KR101286566B1 - Illuminating controller with built-in multidrop optical communication - Google Patents

Abstract

The lighting controller of the present invention receives a lighting control signal transmitted from the lighting server as an optical signal and converts it into an electrical signal, or receives an operating state signal directed to the lighting server as an electrical signal, converts it into an optical signal, and outputs it. And a second optical transceiver configured to receive an operation state signal as an optical signal and convert it into an electrical signal, or receive and output an illumination control signal as an electrical signal and convert it into an optical signal, and electrically connected to at least one lighting device. A lighting driver capable of turning on, turning off or dimming the lighting fixture by controlling the power supply to the controller, and if the lighting control signal includes a preset address, driving the lighting driver according to the instructions contained in the lighting control signal and To generate an operation status signal relating to the ON and OFF states of the It may comprise a control unit.

Description

ILLUMINATING CONTROLLER WITH BUILT-IN MULTIDROP OPTICAL COMMUNICATION}

TECHNICAL FIELD The present invention relates to lighting control, and more particularly, to a lighting controller for controlling lighting of a lighting fixture.

Large buildings, such as large buildings, shopping mall complexes, and campuses, require a large number of lighting fixtures. These luminaires can be turned on and off or dimmed by a light controller networked to a centralized server installed in the control room.

In a conventional centralized light control system, the centralized server and the light controllers are connected via a communication electrical standard such as EIA-485 / 422. EIA-485 / 422 is an electrical standard for 1: N or N: N digital communication. Because of the use of differential signals, EIA-485 / 422 is resistant to noise and provides high speed data communication even at relatively long distances, such as 1.5 km. Can support EIA-485 is a half-duplex that uses two transmission lines, so it can only transmit or receive at any one time, while EIA-422 is a full-duplex that uses at least four transmission lines. At any moment, both transmission and reception are possible. However, in EIA-485 / 422 mode, only one device at a time can monopolize the traffic line.

According to the EIA-485 / 422 invention, up to 32 devices can be connected, but more than 32 devices can be connected, or one device can act as a gateway to expand 32 more devices below. As the number can be increased, more devices are being used in actual field.

However, large building lighting control systems must connect hundreds of lighting controllers to a centralized server, and the length of the connection path easily exceeds the maximum length of the recommendation. When connected in this way, the signal transmission from the server to each of the lighting controllers or from the end lighting controllers to the server takes a very long time, and at any point in time the server can only communicate with any one lighting controller, There is a problem in that it takes a very long time to sequentially transmit the dimming level (dimming level) and the lighting command to the lighting controllers. In particular, the longer the path, the greater the likelihood of data loss. The sender does not know whether the data is lost, and the receiver does not know that someone sent it. This is not possible and the reliability of the system can drop significantly.

The problem to be solved by the present invention is to provide a lighting controller that is fast and reliable, and can control the lighting by various means.

Lighting controller according to an aspect of the present invention,

A first optical transceiver configured to receive an illumination control signal transmitted from an illumination server as an optical signal and convert it into an electrical signal, or receive an operation state signal directed to the illumination server as an electrical signal, convert it into an optical signal, and output the converted optical signal;

A second optical transceiver configured to receive the operation state signal as an optical signal and convert it into an electrical signal, or receive the illumination control signal as an electrical signal and convert it into an optical signal and output the converted optical signal;

An illumination driver electrically connected to at least one luminaire and capable of turning on, turning off or dimming the luminaire by controlling power supply to the luminaire; And

When the lighting control signal includes a preset address, the lighting driving unit is driven according to a command included in the lighting control signal, and an operation state signal related to a lighting state and an off state of the lighting apparatus is generated to the first optical transceiver. It may include a control unit for providing.

According to one embodiment, the lighting controller,

Further comprising a manual dimming switch for generating and outputting information on the on, off or dimming level for the at least one lighting fixture according to the user's operation,

The lighting driver turns on, off, or dims the at least one lighting device based on any one of the illumination control signal received by the controller or information on lighting, extinction, or dimming level output from the manual dimming switch. can do.

According to one embodiment, the lighting driver,

The detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and among the illumination control signals received by the controller or the detection result of the complex sensor. Based on either, the at least one lighting fixture can be turned on, off or dimmed.

According to one embodiment, the lighting controller,

Further comprising a manual dimming switch for generating and outputting information on the lighting, off or dimming level for the at least one lighting fixture according to the user's operation,

The lighting drive unit,

A detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement may be received, and the lighting control signal received from the control unit, the lighting of the manual dimming switch, the lighting may be turned off, or The at least one lighting device may be turned on, off, or dimmed based on at least one of information on a dimming level or a detection result of the complex sensor.

According to one embodiment, the lighting controller,

Further comprising a manual dimming switch for generating and outputting information on the on, off or dimming level for the at least one lighting fixture according to the user's operation,

The controller may be operable to drive the lighting driver based on at least one of the lighting control signal or the information on the lighting, extinguishing, or dimming level output from the manual dimming switch.

According to one embodiment,

A detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and based on at least one of the illumination control signal or the detection result of the complex sensor. Thus, the lighting driver may be driven.

According to an embodiment, the controller may generate the operation state signal including the detection result of the complex sensor.

According to one embodiment, the lighting controller,

Further comprising a manual dimming switch for generating and outputting information on the lighting, off or dimming level for the at least one lighting fixture according to the user's operation,

The control unit,

A detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and the lighting control, the lighting, extinguishing or dimming level output from the manual dimming switch may be received. The lighting driver may be driven based on at least one of information related to the information and a detection result of the complex sensor.

According to an embodiment, the controller may be configured according to any one selected according to a priority from among the illumination control signal, the information on the lighting, extinguishing or dimming level output from the manual dimming switch, or the detection result of the complex sensor. The lighting driver may be driven.

According to an embodiment, the control unit may be configured according to any one selected according to an operating condition formula from among the illumination control signal, information on lighting, extinguishing or dimming level output from the manual dimming switch, or detection result of the complex sensor. The lighting driver may be driven.

According to the lighting controller of the present invention, it is possible to configure a large-scale lighting control system that is connected to a plurality of lighting controllers in a multi-drop method through an optical cable in succession to ensure speed and stability.

In addition, according to the lighting controller of the present invention, lighting can be controlled by various means such as a remote server, a manual switch, a sensor, and cope with various situations.

1 is a block diagram illustrating a lighting controller according to an embodiment of the present invention.
2 is a block diagram illustrating a lighting controller according to another embodiment of the present invention.
3 is a diagram illustrating a lighting control system configured by connecting lighting controllers according to embodiments of the present invention.

For the embodiments of the invention disclosed herein, specific structural and functional descriptions are set forth for the purpose of describing an embodiment of the invention only, and it is to be understood that the embodiments of the invention may be practiced in various forms, The present invention should not be construed as limited to the embodiments described in Figs.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 is a block diagram illustrating a lighting controller according to an embodiment of the present invention.

Referring to FIG. 1, the lighting controller 10 may include a first optical transceiver 11, a second optical transmitter and receiver 12, a receiver 13, a transmitter 14, a controller 15, and an illumination driver 16. A manual dimming switch 17 and a setting interface 18. Additionally, the lighting controller 10 may further include a complex sensor 19 or may receive a sensing result from the complex sensor 19.

The lighting controller 10 may be connected in a multidrop manner from a centralized lighting server (not shown).

The lighting controller 10 receives from the centralized lighting server a lighting control signal including an on / off command of the lighting fixtures and a dimming level, that is, a brightness control level, through the optical cable. The lighting controller 10 analyzes the received lighting control signal and, in the case of lighting / lighting command and dimming level data for lighting devices connected to the lighting controller 10, lights or turns off or adjusts brightness accordingly.

The lighting controller 10 may allow the user to manually turn on / off and dimming the lighting fixtures, in which case the operation controller generates an operation state signal with respect to the changed lighting / off state and the dimming level, so that the other lighting controller 10 and It can be sent to the centralized lighting server side via optical cable.

The lighting controller 10 may be turned on / off or dimmed according to the level of ambient light detected by the complex sensor, or according to human body detection or motion detection, furthermore, when detecting a fire or smoke, or when a crime or a security breach is detected. You can decide the level. Similarly, in such a case, an operating state signal can be generated and transmitted to the centralized lighting server side with respect to the changed on / off state and dimming level.

Furthermore, the lighting controller 10 may be configured according to at least one of the lighting control signal transmitted from the lighting server, the lighting setting by the user's manual dimming switch 17, or the lighting setting by the detection result of the complex sensor 19. , Lighting fixtures can be operated.

For example, the lighting controller 10 selects one lighting setting according to a predetermined priority or according to a predetermined condition expression among lighting control signals, manual dimming switch operation, or detection result of the complex sensor, and according to the selected lighting setting. The lighting fixtures can be operated. At this time, the priority or conditional expression may be stored in the lighting controller 13 in advance and activated when called by the lighting server.

Meanwhile, the lighting controller 10 may provide a relay function by immediately transmitting the received signal to another lighting controller 10 directly connected thereto regardless of address analysis of the received signal, thereby providing a conventional EIA-485. Compatibility can be maintained at the physical layer level with lighting control systems using the / 422 network.

The first and second optical transceivers 11 and 12 may receive and transmit single mode or multimode optical signals, respectively. For convenience of description, a structure of transmitting and receiving both signals through one optical cable is illustrated.

The first optical transceiver 11 receives the optical signal ORx1 transmitted from the lighting server side and converts the optical signal ORx1 into an electrical signal Rx1, and converts the electrical signal Tx1 directed to the lighting server side into the optical signal OTx1. Output

In other words, the first optical transceiver 11 converts a lighting control signal transmitted from the lighting server to the lighting controllers 10 into an electrical signal, or converts an operation state signal directed to the lighting server from the electrical signal into an optical signal. Convert to a signal.

The second optical transceiver 12 converts and outputs an electrical signal Tx2 directed to the lighting controller side of the next stage into an optical signal OTx2 and outputs the optical signal ORx2 transmitted from the lighting controller side of the next stage. Convert to (Rx2).

In other words, the second optical transceiver 12 converts the operation state signal transmitted from the lighting controller of the next stage from the optical signal to the electrical signal, or the lighting control signal transmitted from the lighting server from the electrical signal to the optical signal. To print.

The receiver 13 branches the electrical signal Rx1 obtained by converting the optical signal ORx1 related to the illumination control signal from the first optical transceiver 11 to the second optical transceiver 12 and the controller 15, respectively. .

The transmitter 14 transmits the operation state signal Tx output through the controller 15 to the first optical transceiver 11 in the form of an electrical signal.

In this case, the receiving unit 13 and the transmitting unit 14 may be configured to receive or transmit an electrical signal according to the EIA-485 or EIA-422 communication standards, respectively.

The controller 15 decodes the address, the command, and the data included in the electrical signal Rx1 input through the first optical transceiver 11 and the receiver 13, so that the decoded address corresponds to the lighting controller 10. If it is determined that the address corresponds to, the lighting driver 16 is driven in accordance with the decoded command and data. Otherwise, if the decrypted address is irrelevant to the measurement device 10, the control unit 15 ignores the received command and data and discards it.

The lighting driver 16 may turn on / off the lighting fixtures connected to the corresponding lighting controller 10 according to a lighting / lighting command or a dimming command included in the lighting control signal, and further dimming according to an embodiment.

According to an embodiment, the lighting driver 16 may directly supply electrical energy to the lighting fixtures. When the lighting apparatuses are connected in parallel or in series to one power source, the lighting controller 10 may integrally control all the lighting apparatuses connected to the one lighting driver 16. According to an embodiment, a plurality of lighting drivers 16 are mounted in the lighting controller 10, and each of the lighting drivers 16 can drive a power source of each lighting fixture, so that they are connected to different power paths. Multiple lighting fixtures may be controlled independently.

In the case of simply providing the lighting / lighting function, the lighting driver 16 may drive the relay to connect or cut off the power supplied to the lighting fixtures to perform the lighting command or the lighting command.

Furthermore, in the case of providing the dimming function, the lighting driver 16 directly adjusts the energy supplied to the lighting equipment in the dimming circuit designed according to the dimming method such as the constant voltage method, the constant current method, the PAM method, or the PWM method. Can control the dimming command.

In another embodiment, the light driver 16 may also control only the path of energy supplied to the luminaires. In this case, the lighting driver 16 may output a signal to drive the relay or the dimming circuit located on the power path of the lighting fixtures to the outside of the lighting controller 10.

On the other hand, in consideration of a case where a person near the lighting fixture wants to directly manipulate the lighting fixture, the lighting controller 10 may include a manual dimming switch 17. As the user sets the manual dimming switch 17 directly, the lighting fixtures can be turned on, off or dimmed. In this case, the lighting or turning off function may be implemented by means of a conventional contact switch, push switch, toggle switch, and the like. The dimming function may be implemented by means of a slide, dial, or the like, which may be set to turn on or off at a particular dimming level.

Although the manual dimmer switch 17 may directly control the power connection and disconnection of the luminaire in some embodiments, the manual dimmer switch 17 preferably provides information about the on / off and dimming levels in the form of digital or analog signals. The furnace may be delivered to the lighting driver 16.

In this case, the lighting driver 16 may perform lighting, extinction and dimming according to the latest lighting control signal originating from either the lighting server or the manual dimming switch 17.

In addition, in another embodiment, the lighting controller 10 may further include a complex sensor 19 or receive a detection result from the complex sensor 19.

The composite sensor 19 determines whether to turn on / off or adjust the dimming level according to the detected ambient light level, human body detection, motion detection, fire or smoke detection, or crime or security breach detection. Thus, it is transmitted to the lighting driver 16. Through this, the lighting controller 10 according to the embodiment of the present invention can adjust the lighting, lighting and dimming level of the lighting fixtures according to the external lighting state.

In this case, the light driver 16 may be configured to at least one of a light control signal transmitted from a light server, a light setting by a user's manual dimmer switch 17, or a light setting by a detection result of the complex sensor 19. Thus, the lighting fixtures can be operated.

In this case, the lighting driver 16 may operate the lighting fixtures according to two or more conditions. For example, after the lighting server is turned off in a lighting server, when a person operates the manual dimmer switch 17 in the lit position in the dark state of the ambient light, the lighting driver 16 is turned off even though the lighting control signal is turned off. Can be set to turn on the lighting fixture.

Alternatively, for example, the lighting driver 16 may be set to turn on the lighting fixture only when the lighting control signal is included in the lighting server in the lighting server and a person turns on the manual dimmer switch 17.

In another example, when a fire is detected by the composite sensor 19, the lighting driver 16 manipulates the lighting control signal of the lighting server or the user's manual dimmer switch 17 with respect to the lighting fixtures located in the escape or suppression path. It can be turned on at maximum brightness by bypassing all the states.

In this way, the lighting controller according to embodiments of the present invention may turn on / off or dimm the lighting fixtures according to various conditions.

On the other hand, the control unit 15 is the lighting driver 16 is currently operating by the remote control by the lighting server, manual dimming switch 17 or the composite sensor 19, the lighting or off state of the lighting fixtures, the set dimming Information about the current operation state such as a level or a failure may be generated as an operation state signal and transmitted to the lighting server through the transmitter 14 and the first optical transmitter / receiver 11. Thereby, for example, when the lighting / off state and dimming state set by the lighting server are changed by the user operating the manual dimming switch 17 or in response to the change of the ambient light, the central lighting server can recognize this. .

According to an embodiment, the ambient light level detected by the complex sensor 19, a human body or an object detection, and a motion detection result may also be included in the operation state signal. In this case, the lighting server may generate the lighting control signal based on the detection result of the complex sensor 19 and transmit the lighting control signal to the lighting controller 10.

The control unit 15 is designed to comply with a full-duplex / half-duplex communication method, a synchronous / asynchronous communication method, a low voltage differential signal standard, or the like so as to be compatible with a conventional EIA-485 / 422 network, or by using a conventional controller as it is. It may be implemented.

In other words, when the corresponding lighting controller 10 does not transmit, the driving circuit of the transmitting unit 14 is set to a high-impedance (high-Z) state using the transmission control signal C _TX to operate the other lighting controller 10. Do not interfere with signal transmission.

The setting interface 18 may set an address for the controller 15 to refer to, a priority of the lighting control signal for the lighting driver 16 to refer to, and the like through a dual in-line package (DIP) switch.

2 is a block diagram illustrating a lighting controller according to another embodiment of the present invention.

Referring to FIG. 2, the components of the lighting controller 20 are generally similar to the corresponding respective components of the lighting controller 10 of FIG. 1.

However, the control unit 25 receives from the manual dimming switch 27 an analog signal relating to the on / off and dimming level according to the user's operation, and from the complex sensor 29 the external brightness, the presence of a human body or an object in proximity It receives the results of detecting motion, fire, smoke, crime prevention, etc. as analog signals, and converts these analog signals into digital signals of the same type as the lighting control signals sent from the lighting server.

Subsequently, the controller 25 selects one of a lighting control signal transmitted from the lighting server, a lighting setting by a user's manual dimming switch 27, or a lighting setting based on a detection result of the complex sensor 29 to select a lighting driver. To 26.

In this case, the lighting server may include information about the priority in the lighting control signal and transmit the information to the lighting controller 20. Based on the priority information, the control unit 25 of the lighting controller 20 controls the lighting control signal of the lighting server, the lighting setting by the user's manual dimming switch 27, or the detection result of the complex sensor 29. Can choose one of the lighting settings.

For example, an operation of an adjacent user may be set to take precedence over a remote control of the lighting server, or may be set to give priority to an ambient brightness over an operation of the user.

In addition, the lighting server may transmit information to the lighting controller 20 by including information on an operating condition, for example, a logic condition in the lighting control signal. In this case, the controller 25 may operate the lighting apparatuses according to the operating condition information including two or more conditions. For example, after turning off a light fixture in the lighting server, when a person operates the manual dimmer switch 27 in the lit position (condition 2) in a dark condition (condition 1), the light control signal is turned off ( Despite the condition 3), the controller 25 may be set to drive the lighting driver 26.

Or, for example, only when the lighting control signal is included in the lighting control signal in the lighting server (condition 1) and a person manipulates the manual dimmer switch 27 to lighting (condition 2), the controller 25 controls the lighting driver ( 26) may be set to drive.

In another example, when a fire is detected in the composite sensor 29 (condition 1), the control unit 25 controls the lighting server's lighting control signal (condition 2) or user for the lighting fixtures located in the escape or suppression path. It is also possible to drive the lighting driver 26 to the maximum brightness by bypassing all of the manual dimming switch 27 operating conditions (condition 3).

In this way, the lighting controller according to embodiments of the present invention may turn on / off or dimm the lighting fixtures according to various conditions.

3 is a diagram illustrating a lighting control system configured by connecting lighting controllers according to embodiments of the present invention.

The lighting control system 30 includes a first connection method connected to the lighting server 31, the optical cables 32, and the plurality of lighting controllers 33, the lighting server 31, the electric signal cable 34, By way of example, the second connection scheme may be connected to the gateway 35 and the plurality of lighting controllers 33.

In the first connection, the lighting server 31 of the lighting control system 30 is directly connected to the first lighting controller 33a via the optical cable 32a, and all subsequent lighting controllers 33b and 33c are connected. The connection is made via optical cables 32b and 32c.

In a second connection scheme, the lighting server 31 is connected once with an electrical signal cable 34 between the gateways 35. The electrical signal cable 34 may be embodied as an unshielded twist pair (UTP) cable of RS-232C or RJ-45 standard. The gateway 35 is connected to the lighting controllers 33 by an optical cable 32.

Similar to the conventional EIA-485 / 422 network, the lighting server 31 can transmit a lighting control signal to one lighting controller 33 at a time, and also operation state information from one lighting controller 33 at a time. Can be received. However, unlike the conventional lighting control system using the EIA-485 / 422 network, since the optical cable is used to transmit the lighting control signal to the lighting controller side and the optical controllers are optically insulated between each lighting controller 33, Strong, virtually no signal loss, high reliability, high transmission speed and scalability enable large lighting control systems to be implemented without difficulty.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art. Modifications are possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all of the equivalent or equivalent variations will fall within the scope of the present invention.

10, 20 Lighting controller 11, 21 First optical transceiver
12, 22 Second optical transceiver 13, 23 Receiver
14, 24 transmitter 15, 25 controller
16, 26 light drive 17, 27 manual dimmer switch
18, 28 Settings interface 19, 29 Composite sensor
30 Lighting Control System 31 Lighting Server
32 optical cable 33 lighting controller
34 Electrical Signal Cables 35 Gateways

Claims (10)

The lighting server receives a light control signal for transmission to a controller or a plurality of serially connected lighting controllers as an optical signal and converts it into an electrical signal, and is generated by any one of the controller or the plurality of serially connected lighting controllers. A first optical transceiver configured to receive an operation state signal directed to the lighting server as an electrical signal, convert the optical signal into an optical signal, and output the converted optical signal;
Receives an operation state signal generated by any one of the plurality of serially connected lighting controllers as an optical signal and converts it into an electrical signal, and receives a lighting control signal as an electrical signal to be transmitted to the plurality of serially connected lighting controllers. A second optical transceiver for converting the optical signal into an optical signal and outputting the converted optical signal;
An illumination driver electrically connected to at least one luminaire and capable of turning on, turning off or dimming the luminaire by controlling power supply to the luminaire; And
If the lighting control signal received from the first optical transceiver includes a preset address, the lighting driving unit is driven according to a command included in the lighting control signal, and an operation state signal relating to the lighting and turning off states of the lighting fixture is provided. And a controller for generating and providing the first optical transceiver. The method according to claim 1, further comprising a manual dimming switch for generating and outputting information on the lighting, extinction or dimming level for the at least one lighting fixture according to the user's operation,
The lighting driver turns on, off, or dims the at least one lighting device based on any one of the illumination control signal received by the controller or information on lighting, extinction, or dimming level output from the manual dimming switch. And a light controller operative to. The method of claim 1, wherein the light driving unit,
The detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and among the illumination control signals received by the controller or the detection result of the complex sensor. Based on any one of the above, wherein the at least one lighting fixture is operative to turn on, turn off, or dim the lighting controller. The method according to claim 1, further comprising a manual dimming switch for generating and outputting information on the lighting, extinction or dimming level for the at least one lighting fixture in accordance with the user's operation,
The lighting drive unit,
A detection result of sensing at least one of a brightness level of an ambient light, the presence of a nearby object or a human body, or a movement from a complex sensor may be received, and the lighting control signal received from the control unit and the lighting output from the manual dimming switch may be received. And turn on, turn off, or turn on the at least one lighting fixture based on at least one of information relating to an unlit or dimmed level, or a detection result of the complex sensor. The method according to claim 1, further comprising a manual dimming switch for generating and outputting information on the lighting, extinction or dimming level for the at least one lighting fixture according to the user's operation,
And the controller is operable to drive the lighting driver based on at least one of the lighting control signal or the information on the lighting, extinguishing, or dimming level output from the manual dimming switch. The apparatus of claim 1,
A detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and based on at least one of the illumination control signal or the detection result of the complex sensor. And drive the light driver. The lighting controller of claim 6, wherein the controller is configured to generate the operation state signal including a detection result of the complex sensor. The method according to claim 1, further comprising a manual dimming switch for generating and outputting information on the lighting, extinction or dimming level for the at least one lighting fixture in accordance with the user's operation,
The control unit,
A detection result of detecting at least one of the brightness level of the ambient light, the presence of a nearby object or the human body, or the movement from the complex sensor may be received, and the lighting control, the lighting, extinguishing or dimming level output from the manual dimming switch may be received. And based on at least one of information relating to the detection result of the complex sensor and the lighting controller. The method according to claim 8, wherein the control unit is the illumination according to any one selected according to the priority among the illumination control signal, information on the lighting, off or dimming level output from the manual dimming switch, or the detection result of the complex sensor And a lighting controller operative to drive the driving unit. The method according to claim 8, wherein the control unit is the illumination according to any one selected according to the operating condition equation from the illumination control signal, information on the lighting, extinguishing or dimming level output from the manual dimming switch, or the detection result of the complex sensor. And a lighting controller operative to drive the driving unit.

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