KR102076393B1 - Method and apparatus for lighting control using optical camera communication - Google Patents

Abstract

Lighting control method using an optical camera communication (OCC) according to an embodiment of the present invention, the identification information including the identification information of the light source from the image of the light source photographed by the optical camera communication receiving device image sensor Obtaining data, generating, by the optical camera communication receiving apparatus, command information data including information on the control command according to a control command for the light source based on the identification information of the light source, and the optical camera And transmitting, by the communication receiving device, the command information data to the lighting server controlling the light source.

Description

METHOD AND APPARATUS FOR LIGHTING CONTROL USING OPTICAL CAMERA COMMUNICATION}

The present invention relates to a lighting control method and apparatus using optical camera communication.

Recently, Visible Light Communication (VLC) technology, a technology that enables wireless communication by adding a communication function to a visible light wavelength using an infrastructure in which lights such as incandescent bulbs and fluorescent lamps are replaced with semiconductor LED (Light Emitting Diode) lights It is being studied, and the IEEE 802.15.7 international standard is also completed, and it is promoting the discovery of a business model for commercialization. However, IEEE 802.15.7 is mainly limited to data transmission using a photodiode (PD), and there is a problem in that a dedicated communication device such as a VLC dongle is required. Accordingly, international standardization of optical camera communication (OCC) using an image sensor such as a smartphone camera rather than a photodetector is being conducted in the IEEE 802.15.7m OWC TG (Task Group).

The present invention provides a lighting control method and apparatus using optical camera communication.

Lighting control method using an optical camera communication (OCC) according to an embodiment of the present invention, the identification information including the identification information of the light source from the image of the light source photographed by the optical camera communication receiving device image sensor Obtaining data, generating, by the optical camera communication receiving apparatus, command information data including information on the control command according to a control command for the light source based on the identification information of the light source, and the optical camera It characterized in that it comprises the step of transmitting the command information data to a lighting server for controlling the light source by the communication receiving device.

In one embodiment, the identification information data is characterized in that it comprises a prefix field indicating the type of beacon (type) and a data field indicating the identification information of the light source.

In one embodiment, the identification information data is composed of a full beacon frame or a shorten beacon frame according to the type of the beacon, and when the identification information data is the shortened beacon frame, the data field Includes sub-information among the identification information of the light source, and when the identification information data is the extended beacon frame, the data field includes all of the identification information of the light source.

In one embodiment, the command information data includes a command field indicating a control command for the light source and an identification information field indicating identification information of the light source, and the command field comprises dimming the light source. ) A first sub-field indicating whether to control, and a second sub-field indicating an on / off command for the light source or a dimming command for the light source according to the value of the first sub-field. do.

In one embodiment, the step of transmitting the command information data is characterized in that the optical camera communication receiving device comprises the step of transmitting the command information to the lighting server using wireless communication using radio waves.

In one embodiment, the optical camera communication receiving device is characterized in that it further comprises the step of obtaining a response message for the command information data from the image of the light source captured by the image sensor.

In one embodiment, the generating of the command information data comprises receiving a control command for the light source from a user through an augmented reality interface of the optical camera communication receiving device, and the command according to the input control command And generating information data.

In one embodiment, the step of receiving a control command for the light source, the optical camera communication receiving device screens the plurality of light sources through the augmented reality interface based on the images of the plurality of light sources captured by the image sensor And a step of selecting a light source to be controlled from among the plurality of light sources output on the screen through a user's screen touch input.

In one embodiment, the step of outputting the plurality of light sources to the screen may include displaying a controllable light source among the plurality of light sources, and providing a user interface capable of inputting a control command for the controllable light source. It characterized in that it comprises.

In one embodiment, the step of outputting the plurality of light sources to a screen includes displaying a controllable function of a controllable light source among the plurality of light sources.

Lighting control method using an optical camera communication (OCC) according to an embodiment of the present invention, the optical transmitting device comprising the steps of configuring the identification information data including the identification information of the light source, the optical transmitting device is the And transmitting the identification information data through a light source, and driving the light source according to command information data received by the optical transmission device based on the identification information of the light source.

In one embodiment, the identification information data is characterized in that it comprises a prefix field indicating the type of beacon (type) and a data field indicating the identification information of the light source.

In one embodiment, the identification information data is composed of a full beacon frame or a shorten beacon frame according to the type of the beacon, and when the identification information data is the shortened beacon frame, the data field Includes sub-information among the identification information of the light source, and when the identification information data is the extended beacon frame, the data field includes all of the identification information of the light source.

In one embodiment, the step of transmitting the identification information data includes applying an M-FK (M-Frequency Shift Keying) method or a Hybrid M-FSK / 2-PSK (2-Phase Shift Keying) method. It is characterized by.

In one embodiment, the optical transmission device further comprises the step of transmitting a response message to the command information data to the optical camera communication receiving device in an optical camera communication method.

In the lighting control method using optical camera communication (OCC) according to an embodiment of the present invention, the lighting server receives the optical camera communication receiving device from the light source through the optical camera communication method from the optical camera communication receiving device. And receiving command information data including identification information of the light source, and controlling the light source based on the command information data by the lighting server.

An optical camera communication receiving apparatus using optical camera communication (OCC) according to an embodiment of the present invention acquires identification information data including identification information of the light source from an image of the light source photographed by the image sensor Command information data including information on the control command according to the control command for the light source based on the data processing unit, an input unit that receives a control command for the light source from the user through the augmented reality interface, and the identification information of the light source And a command processor for transmitting the command information data to a lighting server that controls the light source.

An optical transmission apparatus using optical camera communication (OCC) according to an embodiment of the present invention comprises: a data configuration unit that configures identification information data including identification information of a light source, and loads the identification information data on light. And a driving unit for driving the light source according to the received command information data based on the light source to be sent out and the identification information of the light source.

The lighting server using optical camera communication (OCC) according to an embodiment of the present invention identifies the light source received from the light source by the optical camera communication receiving device from the optical camera communication method from the optical camera communication receiving device It characterized in that it comprises a receiving unit for receiving the command information data including information, and a control unit for controlling the light source based on the command information data.

The lighting control system according to an embodiment of the present invention acquires identification information data including identification information of the light source from an image of the light source photographed by the image sensor, and controls the light source based on the identification information of the light source Optical camera communication receiving device for generating command information data including information on the control command according to a command, and transmitting the command information data to a lighting server that controls the light source, identification information including identification information of the light source An optical transmitting device configured to transmit data, transmitting the identification information data through the light source, and driving the light source according to command information data received based on the identification information of the light source, and the optical camera communication receiving device The command information data of the light source is received, and the light is based on the command information data. It characterized in that it comprises a lighting server for controlling the circle.

The present invention includes a computer-readable recording medium on which a program for performing the method according to an embodiment of the present invention is recorded.

The present invention includes a computer program stored in a recording medium in order to execute the method according to an embodiment of the present invention on a computer.

The present invention includes a computer-readable recording medium recording the data format of a message used in the present invention.

According to the present invention, by providing a lighting control method and apparatus using optical camera communication, it is possible to increase efficiency in controlling and managing various lights installed indoors and outdoors.

1 is a view schematically showing a configuration of a lighting control system using optical camera communication (OCC) according to an embodiment of the present invention.
2 is a view for explaining a lighting control method using an optical camera communication according to an embodiment of the present invention.
3 and 4 are diagrams illustrating a beacon mode data frame format according to an embodiment of the present invention.
5 is a M-FSK (M-Frequency Shift Keying) method or a hybrid M-FSK / 2-PSK (2-Phase Shift Keying) method applied to a lighting control method using optical camera communication according to an embodiment of the present invention. It is a diagram for explaining the process.
6 is a diagram showing the principle of an encoding method in the M-FSK method according to an embodiment of the present invention.
7 is a view showing an example of a frequency band used in the M-FSK method according to an embodiment of the present invention.
FIG. 8 is a diagram illustrating a data frame structure when transmitting by the optical camera communication method of FIG. 5.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to clarify the technical spirit of the present invention. In describing the present invention, when it is determined that a detailed description of related known functions or components may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In the drawings, elements having substantially the same functional configuration are assigned the same reference numerals and symbols as possible, even if they are displayed on different drawings. For convenience of explanation, if necessary, describe the device and method together.

1 is a view schematically showing a configuration of a lighting control system using optical camera communication (OCC) according to an embodiment of the present invention.

Referring to FIG. 1, an illumination control system 100 (hereinafter referred to as an OCC illumination control system) using an optical camera communication according to an embodiment of the present invention includes an optical transmission device 110 and an optical camera communication reception device 120 ), And the lighting server 130.

The optical transmission device 110 operates to transmit data to be transmitted through a light source, and may include a data configuration unit 111, a driving unit 112, and an LED light source 113.

The data configuration unit 111 may generate transmission data to be transmitted, or read predefined data from memory and configure it as transmission data.

The transmission data is identification information data including identification information of the LED light source 113, and may include a prefix field indicating the type of beacon and a data field indicating the identification information of the LED light source. A detailed description of the frame format of transmission data will be described later with reference to FIGS. 3 and 4.

The driving unit 112 causes the LED light source 113 to flash according to the transmission data. Here, blinking does not necessarily indicate a method in which the light source is completely turned on and off, but includes all methods of representing data using a change in brightness of the light source. Also, the blinking of the light source includes not only blinking all color channels of the light source, but also blinking some color channels of the light source. For example, the driving unit 112 controls the LED light source 113 to be turned on or off according to the binary value 1 or 0 of the transmission data, and transmits the transmission data through the LED light source 113. The driver 112 may be, for example, a driver circuit, a controller, or the like.

The LED light source 113 is a light source using an LED element or the like that can emit light, and is flashed by the driver 112 to transmit data on the light. For example, the LED light source 113 may include lighting used in indoors such as a home or a company, or digital signage, billboards, signs, signs, etc. installed outdoors. In the present invention, for convenience, the LED light source is described as a reference, but the LED light source 113 is not necessarily limited to using an LED element, and may include all kinds of light sources.

The optical camera communication receiving device 120 may receive a signal transmitted from the LED light source 113 and process a control command of the LED light source 113 based on the received signal. The optical camera communication receiving device 120 may include an image sensor 121, a data processing unit 122, and a command processing unit 123.

The image sensor 121 may acquire image data by photographing the LED light source 113. In one embodiment, the image sensor 121 may continuously photograph the image of the LED light source 113 and obtain a transmission signal of the LED light source 113 such as a flashing signal from the captured images. The image sensor 151 may use, for example, a CCD or CMOS sensor, and may be configured by being included in a camera mounted on a smart device or the like.

The data processing unit 122 may acquire a flashing signal of the LED light source 113 from the image data obtained by the image sensor 121, and restore transmission data based on this. Since the transmission data according to the present invention includes the identification information of the LED light source 113, the data processing unit 122 can restore the identification information of the LED light source 113 from the image data obtained by the image sensor 121. .

The command processor 123 may process control commands for the LED light source 113. In one embodiment, the command processing unit 123 may receive a control command for the LED light source 113 based on the identification information of the LED light source 113 from a user, and include information on the received control command Command information data can be generated. The command information data may include a command field indicating a control command for the LED light source 113 and an identification information field indicating identification information of the LED light source 113. A detailed description of the frame format of the control command data will be described later.

The command processing unit 123 may transmit command information data to the lighting server 130. At this time, the command processing unit 123 may be directly connected to the lighting server 130 through Bluetooth or the like, or may be connected to a network via LAN, Internet, or the like. For example, the command processor 123 may transmit command information data to the lighting server 130 through wireless communication such as Wi-Fi, LTE, WiBro, ZigBee, and Bluetooth.

The lighting server 130 may receive command information data from the command processor 123 at the receiver (not shown), and control the LED light source 113 based on the command information data from the controller (not shown). In addition, the lighting server 130 may transmit a response message to the received command information data to the optical camera communication receiving device 120.

The optical camera communication receiving device 120 according to an embodiment of the present invention may use a smart device, such as a smart phone, for example, and the lighting server 130 may manage and control a plurality of LED light sources 113 locally. It can be a server.

2 is a view for explaining a lighting control method using an optical camera communication according to an embodiment of the present invention. The method of FIG. 2 may be performed by the lighting control system of FIG. 1 described above.

Referring to FIG. 2, the optical transmission device 110 may configure identification information data including identification information of the LED light source 113 and transmit identification information data through the LED light source 113 (S200). In one embodiment, the optical transmission device 110 may configure the identification information data in a beacon mode and transmit it through the LED light source 113. As described above, the identification information data may include a prefix field indicating the type of beacon and a data field indicating identification information of the LED light source.

3 and 4 are diagrams illustrating a beacon mode data frame format according to an embodiment of the present invention.

3 and 4, the identification information data may be configured as a full beacon frame or a shorten beacon frame according to the type of beacon.

When the identification information data is composed of a shortened beacon frame, the prefix field may be composed of a binary value (for example, 000) indicating that the beacon frame and a binary value (for example, 010) indicating that the beacon frame is shortened. . In addition, the data field may be composed of one sub-field indicating lower information among the identification information of the LED light source.

When the identification information data is configured as an extended beacon frame, the prefix field is a binary value (for example, 000) indicating that it is a beacon frame, a binary value (for example, 000 or 001) indicating that it is an extended beacon, and additional information. It may be composed of an option field indicating. The optional field may be a company identifier. In addition, the data field may be composed of a plurality of sub-fields indicating the entire identification information of the LED light source. The identification information of the LED light source may be hierarchically configured (eg, area identification information, building identification information, floor identification information, room identification information, light source identification information), and each of the plurality of sub-fields may each identify an LED light source It may include one layer of information. Each of the plurality of sub-fields may include an identifier (ID-SN) indicating the corresponding layer.

In one embodiment, the optical transmission device 110 may transmit one extended beacon frame and a plurality of shortened beacon frames within one beacon period.

In one embodiment, a short beacon frame is used when the number of LED light sources to be controlled is not large, such as a small indoor space, and an extended beacon frame is used when the number of LED light sources to be controlled is large, such as a large company or building. Can be used.

Referring to FIG. 2 again, the optical camera communication receiving device 120 may acquire identification information data of the LED light source 113 from the image of the LED light source 113 photographed by the image sensor 121 (S210).

The optical camera communication receiving device 120 may generate command information data including information on the control command according to the control command for the LED light source 113 based on the identification information of the LED light source 113 (S220, S230).

In one embodiment, the optical camera communication receiving device 120 displays a plurality of LED light sources 113 on the screen through the augmented reality interface based on the images of the plurality of LED light sources 113 photographed by the image sensor 121. It can be output (S220). For example, an LED light source controllable by the lighting server 130 among the plurality of LED light sources 113 may be specified and displayed. In addition, a user interface for inputting a control command for a controllable LED light source may be provided on the screen. The controllable function of the controllable light source can be displayed on the screen. The optical camera communication receiving device 120 may receive a control command for the LED light source 113 from the user through an augmented reality interface from an input unit (not shown) such as a touch screen (S230). For example, among the plurality of LED light sources 113 output on the screen, an LED light source to be controlled can be selected through a touch input to issue a command. The optical camera communication receiving device 120 may generate command information data according to a control command of the selected LED light source. For example, the control command may include an on / off operation of the LED light source, an operation of adjusting the dimming level of the LED light source, an operation of adjusting the color of the LED light source, and the like. In addition, when the LED light source desired to be controlled can express various forms such as letters, figures, etc., such as digital signage, billboards, signs, signs, etc., the control command may include an operation that can change these various forms. In this case, the command information data may further include subfields other than those shown in Table 1 and Table 2.

As described above, the command information data according to an embodiment of the present invention includes a command field indicating a control command for the LED light source 113 and an identification information field indicating identification information of the LED light source 113. Can be. In one embodiment, the command field indicates a first sub-field indicating whether to control dimming for the LED light source 113, and an on / off command for the LED light source 113, or the LED light source 113. It may include a second sub-field indicating the dimming command for. For example, when the first sub-field is instructed not to perform the dimming control operation for the LED light source 113, the second field may indicate an on / off command for the LED light source 113. When the first sub-field is instructed to perform a dimming control operation for the LED light source 113, the second sub-field may indicate a dimming command for the LED light source 113. Table 1 and Table 2 show a frame format of command information data according to an embodiment of the present invention.

Command field LED-ID field Dimming enable sub-field Command mode sub-field 1 bit 1 bit / 4 bits Variable

Command sub-filed 1 Command sub-filed 2 LED-ID field Description Command sub-filed 1 (1 bit)
0: Turn on / off action or
1: Dimming action
-1 bit for turn on / off action
1: full on
0: full off

-4 bits for dimming action
0000: 10% dimming
0001: 20% dimming
0010: 30% dimming
0011: 40% dimming
0100: 50% dimming
0101: 60% dimming
0110: 70% dimming
0111: 80% dimming
1000: 90% dimming Selected LED
-1 ~ 2 bytes ID (shorten ID) or
-3 ~ 6 bytes ID (full ID)

The optical camera communication receiving device 120 may transmit command information data to the lighting server 130 (S240). In one embodiment, the optical camera communication receiving device 120 may transmit and receive data to and from the lighting server 130 using wireless communication using radio waves such as Wi-Fi, LTE, WiBro, ZigBee, and Bluetooth.

The lighting server 130 may control the LED light source 113 based on the command information data for the LED light source 113 received from the optical camera communication receiving device 120 (S250). In one embodiment, the lighting server 130 may be connected to the LED light source 113 through wired or wireless communication such as Wi-Fi, power line communication (PLC), Ethernet, and control the LED light source 113 according to command information. The light transmitting device 110 may drive the LED light source 113 according to the control signal of the lighting server 130.

The lighting server 130 may transmit a response message to the command information data to the optical camera communication receiving device 120 (S260). In one embodiment, the lighting server 130 may transmit and receive data to and from the optical camera communication receiving device 120 using wireless communication such as Wi-Fi, LTE, WiBro, ZigBee, and Bluetooth.

In addition, the optical transmission device 110 may also transmit a response message to the command information data to the optical camera communication reception device 120. At this time, the optical transmission device 110 may compose a response message using the optical camera communication method and transmit it through the LED light source 113. The optical camera communication receiving device 120 may obtain a response message for command information data from the image of the LED light source 113 photographed by the image sensor 121.

5 is a M-FSK (M-Frequency Shift Keying) method or a hybrid M-FSK / 2-PSK (2-Phase Shift Keying) method applied to a lighting control method using optical camera communication according to an embodiment of the present invention. It is a diagram for explaining the process.

In the lighting control method using the optical camera communication according to an embodiment of the present invention, 32-FSK, 64-FSK, or hybrid 64-FSK / 2-PSK may be applied when transmitting and receiving identification information data. In one embodiment, when the optical transmission device 110 transmits by including a clock signal (Ab) in data for asynchronous reception, the optical camera communication receiving device 120 restores the frequency symbol and then recovers the recovered symbol. Since the clock signal can be extracted, packets can be accurately restored even if the sampling rate is different or fluctuates.

Table 3 shows an example of the structure of a data symbol according to each modulation method.

Referring to FIG. 5, when the optical transmission device 110 transmits identification information data through the LED light source 113, generates a data symbol by including a clock signal in the identification information data, and then encodes the data symbol into a frequency symbol. can do. 6 is a diagram showing the principle of an encoding method in the M-FSK method according to an embodiment of the present invention.

In one embodiment, the 32-FSK scheme encodes a data symbol including a 1-bit clock signal and 4-bit data as a frequency symbol, as shown in Table 3. Table 4 shows an example of a mapping relationship between frequency symbols according to data symbols in 32-FSK and 64-FSK schemes.

As shown in Table 4, the 32-FSK scheme includes two preamble frequencies and 32 data frequencies. Here, the first preamble frequency may be selected as the lowest frequency in the available frequency band, and the second preamble frequency may be selected as the highest frequency in the available frequency band. The 32 data frequencies can be calculated from the values of preamble frequencies. The relationship between the data frequency and the preamble frequency is as follows.

Data frequency: fi = f ₀ + if (i = 1; 2;?; 32)

Preamble frequency: f ₃₃ = f ₀ + 33.f

Where f is the frequency interval, f ₀ and f ₃₃ is two preambles.

In another embodiment, the 64-FSK scheme encodes a data symbol including a 1-bit clock signal and 5-bit data as a frequency symbol, as shown in Table 3. At this time, the mapping relationship of frequency symbols according to each data symbol is shown in Table 4. The frequency band of the 64-FSK system is twice that of the 32-FSK system. 7 is a view showing an example of a frequency band used in the M-FSK method according to an embodiment of the present invention. Referring to Table 4 and FIG. 7, 32 data frequencies and 2 preamble frequencies in the 64-FSK scheme are the same as in the case of 32-FSK, and the remaining 32 frequencies have higher data capacity per frequency symbol. In order to obtain, it can be allocated to an extended region from the frequency band of the 32-FSK scheme.

Meanwhile, the M-FSK method allocates different frequencies in a selected frequency band, and the PSK method can be additionally used to obtain high link capacity. At this time, the PSK method may use two phases. In one embodiment, as shown in FIG. 5, hybrid M-FSK / 2-PSK may be applied when there are two LED light sources. After the optical transmission device 110 generates two frequency signals by applying M-FSK to two LED light sources, an additional 2-PSK may be applied to modulate the phase relationship between the two frequency signals. For example, if the signal is 0, the two LED light sources can be modulated with the same phase signal, and if the signal is 1, the two LED light sources can be modulated with the opposite phase signal. FIG. 8 is a diagram illustrating a data frame structure when transmitting by the optical camera communication method of FIG. 5.

When the optical camera communication receiving apparatus 120 receives a data frame as shown in FIG. 8, the frequency symbol may be restored, and a clock signal may be extracted from the restored symbol to restore identification information data. In addition, when a signal to which the hybrid M-FSK / 2-PSK is applied is received, the optical camera communication receiving device 120 may additionally restore identification information data based on a phase relationship between two frequency signals.

The present invention can also be embodied as computer readable codes on a computer readable recording medium. The computer-readable recording medium includes all storage media such as magnetic storage media and optical reading media. It is also possible to record the data format of the message used in the present invention on a recording medium.

The present invention has been described in detail with reference to preferred embodiments illustrated in the drawings. These embodiments are not intended to limit the invention, but merely illustrative, and should be considered from an explanatory point of view rather than a limiting point of view. The true technical protection scope of the present invention should be defined by the technical spirit of the appended claims rather than the foregoing description. Although specific terms are used in this specification, they are used for the purpose of explaining the concept of the present invention only, and are not used to limit the scope of the present invention as defined in the claims or claims. Each step of the present invention does not necessarily have to be performed in the order described, but can be performed in parallel, selectively or individually. Those skilled in the art to which the present invention pertains will understand that various modifications and other equivalent embodiments are possible without departing from the essential technical idea of the present invention as claimed in the claims. It is to be understood that equivalents include all currently invented equivalents as well as equivalents to be developed in the future, ie, all components invented to perform the same function regardless of structure.

Claims (23)

In the lighting control method using optical camera communication (OPTICAL CAMERA COMMUNICATION; OCC),
Obtaining, by the optical camera communication receiving apparatus, identification information data including a prefix field indicating a beacon type and a data field indicating identification information of the light source from the image of the light source photographed by the image sensor;
Generating, by the optical camera communication receiving apparatus, command information data including information on the control command according to a control command for the light source based on the identification information of the light source; And
The optical camera communication receiving device includes the step of transmitting the command information data to a lighting server that controls the light source,
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, characterized in that the lighting control method. delete delete According to claim 1,
The command information data,
And a command field indicating a control command for the light source and an identification information field indicating identification information of the light source,
The command field,
A first subfield indicating whether to control dimming for the light source, and a second sub indicating an on / off command for the light source or a dimming command for the light source according to the value of the first subfield Lighting control method comprising a field. According to claim 1,
The step of transmitting the command information data,
And the optical camera communication receiving device transmitting the command information to the lighting server using wireless communication using radio waves. According to claim 1,
The optical camera communication receiving apparatus further comprises the step of obtaining a response message for the command information data from the image of the light source photographed by the image sensor. According to claim 1,
Generating the command information data,
Receiving a control command for the light source from a user through an augmented reality interface of the optical camera communication receiving device; And
And generating the command information data according to the input control command. The method of claim 7,
The step of receiving a control command for the light source,
Outputting the plurality of light sources to the screen through the augmented reality interface based on the images of the plurality of light sources photographed by the image sensor by the optical camera communication receiving device; And
And selecting a light source desired to be controlled from among the plurality of light sources output on the screen through a user's screen touch input. The method of claim 8,
The step of outputting the plurality of light sources to the screen,
A controllable light source is specified and displayed among the plurality of light sources,
And providing a user interface capable of inputting a control command for the controllable light source. The method of claim 8,
The step of outputting the plurality of light sources to the screen,
And displaying a controllable function of a controllable light source among the plurality of light sources. In the lighting control method using the optical camera communication (Optical Camera Communication; OCC),
Configuring, by the optical transmission apparatus, identification information data including a prefix field indicating a type of beacon and a data field indicating identification information of a light source;
Transmitting, by the optical transmission device, the identification information data through the light source; And
And the optical transmission device driving the light source according to command information data received based on the identification information of the light source.
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, characterized in that the lighting control method. delete delete The method of claim 11,
The step of transmitting the identification information data,
And a step of applying an M-FK (M-Frequency Shift Keying) method or a Hybrid M-FSK / 2-PSK (2-Phase Shift Keying) method. The method of claim 11,
And transmitting, by the optical transmission device, a response message to the command information data to an optical camera communication receiving device through an optical camera communication method. In the lighting control method using the optical camera communication (Optical Camera Communication; OCC),
The illumination server includes a prefix field indicating the type of beacon the optical camera communication receiving device receives from the light source from the optical camera communication receiving device from the optical camera communication receiving device and a data field indicating identification information of the light source. Receiving command information data including identification information of the light source included in the identification information data; And
And the lighting server controlling the light source based on the command information data.
The identification information data,
Depending on the type of beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, characterized in that the lighting control method. In the optical camera communication (OCC) using the optical camera communication receiving device,
In the optical camera communication receiving apparatus using the optical camera communication (OCC) photographed by the image sensor,
A data processing unit for obtaining identification information data including a prefix field indicating a type of beacon and a data field indicating identification information of the light source from the image of the light source photographed by the image sensor;
An input unit that receives a control command for the light source from a user through an augmented reality interface; And
A command processor for generating command information data including information on the control command according to the control command for the light source based on the identification information of the light source, and transmitting the command information data to a lighting server that controls the light source Includes,
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, the optical camera communication receiving device. In the optical transmission device using the Optical Camera Communication (Optical Camera Communication; OCC),
A data constructing unit configuring identification information data including a prefix field indicating a type of beacon and a data field indicating identification information of a light source;
A light source for transmitting the identification information data on light; And
It includes a driving unit for driving the light source according to the received command information data based on the identification information of the light source,
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes all of the identification information of the light source. In the lighting server using the Optical Camera Communication (Optical Camera Communication; OCC),
Identification information data including a prefix field indicating the type of beacon received from the light source by the optical camera communication receiving device from the optical camera communication receiving device and a data field indicating identification information of the light source from the optical camera communication receiving device. Receiving unit for receiving the command information data including the identification information of the light source included in; And
It includes a control unit for controlling the light source based on the command information data,
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, characterized in that the lighting server. In the lighting control system using the optical camera communication,
Acquiring identification information data including a prefix field indicating the type of beacon and a data field indicating identification information of the light source from the image of the light source photographed by the image sensor, and based on the identification information of the light source, An optical camera communication receiving device generating command information data including information on the control command according to a control command for the light source, and transmitting the command information data to a lighting server that controls the light source;
An optical transmission device that configures identification information data including identification information of the light source, transmits the identification information data through the light source, and drives the light source according to command information data received based on the identification information of the light source ; And
And an illumination server for receiving command information data of the light source from the optical camera communication receiving device, and controlling the light source based on the command information data,
The identification information data,
Depending on the type of the beacon, it is composed of a full beacon frame or a shorten beacon frame,
When the identification information data is the shortened beacon frame,
The data field includes lower information among identification information of the light source,
When the identification information data is the extended beacon frame,
The data field includes the entire identification information of the light source, characterized in that the lighting control system. delete A computer program stored in a recording medium to execute the method of any one of claims 1, 4 to 11 and 14 to 16 on a computer. delete

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