KR20240170896A - Wireless light control system - Google Patents

Abstract

Disclosed is a wireless lighting control system comprising: a plurality of slave lighting devices mapped to a seat layout based on seat information and included in different groups under the control of a master device; an information transmission device acquiring seat information, transmitting mapping request information including the seat information and information on the slave lighting device to a server, receiving mapping completion information from the server, acquiring control pattern information for each group, and transmitting the control pattern information to the slave lighting device; and a master device setting a group of the plurality of slave lighting devices for lighting control, and transmitting control information for each group capable of controlling the plurality of slave lighting devices for each group to the plurality of lighting devices according to a wireless communication method. The plurality of slave lighting devices receive the control information for each group and are controlled by the control information for each group.

Description

{Wireless light control system}

A wireless lighting control system is disclosed. More specifically, a wireless lighting control system capable of remotely controlling a plurality of lighting devices to generate a lighting pattern and improving lighting effects is disclosed.

In general, a lighting device is something that achieves the purpose of lighting by reflecting, refracting, and transmitting light from a light source. Depending on the light distribution, lighting devices can be classified into indirect lighting devices, semi-indirect lighting devices, general diffuse lighting devices, semi-direct lighting devices, and direct lighting devices.

Due to technological advancements, lighting devices are being used for various purposes. For example, lighting devices are used to create media facades. Media facades are lighting devices installed on the exterior walls of buildings to implement media functions.

As another example, lighting devices are used as small cheering tools in sports events or concerts that are held in environments with a certain level of illumination. However, in such environments, it is difficult to create systematic lighting patterns or shapes because multiple lighting devices are individually controlled. In addition, it is not easy to obtain the expected cheering effect by simply using the light sources placed in the lighting devices.

Korean Patent Publication No. 10-2005-0112540 (Title of the invention: Method and system for generating visual effects using a mobile communication terminal, Publication date: December 1, 2005)

A wireless lighting control system capable of generating a lighting pattern by remotely controlling multiple lighting devices in groups and improving lighting effects is disclosed.

In order to solve the above-described problem, a wireless lighting control system according to an embodiment includes: a plurality of slave lighting devices which are mapped to a seating chart based on seat information and are included in different groups according to the control of the master device; an information transmission device which obtains seat information, transmits mapping request information including the seat information and information on the slave lighting devices to a server, receives mapping completion information from the server, and obtains group-specific control pattern information and transmits the obtained information to the slave lighting devices; and a master device which sets groups of the plurality of slave lighting devices for lighting control and transmits group-specific control information capable of controlling the plurality of slave lighting devices by group to the plurality of lighting devices by wireless communication method, wherein the plurality of slave lighting devices receive the group-specific control information and are controlled by the group-specific control information.

Additionally, the group-specific control information may include control information that causes the plurality of slave lighting devices to have at least one of different lighting color, lighting brightness, lighting on time, lighting off time, and lighting blink speed for each of the set groups.

Additionally, the information transmission device can receive seat information from a user of the information transmission device.

In addition, the information transmission device includes a photographing unit that scans a barcode included in an admission ticket, and can obtain seat information by recognizing the barcode scanned by the photographing unit and obtain group-specific control pattern information and transmit the obtained information to the slave lighting device.

In addition, the master device displays a lighting control screen including a seating chart capable of controlling the plurality of slave lighting devices by group, wherein the seating chart includes one or more of the set groups, sets control information for at least one group included in the seating chart, and transmits the set control information to the plurality of lighting devices by a wireless communication method.

Multiple lighting devices can be controlled by group, and various lighting patterns can be created for sports events or concerts, and the cheering effect can be enhanced through various lighting patterns.

Lighting effects can be enhanced by generating lighting patterns by utilizing the resources of the lighting device and the resources of smart devices linked to the lighting device.

FIG. 1 is a diagram illustrating the configuration of a wireless lighting control system according to one embodiment.
FIG. 2 is a drawing illustrating the configuration of the first lighting device illustrated in FIG. 1.
FIG. 3 is a diagram illustrating the configuration of the first smart device illustrated in FIG. 1.
FIG. 4 is a flowchart illustrating the operation of a wireless lighting control system according to one embodiment.
FIG. 5 is a drawing illustrating a lighting control screen displayed through a second smart device in steps S455 and S460 of FIG. 4.
FIG. 6 is a drawing illustrating a lighting control screen displayed through the first smart device in steps S485 to S495 of FIG. 4.

The advantages and features of the present invention, and the methods for achieving them, will become clear with reference to the embodiments described in detail below together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and the embodiments are provided only to make the disclosure of the present invention complete and to fully inform a person having ordinary skill in the art to which the present invention belongs of the scope of the invention, and the present invention is defined only by the scope of the claims.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with a meaning that can be commonly understood by a person of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries shall not be ideally or excessively interpreted unless explicitly specifically defined.

The terminology used herein is for the purpose of describing embodiments only and is not intended to limit the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the text. The terms "comprises" and/or "comprising" as used herein do not exclude the presence or addition of one or more other components in addition to the components mentioned.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. In the drawings, like reference numerals represent like components.

FIG. 1 is a diagram illustrating the configuration of a wireless lighting control system (1) according to one embodiment.

Referring to FIG. 1, a wireless lighting control system (1) according to one embodiment includes a plurality of lighting devices (100A, 100B, 100C, 100D), a plurality of smart devices (200A, 200B, 200C, 200D), a network (300), and a server (400). The plurality of lighting devices (100A, 100B, 100C, 100D) include a first lighting device (100A) operating as a master and a second lighting device (100B, 100C, 100D) operating as a slave. The first lighting device (100A) is electrically connected to the first smart device (200A), and the second lighting device (100B, 100C, 100D) is electrically connected to the second smart device (200B, 200C, 200D). Hereinafter, for convenience of explanation, the first lighting device (100A) and the second lighting devices (100B, 100C, 100D) will be collectively referred to as “lighting devices (100)”, and the first smart device (200A) and the second smart devices (200B, 200C, 200D) will be collectively referred to as “smart devices (200)”.

The lighting device (100) refers to a device that reflects, refracts, or transmits light from a light source to fix or protect the light source. The lighting device (100) may have various shapes. For example, the lighting device (100) may have a rod shape so that the user can hold it. As another example, the lighting device (100) may have a shape that can be worn on a part of the user's body.

According to an embodiment, the lighting device (100) can detect an electrical connection with the smart device (200). When an electrical connection with the smart device (200) is detected, the lighting device (100) transmits and receives data and/or signals with the smart device (200). For example, the lighting device (100) transmits a confirmation request signal to the smart device (200) to confirm whether a lighting control application is installed in the smart device (200). For another example, the lighting device (100) receives group-by-group control pattern information for lighting devices operating as slaves from the smart device (200). A more specific description of the configuration of the lighting device (100) will be described later with reference to FIG. 2.

The smart device (200) can be electrically connected to the lighting device (100). The smart device (200) electrically connected to the lighting device (100) transmits and receives data and/or signals with the lighting device (100). For example, the smart device (200) receives a confirmation request signal for confirming whether a lighting control application is installed from the lighting device (100), and transmits group-by-group control pattern information for lighting devices operating as slaves to the lighting device (100).

The smart device (200) may also communicate with the server (400) via the network (300). According to one embodiment, the smart device (200) transmits at least one of an application request signal requesting a lighting control application, a mapping request signal, and a content request signal to the server (400), and receives at least one of the lighting control application, a mapping completion signal, and the requested content from the server (400).

Meanwhile, when the installation of the lighting control application received from the server (400) is completed, the smart device (200) configures and displays a lighting control screen. When the lighting control screen is displayed, the user can set a group for lighting devices operating as slaves, set a control pattern for each group, or input various commands or information related to lighting control.

The smart device (200) as described above may include communication devices such as smartphones and tablets. However, the smart device (200) is not necessarily limited to the communication devices as exemplified, and any communication device having a wireless communication function and a display function may be included in the smart device (200). A more specific description of the configuration of the smart device (200) will be described later with reference to FIG. 3.

The server (400) communicates with the lighting device (100) and the smart device (200) via the network (300). For example, the server (400) receives an application request signal from the smart device (200) and transmits a lighting control application to the smart device (200) in response thereto. For another example, the server (200) receives a mapping request signal from the smart device (200) and transmits a mapping completion signal to the smart device (200). The mapping request signal is a signal requesting mapping of identification information of the lighting device (100), identification information of the smart device (200), and seat information of the user. For another example, the server (400) receives a content request signal from the smart device (200) and transmits the requested content to the smart device (200). Examples of the content include text, images, and videos.

Above, referring to FIG. 1, the configuration of a wireless lighting control system (1) according to an embodiment has been described. In FIG. 1, a case in which a lighting control application is distributed to a smart device (200) by a server (400) has been described as an example. According to another embodiment, the lighting control application may be distributed to a smart device (200) by a lighting device (100).

FIG. 2 is a drawing showing the configuration of the lighting device (100) illustrated in FIG. 1.

Referring to FIG. 2, the lighting device (100) includes a lighting unit (110), a wired communication unit (120), a control unit (130), and a wireless communication unit (140).

The lighting unit (110) includes one or more light sources. As the light source, a light emitting diode (LED) may be used as an example. The lighting unit (110) may include LEDs of different colors. For example, it may include at least one of a red LED, a green LED, a blue LED, and a white LED. By mixing the light emitted from each of these LEDs, a wide range of colors can be created. The mixed color is determined based on the ratio of the intensities of the light emitted from each LED, and the intensities of the light emitted from each LED are proportional to the driving current of each LED. That is, by controlling the driving current of each LED, the color of the light output from the lighting unit (110) can be controlled. A plurality of LEDs may be arranged in a dot shape, and by selectively lighting them, specific phrases or images can be displayed.

In the above description, LED was used as an example as a light source of the lighting unit (110), but the type of light source is not limited to LED. According to another embodiment, an organic light emitting diode (OLED) may be used as a light source.

The wired communication unit (120) is responsible for wired communication between the lighting device (100) and the smart device (200). Although not shown in the drawing, the wired communication unit (120) may include a wired communication port. The wired communication port provided in the wired communication unit (120) of the lighting device (100) is electrically connected to the wired communication port provided in the wired communication unit (250) of the smart device (200). When the wired communication port of the lighting device (100) is connected to the wired communication port of the smart device (200), signals and/or data are transmitted and received between the lighting device (100) and the smart device (200). For example, a confirmation request signal for confirming whether a lighting control application is installed is transmitted to the smart device (200), and a response signal thereto is received from the smart device (200).

The wireless communication unit (140) is responsible for wireless communication between the lighting device (100) and other lighting devices. For this purpose, the wireless communication unit (140) can support a wireless communication method. An example of a wireless communication method is ZigBee.

ZigBee is a wireless personal area network standard that allows wireless connection of peripherals operating at 868 MHz, 902-928 MHz, and 2.4 GHz. ZigBee is based on the IEEE 802.15 standard approved by the IEEE-SA. ZigBee allows data to be exchanged at speeds of up to 250 Kbps between peripherals that are typically less than 50 m apart in a wireless personal area network.

In the above description, ZigBee is used as an example of a wireless communication method supported by the wireless communication unit (140), but it is not necessarily limited to this, and the wireless communication unit (140) may support one or more other wireless communication methods in addition to the ones exemplified.

The control unit (130) connects and controls each component of the lighting device (100). For example, the control unit (130) detects whether there is an electrical connection between the lighting device (100) and the smart device (200). If a connection with the smart device (200) is detected, the control unit (130) transmits a confirmation request signal to the smart device (200) to confirm whether the lighting control application is installed.

In addition, the control unit (130) controls the lighting pattern of the lighting unit (110) based on the control pattern information. The control pattern information may include at least one of lighting color, lighting brightness, lighting on time, lighting off time, and lighting blinking speed. The control pattern information as exemplified may be defined in advance or may be directly set by the user.

Above, the configuration of the lighting device (100) illustrated in FIG. 1 has been described with reference to FIG. 2. As illustrated in FIG. 2, the lighting device (100) may omit the power supply. In this case, the lighting device (100) is electrically connected to the smart device (200) and then receives power from the smart device (200) to operate. As another example, the lighting device (100) may further be equipped with a power supply (battery). This power supply may be separated from the lighting device (100) and then replaced with another power supply or charged by power supplied from the outside.

FIG. 3 is a drawing illustrating the configuration of the smart device (200) illustrated in FIG. 1.

Referring to FIG. 3, the smart device (200) includes an input unit (210), a display unit (220), a storage unit (230), a control unit (240), a wired communication unit (250), and a wireless communication unit (260).

The input unit (210) receives various information and/or commands from the user. For example, control pattern information for the lighting unit (110) and/or the display unit (220), an operation standby command, a lighting control execution command for starting lighting control, and a lighting control termination command for terminating the lighting control being executed may be received. For this purpose, the input unit (210) may include at least one of a joystick, a mouse, a keypad, and a keyboard. At this time, the keyboard may be implemented in hardware or in software.

The display unit (220) may display a lighting control screen when a lighting control application is driven. According to an embodiment, various information and/or icons may be arranged on the lighting control screen. For example, a seating chart of a location where a user is located, an icon for selecting the user's seat information, a group setting icon for setting a group for a second lighting device and a second smart device, icons corresponding to preset lighting control patterns, an icon for inputting a lighting control execution command, an icon for inputting a lighting control termination command, etc. may be arranged. However, the icons arranged on the lighting control screen are not limited to those illustrated, and the types and arrangement positions of the icons included in the lighting control screen may be implemented so as to be settable by the user.

The display unit (220) can be controlled according to control pattern information. The control pattern information can be selected from predefined control pattern information or directly set by the user.

The storage (230) may include a hard disk drive, an optical disk drive, a magneto-optical disk drive, a non-volatile memory, a volatile memory, or a combination thereof. The storage (230) stores data necessary for the smart device (200) to operate. For example, the storage (230) stores a lighting control application. The lighting control application is an application that can control at least one of the display unit (220) of the smart device (200) and the lighting unit (110) of the lighting device (100). The lighting control application may be implemented as a mobile application and may be distributed by a server (400) through a network (300) or may be distributed by the lighting device (100).

The wired communication unit (250) is responsible for wired communication between the smart device (200) and the lighting device (100). Although not shown in the drawing, the wired communication unit (250) may include a wired communication port. The wired communication port provided in the wired communication unit (250) of the smart device (200) is electrically connected to the wired communication port provided in the wired communication unit (120) of the lighting device (100). When the wired communication port of the smart device (200) is connected to the wired communication port of the lighting device (100), signals and/or data are transmitted and received between the smart device (200) and the lighting device (100). For example, a confirmation request signal for confirming whether a lighting control application is installed is received from the lighting device (100), and a response signal thereto is transmitted to the lighting device (100).

The wireless communication unit (260) is responsible for wireless communication between the smart device (200) and the server (400). To this end, the wireless communication unit (260) may support one or more wireless communication methods. Examples of wireless communication methods include, but are not limited to, Ultra Wide Band (UWB), WiFi, Bluetooth, Bluetooth Low Energy (BLE), ZigBee, Radio Frequency (RF), and Infrared Data Association (IrDA).

The control unit (240) connects and controls each component within the smart device (200). For example, when a confirmation request signal for checking whether a lighting control application is installed is received from the lighting device (100), it is checked whether the application is installed within the smart device (200). If the confirmation result shows that the lighting control application is not installed, the control unit (240) transmits an application request signal to the server (400). Thereafter, when the lighting control application is received from the server (400), the control unit (240) installs the received lighting control application.

After the installation of the lighting control application is completed and the lighting control application is executed, the control unit (240) configures the lighting control screen. The user can input information or data required for lighting control through the lighting control screen, set a group for lighting control, or input a command for lighting control.

FIG. 4 is a drawing illustrating an example of the operation of a wireless lighting control system (1) according to one embodiment.

Before the explanation, it is assumed that the first lighting device (100A) operating as a master and the second lighting device (100B) operating as a slave are located within the wireless control range of the first lighting device (100A).

First, the first lighting device (100A) detects an electrical connection with the first smart device (200A) (S400). Thereafter, the first lighting device (100A) transmits a confirmation request signal to the first smart device (200A) to confirm whether the lighting control application is installed (S405).

The first smart device (200A) checks whether a lighting control application is installed in the first smart device (200A). If the lighting control application is not installed or needs to be updated, an application request signal requesting the lighting control application or an update request signal requesting the update of the lighting control application is transmitted to the server (400) (S410).

The server (400) transmits the requested lighting control application to the first smart device (200A) through the network (300) (S415).

When the lighting control application is installed and executed on the first smart device (200A), a lighting control screen is configured. The lighting control screen is displayed through the display unit (220) of the first smart device (200A).

After this, when the user inputs an operation standby command through the lighting control screen, the input operation standby command is transmitted to the first lighting device (100A) through the wired communication unit (250) (S420).

The first lighting device (100A) transmits the operation standby command received from the first smart device (200A) to the second lighting device (100B) via wireless communication (S425).

The second lighting device (100B) controls the lighting unit (110) based on the operation standby command received from the first lighting device (100A), thereby informing the users that the operation standby command has been received (S430). For example, the light source of the lighting unit (110) is blinked at a certain interval for a certain period of time to inform the user carrying the second lighting device (100B) that the operation standby command has been received.

A user who confirms that a motion standby command has been received connects the second lighting device (100B) to the second smart device (200B). As a result, the second lighting device (100B) detects an electrical connection with the second smart device (200B) (S435).

In this way, when an electrical connection with the second smart device (200B) is detected, the second lighting device (100B) transmits a confirmation request signal to the second smart device (200B) to confirm whether the lighting control application is installed (S440).

Thereafter, the second smart device (200B) checks whether the lighting control application is installed. If the lighting control application is not installed or needs to be updated, the second smart device (200B) transmits an application request signal requesting the lighting control application or an update request signal requesting the update of the lighting control application to the server (400) (S445).

The server (400) transmits the requested lighting control application to the second smart device (200B) through the network (300) (S450).

When the lighting control application is installed and executed on the second smart device (200B), a lighting control screen is configured. When the user of the second smart device (200B) inputs information on the location where he or she is located through the lighting control screen, a seating chart for the corresponding location can be searched and displayed as shown in FIG. 5 (S455). For example, a seating chart of a sports stadium or concert hall where the user is located is searched and displayed. At this time, the seating chart may be searched from the storage (230) of the second smart device (200B). As another example, the seating chart may be searched from a server (300) and provided to the second smart device (200B).

In the lighting control screen of Fig. 5, the user of the second smart device (200B) can directly input his/her seat information by selecting his/her seat (S460).

Meanwhile, the seat information may be entered automatically. For example, a barcode (2D barcode, 3D barcode) including seat information may be printed on the ticket held by the user of the second smart device (200B). When the user scans the barcode of the ticket using the second smart device (200B), the second smart device (200B) can recognize the barcode and obtain the seat information. To this end, the second smart device (200B) may further include a photographing unit (not shown) for scanning the barcode and obtaining an image. In addition, the second smart device (200B) may further include a barcode recognition program that recognizes the seat information from the image obtained by the photographing unit. In this case, the barcode recognition program may be implemented to be included in the lighting control application.

As another example, an NFC tag that records seat information for each seat may be attached to each seat. When a user sits in his or her seat and brings a second smart device (200B) close to the NFC tag, the second smart device (200B) can obtain seat information from the NFC tag. In this case, when the second smart device (200B) automatically obtains seat information, step S455 of displaying a seat map may be omitted.

After this, when the 'seat selection complete' icon (22) is selected on the lighting control screen of Fig. 5, the control unit (240) of the second smart device (200B) transmits a mapping request signal to the server (400) (S470). The mapping request signal may include identification information of the second lighting device (100B) (e.g., serial number), identification information of the second smart device (200B), and seat information.

The server (400) maps the information included in the mapping request signal to each seat in the seating chart (S475). When identification information is mapped to all seats in the seating chart, the server (400) transmits a mapping completion signal to the first smart device (200A) acting as a master (S480).

After this, a lighting control screen including a seat layout is displayed on the display unit (220) of the first smart device (200A) (S485). The user of the first smart device (200A) can set a group for lighting control by referring to the seat layout (S490). For example, as shown in Fig. 6, the user can set a group for lighting control by drawing a boundary (24) by dragging a specific area of the seat layout.

After setting the group, the user can set control pattern information for each group (S495). The control pattern information may include at least one of control pattern information for the lighting unit (110) and control pattern information for the display unit (220). Examples of the control pattern information for the lighting unit (110) include lighting color, lighting brightness, lighting on time, lighting off time, and lighting blink speed. Examples of the control pattern information for the display unit (220) include screen color, screen brightness, screen display start time, screen blink interval, screen display end time, and identification information of content to be displayed through the screen. The user can set control pattern information by selecting each group. Specifically, when the user selects within the boundary (24) of a given group, menus for setting control pattern information for the corresponding group are displayed, and the user can set control pattern information for the corresponding group using the displayed menus.

After setting the control pattern information for each group and selecting the 'Setting Complete' icon (23), the first smart device (200A) transmits the control pattern information for each group to the first lighting device (100A) (S500).

The first lighting device (100A) transmits group-specific control pattern information to the second lighting device (100B) according to a wireless communication method (S505).

The second lighting device (100B) transmits the group-specific control pattern information received from the first lighting device (100A) to the second smart device (200B). The second smart device (200B) checks the content of the group-specific control pattern information and then determines whether communication with the server (400) is necessary (S515). For example, if the control pattern information of the display unit (220) is checked among the control pattern information and content identification information is included, the second smart device (200B) transmits a content request signal requesting the corresponding content to the server (400) (S520).

The server (400) searches for the content requested by the second smart device (200B) and transmits it to the second smart device (200B) (S525). Thereafter, the server (400) transmits a transmission completion signal to the first smart device (200A) notifying that the content transmission is complete (S530).

After this, when a lighting control execution command is input from a user, the first smart device (200A) transmits the input lighting control execution command to the first lighting device (100A) (S535).

The first lighting control device (100A) transmits a lighting control execution command to the second lighting device (100B) (S540).

The second lighting device (100B) transmits the lighting control execution command received from the first lighting device (100A) to the second smart device (200B) (S545).

Thereafter, the lighting unit (110) of the second lighting device (100B) and the display unit (220) of the second smart device (200B) are controlled (S550, S555) according to the group-specific control pattern information received in the previous step (S505, S510).

Referring to FIGS. 4 to 6, the operation of the wireless lighting control system (1) and the lighting control screen according to one embodiment have been described. Some of the steps illustrated in FIG. 4 may be omitted. For example, if a plurality of second lighting devices are arranged at each seat in the order of identification information (e.g., serial number), the step (S455) of displaying the seat layout on the second smart device (200B) and the step (S460) of the user entering his/her seat information may be omitted.

According to the above-described method, since the lighting unit (110) of the second lighting device (100B, 100C, 100D) and the display unit (220) of the second smart device (200B, 200C, 200D) can be controlled simultaneously by group, the visual cheering effect can be improved compared to the case where only the lighting unit (110) of the plurality of second lighting devices (100B, 100C, 100D) is controlled. In addition, since various contents such as text, images, or videos can be displayed simultaneously through the plurality of second smart devices (200B, 200C, 200D), various types of visual cheering are possible.

The embodiments of the present invention have been described above. In addition to the embodiments described above, the embodiments of the present invention may also be implemented through a medium, for example, a computer-readable medium, including computer-readable code/instructions for controlling at least one processing element of the embodiments described above. The medium may correspond to a medium/medium that enables storage and/or transmission of the computer-readable code.

The computer-readable code may be recorded on a medium, and may also be transmitted via the Internet, which may include, for example, a recording medium such as a magnetic storage medium (e.g., a ROM, a floppy disk, a hard disk, etc.) and an optical recording medium (e.g., a CD-ROM, Blu-Ray, a DVD), and a transmission medium such as a carrier wave. Since the media may be a distributed network, the computer-readable code may be stored/transmitted and executed in a distributed manner. Furthermore, by way of example only, the processing element may include a processor or a computer processor, and the processing element may be distributed and/or contained within a single device.

Although the embodiments of the present invention have been described with reference to the drawings as exemplified above, those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features thereof. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not limiting.

1: Wireless lighting control system
100: Lighting Device
200: Smart Devices
400: Server

Claims (10)

In a smart device controlling at least one cheering lighting device,
Department of Communications; and
A smart device, comprising: a control unit that transmits a mapping request signal for the lighting device and corresponding seat information to a server, and, when a mapping completion signal is received from the server in response to the mapping request signal, transmits preset lighting control-related information to control the lighting device.
In the first paragraph,
The above control unit,
A smart device that, when communication is established with the lighting device through the communication unit, transmits the mapping request signal and transmits the preset lighting control related information to the lighting device.
In the first paragraph,
The above seat information is a smart device that includes the seat information included in the admission ticket held by the audience.
In the third paragraph,
A photographing unit for scanning the identification code of the above admission ticket; and
A smart device including a program that determines the corresponding seat information based on the identification code scanned by the above photographing unit.
In the first paragraph,
The above smart device has an application installed for controlling the lighting device,
The above control unit is a smart device that requests the server to map the identification information of the lighting device with the corresponding seat information through the application.
In the first paragraph,
Further comprising a display unit for displaying a lighting control screen;
A smart device, wherein the preset lighting control related information includes control pattern information related to light emission by group of the lighting device.
In Article 6,
A smart device, wherein the above control pattern information includes at least one of a light color, a light brightness, a light turning on time, a light turning off time, and a light blinking speed.
In Article 6,
The above control unit,
A smart device that transmits a content request signal to the server and receives content from the server when the control pattern information further includes content identification information to be displayed through the display unit.
A method for controlling at least one cheering lighting device performed on a smart device,
A step of transmitting a mapping request signal for the lighting device and corresponding seat information to the server; and
A method comprising the step of transmitting preset lighting control related information to control the lighting device when a mapping completion signal is received in response to the mapping request signal from the server.
A smart device that transmits a mapping request signal for at least one cheering lighting device and seat information to a server, and when a mapping completion signal is received from the server in response to the mapping request signal, transmits preset lighting control-related information to control the lighting device; and
A lighting control system including a lighting device that controls the output of lighting based on the preset lighting control-related information when group-specific control pattern information is received from the smart device.