JP2018098156A - Lighting control system and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a configuration that is easy to be introduced and can be operated intuitively in a lighting control system that controls illumination of a lamp from a portable terminal.SOLUTION: Each of lighting control systems 1 and 1A includes a camera 10 of a portable terminal 2, a touch panel 20 on which a photographing lamp 4c is displayed, an icon output unit 31 for outputting an icon indicating a choice of illumination control to the touch panel 20, a control content determination unit 32 that determines the content of illumination control on the basis of a touch operation on the icon, a position acquiring unit 33 that acquires the terminal position including the latitude and the longitude of the portable terminal 2 by positioning means 33a, a direction acquiring unit 34 that acquires the photographing direction by an electronic compass 34a, memories 70 and 40 each of which stores a lamp position including the latitude and the longitude with respect to each of the lamps 4, a lamp specifying unit 61 that specifies a target lamp 4t corresponding to the photographing lamp 4c on the basis of the terminal position, the photographing direction, and the lamp position, and a signal generating unit 62 that generates an illumination control signal used to cause the target lamp 4t to execute the illumination control content.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a lighting control system and a program used therefor.

  Patent Document 1 discloses a lighting control system including a controllable overall control unit and a portable terminal capable of photographing a plurality of lighting fixtures among a plurality of lighting fixtures as an imaging range. This illumination control system performs image analysis processing on a captured image obtained by a portable terminal using information of a layout diagram indicating the layout position of a plurality of lighting fixtures, and thereby on an image portion and a layout diagram of the lighting fixture in the captured image. A process for obtaining a correspondence relationship with the arrangement position of the lamp, a process for obtaining a correspondence between a lighting apparatus that is sequentially turned on and a lighting apparatus on the arrangement drawing, and a plurality of lights at each address corresponding to the lighting apparatus arranged on the arrangement drawing It has a control part which performs processing which associates each ID information of an appliance.

  Patent Literature 2 discloses an illumination control device that controls a lighting fixture in a portable terminal. The illumination control device includes an image acquisition unit that acquires an image, an instruction acquisition unit that acquires an operator's instruction, and a control unit that controls the lighting apparatus. The control unit includes a color candidate selection unit that selects a plurality of color candidates used for the toning of the lighting fixture according to the instruction acquired by the instruction acquisition unit, a color candidate adjustment unit that performs adjustment in the automatic mode, and a color candidate adjustment unit A toning unit for controlling the lighting fixture so that the lighting fixture emits the illumination light of the color determined in (1). Moreover, the control part has memorize | stored the communication address of the lighting fixture by the communication setting by prior pairing. And a control part receives the setting of a lighting fixture on the illustration screen of the space which simulated the room about each of the lighting fixture by dialogue with an operator.

JP 2014-222652 A JP, 2006-170922, A

  However, in the configuration of Patent Document 1, in order to match the ID and the installation position of the luminaire, it is necessary to obtain a layout drawing showing the arrangement position of the luminaire in advance, a sequential lighting operation of the luminaire, System setting work becomes complicated. In particular, when a layout drawing of lighting fixtures cannot be obtained in advance, the introduction of the system is not realized. Thus, in the above configuration, there is a problem in the ease of introduction of the system. In the configuration of Patent Document 2, when an illustration screen simulating an illumination space is displayed on the screen of the mobile terminal, the visual field actually viewed by the user and the visual field on the illustration screen are the viewpoint, viewing direction, and the like. May be different. In such a case, the user cannot easily recognize the correspondence between the operation on the screen and the lamp controlled by the operation, and cannot perform intuitive illumination control. In general, in operation devices such as a remote control for outdoor lighting and a control panel, only the ID and control content of each lamp are often displayed. There is a problem that it is difficult to intuitively understand the correspondence between the ID and the actual lamp.

  Accordingly, an object of the present invention is to provide a configuration that is easy to introduce and can be intuitively operated in an illumination control system that controls illumination of a lamp using a mobile terminal. Moreover, this invention makes it a subject to provide the program used for such an illumination control system.

  The illumination control system for controlling a lamp from a portable terminal according to the present invention shows a camera of the portable terminal, a touch panel of the portable terminal on which an image of the lamp photographed by the camera is displayed, and lighting control options on the touch panel. An icon output unit that outputs an icon, a control content determination unit that determines illumination control content based on a touch operation on the icon, a position acquisition unit that acquires a terminal position including the latitude and longitude of the mobile terminal, and a positioning unit; A plurality of lamps based on an azimuth acquisition unit that acquires a shooting direction by a camera using an electronic compass, a memory that stores a lamp position including latitude and longitude for each of the plurality of lamps, and a terminal position, a shooting direction, and a lamp position To specify the target lamp corresponding to the captured lamp, and to cause the target lamp to execute the lighting control content And a signal generator for generating a lighting control signal.

  With the above configuration, when the user of the portable terminal photographs the lamp by the camera and selects an icon corresponding to the lighting control content, the photographing lamp is connected to the photographing lamp based on the acquired terminal position and photographing direction and the stored lamp position. The corresponding target lamp is specified, and the lighting control content is executed in the target lamp. As described above, information that needs to be stored in advance is each lamp position (latitude and longitude) for identification of each lamp, and such information can be easily obtained and processed. In addition, the user can perform illumination control of the photographing lamp by an intuitive operation only by photographing the lamp and selecting an icon. Therefore, in a lighting control system that controls lighting of a lamp using a portable terminal, a configuration that is easy to introduce and can be operated intuitively is realized.

  According to the first aspect of the present invention, in an illumination control system that includes a portable terminal and a server and controls a lamp from the portable terminal, the portable terminal displays a camera and an image of the lamp taken by the camera. A touch panel, an icon output unit that outputs an icon indicating lighting control options on the touch panel, a control content determination unit that determines lighting control content based on a touch operation on the icon, and a terminal position that includes the latitude and longitude of the mobile terminal A position acquisition unit for acquiring a shooting direction by a positioning unit, a direction acquisition unit for acquiring a shooting direction by a camera using an electronic compass, a command information generation unit for generating command information including illumination control content, a terminal position, and a shooting direction, and command information A terminal communication unit that transmits a lamp to the server, and the server includes a lamp position including a latitude and a longitude for each of the plurality of lamps. A target lamp corresponding to the photographed lamp is identified from a plurality of lamps based on the memory to be stored, the server communication unit that receives the command information, the received terminal position and shooting direction, and the stored lamp position. And a signal generation unit that generates an illumination control signal for causing the target lamp to execute the received illumination control content. As described above, since the server is provided with the memory for storing the lamp position, the lamp specifying unit for specifying the target lamp, and the signal generating unit for generating the illumination control signal, a large-capacity and high-speed illumination control process can be performed.

  According to the second aspect of the present invention, in an illumination control system for controlling a lamp from a portable terminal, the portable terminal has a camera, a touch panel on which an image of the lamp photographed by the camera is displayed, and illumination control on the touch panel. An icon output unit that outputs an icon indicating an option of the device, a control content determination unit that determines the lighting control content based on a touch operation on the icon, and a position at which the terminal position including the latitude and longitude of the mobile terminal is acquired by the positioning unit Based on the acquisition unit, the direction acquisition unit that acquires the shooting direction by the camera with an electronic compass, the memory that stores the lamp position consisting of latitude and longitude for each of the plurality of lamps, the terminal position, the shooting direction, and the lamp position , A lamp specifying unit for specifying the target lamp corresponding to the captured lamp from a plurality of lamps, and the lighting control content for the target lamp And a signal generator for generating a lighting control signal for executing. As described above, the memory for storing the lamp position, the lamp specifying unit for specifying the target lamp, and the signal generating unit for generating the illumination control signal are provided in the portable terminal, and the lighting control system is configured by the portable terminal and the lamp. A lighting control system with a simple configuration is realized.

  In any one of the illumination control systems described above, the lamp specifying unit is configured to specify, as the target lamp, a lamp whose lamp position is included in a target area defined by a predetermined center angle centered on the shooting direction from the terminal position. The As a result, by adjusting the setting of the central angle, a lamp in an appropriate range is specified as the target lamp.

  In any one of the illumination control systems described above, the position acquisition unit is configured to acquire the altitude of the mobile terminal in addition to the latitude and longitude by the positioning unit, and the direction acquisition unit includes the shooting elevation angle of the camera in addition to the shooting direction. Is obtained by an electronic compass, the lamp position is defined by the latitude, longitude, and altitude of the lamp, and the lamp specifying unit extends from the terminal position to the photographing axis direction defined by the photographing orientation and the photographing elevation angle. Alternatively, a lamp that includes a lamp position within a polygonal pyramid target area may be specified as the target lamp. Thereby, various illumination control by three-dimensional lamp position specification becomes possible.

  Furthermore, it is preferable that the lamp specifying unit is configured to define the far end of the target area according to a radius from the terminal position or a grouping of a plurality of lamps. Thus, by adjusting the far end setting, a lamp in an appropriate range is specified as the target lamp.

  In the illumination control system according to the first aspect, the lamp specifying unit specifies, as the target lamp, a lamp whose lamp position is included in a target area defined by a predetermined center angle centered on the shooting direction from the terminal position. The server may further include a control limiting unit configured to narrow the central angle with respect to an increase in the transmission frequency of the illumination control signal. With this configuration, even when the user is congested, by narrowing the target area, more users can enjoy lighting control.

  In the illumination control system according to the first aspect, the lamp specifying unit specifies, as a target lamp, a lamp whose lamp position is included in a target area defined by a predetermined center angle centered on the shooting direction from the terminal position. The far end of the region is configured to be determined according to a radius from the terminal position or a grouping of a plurality of lamps, and the server causes the far end position to approach the terminal position with respect to an increase in the transmission frequency of the illumination control signal. It may further include a control limiting unit configured as described above. With this configuration, even when the user is congested, by narrowing the target area, more users can enjoy lighting control.

  In any one of the illumination control systems described above, the image is a real-time image, and the position acquisition unit and the direction acquisition unit are configured to acquire the terminal position and the shooting direction at the time when the touch operation is performed, respectively. Thereby, the user can enjoy a more intuitive lighting control operation.

  Alternatively, the image is a still image, and the position acquisition unit and the orientation acquisition unit are configured to acquire the terminal position and the imaging orientation at the time when the still image was captured, respectively. As a result, the user can enjoy the illumination control scanning with a comfortable posture after shooting.

  Furthermore, any one of the illumination control systems includes a lamp communication unit that receives an illumination control signal, a light source, and a lamp having a lighting device that controls a lighting state of the light source based on the illumination control signal. The present invention also includes a program for causing a computer to function as each unit included in any of the lighting control systems.

It is a block diagram of the basic example of the illumination control system by 1st Embodiment. It is a figure explaining operation | movement of the illumination control system by 1st Embodiment. It is a figure explaining operation | movement of the illumination control system by 1st Embodiment. It is a flowchart which shows operation | movement of the illumination control system of 1st Embodiment. It is a flowchart which shows operation | movement of the illumination control system of 1st Embodiment. It is a block diagram of the additional example of the lighting control system by 1st Embodiment. It is a figure explaining operation | movement of the additional Example of FIG. It is a block diagram of the illumination control system by 2nd Embodiment. It is a flowchart which shows operation | movement of the illumination control system of 2nd Embodiment. It is a flowchart which shows operation | movement of the illumination control system of 2nd Embodiment.

<First embodiment, basic example>
FIG. 1 shows a block diagram of a basic example of the illumination control system 1 according to the first embodiment of the present invention. The lighting control system 1 includes a mobile terminal 2, a server 3, lamps 4-1 to 4-n and a network 5. In the following description, the lamps 4-1 to 4-n are also collectively referred to as the lamp 4 as a generic name or a part thereof. The network 5 is, for example, the Internet (hereinafter also referred to as the Internet 5). As an outline, the illumination control system 1 of the present embodiment is for controlling illumination of a desired lamp 4 from the portable terminal 2.

  The portable terminal 2 includes a camera 10, a touch panel 20, a CPU 30, a positioning unit 33a, an electronic compass 34a, a memory 40, and a terminal communication unit 50, which are connected in a manner that allows signals and data to be exchanged with each other via a system bus. Is done. In the present embodiment, the mobile terminal 2 is a smartphone. However, the mobile terminal 2 may be another type of mobile terminal such as a tablet.

  The camera 10 is an imaging unit mounted on the back surface of the mobile terminal 2 (the side facing the touch panel 20). The touch panel 20 functions as a display unit that displays an image captured by the camera 10 and also functions as an operation input unit that receives a touch operation by a user.

  The CPU 30 includes an icon output unit 31, a control content determination unit 32, a position acquisition unit 33, an orientation acquisition unit 34, and a command information generation unit 35. In addition to these functions, the CPU 30 is capable of executing imaging processing by the camera 10, display processing on the touch panel 20, and communication processing of the terminal communication unit 50. Further, each part of the CPU 30 is connected in such a manner that signals and data can be exchanged with each other via a bus.

  The memory 40 is a storage unit such as a RAM or a ROM that stores programs and data, and it is assumed that an application for executing this embodiment has already been installed from the server 3 or the Internet 5.

  FIG. 2 shows an example of the screen on the touch panel 20 according to the environment in which the user of the mobile terminal 2 exists and the shooting by the camera 10. The drawings are schematic diagrams for easy understanding of the description, and dimensions, color schemes, arrangements, and the like may be different from actual ones. As shown in FIG. 2, the user is located in a region where lamps 4-1 to 4-8, which are outdoor lights, are arranged on both sides in a night park or the like. That is, as viewed from the user (mobile terminal 2), the lighting devices 4-1 to 4-4 that are lit from the front are arranged on the left side, and the lighting devices 4-5 to 4-8 that are lit from the back side are arranged on the right side. ing. The user takes a picture of the lamp 4-2 and displays it on the image area 21 on the touch panel 20. In the following, the photographed lamp 4, that is, the lamp displayed in the image area 21, is referred to as a photographing lamp 4c as necessary.

  When the lighting control application according to the present embodiment is activated, the icon output unit 31 outputs an icon region 22 indicating lighting control options to the touch panel 20 as illustrated in FIG. 2. The icon area 22 includes, for example, a turn-off icon 221, a turn-on icon 222, a red icon 223, a blue icon 224, and the like. Further, the icon output unit 31 can output an icon indicating another light color such as green to the icon region 22 in response to a flick operation in the left-right direction by the user. The control content determination unit 32 determines the illumination control content based on a touch operation on any icon by the user.

  The position acquisition unit 33 acquires a terminal position composed of the latitude and longitude of the mobile terminal 2 using positioning means 33a such as GPS or Beacon. The direction acquisition unit 34 acquires the shooting direction of the camera 10 using the electronic compass 34a.

  Here, the image displayed in the image area 21 of the touch panel 20 may be a real-time image captured by the camera 10 or may be a still image captured immediately before by a user's shutter operation. When a real-time image is displayed (hereinafter, referred to as “normal shooting mode”), the position acquisition unit 33 and the direction acquisition unit 34 are configured so that the touch control operation is performed (substantially the control content determination unit 32 controls the illumination control content). Terminal position and shooting direction at the time of determination) are acquired. On the other hand, when a still image is displayed (hereinafter referred to as “still image mode”), the position acquisition unit 33 and the direction acquisition unit 34 acquire the terminal position and the shooting direction at the time of shooting the still image, respectively. To do.

  The command information generation unit 35 transmits the illumination control content acquired by the control content determination unit 32, the terminal position acquired by the position acquisition unit 33, and the shooting direction determined by the orientation acquisition unit 34 to the server 3. Generate command information. In the present embodiment, the illumination control content, the terminal position, and the shooting orientation are included in the command information. However, part or other information of these may be included in the command information as necessary.

  The terminal communication unit 50 is a wireless communication unit equipped in a normal mobile terminal, and can communicate with the server 3 via the Internet 5 in this embodiment. The terminal communication unit 50 can transmit the command information (lighting control content, terminal position, and shooting direction) generated by the transmission information generation unit 35 to the server 3.

  The server 3 includes a CPU 60, a memory 70, and a server communication unit 80, which are connected in such a manner that signals and data can be exchanged with each other via a system bus.

The memory 70 is a storage unit that stores the lamp position including the ID of each lamp 4 and the latitude and longitude corresponding thereto. The memory 70 is, for example,
About lamp 4-1, ID: lamp A, latitude-longitude: 35.68-139.76
About lamp 4-2, ID: lamp B, latitude-longitude: 35.50-139.80
... (omitted for lamps 4-3 to 4-6) ...
About the lamp 4-7, ID: lamp G, latitude-longitude: 35.40-139.95
About the lamp 4-8, ID: lamp H, latitude-longitude: 35.20-140.12
Is remembered. Each lamp position may be acquired manually by a setting operator in each lamp 4 using a positioning device (GPS or the like), or a positioning device (GPS, Beacon mounted in advance in each lamp 4). Etc.) may be acquired automatically. In the latter case, the acquired positioning information is received by the server communication unit 80 from the lamp communication unit 90 via the Internet 5 and stored in the memory 70.

  The server communication unit 80 can communicate with the mobile terminal 2 and the lamp 4 via the Internet 5. The communication connection between the server communication unit 80 and the Internet 5 may be wired or wireless. The server communication unit 80 can receive command information from the mobile terminal 2 and transmit an illumination control signal described later to the lamp 4.

The CPU 60 includes a lamp specifying unit 61 and a signal generating unit 62.
The lamp specifying unit 61 selects the target lamp 4t corresponding to the shooting lamp 4c based on the terminal position and shooting direction included in the command information received by the server communication unit 80 and the lamp position stored in the memory 70. Identify. Specifically, the lamp specifying unit 61 is configured to specify, as the target lamp 4t, a lamp 4 whose lamp position is included in a target area defined by a predetermined central angle centered on the shooting direction from the terminal position. .

  FIG. 3 shows the positional relationship between the mobile terminal 2 and the lamps 4-1 to 4-8 (lamp IDs A to H) in the shooting state of FIG. It is assumed that the terminal position of the mobile terminal 2 is latitude: 35.44 and longitude: 139.82, and the shooting direction (broken line X) is 30 ° 18′12 ″. The shooting range (target region R) is defined. The shooting azimuth is a central angle α with the shooting azimuth as the center, which is a preset angle of several degrees to several tens of degrees and corresponds to a shooting range that can be displayed on the touch panel 20 ( It can be said that the viewing angle of the camera 10 is α).

  In this example, the lamp position of ID: lamp B is latitude-longitude: 35.50-139.80, and is included in the target region R. Therefore, the lamp specifying unit 61 specifies the lamp 4-2 as the target lamp 4t corresponding to the photographing lamp 4c. The far end of the target region R may be defined by a predetermined radius (for example, a radius of about 10 m to 100 m) from the terminal position, or may be defined by grouping the lamps 4. In the latter case, for example, even if there is a lamp 4-x in a group different from the lamps 4-1 to 4-8 on the extended line of the broken line X, the lamp 4-x does not become the target lamp 4t. .

  When a plurality of lamps 4 are displayed in the image area 21, that is, when a plurality of lamps 4 are included in the target area R, the lamp specifying unit 61 specifies all of them as the target lamp 4t. Alternatively, the lamp 4 located closest to the center of the shooting azimuth may be specified as the target lamp 4t. Alternatively, the lamp specifying unit 61 specifies one or a plurality of lamps 4 located in the range of the central angle β (α> β) around the shooting direction (that is, near the center of the shooting direction) as the target lamp 4t. Also good. As described above, by adjusting the setting of the central angle α or β of the target region R or the setting of the near end, the lamp 4 included in an appropriate range is specified as the target lamp 4t.

  As another method, when a plurality of lamps 4 are included in the target region R, the lamp specifying unit 61 calculates the distance between the lamp position and the terminal position for each of the plurality of lamps 4, and the lamp 4 with the smallest distance is obtained. That is, the lamp 4 closest to the portable terminal 2 may be specified as the target lamp 4t.

  The signal generation unit 62 generates an illumination control signal for causing the target lamp 4t (in this example, lamp 4-2 / ID: lamp B) to execute the illumination control content included in the command information received by the server communication unit 80. Generate. Therefore, the lighting control signal includes at least data for specifying the address of the target lamp 4t and the lighting control content. And the server communication part 80 transmits an illumination control signal to the object lamp 4t.

Each lamp 4 is an outdoor lamp including a lamp communication unit 90, a lighting device 92, and a light source 94.
The lamp communication unit 90 is configured to receive an illumination control signal from the server 3 via the Internet 5. The connection between the lamp communication unit 90 and the Internet 5 may be a wired connection or a wireless connection. The communication between the lamp communication unit 90 and the server communication unit 80 may be a push type (a communication method in which an illumination control signal is actively transmitted from the server 3 to the lamp 4), or a pull type (the lamp 4 is A communication method in which the server 3 is periodically inquired and the server 3 transmits an illumination control signal to the lamp 4 may be used.

  The light source 94 includes an LED array having a plurality of light emitting LED elements. The lighting device 92 is an LED power source that receives an AC power supply (not shown) and controls lighting of each of the plurality of light emitting LED arrays. The lighting device 92 includes a rectifier circuit that rectifies an AC power source, and a DC / DC converter that converts the rectified output of the rectifier circuit into a direct current for each color LED array, and supplies the converted direct current to the corresponding LED array. And a control circuit for controlling the value of each DC current based on the illumination control signal received by the lamp communication unit 90.

  In summary, for example, the following operation is possible. It is assumed that the user of the portable terminal 2 touches the red icon 223 in the icon area 22 while photographing the lamp 4-2 with the camera 10 and displaying the lamp 4-2 in the image area 21. In response to this, command information indicating the terminal position, shooting direction, and red light emission is transmitted from the portable terminal 2 to the server 3. In the server 3, the terminal position, the shooting direction, and the lamp position are inquired, the lamp 4-2 (lamp B) is specified as the target lamp 4t, and an illumination control signal for red light emission is transmitted to the lamp 4-2. In the lamp 4-2, the light source 94 emits red light based on the illumination control signal.

  For the operation of the icon area 22, when the second light color is selected while the first light color is turned on, the second light color is mixed with the first light color. A mixed color lighting may be performed, or a first light color lighting may be switched to a second light color lighting. For example, when the blue icon 224 is selected when the red lighting is performed, the lighting may be switched to the lighting by magenta light emission in which blue is mixed with red, or the red lighting is blue. You may make it switch to lighting. Further, not only icons for single color lighting but also other types of lighting icons may be provided. For example, an icon for a sequence-like lighting pattern (for example, a gradation change of a plurality of emission colors) may be provided. Further, an icon for distinguishing lighting of a plurality of emission colors (for example, lighting in which the irradiation center portion becomes the first emission color and the irradiation outer peripheral portion becomes another second emission color) may be provided. In addition, an icon for lighting may be provided by a dynamic pattern (for example, a pattern moving concentrically in the outer circumferential direction or the central direction, a rotation pattern, or the like). Furthermore, an icon for dimming, an icon for returning to the initial (default) lighting state, an icon for returning to the immediately previous lighting state, and the like may be provided.

FIG. 4A shows a flowchart for explaining the operation of the illumination control system 1 in the normal photographing mode.
In step S200, an application for implementing this embodiment is activated.
In step S <b> 205, the icon output unit 31 outputs an icon (icon region 22) to the touch panel 20.
In step S206, the camera 10 starts photographing, and the photographing lamp 4c is displayed in the image area 21. Note that the order of step S205 and step S206 may be reversed, or both steps may be performed simultaneously.

In step S210, the control content determination unit 32 determines whether or not an icon touch operation has been performed. When the touch operation on the icon is performed (step S210, Yes), in step S215, the control content determination unit 32 determines the illumination control content according to the touch operation.
In step S216, the position acquisition unit 33 acquires the terminal position at the time of the touch operation.
In step S217, the direction acquisition unit 34 acquires the shooting direction at the time of the touch operation.

  In step S220, the command information generation unit 35 generates command information including the illumination control content, the terminal position, and the shooting direction obtained in steps S215, S216, and S217, and the terminal communication unit 50 sends the command information to the server 3. Send. The process in the portable terminal 2 returns to step S210.

In step S300, the server communication unit 80 receives command information.
In step S305, the lamp specifying unit 61 specifies the target area R based on the terminal position and the shooting direction included in the command information and the preset central angle, and refers to the memory 70 to set the target area R. The included lamp 4 is specified as the target lamp 4t corresponding to the photographing lamp 4c.
In step S310, the signal generation unit 62 generates an illumination control signal for causing the target lamp 4t to execute the illumination control content included in the command information, and the server communication unit 80 transmits the illumination control signal to the target lamp 4t. .

In step S400, the lamp communication unit 90 receives an illumination control signal.
In step S405, the lighting device 92 controls the lighting of the light source 94 based on the illumination control signal.

FIG. 4B shows a flowchart for explaining the operation of the illumination control system 1 in the still image mode.
In step S200, an application for implementing this embodiment is activated.
In step S <b> 205, the icon output unit 31 outputs an icon (icon region 22) to the touch panel 20.

In step S <b> 230, the CPU 30 determines whether a still image has been taken by the camera 10. When a still image is shot (step S230, Yes), in step S235, the CPU 30 displays the shot still image of the lamp 4 in the image area 21. Note that the order of step S205 and step S230 may be reversed, or both steps may be performed simultaneously.
In step S236, the position acquisition unit 33 acquires the terminal position at the time of still image shooting.
In step S237, the direction acquisition unit 34 acquires the shooting direction at the time of still image shooting.

  In step S240, the control content determination unit 32 determines whether or not an icon touch operation has been performed. When the touch operation on the icon is not performed (No in step S240), in step S241, the CPU 30 determines whether or not the display of the still image in the image area 21 is finished (that is, the user tries to shoot a new still image). Or not). If the display of the still image is completed (step S241, Yes), the process returns to step S230. If the display of the still image is not completed (step S241, No), the process returns to step S240. When the touch operation on the icon is performed (step S240, Yes), in step S245, the control content determination unit 32 determines the illumination control content according to the touch operation.

  In step S250, the command information generation unit 35 generates command information including the terminal position, shooting direction, and illumination control content obtained in steps S236, S237, and S245, and the terminal communication unit 50 sends the command information to the server 3. Send. The process in the portable terminal 2 returns to step S240.

  Steps S300 to S310 in the server 3 and steps S400 and S405 in the lamp 4 are the same as those in FIG. 4A. That is, in the server 3, the command information is received in step S300, the lamp 4 at the lamp position included in the target region R is specified as the target lamp 4t in step S305, and the illumination control signal is transmitted to the target lamp 4t in step S310. Generated and transmitted. In the lamp 4, the illumination control signal is received in step S400, and the light source 94 is controlled to be turned on based on the illumination control signal in step S405.

  As described above, the lighting control system 1 of the present embodiment includes the mobile terminal 2 and the server 3. The mobile terminal 2 illuminates based on a touch operation on the icon, an icon output unit 31 that outputs an icon indicating an illumination control option on the touch panel 20, a touch panel 20 on which an image of the photographing lamp 4c is displayed. A control content determination unit 32 that determines the control content, a position acquisition unit 33 that acquires the terminal position composed of the latitude and longitude of the mobile terminal 2 by the positioning means 33a, and an orientation acquisition that acquires the shooting direction by the camera 10 by the electronic compass 34a A unit 34, a command information generation unit 35 that generates command information including illumination control content, a terminal position, and a shooting direction, and a terminal communication unit 50 that transmits the command information to the server 3. The server 3 includes a memory 70 that stores a lamp position composed of latitude and longitude for each of the plurality of lamps 4, a server communication unit 80 that receives command information, a received terminal position and a shooting direction, and a stored lamp position. Based on the above, a lamp specifying unit 61 that specifies the target lamp 4t corresponding to the photographing lamp 4c from the plurality of lamps 4, and a signal for generating an illumination control signal for causing the target lamp 4t to execute the received lighting control content A generation unit 62 is provided.

  Thereby, when the user of the portable terminal 2 shoots the lamp 4 with the camera 10 and selects the icon of the lighting control content, the shooting lamp 4c is set on the basis of the acquired terminal position and shooting direction and the stored lamp position. The corresponding target lamp 4t is specified, and the lighting control content is executed in the target lamp 4t. Thus, information that needs to be stored in advance is each lamp position (latitude and longitude) for identification of each lamp, and such information is easy to obtain and process. In addition, the user can perform illumination control of the photographing lamp 4c by an intuitive operation only by photographing the lamp 4 and selecting an icon. Therefore, in the lighting control system 1 that controls the lighting of the lamp 4 using the portable terminal 2, a configuration that is easy to introduce and that can be intuitively operated is realized. In particular, in the present embodiment, the server 3 is provided with the memory 70 for storing the lamp position, the lamp specifying unit 61 for specifying the target lamp 4t, and the signal generating unit 62 for generating the illumination control signal. Control processing is possible.

  Further, as described above, this embodiment can be applied to either the normal shooting mode using a real-time image or the still image mode using a still image. In the normal shooting mode, the user can enjoy a more intuitive lighting control operation. On the other hand, in the still image mode, in particular, when the mobile terminal 2 is a relatively heavy terminal such as a tablet, the user picks up the mobile terminal 2 in an easy-to-hold posture after shooting, or places the mobile terminal 2 on the table. Thus, it is possible to enjoy illumination control scanning with an easy posture.

<First Embodiment, Additional Example 1>
Various additional functions can be added to the basic example of the present embodiment described above. For example, a configuration is also possible in which lighting control is performed on the lamps 4 that are distributed in the vertical direction as well as in the vertical direction (that is, arranged in different heights). In this case, the electronic compass 34a is configured by a 3D compass or a gyrocompass, or an acceleration sensor is provided in addition to the electronic compass 34a.

  In this additional embodiment, for example, a lamp 4 (including a lamp for indirect illumination) arranged on a wall surface of a building, a high object or the like is photographed, specified and controlled. In this case, three-dimensional positioning is performed by the positioning means 33 a made of GPS, and the position acquisition unit 33 acquires altitude in addition to the latitude and longitude of the mobile terminal 2. That is, the terminal position is defined by the latitude, longitude, and altitude of the mobile terminal 2. Further, the azimuth acquisition unit 34 acquires a shooting elevation angle (that is, an elevation angle or depression angle) in addition to the shooting direction of the camera 10 by the electronic compass 34a. Therefore, the command information generation unit 35 generates command information including the terminal position, the shooting direction, the shooting elevation angle, and the illumination control content. Further, the lamp position of each lamp 4 is also defined by its latitude, longitude, and altitude, and these are stored in the memory 70.

  Then, the lamp specifying unit 61 specifies, as the target lamp 4t, the lamp 4 in which the lamp position is included in a conical or polygonal cone-shaped target area that extends in the shooting axis direction defined by the shooting direction and the shooting elevation angle from the terminal position. . For example, the target region may be a conical space that extends from the terminal position with a predetermined central angle γ around the imaging axis direction. Alternatively, the target region is a quadrangular pyramid that is defined by a central angle α (or β) in the planar direction from the terminal position in the plane direction and centered on the direction of the imaging elevation angle and in the vertical direction by a predetermined angular width δ. It may be a space. Further, the far end of these target areas can be defined in the same manner as in the above embodiment. With the configuration of this additional embodiment, various illumination controls by three-dimensional lamp position specification are realized.

<First Embodiment, Additional Example 2>
FIG. 5 is a block diagram of a lighting control system 1 according to an additional embodiment 2 in which an additional function is added to the basic embodiment. In this additional embodiment, the same components as those in the embodiment shown in FIG. 1 are denoted by the same reference numerals, and redundant description thereof is omitted.

  As shown in FIG. 5, the CPU 30 of the mobile terminal 2 further includes an additional information processing unit 36 and an operation information output unit 37. The CPU 60 of the server 3 further includes a control restriction unit 63.

  The additional information processing unit 36 can acquire additional information regarding the target lamp 4t specified by the lamp specifying unit 61 and output the additional information to the touch panel 20. The additional information may include the lamp ID of the target lamp 4t and information on the irradiation target when there is an irradiation target (such as an object) of the target lamp 4t. Moreover, when the lamp 4 is installed in a building or an object, information on the building or the object itself may be included in the additional information. Such additional information can be acquired from the memory 70 of the server 3 or the Internet 5. Further, as described later, when it is identified that the target lamp 4t is controllable or uncontrollable, that fact may be included in the additional information. For example, as shown in FIG. 6, “lamp B control OK” or the like may be displayed as the additional information for the image of the lamp 4-2 in the image area 21. As described above, AR (Augmented Reality), that is, augmented reality, improves information and operability in lighting control.

  When any of the icons is touched, the operation information output unit 37 displays for visually expressing the operation performed on the icon area 22 (in other words, control based on the touch operation proceeds). (Display indicating that it is in the middle) is output to the touch panel 20. For example, the operation information output unit 37 may blink or highlight the touched icon, or may output an animation or the like extending from the touched icon toward the image of the lamp. The approximate position of the lamp image that is the end point of the animation (image position of the light source) can be specified as the brightest region in the image. In the example illustrated in FIG. 6, a wedge-shaped pattern that progresses from the vicinity of the icon 224 toward the lamp (light source) image portion in accordance with the touch operation of the icon 224 is displayed on the touch panel 20. Such an animation is not limited to the illustrated one. For example, a concentric arc-shaped pattern that simulates the diffusion of radio waves goes from the icon area 22 to the lamp image portion, and a straight line that simulates a light ray extends from the icon area 22 to the lamp. Various modes, such as what runs in an image part, can be employ | adopted. Thereby, the operativity and entertainment property in lighting control improve.

  The control restriction unit 63 restricts lighting control of the lamp 4 by the user. For example, when the target lamp 4t specified by the lamp specifying unit 61 is already controlled by another user, the control restriction unit 63 may prohibit new illumination control on the target lamp 4t. Further, the control restriction unit 63 may prohibit the lighting control for the lamp 4 outside the predetermined time. For example, lighting control during the daytime period may be prohibited in consideration of energy saving, and lighting control in the midnight time period may be prohibited in consideration of security, noise, and the like. Thus, when prohibiting illumination control, the control restriction unit 63 stops the generation of the illumination control signal by the signal generation unit 62. Thereby, the manageability of the illumination control system 1 is improved.

  Further, when the lighting control is prohibited by the control restriction unit 63 as described above, as described above, a notification indicating that the target lamp 4t is not controllable is transmitted from the server 3 to the portable terminal 2 as additional information. A message may be displayed on the touch panel 20. Thereby, the useless operation after that in a user is prevented. Conversely, when there is no prohibition operation by the control restriction unit 63, a notification indicating that the target lamp 4t can be controlled is transmitted from the server 3 to the portable terminal 2 as additional information, and this is displayed on the touch panel 20. You may make it be performed (refer FIG. 6).

  Further, the control restriction unit 63 may adjust the center angle α (or the center β, the center angle γ, or the angle width δ) that defines the target region R according to the transmission frequency of the illumination control signal. For example, in accordance with an increase in the transmission frequency of the illumination control signal (that is, in response to a relatively large number of users trying to control the lamps 4-1 to 4-n), the control limiting unit 63 has the center angle α (Or the center β, the center angle γ, or the angle width δ) may be narrowed. Further, the control restriction unit 63 may adjust the far end of the target region R according to the transmission frequency of the illumination control signal. For example, the control limiting unit 63 may bring the far end of the target region R closer to the terminal position in accordance with the increase in the transmission frequency of the illumination control signal. As described above, by narrowing the target area R when the user operation is congested, more users can enjoy the illumination control.

<Second Embodiment>
In the first embodiment, the illumination control system 1 includes the mobile terminal 2 and the server 3. However, in the present embodiment, the illumination control system is configured without using the server 3.

  FIG. 7 shows a block diagram of the lighting control system 1A of the present embodiment. In the present embodiment, elements having the same functions as those in the first embodiment are denoted by the same reference numerals, and redundant description thereof is omitted. The lighting control system 1 </ b> A includes a mobile terminal 2, lamps 4-1 to 4-n and the Internet 5. That is, the portable terminal 2 can communicate with each lamp 4 via the Internet 5.

  The portable terminal 2 includes a camera 10, a touch panel 20, a CPU 30, positioning means 33a, an electronic compass 34a, a memory 40, and a terminal communication unit 50. As an outline, the functions of the CPU 30 of the present embodiment substantially correspond to the functions of the CPU 30 and the CPU 60 of the first embodiment, and the function of the memory 40 of the present embodiment is the function of the memories 40 and 70 of the first embodiment. Substantially corresponds to.

  The CPU 30 includes an icon output unit 31, a control content determination unit 32, a position acquisition unit 33, an orientation acquisition unit 34, a lamp specification unit 61, and a signal generation unit 62. Note that the command information generation unit 35 may not be included. Further, the CPU 30 may optionally include an additional information processing unit 36 and an operation information output unit 37.

  It is assumed that an application for executing this embodiment is already installed in the memory 40 from the Internet 5. The memory 40 stores a correspondence relationship between the ID of each lamp 4 and the lamp position including the latitude and longitude of each lamp 4. However, from the viewpoint of the processing capacity of the CPU 30 and the storage capacity of the memory 40, the memory 40 may store a part of the data of the lamp 4 stored in the memory 70 of the first embodiment. For example, the memory 40 includes a lamp 4 installed in a region (a specific prefecture, city, ward, etc.) in which the user of the mobile terminal 2 lives, and a lamp installed in a specific facility (park, etc.) used by the user. Four data can be stored.

  FIG. 8A shows a flowchart for explaining the operation of the illumination control system 1A in the normal photographing mode. Steps S200 to S217 are the same as the processing shown in FIG. 4A of the first embodiment. That is, the application is activated in step S200, an icon is output to the touch panel 20 in step S205, and shooting by the camera 10 is started in step S206. When the touch operation on the icon is performed (step S210, Yes), the lighting control content is determined in accordance with the touch operation in step S215. In step S216, the terminal position at the time of the touch operation is acquired, and in step S217, the shooting direction at the time of the touch operation is acquired.

In step S255, the lamp specifying unit 61 specifies the target region R based on the terminal position and the shooting direction acquired by the position acquiring unit 33 and the azimuth acquiring unit 34 and the preset central angle, and the memory 40 is stored. The lamp 4 included in the target region R is specified as the target lamp 4t with reference to the target area R.
In step S260, the signal generation unit 62 generates an illumination control signal for causing the target lamp 4t to execute the illumination control content included in the command information, and the terminal communication unit 50 transmits the illumination control signal to the target lamp 4t. .

  Steps S400 and S405 in the lamp 4 are the same as the processing in the first embodiment. That is, in step S400, an illumination control signal is received, and in step S405, lighting of the light source 94 is controlled based on the illumination control signal.

  FIG. 8B shows a flowchart for explaining the operation of the illumination control system 1A in the still image mode. Steps S200 to S245 are the same as the processing shown in FIG. 4B of the first embodiment. That is, when the application is activated in step S200, an icon is output to the touch panel 20 in step S205, and a still image is captured (step S230, Yes), the captured still image of the lamp 4 is displayed in the image area in step S235. 21. In step S236, the terminal position at the time of shooting is acquired, and in step S237, the shooting direction at the time of shooting is acquired. When the touch operation on the icon is not performed (step S240, No), and when the display of the still image is finished (step S241, Yes), the process returns to step S230, and the touch operation on the icon is not performed. If (Step S240, No) and the display of the still image has not ended (Step S241, No), the process returns to Step S240. When the touch operation on the icon is performed (step S240, Yes), the lighting control content is determined in accordance with the touch operation in step S245.

  Steps S255 and S260 and steps S400 and S405 are the same as the processing shown in FIG. 8A. That is, the lamp 4 included in the target region R is specified as the target lamp 4t in step S255, and an illumination control signal is generated and transmitted to the target lamp 4t in step S260. In the lamp 4, the illumination control signal is received in step S400, and the light source 94 is controlled to be turned on based on the illumination control signal in step S405.

  As described above, in the lighting control system 1A according to the present embodiment, the mobile terminal 2 outputs an icon indicating lighting control options on the touch panel 20 and the touch panel 20 on which the camera 10 and the photographing lamp 4c are displayed. Unit 31, a control content determination unit 32 that determines illumination control content based on a touch operation on an icon, a position acquisition unit 33 that acquires a terminal position composed of the latitude and longitude of the mobile terminal 2 by positioning means 33a, and a camera 10 based on the orientation acquisition unit 34 that acquires the shooting direction by the electronic compass 34a, the memory 40 that stores the lamp position including the latitude and the longitude for each of the plurality of lamps 4, and the terminal position, the shooting direction, and the lamp position. The lamp specifying unit 61 that specifies the target lamp 4t corresponding to the photographing lamp 4c from the plurality of lamps 4 and the target lamp 4t are illuminated. It includes a signal generator 62 for generating a lighting control signal for executing the control content.

  Thus, as in the first embodiment, when the user of the portable terminal 2 photographs the lamp 4 with the camera 10 and selects an icon corresponding to the lighting control content, the acquired terminal position and photographing direction are stored. The target lamp 4t corresponding to the photographing lamp 4c is specified based on the position of the lamp, and the lighting control content is executed in the target lamp 4t. Thus, information that needs to be stored in advance is each lamp position (latitude and longitude) for identification of each lamp, and such information is easy to obtain and process. In addition, the user can perform illumination control of the photographing lamp 4c by an intuitive operation only by photographing the lamp and selecting an icon. Therefore, in the lighting control system 1A that controls the lighting of the lamp 4 using the portable terminal 2, a configuration that is easy to introduce and can be operated intuitively is realized. In particular, in the present embodiment, a memory 40 that stores lamp positions, a lamp specifying unit 61 that specifies a target lamp, and a signal generation unit 62 that generates an illumination control signal are provided in the portable terminal 2. Since the illumination control system 1A is configured, the illumination control system 1A having a simple configuration is realized.

<Program>
In addition, each component which implement | achieves the illumination control system 1 or 1A (CPU30 and 60) in each embodiment mentioned above and each step of a process operate | move the program memorize | stored in RAM or ROM of the memory 40 or 70, etc. It is realized by.

  In the present invention, the software program (the program corresponding to the flowchart shown in any one of FIGS. 4A, 4B, 8A, and 8B) that realizes the functions of the above embodiments is used in the lighting control system 1 or 1A (mobile phone). The case where the data is supplied directly to the terminal 2 or the server 3) or remotely is also included. Therefore, the program code itself installed in the lighting control system 1 or 1A (the portable terminal 2 or the server 3) in order to realize the functional processing of the present invention is also included in the present invention. That is, the present invention includes a computer program for realizing the functional processing of the present invention. The program includes a computer such as the portable terminal 2 and the server 3, the icon output unit 31, the control content determination unit 32, the position acquisition unit 33, the direction acquisition unit 34, the command information generation unit 35, the additional information processing unit 36, It can function as all or part of the operation information output unit 37, the lamp specifying unit 61, the signal generation unit 62, and the control restriction unit 63. As described above, according to the present invention, the operational effects as shown in the above-described embodiment can be realized by the introduction of software, so that the ease of introduction of the illumination control system 1 or 1A can be improved.

  The program may be downloaded from the Internet. In this case, the computer program or the compressed file including the automatic installation function is downloaded from the homepage to the lighting control system 1 or 1A connected to the homepage on the Internet by the browser function.

<Modification>
Although preferred embodiments of the present invention have been described above, the present invention can be modified into various modes as shown below, for example.

(1) Modification concerning lamp 4 In each of the above embodiments, each lamp 4 has been described as an outdoor lighting device. However, when the positioning accuracy of the GPS or Beacon constituting the positioning means 33a is ensured, The present invention is also applicable when each lamp 4 is an indoor lighting device.

(2) Modification Regarding Network 5 In the above embodiments, the network 5 is configured as the Internet. However, when the lighting control system 1 or 1A is relatively small, the network 5 is configured by a dedicated line. May be.

(3) Modifications related to photographing by the camera 10 In each of the embodiments described above, an example in which the mobile terminal 2 that is a smartphone is used on a vertical screen has been shown, but the mobile terminal 2 may be used on a horizontal screen. Further, in each of the above embodiments, the configuration in which the camera 10 is a camera on the back side of the touch panel 20 has been described. (Configuration).

DESCRIPTION OF SYMBOLS 1, 1A Lighting control system 2 Portable terminal 3 Server 4, 4-1 to 4-n Lamp 5 Network (Internet)
10 Camera 20 Touch panel 30 CPU
31 Icon output unit 32 Control content determination unit 33 Position acquisition unit 33a Positioning means 34 Direction acquisition unit 34a Electronic compass 35 Command information generation unit 36 Additional information processing unit 37 Operation information output unit 40 Memory 50 Terminal communication unit 60 CPU
61 Lamp Specification Unit 62 Signal Generation Unit 63 Control Limiting Unit 70 Memory 80 Server Communication Unit 90 Lamp Communication Unit 92 Lighting Device 94 Light Source

Claims (12)

A lighting control system for controlling a lamp from a portable terminal,
A camera of the mobile terminal;
A touch panel of the portable terminal on which an image of a lamp taken by the camera is displayed;
An icon output unit for outputting an icon indicating lighting control options on the touch panel;
A control content determination unit that determines illumination control content based on a touch operation on the icon;
A position acquisition unit for acquiring a terminal position composed of the latitude and longitude of the mobile terminal by positioning means;
An azimuth acquisition unit for acquiring a shooting azimuth by the camera using an electronic compass;
A memory for storing a lamp position composed of latitude and longitude for each of a plurality of lamps;
A lamp specifying unit that specifies a target lamp corresponding to the photographed lamp from the plurality of lamps based on the terminal position, the shooting direction, and the lamp position;
The illumination control system provided with the signal generation part which produces | generates the illumination control signal for making the said object lamp perform the said illumination control content. A lighting control system for controlling a lamp from the portable terminal, including a portable terminal and a server,
The mobile terminal is
A camera,
A touch panel on which an image of a lamp taken by the camera is displayed;
An icon output unit for outputting an icon indicating lighting control options on the touch panel;
A control content determination unit that determines illumination control content based on a touch operation on the icon;
A position acquisition unit for acquiring a terminal position composed of the latitude and longitude of the mobile terminal by positioning means;
An azimuth acquisition unit for acquiring a shooting azimuth by the camera using an electronic compass;
A command information generating unit that generates command information including the illumination control content, the terminal position, and the shooting direction;
A terminal communication unit that transmits the command information to the server,
The server is
A memory for storing a lamp position composed of latitude and longitude for each of a plurality of lamps;
A server communication unit for receiving the command information;
A lamp identifying unit that identifies a target lamp corresponding to the photographed lamp from the plurality of lamps, based on the received terminal position and the shooting direction, and the stored lamp position;
A lighting control system comprising: a signal generation unit that generates a lighting control signal for causing the target lamp to execute the received lighting control content. A lighting control system for controlling a lamp from a portable terminal,
The mobile terminal is
A camera,
A touch panel on which an image of a lamp taken by the camera is displayed;
An icon output unit for outputting an icon indicating lighting control options on the touch panel;
A control content determination unit that determines illumination control content based on a touch operation on the icon;
A position acquisition unit for acquiring a terminal position composed of the latitude and longitude of the mobile terminal by positioning means;
An azimuth acquisition unit for acquiring a shooting azimuth by the camera using an electronic compass;
A memory for storing a lamp position composed of latitude and longitude for each of a plurality of lamps;
A lamp specifying unit that specifies a target lamp corresponding to the photographed lamp from the plurality of lamps based on the terminal position, the shooting direction, and the lamp position;
An illumination control system comprising: a signal generation unit that generates an illumination control signal for causing the target lamp to execute the illumination control content.   2. The lamp specifying unit is configured to specify, as the target lamp, a lamp whose lamp position is included in a target area defined by a predetermined central angle centered on the shooting direction from the terminal position. The lighting control system according to any one of claims 1 to 3. The position acquisition unit is configured to acquire the altitude of the mobile terminal in addition to the latitude and longitude by the positioning means,
The azimuth acquiring unit is configured to acquire a shooting elevation angle of the camera by the electronic compass in addition to the shooting azimuth,
The lamp position is defined by the latitude, longitude and altitude of the lamp;
The lamp specifying unit specifies, as the target lamp, a lamp whose lamp position is included in a conical or polygonal pyramid target area extending from the terminal position in the shooting axis direction defined by the shooting direction and the shooting elevation angle. The illumination control system according to claim 1, configured as described above.   The lighting control system according to claim 4 or 5, wherein the lamp specifying unit is configured to define a far end of the target area according to a radius from the terminal position or a grouping of the plurality of lamps. . The lamp specifying unit is configured to specify, as the target lamp, a lamp whose lamp position is included in a target area defined by a predetermined central angle centered on the shooting direction from the terminal position,
The lighting control system according to claim 2, wherein the server further includes a control limiting unit configured to narrow the central angle with respect to an increase in the transmission frequency of the lighting control signal. The lamp specifying unit specifies, as the target lamp, a lamp whose lamp position is included in a target area defined by a predetermined central angle from the terminal position with the photographing direction as a center, and a far end of the target area is defined as the target lamp. Configured to determine according to a radius from the terminal position or grouping of the plurality of lamps,
The lighting control system according to claim 2, wherein the server further includes a control limiting unit configured to bring the far end position closer to the terminal position with respect to an increase in the transmission frequency of the lighting control signal.   The image is a real-time image, and the position acquisition unit and the direction acquisition unit are configured to acquire the terminal position and the shooting direction at the time when the touch operation is performed, respectively. The lighting control system according to any one of the above.   The image is a still image, and the position acquisition unit and the orientation acquisition unit are configured to acquire the terminal position and the imaging orientation at the time when the still image was captured, respectively. The lighting control system according to any one of the above.   11. The lamp according to claim 1, further comprising a lamp communication unit that receives the illumination control signal, a light source, and a lighting device that controls a lighting state of the light source based on the illumination control signal. Lighting control system. The program for functioning a computer as each part with which the illumination control system as described in any one of Claims 1-11 is provided.

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