JP6326850B2 - Operating device and lighting control system - Google Patents

Description

  Embodiments described herein relate generally to an operating device and a lighting control system.

  2. Description of the Related Art There is an illumination device that emits single white light or full color light using a plurality of LEDs (Light Emitting Diodes) that emit different colors as a light source as a lighting device for production in a stage or a studio. For example, as an illumination device that emits white light, there is an illumination device that uses a color sensor to perform feedback control to bring the color of the emitted white light closer to a desired color (see, for example, Patent Document 1).

  In addition, a plurality of lighting devices for the above-described effects are used in a stage or a studio, for example, the same color (for example, a color such as red or white) is applied to the floor of the stage to emit the same color. It is controlled to light up the floor of the stage. For example, in order to illuminate the floor of the stage with red light, control is performed so that each of a plurality of lighting devices for production is irradiated with red light.

Special table 2007-535114 public information

  However, even if it is controlled to irradiate a predetermined color of light to each of a plurality of lighting devices for production at a stage or a studio, the color of the light emitted by each of the lighting devices is May be different. For example, even if it is controlled to emit red light, a certain lighting device emits reddish red light, and another lighting device emits yellowish red light. In some cases, light may be irradiated. This may be due to, for example, that the characteristics of the color of light emitted from different manufacturers of lighting devices are different, or that the color of the emitted light changes because the lighting device itself has deteriorated over time. . In such a case, since the color of light emitted from each of the lighting devices is different, the color of the light emitted to the stage or the studio is different.

  An object of the present invention is to provide an operating device and an illumination control system that can suppress the difference in color of light emitted from each of a plurality of illumination devices.

  The operation device according to the embodiment includes a specifying unit that specifies a chromaticity range that can be irradiated by all the illumination devices from a plurality of illumination light chromaticity ranges of a plurality of illumination devices each having a different chromaticity range of irradiation light. It has. The operation device of the embodiment includes an irradiation control unit that controls a plurality of illumination devices so as to perform irradiation in the chromaticity range specified by the specifying unit.

  According to the operation device of the embodiment, an effect that a difference in color of light emitted from each of the plurality of illumination devices can be suppressed can be expected.

Drawing 1 is a figure showing an example of the composition of the lighting control system concerning an embodiment. FIG. 2 is a diagram illustrating an example of the configuration of the illumination device. FIG. 3 is a diagram illustrating an example of the configuration of the operation device. FIG. 4 is a diagram illustrating an example of the data structure of the lighting device table. FIG. 5 is a diagram illustrating an example of the data structure of the correction table. FIG. 6 is a diagram for explaining an example of the chromaticity range. FIG. 7 is a flowchart illustrating a flow of chromaticity range adjustment processing executed by the operation device according to the embodiment. FIG. 8 is a flowchart illustrating a flow of irradiation control processing executed by the operation device according to the embodiment.

  In the operation device 2 according to the embodiment described below, all the illumination devices 10a to 10c are out of the plurality of illumination light chromaticity ranges of the plurality of illumination devices 10a to 10c having different illumination light chromaticity ranges. A specifying unit 8b that specifies the chromaticity range that can be irradiated is provided. And the operating device 2 comprises the irradiation control part 8c which controls the some illuminating devices 10a-10c so that it may irradiate in the chromaticity range specified by the specific part 8b.

  Moreover, the specific | specification part 8b demonstrated below specifies the smallest chromaticity range as a chromaticity range which all the illuminating devices 10a-10c can irradiate among the chromaticity ranges of several irradiation light.

  In addition, when the smallest chromaticity range is not included in all chromaticity ranges, the specifying unit 8b described below sets the maximum chromaticity range included in all chromaticity ranges to all the lighting devices 10a. -10c is specified as an irradiable chromaticity range.

  Moreover, the operating device 2 described below is based on the image obtained by imaging the place irradiated with the light emitted from each of the plurality of lighting devices 10a to 10c, and the plurality of lighting devices 10a to 10c. The measurement part 8a which measures the chromaticity of the light irradiated from each of these is comprised. And the specific | specification part 8b specifies the chromaticity range of the some irradiated light of several illuminating devices 10a-10c based on the chromaticity measured by the measurement part 8a, and the chromaticity range of the specified some irradiated light The chromaticity range that can be irradiated by all of the lighting devices 10a to 10c is specified.

  Moreover, the illumination control system 1 demonstrated below comprises the some illuminating device 10a-10c from which the chromaticity range of irradiation light differs, and the operation device 2, respectively.

  Hereinafter, an operation device and a lighting control system according to an embodiment will be described with reference to the drawings. In addition, the operation device and the illumination control system described in the following embodiments are merely examples, and do not limit the present invention.

[Configuration of lighting control system]
Drawing 1 is a figure showing an example of the composition of lighting control system 1 concerning an embodiment. As shown in FIG. 1, the lighting control system 1 according to the present embodiment includes an operating device 2, a plurality of lighting devices 10 a to 10 c, a node 20, a HUB (hub) 21, and an access point 22. In the illumination control system 1, when the user inputs a specification of the brightness level (dimming ratio (%)) of light emitted from the illumination devices 10a to 10c to the operation device 2, the illumination devices 10a to 10c. The brightness of the light emitted from the light source substantially matches the designated dimming ratio. Hereinafter, when each of the lighting devices 10a to 10c is described without being distinguished, the lighting devices 10a to 10c may be simply referred to as “lighting device 10”.

  The illuminating device 10 is, for example, an effect light for a stage or a studio. FIG. 2 is a diagram illustrating an example of the configuration of the illumination device. As shown in the example of FIG. 2, the illumination device 10 includes a control unit 11, drive circuits 12a to 12c, a plurality of light emitting elements 13a that emit red light, a plurality of light emitting elements 13b that emit green light, A light emitting element 13c that emits blue light. Hereinafter, when the description is made without distinguishing each of the drive circuits 12a to 12c, it is simply referred to as “drive circuit 12”, and when the explanation is made without distinguishing each of the light emitting elements 13a to 13c, , May be referred to as “light emitting element 13”.

  The control unit 11 controls the operation of the entire lighting device 10. The control unit 11 performs the following processing in addition to performing known control of the effect light. For example, when receiving the DMX signal transmitted from the node 20, the control unit 11 acquires a light emitting element ID (Identification) added to the received DMX signal. The light emitting element ID is an identifier for identifying the light emitting elements 13a to 13c. The DMX signal is a digital signal used in a production field or the like standardized by the American Theater Technology Association (USITT), and indicates a DMX 512 used as a standard of a dimming signal for dimming control. The 0th to 255th gradations of the DMX signal correspond to a dimming ratio of 0% to 100%. Then, the control unit 11 generates a PWM signal having a duty ratio corresponding to the gradation indicated by the DMX signal. And the control part 11 transmits the produced | generated PWM signal to the drive circuit 12 connected to the light emitting element 13 which acquired light emitting element ID shows. Examples of the hardware of the control unit 11 include a microcomputer having a central processing unit (CPU), a read only memory (ROM), and a random access memory (RAM).

  The drive circuits 12a to 12c each control the brightness of light emitted by the corresponding type of light emitting element. The drive circuit 12a is provided corresponding to the plurality of light emitting elements 13a, and is connected to the plurality of light emitting elements 13a. The drive circuit 12b is provided corresponding to the plurality of light emitting elements 13b, and is connected to the plurality of light emitting elements 13b. The drive circuit 12c is provided corresponding to the plurality of light emitting elements 13c, and is connected to the plurality of light emitting elements 13c.

  The drive circuit 12a supplies power to the plurality of light emitting elements 13a according to the duty ratio of the PWM signal input by the control unit 11, thereby emitting a plurality of lights with brightness according to the duty ratio of the PWM signal. The light emitting element 13a is controlled.

  The drive circuit 12b supplies a plurality of light emitting elements 13b according to the duty ratio of the PWM signal input by the control unit 11 to emit light having brightness according to the duty ratio of the PWM signal. The light emitting element 13b is controlled.

  The drive circuit 12c supplies a plurality of light emitting elements 13c according to the duty ratio of the PWM signal input by the control unit 11 to emit light with brightness according to the duty ratio of the PWM signal. The light emitting element 13c is controlled.

  Each of the plurality of light emitting elements 13a is an LED that emits red light (for example, light having a peak wavelength of 570 nm to 690 nm).

  Each of the plurality of light emitting elements 13b is an LED that emits green light (for example, light having a peak wavelength of 460 nm to 630 nm).

  Each of the plurality of light emitting elements 13c is an LED that emits blue light (for example, light having a peak wavelength of 420 nm to 530 nm).

  Returning to the description of FIG. 1, when the node 20 receives the dimming signal transmitted from the controller 2 via the HUB 21 and the access point 22, the lighting device ID and the light emitting element ID added to the received dimming signal. To get. The illumination device ID is an identifier for identifying the illumination devices 10a to 10c. Then, the node 20 specifies a gradation corresponding to the dimming ratio indicated by the received dimming signal. Then, the node 20 generates a DMX signal indicating the specified gradation. Then, the node 20 adds the acquired light emitting element ID to the generated DMX signal. Then, the node 20 transmits the DMX signal to which the light emitting element ID is added to the lighting device 10 indicated by the acquired lighting device ID.

  The HUB 21 is a device that connects the node 20 and the access point 22. When the HUB 21 receives the dimming signal transmitted from the access point 22, the HUB 21 transmits the received dimming signal to the node 20.

  The access point 22 performs wireless communication with the controller 2 using various wireless technologies. For example, when the access point 22 receives the dimming signal transmitted from the controller 2 by wireless communication, the access point 22 transmits the received dimming signal to the HUB 21.

  The operation device 2 is a terminal owned by a user who adjusts the color of light emitted from the lighting device 10. For example, the operation device 2 is a smartphone or a tablet on which an imaging unit such as a camera is mounted.

  FIG. 3 is a diagram illustrating an example of the configuration of the operation device 2. As illustrated in the example of FIG. 3, the operation device 2 includes an input unit 3, a display unit 4, an imaging unit 5, a communication unit 6, a storage unit 7, and a control unit 8.

  When the input unit 3 receives a user instruction or operation, the input unit 3 inputs the received instruction or operation to the control unit 8. Examples of the hardware of the input unit 3 include a receiving device such as a touch panel that receives user instructions and operations.

  The display unit 4 displays various information by display control by the control unit 8. Examples of the hardware of the display unit 4 include a display such as an LCD (Liquid Crystal Display).

  When the imaging unit 5 receives an imaging instruction from the control unit 8, the imaging unit 5 images a subject existing within the viewing angle and inputs an image obtained as a result of the imaging to the control unit 8. An example of the hardware of the imaging unit 5 is a camera.

  The communication unit 6 performs wireless communication with the access point 22. Examples of the hardware of the communication unit 6 include a network interface card that performs wireless communication.

  The storage unit 7 stores a lighting device table 7a, xy chromaticity diagram data 7b, and a correction table 7c. Examples of the hardware of the storage unit 7 include a storage device such as a hard disk.

  The illumination device table 7a is a table in which illumination device IDs indicating the illumination devices 10 existing in the illumination control system 1 are registered. FIG. 4 is a diagram illustrating an example of a data structure of the lighting device table 7a. As illustrated in the example of FIG. 4, the lighting device table 7 a includes an item “lighting device ID”. In the item “illumination device ID”, the illumination device ID of the illumination device 10 existing in the illumination control system 1 is registered. For example, in the example of FIG. 4, in the item “illumination device ID”, the illumination device ID “AA” indicating the illumination device 10a, the illumination device ID “BB” indicating the illumination device 10b, and the illumination device indicating the illumination device 10c. ID “CC” is registered.

  The xy chromaticity diagram data 7b is a CIE (Commission International de l'Eclairage) chromaticity diagram.

  In the correction table 7c, the dimming rate of each light emitting element 13a, the dimming rate of the light emitting element 13b, and the light emission when the color of light emitted from each of the lighting devices 10a to 10c is approximate. The dimming rate of the element 13c is registered in association with the irradiation control unit 8c described later.

  FIG. 5 is a diagram illustrating an example of the data structure of the correction table 7c. The example of FIG. 5 shows an example of the correction table 7c in which the dimming rate is registered by the irradiation control unit 8c. For example, in the first record of the correction table 7c shown in the example of FIG. 5, each of the illumination devices 10a to 10c in the case where the color of the light emitted from each of the illumination devices 10a to 10c is red and approximates is red. The light control rate of the light emitting element 13a, the light control rate of the light emitting element 13b, and the light control rate of the light emitting element 13c are shown. That is, in the first record, when the light color (red) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10a indicated by the lighting device ID “AA” is 100%, and the light emitting element 13b. The dimming rate is 0%, and the dimming rate of the light emitting element 13c is 0%. In the first record, when the light color (red) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10b indicated by the lighting device ID “BB” is 80%, and the light emitting element 13b. The dimming rate is 20%, and the dimming rate of the light emitting element 13c is 5%. In the first record, when the light color (red) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10c indicated by the lighting device ID “CC” is 80%, and the light emitting element 13b The dimming rate is 5%, and the dimming rate of the light emitting element 13c is 20%.

  In the second record of the correction table 7c shown in the example of FIG. 5, the color of light emitted from each of the illumination devices 10a to 10c is green, and each of the illumination devices 10a to 10c in the case of approximation is used. The light control rate of the light emitting element 13a, the light control rate of the light emitting element 13b, and the light control rate of the light emitting element 13c are shown. That is, in the second record, when the light color (green) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10a indicated by the lighting device ID “AA” is 0%, and the light emitting element 13b. The dimming rate is 100%, and the dimming rate of the light emitting element 13c is 0%. In the second record, when the light color (green) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10b indicated by the lighting device ID “BB” is 20%, and the light emitting element 13b. The light control rate is 80%, and the light control rate of the light emitting element 13c is 5%. In the second record, when the light color (green) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10c indicated by the lighting device ID “CC” is 5%, and the light emitting element 13b The light control rate is 80%, and the light control rate of the light emitting element 13c is 20%.

  Further, in the third record of the correction table 7c shown in the example of FIG. 5, each of the illumination devices 10a to 10c in the case where the color of the light emitted from each of the illumination devices 10a to 10c is blue and is approximated. The light control rate of the light emitting element 13a, the light control rate of the light emitting element 13b, and the light control rate of the light emitting element 13c are shown. That is, in the third record, when the color of light (blue) is approximate, the dimming rate of the light emitting element 13a of the lighting apparatus 10a indicated by the lighting apparatus ID “AA” is 0%, and the light emitting element 13b. This indicates that the light control rate is 0%, and the light control rate of the light emitting element 13c is 100%. In the third record, when the light color (blue) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10b indicated by the lighting device ID “BB” is 20%, and the light emitting element 13b The dimming rate of 5 is 5%, and the dimming rate of the light emitting element 13c is 80%. In the third record, when the light color (blue) is approximate, the dimming rate of the light emitting element 13a of the lighting device 10c indicated by the lighting device ID “CC” is 5%, and the light emitting element 13b The dimming rate is 20%, and the dimming rate of the light emitting element 13c is 80%.

  The control unit 8 controls the overall operation of the operation device 2. The control part 8 controls the whole so that operation of operation devices, such as a well-known smart phone and a tablet, is performed. Moreover, the control part 8 has the measurement part 8a, the specific | specification part 8b, and the irradiation control part 8c. Examples of the hardware of the control unit 8 include a microcomputer having a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). The CPU reads a program stored in the ROM, expands the read program in the RAM, and executes the program expanded in the RAM. When the CPU that executes the program is functionally expressed as described above, the CPU includes the measurement unit 8a, the specifying unit 8b, and the irradiation control unit 8c.

  The measuring unit 8a measures a chromaticity range that is a chromaticity range of the lighting devices 10a to 10c. For example, when an instruction to execute chromaticity range adjustment processing is input from the user to the measurement unit 8a via the input unit 3, the measurement unit 8a refers to the illumination table 6a and the illumination device registered in the illumination table 6a Select one ID at a time. For example, as shown in the example of FIG. 4, when “AA”, “BB”, and “CC” are registered as the illumination device IDs in the illumination table 6 a, the measurement unit 8 a uses “AA”, “ BB "and" CC "are selected one by one.

  Here, the measurement part 8a performs the process demonstrated below, whenever one illumination apparatus ID is selected. That is, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 100%, and adds the selected lighting device ID and the light emitting element ID “aa” indicating the light emitting element 13a to the generated dimming signal. . Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “aa” are added to the access point 22. Further, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and the light emitting element ID “bb” indicating the light emitting element 13b to the generated dimming signal. . Then, the measurement unit 8 a controls the communication unit 6 so as to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “bb” are added to the access point 22. In addition, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and the light emitting element ID “cc” indicating the light emitting element 13c to the generated dimming signal. . Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “cc” are added to the access point 22. Thereby, red light is emitted from the light emitting element 13a of the lighting device 10 indicated by the selected lighting device ID with a brightness corresponding to the dimming ratio of 100%.

  And the measurement part 8a displays the message to the effect of imaging the red light irradiated from the illuminating device 10 which the selected illuminating device ID shows on the display part 4. FIG. For example, when the selected lighting device ID is “AA”, the measuring unit 8a indicates that “the lighting device A (the name of the lighting device 10a) irradiates the floor surface of the stage with red light. “Display the red light irradiated on the floor with a camera.” Is displayed on the display unit 4. When the user points the camera of the operation device 2 toward the floor surface irradiated with light and inputs an imaging instruction to the measurement unit 8a via the input unit 3, the measurement unit 8a issues an imaging instruction to perform imaging. Output to the imaging unit 5. Thereby, the imaging part 5 images the floor surface irradiated with red light, and outputs the image obtained as a result of the imaging to the measuring part 8a.

  When the measurement unit 8a receives the image output from the imaging unit 5, the measurement unit 8a analyzes the received image, derives the RGB mixing ratio of the red light irradiated on the floor, and x in the CIE chromaticity diagram. The coordinates and y coordinates are derived. In this way, the measurement unit 8a measures the chromaticity of red light emitted from the illumination device 10 indicated by the selected illumination device ID.

  Next, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 100%, and adds the selected lighting device ID and light emitting element ID “bb” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 so as to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “bb” are added to the access point 22. In addition, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and light-emitting element ID “aa” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “aa” are added to the access point 22. The measuring unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and light emitting element ID “cc” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “cc” are added to the access point 22. Accordingly, green light is emitted from the light emitting element 13b of the lighting device 10 indicated by the selected lighting device ID with a brightness corresponding to the dimming ratio of 100%.

  And the measurement part 8a displays on the display part 4 the message to the effect of imaging the green light irradiated from the illuminating device 10 which the selected illuminating device ID shows. For example, when the selected lighting device ID is “AA”, the measuring unit 8a indicates that “the lighting device A (the name of the lighting device 10a) irradiates the floor of the stage with green light. “Display the green light irradiated on the floor with a camera.” Is displayed on the display unit 4. When the user points the camera of the operation device 2 toward the floor surface irradiated with light and inputs an imaging instruction to the measurement unit 8a via the input unit 3, the measurement unit 8a issues an imaging instruction to perform imaging. Output to the imaging unit 5. Thereby, the imaging part 5 images the floor surface irradiated with green light, and outputs the image obtained as a result of imaging to the measurement part 8a.

  When the measurement unit 8a receives the image output from the imaging unit 5, the measurement unit 8a analyzes the received image to derive the RGB mixture ratio of green light irradiated on the floor surface, and x in the CIE chromaticity diagram. The coordinates and y coordinates are derived. In this way, the measurement unit 8a measures the chromaticity of the green light emitted from the illumination device 10 indicated by the selected illumination device ID.

  Next, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 100%, and adds the selected lighting device ID and light emitting element ID “cc” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “cc” are added to the access point 22. In addition, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and light-emitting element ID “aa” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “aa” are added to the access point 22. In addition, the measurement unit 8a generates a dimming signal indicating a dimming ratio of 0%, and adds the selected lighting device ID and light-emitting element ID “bb” to the generated dimming signal. Then, the measurement unit 8 a controls the communication unit 6 so as to transmit the dimming signal to which the selected lighting device ID and the light emitting element ID “bb” are added to the access point 22. As a result, blue light is emitted from the light emitting element 13c of the lighting device 10 indicated by the selected lighting device ID at a brightness corresponding to a dimming ratio of 100%.

  And the measurement part 8a displays the message to the effect of imaging the blue light irradiated from the illuminating device 10 which the selected illuminating device ID shows on the display part 4. FIG. For example, when the selected lighting device ID is “AA”, the measurement unit 8a indicates that “the lighting device A (the name of the lighting device 10a) irradiates the floor surface of the stage with blue light. “Display the blue light irradiated on the floor with a camera.” Is displayed on the display unit 4. When the user points the camera of the operation device 2 toward the floor surface irradiated with light and inputs an imaging instruction to the measurement unit 8a via the input unit 3, the measurement unit 8a issues an imaging instruction to perform imaging. Output to the imaging unit 5. Thereby, the imaging part 5 images the floor surface irradiated with the blue light, and outputs an image obtained as a result of the imaging to the measuring part 8a.

  When the measurement unit 8a receives the image output from the imaging unit 5, the measurement unit 8a analyzes the received image to derive the RGB mixing ratio of the blue light irradiated on the floor surface, and x in the CIE chromaticity diagram. The coordinates and y coordinates are derived. In this way, the measurement unit 8a measures the chromaticity of the blue light emitted from the illumination device 10 indicated by the selected illumination device ID.

  The measuring unit 8a performs the above-described process every time one lighting device ID registered in the lighting table 6a is selected. That is, the measurement unit 8a measures the chromaticity of red light, the chromaticity of green light, and the chromaticity of blue light emitted from each of the lighting devices 10a to 10c.

  Here, for example, when the lighting device 10a irradiates the floor with red light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.6) and the y coordinate (0.3). When the lighting device 10a irradiates the floor with green light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.2) and the y coordinate (0.7), and the lighting device 10a. Will be described when the measurement unit 8a derives the x coordinate (0.3) and the y coordinate (0.2) as a result of analyzing the image when the floor surface is irradiated with blue light. FIG. 6 is a diagram for explaining an example of the chromaticity range. In this case, as shown in FIG. 6, the measurement unit 8 a has a point V (0.6, 0.3), a point W (0.2, 0.7), and a point M (0.3, 0. 2) is plotted on the CIE chromaticity diagram indicated by the xy chromaticity diagram data 7b. And the measurement part 8a determines the triangular area | region which has the point V, the point W, and the point M as a vertex as a chromaticity range of the illuminating device 10a. In this way, the measurement unit 8a measures the chromaticity range of the illumination device 10a.

  Further, for example, when the lighting device 10b irradiates the floor with red light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.65) and the y coordinate (0.3), When the lighting device 10a irradiates the floor with green light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.15) and the y coordinate (0.75), and the lighting device 10a The case where the measurement unit 8a derives the x coordinate (0.25) and the y coordinate (0.15) as a result of analyzing the image when the floor surface is irradiated with blue light will be described. In this case, as shown in FIG. 6, the measurement unit 8 a has a point S (0.65, 0.3), a point T (0.15, 0.75), and a point U (0.25, 0. 15) is plotted on the CIE chromaticity diagram indicated by the xy chromaticity diagram data 7b. And the measurement part 8a determines the triangular area | region which has the point S, the point T, and the point U as a vertex as a chromaticity range of the illuminating device 10b. In this way, the measurement unit 8a measures the chromaticity range of the illumination device 10b.

  For example, when the lighting device 10c irradiates the floor with red light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.7) and the y coordinate (0.3), When the lighting device 10a irradiates the floor with green light, the measurement unit 8a analyzes the image, and as a result, derives the x coordinate (0.1) and the y coordinate (0.8), and the lighting device 10a The case where the measurement unit 8a derives the x coordinate (0.2) and the y coordinate (0.1) as a result of analyzing the image when the floor surface is irradiated with blue light will be described. In this case, the measurement unit 8a, as shown in FIG. 6, includes a point P (0.7, 0.3), a point Q (0.1, 0.8), and a point R (0.2, 0. 1) is plotted on the CIE chromaticity diagram indicated by the xy chromaticity diagram data 7b. And the measurement part 8a determines the triangular area | region which has the point P, the point Q, and the point R as a vertex as a chromaticity range of the illuminating device 10c. In this way, the measurement unit 8a measures the chromaticity range of the illumination device 10c.

  Returning to the description of FIG. 3, the specifying unit 8b can irradiate all the illumination devices 10a to 10c from among the plurality of chromaticity ranges of the plurality of illumination devices 10a to 10c having different chromaticity ranges of the irradiation light. Specify the degree range. For example, the specifying unit 8b specifies the chromaticity range having the smallest area among the chromaticity ranges of the lighting devices 10a to 10c. And the specific | specification part 8b determines whether the specified chromaticity range is contained in the chromaticity range of all the illuminating devices 10a-10c. When it determines with the specified chromaticity range being included in the chromaticity range of all the illuminating devices 10a-10c, the specific | specification part 8b uses the specified chromaticity range for all the illuminating devices 10a-10c. The chromaticity range that can be irradiated is specified. When it determines with the specified chromaticity range not being contained in the chromaticity range of all the illuminating devices 10a-10c, the specific | specification part 8b is the maximum contained in the chromaticity range of all the illuminating devices 10a-10c. The specified chromaticity range is specified, and the specified maximum chromaticity range is specified as the chromaticity range that can be irradiated by all of the lighting devices 10a to 10c.

  For example, when each chromaticity range of the lighting devices 10a to 10c is the chromaticity range illustrated in the example of FIG. 6, the specifying unit 8b includes the point V and the point W that are the chromaticity range having the smallest area. A triangular area having the point M as a vertex is specified as a chromaticity range that can be irradiated by all of the lighting devices 10a to 10c.

  The irradiation control unit 8c controls the plurality of lighting devices 10a to 10c so as to perform irradiation in a chromaticity range that can be irradiated by all the lighting devices 10a to 10c.

  One aspect of the irradiation control unit 8c will be described. Here, the chromaticity range of each of the lighting devices 10a to 10c is the chromaticity range shown in the example of FIG. 6, and points V, W, and M, which are the chromaticity ranges with the smallest areas, are the vertices. A case where a triangular region is specified as a chromaticity range that can be irradiated by all the illumination devices 10a to 10c will be described as an example. In this case, the irradiation control unit 8c generates a dimming signal indicating a predetermined initial dimming ratio R%, and adds the illumination device ID “BB” and the light emitting element ID “aa” to the generated dimming signal. . Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “aa” are added is transmitted to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a predetermined initial dimming ratio G%, and adds the illumination device ID “BB” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “bb” are added is transmitted to the access point 22. Further, the irradiation controller 8c generates a dimming signal indicating a predetermined initial dimming ratio B%, and adds the illumination device ID “BB” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “cc” are added is transmitted to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to the dimming ratio R%, green light having a brightness corresponding to the dimming ratio G%, and brightness corresponding to the dimming ratio B%. The light mixed with the blue light is irradiated.

  And the irradiation control part 8c displays on the display part 4 the message to the effect of imaging the light irradiated from the illuminating device 10b. For example, the illumination control unit 8c reads: “The illumination device B (name of the illumination device 10b) is irradiating light on the floor surface of the stage. Please capture the light emitted on the floor surface with a camera.” Is displayed on the display unit 4. When the user points the camera of the operation device 2 toward the floor irradiated with light and inputs an imaging instruction to the irradiation control unit 8c via the input unit 3, the irradiation control unit 8c performs imaging to perform imaging. An instruction is output to the imaging unit 5. Thereby, the imaging part 5 images the floor surface irradiated with light, and outputs the image obtained as a result of imaging to the irradiation control part 8c.

  When the irradiation control unit 8c receives the image output from the imaging unit 5, the irradiation control unit 8c analyzes the received image to derive the RGB mixing ratio of the light irradiated on the floor surface, and the x coordinate in the CIE chromaticity diagram. And the y-coordinate is derived. In this way, the irradiation control unit 8c measures the chromaticity of the light irradiated from the illumination device 10b.

  Then, the irradiation control unit 8c has a difference between the derived x-coordinate value and the x-coordinate value (0.6) of the point V equal to or less than a predetermined threshold value α, and the derived y-coordinate value; It is determined whether or not the difference between the point V and the y coordinate value (0.3) is equal to or less than a predetermined threshold value β. Note that the threshold value α and the threshold value β may be the same value. The difference between the derived x-coordinate value and the x-coordinate value (0.6) of the point V is less than or equal to a predetermined threshold value α, and the derived y-coordinate value and the y-coordinate value of the point V ( 0.3) is determined to be equal to or less than the predetermined threshold value β, the irradiation control unit 8c determines that the light control ratio of the light emitting element 13a of the illumination device 10a is 100% and the light control ratio of the light emitting element 13b is 0. % And the dimming ratio 0% of the light emitting element 13c are associated with the dimming ratio R% of the light emitting element 13a, the dimming ratio G% of the light emitting element 13b, and the dimming ratio B% of the light emitting element 13c. And registered in the correction table 7c. Here, when R = 80, G = 20, and B = 5, as shown in the example of FIG. 5, the irradiation control unit 8 c has a light control ratio of 100% of the light emitting element 13 a of the illumination device 10 a and emits light. The dimming ratio 0% of the element 13b and the dimming ratio 0% of the light emitting element 13c, the dimming ratio 80% of the light emitting element 13a of the lighting device 10b, the dimming ratio 20% of the light emitting element 13b, and the dimming of the light emitting element 13c. The ratio 5% is registered in association with the correction table 7c.

  On the other hand, the difference between the derived x-coordinate value and the x-coordinate value (0.6) of the point V is not less than a predetermined threshold value α, or the derived y-coordinate value and the y-coordinate of the point V If it is determined that the difference from the value (0.3) is not less than or equal to the predetermined threshold β, the irradiation control unit 8c performs the following process. That is, the irradiation control unit 8c has a difference between the derived x-coordinate value and the x-coordinate value (0.6) of the point V equal to or less than a predetermined threshold value α, and the derived y-coordinate value; Until it is determined that the difference from the y-coordinate value (0.3) of the point V is equal to or less than the predetermined threshold β, the dimming ratio of the light emitting element 13a, the dimming ratio of the light emitting element 13b, and Each dimming ratio of the dimming ratio of the light emitting element 13c is changed, and the same process as the process described above is performed. In this way, the irradiation control unit 8c derives the three dimming ratios of the illumination device 10b when the chromaticity corresponding to the point V is obtained, and the derived three dimming ratios are stored in the correction table 7c. sign up.

  And the irradiation control part 8c derived | led-out and derived | led-out three light control ratios of the illuminating device 10c in case the same chromaticity as the chromaticity corresponding to the point V is obtained by the method similar to the method mentioned above. Three dimming ratios are registered in the correction table 7c.

  Then, the irradiation control unit 8c derives each of the three dimming ratios of the lighting devices 10b and 10c when the same chromaticity as the chromaticity corresponding to the point W is obtained by the same method as described above. Thus, the derived three dimming ratios are registered in the correction table 7c. In addition, the irradiation control unit 8c derives the three dimming ratios of the illumination devices 10b and 10c when the same chromaticity as the chromaticity corresponding to the point M is obtained by the same method as described above. Thus, the derived three dimming ratios are registered in the correction table 7c. In this way, the irradiation control unit 8c can derive the dimming ratio when substantially the same chromaticity is obtained for each of the red, green, and blue colors for each of the lighting devices 10a to 10c.

  Next, when the user inputs an instruction to irradiate light of the color specified by the user to the irradiation control unit 8c via the input unit 3, the irradiation control unit 8c executes. An example of the irradiation control process will be described.

  For example, when the designated color is red, the irradiation control unit 8c performs dimming of the light emitting element 13a of the lighting device 10a from the first record corresponding to red in the correction table 7c illustrated in the example of FIG. The ratio 100%, the dimming ratio 0% of the light emitting element 13b, and the dimming ratio 0% of the light emitting element 13c are acquired. Further, the irradiation control unit 8c obtains the dimming ratio 80% of the light emitting element 13a, the dimming ratio 20% of the light emitting element 13b, and the dimming ratio 5% of the light emitting element 13c from the first record. . Further, the irradiation control unit 8c obtains the dimming ratio 80% of the light emitting element 13a, the dimming ratio 5% of the light emitting element 13b, and the dimming ratio 20% of the light emitting element 13c from the first record. .

  Then, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 100%, and adds the illumination device ID “AA” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “aa” are added to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit a dimming signal to which the illumination device ID “AA” and the light emitting element ID “bb” are added to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “cc” are added to the access point 22. Thereby, red light with brightness corresponding to a dimming ratio of 100% is emitted from the lighting device 10a.

  Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the illumination device ID “BB” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “aa” are added is transmitted to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the illumination device ID “BB” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “bb” are added is transmitted to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “BB” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “cc” are added is transmitted to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 80%, green light having a brightness corresponding to a dimming ratio of 20%, and brightness corresponding to a dimming ratio of 5%. The red light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the illumination device ID “CC” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “aa” are added to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “CC” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “bb” are added to the access point 22. The irradiation controller 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the illumination device ID “CC” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “cc” are added to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 80%, green light having a brightness corresponding to a dimming ratio of 5%, and brightness corresponding to a dimming ratio of 20%. The red light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  When the designated color is green, the irradiation control unit 8c controls the light control of the light emitting element 13a of the illumination device 10a from the second record corresponding to the green color of the correction table 7c shown in the example of FIG. The ratio 0%, the light control ratio 100% of the light emitting element 13b, and the light control ratio 0% of the light emitting element 13c are acquired. Further, the irradiation control unit 8c obtains the dimming ratio 20% of the light emitting element 13a, the dimming ratio 80% of the light emitting element 13b, and the dimming ratio 5% of the light emitting element 13c from the second record. . Further, the irradiation control unit 8c obtains the dimming ratio 5% of the light emitting element 13a, the dimming ratio 80% of the light emitting element 13b, and the dimming ratio 20% of the light emitting element 13c from the second record. .

  Then, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “aa” are added to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 100%, and adds the illumination device ID “AA” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit a dimming signal to which the illumination device ID “AA” and the light emitting element ID “bb” are added to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “cc” are added to the access point 22. Thereby, green light of brightness corresponding to the dimming ratio of 100% is emitted from the lighting device 10a.

  In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the illumination device ID “BB” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “aa” are added is transmitted to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the illumination device ID “BB” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “bb” are added is transmitted to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “BB” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “cc” are added is transmitted to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 20%, green light having a brightness corresponding to a dimming ratio of 80%, and brightness corresponding to a dimming ratio of 5%. The green light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “CC” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “aa” are added to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the lighting device ID “CC” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “bb” are added to the access point 22. The irradiation controller 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the illumination device ID “CC” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “cc” are added to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 5%, green light having a brightness corresponding to a dimming ratio of 80%, and brightness corresponding to a dimming ratio of 20%. The green light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  When the designated color is blue, the irradiation control unit 8c adjusts the light control of the light emitting element 13a of the illumination device 10a from the third record corresponding to the blue color of the correction table 7c shown in the example of FIG. The ratio 0%, the light control ratio 0% of the light emitting element 13b, and the light control ratio 100% of the light emitting element 13c are acquired. Further, the irradiation control unit 8c obtains the dimming ratio 20% of the light emitting element 13a, the dimming ratio 5% of the light emitting element 13b, and the dimming ratio 80% of the light emitting element 13c from the third record. . Further, the irradiation control unit 8c obtains the dimming ratio 5% of the light emitting element 13a, the dimming ratio 20% of the light emitting element 13b, and the dimming ratio 80% of the light emitting element 13c from the third record. .

  Then, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “aa” are added to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 0%, and adds the illumination device ID “AA” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit a dimming signal to which the illumination device ID “AA” and the light emitting element ID “bb” are added to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 100%, and adds the illumination device ID “AA” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “AA” and the light emitting element ID “cc” are added to the access point 22. Thereby, blue light with brightness corresponding to a dimming ratio of 100% is emitted from the lighting device 10a.

  In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the illumination device ID “BB” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “aa” are added is transmitted to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “BB” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “bb” are added is transmitted to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the illumination device ID “BB” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so that the dimming signal to which the illumination device ID “BB” and the light emitting element ID “cc” are added is transmitted to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 20%, green light having a brightness corresponding to a dimming ratio of 5%, and brightness corresponding to a dimming ratio of 20%. The blue light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 5%, and adds the illumination device ID “CC” and the light emitting element ID “aa” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “aa” are added to the access point 22. Further, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 20%, and adds the lighting device ID “CC” and the light emitting element ID “bb” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “bb” are added to the access point 22. In addition, the irradiation control unit 8c generates a dimming signal indicating a dimming ratio of 80%, and adds the illumination device ID “CC” and the light emitting element ID “cc” to the generated dimming signal. Then, the irradiation control unit 8 c controls the communication unit 6 so as to transmit the dimming signal to which the illumination device ID “CC” and the light emitting element ID “cc” are added to the access point 22. Thereby, from the lighting device 10b, red light having a brightness corresponding to a dimming ratio of 5%, green light having a brightness corresponding to a dimming ratio of 20%, and brightness corresponding to a dimming ratio of 80%. The blue light mixed with the blue light is irradiated. And the color of this mixed light becomes substantially the same as the color of the light irradiated from the illuminating device 10a.

  FIG. 7 is a flowchart showing a flow of chromaticity range adjustment processing executed by the operation device 2 according to the embodiment. The chromaticity range adjustment process is executed by the control unit 8 when the user inputs an instruction to execute the chromaticity range adjustment process to the control unit 8 via the input unit 3, for example. Here, in addition to the first use of the lighting control system 1, the user periodically performs the chromaticity range adjustment processing because the light emitting element 13 and the like deteriorate over time. Enter the chromaticity range adjustment process. As shown in FIG. 7, the measurement unit 8a measures a chromaticity range that is a chromaticity range of the illumination devices 10a to 10c (S101). And the specific | specification part 8b specifies the chromaticity range which all the illuminating devices 10a-10c can irradiate from among the several chromaticity range of the several illuminating devices 10a-10c from which the chromaticity range of irradiation light respectively differs. (S102). And the irradiation control part 8c performs the following process about the case where the color of the light irradiated from each of the illuminating devices 10a-10c is red, green, and blue. That is, the irradiation control unit 8c controls the dimming rate of the light emitting elements 13a of the lighting devices 10a to 10c and the dimming rate of the light emitting elements 13b when the colors of light emitted from the lighting devices 10a to 10c are approximate. And the dimming rate of the light emitting element 13c are registered in the correction table 7c in association with each other (S103), and the chromaticity range adjustment processing is ended.

  FIG. 8 is a flowchart illustrating a flow of irradiation control processing executed by the operation device 2 according to the embodiment. The irradiation control process is executed by the control unit 8 when the user inputs an instruction to irradiate light of a color specified by the user to the control unit 8 via the input unit 3. The As illustrated in FIG. 8, the irradiation control unit 8 c specifies a record corresponding to the specified color from all the records in the correction table 7 c, and the plurality of lighting devices 10 a to 10 c from the registered content of the specified record. The dimming ratio of each light emitting element 13a, the dimming ratio of the light emitting element 13b, and the dimming ratio of the light emitting element 13c are acquired (S201). And the irradiation control part 8c produces | generates the light control signal transmitted to each of each light emitting element 13a of the illuminating devices 10a-10c, the light emitting element 13b, and the light emitting element 13c (S202). Then, the irradiation control unit 8c transmits a corresponding dimming signal to each of the light emitting elements 13a, the light emitting elements 13b, and the light emitting elements 13c of the illumination devices 10a to 10c (S203), and ends the irradiation control process. To do.

  The operation device 2 and the illumination control system 1 according to the present embodiment have been described above. The operation device 2 specifies a chromaticity range that can be irradiated by all the illuminating devices 10a to 10c from among a plurality of chromaticity ranges of the illuminating light of the plurality of illuminating devices 10a to 10c, each having a different chromaticity range of the irradiated light. To do. And the operating device 2 controls the some illuminating devices 10a-10c so that it may irradiate in the specified chromaticity range. Thus, since each of the plurality of lighting devices 10a to 10c is controlled to emit light in the irradiable chromaticity range, the color of the light emitted from each of the plurality of lighting devices 10a to 10c is It will approximate. Therefore, according to the operating device 2, the difference in the color of the light irradiated from each of a some illuminating device can be suppressed.

  Moreover, the operation device 2 specifies the smallest chromaticity range as a chromaticity range that can be irradiated by all the lighting devices 10a to 10c from among the chromaticity ranges of the plurality of irradiation lights. Therefore, according to the operation device 2, the chromaticity range that can be irradiated by all of the lighting devices 10a to 10c can be measured by a simple process of specifying the smallest chromaticity range.

  Further, when the smallest chromaticity range is not included in all chromaticity ranges, the controller 2 irradiates the maximum chromaticity range included in all chromaticity ranges by all the lighting devices 10a to 10c. Specify as possible chromaticity range. Therefore, according to the operation device 2, even if the smallest chromaticity range is not included in all chromaticity ranges, the chromaticity range that can be irradiated by all the lighting devices 10a to 10c can be specified. .

  Moreover, the operating device 2 irradiates from each of several illuminating device 10a-10c based on the image obtained by imaging the place where the light emitted from each of several illuminating device 10a-10c was irradiated. Measure the chromaticity of the emitted light. And the operating device 2 specifies the chromaticity range of the some irradiation light of several illuminating devices 10a-10c based on the measured chromaticity, and all from among the specified chromaticity range of the some irradiation light. The chromaticity range in which the illumination devices 10a to 10c can irradiate is specified. Therefore, according to the operation device 2, the chromaticity range that can be irradiated by all of the lighting devices 10a to 10c is specified using the actually measured chromaticity, so that all of the lighting devices 10a to 10c can be accurately irradiated. Chromaticity range can be specified. As a result, according to the operating device 2, the difference in the color of the light irradiated from each of a some illuminating device can be suppressed effectively.

  In addition, the illumination control system 1 includes a plurality of illumination devices 10a to 10c each having a different chromaticity range of irradiation light, and an operation device 2. The operation device 2 specifies a chromaticity range that can be irradiated by all the illumination devices 10a to 10c from among the chromaticity ranges of the plurality of irradiation lights of the plurality of illumination devices 10a to 10c. And the operating device 2 controls the some illuminating devices 10a-10c so that it may irradiate in the specified chromaticity range. Thus, since each of the plurality of lighting devices 10a to 10c is controlled to emit light in the irradiable chromaticity range, the color of the light emitted from each of the plurality of lighting devices 10a to 10c is It will approximate. Therefore, according to the illumination control system 1, it is possible to suppress a difference in color of light emitted from each of the plurality of illumination devices.

  In the above-described embodiment, the measurement unit 8a analyzes the image output from the imaging unit 5 to derive the RGB mixing ratio of the light irradiated on the floor surface, and the x coordinate in the CIE chromaticity diagram. The case where the chromaticity of the light emitted from the illumination device 10 indicated by the selected illumination device ID is measured by deriving the y and y coordinates has been described. However, the measurement unit 8a sets the chromaticity of the light irradiated on the floor measured by the chromaticity meter or the illuminance meter as the chromaticity of the light irradiated from the lighting device 10 indicated by the selected lighting device ID. Thus, the chromaticity of light emitted from the illumination device 10 indicated by the selected illumination device ID may be measured.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be made to the above-described embodiment. In addition, it is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Illumination control system 2 Controller 5 Image pick-up part 7 Memory | storage part 7a Illuminating device table 7b xy chromaticity diagram data 7c Correction table 8 Control part 8a Measuring part 8b Specific part 8c Irradiation control part 10a-10c Illuminating device 13a-13c Light emitting element

Claims (4)

With lighting device controls the chromaticity of the light to be irradiated, provides information indicating the imaging timing of the light to which the lighting device is irradiated to the user, the user to have a photographing function using the possible operating device carry By causing a user to image a place irradiated with light by the lighting device, an image of the place irradiated with light by the lighting device is acquired, and the lighting device is based on the acquired plurality of images. A measurement unit for measuring the chromaticity range that can be irradiated;
A specifying unit for specifying a chromaticity range that can be irradiated by all of the lighting devices from among the chromaticity ranges measured for each of the plurality of lighting devices by the measuring unit;
An irradiation control unit that controls the plurality of illumination devices to perform irradiation in a chromaticity range specified by the specifying unit;
An operating device comprising:   The specifying unit specifies the smallest chromaticity range from among the chromaticity ranges measured for each of the plurality of lighting devices as a chromaticity range that can be irradiated by all the lighting devices. The operation device according to claim 1.   The operation according to claim 1, wherein the specifying unit specifies a maximum chromaticity range included in all the measured chromaticity ranges as a chromaticity range that can be irradiated by all the lighting devices. vessel. A lighting control system comprising a plurality of lighting devices each having a different chromaticity range of irradiation light, and an operating device,
The controller is
With lighting device controls the chromaticity of the light to be irradiated, provides information indicating the imaging timing of the light to which the lighting device is irradiated to the user, the user to have a photographing function using the possible operating device carry By causing a user to image a place irradiated with light by the lighting device, an image of the place irradiated with light by the lighting device is acquired, and the lighting device is based on the acquired plurality of images. A measurement unit for measuring the chromaticity range that can be irradiated;
A specifying unit for specifying a chromaticity range that can be irradiated by all of the lighting devices from among the chromaticity ranges measured for each of the plurality of lighting devices by the measuring unit;
An irradiation control unit that controls the plurality of illumination devices to perform irradiation in a chromaticity range specified by the specifying unit;
An illumination control system comprising:

Images