JP2012009265A - Lighting control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting control system capable of improving system responsiveness.SOLUTION: In a lighting control system 1 of an embodiment, a central control unit 2 controls a plurality of control terminals S by communicating with a plurality of control terminals S via a transmission line 3. The central control unit 2 transmits a transmission frame 30 to the plurality of control terminals S via the transmission line 3. The transmission frame 30 includes a control transmission part 31 having at least an addresses of the control terminal S and a control data part 30e including control data, and a monitor response part 33 for a monitor response following the control transmission part 31. Among the plurality of control terminals S, the control terminal S corresponding to an address in the transmission frame 30 adds a response signal indicating a control state of a lighting apparatus to the monitor response part 33 in the transmission frame 30 and then transmits the response signal to the central processing unit 2.

Description

  Embodiments of the present invention relate to a lighting control system that remotely controls, for example, a plurality of lighting fixtures arranged on a ceiling surface in a building.

  2. Description of the Related Art Conventionally, for example, in office buildings and various facilities, an illumination control system that remotely controls an illumination load such as a luminaire installed in each illumination area such as each floor or each area has been adopted.

  In this lighting control system, a plurality of lighting devices are communicably connected via a transmission line to a central processing unit that is a lighting control device, and each lighting device is controlled by a signal from the central processing unit. . Further, the central processing unit and the plurality of lighting devices communicate with each other via a transmission line, so that the central processing unit can manage the lighting devices in an integrated manner.

  When communicating with a plurality of lighting devices, a central processing unit in a conventional lighting control system transmits a signal in a predetermined transmission frame every predetermined time.

  This transmission frame includes, for example, mode data indicating the type of signal, address data, checksum data for checking whether or not the transmission data is correctly transmitted, control data of the lighting fixture, an ACK response signal, and the like. It has a format configuration.

  The mode includes a control mode for controlling the lighting fixture and a monitoring mode for monitoring whether the lighting fixture is operating normally.

JP 2009-158280 A

  However, the conventional lighting control system transmits necessary data in the transmission frame of the same format in both the control mode and the monitoring mode. That is, in the control mode, the transmission frame is transmitted in the absence of the ACK response signal in addition to the necessary control data, and in the monitoring mode, the transmission is performed with only the necessary ACK response signal. A frame is transmitted.

  Therefore, the conventional lighting control system must transmit two transmission frames in this way, and each time a ACK response signal is returned to the transmission side with a transmission frame of the same format. As the scale of the system increases, the system response becomes slower.

  Therefore, the present embodiment has been made in view of the above problems, and an object thereof is to provide an illumination control system that can improve the responsiveness of the system.

  The lighting control system according to the embodiment includes a plurality of terminals that are connected to a transmission line and control the lighting fixture based on control data transmitted through the transmission line, and a central control device. The central control device controls the plurality of terminals by communicating with the plurality of terminals through the transmission line, and includes a control data unit having at least an address of the terminal and the control data. A transmission frame including a control transmission unit including the control transmission unit and a monitoring response unit for monitoring response following the control transmission unit is transmitted to the plurality of terminals via the transmission line. The terminal corresponding to the address of the transmission frame among the plurality of terminals adds a response signal indicating the control state of the lighting fixture to the monitoring response unit in the transmission frame and transmits the response signal to the central processing unit. To do.

  According to the illumination system according to the embodiment, the responsiveness of the system can be improved.

The block diagram which shows the whole structure of the illumination control system which concerns on embodiment. The block diagram which shows the specific circuit structure of the central control apparatus of FIG. 1, and a control terminal. The figure which shows the structure of the transmission frame transmitted from a central control apparatus. The figure which shows the structure of the monitoring frame transmitted from a central control unit. The flowchart which shows the example of control in CPU of the central control apparatus of FIG. The flowchart which shows the example of control in CPU of the control terminal of FIG.

  The lighting control system of the embodiment is connected to a transmission line, and controls a lighting fixture based on control data transmitted via the transmission line, the plurality of terminals, and the transmission line via the transmission line. A control transmission unit that controls the plurality of terminals by performing communication, and includes a control data unit including at least the address of the terminal and the control data, and monitoring for monitoring response following the control transmission unit And a central control unit that transmits a transmission frame having a response unit to the plurality of terminals via the transmission line, and a terminal corresponding to the address of the transmission frame among the plurality of terminals. Is characterized by adding a response signal indicating the control state of the luminaire to the monitoring response unit in the transmission frame and transmitting it to the central processing unit. .

  In the embodiments of the present invention and the following claims, the definitions and technical meanings of terms are as follows unless otherwise specified.

  The lighting fixture is, for example, a lighting fixture using an LED as a light source, but is not limited thereto. However, considering the response speed of the light source, if the light source is an illuminator that uses an LED as a light source rather than a normal lamp, the dimming control can be performed quickly even when many luminaires are installed. It is.

  The terminal device is, for example, a control terminal device that controls a plurality of lighting fixtures, but is not limited thereto, and includes a sensor terminal device and the like. The control terminal is configured to be able to connect, for example, a four-circuit lighting fixture, but is not limited thereto, and may be configured to be capable of connecting an eight-circuit lighting fixture, for example.

  The transmission frame includes a control transmission unit including at least a terminal data and a control data unit having the control data, and a monitoring response unit for monitoring response following the control transmission unit. The transmission frame is a frame formatted to transmit the control transmission unit and the monitoring response unit every predetermined period (for example, 20 msec), but is not limited thereto.

  The control transmission unit is configured by, for example, arranging start data, 4-bit mode data, 12-bit address data, 4-bit select data, 8-bit control data, 4-bit select data in order. It is not limited. Further, the monitoring response unit has at least a predetermined period and has monitoring response data that is an 8-bit response signal, but is not limited thereto.

  In addition, the terminal is configured by a wired transmission type controller that transmits control data and the like by wire, but may be configured by a wireless transmission type controller that transmits a control signal wirelessly, for example.

  A lighting control system according to a second aspect of the present invention is the lighting control system according to the first aspect, wherein a predetermined period is set between the control transmission unit and the monitoring response unit of the transmission frame. It is characterized by being.

  The predetermined period provided in the transmission frame is, for example, an operation period in which the relay operates when a relay for sequentially turning on / off the lighting fixture is provided in the terminal. In the case where the terminal device has no relay, the predetermined period may not be provided.

  With this configuration, even when a large number of lighting fixtures are installed, the response signal can be immediately transmitted to the central processing unit after the operation period of the relay has elapsed, so that the responsiveness of the system can be improved.

  The lighting control system according to a third aspect of the present invention is the lighting control system according to the first or second aspect, wherein the terminal is configured such that a control output based on the control data for the lighting fixture is uncertain. The data indicating indefiniteness is added to the monitoring response unit and transmitted.

  Indeterminate is a state where the control output based on the control data for the luminaire is not completely completed, that is, a state where the luminaire is not normally dimmed based on the control data.

  By adding data indicating a state in which such a lighting fixture is not normally dimmed based on the control data to the monitoring response unit and transmitting it to the central control device, the central control device It can be recognized that the dimming state is not normal.

  A lighting control system according to a fourth aspect of the present invention is the lighting control system according to the third aspect, wherein the central processing unit is not confirmed in the monitoring response unit of the transmission frame transmitted from the terminal. When the data indicating is transmitted, an unused monitoring frame similar to the transmission frame is generated, and a response signal is added again to the monitoring response unit of the monitoring frame and transmitted to the corresponding terminal. It is characterized by.

  An unused monitoring frame, similar to a transmission frame, is used for transmitting control signals to the corresponding terminals again by adding a response signal only to the monitoring response unit and no data such as control data in the control transmission unit. It is a transmission frame.

  With this configuration, the state of the luminaire connected to the corresponding terminal device can be monitored again by the central control device.

(Embodiment)
FIG. 1 is a configuration diagram showing the overall configuration of the illumination control system according to the present embodiment.
A lighting control system 1 illustrated in FIG. 1 includes a central processing unit 2 that remotely controls lighting fixtures installed in each lighting area such as each floor or each area such as an office building or various facilities.

  The central processing unit 2 includes a wall switch 4 through a two-wire transmission line (hereinafter referred to as a transmission line) 3, a plurality of control terminals S1, S2, S3,. The terminal device 5, the wireless receivers 6 and 7, and the human sensor 8 are connected. Further, a wireless transmitter 9 that transmits signals to the wireless receiver 6 by infrared rays and a wireless transmitter / receiver 10 that transmits and receives signals to and from the wireless receiver 7 by infrared rays are provided.

The wall switch 4, the plurality of control terminals S, the sensor terminals 5, the wireless receivers 6 and 7, the human sensor 8, the wireless transmitter 9, and the wireless transmitter / receiver 10 are illumination devices connected to the transmission line 3. The plurality of lighting devices are controlled by the central processing unit 2 via the transmission line 3. That is, the central processing unit 2 comprehensively controls this system.
And the said control terminal S is connected to the central processing unit 2 via the transmission line 3, and can control a corresponding lighting fixture.

  The lighting fixture connected to the control terminal S connected to the transmission line 3 includes a lighting fixture that is turned on / off by a relay circuit (hereinafter referred to as a relay).

 The wall switch 4 has an on / off switch corresponding to each lighting fixture or a group which is a set of a plurality of lighting fixtures, and includes a corresponding lighting fixture or a plurality of lighting fixtures based on a user's switch operation. An on / off control signal for turning the group on or off is output to the central processing unit 2.

  The plurality of control terminals S 1, S 2, S 3,... Sn can be connected to, for example, four-circuit lighting fixtures, and such a plurality of control terminals S 1, S 2, S 3,. Has been. In addition, as a lighting fixture, the lighting fixture using light sources, such as a lamp | ramp and a light emitting diode (LED), is used, for example.

  Further, in the configuration in which the relay is provided, the relay performs lighting and extinguishing control with respect to a plurality of connected lighting fixtures, and the corresponding lighting by receiving the lighting control signal from the central processing unit 2. The appliance is turned on and off.

  The sensor terminal device 5 is, for example, a terminal device for dimming control of a lighting fixture in order to constantly control the illuminance on the desk surface. The sensor terminal 5 is connected to the transmission line 3 via a transmission interface. The sensor terminal 5 includes a sensor unit that detects light, a display unit, and a memory that stores address data of the sensor terminal 5.

  The wireless transmitter 9 transmits information on lighting / extinguishing of the luminaire to the wireless receiver 6 by infrared rays, for example. The wireless transmitter 9 includes a transmission interface that can be connected to the transmission line 3, an infrared transmitter that transmits illumination control information by infrared rays, a memory that stores address data of the wireless transmitter 9, and the like. It is configured.

  The wireless transmitter / receiver 10 is a terminal device for transmitting / receiving information on lighting / extinguishing of lighting equipment to / from the wireless receiver 7 by infrared rays. This wireless transmitter / receiver 10 includes an infrared transmitter that transmits infrared rays, an infrared receiver that receives infrared rays, an operation button for controlling lighting equipment to be turned on / off, and a memory that stores address data of the wireless transmitter 10. It is configured.

  The human sensor 8 is a terminal device for detecting the presence of a person and controlling lighting of the lighting apparatus. The human sensor 8 is connected to the transmission line 3 via a transmission interface. Further, the human sensor 8 includes an infrared detecting unit that detects an infrared ray radiated from a person, and a memory that stores address data of the human sensor 8.

  The wireless receiver 6 receives an infrared signal transmitted from the wireless transmitter 9. The wireless receiver 6 is connected to the transmission line 3 via a transmission interface. In addition, the wireless receiver 6 is provided with an address setting unit for storing address data of the wireless receiver 6 and an infrared receiving unit for receiving infrared rays. The wireless receiver 6 has an infrared transmission unit for enabling infrared transmission.

  The wireless receiver 7 receives an infrared signal transmitted from the wireless transmitter 10. This wireless receiver 7 is connected to the transmission line 3 via a transmission interface. In addition, the wireless receiver 7 is provided with an address setting unit for storing address data of the wireless receiver 7 and an infrared receiving unit for receiving infrared rays. The wireless receiver 7 has an infrared transmission unit for enabling infrared transmission.

  In such an illumination control system 1, the central processing unit 2 and the plurality of lighting devices communicate with each other via the transmission line 3, so that the central processing unit 2 manages the lighting fixtures in an integrated manner, The lighting fixtures connected to the control terminals S1, S2, S3,... Sn can be turned on and off, and the light control can be performed.

  Next, a specific circuit configuration of the central processing unit 2 and the control terminal S of the lighting control system 1 of the present embodiment will be described with reference to FIG. FIG. 2 is a block diagram showing a specific circuit configuration of the central controller and the control terminal of FIG.

  As shown in FIG. 2, the central processing unit 2 according to the present embodiment is connected to an internal bus 11 via a connection unit 2a. The central processing unit 2 includes an interface unit (hereinafter abbreviated as I / F) 12, a ROM 13, a RAM 14, a CPU 15, and an operation unit 16 connected to the connection unit 2 a, and each is connected via the bus 11. Configured.

The connection part 2a is a connection cable connector to which the transmission line 3 shown in FIG. 1 is connected, for example. The signal supplied via the connection unit 2a is supplied to the I / F 12. The I / F 12 outputs the supplied signal to the CPU 15 via the bus 11.
In addition, the I / F 12 outputs a control signal from the CPU 15 to lighting devices such as a plurality of control terminals S1, S2, S3,... Sn via the connection unit 2a and the transmission line 3.

  The ROM 13 communicates with a lighting device such as the control terminal S or a program necessary for the CPU 15 as a control means to perform dimming control of the lighting fixture based on the operation of the control terminal S and the wall switch 4. It stores programs and the like necessary for outputting control signals to the lighting fixtures and monitoring the operating state. The CPU 15 executes a predetermined program stored in the ROM 13 to perform dimming control of the entire illumination control system 1 or, as will be described later, an illumination device such as a control terminal S in a predetermined transmission frame. To control the lighting and control the lighting fixture.

  The RAM 14 is used for temporarily storing programs executed by the CPU 15, generated transmission frames, correspondence information (allocation) information between the wall switch 4 and the lighting fixture connected to the control terminal S, and the like. Configure the storage area.

  The operation unit 16 sets addresses of the wall switch 4, the control terminal S, the sensor terminal 5, etc., sets data stored in the RAM 14, or turns on / off the lighting fixtures via the control terminal S, dimming It is an operation means for inputting an operation instruction for performing control or the like.

Next, a specific circuit configuration of the control terminal S that is an illumination device will be described.
As shown in FIG. 2, the control terminal S of this embodiment includes two I / Fs 22 and 26, a ROM 23, a RAM 24, and a CPU 25 that are connected to each other via a bus 21. . The I / F 22 is connected to the transmission line 3 via the connection part Sa. Each illumination load is connected to the I / F 26 via the connection unit 27.

The connection part Sa is, for example, a connection cable connector to which the transmission line 3 shown in FIG. 2 is connected. The signal supplied via the connection portion Sa is supplied to the I / F 22. The I / F 22 outputs the supplied signal to the CPU 25 via the bus 21.
The 1 / F 22 outputs a control signal from the CPU 25 to the central processing unit 2 via the connection portion Sa and the transmission line 3.

  The ROM 23 is used to output a monitoring response signal by performing communication with the central processing unit 2 and a program necessary for dimming control of the lighting fixture based on the control signal transmitted by the CPU 25 as the control means. Stores necessary programs. The CPU 25 executes a predetermined program stored in the ROM 10 to perform dimming control of the connected lighting fixture, or transmits a monitoring response signal indicating an operating state of the connected lighting fixture, which will be described later, to a predetermined transmission. The frame is transmitted to the central processing unit 2 or controlled.

  The RAM 24 constitutes a working storage area for temporarily storing a program executed by the CPU 25, information on a monitoring response signal added to the transmission frame, and the like.

  The I / F 26 outputs the control data from the CPU 25 to the luminaire connected via the connection unit 27. For example, the connection unit 27 can connect a transmission line connected to a four-circuit lighting fixture. In addition, in the configuration in which the relay is provided, the relay connected to each lighting fixture can be connected. is there.

  In the illumination control system 1 of the present embodiment, the CPU 15 of the central processing unit 2 controls the plurality of control terminals S by communicating with the plurality of control terminals S via the transmission line 3. A transmission frame having a control transmission unit including at least a control data unit having an address and control data of the control terminal S and a monitoring response unit for monitoring response following the control transmission unit is transmitted via a transmission line 3. Transmit to the control terminal S.

  Then, the CPU 25 of the control terminal S designated by the address among the plurality of control terminals S1, S2, S3,... Sn sends a response signal indicating the control state of the luminaire in the monitoring response unit of the transmission frame. In addition, control is performed so as to transmit to the central processing unit 2.

The configuration of such a transmission frame is shown in FIG. FIG. 3 is a diagram showing a configuration of a transmission frame transmitted from the central control apparatus.

  A transmission frame 30 shown in FIG. 3 is transmitted from the central processing unit 2 toward the control terminal S. Specifically, the transmission frame 30 includes a control transmission unit 31 including a control data unit having an address of the control terminal S and control data, and a monitoring response unit 33 for monitoring response following the control transmission unit 31. It is configured.

  The transmission frame 30 is formatted to transmit data from the control transmission unit 31 to the monitoring response unit 33 in a predetermined period t0 (for example, 20 msec).

  Note that a predetermined period unit 32 of a preset period t2 in which no data is added is provided between the control transmission unit 31 and the monitoring response unit 33 as necessary. The predetermined period unit 32 is an operation period in which the relay operates when, for example, the control terminal S is provided with a relay that sequentially turns on and off the lighting fixtures. In addition, when it is the structure by which the relay is not included in all the control terminals S, the predetermined period part 32 does not need to be provided.

  The control transmission unit 31 is configured by, for example, sequentially formatting start data 30a, 4-bit mode data 30b, 12-bit address data 30c, 4-bit select data 30d, 8-bit control data 30e, and 4-bit checksum data 30f. Is done. In addition, the monitoring response unit 33 has monitoring response data (also referred to as ACK) 30g which is an 8-bit response signal.

  The mode data 30b indicates the type of signal, for example, mode data indicating a control mode or a monitoring mode.

  The address data 30c is, for example, address data allocated to the control terminal S to be controlled among the plurality of control terminals S1, S2, S3,.

  The select data 30d is select data for selecting a lighting fixture to be controlled among the lighting fixtures of the corresponding control terminal S.

  The control data 30e is control data transmitted to the control terminal S corresponding to the address in the control mode, and is control data for controlling the lighting fixture connected to the control terminal S.

  The checksum data 30f is data for checking whether the transmission data has been sent correctly.

  The monitoring response data (ACK) 30g is monitoring response data indicating the operating state of each lighting fixture, which is transmitted from the corresponding control terminal S to the central processing unit.

  In the configuration shown in FIG. 3, the transmission period of the entire transmission frame 30 is a predetermined period t0. The predetermined period t0 includes a period t1 for transmitting the control transmitter 31, a predetermined period t2, and a monitoring response. This is a period combined with the period t3 during which the unit 33 is transmitted.

FIG. 4 shows a configuration of a monitoring transmission frame transmitted from the central processing unit to a plurality of control terminals.
Although the monitoring transmission frame 30A shown in FIG. 4 will be described later, when data indicating indeterminacy is received in the monitoring response unit 33 transmitted from the control terminal S to be controlled, the corresponding control terminal is again provided. A transmission frame for transmission to S.

  The monitoring transmission frame 30A is configured in the same manner as the transmission frame 30 shown in FIG. 3, but the control transmission unit 31A includes start data 30a, mode data 30b, address data 30c, select data 30d, and control data. Each of the data 30e is in an unused state. A monitoring response signal 30g to be transmitted again to the corresponding control terminal is added to the monitoring response unit 33A.

  The lighting control system 1 according to the present embodiment uses the transmission frame shown in FIG. 3 or FIG. 4 between the central processing unit 2 and the plurality of control terminals S to control data or control data associated with execution of the monitoring mode. The monitoring response signal is sent and received.

  Next, the operation of the lighting control system according to the present embodiment will be described with reference to FIGS. FIG. 5 is a flowchart showing an example of control in the CPU of the central controller in FIG. 2, and FIG. 6 is a flowchart showing an example of control in the CPU of the control terminal in FIG.

First, a control example of the CPU 15 of the central processing unit 2 will be described with reference to FIG.
It is assumed that the illumination control system 1 of the present embodiment is turned on. Then, the CPU 15 of the central processing unit 2 reads the program shown in FIG.
In step S1, the CPU 15 turns on the timer, and in the subsequent step S2, starts transmission so that various data are sequentially transmitted using the transmission frame 30 shown in FIG.

  Thereafter, the CPU 15 determines whether or not it is the response timing of the monitoring response signal (ACK) of the monitoring response unit 33 shown in FIG. If it is not the response timing of the monitoring response signal (ACK), the determination process of step S3 is performed until the response timing is reached, and if it is the response timing of the monitoring response signal (ACK), the process is performed in step S4. Migrate to

  In the process of step S4, the CPU 15 acquires the monitoring response signal (ACK) of the monitoring response unit 33, and the process proceeds to the determination process of step S5.

  In the determination process of step S5, the CPU 15 determines the operating state of the corresponding lighting fixture based on the acquired monitoring response signal. That is, the CPU 15 determines whether or not the corresponding lighting fixture has normally operated based on the control data from the monitoring response signal, that is, whether or not the control has been executed based on the control data. When it is determined that the execution result is indeterminate, the monitoring data frame 31A shown in FIG. 4 is generated in the process of step S7 in order to monitor the luminaire connected to the corresponding control terminal S again. Then, the process returns to step S1, and the generated monitoring data frame 31A is transmitted in the process of step S2.

  On the other hand, when it is determined that it is not determined, that is, when control is executed, the CPU 15 determines whether or not the corresponding control terminal S and the luminaire connected thereto are abnormal in the subsequent determination process of step S6. If it is determined that there is no abnormality, this program is completed, and if it is determined that there is an abnormality, in the process of step S8, for example, a control terminal having an abnormality is displayed on a display unit (not shown). This program is completed by performing an abnormal process such as displaying the device S and the luminaire connected thereto, or notifying by voice.

Next, a control example of the CPU 25 of the control terminal S will be described with reference to FIG.
It is assumed that the illumination control system 1 of the present embodiment is turned on. Then, the CPU 25 of the control terminal S reads out the program shown in FIG.
The CPU 25 determines whether or not the transmission frame 30 shown in FIG. 3 transmitted from the central processing unit 2 has been received by the determination process in step S10. In this case, when the transmission frame 30 is received, the CPU 25 turns on the timer by the processing of the subsequent step S11, and controls the mode data 30b of the transmission frame 30 shown in FIG. 3 received by the processing of the next step S12. The mode is confirmed whether the mode or the monitoring mode, and the process proceeds to the determination process in step S13.

  In the determination process of step S13, the CPU 25 determines whether or not the address data 30c of the transmission frame 30 shown in FIG. If the addresses do not match, this program is completed. If the addresses match, the process proceeds to step S14.

  In the process of step S14, the CPU 25 acquires the control data 30e of the transmission frame 30 shown in FIG. Thereafter, in the subsequent step S15, the CPU 25 outputs the acquired control data to the connected lighting fixture to control lighting, extinction, or dimming.

  Then, the CPU 25 reads the operating state of the corresponding lighting fixture in the subsequent step S16, and determines whether all control data has been output to the corresponding lighting fixture in the subsequent determination processing in step S17. .

  In this case, if it is determined that the control data output has not been completed, that is, if it has not been determined, the CPU 25 proceeds to step S19, and if it is determined that the control data output has been completed, that is, the control Is executed, after setting a flag to set the error bit to “1” in the processing of the subsequent step S18, the process proceeds to step S19.

  Thereafter, the CPU 15 determines whether or not it is the response timing of the monitoring response signal (ACK) of the monitoring response unit 33 shown in FIG. If it is not the response timing of the monitoring response signal (ACK), the process returns to step S16 and the state reading process is performed again. On the other hand, if it is the response timing of the monitoring response signal (ACK), the processing is performed. The process proceeds to step S20.

  In step S20, the CPU 15 adds a monitoring response signal (ACK) indicating the operating state of the corresponding lighting fixture to the monitoring response unit 33 of the transmission frame 30 shown in FIG. This program is completed after controlling to transmit to 2.

  The control terminal S has been described as a terminal that transmits the transmission frame 30. However, the control terminal S is not limited to this, and is transmitted to terminals such as the wall switch 4 and the center terminal 5 in addition to the control terminal. The frame 30 may be transmitted.

  As described above, since the central processing unit 2 and the control terminal S control the necessary control data and monitoring response signal using one transmission frame 30, the transmission data of the system can be simplified. .

  In addition, during the period t3 of the monitoring response unit 33 of the transmission frame 30 transmitted from the central processing unit 2, a lighting device monitoring response signal (ACK) 30g is returned to the central processing unit 2 from the corresponding control terminal S. Therefore, the response speed of the control terminal S can be made faster than before, and the control speed of the control terminal S can be increased to speed up the control to the next control terminal S. It can be done.

  Furthermore, since the central processing unit 2 transmits the monitoring data frame 31A only when the control terminal S determines that the execution result is indeterminate, the signal transmission as the monitoring mode can be minimized.

  Therefore, according to the present embodiment, it is possible to realize the illumination control system 1 that can improve the responsiveness of the system.

  In the present embodiment, the control terminal S is configured so that, for example, a four-circuit lighting fixture can be connected. However, the control terminal S is not limited thereto, and, for example, is configured so that an eight-circuit lighting fixture can be connected. It may be. In this case, the control terminal S adds the monitoring response data (ACK) 33g corresponding to the lighting circuit of 8 circuits to the monitoring response unit 33 of the transmission frame 40 shown in FIG. To be transmitted to.

  The present invention is not limited to the above-described embodiments and modifications, and various changes and modifications can be made without departing from the scope of the present invention.

1 ... Lighting control system,
2 ... Central processing unit,
2a ... connection part,
3 ... transmission line,
4 ... Wall switch
5 ... Sensor terminal,
6, 7 ... Wireless receiver,
8 ... Human sensor,
9, 10 ... Wireless transmitter,
15 ... CPU,
25 ... CPU,
30 ... transmission frame,
31 ... Control transmission unit,
32 ... a predetermined period part,
32 ... monitoring response unit,
S: Control terminal.

Claims (4)

A plurality of terminals connected to the transmission line and controlling the luminaire based on the control data transmitted through the transmission line;
A control transmission unit that controls the plurality of terminals by communicating with the plurality of terminals via the transmission line, and includes a control data unit having at least the address of the terminal and the control data; A central control unit that transmits a transmission frame having a monitoring response unit for monitoring response following the control transmission unit to the plurality of terminals via the transmission line;
Comprising
The terminal corresponding to the address of the transmission frame among the plurality of terminals adds a response signal indicating the control state of the lighting fixture to the monitoring response unit in the transmission frame and transmits the response signal to the central processing unit. The lighting control system characterized by controlling to do.   The illumination control system according to claim 1, wherein a predetermined period is set between the control transmission unit and the monitoring response unit of the transmission frame.   2. The terminal according to claim 1, wherein when the control output based on the control data for the lighting apparatus is unconfirmed, data indicating unconfirmed is added to the monitoring response unit and transmitted. Or the illumination control system of Claim 2.   When the central processing unit receives data indicating the indefiniteness in the monitoring response unit of the transmission frame transmitted from the terminal, an unused monitoring frame similar to the transmission frame is received. 4. The illumination control system according to claim 3, wherein the illumination control system generates, transmits a response signal to the monitoring response unit of the monitoring frame again, and transmits the response signal to the corresponding terminal.

Images