Lighting device integrated control method and lighting device integrated control system

JP2025029136A5Pending Publication Date: 2026-06-23HYBE CO LTD

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
HYBE CO LTD
Filing Date
2024-12-04
Publication Date
2026-06-23

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Abstract

To provide an integrated control method and system capable of collectively controlling all lighting devices regardless of the operating environments of the lighting devices.SOLUTION: A method for integrated control of multiple lighting devices by a directing application executed by at least one processor of a director terminal includes the steps of sending a default control signal to the multiple lighting devices instructing them to execute, pause or terminate a lighting pattern based on a basic library stored in the lighting devices, and implementing integrated lighting control processing based on the sent default control signal, and the integrated lighting control processing controls each of the multiple lighting devices to operate collectively with a predetermined lighting pattern such that the multiple lighting devices as a whole form a specific lighting pattern shape.SELECTED DRAWING: Figure 5
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Description

[Technical field]

[0001] The present invention relates to a plurality of lighting devices (hereinafter referred to as lighting) and a method and system for integrated control thereof. More specifically, the present invention relates to a plurality of lighting devices and a method and system for integrated control thereof that can collectively control all of the lighting devices regardless of the operating environment of each of the plurality of lighting devices. [Background technology]

[0002] "Lighting device" means a device carried by or provided to an individual that emits light in various patterns.

[0003] Such lighting devices are provided to users who are viewing a performance or exhibition in a space where many people gather, such as a theater, concert hall, and / or museum, either carried by the user or fixed to the seat of each user. The lighting devices can be used for purposes such as performance guidance, movement instructions, or aesthetic support in such spaces.

[0004] In particular, the lighting devices provided to each individual can operate differently depending on the specific location in the space or the individual to whom they are provided. Recently, a production method that utilizes this to remotely control the light emission of multiple lighting devices to realize a specific shape or pattern that has been planned in advance over a wide area in the space in which the multiple lighting devices are arranged has been used in various fields.

[0005] However, in the conventional technology field, when the operating environment is not in place and various data required for the performance is not pre-stored on the lighting device due to certain factors (e.g., insufficient advance preparation by the user and / or a system error), there is a problem that it is difficult to remotely control the lighting device.

[0006] Generally, such lighting devices can be controlled based on different control protocols depending on the main performer (eg, a specific musician) of the performance, the manufacturing method, and the like.

[0007] For example, a first lighting device group used in a performance by a first musician and a second lighting device group used in a performance by a second musician may control their lighting operations according to different control protocols.

[0008] However, as described above, situations may arise where a unified presentation is required by collectively controlling a plurality of lighting device groups based on different control protocols.

[0009] For example, when the first musician and the second musician perform a joint performance, i.e., when the first lighting device group and the second lighting device group are mixed, the first lighting device group and the second lighting device group each use a different control protocol, but it may be necessary to perform a unified performance for the collaboration.

[0010] However, the multiple lighting device groups require a control console for each lighting device group that performs control in accordance with a control protocol, which poses a problem that the same number of control consoles are required as there are different control protocols.

[0011] Another reason for this is the increased need for external factors such as various cue signs and LTCs for simultaneous control between the multiple control consoles, which increases the required costs and labor. In addition, there is a problem of reduced flexibility in terms of being able to dynamically add lighting device groups using new control protocols to create a unified presentation.

[0012] Therefore, there is a need to develop and implement new technologies to overcome the problems discussed above. [Prior art documents] [Patent documents]

[0013] [Patent Document 1] Korean Patent No. 10-1970358 Summary of the Invention [Problem to be solved by the invention]

[0014] The present invention has been devised to solve the above-mentioned problems, and aims to provide a plurality of lighting devices and an integrated control method and system thereof that can collectively control all the lighting devices regardless of the operating environment of each lighting device.

[0015] Specifically, the present invention aims to provide a plurality of lighting devices and an integrated control method and system thereof that supports remote control based on a generic event code even for lighting devices for which initial settings for remote control of the plurality of lighting devices have not been completed.

[0016] It is a further object of the present invention to provide a method and system for integrated control of multiple lighting devices that supports collective simultaneous control of a group of multiple lighting devices controlled based on different control protocols.

[0017] However, the technical objectives that the present invention and one embodiment of the present invention are to achieve are not limited to the above technical objectives, and other technical objectives may exist. [Means for solving the problem]

[0018] One embodiment of the present invention relates to a method for integrated control of multiple lighting devices by a directing application executed by at least one processor of a director terminal, and includes the steps of sending a default control signal to the multiple lighting devices to instruct them to execute, pause or terminate a lighting pattern based on a basic library stored in the lighting devices, and executing an integrated lighting control process in accordance with the sent default control signal, where the integrated lighting control process controls the multiple lighting devices to generally adopt a specific lighting pattern by collectively operating each of the multiple lighting devices with a predetermined lighting pattern.

[0019] In this case, the basic library is a library that is stored by default in the firmware stage of the plurality of lighting devices and operates based on the default control signal.

[0020] The method further includes the step of performing initial settings for at least some of the plurality of lighting devices.

[0021] The initial setting also includes an event registration process that defines a control protocol for controlling the lighting device, and a pairing process that stores performance preparation data in the lighting device.

[0022] The performance preparation data also includes at least one of a library for setting a specific lighting pattern for the lighting device, and a scenario for setting a specific lighting pattern for the lighting device for a predetermined period of time.

[0023] The method further includes a step of transmitting a custom control signal to a plurality of setting-type lighting devices instructing the execution, interruption or termination of a lighting pattern based on the performance preparation data stored in the setting-type lighting device for which the initial setting has been completed, and a step of performing integrated lighting control processing in accordance with the transmitted custom control signal.

[0024] The method further includes the steps of transmitting a combined control signal to command execution, interruption or termination of a lighting pattern based on the basic library stored in the lighting device and the performance preparation data stored in the setting-type lighting device, and performing integrated lighting control processing in response to the transmitted combined control signal.

[0025] Also, the combined control signal includes the default control signal and the custom control signal.

[0026] In addition, the step of performing integrated lighting control processing in response to the combined control signal includes, when the lighting device that receives the combined control signal is the setting-type lighting device, first applying a custom control signal within the combined control signal to control the light emission of the setting-type lighting device.

[0027] Meanwhile, a method for integrated control of multiple lighting devices according to one embodiment of the present invention is a method for integrated control of multiple lighting devices by at least one processor module of a central server, comprising the steps of receiving a request to send a lighting device control signal for multiple lighting device groups controlled based on different control protocols from a director's terminal, sending the requested lighting device control signal to the multiple lighting device groups, and performing integrated lighting control processing according to the sent lighting device control signal, wherein the lighting device control signal is a control signal that instructs execution, interruption or termination of a lighting pattern based on at least one of the multiple lighting device groups, libraries and scenarios stored in the lighting devices.

[0028] In this case, the step of transmitting the lighting device control signal to the group of the plurality of lighting devices includes a step of transmitting an integrated protocol control signal instructing execution, interruption or termination of a light emission pattern based on integrated control data stored in the lighting device, and the integrated protocol control signal is a lighting device control signal transmitted and received based on an integrated protocol, which is a third control protocol that provides unified control rules for the group of the plurality of lighting devices.

[0029] In addition, the integration protocol control signal includes at least one control signal from a default integration control signal that commands the execution, interruption or termination of a lighting pattern based on an integration basic library stored in the lighting device, and a custom integration control signal that commands the execution, interruption or termination of a lighting pattern based on integration performance preparation data stored in the lighting device.

[0030] Also, transmitting the lighting device control signals to the plurality of lighting device groups may include obtaining converted control signals by detecting control signals corresponding to the lighting device control signals in each of the different control protocols.

[0031] In addition, the step of transmitting the lighting device control signals to the plurality of lighting device groups further includes transmitting the converted control signals detected for the different control protocols to the plurality of lighting device groups via each control protocol matching the converted control signal.

[0032] A system for integrated control of multiple lighting devices according to an embodiment of the present invention includes at least one memory in which an integrated lighting control application is stored, and at least one processor that reads the integrated lighting control application stored in the memory and executes a method for integrated control of multiple lighting devices, wherein commands of the integrated lighting control application include steps of: transmitting a default control signal to a plurality of lighting devices instructing the execution, interruption or termination of a light emitting pattern based on a basic library stored in the lighting devices, and performing integrated lighting control processing in accordance with the transmitted default control signal; transmitting a custom control signal to a plurality of setting type lighting devices instructing the execution, interruption or termination of a light emitting pattern based on performance preparation data stored in a setting type lighting device, and performing integrated lighting control processing in accordance with the transmitted custom control signal; transmitting a combined control signal to the plurality of lighting devices instructing the execution, interruption or termination of a light emitting pattern based on the basic library stored in the lighting devices and the performance preparation data stored in the setting type lighting devices, and performing integrated lighting control processing in accordance with the transmitted combined control signal; and transmitting a combined control signal to the plurality of lighting devices instructing the execution, interruption or termination of a light emitting pattern based on the basic library stored in the lighting devices and the performance preparation data stored in the setting type lighting devices, and performing integrated lighting control processing in accordance with the transmitted combined control signal. Among the instructions for executing steps for performing processing, an instruction for executing at least one step is included.

[0033] In this case, the command of the unified lighting control application further includes at least one command to execute a step of transmitting a unified protocol control signal, which is transmitted and received based on a unified protocol providing a unified control agreement for a plurality of lighting device groups controlled based on different control protocols, to the plurality of lighting device groups and performing a unified lighting control process according to the transmitted unified protocol control signal, and a step of transmitting a converted control signal for each of the different control protocols detected based on a target control signal to be transmitted to the plurality of lighting device groups and performing a unified lighting control process according to the transmitted converted control signal.

[0034] A lighting device according to one embodiment of the present invention includes at least one storage unit for storing a basic library, at least one communication unit, at least one light source unit, and at least one processor, wherein the processor controls the communication unit to receive performance preparation data, controls the storage unit to store the received performance preparation data, controls the communication unit to receive a lighting device control signal, reads out at least one of the libraries and scenarios corresponding to the received lighting device control signal from the basic library or performance preparation data in the storage unit, and controls the light source unit to perform a light emission pattern operation according to at least one of the read libraries and scenarios.

[0035] In this case, the processor controls the communication unit to receive a lighting device control signal including at least one of a custom control signal, a default control signal, a binding control signal, an integrated protocol control signal, and a conversion control signal. Effect of the Invention

[0036] A method and system for integrated control of multiple lighting devices according to one embodiment of the present invention supports centralized control of all lighting devices regardless of the operating environment of each of the multiple lighting devices, thereby facilitating simultaneous control of all associated lighting devices without additional efforts to perform separate processes or unify each lighting device having a different operating environment.

[0037] In addition, the multiple lighting devices and the integrated control method and system thereof according to one embodiment of the present invention support remote control based on a generic event code even for lighting devices for which the initial settings for remotely controlling the multiple lighting devices have not been completed. Therefore, even if the operating environment is incomplete, such as various data for remote control not being pre-stored on at least some of the lighting devices due to a specific factor (e.g., insufficient advance preparation by the user and / or a system error), unified remote control can be performed for all lighting devices including the lighting devices, and all the lighting devices can be smoothly involved in the planned processing.

[0038] Furthermore, the multiple lighting devices and the integrated control method and system thereof according to one embodiment of the present invention support simultaneous control of multiple lighting device groups controlled based on different control protocols, so that even when multiple lighting device groups following different control protocols are mixed, unified processing based on the light emission operations of the multiple lighting device groups can be easily and accurately implemented with only one control console, thereby significantly reducing the costs and labor required. In addition, new lighting device groups based on yet another control protocol can be easily and flexibly added and included in the performance production.

[0039] However, the effects obtained by the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood from the following description. [Brief description of the drawings]

[0040] [Figure 1] 1 is a conceptual diagram of a multiple lighting device integrated control system according to an embodiment of the present invention; [Diagram 2] FIG. 2 is an internal block diagram of a terminal according to an embodiment of the present invention. [Diagram 3] FIG. 2 is a diagram illustrating an example of a method for transmitting lighting device control signals from a central server based on a broadcast method according to an embodiment of the present invention. [Figure 4] 1 is an internal block diagram of a lighting device according to an embodiment of the present invention; [Diagram 5] 1 is a flowchart illustrating a method for integrated control of a plurality of lighting devices based on a basic library according to an embodiment of the present invention. [Figure 6] 1 is an example of a specific pattern designed for the integrated lighting control process according to an embodiment of the present invention. [Figure 7] 1 is a conceptual diagram illustrating a method for integrating and controlling a plurality of lighting device groups based on different control protocols according to an embodiment of the present invention; [Figure 8] 1 is a conceptual diagram illustrating a method for integrating and controlling a plurality of lighting device groups based on different control protocols according to an embodiment of the present invention; DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0041] The present invention can be modified in various ways and can have various embodiments, and a specific embodiment is shown in the drawings and described in detail in the detailed description. The effects and features of the present invention, and the method of achieving them, will become apparent with reference to the embodiments described in detail below with the drawings. However, the present invention is not limited to the embodiments disclosed below, and can be realized in various forms. In the following embodiments, terms such as first and second are not used in a limiting sense, but are used to distinguish one component from another component. Furthermore, singular expressions include plural expressions unless the context clearly indicates otherwise. Furthermore, terms such as include or have mean the presence of a feature or component described in the specification, and do not preclude the possibility that one or more other features or components are added. Furthermore, in the drawings, the size of the components may be exaggerated or reduced for the convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for the convenience of explanation, so the present invention is not necessarily limited to those shown in the drawings.

[0042] Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. When describing with reference to the drawings, the same or corresponding elements are given the same reference numerals, and duplicate descriptions thereof will be omitted.

[0043] FIG. 1 is a conceptual diagram of an integrated control system for multiple lighting devices according to one embodiment of the present invention.

[0044] Referring to FIG. 1, an integrated control system 1000 for multiple lighting devices (hereinafter, the integrated lighting control system) according to one embodiment of the present invention can provide, for each of the multiple lighting devices, an integrated control service for multiple lighting devices (hereinafter, the integrated lighting control service) that can collectively control all of the lighting devices regardless of the operating environment.

[0045] In this embodiment, an integrated lighting control system 1000 that provides an integrated lighting control service may include a terminal 100, a central server 200, a lighting device 300, and a network 400 (Network).

[0046] In this case, the terminal 100 , the central server 200 , and the lighting device 300 may be connected via a network 400 .

[0047] Here, the network 400 according to the present embodiment refers to a connection structure that enables information exchange between each node such as the terminal 100, the central server 200 and / or the lighting device 300. Examples of such a network 400 include, but are not limited to, a 3GPP (registered trademark) (3rd Generation Partnership Project) network, a LTE (Long Term Evolution) network, a WIMAX (World Interoperability for Microwave Access) network, the Internet, a LAN (Local Area Network), a Wireless LAN (Wireless Local Area Network), a WAN (Wide Area Network), a PAN (Personal Area Network), a Bluetooth (registered trademark) network, a satellite broadcasting network, an analog broadcasting network, and a DMB (Digital Multimedia Broadcasting) network.

[0048] For a more effective description of the implementation of the integrated lighting control service according to an embodiment of the present invention, some terms used in the present embodiment will be defined below.

[0049] A "library" in one embodiment of the present invention is preset data for causing the lighting device 300 to operate in a specific light emission pattern (i.e., a specific light emission form), and can include library identification information and light emission pattern information.

[0050] Specifically, in this embodiment, the library may include identification information (e.g., an identification number and / or library name) that identifies the corresponding library, and lighting pattern information that provides a specific lighting pattern preset for the corresponding library.

[0051] Here, the “lighting pattern information” according to this embodiment may include the lighting device 300’s light emission, color, brightness and / or dynamic effect parameters, and the lighting device 300 may be operated according to the setting values ​​for each parameter (hereinafter, the lighting pattern setting values).

[0052] In this case, the dynamic effect in this embodiment may be data that realizes a specified effect by dynamically changing the setting values ​​of other parameters (in this embodiment, the presence or absence of light emission, color and / or brightness) in the light emission pattern information.

[0053] For example, the dynamic effects may include a blink effect in which the lighting device 300 is set to emit light differently for each time period within a predetermined time period and the blink effect is performed quickly, and a fade in / out effect in which the light emission hue is set to be different for each time period and the light gradually becomes darker or brighter.

[0054] In this embodiment, at least one such library may be created, stored, and managed.

[0055] For example, the library can be realized with multiple libraries, such as a first library in which library identification information and lighting pattern information (lighting pattern setting value) are set to "identification number 0001 / light on / first color / first brightness / first dynamic effect" and a second library in which library identification information and lighting pattern information (lighting pattern setting value) are set to "identification number 0002 / light on / second color / second brightness / second dynamic effect."

[0056] In this embodiment, the library may be generated to include a library for each seat.

[0057] Here, each seat library in this embodiment may have the same library identification information corresponding to each seat where the lighting device 300 is placed within a specific space (e.g., a performance hall), or may have different lighting pattern information depending on the library.

[0058] That is, the library may be generated to include a library for each seat that controls the lighting device 300 to operate with different light emission patterns depending on the position of the seat where the lighting device 300 is placed.

[0059] For example, a first library may be generated to include a library for each seat having: first library - first seat - first lighting pattern information; and first library - second seat - second lighting pattern information.

[0060] In this way, in one embodiment of the present invention, based on the library for each seat described above, the lighting devices 300 arranged at each seat can be operated collectively with a lighting device-specific light emission pattern, thereby implementing integrated lighting control processing that creates a specific shape as a whole.

[0061] Meanwhile, in an embodiment of the present invention, a scenario is data that is preset so that the lighting device 300 operates in a specific lighting pattern for a predetermined period of time, and may include scenario identification information and lighting pattern information.

[0062] Specifically, in this embodiment, the scenario may include identification information that identifies the scenario (e.g., an identification number and / or a scenario name, etc.) and light emission pattern information (hereinafter, scenario pattern information) that provides a specific light emission pattern already established in the scenario.

[0063] At this time, in this embodiment, a scenario may be generated to include a scenario for each seat.

[0064] Here, the scenario of each seat in this embodiment and the scenario identification information corresponding to each seat where the lighting device 300 is placed in a specified space (e.g., a performance hall, etc.) are the same, but the scenario pattern information according to the scenario may mean scenarios that are set to be different from each other.

[0065] That is, the scenario may be generated to include seat scenarios that control the lighting device 300 to operate in different light emission patterns depending on the position of the seat where the lighting device 300 is placed.

[0066] For example, the first scenario may be generated to include scenarios for each seat that are first scenario-first seat-first scenario pattern information and first scenario-second seat-second scenario pattern information.

[0067] Through this, in one embodiment of the present invention, an integrated lighting control process can be implemented in which different lighting devices 300 arranged at each seat operate collectively with device-specific light emission patterns based on the scenario of each seat to create a specific shape as a whole.

[0068] In addition, in one embodiment of the present invention, the performance preparation data refers to data that predefines various lighting patterns for each seat where the lighting device 300 is placed for the integrated lighting control processing, and may refer to data that should be pre-stored in the lighting device 300 before the performance begins.

[0069] In this embodiment, the performance preparation data may be generated from at least one of the aforementioned libraries and / or scenarios.

[0070] In this embodiment, the integrated lighting control process may refer to a lighting device 300-based presentation method in which multiple different lighting devices 300 each operate collectively with a predetermined light emission pattern to produce a specific shape as a whole.

[0071] Also, in this embodiment, the lighting device control signal may mean a control signal that controls the light emitting operation of the lighting device 300 based on data stored in the lighting device 300 (in this embodiment, the basic library and / or performance preparation data, etc.).

[0072] Hereinafter, the terminal 100, the central server 200, and the lighting device 300 which realize the integrated lighting control system 1000 will be described in detail with reference to the accompanying drawings.

[0073] -Terminal (100: Terminal)- The terminal 100 according to an embodiment of the present invention may be a predetermined computing device in which a lighting control application (hereinafter, application) that provides an integrated lighting control service is installed.

[0074] Here, the application according to this embodiment is divided into a directing application and a support application.

[0075] In this case, the directing application and the support application may be a single application or may be applications for performing different functions for different users.

[0076] In other words, the directing application and the cheering application may be distinguished from each other in that they operate functionally by being granted different permissions depending on a single application or a user's (in this embodiment, a director's or user's) account.

[0077] Returning again to this embodiment, the terminal 100 on which the above-mentioned application is installed may include a director terminal 100-1 used by a director who plans a performance, and a cheering pole terminal 100-2 used by a user who watches the performance and uses the lighting device 300.

[0078] In this embodiment, the director terminal 100-1 may be installed with the aforementioned directing application, and the cheering application may be installed in the cheering stick terminal 100-2.

[0079] Here, the director terminal 100-1 and the cheering stick terminal 100-2 are used to distinguish users in this embodiment, and their components and functions may be the same.

[0080] However, in this embodiment, the cheering rod terminal 100-2 can perform various functional operations for the integrated lighting control service by matching and linking with a predetermined lighting device 300 on a one-to-one basis.

[0081] Specifically, in this embodiment, the cheering rod terminals 100-2 can be mapped one-to-one to each other based on an identification code that identifies the terminal 100 that identifies each cheering rod terminal 100-2 and a device identification code that identifies each lighting device 300, and can be paired and operated.

[0082] Returning again, from a hardware perspective, the terminal 100 may include a mobile type computing device and / or a desktop type computing device on which an application is installed, and the like.

[0083] Here, the mobile type computing device may be a mobile device such as a smartphone or a tablet PC on which an application is installed.

[0084] For example, mobile-type computing devices may include smart phones, mobile phones, digital broadcasting devices, personal digital assistants (PDAs), portable multimedia players (PMPs), tablet PCs, and the like.

[0085] In addition, the desktop computing device may include a device installed with a program for executing an integrated lighting control service based on wired / wireless communication, such as a fixed desktop PC with an application installed, a laptop computer, an ultrabook, or other personal computer.

[0086] Furthermore, according to the present embodiment, the terminal 100 may further include a predetermined server computing device that provides an integrated lighting control service environment.

[0087] FIG. 2 is an internal block diagram of the terminal 100 according to an embodiment of the present invention.

[0088] 2, from a functional point of view, the terminal 100 may include a memory 110, a processor assembly 120, a communication processor 130, an interface unit 140, an input system 150, a sensor system 160, and a display system 170. Such components may be configured to be included within the housing of the terminal 100.

[0089] In particular, the memory 110 stores an application 111, which may store one or more of various application programs, data, and instructions for providing an integrated lighting control service environment.

[0090] That is, the memory 110 may store instructions, data, etc. that may be used to generate an integrated lighting control services environment.

[0091] The memory 110 may also include a program area and a data area.

[0092] Here, the program area in this embodiment links the operating system (OS) for starting the terminal 100 and the functional elements, and the data area may store data generated in conjunction with the use of the terminal 100.

[0093] Additionally, memory 110 may include at least one or more non-transitory computer-readable storage media and transitory computer-readable storage media.

[0094] For example, the memory 110 may be implemented using various storage devices such as a ROM, an EPROM, a flash drive, a hard drive, etc., and may also be implemented as a web storage that performs the storage function of the memory 110 over the internet.

[0095] The processor assembly 120 may include at least one or more processors capable of executing instructions of the applications 111 stored in the memory 110 to perform various operations for generating an integrated lighting control services environment.

[0096] According to this embodiment, the processor assembly 120 can control the overall operation of the components via the application 111 in the memory 110 to provide an integrated lighting control service.

[0097] Such a processor assembly 120 may be a system-on-chip (SOC) suitable for the terminal 100 including a central processing unit (CPU) and / or a graphics processing unit (GPU), and can execute an operating system (OS) and / or application programs stored in the memory 110 and control each component installed in the terminal 100.

[0098] Furthermore, the processor assembly 120 can internally communicate with each component via a system bus, which can include one or more predetermined bus structures including a local bus.

[0099] Additionally, the processor assembly 120 may perform functions using at least one of application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), controllers, micro-controllers, microprocessors, and other electrical units for performing functions.

[0100] The communications processor 130 may include one or more devices for communicating with external devices. Such communications processor 130 may communicate over a wireless network.

[0101] In particular, the communications processor 130 can communicate with the terminal 100 that stores content sources for implementing the integrated lighting control services environment, and can communicate with various user input components, such as a controller that receives user input.

[0102] In this embodiment, the communication processor 130 can transmit and receive various data related to the unified lighting control service to and from other terminals 100, external servers and / or devices, and the like.

[0103] Such a communication processor 130 can wirelessly transmit and receive data with at least one of a base station, an external terminal 100, and an arbitrary server on a mobile communication network constructed via a communication device capable of performing a technical standard or communication method for mobile communication (e.g., LTE (Long Term Evolution), LTE-A (Long Term Evolution-Advanced), 5G NR (New Radio), WiFi (registered trademark), or a short-range communication method, etc.).

[0104] The sensor system 160 can include various sensors such as an image sensor 161, a position sensor (IMU: Integral Measurement Unit, 163), an audio sensor 165, a distance sensor, a proximity sensor, and a contact sensor.

[0105] Here, the image sensor 161 can capture images and / or videos of the physical space surrounding the terminal 100.

[0106] In an embodiment, the image sensor 161 can capture and acquire images related to the integrated lighting control service (eg, projected processed images, etc.).

[0107] In addition, the image sensor 161 can be arranged on the front and / or rear of the terminal 100 to capture images in the direction in which it is arranged, and can physically capture images of the space through a camera arranged facing outside the terminal 100.

[0108] Such an image sensor 161 may include an image sensor device and an image processing module. Specifically, the image sensor 161 may process still or moving images obtained by an image sensor device (e.g., CMOS or CCD).

[0109] Furthermore, the image sensor 161 can use an image processing module to process still images or moving images acquired via the image sensor device, extract necessary information, and transmit the extracted information to the processor.

[0110] The image sensor 161 may be a camera assembly including at least one camera.

[0111] In this case, the camera assembly may include a general camera that captures images in the visible light band, and may further include a special camera such as an infrared camera or a stereo camera.

[0112] In addition, the above-mentioned image sensor 161 may be included in the terminal 100 and operate according to this embodiment, or may be included in an external device (e.g., an external server and / or device, etc.) and operate by interworking based on the communication processor 130 and / or the interface unit 140.

[0113] The position sensor 163 may detect at least one of the motion and acceleration of the terminal 100. For example, the IMUT 163 may be implemented as a combination of various position sensors such as an accelerometer, a gyroscope, and a magnetometer.

[0114] In addition, the IMU 163 may work in conjunction with a position communication processor 130 such as a GPS of the communication processor 130 to recognize spatial information regarding the physical space around the terminal 100.

[0115] The audio sensor 165 can recognize sounds around the terminal 100 .

[0116] In particular, the audio sensor 165 may include a microphone capable of detecting voice input of a user using the terminal 100 .

[0117] In this embodiment, the audio sensor 165 may receive audio data from the user required for the integrated lighting control service.

[0118] The interface unit 140 may communicatively connect the terminal 100 to one or more other devices.

[0119] In particular, the interface unit 140 may include wired and / or wireless communication devices compatible with one or more different communication protocols.

[0120] Through the interface unit 140, the terminal 100 may be connected to various input / output devices.

[0121] For example, the interface unit 140 can be connected to an audio output device such as a headset port or a speaker to output audio.

[0122] For example, the description has been given on the assumption that the audio output device is connected via the interface unit 140, but the present embodiment may also be such that the audio output device is installed inside the terminal 100.

[0123] Also, for example, the interface unit 140 may be connected to an input device such as a keyboard and / or a mouse to obtain user input.

[0124] For example, the above description is based on the assumption that a keyboard and / or mouse is connected via the interface unit 140, but the present embodiment may also be configured such that the keyboard and / or mouse are installed inside the terminal 100.

[0125] The interface unit 140 may be configured to include at least one of a wired / wireless headset port, an external charger port, a wired / wireless data port, a memory card port, a port for connecting a device equipped with an identification module, an audio I / O (Input / Output) port, a video I / O (Input / Output) port, an earphone port, a power amplifier, an RF circuit, a transceiver, and other communication circuits.

[0126] The input system 150 may detect user input (eg, gestures, voice commands, button presses, or other types of input) associated with the integrated lighting control service.

[0127] Specifically, the input system 150 may include a predetermined button, a touch sensor, and / or an image sensor 161 for receiving user motion input.

[0128] The input system 150 may also be connected to an external controller via the interface unit 140 to receive user input.

[0129] The display system 170 may output various information related to the integrated lighting control service as graphic images.

[0130] In this embodiment, the display system 170 may display various user interfaces, including a library generation interface and / or a scenario generation interface.

[0131] Display system 170 may include at least one of a liquid crystal display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), a flexible display, a three-dimensional (3D) display, and an electronic ink (e-ink) display.

[0132] Here, the components may be disposed within a housing of the terminal 100, and the user interface may include a touch sensor 173 on a display 171 configured to receive user touch input.

[0133] Specifically, the display system 170 may include a display 171 that outputs images and a touch sensor 173 that detects a user's touch input.

[0134] For example, the display 171 may be implemented as a touch screen by forming a layered structure with the touch sensor 173 or by being integrally formed with the touch sensor 173 .

[0135] The touch screen may function as a user input unit to provide an input interface between the terminal 100 and a user, and may also provide an output interface between the terminal 100 and a user.

[0136] Furthermore, according to the present embodiment, the terminal 100 may further execute at least some of the functional operations executed by the central server 200 and / or the lighting device 300, which will be described later.

[0137] - Central server 200 Meanwhile, the central server 200 according to an embodiment of the present invention may execute a series of processes for providing an integrated lighting control service.

[0138] Specifically, in this embodiment, the central server 200 can provide the integrated lighting control service by exchanging data with an external device, such as a terminal 100 and / or a lighting device 300, required to drive a lighting device control process in the external device.

[0139] In this embodiment, the central server 200 may provide an environment in which the application 111 may run on an external device (eg, a mobile type computing device and / or a desktop type computing device).

[0140] To this end, the central server 200 may include application programs, data, and / or commands for the application 111 to operate, and may transmit and receive data to and from the external device based thereon.

[0141] In addition, in this embodiment, the central server 200 can provide a signal that can realize a predetermined light emitting operation in an external device (eg, the lighting device 300, etc.).

[0142] To this end, the central server 200 may include application programs, data and / or commands for implementing the light emitting operations, and may transmit and receive data based thereon to and from the external device.

[0143] Additionally, in this embodiment, the central server 200 may generate a library as previously described.

[0144] Furthermore, in this embodiment, the central server 200 can generate a scenario as described above.

[0145] Additionally, in this embodiment, the central server 200 may generate performance preparation data as previously described.

[0146] In addition, in this embodiment, the central server 200 can distribute the generated performance preparation data.

[0147] Specifically, in this embodiment, the central server 200 can distribute the co-star preparation data to multiple lighting devices 300 in conjunction with terminals 100 (in this embodiment, the director terminal 100-1 and / or the cheering stick terminal 100-2) etc.

[0148] More specifically, in this embodiment, the central server 200 can receive a request for distribution of the performance preparation data to a plurality of lighting devices 300 from the director's terminal 100-1.

[0149] Furthermore, in this embodiment, the central server 200 can transmit performance preparation data requested for distribution to a plurality of cheering rod terminals 100-2.

[0150] In this embodiment, each of the cheering rod terminals 100-2 can be matched with each of the lighting devices 300 on a one-to-one basis and linked to the corresponding lighting device 300.

[0151] In this embodiment, each of the multiple cheering rod terminals 100-2 is associated one-to-one with each of the multiple lighting devices 300 based on a terminal 100 identification code that identifies each cheering rod terminal 100-2 and a device identification code that identifies each of the multiple lighting devices 300, and can be paired with each other to operate.

[0152] Therefore, the plurality of cheering rod terminals 100-2 can provide the performance preparation data received from the central server 200 to the lighting device 300 suitable for each cheering rod terminal 100-2.

[0153] At this time, in this embodiment, the plurality of cheering stick terminals 100-2 can provide performance preparation data to a lighting device 300 compatible with each cheering stick terminal 100-2 based on a Bluetooth pairing method or the like.

[0154] Therefore, the lighting devices 300 can receive, store, and manage performance preparation data corresponding to the seat where each lighting device 300 is located.

[0155] Thus, in this embodiment, the central server 200 can distribute the performance preparation data to multiple lighting devices 300 .

[0156] FIG. 3 is a diagram illustrating a method for transmitting lighting device control signals in a broadcast manner in the central server 200 according to an embodiment of the present invention.

[0157] Also, referring to FIG. 3, in this embodiment, the central server 200 can send lighting device control signals as described above to a plurality of lighting devices 300 to implement an integrated lighting control process.

[0158] Specifically, in this embodiment, the central server 200 can receive a request from the director's terminal 100-1 to distribute lighting device control signals (in this embodiment, custom control signals, default control signals, combined control signals, integrated protocol control signals, and / or converted control signals, etc.) to multiple lighting devices 300.

[0159] In addition, in this embodiment, the central server 200 can transmit the requested lighting device control signals to a plurality of lighting devices 300 .

[0160] In this embodiment, the central server 200 may be connected to at least one repeater R to smoothly transmit the lighting device control signals to a plurality of lighting devices 300 .

[0161] Here, each of the at least one repeater R according to the present embodiment can transmit a predetermined data packet (a lighting device control signal in the present embodiment) to a lighting device 300 adjacent to the repeater based on a broadcasting method.

[0162] For reference, the broadcast method may be a one-to-many communication method in which a predetermined data packet is transmitted to the entire network to which the source host belongs, without separately specifying a receiver.

[0163] In general, when using a unicast method rather than a broadcast method, the central server 200 must transmit a data packet (a control signal in this embodiment) to multiple recipients (a plurality of lighting devices 300 in this embodiment) multiple times, which may result in a decrease in network efficiency due to duplicate transmission of the same packet. In addition, when using a unicast method rather than a broadcast method, the central server 200 must receive an ack message corresponding to reception of the transmitted data packet (a control signal in this embodiment) from each of the multiple recipients (the lighting devices (300) in this embodiment), which may cause a deterioration in communication conditions and thus hinder smooth data communication.

[0164] Therefore, in one embodiment of the present invention, the central server 200 can transmit the lighting device control signal to the plurality of lighting devices 300 using a one-to-many communication broadcast method in which a data packet (in this embodiment, the lighting device control signal) is transmitted to the entire network to which the central server host belongs without separately designating a recipient, in cooperation with at least one repeater R as described above.

[0165] That is, in this embodiment, the central server 200 transmits the lighting device control signal to the multiple lighting devices 300 based on a broadcast method, thereby minimizing communication loss of the control signal and minimizing communication synchronization errors between the multiple lighting devices 300, thereby improving communication efficiency.

[0166] Returning again, at least one repeater R performing data transmission based on the broadcast scheme as described above can be included directly in the central server 200 or realized as a device separate from the central server 200 and can perform the functional operations as described above.

[0167] In the following description, the at least one relay R is implemented in a central server 200, but the present disclosure is not limited thereto.

[0168] Subsequently, in this embodiment, the plurality of lighting devices 300 that receive the lighting device control signal from the central server 200 can perform light emission control in accordance with the received lighting device control signal.

[0169] Specifically, in this embodiment, the multiple lighting devices 300 can perform light emission control based on the lighting device control signal by controlling the light source unit of each lighting device 300 according to a light emission pattern based on the received lighting device control signal.

[0170] Accordingly, the central server 200 according to an embodiment of the present invention can implement an integrated lighting control process based on the lighting device control signals in a small and fast manner.

[0171] Meanwhile, in this embodiment, the central server 200 may store and manage various application programs, commands and / or data for implementing an integrated lighting control service.

[0172] In this embodiment, the central server 200 can store and manage at least one or more libraries, a basic library, an integrated basic library, a scenario, performance preparation data, integrated performance preparation data, lighting device control signals, and / or various user interfaces.

[0173] Meanwhile, referring further to FIG. 1, in this embodiment, the central server 200 as described above may be realized by a predetermined computing device including at least one processor module (210: Processor Module) for data processing, at least one communication module (220: Communication Module) for data exchange with external devices, and at least one database module (230: Database Module) for storing various applications, data, and / or commands for providing an integrated lighting control service.

[0174] Here, the database module 230 may store at least one of an operating system (OS), various application programs, data, and commands for providing an integrated lighting control service.

[0175] Furthermore, the database module 230 may include a program area and a data area.

[0176] Here, the program area in this embodiment can be linked between the operating system (OS) that starts the server and the functional elements, and the data area can store data that is generated in response to the use of the server.

[0177] In this embodiment, such database module 230 may be various storage devices such as ROM, RAM, EPROM, flash drive, hard drive, etc., or may be a web storage that performs the storage function of the database module 230 over the Internet.

[0178] Furthermore, the database module 230 may be a recording medium that is detachable from the server.

[0179] Meanwhile, the processor module 210 can control the overall operation of each of the above-mentioned units to implement an integrated lighting control service.

[0180] The processor module 210 may be a system-on-chip (SOC) suitable for a server including a central processing unit (CPU) and / or a graphics processing unit (GPU), and can execute an operating system (OS) and / or application 111 programs stored in the database module 230, and can control each component installed in the server.

[0181] Additionally, the processor module 210 may be implemented using at least one of ASICs (application specific integrated circuits), DSPs (digital signal processors), DSPDs (digital signal processing devices), PLDs (programmable logic devices), FPGAs (field programmable gate arrays), controllers, micro-controllers, microprocessors, and other electrical units for performing functions.

[0182] In the above description, it has been described that the central server 200 according to one embodiment of the present invention performs the functional operations as described above. However, various embodiments of the present invention may be possible, such as at least a portion of the functional operations performed by the central server 200 according to this embodiment being performed by an external device (e.g., the terminal 100 and / or the lighting device 300, etc.), and at least a portion of the functional operations performed by the external device being further performed by the central server 200.

[0183] - Lighting device (300: Lighting device) The lighting device 300 according to an embodiment of the present invention can perform light emitting operations under the control of the integrated lighting control system 1000 .

[0184] Here, the lighting device 300 according to the present embodiment may refer to a device that is carried by an individual or provided to an individual and emits light in various patterns. The lighting device 300 may be carried by a user who is watching a performance in a given space such as a performance hall, or may be fixed to each seat of the user.

[0185] Specifically, in this embodiment, the lighting device 300 can store and manage various data required for integrated lighting control processing (in this embodiment, a basic library, performance preparation data, an integrated basic library and / or integrated performance preparation data, etc.).

[0186] Additionally, in this embodiment, the lighting device 300 is capable of receiving lighting device control signals as previously described.

[0187] In addition, in this embodiment, the lighting device 300 can perform a light emitting operation according to the received lighting device control signal and the various stored data.

[0188] FIG. 4 is an internal block diagram of a lighting device 300 according to an embodiment of the present invention.

[0189] In more detail, referring to FIG. 4, in this embodiment, the lighting device 300 may include a first communication unit 310, a storage unit 320, a second communication unit 330, a protocol processing unit 340, a timing adjustment unit 350, a light source unit 360 and a processor 370.

[0190] Specifically, in this embodiment, the first communication unit 310 can receive performance preparation data and / or integrated performance preparation data from the terminal 100.

[0191] The first communication unit 310 may include a BLE module or a wireless communication module using the IEEE 802.15.4 standard, but is not limited thereto, and the first communication unit 310 may receive the performance preparation data and / or the integrated performance preparation data via a wired connection.

[0192] In one embodiment of the present invention, the lighting device 300 may receive and store performance preparation data and / or integrated performance preparation data in advance at a location other than the performance venue (e.g., a home, etc.), or may receive and store the data at the performance venue.

[0193] In addition, in this embodiment, the storage unit 320 can store and manage various data required for the integrated lighting control service (in this embodiment, a basic library, performance preparation data, an integrated basic library and / or integrated performance preparation data, etc.).

[0194] In addition, in this embodiment, the second communication unit 330 can receive the lighting device control signal from the central server 200 (and / or the repeater R).

[0195] In this case, the second communication unit 330 can transmit and receive data with the central server 200 (and / or repeater) (R) using RF (Radio Frequency) communication such as Bluetooth, BLE (Bluetooth Low Energy), WiFi, ZigBee, UWB, etc.

[0196] In addition, in this embodiment, the protocol processor 340 can determine the type of information received by the first communication unit 310 and / or the second communication unit 330 .

[0197] At this time, if the received information is a control message (ie, a lighting device control signal in this embodiment), a retransmission packet, or a sync packet, the protocol processor 340 can transmit it to a timing adjuster 350 .

[0198] Then, the timing adjuster 350 can adjust the operation timing of the lighting device 300 based on the sequence of each of the control messages included in the received control message, retransmission packet, or sync packet.

[0199] In FIG. 4, the timing adjustment unit 350 is described as a separate configuration, but this is merely an example and may be included in the configuration of the processor 370 according to the present embodiment.

[0200] In addition, in this embodiment, the light source unit 360 may emit light of a specific color according to the information stored in the storage unit 320 and the control of the processor 370, or may perform light-emitting operations such as blinking or adjusting brightness.

[0201] The light source unit 360 may be configured with an LED (Light Emitting Device), but this is merely one example, and may be realized in any form that is made of a specific luminescent material and can perform a specified light emitting operation.

[0202] Additionally, in this embodiment, the processor 370 may control the overall operation of the lighting device 300 .

[0203] In this embodiment, the processor 370 can control the light emitting operation of the light source unit 360 in response to various data (in this embodiment, basic library, performance preparation data, integrated basic library and / or integrated performance preparation data, etc.) stored in the storage unit 320 and a lighting device control signal received via the second communication unit 330.

[0204] The processor 370 can then determine which libraries and / or scenarios to execute within the various data based on the received lighting device control signals.

[0205] That is, the processor 370 may determine which of a given library and / or scenario to play by analyzing received lighting device control signals.

[0206] The processor 370 may then control the light source unit 360 to emit light according to the determined library and / or scenario.

[0207] In particular, in this embodiment, the processor 370 can read out a lighting pattern corresponding to the library and / or scenario identification information included in the lighting device control signal from the storage unit 320, and control the light source unit 360 to output the read out lighting pattern.

[0208] Meanwhile, according to the present embodiment, the lighting device 300 may further execute at least a part of the functional operations executed by the terminal 100 and / or the central server 200 described above.

[0209] In this embodiment, the lighting device 300 may further include the sensor system 160 as described above, and may further perform various functional operations based on the sensor system 160.

[0210] - A method for integrated control of multiple lighting devices based on a basic library In one embodiment of the present invention, a method is disclosed for supporting light emission control for a lighting device 300 even when event registration or pairing with the lighting device 300 is incomplete due to certain factors (e.g., insufficient advance preparation by a user and / or a system error).

[0211] For this reason, each of the lighting devices 300 according to an embodiment of the present invention can store at least one basic library on the firmware side.

[0212] Here, the basic library according to one embodiment of the present invention may refer to a default library that is basically stored in the self-storage unit 320 of the lighting device 300 and operates according to an external control signal (a lighting device control signal including a general-purpose event code in this embodiment) without pairing with a specific terminal 100 (in this embodiment, the cheering pole terminal 100-2) for receiving and storing separate event registration (i.e., control protocol definition) or performance preparation data for the lighting device 300.

[0213] In this embodiment, such a basic library may be, for example, a library that realizes a relatively simple light emission pattern such as turning the light emission of the lighting device 300 on / off or fading in / out.

[0214] Meanwhile, in one embodiment of the present invention, at least a portion of the plurality of lighting devices 300 may be setting-type lighting devices for which initial setting has been completed, and at least a portion of the remaining lighting devices may be basic-type lighting devices for which initial setting has not been completed.

[0215] Here, the initial setting according to the present embodiment may refer to a process of registering an event and / or storing performance preparation data for the lighting device 300.

[0216] Specifically, in this embodiment, the setting type lighting device may be 1) a lighting device 300 for which an event registration has been performed.

[0217] Here, the event registration according to the present embodiment may refer to a functional operation that defines a control protocol for controlling the lighting device 300 .

[0218] That is, in the present embodiment, the setting type lighting device can control the light emission of the light source unit 360 according to a lighting device control signal according to a predefined control protocol of the corresponding lighting device 300.

[0219] In this embodiment, the setting type lighting device may be 2) a lighting device 300 in which performance preparation data is stored.

[0220] Specifically, in this embodiment, after the event registration is completed, the setting-type lighting device can execute pairing with the cheering rod terminal 100-2 that matches the setting-type lighting device.

[0221] In addition, the setting type lighting device may receive, store, and manage predetermined performance preparation data through the executed pairing.

[0222] In this embodiment, the setting type lighting device can perform Bluetooth pairing with a specific cheering rod terminal 100-2 to receive specific performance preparation data, and can store and manage the received performance preparation data in the storage unit 320.

[0223] Meanwhile, in this embodiment, the basic lighting device may be a lighting device 300 in which event registration and / or storage of performance preparation data as described above has not been completed.

[0224] Meanwhile, in this embodiment, each of the plurality of lighting devices 300 may perform a light emitting operation in a manual operation mode in which the light source unit 360 is controlled according to a user's operation, or may perform a light emitting operation in a performance operation mode in which the light source unit 360 is controlled according to a lighting device control signal received from the outside (in this embodiment, the lighting device control signal is received in a broadcasting manner from the central server 200).

[0225] In the present embodiment, each of the plurality of lighting devices 300 may automatically switch to a performance operation mode and control the light source unit 360 to perform a light emitting operation when a lighting device control signal is detected while operating based on the manual operation mode.

[0226] Hereinafter, a method for an embodiment of the present invention in which a directing application 111 executed by at least one processor of a director terminal 100-1 controls a plurality of lighting devices 300 in an integrated manner based on a basic library will be described in detail with reference to the accompanying drawings.

[0227] In one embodiment of the present invention, at least one or more processors of the director terminal 100-1 can execute at least one or more directing applications 111 stored in at least one or more memories 110 or can operate in a background state.

[0228] In this case, the at least one processor operates to execute the commands of the directing application 111 to perform the method of providing the above-mentioned integrated lighting control service, which will be briefly described as being executed by the directing application 111.

[0229] FIG. 5 is a flowchart illustrating a method for integrated control of a plurality of lighting devices 300 based on a basic library according to an embodiment of the present invention.

[0230] Referring to FIG. 5, in this embodiment, a directing application 111 executed by at least one processor of the director's terminal 100-1 or operating in background mode can transmit a custom control signal to a performance preparation database (S101).

[0231] Here, the custom control signal in this embodiment may refer to a lighting device control signal that instructs execution / pause / termination of at least one library and / or scenario included in the performance preparation data stored in the lighting device 300.

[0232] That is, in this embodiment, the directing application 111 can transmit the above-mentioned custom control signal to the plurality of lighting devices 300 and perform lighting control based on the library and / or scenario in the performance preparation data stored in each of the plurality of lighting devices 300.

[0233] Specifically, in this embodiment, the directing application 111 can communicate with the central server 200 to transmit such custom control signals to a plurality of lighting devices 300 .

[0234] More specifically, in this embodiment, the directing application 111 may execute a transmission request for the custom control signal to the central server 200 .

[0235] The central server 200 may communicate with at least one repeater R to transmit the custom control signals to the lighting devices 300 .

[0236] In this embodiment, the central server 200 can transmit the custom control signal to the lighting devices 300 in a broadcasting manner.

[0237] Furthermore, if a unicast method is used instead of a broadcast method, the central server 200 must transmit the data packet to be transmitted (in this embodiment, the lighting device control signal) multiple times to multiple recipients (in this embodiment, the lighting devices 300), which may result in a decrease in network efficiency due to duplicate transmission of the same packet.

[0238] Furthermore, when using the unicast method instead of the broadcast method, the central server 200 must receive ack messages corresponding to receipt of the transmitted data packet (in this embodiment, the lighting device control signal) from a large number of recipients (in this embodiment, each of the lighting devices 300), which may deteriorate the communication conditions and hinder smooth data communication.

[0239] Therefore, in one embodiment of the present invention, the central server 200 can transmit a predetermined lighting device control signal to the multiple lighting devices 300 using a one-to-many communication broadcast method in which the central server 200 works in conjunction with a repeater R to transmit a data packet (in this embodiment, a lighting device control signal) to the entire network to which its host belongs without separately designating a recipient.

[0240] Therefore, in this embodiment, the central server 200 can minimize communication leakage for the lighting device control signals transmitted, as well as minimize communication synchronization errors between the multiple lighting devices 300, thereby improving communication efficiency.

[0241] Returning again, in this embodiment, the directing application 111 may transmit custom control signals to multiple lighting devices 300 in a broadcast manner via interaction with the central server 200 (and / or repeater R).

[0242] In this case, in the present embodiment, if the lighting device 300 that receives the custom control signal is a setting type lighting device, the setting type lighting device can perform a light emitting operation according to the received custom control signal.

[0243] On the other hand, in this embodiment, if the lighting device 300 that receives the custom control signal is a basic lighting device, the basic lighting device may receive the custom control signal, but may not perform a corresponding light-emitting operation.

[0244] That is, in this embodiment, the directing application 111 can use the custom control signal to control the emission of a plurality of setting-type lighting devices for which initial setting (i.e., in this embodiment, event registration and / or performance preparation data storage) has been completed.

[0245] Next, in this embodiment, the rendering application 111 performs integrated lighting control processing in accordance with the transmitted custom control signal (S103).

[0246] FIG. 6 is an example of a particular shape designed for integrated lighting control processing according to one embodiment of the present invention.

[0247] In other words, referring to FIG. 6, the performance application 111 in this embodiment may perform integrated lighting control processing in which a plurality of setting-type lighting devices are operated collectively with a specialized lighting pattern based on the transmitted custom control signal, to produce a specific shape (SS) as a whole.

[0248] In this case, in the present embodiment, each of the plurality of setting type lighting devices that have received the custom control signal may control the light emitting operation of each light source unit 360 based on the received custom control signal.

[0249] Specifically, in this embodiment, the setting-type lighting device can detect a library and / or scenario that matches the received custom control signal based on the performance preparation data stored in the storage unit 320.

[0250] For example, when the received first custom control signal is a first library execution signal, the setting-type lighting device may read out a first library in the performance preparation data stored in the storage unit 320. As another example, when the received second custom control signal is a first scenario execution signal, the setting-type lighting device may read out a first scenario in the performance preparation data stored in the storage unit 320.

[0251] At this time, for example, the setting type lighting device can read out a library and / or a scenario corresponding to the custom control signal based on predetermined identification information (in this embodiment, library identification information and / or scenario identification information) indicated by the received custom control signal.

[0252] In addition, in this embodiment, the setting type lighting device can control the light emission operation of the light source unit 360 according to a light emission pattern corresponding to the detected library and / or scenario.

[0253] In this embodiment, the setting type lighting device can control the light emission operation of the light source unit 360 according to the light emission pattern information of the detected library, and may also control the light emission operation of the light source unit 360 according to the light emission pattern information of the detected scenario (hereinafter, scenario pattern information).

[0254] For example, the setting type lighting device can control the light emitting operation of the light source unit 360 based on the color, brightness and / or dynamic effect setting values, whether or not to emit light according to the first light emitting pattern information (e.g., "light on / first color / first brightness / first dynamic effect") of the read first library.

[0255] As another example, the setting type lighting device may control the light emission operation of the light source unit 360 based on the presence or absence of light emission, color, brightness and / or dynamic effect setting values ​​according to the first scenario pattern information of the read first scenario (e.g., "first light emission pattern information of the first library / second light emission pattern information of the second library / first self-emission pattern information", etc.).

[0256] That is, in this embodiment, the performance application 111 can perform integrated lighting control processing based on multiple setting-type lighting devices by transmitting custom control signals to multiple setting-type lighting devices and causing the multiple setting-type lighting devices to perform a collective light-emitting operation through the process described above.

[0257] In this way, the production application 111 stores performance preparation data including at least one library and / or scenario in each of the multiple setting-type lighting devices, and then provides a custom control signal to the multiple setting-type lighting devices instructing execution / interruption / termination of at least one of the libraries and / or scenarios, analyzes the provided custom control signal based on the performance preparation data already stored in each of the multiple setting-type lighting devices, and causes each of the multiple setting-type lighting devices to perform a light emission operation in unison according to the light emission pattern of a predetermined library and / or scenario corresponding to the custom control signal, thereby smoothly performing various preset light emission patterns according to the needs of the director, etc., using the multiple setting-type lighting devices.

[0258] Furthermore, in this embodiment, the directing application 111 can transmit a default control signal based on the basic library (S105).

[0259] Here, the default control signal according to the present embodiment may refer to a lighting device control signal that commands execution / pause / end of the basic library stored in the lighting device 300 .

[0260] In this embodiment, such default control signals can be implemented by including generic event codes that control the basic library described above.

[0261] In particular, in this embodiment, the directing application 111 can transmit default control signals to a plurality of lighting devices 300 in a broadcast manner in conjunction with the central server 200 (and / or the repeater R).

[0262] Here, a detailed description of the method in which the central server 200 in this embodiment transmits a default control signal to a plurality of lighting devices 300 shall be the same as the description of the method in which the central server 200 transmits a custom control signal to a plurality of lighting devices 300 in step S101 described above, and in the following, duplicate descriptions may be summarized or omitted, and the focus will be on the contents that are differentiated from the above-mentioned contents.

[0263] At this time, in this embodiment, the lighting devices 300 that have received the default control signal can perform light emitting operations in accordance with the received default control signal.

[0264] In other words, in one embodiment of the present invention, multiple lighting devices 300 already have at least one basic library stored in their firmware as described above, thereby allowing them to perform basic lighting operations according to default control signals without having to perform separate event registration or pairing.

[0265] That is, in this embodiment, rendering application 111 can perform light emission control using default control signals for all lighting devices 300, regardless of whether the initial settings have been completed or not.

[0266] Next, in this embodiment, the rendering application 111 can perform integrated lighting control processing according to the transmitted default control signal (S107).

[0267] That is, in this embodiment, rendering application 111 can perform integrated lighting control processing for collectively operating a plurality of lighting devices 300 in a predetermined light emission pattern based on the transmitted default control signal.

[0268] Specifically, in this embodiment, each of the lighting devices 300 that receives the default control signal can control the light emitting operation of each light source unit 360 based on the received default control signal.

[0269] More specifically, in this embodiment, the lighting device 300 can detect a basic library that matches the received default control signal from among at least one basic library stored in the storage unit 320 .

[0270] For example, the lighting device 300 may read a first library from among the at least one basic library stored in the storage unit 320 if the received first default control signal is a first basic library execution signal.

[0271] At this time, for example, the lighting device 300 can read out a basic library based on the default control signal based on predetermined identification information (library identification information in this embodiment) indicated by the received default control signal.

[0272] In addition, in this embodiment, the lighting device 300 can control the light emission operation of the light source unit 360 according to the light emission pattern corresponding to the detected basic library.

[0273] For example, the lighting device 300 can control the light emission operation of the light source unit 360 based on the light emission pattern setting value according to the first light emission pattern information (eg, "light emission on" or "light emission off") of the read first basic library.

[0274] That is, in this embodiment, the rendering application 111 transmits default control signals to the multiple lighting devices 300, and causes the multiple lighting devices 300 to collectively perform light emission operations through the process described above. This allows integrated lighting control processing based on the multiple lighting devices 300.

[0275] In this way, the directing application 111 makes it possible to execute light emission control of the lighting device 300 using the basic library that is basically stored in the storage unit 320 of the lighting device 300 without performing separate event registration or pairing. Therefore, even if the initial setting of the lighting device 300 is not performed smoothly due to various reasons (e.g., the user is late for the performance, the performance preparation data cannot be downloaded to the lighting device 300 in advance, or a problem occurs in transmitting data to the lighting device 300 due to a system error), the directing application 111 can perform light emission control using the basic library that is basically stored in the lighting device 300, thereby enabling a lighting device 300 (in this embodiment, a basic lighting device) whose initial setting has not been completed to effectively participate in the planned performance.

[0276] At this time, according to the present embodiment, the production application 111 can operate the plurality of setting type lighting devices and the plurality of basic type lighting devices with different light emission patterns based on the default control signal.

[0277] Specifically, in this embodiment, when the performance preparation data is received through pairing with multiple setting-type lighting devices, the performance application 111 can change the lighting pattern information of one of the basic libraries (hereinafter, the basic library for setting confirmation) already stored in the firmware of the multiple setting-type lighting devices to the lighting pattern information of a specific library (hereinafter, the preparation library for setting confirmation) in the performance preparation data.

[0278] Thereafter, in this embodiment, the rendering application 111 can send a default control signal to all of the plurality of setting type lighting devices and the plurality of basic type lighting devices to execute the setting confirmation basic library.

[0279] In this way, the performance application 111 can cause a plurality of basic lighting devices which receive the default control signal to operate according to a lighting pattern according to the basic library for setting confirmation, and a plurality of setting lighting devices which receive the default control signal to operate according to a lighting pattern according to the preparation library for setting confirmation.

[0280] That is, in this embodiment, the production application 111 changes the lighting pattern information of one of the basic libraries already stored in the multiple setting-type lighting devices (in this embodiment, the basic library for setting confirmation) to the lighting pattern information of one of the libraries in the performance preparation data, and then sends a default control signal to the multiple basic lighting devices and all of the multiple setting-type lighting devices to execute the basic library for setting confirmation.The multiple basic lighting devices then perform lighting operations using the basic library for setting confirmation, and the multiple setting-type lighting devices perform lighting operations using the preparation library for setting confirmation.

[0281] In other words, the performance application 111 transmits a default control signal to a plurality of basic lighting devices and a plurality of setting-type lighting devices to execute a basic library for setting confirmation, and causes the plurality of basic lighting devices and the plurality of setting-type lighting devices to emit light according to different light emission patterns.

[0282] As a result, even if the performance application 111 sends only the default control signal, it can perform the light-emitting operation for all lighting devices 300 without the inoperative lighting devices 300, thereby not spoiling the performance scenery. At the same time, the lighting device 300 that stores performance preparation data (in this embodiment, a setting-type lighting device) can be more clearly distinguished and identified from the lighting device 300 that does not (in this embodiment, a basic-type lighting device) through the light-emitting operation that expresses a striking visual contrast between the lighting device 300 that stores performance preparation data (in this embodiment, a setting-type lighting device).

[0283] Furthermore, in this embodiment, the directing application 111 can transmit a combined control signal including a custom control signal and a default control signal (S109).

[0284] Here, the combination control signal according to the present embodiment may refer to a lighting device control signal that can simultaneously execute execution / pause / end commands for the performance preparation data and the basic library stored in the lighting device 300.

[0285] In this embodiment, such a combined control signal may include a first control signal (i.e., a custom control signal in this embodiment) that instructs lighting control based on performance preparation data stored in the lighting device 300, and a second control signal (i.e., a default control signal in this embodiment) that instructs lighting control based on a basic library stored in the lighting device 300.

[0286] In particular, in this embodiment, the directing application 111 can transmit a combined control signal to a plurality of lighting devices 300 in a broadcast manner in conjunction with the central server 200 (and / or the repeater R).

[0287] At this time, a detailed description of the method in which the central server 200 transmits the default control signal to the plurality of lighting devices 300 is the same as the description of the method in which the central server 200 transmits the custom control signal to the plurality of lighting devices 300 in step S101 described above.

[0288] Furthermore, in this embodiment, the rendering application 111 can perform integrated lighting control processing according to the transmitted combined control signal (S111).

[0289] That is, in this embodiment, the rendering application 111 can perform integrated lighting control processing that causes a plurality of lighting devices 300 to operate collectively according to a predetermined light emission pattern based on the transmitted combined control signal.

[0290] At this time, in this embodiment, if the lighting device 300 that received the combined control signal is a setting type lighting device, the performance application 111 can prioritize the first control signal (i.e., the custom control signal in this embodiment) among the combined control signals to perform a light emitting operation.

[0291] That is, in this embodiment, the setting type lighting device that receives the combination control signal can control the light emitting operation of the light source unit 360 of the setting type lighting device by preferentially applying the first control signal among the received combination control signals.

[0292] On the other hand, in this embodiment, if the lighting device 300 that received the combined control signal is a basic lighting device, the performance application 111 can prioritize the second control signal (i.e., the default control signal in this embodiment) in the combined control signal to perform a light-emitting operation.

[0293] That is, in this embodiment, the basic lighting device that receives the combination control signal can control the light emitting operation of the light source unit 360 of the basic lighting device by preferentially applying the second control signal within the received combination control signal.

[0294] In this way, the performance application 111 can perform collective light emission control for all setting-type lighting devices for which initial setting has been completed and basic-type lighting devices for which initial setting has not been completed using a single lighting device control signal, so that the light emission operations of all lighting devices 300 can be easily and simply controlled simultaneously via a single lighting device control signal (in this embodiment, a combined control signal) without having to send different lighting device control signals to the setting-type lighting devices and the basic lighting devices depending on whether or not initial setting has been completed.

[0295] - A method for integrated control of a group of lighting devices based on different control protocols In general, the lighting device 300 can be controlled based on different control protocols depending on the performance entity (eg, a particular musician) or manufacturing method of the lighting device 300.

[0296] For example, a first lighting device group used in a performance by a first musician and a second lighting device group used in a performance by a second musician may control their light-emitting operations according to different control protocols.

[0297] However, as described above, there may be a situation where a plurality of lighting device groups controlled based on different control protocols must be collectively controlled to realize a unified presentation.

[0298] For example, when a first musician and a second musician perform a joint performance, i.e., when a first lighting device group and a second lighting device group are mixed, the first lighting device group and the second lighting device group may have to execute a unified performance for the joint performance even though they follow different control protocols.

[0299] However, each of the multiple lighting device groups described above requires a control console that performs control in accordance with the control protocol of each lighting device group, which poses the problem that a number of control consoles are required, one for each of the different control protocols.

[0300] Furthermore, this requires external factors such as various cue signs and LTCs for simultaneous control between multiple control consoles, which increases the required costs and labor. In addition, there are limitations that reduce the degree of freedom, such as the ability to dynamically add lighting device groups using new control protocols to create a unified presentation.

[0301] Accordingly, in one embodiment of the present invention, a method is disclosed that can collectively and simultaneously control a group of lighting devices controlled according to different control protocols to provide an integrated lighting control process.

[0302] Hereinafter, a method for integrating and controlling a plurality of lighting device groups based on different control protocols by at least one processor module (210: hereinafter, server processor) of a central server 200 according to one embodiment of the present invention will be described in detail with reference to the accompanying drawings.

[0303] In this regard, in the following embodiment, for the sake of efficient explanation, a plurality of lighting device groups will be described based on a first lighting device group (hereinafter, the first lighting group) and a second lighting device group (hereinafter, the second lighting group), but it is clear that this is not limited to this and the embodiment of the present invention can also be applied when there are a greater number of lighting device groups.

[0304] Furthermore, in the following embodiment, for the sake of efficient explanation, the embodiment is divided and described as follows, but various embodiments may be possible, such as at least some of the embodiments being capable of operating in an organic combination with each other.

[0305] In addition, in the following embodiment, descriptions that overlap with the contents described in the above-mentioned method for integrated control of a plurality of lighting devices 300 based on a basic library may be summarized or omitted.

[0306] 7 and 8 are conceptual diagrams illustrating a method for integrating and controlling a plurality of lighting device groups based on different control protocols according to an embodiment of the present invention.

[0307] <First embodiment: Integrated protocol control signal transmission based on integrated control data> Specifically, referring to Figure 7, the unified protocol control signal in this embodiment may refer to a lighting device control signal transmitted and received based on a third control protocol (hereinafter, the unified protocol) that provides a unified control protocol for a first lighting group and a second lighting group that are controlled based on different control protocols.

[0308] In this embodiment, such integration protocol control signals may include custom integration control signals and / or default integration control signals.

[0309] Here, the custom integrated control signal in this embodiment may mean a lighting device control signal that instructs execution / pause / termination of at least one library and / or scenario included in the integrated performance preparation data stored in the lighting device 300.

[0310] That is, the integrated performance preparation data according to this embodiment may be performance preparation data including at least one library and / or scenario that is executed / interrupted / ended by a custom integrated control signal.

[0311] At this time, each of the lighting devices 300 according to an embodiment of the present invention can store and manage at least one integrated performance preparation data through pairing as described above.

[0312] Meanwhile, the default unified control signal according to the present embodiment may refer to a lighting device control signal that instructs execution / pause / end of the unified basic library stored in the lighting device 300 .

[0313] That is, the integrated basic library according to this embodiment may be at least one basic library that is executed / interrupted / terminated by the default integrated control signal.

[0314] Similarly, in one embodiment of the present invention, each of the plurality of lighting devices 300 can pre-store and manage at least one unified basic library in firmware as described above.

[0315] In addition, the integrated control data in this embodiment may refer to data including the integrated performance preparation data and / or the integrated basic library described above.

[0316] Returning again, specifically in this embodiment, the server processor 210 can transmit the above-mentioned unified protocol control signal to the multiple lighting devices 300 included in the first lighting group and the second lighting group based on a broadcasting method.

[0317] In this embodiment, when the lighting devices 300 are setting-type lighting devices storing integrated performance preparation data, the server processor 210 can transmit an integrated protocol control signal based on the custom integrated control signal.

[0318] Then, the plurality of setting type lighting devices receiving the custom integrated control signal can control the light emitting operation of each light source unit 360 based on the received custom integrated control signal, the detailed description of which is the same as that of step S103 described above.

[0319] That is, in this embodiment, the server processor 210 can send a custom integrated control signal to multiple setting-type lighting devices so that even if the multiple setting-type lighting devices conform to different control protocols, they can perform a collective lighting operation through the process described above using the integrated protocol.

[0320] The server processor 210 can easily realize integrated lighting control processing using a plurality of setting-type lighting devices having mutually different control protocols on one control console (the central server 200 in this embodiment).

[0321] Meanwhile, in this embodiment, the server processor 210 can send unified protocol control signals to the multiple lighting devices 300 based on a default unified control signal.

[0322] In other words, in one embodiment of the present invention, the multiple lighting devices 300 already have at least one unified basic library as described above stored in their firmware, and therefore can perform light-emitting operations according to the default unified control signal without having to perform separate event registration or pairing.

[0323] The lighting devices 300 that have received the default integrated control signal can control the light emitting operation of each light source unit 360 based on the received default integrated control signal.

[0324] That is, in this embodiment, the server processor 210 sends a default integrated control signal to the multiple lighting devices 300, and even if the multiple lighting devices 300 conform to different control protocols, they can be made to emit light collectively in accordance with the process described above using the integrated protocol, thereby enabling integrated lighting control processing using multiple lighting devices 300 having different control protocols to be efficiently performed using only one control console (in this embodiment, the central server 200).

[0325] As described above, the server processor 210 enables multiple lighting groups using different control protocols to be collectively controlled with only one unified protocol control signal, thereby significantly reducing the cost and labor required to collectively control multiple lighting groups, and further enables new lighting device groups based on other control protocols to be easily and flexibly added and participated in an unified lighting control performance.

[0326] <Second embodiment: Transmission of conversion control signal based on each control protocol> Meanwhile, referring to FIG. 8, the converted control signal in this embodiment may mean a lighting device control signal detected in a control signal corresponding to a lighting device control signal (in this embodiment, a custom control signal, a default control signal, and / or a combined control signal, etc.) to be transmitted to multiple lighting devices 300 based on the control protocol of each lighting group.

[0327] That is, in this embodiment, the converted control signal may be a lighting device control signal obtained by detecting a control signal corresponding to a lighting device control signal (hereinafter, a target control signal) to be transmitted to a plurality of lighting devices 300 included in the first lighting group and the second lighting group based on a control protocol for each lighting group.

[0328] Specifically, the directing application 111 according to the present embodiment can execute a request for transmitting target control signals to the central server 200 for a plurality of lighting devices 300 .

[0329] The server processor 210 of the central server 200 that receives a request to send a target control signal can detect a control signal corresponding to the received target control signal (i.e., a converted control signal in this embodiment) from each of a number of control protocols associated with a number of lighting devices 300.

[0330] In this embodiment, the server processor 210 can detect a first converted control signal for a target control signal on a first control protocol for a first lighting group, and can detect a second converted control signal for the target control signal on a second control protocol for a second lighting group.

[0331] In addition, in this embodiment, the server processor 210 can transmit the conversion control signal detected for each lighting group to the multiple lighting devices 300 for each lighting group via the control protocol of each lighting group.

[0332] That is, the server processor 210 can convert the target control signal into a corresponding control signal on the control protocol for each lighting group, and transmit the converted control signal to each of the corresponding lighting devices 300 using the control protocol of each lighting group.

[0333] In this embodiment, the server processor 210 can transmit a first converted control signal detected on a first control protocol of a first lighting group for a target control signal to a first lighting group via the first control protocol, and can transmit a second converted control signal detected on a second control protocol of a second lighting group for a target control signal to a second lighting group via the second control protocol.

[0334] In this embodiment, the server processor 210 may transmit the conversion control signal to the lighting devices 300 in a broadcasting manner.

[0335] In this way, the server processor 210 automatically converts the target control signal to be sent to the multiple lighting devices 300 into an optimal form corresponding to each control protocol related to the multiple lighting devices 300, and uses this to send lighting device control signals instructing the multiple lighting devices 300 to perform light emission operations via each control protocol, thereby making it possible to easily send target control signals to the corresponding multiple lighting devices 300 on a single control console (in this embodiment, the central server 200) even when multiple lighting groups controlled based on different control protocols are mixed.

[0336] This allows the server processor 210 to more easily realize unified processing based on a plurality of lighting devices 300, while improving the precision of collective simultaneous control and enhancing the degree of completion.

[0337] As described above, the multiple lighting devices 300 and the integrated control method and system thereof according to one embodiment of the present invention support centralized control of all the lighting devices 300 regardless of the operating environment of each of the multiple lighting devices 300. As a result, all related lighting devices 300 can be easily controlled simultaneously without having to perform separate processing for each lighting device 300 having a different operating environment or without making additional efforts to unify them.

[0338] Furthermore, the multiple lighting devices 300 and the integrated control method and system thereof according to one embodiment of the present invention support remote control based on a generic event code for multiple lighting devices 300 and for lighting devices 300 for which initial settings for remote control have not been completed. Therefore, even if the construction of the operating environment has not been completed, such as various data for remote control not being pre-stored on at least some of the lighting devices 300 due to a specific factor (e.g., insufficient advance preparation by the user and / or a system error), unified remote control can be performed for all lighting devices 300 including the lighting devices 300, thereby enabling all lighting devices 300 to smoothly participate in the planned performance.

[0339] In addition, the multiple lighting devices 300 and the integrated control method and system thereof according to one embodiment of the present invention support simultaneous control of multiple lighting device groups controlled based on different control protocols, so that even when multiple lighting device groups following different control protocols are mixed, unified processing based on the light emission operations of the multiple lighting device groups can be easily and accurately performed using only one control console, thereby significantly reducing the costs and efforts required therefor, and further allowing new lighting device groups based on other control protocols to be easily and flexibly added and participated in the corresponding processing.

[0340] Meanwhile, the present invention described above may be realized in the form of program instructions that can be executed by various computer components and recorded on a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floptical disks, and hardware devices specially configured to store and execute program instructions, such as ROMs, RAMs, flash memories, and the like. Examples of program instructions include not only machine language codes such as those created by a compiler, but also high-level language codes that can be executed by a computer using an interpreter, and the like. The hardware devices may be modified into one or more software modules to execute the control processes according to the present invention, and vice versa.

[0341] The specific implementation described in the present invention is one embodiment and does not limit the scope of the present invention in any way. For the sake of brevity of the specification, descriptions of conventional electronic configurations, control systems, software, and other functional aspects of the system may be omitted. Furthermore, the wire connections or connecting members between components shown in the drawings are illustrative of functional connections and / or physical or circuit connections, and may be represented as various alternative or additional functional connections, physical connections, or circuit connections in an actual device. Furthermore, unless specifically mentioned as "essential", "importantly", etc., a component may not necessarily be required to apply the present invention.

[0342] In addition, although the detailed description of the present invention has been described with reference to the preferred embodiment of the present invention, it is understood that a person skilled in the art or an ordinary person having ordinary knowledge in the art can modify and change the present invention in various ways without departing from the spirit and technical scope of the present invention described in the claims below. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be determined by the claims.

Claims

1. A method for controlling multiple lighting devices using a computing device, The steps include: transmitting lighting device control signals to multiple lighting devices included in a group of multiple lighting devices; The steps include: performing an integrated lighting control performance for the plurality of lighting devices in the plurality of lighting device groups in accordance with the transmitted lighting device control signals; The lighting device control signal is a control signal based on a third control protocol that provides a unified control protocol for a first group of lighting devices controlled based on a first control protocol and a second group of lighting devices controlled based on a second control protocol different from the first control protocol. method.

2. The control signal according to the first control protocol includes control information that instructs the execution, interruption, or termination of at least one of the basic library and performance preparation data stored in a plurality of lighting devices in the first lighting device group, The method according to claim 1.

3. The basic library or the performance preparation data is control information including at least one parameter selected from the group consisting of color information, brightness information and dynamic effect information for operating the light source unit of the lighting device when it receives a command in accordance with the control protocol. The method according to claim 2.

4. The control signal by the second control protocol includes control information relating to at least one parameter selected from the group consisting of color information, brightness information, and dynamic effect information for operating the light source unit in real time. The method according to claim 1.

5. The control signal according to the third control protocol includes control information for operating the first lighting device group and the second lighting device group, The method according to claim 1, wherein the first lighting device group and the second lighting device group operate according to the control information when they receive the control signal from the third control protocol.

6. The basic library is data that is stored by default in the storage units of the plurality of writing devices and realizes dynamic effects, The aforementioned performance preparation data is stored in each of the multiple lighting devices according to the initial settings. The method according to claim 2 or 3.

7. The lighting device control signal is transmitted to the plurality of lighting devices included in the plurality of lighting device group by broadcast communication method, The method according to claim 1.

8. The step of performing the integrated lighting control effect is: The steps include: executing an event registration process that defines a control protocol for controlling multiple lighting devices within the aforementioned group of multiple lighting devices; The process includes the step of performing a pairing process in which performance preparation data is stored in the plurality of lighting devices within the plurality of lighting device groups, The method according to claim 1.

9. The integrated lighting control effect is an effect method in which a plurality of lighting devices included in different lighting device groups are controlled according to the lighting device control signals including the third control protocol, so that the plurality of lighting devices as a whole emit light in a specific graphic pattern or dynamic lighting effect. The method according to claim 1.

10. The integrated lighting control display transmits an integrated control signal that includes a single data packet generated based on first control information by the first control protocol and second control information by the second control protocol. The method according to claim 9.

11. A method for controlling multiple lighting devices using a computing device, A step of obtaining target control signals for multiple groups of lighting devices that are controlled based on different control protocols, The steps include converting the target control signal into a conversion control signal corresponding to each lighting device group among the different control protocols of the plurality of lighting device groups, The steps include transmitting the conversion control signal to multiple lighting devices within the multiple lighting device groups via the control protocol of each lighting device group, The step includes performing an integrated lighting control performance according to the transmitted conversion control signal. method.

12. The step of acquiring the target control signal includes receiving from the computing device a lighting device control signal that is transmitted from the computing device to a plurality of lighting devices included in an nth group of lighting devices that are controlled based on different control protocols. The method according to claim 11.

13. The step of acquiring the target control signal includes acquiring control information that includes at least one parameter selected from the group consisting of color information, brightness information and dynamic effect information for operating the light source unit of the lighting device, The method according to claim 11.

14. The step of converting the target control signal to the conversion control signal includes detecting the nth conversion control signal corresponding to the target control signal on the nth control protocol of the nth lighting device group, The method according to claim 11.

15. The conversion control signal is, A first conversion control signal that instructs the execution, interruption, or termination of a basic library stored in a writing device within the group of writing devices. A second conversion control signal that instructs the execution, interruption, or termination of performance preparation data stored in the lighting devices within the group of multiple lighting devices, and Among the third conversion control signals, which are a combination of the first conversion control signal and the second conversion control signal, At least one lighting device control signal corresponding to the control protocol of each of the aforementioned group of lighting devices, The method according to claim 11.

16. The basic library is stored by default in the storage unit of the plurality of writing devices, The aforementioned performance preparation data is stored in each of the multiple lighting devices according to the initial settings. The method according to claim 15.

17. The conversion control signal is transmitted to a plurality of lighting devices included in the plurality of lighting device group by broadcast communication method, The method according to claim 11.

18. The integrated lighting control effect is a method of causing multiple lighting devices belonging to different lighting device groups to be controlled according to a conversion control signal converted to a control protocol corresponding to the lighting device group to which each lighting device belongs, and causing the multiple lighting devices to emit light in a unified specific graphic pattern or dynamic lighting effect as a whole. The method according to claim 11.

19. A system for integrated control of multiple lighting devices, A computing device configured to generate and transmit lighting device control signals based on a third control protocol that provides a unified control protocol for a first group of lighting devices controlled based on a first control protocol and a second group of lighting devices controlled based on a second control protocol different from the first control protocol, A relay configured to transmit the lighting device control signal under the control of the computing device, The system comprises a plurality of lighting devices included in the first lighting device group and the second lighting device group, The plurality of lighting devices are configured to receive lighting device control signals based on the third control protocol from the relay and to perform integrated lighting control effects in accordance with the lighting device control signals.

20. A method for integrated control of multiple lighting devices using a computing device, To simultaneously control a first group of lighting devices operating according to a first control protocol and a second group of lighting devices operating according to a second control protocol different from the first control protocol, The steps include generating an integrated control signal that includes first control information according to the first control protocol and second control information according to the second control protocol, The steps include transmitting the generated integrated control signal to the first lighting device group and the second lighting device group, The multiple lighting devices in the first lighting device group that have received the integrated control signal operate the light source unit based on the first control information. The multiple lighting devices in the second lighting device group that have received the integrated control signal operate the light source unit based on the second control information. method.

21. At least one of the first control information and the second control information includes at least one parameter selected from the group consisting of color information, brightness information and dynamic effect information for operating the light source unit in real time. The method according to claim 20.

22. At least one of the first control information and the second control information is identification information for executing a library or scenario pre-stored in the corresponding writing device. The method according to claim 20.

23. The integrated control signal includes the first control information and the second control information in a single data packet. The method according to claim 20.