from the packet (status signal). Generates a packet (transmission signal) for conveying the most recent state of to another operation terminal 2B. In other words, the packet (transmission signal) has a control command, a destination address, and a source address. The control command indicates an instruction to transfer the most recent state of the load L obtained from the packet (status signal) to the other operation terminal 2B. The destination address is determined as the second multicast address corresponding to the operation terminal 2. The source address is determined by the operation terminal identification code of the operation terminal itself. Thereafter, the control unit 20 transmits a packet (transmission signal) to the signal line Ls. When the operation terminal 2B rather than the operation terminal 2A receives a packet (transmission signal) from the operation terminal 2A, the control unit 20 of the operation terminal 2B is " load L after the control terminal control. In addition to " state of the " Subsequently, the operation terminal 2B transmits an ACK packet (which acknowledges receipt of the packet from the operation terminal 2A) to the operation terminal 2A via unicast. However, when the operation terminal 2A cannot receive the ACK packet, the operation terminal 2A retransmits the packet for transmitting the state of the load L.

Next, the pattern control (2nd pattern control) of the operation terminal 2B is demonstrated with reference to FIG. When the operation switch S62 of the operation terminal 2B is operated, the input receiving unit 21 outputs an operation signal to the control unit 20 of the operation terminal 2B. The control unit 20 receives the operation signals and then accesses the memory to obtain their relationship. Then, the control unit 20 controls the control terminal identification code (of the control terminals 1C and 1D) and control information (control terminals 1C and 1D) that are all associated with the control command from the operation switch S62. For the load L to be controlled by. The control terminal identification code represents the control terminals 1C and 1D. The control information includes a command for the load L to be controlled by the control terminals 1C and 1D. The control information also includes the light amount adjustment level of the load L when the load L is operated by the control terminals 1C and 1D. In accordance with the control information obtained from the memory 23, the control unit 20 turns on the load L to 70% light quantity control level under the control of the control terminal 1C, and under the control of the control terminal 1D. Generate a control command to turn on (L) to 30% light intensity control level. Subsequently, the control unit 20 of the control unit 20B generates a packet (command signal) having control information, a destination address, and a source address. The destination address is set as a multicast address. The source address is set as an operation terminal identification code assigned to the operation terminal itself. Thereafter, the control unit 20 transmits a packet (command signal) from the communication unit 22 to the signal line Ls. Note that since the control terminals 1A and 1B do not belong to the second pattern group, the control command does not have the identification code and the control information of the control terminals 1A and 1B.

In each of the control terminals 1A to 1D, when the communication unit 12 receives a packet (command signal), the communication unit 12 transmits a packet (command signal) to the control unit 10. Each control unit 10 of the control terminals 1A and 1B compares the identification code in the packet with the control terminal identification code of the control terminal itself. However, the packet does not contain the same identification code as the control terminal identification codes of the control terminals 1A and 1B. Therefore, each control terminal 1A, 1B does not control the load, but generates a packet (status signal) having data indicating the current state (lighting or turning off) of the load. Subsequently, the control unit 10 transmits the generated packet (status signal) to the signal line Ls. On the other hand, each control unit 10 of the control terminals 1C and 1D compares the identification code in the packet (command signal) with the control terminal identification code of the control terminal itself. In this case, the packet (command signal) contains the same identification code as the control terminal identification codes of the control terminals 1C and 1D. Therefore, each control unit 10 of the control terminals 1C and 1D recognizes the control information corresponding to the identification code of the control terminal itself. Subsequently, each control unit of the control terminals 1C and 1D generates a control signal based on the control signal of the packet (command signal), controls this control signal (load to be turned on, and is represented by the control signal). To operate at the advanced light control level) to the load operation unit 14. In accordance with the control signal transmitted from the control unit 10, the load operation unit 14 controls the drive circuit to adjust the amount of electric power supplied to the load per unit time. In addition, each control unit of the control terminals 1C, 1D generates a packet (status signal) after a predetermined waiting time has elapsed from the reception of the control command. The packet (status signal) contains a destination address, a source address, and data. The destination address is the same as the source address in the control command of the received packet (command signal). The source address is the same as the control terminal identification code of the control terminal itself. The data indicates the state of the load after the load is controlled by the load operating unit 14. Then, the control unit 10 transmits a packet (status signal) to the signal line Ls. That is, the control unit 10 transmits a packet (status signal) to the signal line at a predetermined timing. The control unit 10 also controls the display 15 of the control terminal itself so that the display 15 displays the state of the load L after the load is controlled by the load operation unit 14.

In the control terminal 2B, when the communication unit 22 receives a packet (status signal), the communication unit 22 transmits a packet (status signal) to the control unit 20. The control unit 20 recognizes the current state of the load L from the received packet (status signal), and stores the current state of the load L in the memory 23. Thereafter, the control unit 20 is under control of the control terminals 1C and 1D, and a packet (status signal) for informing all of the states of the load L belonging to the second pattern group corresponding to the operation switch S62. When receiving the control unit 20, the control unit 20 controls the display 24 to turn on the light emitting element LD62. By turning on the light emitting element LD62, the state in which the load L is operated based on the second pattern control is known. Further, after the control unit 20 receives a packet (status signal) for informing the state of the load L from the control terminals 1A to 1D, the control unit 20 receives the most recent load L. Generate a control command to convey the state (obtained from the received packet) to the other operation terminal 2A. Subsequently, the control unit 20 sets the destination address (set as the second multicast address), the source address (set as the operation terminal identification code of the operation terminal 2B itself), and the data (based on the received packet). Generate a packet with the control command generated). The control unit 20 then transmits a packet (transmission signal) from the communication unit 22 to the signal line Ls. The packet (transmission signal) is received by the other operation terminal 2A. The control unit 20 of the operation terminal 2A selects "the most recent state of the load L" and "the state of the load L before the load L is controlled by the control terminal". In the memory 23. Note that the operation of the first pattern control is common to the operation of the second pattern control. Therefore, description of the operation of the first pattern control is omitted.

As described above, in the load control system of the present embodiment, it is possible to directly control the load L under the control of the control terminal 1 via the operation switches S11, ... of the control terminal 1. Further, the load L under the control of the control terminal 1 is operated to operate the operation switches S51, ... of the operation terminal 2 connected to the control terminal 1 via the signal line Ls. It is also possible to control remotely. Further, both the operation terminal 2 and the operation terminal 1 transmit a packet containing a control command to the other terminal via the signal line Ls. Therefore, even when a failure occurs in the operation terminal 2 or the control terminal 1, there is no possibility that a system down occurs. In addition, when the operation terminal 2 remotely controls the plurality of control terminals 1, the operation terminal 2 transmits a packet (command signal) having a control command through a multicast transmission to the plurality of control terminals 1. (When the control terminal 2 remotely controls the plurality of control terminals 1 collectively, the control terminal 2 performs a non-unicast transmission of a packet (command signal) having a control command. Transmission to the plurality of control terminals 1). Therefore, it is possible for the operation terminal 2 to collectively control the load L to be controlled by the operation of the operation terminal 2. That is, the present system has an advantage of improving the response and stability of the load control over the conventional system of the central control method.

Next, the step of registering the relationship of the bulk control to the operation terminal 2 will be described (here, the relationship means a group in the group control and a pattern group of the pattern control).

The steps of registering a group for group control with respect to the operation terminal 2 will be described by the procedure of Figs. "Operation mode" indicates a normal operation mode for performing the above-described individual control or bulk control.

First, when the mode selection switch (not shown) of the input receiving unit 21 of the operation terminal 2A is operated, the input receiving unit 21 receives a control command (same as a storage command). Upon reception of the storage command, the input receiving unit 21 transmits an operation signal to the control unit 20. In response to the reception of the operation signal from the input reception unit 21, the control unit 20 switches the operation mode to the registration mode. Note that a mode selection switch does not need to be provided to the input receiving unit 21 to switch the operation mode to the registration mode. It is possible to employ an input receiving unit 21 configured to detect a command to switch the normal mode to the registration mode when the operation switch is pushed over a predetermined period. In this case, the input receiving unit 21 transmits an operation signal for switching the mode to the registration mode upon detection of an instruction to switch the normal mode to the registration mode.

When the operation switch S51 of the operation terminal 2A is pressed in the state where the operation terminal 2A has the registration mode, the input receiving unit 21 (receiving a control command) sends the operation signal to the control unit 20. Send to The control unit 20 transmits a control signal to cause the display 24 to light up the light emitting element LD1 corresponding to the operation switch S51, whereby the display 24 causes the operation terminal 2A to register. Inform the user that it has a. In addition, the control unit 20 generates a control command instructing the control unit 10 of the control terminal 1 to switch the normal mode to the registration mode. Then, the control unit 20 generates a packet (registration signal) having a control command, a destination address (set as a multicast address), and a source address (set as an operation terminal identification code of the operation terminal itself). The control unit 20 transmits a packet (registration signal) from the communication unit 22 to the signal line Ls.

Immediately after receiving the packet (registration signal) from the operation terminal 2, the control unit 10 of the control terminal 1 registers the operation mode according to the control command in the packet (registration signal) transmitted from the operation terminal 2. Switch to mode. When the control terminal 1 has a registration mode, it is possible to select whether or not the load L under the control terminal 1 is included in a group of group control by pushing the operation switch S11 for a predetermined period. . That is, when the operation switch S11 is pushed for a predetermined period, the load L under the control terminal 1A is controlled when the group control is performed. On the other hand, if the operation switch S11 is not pushed, the load L under the control terminal 1A is not controlled even when group control is performed. At the time when the control terminal is switched from the operation mode to the registration mode, the control terminal is set not to be included by the group control. Therefore, when the user desires that the load L to be controlled by the control terminal 1C be included by the group control, the operation switch S31 is pushed for a predetermined period. As a result, the input receiving unit 11 recognizes the entry of the group control. Subsequently, when the input receiving unit 11 receives the control command by the operation of the operation switch S31, the control unit 10 is connected to the control terminal 1 when the group control is performed for the second pattern group. The setting of the control terminal 1 is determined to be controlled, and a setting result indicating the setting is generated. Then, the control unit 10 generates a packet (decision packet) containing the setting result and the destination address (set as the operation terminal identification code of the operation terminal 2A). Thereafter, the control unit 10 transmits the packet (decision packet) from the communication unit to the signal line Ls via unicast transmission. Note that the control unit 20 of the operation terminal 2A temporarily stores the selection result from the control terminal 1C in the memory 23. In addition, when the setting result indicates that the control terminal 1C is included by the group, the control unit 10 of the control terminal 1C turns on the display 15 so that the light emitting element LD31 lights up in the first predetermined period. To control. On the other hand, when the setting result indicates that the control terminal 1C is not included by the group, the control unit 10 of the control terminal 1C is selected from the second predetermined period in which the light emitting element LD31 is shorter than the first predetermined period. The display 15 is controlled to light up in the period. As a result, the control terminal 1 informs the user of the entry of the group. However, the means for displaying the settings to be included or not included by the group is not limited to this.

In the same step, when the operation switches S11, ... of the control terminals 1A, 1B, 1D are operated, the control units 20 of the operation terminals 2A each temporarily store the setting results in the memory 23. Store in

After the selection operation as to whether or not the control terminals 1A to 1D are included by the group, the input receiving unit 11 switches the operation signal for switching the mode when the mode selection switch of the operation terminal 2A is operated by the user. (The same control command as the storage completion command) is transmitted to the control unit 20. When the control unit 20 receives the operation signal, the control unit 20 controls the "control terminal identification code of the control terminals 1A to 1D belonging to the group" when the group is controlled by bulk control. Register as an identification code of. That is, when the control unit 20 receives the operation signal, the control unit 20 controls the "control terminal identification code of the control terminals 1A to 1D belonging to the group" when the group is controlled by the bulk control. Update as the identification code of the control terminal. That is, when the control unit 20 receives the operation signal, the control unit 20 controls the "control terminal identification code of the control terminals 1A to 1D belonging to the group" when the group is controlled by the bulk control. Overwrite as an identification code of the control terminal. Then, the control unit 20 switches the registration mode to the operation mode. In addition, the control unit 20 of the operation terminal 2A generates a control command for instructing the control unit 10 of the control terminal 1 to switch the registration mode to the operation mode. Subsequently, the control unit 20 issues a control command (instructing the control unit 10 of the control terminal 1 to switch the registration mode to the operation mode), a destination address (set to a multicast address), and a source address. A packet (transmission signal) containing (set as an operation terminal identification code of the operation terminal 2A) is generated. Thereafter, the control unit 20 transmits the packet to the signal line Ls. The control unit 10 of the control terminal 1 switches the mode of the control terminal 1 from the registration mode to the operation mode. Note that the control unit 10 does not store information in the memory when the control unit 10 switches the registration mode to the operation mode regardless of whether the control terminals are grouped or not. Upon completion of the switching from the registration mode to the operation mode, the control unit 20 of the operation terminal 2A transmits a control signal to turn on or turn off the light emitting element of the display 15, whereby the light emitting element ( 15) is turned on or turned off. Similarly, upon completion of the transition from the registration mode to the operation mode, each control unit 10 of the control terminal 1 transmits a control signal to turn on or off the light emitting element of the display 24, and thus The light emitting element is thereby turned on or off.

However, when either of the operation terminal 2 (e.g., operation terminal 2A) and the control unit 10 of the control terminal 1 has a registration mode, the operation terminal 2 (2B) is operated. In addition, the operation terminal 2B (not the operation terminal 2A) does not generate a packet (command signal) for remotely controlling the control terminal. That is, when either of the operation terminal 2 (for example, operation terminal 2A) and the control unit 10 of the control terminal 1 has the registration mode, the operation terminal 2 (2B) is operated In addition, the operation terminal 2B (not the operation terminal 2A) does not generate a packet (command packet) for performing pattern control for controlling the control terminal. That is, in the above-described registration mode, the operation terminal 2 (operation terminal 2B rather than the operation terminal 2A) receives a packet (command signal) having a control command for performing pattern control to remotely control the control terminal. In the case of generating, there exists a possibility that the operation terminal 2 increases traffic by a packet. Therefore, in order to prevent an increase in traffic, the control unit 20 of the operation terminal 2 (operation terminal 2B rather than the operation terminal 2A) is blocked from generating and transmitting a packet. However, even when the operation terminal 2B generates and transmits a packet having a control command for remotely performing control of the terminal, there is no problem of increasing traffic, so that the control unit of the operation terminal and the control terminal 1 It is possible to employ the operation terminal 2 configured to generate and transmit a packet (command signal) having a control command even when any one of the 100's has a registration mode. In this case, the operation terminal 2B (not the operation terminal 1A) is configured to discard the control command in the packet when the operation terminal 1A has the registration mode.

On the contrary, even when the operation terminal 2 has the registration mode, the control terminal 1 is loaded with the load L to be controlled by the control terminal itself when the operation switches S11, ... of the control terminal 1 are operated. ) Can be controlled. This is because there is no possibility of increasing traffic even when each control terminal 1 controls the load L under direct control of the control terminal.

As described above, it is also possible to register (update, overwrite) the identification code of the control terminal 1 for the pattern group (first pattern group and second pattern group) to be controlled by the operation terminal 2B. Please note. Therefore, description of the step of registering the identification code is omitted. However, when the operation terminal 2 has a registration mode, the light amount adjustment level of each load L is also registered (updated, overwritten). Therefore, the step of registering the light amount adjustment level of each load L will be described below.

First, adjusting the light amount adjustment level of the load L is performed by operating the operation switches S32, S33, S42, S43. Subsequently, when the operation switch S62 is pushed over a predetermined period, the input receiving unit 21 recognizes a control command for registering the state of the load L in the control unit 20. The control command is defined as a save command. Then, the input receiving unit 21 transmits a storage command that registers (updates, overwrites) the state of the load L with the control unit 20. Upon receiving the storage command to register the state of the load L, the control unit 20 of the operation terminal 2B is controlled terminal 1C, 1D grouped as a second pattern group corresponding to the operation switch S62. Obtains the control terminal identification code. Subsequently, the control unit of the operation terminal 2B includes command data (indicating to return the current state (light quantity adjustment level) of the load L) and a destination address (set as each control terminal identification code). A packet (request signal) is generated, and the packet (request signal) is transmitted from the communication unit 22 to the signal line Ls via unicast transmission.

Upon receiving a packet (request signal) from the operation terminal 2B, the control unit 10 of each of the control terminals 1C and 1D receives data (the current state of the load L stored in the memory 13 (light quantity). Packet (status signal), including the destination address (set as the source address of the packet from the operation terminal 2B), and the source address (set as the control terminal identification code of the control terminal itself). Create The control unit 10 then transmits this packet (status signal) to the signal line Ls via unicast transmission.

The control unit 20 of the operation terminal 2B receives a packet (status signal) from the control terminals 1C and 1D, and subsequently the current state (light quantity control level) of the load L from the packet (status signal). Recognize. Subsequently, the control unit 20 determines the current state of the light amount adjustment level of the load L as a control command for each load L in the second pattern control. Then, the control unit 20 stores the control command of the load L in the second pattern control in the memory 23. Note that only the operation terminal 2A performs group control. Therefore, it is not necessary for the operation terminal 2A which performs group control uniquely to determine the light quantity adjustment level of each load L. FIG. Therefore, it is not necessary for the operation terminal 2A to perform the above registration.

As described above, after the state of the load L (light quantity control level of the load L) is adjusted, the input receiving unit 21 of the operation terminal 2 registers the state of the load (update, overwriting). Receive a control command (storage command). As a result, the control unit 20 registers (updates, overwrites) the relationship between the current state of the load L and each load L in the memory 23. Thus, an inexperienced user can also easily register a relationship for bulk control (pattern control). In this embodiment, the control unit 20 of the operation terminal 2 which receives the operation signal for registering the state of the load L is in the state of the load L at the control terminal 1 belonging to the pattern group to be registered. Send a packet (request signal) instructing to return. However, as described above, the control terminal 1 is " load after the load L is controlled by the control terminal 1 whenever the control terminal 1 belonging to the pattern group controls the load L " The state of L). In addition, the control unit 20 temporarily stores the state of the load L transmitted from the control terminal in the memory 23. Therefore, the control unit 20 of the operation terminal 2 can acquire the state of the load L under the control of the control terminal 1 from the memory 23. In the former case, the state of the load L connected to the control terminal 1 does not necessarily need to be stored in the memory 23. Thus, the former case has the advantage of reducing the consumption space of the memory 23. In the latter case, it is not necessary to transmit the packet (request signal) instructing to transmit the state of the load L to the control terminal 1. Thus, the latter case has the advantage of reducing the traffic between the control terminal 1 and the operation terminal 2.

By the way, the operation terminal 2B in this embodiment receives a control command (storage command) for registering the state of the load L when the operation switch S62 of the operation terminal 2B is pushed for a predetermined period. And an input receiving unit 21 configured to. That is, the control unit 20 of the operation terminal 2B is configured to recognize the first operation input and the second operation input. The control unit 20 of the operation terminal 2B is configured to recognize the first operation input when the operation switch S61 (or S62) is pushed for the first predetermined period. The control unit 20 of the operation terminal 2B is configured to recognize the second operation input when the operation switch S61 (or S62) is pushed for the second predetermined period. The second predetermined period is longer than the first predetermined period. When the control unit 20 receives the first operation input, the control unit 20 performs bulk control (pattern control). On the contrary, when the control unit 20 receives the second operation input, the control unit 20 performs a process of registering the state of the load L. FIG. In this way, the operation terminal 2 has an operation switch S62 which acts as a switch for generating a first operation input or for generating a second operation input. In addition, the operation terminal 2 cannot simultaneously perform the process for registering the pattern control and the state of the load. Therefore, such a configuration makes it possible to improve the convenience of the operation terminal.

(2nd Example)

9 shows a diagram of the system in this embodiment. In the load control system in this embodiment, the operation terminal 2 is almost the same as the operation terminal 2 in the first embodiment. Moreover, the operation terminal 2 is connected to the load L, and is comprised so that the load L may be controlled directly. That is, the load control system in this embodiment includes a control terminal 1A and control terminals 1B to 1D different from this control terminal 1A. In order to broaden the understanding of the present invention, hereinafter, the control terminal 1A is referred to as the first control terminal 1A, and the control terminals 1B to 1D are referred to as the second terminals 1B to 1D. The first terminal 1A is configured to remotely control the second terminals 1B to 1D. The second terminals 1B to 1D do not have the function of remotely controlling other control terminals. Therefore, the first control terminal 1A differs from the second terminals 1B to 1D in that it has a function of remotely controlling other control terminals. The load control system in the present invention basically has the same components as the components of the load control system in the first embodiment. Therefore, the same reference numerals as those in the first embodiment are assigned to the components of the same load control system as in the first embodiment.

Each second terminal 1B to 1D has a component common to that of the respective control terminal 1B to 1D. In addition, the operation terminal 2 corresponds to the 1st control terminal 1A in a present Example. The first control terminal 1A has basic components common to those of the respective second terminals 1B to 1D. Therefore, detailed description and illustration of the first control terminal 1A are omitted.

At the first control terminal 1A, the operation switch S51 corresponds to the group control described in the first embodiment. The operation switches S52 and S53 correspond to the first pattern control and the second pattern control, respectively. The memory 13 has a relationship between the operation switches S51 to S53 and the control terminal identification codes of the respective control terminals 1B to 1D, and the control of the operation switches S51 to S53 and the respective control terminals 1B to 1D. Stores the relationship between the information (light control level). That is, the memory 13 is connected between the operation switches S51 to S53 and the control terminal identification codes of the respective control terminals 1B to 1D in relation to the control information (light quantity control level) of the respective control terminals 1B to 1D. Save the relationship.

Next, an operation of the first control terminal 1A for performing group control will be described. When the operation switch S51 of the first control terminal 1A operates, the input receiving unit 11 transmits an operation signal to the control unit 10. Upon receiving this operation signal, the control unit 10 accesses the memory to " the most recent state of the load L connected to the second control terminals 1B to 1D " and " the second control terminals 1B to 1D. &Quot; Control terminal identification code ", both of which correspond to an operation signal sent when the operation switch S51 operates. The control unit 10 recognizes the current state of the load L from this obtained data. If the control unit 10 recognizes that all the loads L are in the same state, the control unit 10 generates a control command for switching the state of the load L to the inverted state (control unit 10 If it is recognized that all the loads L are on, the control unit 10 generates a control command for turning off the loads L, on the contrary, the control unit 10 causes all the loads L to light up. If it is recognized that it is not doing, the control unit 10 generates a control command for turning on the light). If the control unit 10 recognizes that one of the loads L is in a different state from the other load L, the control unit 10 generates a control command for switching all the loads L to the same state. (If the control unit 10 recognizes that one load L is in the lit state but the other load L is not in the lit state, the control unit 10 causes the light of all the loads L to be turned on or off. To generate a control command). In addition, the control unit 10 includes a packet having data (set as a control command), a destination address (set as a multicast address), and a source address (set as a terminal terminal identification code of the control terminal 1A) ( Command signal) and transmits this packet (command signal) from the communication unit 12 to the signal line Ls.

At the second control terminals 1B to 1D, when each communication unit 12 receives a packet (command signal), the communication unit 12 transmits this packet (command signal) to the control unit 10. The control unit 10 determines whether the destination address of the packet (command signal) is the same as the second control terminal identification code of the second control terminal itself. If the control unit recognizes that the control command of the packet (command signal) includes the same destination address as the second control terminal identification code of the second control terminal itself, the control unit 10 corresponds to this second control terminal identification code. Based on the control information to generate a control signal for turning on or off the load (L) under the control of each second control terminal. The control unit 10 transmits this control signal to the load operation unit 14. Upon receiving the control signal, the load manipulation unit 14 opens and closes the relay in accordance with this control signal, whereby the load manipulation unit 14 turns the load L on or off. In addition, the control unit 10 generates a packet (status signal) after a predetermined time has elapsed. The packet (status signal) indicates data (indicative of the state of the load L after the load L is controlled), the destination address (same as the identification code of the source address of the packet received by the second control terminal), and the source Address (set as the control terminal identification code of the second control terminal itself). The control unit 10 then transmits this packet (status signal) from the communication unit 12 to the signal line Ls. The control unit 10 also controls the display 15 such that the display 15 displays the state of the load L after the load L is controlled by the second control terminal.

On the other hand, at the first control terminal 1A, the communication unit 12 receives a packet (status signal) and transmits this packet (status signal) to the control unit 10. The control unit 10 recognizes the current state of the load L from this packet (status signal). The control unit 10 stores the state of the load L in the packet (status signal) in the memory. Then, when all the second control terminals grouped in the group corresponding to the operation switch S51 receive this packet (status signal), the control unit 10 controls the display to change the display of the display 15. (For example, when all the loads L are turned on, the light emitting element LD51 is turned off. On the contrary, when all the loads L are turned off, the light emitting element LD51 is turned on.) , 1st control terminal 1A cannot receive the packet (status signal) which informs the state of a load from 2nd control terminal 1D. If the first control terminal 1A cannot receive a packet (status signal) from the second control terminal 1D, the control unit 10 of the first control terminal 1A does not transmit the destination address (the packet which does not transmit the packet). 2 is set as the second terminal identification code of the control terminal 1D), the source address (is set as the control terminal identification code of the first control terminal 1A), and the control command (the state of the load L). Generate a packet (retry signal) including an instructed packet to be sent. Then, the first control terminal 1A transmits this packet (retry signal) to the signal line Ls. When a packet (status signal) is returned from the second control terminal 1D, the control unit 10 of the first control terminal 1A stores the state of the load in the packet (status signal) in the memory 13. In contrast, if a packet (status signal) is not returned from the second control terminal 1D, the control unit 10 controls the display 15 to flash the light emitting element LD51, whereby the display 15 is user Notify errors.

Next, operation | movement of pattern control (2nd pattern control) is demonstrated using the procedure of FIG. When the operation switch S53 of the first control terminal 1A operates, the input receiving unit 11 receives a control command. Upon receiving this control command, the input receiving unit 11 transmits an operation signal to the control unit 10. When the control unit 10 receives the operation signal, the control unit 10 accesses the memory, by " control terminal identification codes of the control terminals 1C and 1D " and " control terminals 1C and 1D, respectively. &Quot; Control command " to the controlled load L ", both of which relate to an operation signal when the operation switch S53 operates. Then, the control unit 10 generates a control command based on the control command (second pattern control) from the memory 13. The control command includes an indication that the control terminal 1C turns on the load L controlled by the control terminal 1C to a 70% light amount adjustment level. The control command also includes an indication that the control terminal 1D turns on the load L controlled by the control terminal 1D to the 30% light amount adjustment level. Then, the control unit 10 sets the data (set as a control command), the destination address (set as a multicast address), and the source address (set as the control terminal identification code of the control terminal 1A). Generates an included packet (command signal). The control unit 10 then transmits this packet (command signal) from the communication unit 12 to the signal line Ls. Note that the control signal does not include the control terminal identification code of the second control terminal 1B and the control information for controlling the second control terminal 1B.

At the second control terminals 1B to 1D, when the communication unit 12 receives a packet (command signal), the communication unit 12 transmits this packet (command signal) to the control unit 10. In the second control terminal 1B, the control unit 10 of the second control terminal 1B indicates that the packet (command signal) does not have the same identification code as the control terminal identification code of the second control terminal 1B. Recognize. Therefore, the second control terminal 1B does not control the load L under the control of the second terminal 1B, whereby the load L under the control of the control terminal 1B maintains its current state. Further, the second control terminal 1B generates a packet (status signal) having data indicating the current state of the load L under the control of the control terminal 1B. In contrast, in each control unit 10 of the second control terminals 1C and 1D, the control unit 10 receives the same identification code as that of the control terminal identification codes of the second control terminals 1C and 1D. Signal). Since the control signal includes a control signal for turning on the load L at a predetermined light amount adjustment level, each control unit 10 of the second control terminals 1C and 1D corresponds to the control level of this control signal. The control signal for turning on to the predetermined light quantity adjustment level is transmitted to each load operation unit 14 of the control terminals 1C and 1D. When the load operation unit 14 receives the control signal, the load operation unit 14 drives the control circuit in accordance with this control signal to adjust the amount of power supplied to the load L per unit time. In addition, the control unit 10 of each of the control terminals 1C and 1D generates a packet (status signal) after a predetermined time has elapsed. This packet (status signal) is set as an identification code of the first control terminal 1A of the source address in the packet (command signal), and the source address (control of the respective control terminals 1C and 1D). Set as a terminal identification code), and data (set as a state of the load L after the control terminal controls the load L). Then, the control unit 10 of each control terminal 1C and 1D transmits a packet (status signal) from the communication unit 12 to the signal line Ls. The control unit 10 also controls the display 15 of the control terminal itself to change the display of the display 15.

At the first control terminal 1A, when the communication unit 12 receives a packet (status signal), the communication unit 12 transmits this packet (status signal) to the communication unit 12. Upon receiving this packet (status signal), the control unit 10 stores the state of the load L in this packet in the memory 13. In addition, when the control unit 10 receives a packet (status signal) informing the state of the load from all the control terminals 1C and 1D belonging to the second pattern group corresponding to the operation switch S53, the control unit 10 ) Manipulates the display 15 to turn on the light emitting element LD53. As a result, the display 15 indicates that the second pattern control is performed. Note that the operation of the first pattern control is basically common to the second control pattern. Therefore, description of the operation of the first pattern control is omitted.

In this embodiment, as in the first embodiment, when the mode selection switch (not shown) of the first control terminal 1A is configured to perform remote control (bulk control), the control terminal 1A The control unit 10 switches from the operation mode to the registration mode. The control unit 10 also transmits a packet (registration signal) having a control command instructing the user to switch from the operation mode to the registration mode from the communication unit 12 to the signal line Ls by multicast transmission. Then, when the control unit 10 of each of the second control terminals 1B to 1D receives this packet (registration signal), each control unit 10 switches from the operation mode to the registration mode. In the registration mode, the steps of registering the identification codes of the second control terminals 1B to 1D to the group controlled by the first control terminal 1A are common to the steps in the first embodiment. Therefore, the description of the step of registering the identification codes of the second control terminals 1B to 1D to the group controlled by the first control terminal 1A is omitted. Here, there is a possibility that the load control system has a plurality of first control terminals 1A configured to perform remote control (bulk control). In this case, when one control unit 10 of the first control terminal 1A switches from the operation mode to the registration mode according to the operation of one mode selection switch, the other control unit 10 moves from the operation mode to the registration mode. It is switched to determine this one control unit 1 as the center of the registration mode. Therefore, the first control terminals 1 which are not the center of the registration mode are selected as to whether the control terminals are grouped by the operation of the operation switch.

In this case, first, the light quantity adjustment level of the load L is adjusted by operation of the operation switches S32, S33, S42, S43 of the control terminals 1C, 1D in the operation mode. Subsequently, when the operation switch S53 of the control terminal 1A is pressed for a predetermined period, the input receiving unit 11 receives a control command and then sends an operation signal to the control unit 10 for registering the state of the load. Send. Upon receiving this control signal, the control unit 10 of the first control terminal 1A receives the " current state of the load L " and " control terminal identification codes of the control terminals 1C and 1D belonging to the second pattern group. ", Both of which correspond to the operation switch S53. The control unit 10 then determines the current state of the load L as the control information for each load L in the second pattern control, and stores this control information in the memory 23. However, as described in the first embodiment, it is also possible to obtain the current state of the load by transmitting a packet (command signal) having a command informing the state of the load.

Claims (5)

A load control system for controlling one or more loads,
At least one control terminal and at least one operating terminal;
The control terminal is connected to the at least one load,
The operation terminal is connected to the at least one control terminal via a signal line,
Each said control terminal individually has a control terminal identification code,
Each said operation terminal has an operation terminal identification code individually,
The control terminal comprises a first input receiving means, a first control means, and a first communication means,
The first input receiving means has at least one first operating switch for inputting a first control command,
The first control means is configured to control a predetermined load in response to the first control command when the first input receiving means receives the first control command, wherein the predetermined load is applied to the first control command. Correspondingly, controlled by the first control means,
The operation terminal has a second input receiving means, a memory, a second control means, and a second communication means,
The second input receiving means has one or more second operation switches for inputting a second control command,
The memory stores a relationship between the second control command and one or more control terminal identification codes in relation to control information, wherein the control information indicates a predetermined state and wherein one or more loads to be controlled by the control terminal are predetermined. State,
The second communication means is in communication with the first communication means,
The second control means is configured to recognize the second control command received by the second input receiving means and to obtain a control terminal identification code and control information associated with the second control command from the memory, The second control means also generates a control command for controlling the load to be in a predetermined state based on the obtained control information, and sends a command signal including a control command and an obtained control terminal identification code to the second communication means. And transmit to the control terminal via a signal line from
The control terminal receives the command signal transmitted from the second communication means via the signal line via the first communication means, and the control terminal identification code of the command signal is the control terminal of the control terminal itself. When the same as the identification code is configured to control a predetermined load to a predetermined state according to the control command,
The first control means is configured to transmit a status signal to the operation terminal at a predetermined timing, the status signal representing a current state of a predetermined load controlled by the control terminal,
The second control means recognizes a current state of a predetermined load and determines the current state as a predetermined state of the load, and when the second input receiving means receives a storage command by the second input receiving means. Store the relationship between the current state and the control terminal identification code in the memory;
Load control system. The method of claim 1,
The first control means is configured to transmit a status signal indicating a current state of a predetermined load when the first control means controls the load,
The second control means is configured to store the state of the load included in the state signal when the second control means receives the state signal,
The second control means is configured to obtain a state of the load controlled by the control terminal from the memory when the second input receiving means receives a storage command, wherein the second control means is adapted from the load and the memory; Generate and store in the memory a relationship between the obtained states of the load,
Load control system. The method of claim 1,
The second control means is configured to cause the second communication means to transmit a request signal to the first communication means when the second input receiving means receives the storage command,
The first control means is arranged to cause the first communication means to send the status signal to the second communication means when the first communication means receives the request signal, the status signal being a current state of the load Indicates
The second control means is configured to recognize a current state of the load from the state signal, to generate a relationship between the load and the state of the load, and the second control means is configured to store the relationship in a memory felled,
Load control system. The method of claim 1,
The second control means is configured to detect a first operation input when the second operation switch is operated over a first period of time,
The second control means is configured to detect a second operation input when the second operation switch is operated over a second period longer than the first period,
The second control means is configured to obtain a control terminal identification code corresponding to the first operation input from the memory, and is configured to generate a control command for controlling the load, the second control means being the control command And generate a command signal having a control terminal identification code obtained from the memory, and transmit the command signal to the control terminal via a signal line.
The second control means is configured to recognize a state of a load controlled by the control terminal when the control terminal receives the second operation input, and is configured to generate a relationship between the load and the state of the load, The second control means is configured to store the relationship in the memory,
Load control system. The method of claim 1,
The operation terminal is connected to one or more of the loads controlled by the operation terminal,
The second control means is configured to control the load controlled by the operation terminal when the second input receiving means receives the second control command,
Load control system.

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