KR20100090623A - Apparatus, method and system for controlling lighting - Google Patents

Abstract

PURPOSE: A device, a method and a system for controlling illumination are provided to control a RGB color value of one or more lighting devices, thereby setting a white balance. CONSTITUTION: An operation management unit(130) differently sets a first control data and a second control data based on IP of one or more lighting devices. The first control data comprises scheduling information and directing information of the lighting devices. A second control data comprises information about RGB value for controlling white balance of the lighting devices. A communication unit(110,120) transmits a third control data for executing the first control data and the second data to one or more lighting device.

Description

Apparatus, method and system for controlling lighting

The present invention relates to apparatus, methods and systems for controlling lighting, and more particularly, to apparatus, methods and systems capable of controlling one or more lighting fixtures.

In general, a luminaire reflects, refracts, and transmits light from a light source to achieve an object of illumination. Lighting equipment is classified into five types: indirect lighting, semi-indirect lighting, total diffuse lighting, semi-direct lighting, and direct lighting.

An LED (Light Emitting Diode) generates a small number of carriers (electrons) injected using a p-n junction structure of a semiconductor and emits light by recombination of these minority carriers.

Such LEDs are not only compact and have a long life compared to conventional light sources, but also have low power consumption and good efficiency because electrical energy is directly converted into light energy.

In addition, LEDs have high-speed response and are widely used for display lamps and numeric display devices of various electronic devices such as display devices for automobile instruments and light sources for optical communication, and for homes, vehicles, ships, traffic signals, various guidance, It has been applied to various lighting means (means) such as induction.

In a conventional lighting fixture, when the LED specification is changed, the light output value of each RGB is changed, so that it is difficult to realize white color and a dichroic phenomenon is generated, which causes difficulty in producing colors. In other words, if the white balance of the lighting fixture does not match, there is a problem that the hardware of the lighting fixture must be redesigned.

In addition, the conventional lighting equipment has a problem that it is not possible to perform a variety of lighting by repeating only limited lighting direction.

Therefore, the present invention proposes a solution for solving the above problems.

The present invention aims to control one or more luminaires.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the apparatus for controlling lighting according to an embodiment of the present invention, in the apparatus for controlling one or more lighting devices, the predetermined schedule information of the first lighting device and the white balance of the first lighting device An operation manager for managing first control data including direction information on an RGB value for fitting the control unit; and second control data requesting execution of the first control data and the first control data to the first lighting device. And a second communication unit for transmitting, wherein the first control data is differently set based on IPs of the one or more lighting devices.

In addition, the method for controlling lighting according to an embodiment of the present invention, in the method for controlling one or more lighting devices, the predetermined schedule information of the first device and the RGB value for matching the white balance of the first device Managing first control data including direction information, and transmitting second control data requesting execution of the first control data and the first control data to the first device. The first control data may be set differently based on the IP of the one or more lighting devices.

In addition, the apparatus for controlling lighting according to an embodiment of the present invention, the first communication unit for receiving the first control data including the direction information on the RGB value for adjusting the white balance from the first device, and the received An operation processor for adjusting white balance based on the RGB value included in the first control data, and an output unit for outputting the adjusted RGB value.

In addition, the method of controlling the lighting according to an embodiment of the present invention, receiving the first control data including the direction information on the RGB value for adjusting the white balance from the first device, and the received first Adjusting the white balance based on the RGB value included in the control data, and outputting the adjusted RGB value.

In addition, the system for controlling illumination according to an embodiment of the present invention, the first control data including the direction information on the predetermined schedule information and the RGB value for matching the white balance, and manages the first control data and the Receiving a first device for transmitting the second control data for requesting the execution of the first control data, and the first control data including the direction information on the RGB value for the white balance from the first device, And adjusting a white balance based on the RGB value included in the received first control data, and outputting the adjusted RGB value, wherein the first device comprises one or more second control data. It is characterized in that different settings based on the IP of the device.

Specific details of other embodiments are included in the detailed description and drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

The apparatus, method and system for controlling the illumination of the present invention as described above have one or more of the following effects.

First, there is an advantage that white balance can be adjusted by adjusting RGB color values of one or more lighting fixtures.

Second, by adjusting the white balance of the luminaire through the central control unit, there is an advantage that the white balance of one or more luminaires can be adjusted through simple GUI operation without redesigning the hardware of the luminaires to which various types of LEDs are applied. .

Third, there is an advantage that it is possible to produce a variety of lighting of one or more lighting fixtures based on the predetermined schedule information and the direction information.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a system for controlling lighting according to an embodiment of the present invention.

As shown, the system for controlling lighting comprises a central control device 100 and a lighting control device 200. Here, the system for controlling lighting is configured by connecting one central control apparatus 100 and one or more lighting control apparatuses 200 (21, 22, 23, .., 2n) in series. Here, the central control apparatus 100 may be connected to 8,000 lighting fixtures.

The central control apparatus 100 communicates with the lighting control apparatus 200 provided in each lighting fixture to control one or more lighting fixtures configured in series. Here, the order of the lighting control devices 200 (21, 22, 23, ..., 2n) provided in the lighting fixture is set according to the connection order of the one or more lighting fixtures.

For example, the central control device 100 communicates with the first lighting control device 21 to control one or more lighting fixtures configured in series (ie, IP assignment, operation command, error detection, scheduling function and RGB color). Each lighting device can be controlled by sending an adjustment.

That is, when the central control apparatus 100 transmits data (hereinafter referred to as "control data") for the control command to designate the IP as 01 to the first lighting control apparatus 21, the first lighting control apparatus 21 It designates its own IP as IP01 transmitted from the central control device 100 of), and transmits control data to specify the IP as 02 to the second lighting control device 22. Here, the control data for specifying IP is transmitted to the lighting control device 2n provided in the last lighting device located. In other words, an IP is automatically assigned to each luminaire according to the connection order of the luminaires (ie, the sequence of the lighting control device). Hereinafter, the central control apparatus 100 will be described in more detail with reference to FIG. 2.

The lighting control apparatus 200 manages and controls the lighting apparatus according to a control command transmitted from the central control apparatus 100.

For example, when the first lighting control device 21 receives data for requesting IP designation (that is, data for designating IP as 01) from the central control device 100, the first lighting control device 21 recognizes the received control data and receives IP 01. Set your own IP and save it.

Then, the first light control device 21 increases the IP value of 1, and then transmits data to the second light control device 22 requesting the IP designation (that is, data to designate the IP as 02). do. Accordingly, the second lighting control device 22 designates and stores its IP as IP 02. This process is carried out until the IP is assigned to the lighting control device 2n provided in the luminaire positioned last of the one or more luminaires. Hereinafter, the lighting control device 200 will be described in more detail with reference to FIG. 3.

2 is a block diagram illustrating an internal control apparatus of the central control apparatus in the system for controlling lighting according to an embodiment of the present invention.

As shown in the drawing, the central control apparatus 100 controls the first communicator 110, the second communicator 120, the operation manager 130, the schedule checker 140, the storage 150, and the controller 160. It is configured to include.

In this case, the term '~ part' used in the present embodiment refers to software or a hardware component such as an FPGA or an ASIC, and '~ part' performs certain roles. However, '~' is not meant to be limited to software or hardware. '~ Portion' may be configured to be in an addressable storage medium or may be configured to play one or more processors. Thus, as an example, '~' means components such as software components, object-oriented software components, class components, and task components, and processes, functions, properties, procedures, and the like. Subroutines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables. The functionality provided within the components and the 'parts' may be combined into a smaller number of components and the 'parts' or further separated into additional components and the 'parts'.

The first communication unit 110 serves to transmit and receive control data with a computer (not shown) of the client. Here, the first communication unit 110 receives control data for controlling one or more lighting fixtures from the computer of the client. Here, the first communication unit 110 uses a LAN communication method, but is not necessarily limited thereto.

The second communication unit 120 transmits control data to the first lighting control device 21 and receives a result of performing the control data from the first lighting control device 21. Here, the second communication unit 120 communicates in a serial communication method, for example, may be configured as an RS-485 port.

For example, when the second communication unit 120 transmits control data for specifying IP to 01 to the first lighting control device 21, the first lighting control device 21 to the nth lighting control device 2n Assign IP sequentially. Thereafter, when IP is assigned to the lighting control device 2n provided in the last lighting device, data including IP information designated in the reverse order in which the IP is specified is transmitted, and the first lighting control device 21 receives the central control device ( The corresponding data (that is, data including IP information) is transmitted to the second communication unit 120 of 100.

The operation manager 130 manages predetermined control data for controlling one or more lighting fixtures. Here, the predetermined control data may be understood as IP specification, operation command, error detection, schedule function, RGB color adjustment, and the like. In addition, the predetermined control data can be set differently according to the control command for each IP, the lighting control devices 200 need only execute the control data corresponding to its own IP.

The schedule checker 140 notifies the operation manager 130 of the arrival of the time for the operation of the directed data based on previously stored schedule information (ie, time information) and the directed information. Here, the schedule checker 140 may be understood as a real time clock (RTC) timer. In addition, the schedule information refers to time and date information for directing data to operate, and the directing information refers to information for executing lighting on and blinking operations.

The storage unit 150 stores predetermined control data received from the computer of the client.

The controller 160 controls the operations of the respective functional blocks 110 to 150 constituting the central control apparatus 100.

3 is a block diagram illustrating an interior of a lighting control device in a system for controlling lighting according to an embodiment of the present invention.

As shown, the lighting control device 200 includes a first communication unit 210, a second communication unit 220, an operation processor 230, an output unit 240, a storage unit 250, and a controller 260. It is configured by.

The first communication unit 210 communicates with a device located in the direction of the central control device 100 among adjacent devices. Here, the first communication unit 210 communicates in a serial communication method, for example, may be configured as an RS-485 port.

For example, in the case of the first communication unit 210 of the first light control device 21, the communication with the central control unit 100, if the first communication unit of the second light control device 22, the first Communicates with the lighting control device 21.

The second communication unit 220 communicates with a device in a position opposite to the direction of the central control device 100 among adjacent devices. Here, the second communication unit 220 communicates in a serial communication method, for example, may be configured as an RS-485 port.

For example, in the case of the second communication unit 220 of the first light control device 21, in communication with the second light control device 22, and in the case of the second communication unit of the second light control device 22, In communication with the third lighting control device 23.

The operation processor 230 analyzes the control data received from the first communication unit 210 and the second communication unit 210 and performs an operation corresponding to the analysis result. Here, the control data may be understood as command data for requesting an IP designation, performing an operation of a specific lighting device, directing according to a schedule, and adjusting white balance.

For example, when the operation processor 230 commands the IP designation as a result of analyzing the received control data, the operation processor 230 designates and stores its own IP. In addition, the operation processor 230 stores its own IP (ie, IP 01), and then increments 1 to its own IP value so that the device at the position opposite to the direction of the central control device 100 among the adjacent devices (ie, Control data (that is, data to designate IP as 02) is transmitted to the second lighting control device. Here, the operation processor 230 first checks whether an error occurs in the corresponding lighting fixture, and then designates its own IP as the received IP, and transmits error check data including whether the error is detected to the central control apparatus 100. . Hereinafter, a process of specifying an IP and detecting an error in the operation processor will be described in detail with reference to FIG. 4.

In addition, when the operation processor 230 analyzes the received control data and is not the control data corresponding to the IP, the device at the position opposite to the direction of the central control device 100 among the adjacent devices (ie, the second lighting). The control data). Hereinafter, a process of performing a command operation for a specific IP of the operation processor in FIG. 5 will be described in detail.

The output unit 240 outputs the RGB value adjusted by the operation processor 230 to match the white balance of the lighting fixture to the LED module (not shown). Here, the output unit 240 may be configured as a pulse width modulation (PMW) port, and the adjusted RGB value is output in a PMW voltage (V) adjustment scheme.

The storage unit 250 stores the control data received through the first communication unit 210 and the IP designated through the operation processor 240.

The controller 260 controls the operation of each of the functional blocks 210 to 250 constituting the lighting control device 200.

4 is a flowchart illustrating a process of performing IP designation in a method of controlling lighting according to an embodiment of the present invention. In this case, the central control apparatus 100 transmits control data instructing IP designation to the one or more lighting control apparatuses 21, 22, and 23 so that the IP is automatically assigned sequentially according to the connection order of the lighting fixtures. The error detection procedure is explained.

First, the central control apparatus 100 transmits control data to designate the IP of the corresponding lighting apparatus as 01 to the first lighting control apparatus 21 (S410). Here, the control data includes a command message for IP specification and error detection.

Accordingly, the operation processor 230 analyzes the control data received through the first communication unit 210 of the first lighting control device 21 to recognize that the received control data is an error detection and an instruction to designate IP01 ( S412).

Next, the operation processor 230 confirms whether an error of the lighting fixture occurs, and then designates and stores the IP of the lighting fixture as 01 (S414 and S416). Next, the operation processor 230 transmits error check data including whether an error is detected to the central control apparatus 100 through the first communication unit 210 (S418). Here, when the error processing unit 230 checks whether an error has occurred and the error does not occur in the lighting device, the operation processor 230 designates an IP. In addition, the error check data may include whether an error is detected and whether the IP designation is performed.

Accordingly, the central control apparatus 100 receives the error check data and checks whether the first lighting control apparatus 21 detects an error (S420). Here, the operation processor 230 may transmit error detection data (or non-error detection data indicating that no error has occurred) including the fact that an error has occurred instead of the error check data. That is, when the first lighting control device 21 transmits the error detection data, the central control device 100 only needs to check whether the error detection data is received. At this time, the central control apparatus 100 checks whether the error detection data is received for a predetermined time, and if the error detection data is not received during the predetermined time, the central control apparatus 100 determines that no error is detected in the first lighting control apparatus 21.

Next, the operation processor 230 generates a new IP (that is, IP02) to which 1 is added to its IP, and transmits control data (that is, a command to designate the IP as 02) through the second communication unit 220. It transmits to the 2nd light control apparatus 22 (S422). Here, the method of adding 1 to its IP as a method of generating a new IP has been described, but is not necessarily limited thereto.

Then, the first communication unit of the second lighting control device 22 receives the control data transmitted from the first lighting control device 21. Next, the operation processor analyzes the received control data to recognize that the received control data is an error detection and an instruction to designate IP02 (S424).

Next, after confirming whether an error occurs in the corresponding lighting fixture, the operation processor of the second lighting control device 22 designates and stores the IP of the corresponding lighting fixture as 02 (S426, S428). Next, the operation processor transmits error check data including whether an error is detected to the first lighting control device 21 through the first communication unit (S430).

Thus, the first lighting control device 21 analyzes the error check data and checks whether the second lighting control device 22 detects an error (S432). Here, the operation processing unit of the second lighting control device 22 may transmit error detection data (or error undetected data indicating that no error has occurred) including the fact that an error has occurred instead of the error check data. That is, when the second lighting control device 22 transmits the error detection data, the first lighting control device 21 only needs to check whether the error detection data is received. At this time, the first lighting control device 21 checks whether the error detection data is received for a predetermined time, and determines that no error is detected in the second lighting control device 22 when the error detection data is not received for the predetermined time. .

When an error is detected in the second lighting control device 22 as a result of analyzing the error check data by the operation processing unit 230 of the first lighting control device 21, the first lighting control device 21 is configured to determine the lighting fixture. RGB flashes sequentially (S434). Here, when no error is detected in the second lighting control device 22 as a result of analyzing the error check data, the operation processing unit 230 of the first lighting control device 21 is abnormal to the second lighting control device 22. It is determined that there is no, do not perform a separate operation.

Next, the operation processing unit of the second lighting control device 21 generates a new IP (i.e., IP03) in which 1 is added to its IP, and designates control data (i.e., IP as 03) through the second communication unit. Command) is transmitted to the third lighting control device 22 (S436).

Then, the first communication unit of the third light control device 23 receives the control data transmitted from the second light control device 22. Next, the operation processor analyzes the received control data and recognizes that the received control data is an error detection and an instruction to designate IP03 (S438).

Next, after confirming whether an error occurs in the corresponding lighting fixture, the operation processor of the third lighting control apparatus 23 designates and stores IP of the corresponding lighting fixture as 03 (S440 and S442). Next, the operation processor transmits the error check data including whether the error is detected to the second lighting control device 22 through the first communication unit (S444).

Thus, the second lighting control device 22 analyzes the error check data and checks whether the third lighting control device 23 detects an error (S446). Here, the operation processing unit of the third lighting control device 23 may transmit error detection data (or error undetected data indicating that no error has occurred) including the fact that an error has occurred instead of the error check data. That is, when the third lighting control device 23 transmits the error detection data, the second lighting control device 22 only needs to check whether the error detection data is received. At this time, the second lighting control device 22 checks whether the error detection data is received for a predetermined time, and determines that no error is detected in the third lighting control device 23 when the error detection data is not received for the predetermined time. .

Next, when an error is detected in the third lighting control device 23 as a result of analyzing the error check data by the operation processing unit of the second lighting control device 22, the second lighting control device 22 determines the RGB flashes sequentially (S448). Here, when the error check data is analyzed and no error is detected in the third lighting control device 23, the operation processing unit of the second lighting control device 22 determines that the third lighting control device 23 has no abnormality. And does not perform a separate operation.

Next, the third lighting control device 23 transmits its own IP information (ie, IP03) to the second lighting control device 22 (S450). Here, the transmission of the own IP information to the second lighting control device 22 means that the third lighting control device 23 recognizes that it is the last lighting device. To give 100.

Next, the second lighting control device 22 transmits the IP information transmitted from the third lighting control device (ie, IP03) to the first lighting control device 22 (S452), and the first lighting control device 21. ) Transmits the IP information (that is, IP03) transmitted from the second lighting control device 22 to the central control device 100 (S454).

Then, the central control apparatus 100 checks the IP information (that is, the number of the specified IPs) assigned to the luminaire positioned last by the IP information (ie, IP03) transmitted from the first lighting control apparatus 21. (S456).

Accordingly, the central control apparatus 100 may check not only IP designation of one or more lighting fixtures but also whether an error occurs.

5 is a flowchart illustrating a process of performing a command operation for a specific IP in a method of controlling lighting according to an embodiment of the present invention.

First, when control data for requesting to perform an operation on a specific IP is transmitted from the central control apparatus 100 (S510), the first communication unit 210 of the first lighting control apparatus 21 receives control data and operates. The processor 230 analyzes the received control data (S520).

As a result of analysis, when its IP (ie, IP01) is set in the received control data (YES in S530), the operation processor 230 of the first lighting control device 21 performs the corresponding operation (S540). .

On the other hand, if the own IP (that is, IP01) is not set in the control data received as a result of the analysis (No in S530), the first lighting control device 21 through the second communication unit 220, the second lighting control device Control data is transmitted to (22) (S550).

Here, the control data for a plurality of specific IPs may be transmitted from the central control apparatus 100. In this case, each lighting control apparatus stores only control data for which its IP is set, and performs a corresponding operation. The set control data is transmitted to the lighting control device at a position opposite to the direction of the central control device 100 among the adjacent lighting control devices.

In addition, the second lighting control device 22 performs the steps S520 to S550 in the same manner. Here, the steps S520 to S550 are performed in the same way to the lighting control device 2n provided in the last lighting device. Accordingly, by receiving control data specifying a specific IP transmitted from the central control apparatus 100 from the lighting control apparatuses in the adjacent lighting apparatuses, the connection distance between the lighting apparatuses can be extended (for example, the distance between the lighting apparatuses is about 500M). Can be.

 6 is a flowchart illustrating a process of performing a schedule function in a method of controlling lighting according to an embodiment of the present invention.

First, the central control apparatus 100 receives control data (ie, production data) produced through software of a computer through the first communication unit 110, and stores the received production data in the storage unit 150. Here, the direction data represents the direction information based on the schedule information, the schedule information refers to the time and date information for the direction data to operate, the direction information refers to information for performing the lighting and blinking operation of the illumination.

Next, the operation manager 130 of the central control apparatus 100 transmits control data (that is, directing data) to the first lighting control apparatus 21 so that the directing data can operate according to a set schedule (S610). .

Next, the first communication unit 210 of the first lighting control device 21 receives the control data, and the operation processor 230 analyzes the transmitted control data to recognize that the transmitted control data is the directing data. Then, the received control data is stored in the storage 250 (S620).

Next, the second communication unit 220 of the first light control device 21 transmits control data to the second light control device 22 (S630). Here, the second lighting control device 22 performs the steps S620 and S630 in the same manner, and performs the same steps S620 and S630 to the lighting control device 2n provided in the last luminaire. .

Next, the operation manager 130 of the central control apparatus 100 checks whether or not the time for the presentation data to operate in cooperation with the schedule checker 140 (S640), and the operation time of the presentation data is determined. When it arrives, the control data for requesting the execution of the operation of the presentation data is transmitted (S650).

Next, when the first communication unit 210 of the first lighting control device 21 receives the control data, the operation processor 230 checks whether the corresponding presentation data exists in the storage unit 250 (S660).

As a result of the check, when the corresponding presentation data exists, the operation processor 230 performs the corresponding operation so that the lighting is turned on and blinks according to the schedule (S670).

Next, the second communication unit 220 of the first lighting control device 21 transmits the control data (that is, data for requesting the execution of the operation of the directing data) to the second control device 22 (S680). Here, the second lighting control device 22 performs the steps S650 to S680 in the same way, and performs the steps S650 to S670 in the same way to the lighting control device 2n provided in the last luminaire. . Thus, each lighting fixture can perform a variety of lighting production based on the stored production data.

As illustrated in FIG. 7, the graphical user interface (GUI) 700 of Windows Software displaying presentation data according to a schedule may include: a first area 710 for calling and selecting presentation data created based on schedule information; Based on the information of the presentation data selected in the first area 710, information about the direction data selected in the second area 720 and the first area 710, which selects the direction information and schedule information that is operated during the day. Based on the third region 730 selecting the presentation information and the schedule information operated for a week based on the information of the presentation data selected in the first region 710, the production information and schedule operated for one year. A fourth region 740 for selecting information, a fifth region 750 for storing the schedule file of the presentation data according to the selected presentation information, and the schedule information in the first region 710 to the fourth region 740; Schedule of presentation data stored in area 750 And a sixth area 760 including an execution button for storing the file and a cancel button for not storing the schedule file of the presentation data. Here, only one region of the second region 720 to the fourth region 740 may be selected.

For example, if information (ie, number) of the presentation data selected in the first area 710 is written in the blank area 721 (that is, numbers 1 to 7) in the second area 720, one day in the order described The rendering data stored in the lighting control devices is executed.

In addition, the third area 730 is used when a different rendering order is to be made for each Monday through Sunday.

In other words, if the information of the presentation data is described as 1,2,3,4,5,6,7 on Monday, and the information of the presentation data is 2,4,6,1,3,5,7 on Tuesday, Different renderings are performed for each day in the order described.

In addition, the fourth area 740 is used to set the direction differently for each month for one year.

On the other hand, the presentation data based on the stored schedule information made by the Windows software is transmitted to the central control unit 100 via LAN communication and stored, and stored in the storage unit 150 of the central control unit 100 The data is transmitted to each of the lighting control apparatuses 21 to 2n, and the directing data is operated according to the schedule information to perform the directing.

8 is a flowchart illustrating a process of adjusting a white balance of a lighting device in a method of controlling lighting according to an embodiment of the present invention.

First, when control data for requesting white balance adjustment is transmitted from the central control apparatus 100 (S810), the first communication unit 210 of the first lighting control apparatus 21 receives the control data, and the operation processor 230 ) Analyzes the received control data (S820). Here, the control data includes information on the RGB value for matching the white balance of the luminaire.

As a result of the analysis, the operation processor 230 recognizes that the command to adjust the white balance, stores the RGB value included in the control data, and performs the corresponding operation (S830, S840).

For example, the operation processor 230 adjusts the RGB value of the lighting apparatus based on the information on the RGB value included in the control data in order to match the white balance of the lighting apparatus. In this case, the RGB values included in the control data may be set differently, and white balance may be adjusted through color adjustment of each RGB. In addition, the adjusted RGB value is provided to the LED module through the output unit 240 in a PWM voltage (V) adjustment scheme.

Next, the first lighting control device 21 transmits control data to the second lighting control device 22 through the second communication unit 220 (S850).

In addition, the second lighting control device 22 performs the steps S820 to S850 in the same manner. Here, the steps S820 to S850 are performed in the same way to the lighting control device 2n provided in the last lighting device. Thus, the white balance of one or more lighting fixtures may be more easily adjusted through control data requesting the white balance adjustment transmitted from the central control apparatus 100.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. You will understand that. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1 is a view showing a system for controlling lighting according to an embodiment of the present invention.

2 is a block diagram illustrating an internal control apparatus of the central control apparatus in the system for controlling lighting according to an embodiment of the present invention.

3 is a block diagram illustrating an interior of a lighting control device in a system for controlling lighting according to an embodiment of the present invention.

4 is a flowchart illustrating a process of performing IP designation in a method of controlling lighting according to an embodiment of the present invention.

5 is a flowchart illustrating a process of performing a command operation for a specific IP in a method of controlling lighting according to an embodiment of the present invention.

6 is a flowchart illustrating a process of performing a schedule function in a method of controlling lighting according to an embodiment of the present invention.

7 is a diagram illustrating a GUI of Windows Software for displaying presentation data according to a schedule according to an embodiment of the present invention.

8 is a flowchart illustrating a process of adjusting a white balance of a lighting device in a method of controlling lighting according to an embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

100: central control unit 200: light control unit

110,210: first communication unit 120,220: second communication unit

130: operation management unit 140: schedule check unit

230: operation processing unit 240: output unit

150, 250: storage unit 160,260: control unit

Claims (10)

An apparatus for controlling one or more lighting devices, Manage second control data including first control data including schedule information and presentation information of the one or more lighting devices and information on an RGB value for matching white balance of the lighting device, and An operation manager configured to set the first control data and the second control data differently based on IP; A schedule checker which checks execution times of the first control data and the second control data based on the schedule information; And And a communication unit configured to transmit the first control data and the second control data and third control data requesting the execution of the first control data and the second data to the one or more lighting devices based on the execution time. The one or more lighting devices analyze the first control data and the second control data transmitted through the communication unit, check an IP included in the first control data and the second control data, and check the IP with the checked IP. And comparing the previously stored IPs and controlling the lighting to perform an operation according to the first control data and the second control data when the IPs are the same. The method of claim 1, And RGB values included in the second control data are set differently from each other. 3. The method of claim 2, And the at least one lighting device adjusts white balance based on an RGB value included in the second control data. A method of controlling one or more lighting devices, Manage second control data including first control data including schedule information and presentation information of the one or more lighting devices and information on an RGB value for matching white balance of the lighting device, and Differently setting the first control data and the second control data based on IP; Checking execution times of the first control data and the second control data based on the schedule information; And Transmitting the first control data and the second control data and third control data requesting the execution of the first control data and the second data to the one or more lighting devices based on the execution time. The one or more lighting devices analyze the first control data and the second control data transmitted through the communication unit, check an IP included in the first control data and the second control data, and check the IP with the checked IP. Comparing the previously stored IPs and performing an operation according to the first control data and the second control data when the IPs are the same. The method of claim 4, wherein The RGB values included in the second control data are each set differently. The method of claim 5, And the one or more devices adjust white balance based on an RGB value included in the second control data. A communication unit configured to receive first control data including schedule information and presentation information and second control data including information on RGB values for matching white balance from the first device; Analyzing the received first control data and the second control data, checking an IP included in the first control data and the second control data, comparing the checked IP with a pre-stored IP, and the IP is the same. An operation processor configured to perform directing and white balance adjustment according to the first control data and the second control data; And And an output unit for outputting the adjusted RGB value of the white balance. The method of claim 7, wherein And RGB values included in the second control data are set differently from each other. Receiving first control data including schedule information and presentation information and second control data including information on RGB values for matching white balance from the first device; Analyzing the received first control data and the second control data and checking an IP included in the first control data and the second control data; Comparing the checked IP with a pre-stored IP and performing directing and white balance adjustment according to the first control data and the second control data when the IPs are the same; And Outputting the adjusted RGB value of the white balance. The method of claim 9, The RGB values included in the second control data are each set differently.

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