JP2006277972A - Illumination setting device and illumination setting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve trouble where, when illumination is tried to be implemented in accordance with intended use by installing multiple luminaires in a room, the illumination situations of multiple lighting systems cannot easily be acquired. <P>SOLUTION: This illumination setting device is provided with: a display part for displaying an operation screen having a plurality of first figures corresponding to a plurality of luminaires and for displaying an second figure on the operation screen; an operation part for detecting a direction to the operation screen; an input processing part for acquiring direction coordinate information of the direction; a control part for detecting the directed first figure to compose the second figure; and a display processing part for directing the display part to display the second figure in the vicinity of the first figure detected by the control part. The control part acquires a luminosity input value based on the direction to the second figure; and the control part can easily obtain the illumination situations of the multiple lighting systems by the illumination setting device for outputting luminosity information corresponding to the luminosity input value as luminosity information for the luminaire corresponding to the first figure. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an illumination setting device and an illumination setting method, and more particularly to an illumination setting device, an illumination setting method, and the like capable of flexible control and management such as luminous intensity for each lighting fixture and illuminance in a room.

  In a conventional lighting system, for example, when a large number of light sources are provided in a hall or the like, the light intensity is adjusted for each individual light source in order to appropriately set the illuminance at a large number of locations in the hall. In such a method, it is necessary to repeat adjustment of each light source by trial and error in order to set the illuminance at a predetermined position to a desired value.

On the other hand, as an intelligent lighting system, an illuminance at a desired position is detected, and a plurality of lighting devices sequentially change their own luminosity so that the illuminance at the desired position becomes the desired illuminance. Algorithm has been proposed. (For example, refer nonpatent literature 1).
Mitsunori Miki, Tomoyuki Yasu, Kazuhiro Imazato, Satoshi Ikeda “Proposal of Intelligent Lighting System and Verification of Effectiveness of Control Method” Proceedings of the 14th Design Engineering and System Division Lecture Meeting of the Japan Society of Mechanical Engineers [No. 04-11-29 to 12-1] p. 55-58

If a large number of lighting fixtures are provided in the room and illumination is performed according to the purpose of use, it is necessary to appropriately set the luminous intensity of each lighting device, the illuminance at each position in the room, and the like. For this purpose, it is necessary to make it possible to easily and flexibly set and change the luminosity of a large number of lighting fixtures and the illuminance at each position.
The present invention provides an illumination setting device and an illumination setting method that make it easy to set the luminosity of a plurality of illumination devices and the illuminance at a plurality of positions in a hall, a general room, or an outdoor room. With the goal.

  In order to solve the above-described problems, the illumination setting device and the illumination setting method of the present invention employ the following means and procedures.

  (1) First graphic information that is information relating to a plurality of first figures corresponding to a plurality of lighting fixtures and second graphic information relating to a second graphic for inputting the luminous intensity for each lighting fixture are stored. A storage unit, and a display unit for displaying an operation screen having a first graphic and displaying the second graphic on the operation screen based on the first graphic information stored in the storage unit; An operation unit that detects an instruction to the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit Based on the designated coordinate information, the instructed first graphic is detected, and on the basis of the second graphic information, the control unit constituting the second graphic and the first graphic detected by the control unit are detected. In the vicinity, the second graphic configured by the control unit A display processing unit for instructing the display unit to display, wherein the control unit is instruction coordinate information acquired by the input processing unit, and is based on instruction coordinate information indicating an instruction for the second graphic The light setting device that acquires a light intensity input value and outputs the light intensity information corresponding to the light intensity input value as light intensity information for a lighting fixture corresponding to the instructed first graphic.

  (2) First graphic information that is information relating to a plurality of first figures corresponding to a plurality of lighting fixtures and third graphic information relating to third graphics for inputting the luminous intensity of all the lighting fixtures are stored. A storage unit, and a display unit that displays an operation screen having a first graphic and displays the third graphic on the operation screen based on the first graphic information stored in the storage unit. An operation unit that detects an instruction to the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit A control unit that detects a light intensity input value based on the designated coordinate information and outputs light intensity information corresponding to the light intensity input value as light intensity information for all the lighting fixtures.

(3) First graphic information that is information relating to a plurality of first figures corresponding to a plurality of lighting fixtures and third graphic information relating to a third graphic for inputting the luminous intensity for each lighting fixture are stored. A storage unit, and a display unit that displays an operation screen having a first graphic and displays the third graphic on the operation screen based on the first graphic information stored in the storage unit. An operation unit that detects an instruction to the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit Based on the designated coordinate information, one or more designated first graphics are detected, and a control unit that configures a third graphic based on the third graphic information, and the control unit are configured. The display so as to display the third figure made A display processing unit for instructing, wherein the control unit is instruction coordinate information acquired by the input processing unit, acquires a luminous intensity input value based on instruction coordinate information indicating an instruction for the third graphic, And the said control part is an illumination setting apparatus which outputs the luminous intensity information corresponding to the said luminous intensity input value as luminous intensity information for lighting fixtures corresponding to the said instruct | indicated 1st figure.
(4) The illumination setting device according to any one of (1) to (3), wherein the display unit performs display corresponding to the light intensity input value on or around the first graphic corresponding to the light intensity input.
(5) The illumination setting device according to (4), wherein the display according to the light intensity input value on or around the first graphic is a highlight display according to the light intensity input value.

  (6) First graphic information that is information relating to a plurality of first figures corresponding to a plurality of illuminance setting positions, and second graphic information relating to a second graphic for inputting illuminance for each illuminance setting value are stored. And a display for displaying the operation screen having the first graphic and displaying the second graphic on the operation screen based on the first graphic information stored in the storage unit. An operation unit that detects an instruction on the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit The detected first graphic is detected based on the indicated coordinate information acquired by the control unit, and the control unit constituting the second graphic is detected based on the second graphic information, and the first detected by the control unit. The second configured by the control unit in the vicinity of the figure. A display processing unit for instructing the display unit to display a graphic, wherein the control unit is instruction coordinate information acquired by the input processing unit, and includes instruction coordinate information indicating an instruction for the second graphic; An illumination setting device that obtains an illuminance input value based on the illuminance information and outputs the illuminance information corresponding to the illuminance input value as illuminance information at an illuminance setting position corresponding to the instructed first graphic. .

  (7) storing first graphic information that is information related to a plurality of first graphics corresponding to a plurality of illuminance setting positions, and third graphic information related to a third graphic for inputting the illuminances of all lighting fixtures; And a display unit that displays an operation screen having a first graphic and displays the third graphic on the operation screen based on the first graphic information stored in the storage unit. An operation unit that detects an instruction to the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit A lighting setting device comprising: a control unit that detects an illuminance input value based on the acquired designated coordinate information and outputs illuminance information corresponding to the illuminance setting position as illuminance information of the entire illuminance setting position.

(8) First graphic information that is information related to a plurality of first figures corresponding to a plurality of illuminance setting positions, and third graphic information related to a third graphic for inputting illuminance for each illuminance setting value are stored. And a display for displaying the operation screen having the first graphic and displaying the third graphic on the operation screen based on the first graphic information stored in the storage unit. An operation unit that detects an instruction on the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and the input processing unit A control unit that detects one or a plurality of instructed first graphics based on the designated coordinate information acquired by the computer and configures a third graphic based on the third graphics information; and the control unit To display the third figure configured by A display processing unit for instructing the display unit is provided, and the control unit is the instruction coordinate information acquired by the input processing unit, and acquires an illuminance input value based on the instruction coordinate information indicating an instruction for the third graphic And the said control part is an illumination setting apparatus which outputs the illumination intensity information corresponding to the said illumination intensity input value as illumination intensity information of the illumination intensity setting position corresponding to the said instruct | indicated 1st figure.
(9) The illumination setting device according to any one of (6) to (8), wherein the display unit performs display corresponding to the illuminance input value on or around the first graphic corresponding to the illuminance input.
(10) The display according to the illuminance input value on or around the first graphic is a highlight display according to the illuminance input value.
(11) The illumination setting device according to any one of (1) to (10), wherein the first graphic is a graphic of a lighting fixture.
(12) An illumination status display device that visually outputs the light intensity at a predetermined point.
(13) An illumination status display device that visually outputs illuminance at a predetermined point.

  (14) A procedure for displaying a plurality of first graphics corresponding to a plurality of lighting fixtures on a display unit, a procedure for accepting an instruction for any of the first graphics, and a first graphics that has received the instruction Based on a procedure for displaying a second graphic for light intensity input in the vicinity, a procedure for receiving an instruction for the second graphic, and indication coordinate information which is information indicating the position of the instruction for the second graphic. A procedure for detecting an input value, and a procedure for outputting luminous intensity information corresponding to the detected luminous intensity input value as luminous intensity information for a lighting fixture corresponding to the first graphic that has received the instruction. A lighting setting method.

  (15) a procedure for displaying a plurality of first graphics corresponding to a plurality of lighting fixtures and a third graphic for light intensity input on a display unit, a procedure for receiving an instruction for the third graphics, and the third A procedure for detecting a luminous intensity input value based on designated coordinate information, which is information indicating the position of an instruction with respect to the figure, and luminous intensity information corresponding to the detected luminous intensity input value are converted into illumination corresponding to the plurality of first figures. And a procedure for outputting as luminosity information for appliances.

(16) a procedure for displaying a plurality of first graphics corresponding to a plurality of lighting fixtures on a display unit, a procedure for receiving an instruction for any of the first graphics, a procedure for displaying a third graphics, Corresponding to a procedure for receiving an instruction for the third graphic, a procedure for detecting a light intensity input value based on instruction coordinate information that is information indicating a position of an instruction for the third graphic, and the detected light intensity input value And a procedure for outputting the luminous intensity information to be performed as luminous intensity information for a lighting fixture corresponding to the first graphic that has received the instruction.
(17) The illumination setting method according to any one of (14) to (16), wherein display corresponding to the light intensity input value is performed on or around the first graphic corresponding to the light intensity input.
(18) The illumination setting method according to (17), wherein the display according to the light intensity input value on or around the first graphic is a highlight display according to the light intensity input value.

  (19) A procedure for displaying a plurality of first graphics corresponding to a plurality of illuminance setting positions on the display unit, a procedure for accepting an instruction for any of the first graphics, and a first graphic for accepting the instruction On the basis of a procedure for displaying a second graphic for illuminance input in the vicinity, a procedure for receiving an instruction for the second graphic, and pointing coordinate information which is information indicating the position of the instruction for the second graphic, A procedure for detecting an illuminance input value, and a procedure for outputting luminosity information corresponding to the detected luminosity input value as illuminance information at an illuminance setting position corresponding to the first figure that received the instruction. Lighting setting method characterized by.

  (20) A procedure for displaying a plurality of first graphics corresponding to a plurality of illuminance setting positions and a third graphic for illuminance input on the display unit, a procedure for receiving an instruction for the third graphics, and the third The procedure for detecting the illuminance input value based on the indicated coordinate information, which is information indicating the position of the instruction with respect to the figure, and the luminous intensity information corresponding to the detected illuminance input value correspond to the plurality of first figures. And an output procedure as illuminance information of the illuminance setting position.

(21) A procedure for displaying a plurality of first graphics corresponding to a plurality of illuminance setting positions on the display unit, a procedure for receiving an instruction for any one of the first graphics, and a procedure for displaying a third graphic , A procedure for receiving an instruction for the third graphic, a procedure for detecting an illuminance input value based on instruction coordinate information which is information indicating a position of the instruction for the third graphic, and the detected illuminance input value. And a procedure for outputting corresponding luminosity information as illuminance information at an illuminance setting position corresponding to the first figure that has received the instruction.
(22) The illumination setting method according to any one of (19) to (21), wherein display corresponding to the illuminance input value is performed on or around the first graphic corresponding to the illuminance input.
(23) The illumination setting method according to (22), wherein the display according to the illuminance input value on or around the first graphic is a highlight display according to the illuminance input value.
(24) The illumination setting method according to any one of (14) to (23), wherein the first graphic is a graphic of a lighting fixture.

  As described above, according to the illumination setting device and the illumination setting method of the present invention, the user can easily set the luminosity of a plurality of illumination fixtures and the illuminance by these illumination fixtures by an easy-to-understand operation.

Embodiments of the illumination setting device and illumination setting method of the present invention will be described with reference to the drawings. In addition, when the component which attached | subjected the same code | symbol performed in embodiment performs the same operation | movement, description may be abbreviate | omitted again.
(Embodiment 1)

  FIG. 1 is a configuration block diagram of an illumination system using the illumination setting device of the present invention. The illumination system includes an illumination setting device 100, an illumination control device 200, and an illumination device 300. The lighting device 300 is composed of a plurality of lighting fixtures installed on the ceiling of the room, and the light intensity of each is set by the lighting control device 200. The lighting setting device 100 is a control terminal device that can select the blinking of each lighting fixture or set the luminous intensity of each lighting fixture, and can display the blinking status and the luminous intensity setting status of each lighting fixture. The lighting setting device 100 supplies the light intensity information set by the user to the lighting control device 200. The lighting control device 200 controls the light intensity of each lighting fixture according to the setting information.

  As the illumination control device 200, an inverter control circuit can be applied. The inverter lighting method is a method in which blinking of a light source such as a fluorescent lamp is repeated at a high frequency, and a lighting time rate that is a ratio between a lighting time and a lighting time is controlled by light intensity information to obtain a desired average light intensity value. is there. The inverter control circuit is a circuit that controls the lighting time rate, and can set the average brightness of the light source to a luminous intensity amount corresponding to luminous intensity information. Since it is appropriate to arrange the inverter control circuit in or near the lighting fixture, in this case, the lighting control device 200 in FIG. 1 is distributed in the vicinity of the lighting device 300.

  FIG. 2 is a configuration diagram of the illumination setting device 100. The lighting setting device 100 includes a display unit 10, an operation unit 11, a display processing unit 12, an input processing unit 13, a storage unit 14, and a control unit 15, and prompts the user to input lighting settings and is set by the user. In accordance with the input information, the light control device 200 has a function of supplying luminous intensity information.

  The display unit 10 and the operation unit 11 are preferably display devices that can detect and display a user's instructions like a liquid crystal touch panel. The touch panel portion (including the touch panel software driver) corresponds to the operation unit 11. However, the display unit 10 may be a display (liquid crystal, CRT, etc.) that does not include a touch panel. In such a case, the operation unit 11 detects a user instruction by pressing a button of a mouse constituting the operation unit 11 or the like. The left part of the display unit 10 is an all-on / all-off area 10a (hereinafter sometimes referred to as a third graphic), and includes characters for inputting all-on / all-off, an all-on button, A graphic including an all-off button and a plurality of light intensity% buttons for specifying light intensity from 0% to 100% is displayed. A button area and a mode selection area are also displayed below the all-on / all-off area 10a. More button areas will be described later, but a description of the mode selection area will be omitted. In the right part of the all-on / all-off area 10a, a figure (hereinafter referred to as the first figure or the first figure) indicating a plurality of lighting fixtures Lij (i = 1 to 3, j = 1 to 5) arranged on the ceiling of the room. May be called a luminaire button). Note that the characters Lij in the figure need not be displayed. The first graphic may be any graphic that indicates to the user that the light intensity can be set, and is not limited to the graphic of the lighting fixture Lij. Circular or square shapes may be used.

The storage unit 14 includes first graphic information that is information related to a plurality of first graphics corresponding to a plurality of lighting fixtures, second graphic information related to a second graphic for inputting a luminous intensity for each lighting fixture, Third graphic information relating to the third graphic for inputting the luminous intensity of the lighting fixture is stored. The 1st figure is a figure which shows lighting fixture Lij. The second graphic is various graphic components described later. The first graphic information may be a bitmap indicating the first graphic (lighting fixture) or a script (for example, PostScript) for configuring the first graphic. The data structure of the first graphic information is not limited. The second graphic information may have any data structure such as a bitmap indicating a second graphic (for example, a symbol indicating an operation menu or a menu item), a script such as HTML or XML, or the like. The third graphic information includes data such as a bitmap indicating a third graphic (for example, a symbol indicating an operation menu or menu item) for inputting the luminosity of all lighting fixtures, a script such as HTML or XML, and the like. Any structure is acceptable. The first graphic information, the second graphic information, and the third graphic information are information constituting the first graphic, the second graphic, and the third graphic, respectively. The storage unit 14 is preferably realized by a nonvolatile recording medium, but may be realized by a volatile recording medium.
Moreover, the memory | storage part 14 has a storage area corresponding to 15 lighting fixtures Lij, for example, and can memorize | store the setting light intensity value etc. of each lighting fixture Lij. The set luminous intensity value is a value indicating the currently set luminous intensity.

  The control unit 15 detects the instructed first graphic based on the designated coordinate information acquired by the input processing unit 13 and configures the second graphic based on the second graphic information in the storage unit 14. More specifically, for example, the control unit 15 generates bitmap-format graphic information based on the graphic information stored in the storage unit 14 and supplies the graphic information to the display processing unit 12. As a result, a predetermined figure is displayed on the display unit 10. Further, the control unit 15 acquires the luminous intensity input value based on the instruction coordinate information acquired by the input processing unit 13 and indicating the instruction for the second graphic. Further, the control unit 15 generates graphic information by generating or transforming a graphic, which will be described later, according to the received instruction coordinate information, and supplies the graphic information to the display processing unit 12 to display on the display unit 10 or set by the user. The light intensity information is supplied to the lighting control device 200 for each lighting fixture Lij according to the brightness designation information. The light intensity information supplied by the control unit 15 may be information corresponding to the set brightness, and may be in a form accepted by the lighting control device 200. When the illumination control device 200 accepts the% luminous intensity value, it supplies the% luminous intensity value, and when accepting the candela value, it supplies the candela value. The control unit 15 can be configured by an MPU and a memory, and can be realized by storing a processing program in the memory. However, the control unit 15 can also be realized by dedicated hardware.

  When it is considered that the display processing unit 12 is included in the display unit 10, the display processing unit 12 is not necessary, and the control unit 15 may supply graphic information to the display unit 10. The operation unit 11 provided in the display unit 10 has, for example, a touch panel function, and when it is pressed with a pen or a finger or the like, designated coordinate information that is information indicating the pressed position coordinates is output to the input processing unit 13. . The display unit 10 may not be provided with a touch panel and may be designated with a mouse or the like. In this case, the mouse serves as the operation unit 11. The operation unit 11 has a pressing force detection function, and it is preferable that pressing information indicating pressing ON is supplied to the input processing unit 13 when pressed at a certain pressure or more. The display processing unit 12 outputs the luminous intensity information corresponding to the luminous intensity input value as luminous intensity information for the lighting fixture corresponding to the instructed first graphic. The display processing unit 12 can be realized by software, for example.

  Based on the instruction detected by the operation unit 11, the input processing unit 13 acquires instruction coordinate information that is information indicating the position of the instruction. Then, the input processing unit 13 supplies the designated coordinate information to the control unit 15. Note that the input processing unit 13 may supply, for example, information indicating ON / OFF of pressing and instruction coordinate information to the control unit 15. For example, the input processing unit 13 can be realized by software that passes the designated coordinate information received from the driver of the touch panel to the control unit 15. The designated coordinate information is, for example, information in the format (x, y).

  The designated coordinate information means designated coordinate information or both information indicating pressing ON / OFF and designated coordinate information. Further, information indicating pressing ON and OFF may be embedded in the representation of the designated coordinate information so that the designated coordinate information serves as both. For example, if a value outside the XY coordinate area is taken, the pressure OFF is indicated. If the value is within the XY coordinate area, the pressure is ON. Can be embedded.

  Next, an example of an operation method for setting each lighting fixture Lij to a desired brightness will be described. The user presses the figure of the lighting fixture Lij for which the brightness is desired to be set with the finger among the lighting fixture figures on the display unit 10. The operation unit 11 supplies the input processing unit 13 with touch-on information, which is information indicating that the button is pressed, and instruction coordinate information, which is information about the pressed position. The input processing unit 13 converts the position information into coordinate information and supplies it to the control unit 15 together with the touch ON information. The control unit 15 determines what has been pressed based on the coordinate information. When it is determined that the coordinate information is a coordinate position in the figure of the lighting fixture Lij, the control unit 15 inputs the brightness designation input figure (the second figure described above) at a position near the figure of the lighting fixture Lij. Is generated into graphic information superimposed on the screen information of the display screen of FIG. 2, supplied to the display processing unit 12 and displayed on the display unit 10. The second graphic is a graphic constituting a menu for designating brightness, and is, for example, (C) in FIG. The data structure of the second graphic is not limited. The second graphic may be realized by a script such as HTML, or may be a bitmap or the like.

  An example of the display figure in this state is shown in FIG. As shown in the brightness designation figure 21 in FIG. 3C, the brightness designation input figure includes the characters “brightness designation”, “100%”, “80%”, “60%”, “ It is a figure in which light intensity designation areas of “40%”, “20%”, and “0%” are provided in a button shape. The menu items “100%” and “80%” are menu items (buttons) selected in accordance with a user instruction.

  When the user sees that the brightness designation figure 21 has appeared, it can be seen that the user has instructed to select any light intensity% button from 0% to 100%. Select either of the% intensity buttons with your finger. Then, the display unit 10 supplies the touch processing information and the pressed position information to the input processing unit 13.

  Next, the input processing unit 13 receives the touch ON information and the pressed position information, converts the position information into coordinate information, and supplies the coordinate information to the control unit 15 together with the ON information. Then, the control unit 15 checks which light intensity% button from 0% to 100% is pressed from the position information, and supplies light intensity information corresponding to the specified light intensity input value of% to the illumination control device 200. The lighting control device 200 controls the light intensity of the lighting fixture Lij in accordance with the supplied light intensity information.

  The control unit 15 deletes the display of the brightness designation figure 21, generates a figure on which the graphic information of the highlight part having brightness and area corresponding to the supplied light intensity information is superimposed, and supplies the figure to the display processing unit 12. It is displayed on the display unit 10. The display unit 10 displays a bright circular figure around the lighting fixture Lij. FIG. 3 shows an example in which highlight display is performed on five lighting fixtures of lighting fixtures Lij (ij = 11, 12, 13, 14, 33). In this example, the magnitude of the luminous intensity corresponds to the size of the highlight figure. The shape, brightness, and color of the highlight figure are not limited to this example. The display unit 10 displays a highlight figure in such a manner that the luminaire Lij is highlighted to the luminance or color of the background. That is, the user can intuitively grasp the light intensity of the lighting fixture Lij immediately by looking at the display on the display unit 10 in FIG.

  FIG. 4 is an example of the display position coordinate expression of the lighting fixture Lij and the brightness designation figure 21. The coordinates of the display area of the display unit 10 are represented by an XY coordinate system with the lower left corner as the origin. In the coordinate representation of the display unit 10, when a rectangular figure having a width W and a height H is arranged at the position of the reference coordinates (Xa, Ya) with the lower left corner, the display area of the rectangular figure is a set of four coordinate values. (X1, X2, Y3, Y4) = (Xa, Xa + W, Ya, Ya + H). Let (X1, X2, Y3, Y4) be called rectangular coordinate values. It can be said that it represents a range surrounded by a total of four line segments of two horizontal lines and two vertical lines. When the width of the lighting fixture Lij is WL and the height is HL, and the lower left coordinates of the figure of the lighting fixture Lij are the reference coordinates (Xij, Yij), the rectangular coordinate value of the lighting fixture Lij is (Xij, Xij + WL, Yij, Yij + HL). When the display size of the brightness designation figure 21 is the width Ws and the height Hs, and the lower left corner is arranged at the position of the reference coordinate (Xa, Ya), the rectangular coordinate value is (Xa, Xa + Ws, Ya). , Ya + Hs).

  5A shows the rectangular coordinate values indicating the display positions of the graphic parts such as the areas, buttons, and lighting fixtures displayed on the display unit 10 in FIG. 2, the graphic names of the graphic parts, and the graphic parts. It is the list showing the next processing contents when it is judged that it was suppressed. The “rectangular coordinate value” field and the “graphic name” field indicated by (X1, X2, Y3, Y4) are called the coordinate / graphic correspondence table, and the “graphic name” field and the “next processing” field are This is called a figure / instruction correspondence table. This table is stored in the storage unit 14 as a table referred to by the control unit 15. First, area 1 is a rectangular coordinate value based on the coordinate values of the four corners of the outer peripheral portion of the all-lit / all-off area 10a. In the “graphic name” column, an identification code of the all-lit / all-off area 10a is stored. Area 2 is a rectangular coordinate value of the figure of the all-lit button. In the “graphic name” column, codes assigned to all the lit buttons are stored. Similarly, in area 3 to area 9, the rectangular coordinate values of the buttons in the all-lit / all-off area 10a and the code of the figure name of the figure part are stored. The “next processing” column stores the next processing content when it is determined that the corresponding graphic part is pressed, information related to the coordinates necessary for the processing, and the like. The next processing content is a command or information constituting the command, and is information regarding a command for controlling the lighting device 300 or changing the display of the display unit 10.

  In FIG. 5, an area Lij (i = 1 to 3, j = 1 to 5) stores rectangular coordinate values (Xij, Xij + WL, Yij, Yij + HL) for displaying the figure of the lighting fixture Lij. In the graphic name, the identification code of the lighting fixture Lij is stored. As the “next processing”, the brightness designation figure is set with reference position Zij = (Xij + αij, Yij + βij) separated by αij on the right and βij on the right from the reference coordinates (Xij, Yij) of the lighting fixture Lij. A command (command) for displaying 21 is stored. Therefore, the rectangular coordinate value of the brightness designation figure 21 for the lighting fixture Lij is (Xij + αij, Xij + αij + Ws, Yij + βij, Yij + βij + Hs). αij and βij are selected so that the brightness designating figure 21 can be positioned in the vicinity of the lighting fixture Lij and can be located within the display unit 10. It should be noted that the neighborhood means that the user can feel that the brightness designation figure 21 and the figure of the lighting fixture Lij are displayed nearby, and the distance is not limited. Further, the vicinity may be a position that overlaps when both figures are displayed.

  In FIG. 5B, the rectangular coordinate value of the brightness% button from 0% to 100% in the area of the brightness designation figure 21 when one lighting fixture Lij is selected is (X1, X2, Y3). , Y4) is stored for each luminous intensity%. In addition, the figure name corresponding to each luminous intensity% button and the next processing content are also stored. The parts of the “rectangular coordinate value” field and the “graphic name” field are referred to as a coordinate / graphic correspondence table, and the parts of the “graphic name” field and the “next processing” field are referred to as a graphic / instruction correspondence table. This table is also stored in the storage unit 14 as a table for reference to the control unit 15. Assuming that the height of each light intensity% button from 0% to 100% is Hr as shown in FIG. 4 and the reference coordinates are (Xa, Yc), the rectangular coordinate values of each button are as follows.

  That is, the rectangular coordinate value of the “0% button” is (Xa, Xa + Ws, Ya, Ya + Hr). The rectangular coordinate value of the “20% button” is (Xa, Xa + Ws, Ya + Hr, Ya + 2Hr). The rectangular coordinate values of the “40% button” are (Xa, Xa + Ws, Ya + 2Hr, Ya + 3Hr). Further, the rectangular coordinate values of the “60% button” are (Xa, Xa + Ws, Ya + 3Hr, Ya + 4Hr). The rectangular coordinate values of the “80% button” are (Xa, Xa + Ws, Ya + 4Hr, Ya + 5Hr). The rectangular coordinate values of the “100% button” are (Xa, Xa + Ws, Ya + 5Hr, Ya + 6Hr). Further, the rectangular coordinate value of “brightness designation name” is (Xa, Xa + Ws, Ya + 6Hr, Yij + βij + 7Hr). However, “Xa = Xij + αij”, “Ya = Yij + βij”.

  The rectangular coordinate values are (Xa, Xb, Ya1, Ya2), (Xa, Xb, Ya2, Ya3), (Xa, Xb, Ya3, Ya4), (Xa, Xb, Ya4, Ya5) in FIG. ), (Xa, Xb, Ya5, Ya6), (Xa, Xb, Ya6, Ya7), and (Xa, Xb, Ya7, Ya8). It goes without saying that these rectangular coordinate values are variables that take different values depending on ij of the lighting fixture Lij. In the “graphic name” field, brightness designation 0%, brightness designation 20%, brightness designation 40%, brightness designation 60%, brightness designation 80%, brightness corresponding to each rectangular coordinate value. Each of the six luminous intensity% button identification codes with the specified 100% is stored. In the “next processing” column, the luminous intensity information to be output and an instruction on the presence / absence of highlight display are stored as processing contents.

  When the coordinate values (Xf, Yf) supplied from the input processing unit 13 to the control unit 15 when the touch is on are within the rectangular coordinate values (X1, X2, Y3, Y4), It can be determined that the area has been pressed. That is, when X1 ≦ Xf <X2 and Y3 ≦ Yf <Y4, it is determined that the button corresponding to the rectangular coordinate value (X1, X2, Y3, Y4) has been pressed.

  FIG. 6 is a basic flowchart for explaining an operation procedure of the illumination setting apparatus 100 according to the present embodiment. When the illumination setting device 100 is turned on, at the start, the control unit 15 reads the graphic information from the storage unit 14, generates the initial screen shown in the display unit 10 of FIG. 2, supplies it to the display processing unit 12, and displays it. Display on the unit 10. Since such initial processing is a known technique, it will not be described in the flowchart of FIG. Proceeding to (S10), the control unit 15 waits for touch-on information and designated coordinate information from the input processing unit 13. In the case of a mouse, it is only necessary to wait for a mouse click instruction for moving the mouse and the position coordinate information of the pointer icon at that time. When the touch-on information is received, the result becomes Yes in (S10), and the process proceeds to (S11). In (S11), the indicated coordinate information is compared with the coordinate / graphic correspondence table to determine the indicated graphic. Specifically, the (Xa, Xb, Ya, Yb) column of the table described in FIG. 15A is searched to search for rectangular coordinate values that include the designated coordinate information in the area. When the rectangular coordinate value is found, it is determined that the figure of the lighting fixture Lij having the corresponding figure name or the light intensity% button has been pressed. If it is not found, it is determined that neither a figure with any figure name nor a button has been pressed, and an area other than the button has been pressed. Next, it progresses to (S12), and when determination is other than a button, it becomes No and returns to (S10). In the case of Yes, the process proceeds to (S13), and the figure / instruction correspondence table is searched to determine the instruction content. Specifically, in the table described with reference to FIG. 15A, the instruction content in the “next processing” column corresponding to the determined graphic name is read. Next, proceeding to (S14), based on the acquired instruction content, predetermined graphic display, luminous intensity information output corresponding to the luminous intensity input value instructed by the user, and the like are performed. Next, the process returns to (S10) and waits for the next operation. Note that the next operation may be waited after confirming the touch-off after the touch-on. In the flowchart of FIG. 6, the operation is ended by receiving an end instruction, an interrupt such as power-off, or the like.

  FIG. 7 is a detailed flowchart for explaining an operation procedure of the illumination setting apparatus 100 according to the present embodiment. When the power of the lighting setting device 100 is turned on, the control unit 15 reads the graphic information from the storage unit 14, generates an initial screen including the first graphic shown in the display unit 10 of FIG. Display on the display unit 10. Proceeding to (S20), the control unit 15 waits for touch-on information and designated coordinate information from the input processing unit 13. In the case of a mouse, it is only necessary to wait for a mouse click instruction for moving the mouse and the position coordinate information of the pointer icon at that time. When the touch-on information is received, the result becomes Yes in (S20), and the process proceeds to (S21). In (S21), the designated coordinate information is compared with the coordinate / graphic correspondence table to determine the designated graphic. Specifically, the area L11 is searched from the area L11 in the (X1, X2, Y3, Y4) column of the table described in FIG. 15A, and it is determined whether or not the point indicated by the designated coordinate information is included in the area. To do. If an area including the designated coordinate information is found within the rectangular coordinate value area, it is determined that the button of the corresponding lighting fixture Lij has been pressed. If not found, it is determined that no luminaire button has been pressed, and an area other than the luminaire button has been pressed. Next, it progresses to (S22), and when determination is other than a lighting fixture button, it becomes No and returns to (S20). In the case of Yes (S23), the brightness designation figure 21 (second figure) is displayed near (in the vicinity of) the lighting fixture Lij. Specifically, the figure name Lij in the table of FIG. 5A is searched, the “next processing” column is read, the reference coordinate value Zij is read, and the reference coordinate Zij set for each lighting fixture Lij is used as a reference. Thus, a screen in which the brightness designation figure 21 is superimposed on the initial screen is generated, supplied to the display processing unit 12, and displayed on the display unit 10. Further, based on the value of the reference position coordinate Zij = (Xij + αij, Yij + βij) of the lighting fixture Lij, Xa = Xij + αij and Ya = Yij + βij are substituted into (Equation 1) to obtain the lighting fixture Lij. The rectangular coordinate value (X1, X2, Y3, Y4) of each button in the brightness designating figure 21 is calculated, and the “rectangular coordinate value” (X1, X2, X2) in the coordinate / graphic correspondence table of FIG. Write in the column of Y3, Y4).

  Next, proceeding to (S24), it is determined whether or not an area other than the brightness designation area is instructed. In other words, once the touch-off is detected, if the coordinate information when the touch is turned on is not within the display area of the brightness designating figure 21, the answer is Yes, and the process proceeds to (S25). Whether or not it is within the display area of the brightness designation figure 21 is determined by whether the indicated coordinate information is within the seven rectangular coordinate values in the column of “rectangular coordinate values” (X1, X2, Y3, Y4) in FIG. Judgment can be made by whether or not there is. When proceeding to (S25), it is interpreted as redoing, the display of the brightness designation figure 21 is once terminated, the initial screen is displayed, and the process returns to (S20) to wait for touch-on. If it is determined in (S24) that there is an instruction in the brightness designation area, the result is No, and the process proceeds to (S26). In (S26), it is determined whether or not a brightness% button for specifying brightness has been instructed. Specifically, the designated coordinate information is (Xa, Xb, Ya1, Ya2), (Xa, Xb, Ya2, Ya3), (Xa, Xb, Ya3, Ya4), (Xa, Xb) in FIG. , Ya4, Ya5), (Xa, Xb, Ya5, Ya6), and (Xa, Xb, Ya6, Ya7), it is determined whether the point is within the area of the six rectangular coordinate values. If it is outside the said area, it will become No and will return to (S24) and will wait for a touch. If it is within the area, the process proceeds to (S27), and the luminous intensity instruction% is determined from the touch coordinates. That is, the column of “rectangular coordinate values” (X1, X2, Y3, Y4) in the table of FIG. 5B is searched to find out which of the six rectangular coordinate values the designated coordinate information is located and the figure name. Is extracted, and the process proceeds to (S28). In (S28), the luminous intensity information corresponding to the luminous intensity input value of the instruction% is output to the luminaire Lij. That is, the “next processing” column corresponding to the graphic name of the brightness designation button extracted in the above (S27) is read from the table of FIG. 5B, and the corresponding luminous intensity information is supplied to the illumination control device 200. Proceed to (S29). Accordingly, the lighting control device 200 controls the light intensity of the lighting fixture Lij according to the light intensity information, and the lighting fixture Lij of the lighting device 300 emits light of the set light intensity. In (S29), the control unit 15 generates a figure in which the brightness designation figure 21 that has been displayed so far is deleted, generates a highlight display figure corresponding to the luminous intensity, and superimposes the figure superimposed around the lighting fixture Lij. After being generated and supplied to the display processing unit 12 and displayed on the display unit 10, the process returns to (S20) and waits for the next operation.

  If the above operations and processes are repeated for a desired plurality of lighting fixtures Lij, it can be set between 0% and 100% of the luminosity of the lighting fixture at an arbitrary position in the room. Since the highlight display is performed around the luminaire Lij according to the light intensity setting, the indoor lighting state can be checked at a glance and intuitively. That is, it is preferable to perform highlight display according to the light intensity input value around the first graphic. The periphery of the first graphic may be on the first graphic or may be around the first graphic. In the flowchart of FIG. 7, it goes without saying that the algorithm for highlight display is not limited to the above.

  Further, regarding the supply of luminous intensity information from the lighting setting device 100 to the lighting control device 200, when the luminous intensity information is sent by a separate transmission line for each lighting fixture Lij, only the luminous intensity information may be transmitted, but the luminous intensity information of all the lighting fixtures Lij. When information is multiplexed and transmitted, it goes without saying that the information is transmitted together with the identification code of the lighting fixture Lij so that the lighting control device 200 supplies the luminous intensity information of each lighting fixture Lij to the corresponding lighting fixture Lij without error. Yes. Further, it may be transmitted in a time-division manner in time slots corresponding to the number of lighting fixtures assigned to the lighting fixture Lij.

  Further, the light intensity information and highlight display information of each set of the lighting fixtures Lij is temporarily stored in a nonvolatile storage area provided in the storage unit 14 so that the storage remains even when the power is turned off. When the power is turned on, the previous illumination state may be reproduced.

  The highlight display method may be performed on or around the figure of the lighting fixture Lij, and the display form is not limited to the above description. Further, instead of the highlight display or together with the highlight display, the light intensity value or the% value of the light intensity value may be displayed numerically at a position on or near the figure of the corresponding lighting fixture Lij.

  The coordinate display system may be another system. The reference coordinates can be the center position of the figure. When the button has a circular shape, it may be determined that the button is touched when the center of the circle is the reference coordinate and the touch coordinates are within a predetermined radius around the center. These determinations may be performed based on geometry.

Further, the storage unit 14 is preferably a non-volatile recording medium, but can also be realized by a volatile recording medium. In addition, the control unit 15 can be usually realized by an MPU, a memory, or the like. Each processing procedure performed by the control unit 15 is usually realized by software, and the software is recorded in a recording medium such as a ROM. However, it may be realized by hardware (dedicated circuit). When the display processing unit 12 is included in the display unit 10, for example, when the display processing unit 12 is integrated with a liquid crystal touch panel, the control unit 15 may supply graphic information to the display unit 10.
As described above, according to the embodiment, the lighting conditions of a large number of lighting devices can be grasped at a glance, and for example, the lighting conditions of a remote room can be grasped easily and intuitively.

  In addition, it can be said that the illumination setting device in the embodiment includes an illumination status display device that visually outputs the light intensity at a predetermined point. The illumination status display device is configured to include a display unit of an illumination setting device. The predetermined point is usually two or more points.

  As already described, the inverter lighting system is suitable in terms of power saving as the lighting control device 200 that adjusts and sets the luminous intensity of each lighting fixture Lij of the lighting device 300. The inverter lighting method is a method of controlling the average luminous intensity by frequently repeating blinking of the light source and adjusting the time ratio of the lighting time. Such an illumination control circuit for lighting an inverter is generally provided inside each lighting fixture Lij. That is, the lighting control device 200 is distributed and arranged in each lighting fixture Lij. In this case, the lighting setting device 100 needs to transmit light intensity information corresponding to each lighting fixture Lij to the lighting control device 200 for the lighting fixture Lij inside each lighting fixture Lij. For this purpose, the lighting setting device 100 and the lighting control device 200 are connected by transmission lines as many as the number of lighting fixtures Lij, and the lighting setting device 100 transmits the luminous intensity information of each lighting fixture Lij via each transmission line. What is necessary is just to transmit to the lighting control apparatus 200 of each lighting fixture Lij.

  Further, the lighting control device 100 may transmit the light intensity information to the lighting control device 200 for the lighting fixture Lij inside each lighting fixture Lij via a LAN line. The LAN line couples the lighting setting device 100 and each lighting fixture Lij. Packet transmission can be applied to transmit luminous intensity information through a LAN line. When packet transmission is applied, for example, a luminaire identification code storage area and a luminous intensity information area are provided in each packet. In the lighting fixture identification code storage area, a lighting fixture identifier, for example, a numerical value of ij = 11 to 35, or “ij” in the case of the lighting fixture Lij is stored. In the luminous intensity information area, numerical values from 0% to 100% of the sensitivity lighting information table are stored. Each lighting fixture Lij of the lighting device 200 obtains light intensity information addressed to each of the lighting fixtures Lij (i = 1 to 3, j = 1 to 5) by examining each identifier of the received packet. It becomes possible to control the light intensity. In addition, you may time-division-superimpose and send to the several 15 time slots of the lighting fixture allocated to the lighting fixture Lij. A predetermined synchronization code is arranged at the head of the time slot. The lighting fixture Lij acquires information on its own time slot with reference to the synchronization signal. A part of the LAN line may be a wireless LAN line. For example, the lighting control device 200 for the lighting fixture Lij inside each lighting fixture Lij is connected by a wired LAN line, and one wireless LAN receiving terminal is connected to the wired LAN line. The luminous intensity information may be transmitted to the wireless LAN receiver by wireless communication using a wireless LAN system. If a communication system using a power line is applied as a wired LAN line, wiring work is simplified.

The control unit 15 transmits the packet to each lighting fixture Lij by the wireless LAN method. The lighting fixture Lij has a built-in wireless LAN receiver, receives the packet by the wireless LAN receiver, and the lighting fixture Lij itself. It is also possible to acquire the addressed packet, obtain light intensity information for itself, and control the light intensity to the set light intensity. That is, the means for transmitting the luminous intensity information from the illumination setting device 100 to the illumination control device 200 may be a wired communication unit, a wireless communication unit, a broadcasting unit, or the like.
(Embodiment 2)

  In the present embodiment, the light intensity setting using the all-on / all-off area 10a shown in FIG. 2 will be described. FIG. 3B shows an enlarged view of the all lit / all unlit figure 20 (third figure). The all-on / all-off figure 20 occupies about a half or more of the upper part of FIG. 5B, and from the bottom “all off”, “all on”, “0%”, “20%”, “40%” , “60%”, “80%”, and “100%” button graphics are provided as graphic parts. In the table of FIG. 5A, the rectangular coordinate value of each button graphic is stored together with the corresponding “graphic name” code and “next processing” corresponding to each row of area 2 to area 9. Area 1 is a rectangular coordinate value corresponding to the display position of the all lit / all unlit area 10a, but there is no need for “next processing” information.

  When the all-on / all-off area 10a is used, the luminosity of all the lighting fixtures in the room can be set in a lump. When the light intensity% buttons of “all off”, “0%”, “20%”, “40%”, “60%”, “80%”, “100%” are directly pressed, the control unit 15 displays the designated coordinates. The point indicated by the information is searched for which of the areas indicated by the rectangular coordinate values in FIG. 5A, the corresponding “graphic name” is checked, the corresponding “next process” is read, and the process is performed. . The processing means that the control unit 15 supplies the light intensity information corresponding to the “graphic name” to the lighting control device 200 to emit the light intensity of all the lighting fixtures Lij with the lightness of the corresponding lightness information, and The highlight display of the brightness corresponding to the magnitude of the luminous intensity information is performed around the figure.

  This series of procedures can be executed by the flowchart described in FIG. Area 2 is a rectangular coordinate value corresponding to the all-lit button, and the next process is to prompt the user to press the light intensity% button as a process of blinking the 0% to 100% button. .

Also in the present embodiment, the control unit 15 can usually be realized by an MPU, a memory, or the like. Each processing procedure performed by the control unit 15 is usually realized by software, and the software is recorded in a recording medium such as a ROM. However, it may be realized by hardware (dedicated circuit). When the display processing unit 12 is included in the display unit 10, for example, when the display processing unit 12 is integrated with a liquid crystal touch panel, the control unit 15 may supply graphic information to the display unit 10.
(Embodiment 3)

  In the first embodiment, the brightness designation figure 21 is displayed in the vicinity of the lighting fixture Lij, and the luminous intensity is input by selecting the light intensity% button of the brightness designation figure 21. In the present embodiment, the light intensity of each lighting apparatus is input using the light intensity% button inside the fully lit / all unlit area 10a instead of the brightness designation figure 21. That is, in the present embodiment, the illumination setting device is configured to input the first graphic information that is information related to the plurality of first graphics corresponding to the plurality of lighting fixtures and the third graphic for inputting the luminous intensity of all the lighting fixtures. A storage unit storing third graphic information on the display, an operation screen having a first graphic based on the first graphic information stored in the storage unit, and a third graphic displayed on the operation screen A display unit displayed above, an operation unit that detects an instruction to the operation screen, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction based on the instruction detected by the operation unit, and an input Based on the indicated coordinate information acquired by the processing unit, a light intensity input value is detected, and a light intensity information corresponding to the light intensity input value is output as light intensity information for all lighting fixtures. All first figures corresponding to all lighting fixtures Performs display according to light intensity input value on or around the.

  In the flowchart of FIG. 7, instead of displaying the brightness designation figure 21 in (S23), the figure of the lighting fixture Lij is highlighted with a thick outline, (S24), (S25), (S26) are omitted, and (S27 ), The six light intensity% buttons in the all-lit / all light-off area 10a are blinked, it is determined whether any of the six light intensity% buttons are touched, and the light intensity% value determined to be touched is determined. The light intensity information of the lighting fixture Lij may be output, the highlighting of the lighting fixture Lij may be canceled, and the surroundings may be highlighted. It should be noted that in (S27), it is less misunderstood by the user to stop displaying the characters “all lit / all lit”, all lit button, all lit button in the all lit / all unlit area 10a. In this case, the third graphic is a graphic with six luminous intensity% buttons. This embodiment is functionally almost the same as displaying the brightness designation figure 21 as the second figure in the all-lit / all-off area 10a. From another point of view, the third graphic can also be viewed as the second graphic arranged at a certain position.

  In this embodiment, the table in FIG. 5B is not necessary. Needless to say, the contents of the “next processing” column in the table of FIG. Areas 1 and 2 are unnecessary, and in areas 3 to 9, “the luminous intensity and highlight of lighting fixture Lij are set to xx%. The blinking of the luminous intensity% button is stopped”. In the area Lij, “a figure of the lighting fixture Lij is highlighted. The luminous intensity% button in the all-lit / all-off area 10a is blinked”.

The illumination setting device in the present embodiment is substantially the same in function as displaying the brightness designation figure 21 as the second figure in the area of the all-lit / all-off area 10a. That is, the third graphic in the present embodiment is obtained by arranging the second graphic at a fixed position.
(Embodiment 4)

  In Embodiment 3 described above, the lighting fixtures Lij are selected one by one and their luminous intensity is set, but a plurality of lighting fixtures Lij may be selected and set together. The user designates and selects a desired figure in order from the figure of the lighting fixture Lij. The control unit 15 detects that the lighting fixture Lij has been selected, and blinks or highlights the figure of the selected lighting fixture Lij. In parallel with this display, the control unit 15 displays “0%”, “20%”, “40%”, “60%”, “80%”, “100%” of the all lit / unlit area 10a. Flashes the luminous intensity% button. When it is determined that the user has selected the necessary lighting fixture Lij, the user can blink “0%”, “20%”, “40%”, “60%”, “80%”, A desired light intensity% button is selected from the light intensity% buttons of “100%”. The control unit 15 detects the selection of the light intensity% button, and the light intensity information corresponding to the selected light intensity% button is blinking or highlighted, in other words, the light intensity information of the plurality of selected lighting fixtures Lij. As luminosity information is output.

  There is a case where the user selects the wrong lighting fixture Lij and wants to cancel the selection. In this case, when the user selects the lighting fixture Lij figure that is blinking or highlighted again, the control unit 15 For the lighting fixture Lij that is blinking or highlighted, the blinking or highlighted display may be eliminated.

  For this purpose, in the flowchart of FIG. 7, instead of displaying the brightness designation figure 21 in (S23), the figure of the luminaire Lij is highlighted or blinked with a thick outline, Six luminous intensity% buttons in the all extinction area 10a are displayed blinking. If the luminaire Lij has already been selected and is highlighted or blinking, the selection is canceled and the highlighting or blinking is stopped. In (S24), if Yes, bypass (S25) and return to (S20). (S23) is repeated as the instruction to select the lighting fixture Lij is added or canceled. In (S24) and (S26), it is determined whether or not any of the six luminous intensity% buttons has been instructed. If it is determined that there is an instruction, the result is Yes, and the process proceeds to (S27). In (S27), the luminous intensity instruction% is determined from the indicated coordinate information, and the process proceeds to (S28). In (S28), corresponding to the instructed light intensity% value, light intensity information for a plurality of selected lighting fixtures Lij is output, and the process proceeds to (S29). In (S29), the highlighted display or the blinking display of the plurality of selected lighting fixtures Lij may be canceled and the surroundings may be highlighted. In (S23), the misunderstanding of the user is reduced by stopping the display of the characters “all lit / all lit”, all lit button, and all lit button in the all lit / all unlit area 10a. In this case, the third graphic is a graphic with six luminous intensity% buttons. This embodiment is functionally almost the same as displaying the brightness designation figure 21 as the second figure in the all-lit / all-off area 10a. From another point of view, the third graphic in the present embodiment can be regarded as the second graphic arranged at a certain position.

In this embodiment, the table in FIG. 5B is not necessary. Needless to say, the contents of the “next processing” column in the table of FIG. Areas 1 and 2 are unnecessary, and in areas 3 to 9, “the luminous intensity and highlight of lighting fixture Lij are set to xx%. The blinking of the luminous intensity% button is stopped”. In the area Lij, “if the lighting fixture Lij is not selected, the figure of the lighting fixture Lij is highlighted. If the lighting fixture Lij has been selected, the highlighting of the figure of the lighting fixture Lij is stopped. The light intensity% button in the area 10a is flashed. "
(Embodiment 5)

  Next, a case where the more button area of the display screen of FIG. 2 is used instead of the brightness designation figure 21 will be described. If the “brighter” button in the button area is instructed after designating the first figure of the lighting fixture Lij, the luminous intensity of the selected lighting fixture Lij is increased. When the “dark” button is instructed, the light intensity of the selected luminaire Lij is decreased. The “brighter” button and the “darker” button are the third figure.

  In the flowchart of FIG. 7, instead of displaying the brightness designation figure 21 in (S23), the figure of the lighting fixture Lij is highlighted with a thick outline, (S24), (S25), (S26) are omitted, and (S27 ), The “brighter” button and “darker” button blink, and it is determined whether any of the “brighter” button or “darker” button is instructed. If it is determined that the “brighter” button has been instructed, In S28), the luminous intensity information of the lighting fixture Lij is output while being increased. In (S29), the blinking display is stopped, the highlighting of the lighting fixture Lij is canceled, and the surroundings are displayed while increasing the highlight display. Good. If it is determined in (S27) that the “dark” button has been instructed, the light intensity information of the lighting fixture Lij is outputted while decreasing in (S28), and the blinking display is stopped in (S29), and the lighting fixture Lij is displayed. The highlighting may be canceled and the surroundings may be displayed while reducing the highlighting.

In this embodiment, the table in FIG. 5B is not necessary. Further, a column of “brighter” button and “darker” button is added to the table of FIG. 5A to store the rectangular coordinate value, the figure name, and the next processing. The contents of the “next processing” column are “increase the brightness of the lighting fixture Lij and increase the highlight” for the “bright” button, and “decrease the brightness of the lighting fixture Lij for the“ dark ”button. And reduce the highlights. "
(Embodiment 6)

  In each of the above embodiments, the maximum luminous intensity of the luminous intensity information is set to 100%, and is set at intervals of 20%. FIG. 8 is an example of buttons and bars for other setting methods. FIGS. 8A1 and 8A2 are examples of lighting device buttons (first graphics) corresponding to the lighting fixture Lij. When the light is turned off, a black frame concentric button is displayed as shown in FIG. When lit, the display is blacked out from the inside of the circle in proportion to the magnitude of the light intensity. FIGS. 8B1 and 8B2 are another example and display the magnitude of luminous intensity in a pie chart. These figures can be used as the first figure.

FIGS. 8C, 8D, 8E, and 8F are displayed within the brightness designation figure 21 as the second figure component, and are buttons and bars for setting the luminous intensity. . In setting the luminous intensity of the lighting fixture Lij, the set luminous intensity can be increased by pressing the upward arrow button in FIG. 8C, and the setting luminous intensity can be decreased by pressing the downward button. FIG. 8D shows another example. When the light intensity setting of the lighting fixture Lij is set, the setting light intensity can be increased by pulling the knob of the bar up with a finger, and the setting light intensity can be decreased by lowering. The light intensity corresponding to the knob position is displayed in% at the top of the bar. FIG. 8E illustrates another example of buttons 0 to 100. FIG. 8F is a button for determining the light intensity setting. Thus, the form and arrangement of the buttons are not limited to the examples in the first and second embodiments. 8C, 8D, 8E, and 8F may be used as the third graphic.
(Embodiment 7)
In each of the above embodiments, the light intensity of the lighting device is set. However, in this embodiment, the control system that can set the illuminance at a predetermined position in the room, and the control terminal device for the control system can be set. explain.

  FIG. 9 is a block diagram of an illumination system capable of setting illuminance according to the present embodiment. The illumination system includes an illumination setting device 100a, a conversion device 400, an illumination control device 200, and an illumination device 300. The lighting control device 200 and the lighting device 300 may be the same as those described in the first embodiment.

  The illumination setting device 100a of the present embodiment has substantially the same configuration as the illumination setting device 100 shown in FIG. The figure of each lighting fixture Lij in FIG. 2 is the first figure, and indicates the illuminance setting position, that is, the position where the illuminance can be set. Accordingly, when the lighting fixture Lij is touched, as shown in FIG. 3, the brightness designation figure 21 as the second figure is displayed in the vicinity, and the user selects and presses the 0% to 100% button. In the present embodiment, a value from 0% to 100% does not represent the light intensity of the lighting fixture Lij but represents the illuminance at the position of the lighting fixture Lij. Therefore, the illumination setting device 100 of the present embodiment is a device that sets illuminance instead of luminous intensity. The% button of the all-lit / all-off area 10a, which is the third figure shown in FIG. If the luminosity in each of the above embodiments is read as illuminance, this embodiment is obtained. Therefore, the detailed procedure of this embodiment and the description of the contents of the tables in FIGS. This embodiment can be implemented. The highlight display corresponding to the magnitude of the set illuminance value is also performed at the position on the display unit 10 where the illuminance setting is input, as in the above embodiments. The 1st figure in this Embodiment should just be a figure which shows a user the position which can set illumination intensity. In addition to the lighting fixture Lij, a circular or square figure may be used. As will be described later, a square mesh figure may be used. The 2nd figure in this Embodiment is a figure which shows the menu for inputting illuminance. In addition, the third graphic explained in the second embodiment is used as a graphic used for inputting the illuminance at all illuminance setting positions in the present embodiment. The third graphic in the third embodiment is used as a graphic used for inputting the illuminance at each illuminance setting position.

  Next, the configuration of the conversion device 400 will be described. The conversion device 400 is a device that converts input illuminance information into luminous intensity information. In the conversion device 400, the target information storage unit 30 stores illuminance setting value information supplied from the illumination setting device 100a. The control unit 34 has a function of outputting light intensity information for each lighting fixture Lij of the lighting device 300 and supplies light intensity information to the conversion model 35. The conversion model 35 is a calculation device having a function of calculating a predicted illuminance value at a predetermined position in the room when the light intensity information of each lighting fixture Lij is input as input information. Moreover, it is a model which can predict the illumination value of the predetermined position illuminated by each lighting fixture Lij of the room where the illuminating device 300 is installed. From the conversion model 35, the predicted illuminance value at a predetermined position is supplied to the observation information storage unit 31. The comparison unit 32 compares the illuminance setting value information in the target information storage unit 30 with the predicted illuminance value in the observation information storage unit 31 and supplies the comparison result to the determination unit 33. The determination unit 33 changes the light intensity information for each lighting fixture Lij stored in a memory provided in the control unit 34 so that the difference between the illuminance setting value information and the predicted illuminance value is reduced. Finally, the predicted illuminance value of the observation information storage unit 31 is sufficiently close to the illuminance setting value information of the target information storage unit 30. For example, when the position of the luminaire Lij displayed in FIG. 2 is adopted as the predetermined position of the conversion model 35 and the illuminance value at that position is set and input, the predicted illuminance value of the observation information storage unit 31 is set to the set input value. Close value. At this time, when the luminous intensity information output by the control unit 34 is supplied to the lighting device 300, the illuminance at the position directly below the lighting fixture Lij in the actual room becomes the value set and input. When setting the illuminance at a plurality of positions, the illuminance at each position can be controlled to a value close to the set input value.

  In the above description of the present embodiment, the illuminance at the position of the lighting fixture Lij, that is, the illuminance directly below the lighting fixture Lij is set. As the first figure, a circular button Bij may be displayed instead of the figure of the lighting fixture Lij. The illuminance at the position of the button Bij is set as the illuminance setting value information of the target information storage unit 30, and the illuminance prediction value of the observation information storage unit 31 predicts and calculates the illuminance at the position of the button Bij. In this way, it is possible to control the illuminance at a position other than the position of the lighting fixture Lij to be a set value.

  The conversion model 35 is a computer that calculates the illuminance at P positions when the Q lighting devices in the room change the light intensity. The illuminance Li (i = 1, 2,... P) at each of the P positions is obtained by multiplying each luminous intensity value Kj (j = 1, 2,... Q) of the Q lighting fixtures Lij by a coefficient .PHI.ij. To obtain the total. That is, Li = ΣΦij * Kj. In other words, the influence of the luminous intensity of each lighting device on the illuminance is independent of each other, and when there is a linear relationship, the illuminance Li can be calculated by the previous equation. The conversion model 35 calculates P output information from the Q pieces of input information, and supplies the output information to the P memories of the observation information storage unit 31 as a predicted illuminance value.

The coefficient Φij differs depending on the position of the illumination device and the position of the observation point. It also depends on the reflection and absorption of light by the ceiling, walls, floors, furniture, etc. Therefore, the coefficient Φij is determined in consideration of these reflections and absorptions. The coefficient Φij may be obtained by actually measuring the degree of influence on the illuminance at each position i for each lighting device j in an actual room.
If there are a number of states such as windows, shutters, screens, curtains, etc. in the room, a plurality of conversion models may be prepared corresponding to each state and selected and used.
P observation points can be freely set on the floor, the height of the desk, and other positions. A coefficient Φij matched to each position may be prepared.

The interior of the room is divided into a two-dimensional mesh in a plane, and a coefficient Φij (in this case, P is a large number) at the position of each intersection is prepared, on the liquid crystal touch panel of the display unit 10 of the illumination setting device 100a The target illuminance may be set for some freely selected intersections, and the illuminance may be calculated by calculating only the expression related to the position. In this way, it is possible to set the illuminance at a substantially free position as the target illuminance without being limited to the position of the lighting fixture Lij. A grid diagram corresponding to the mesh may be displayed as the first graphic on the liquid crystal touch panel of the display unit 10 to select an intersection. Highlighting may be performed at the intersection and its surroundings. The room can be divided into a three-dimensional mesh, and the illuminance at an arbitrary position in the three-dimensional space can be set to a desired value. That is, the button Bij is displayed at an almost arbitrary position in the room area displayed on the liquid crystal touch panel, and the illuminance at that position is set.
As described above, the conversion model 39 may be modeled by an optical line such as a direct ray or a reflected ray from an indoor light source, a reflectance, or an absorptance.

  Also in the present embodiment, since the highlight display corresponding to the magnitude of the illuminance setting value is performed at the touch position on the display unit 10 where the illuminance setting is input, the illumination state in the room can be recognized at a glance. That is, it is easy to recognize the improvement point by knowing the actual lighting situation (illuminance, not luminosity) of the room. That is, it can be said that the illumination setting device in the present embodiment includes an illumination status display device that visually outputs the illuminance at a predetermined point. The illumination status display device is configured to include a display unit of an illumination setting device. The predetermined point is usually two or more points.

  Note that the conversion device 400 can usually be realized by an MPU, a memory, or the like. Each processing procedure performed by the conversion device 400 is usually realized by software, and the software is recorded in a recording medium such as a ROM. However, it may be realized by hardware (dedicated circuit). Further, as described in the first embodiment, the method of supplying luminous intensity information from the control unit 34 to the illumination control unit 200 can be applied to wired transmission, wired LAN method, wireless LAN method, and the like. Any communication means, broadcast means, etc. may be used.

  In addition, each processing procedure described with the flowcharts of FIGS. 6 and 7 in each of the above embodiments may be branched from a main routine including power ON and power OFF of the processing program of the illumination setting devices 100 and 100a. Alternatively, it may be activated by interruption processing in the main routine.

  The lighting setting devices 100 and 100a of the present invention are generally installed on the wall surface of a conference room or the entrance of a hall. You may make it transmit to the apparatus 200,200a. It can also be configured on a portable information device such as a PDA, a personal computer, a mobile phone, etc., so that the lighting can be set easily.

  When the mouse is applied as the operation unit 11, the input processing unit 12 responds to a click instruction by the mouse and displays the display coordinate position information of the pointer icon stored in the control unit 14 as the position of the instruction. What is necessary is just to acquire as instruction | indication coordinate information which is the information to show. As the operation unit 11, a navigation switch as used in a mobile phone or the like, a cross-shaped up / down / left / right movement switch used for a joystick, a game, a remote control, etc., and a cross-shaped with a determination switch at the center Even when the operating device is used, the designated coordinate information can be acquired by performing the same information processing. Instead of using the pointer icon, the operation target may be determined by moving and selecting the operation target in the order of each lighting fixture Lij and each figure of each button. In this case, the designated coordinate information is the coordinate position corresponding to the figure selected for movement. A figure name code can be used instead of the coordinate position. Since these pieces of information are stored in the control unit 15, the control unit 15 itself may use the information to determine the content of the instruction. A voice guide such as “Please select a luminaire” or “Please select brightness” may be used in combination with the blinking display. In this case, it goes without saying that the control unit 15 is provided with a sound information generation function to generate sound from a speaker (not shown).

Note that the processing of the illumination setting device 100 and the illumination control device 200 in all the embodiments described above may be realized by software. Then, this software may be distributed by software download or the like. Further, this software may be recorded and distributed on a recording medium such as a CD-ROM.
The present invention is not limited to the above-described embodiments, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  The lighting setting device and the lighting setting method according to the present invention are useful for lighting control systems in buildings, outside, halls and various facilities, and in various control systems such as temperature management and environmental management. It can be used.

The block diagram of one Embodiment of the illumination setting apparatus of this invention The block diagram containing an example of the display of one Embodiment of the illumination setting apparatus of this invention The figure of an example of the display of one embodiment of the lighting setting device of the present invention The figure of one Embodiment of the display coordinates of the lighting setting device of the present invention The figure of one Embodiment of the illumination control information of the illumination setting apparatus of this invention The flowchart of one Embodiment of the illumination control procedure of the illumination setting apparatus of this invention The flowchart of one Embodiment of the illumination control procedure of the illumination setting apparatus of this invention Example of display figure of illumination setting device of the present invention The block diagram of other embodiment of the illumination setting apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Display part 10a All lighting / all extinction area 10b Lighting fixture area 11 Operation part 12 Display processing part 13 Input processing part 14 Storage part 15 Control part 30 Target information storage part 31 Observation information storage part 32 Comparison part 33 Judgment part 34 Control part 35 Conversion Model 100 Illumination Setting Device 200 Illumination Control Device 300 Illumination Device

Claims (24)

A first graphic information that is information relating to a plurality of first graphics corresponding to a plurality of lighting fixtures, and a storage unit that stores second graphic information relating to second graphics for inputting the luminous intensity for each lighting fixture; ,
Based on the first graphic information stored in the storage unit, a display unit that displays an operation screen having a first graphic and displays the second graphic on the operation screen;
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the indicated coordinate information acquired by the input processing unit, a first graphic that is instructed is detected, and a control unit that configures a second graphic based on the second graphic information;
A display processing unit for instructing the display unit to display a second graphic configured by the control unit in the vicinity of the first graphic detected by the control unit;
The control unit is instruction coordinate information acquired by the input processing unit, acquires a luminous intensity input value based on instruction coordinate information indicating an instruction for the second graphic,
And the said control part is an illumination setting apparatus which outputs the luminous intensity information corresponding to the said luminous intensity input value as luminous intensity information for lighting fixtures corresponding to the said instruct | indicated 1st figure. A first graphic information that is information relating to a plurality of first graphics corresponding to a plurality of lighting fixtures, and a storage unit that stores third graphic information relating to third graphics for inputting the luminous intensity of all the lighting fixtures; ,
Based on the first graphic information stored in the storage unit, a display unit that displays an operation screen having a first graphic and displays the third graphic on the operation screen;
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the indicated coordinate information acquired by the input processing unit, a light intensity input value is detected, and a light intensity information corresponding to the light intensity input value is output as light intensity information for all the lighting fixtures;
An illumination setting device comprising: A first graphic information that is information related to a plurality of first graphics corresponding to a plurality of lighting fixtures, and a storage unit that stores third graphic information related to a third graphics for inputting the luminous intensity for each lighting fixture; ,
Based on the first graphic information stored in the storage unit, a display unit that displays an operation screen having a first graphic and displays the third graphic on the operation screen;
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the designated coordinate information acquired by the input processing unit, one or more designated first graphics are detected, and based on the third graphics information, a control unit constituting a third graphic; ,
A display processing unit for instructing the display unit to display a third graphic configured by the control unit;
The control unit is instruction coordinate information acquired by the input processing unit, acquires a luminous intensity input value based on instruction coordinate information indicating an instruction to the third graphic,
And the said control part is an illumination setting apparatus which outputs the luminous intensity information corresponding to the said luminous intensity input value as luminous intensity information for lighting fixtures corresponding to the said instruct | indicated 1st figure. The illumination setting device according to any one of claims 1 to 3, wherein the display unit performs display corresponding to the light intensity input value on or around the first graphic corresponding to the light intensity input. The illumination setting device according to claim 4, wherein the display according to the light intensity input value on or around the first graphic is a highlight display according to the light intensity input value. Memory storing first graphic information that is information related to a plurality of first graphics corresponding to a plurality of illuminance setting positions, and second graphic information related to a second graphic for inputting illuminance for each illuminance setting position And
An operation screen having a first graphic is displayed based on the first graphic information stored in the storage unit, and a second graphic is displayed on the operation screen based on the second graphic information. A display unit to
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the indicated coordinate information acquired by the input processing unit, a first graphic that is instructed is detected, and a control unit that configures a second graphic based on the second graphic information;
A display processing unit for instructing the display unit to display a second graphic configured by the control unit in the vicinity of the first graphic detected by the control unit;
The control unit is instruction coordinate information acquired by the input processing unit, acquires an illuminance input value based on instruction coordinate information indicating an instruction for the second graphic,
And the said control part is an illumination setting apparatus which outputs the illumination intensity information corresponding to the said illumination intensity input value as illumination intensity information of the illumination intensity setting position corresponding to the said instruct | indicated 1st figure. Memory storing first graphic information that is information related to a plurality of first graphics corresponding to a plurality of illuminance setting positions, and third graphic information related to a third graphic for inputting the illuminances at all illuminance setting positions. And
An operation screen having a first graphic is displayed based on the first graphic information stored in the storage unit, and a third graphic is displayed on the operation screen based on the third graphic information. A display unit to
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the indicated coordinate information acquired by the input processing unit, a control unit that detects an illuminance input value and outputs illuminance information corresponding to the illuminance input value as illuminance information of the total illuminance setting position;
An illumination setting device comprising: Memory storing first graphic information that is information related to a plurality of first graphics corresponding to a plurality of illuminance setting positions, and third graphic information related to a third graphic for inputting illuminance for each illuminance setting value And
An operation screen having a first graphic is displayed based on the first graphic information stored in the storage unit, and a third graphic is displayed on the operation screen based on the third graphic information. A display unit to
An operation unit for detecting an instruction to the operation screen;
Based on the instruction detected by the operation unit, an input processing unit that acquires instruction coordinate information that is information indicating a position of the instruction;
Based on the designated coordinate information acquired by the input processing unit, one or more designated first graphics are detected, and based on the third graphics information, a control unit constituting a third graphic; ,
A display processing unit for instructing the display unit to display a third graphic configured by the control unit;
The control unit is instruction coordinate information acquired by the input processing unit, acquires an illuminance input value based on instruction coordinate information indicating an instruction for the third graphic,
And the said control part is an illumination setting apparatus which outputs the illumination intensity information corresponding to the said illumination intensity input value as illumination intensity information of the illumination intensity setting position corresponding to the said instruct | indicated 1st figure. The illumination setting device according to any one of claims 6 to 8, wherein the display unit performs display corresponding to the illuminance input value on or around the first graphic corresponding to the illuminance input. The illumination setting device according to claim 9, wherein the display according to the illuminance input value on or around the first graphic is a highlight display according to the illuminance input value. The lighting setting device according to any one of claims 1 to 10, wherein the first graphic is a graphic of a lighting fixture. An illumination status display device that visually outputs the light intensity at a predetermined point. An illumination status display device that visually outputs illuminance at a predetermined point. Displaying a plurality of first figures corresponding to a plurality of lighting fixtures on the display unit;
A procedure for receiving an instruction for any of the first figures;
Displaying a second graphic for light intensity input in the vicinity of the first graphic that has received the instruction;
Receiving a command for the second graphic;
A procedure for detecting a luminous intensity input value based on designated coordinate information which is information indicating a position of an instruction with respect to the second graphic;
A procedure for outputting luminous intensity information corresponding to the detected luminous intensity input value as luminous intensity information for a luminaire corresponding to the first graphic having received the instruction;
A lighting setting method characterized by comprising: Displaying a plurality of first figures corresponding to a plurality of lighting fixtures and a third figure for light intensity input on the display unit;
Receiving a command for the third graphic;
A procedure for detecting a luminous intensity input value based on indication coordinate information which is information indicating the position of an indication with respect to the third graphic;
And a procedure for outputting luminous intensity information corresponding to the detected luminous intensity input value as luminous intensity information for a lighting fixture corresponding to the plurality of first figures. Displaying a plurality of first figures corresponding to a plurality of lighting fixtures on the display unit;
A procedure for receiving an instruction for any of the first figures;
A procedure for displaying a third graphic;
Receiving a command for the third graphic;
A procedure for detecting a luminous intensity input value based on indication coordinate information which is information indicating the position of an indication with respect to the third graphic;
A procedure for outputting luminous intensity information corresponding to the detected luminous intensity input value as luminous intensity information for a luminaire corresponding to the first graphic having received the instruction;
A lighting setting method characterized by comprising: The illumination setting method according to any one of claims 14 to 16, wherein a display corresponding to the light intensity input value is performed on or around the first graphic corresponding to the light intensity input. The illumination setting method according to claim 17, wherein the display according to the light intensity input value on or around the first graphic is a highlight display according to the light intensity input value. Displaying a plurality of first figures corresponding to a plurality of illuminance setting positions on the display unit;
A procedure for receiving an instruction for any of the first figures;
Displaying a second graphic for illuminance input in the vicinity of the first graphic that has received the instruction;
Receiving a command for the second graphic;
A procedure for detecting an illuminance input value based on instruction coordinate information which is information indicating a position of an instruction with respect to the second graphic;
A procedure for outputting luminous intensity information corresponding to the detected luminous intensity input value as illuminance information of an illuminance setting position corresponding to the first graphic that has received the instruction;
A lighting setting method characterized by comprising: Displaying a plurality of first figures corresponding to a plurality of illuminance setting positions and a third figure for illuminance input on the display unit;
Receiving a command for the third graphic;
A procedure for detecting an illuminance input value based on instruction coordinate information which is information indicating a position of an instruction with respect to the third graphic;
And a procedure for outputting light intensity information corresponding to the detected illuminance input value as illuminance information at illuminance setting positions corresponding to the plurality of first figures. Displaying a plurality of first figures corresponding to a plurality of illuminance setting positions on the display unit;
A procedure for receiving an instruction for any of the first figures;
A procedure for displaying a third graphic;
Receiving a command for the third graphic;
A procedure for detecting an illuminance input value based on instruction coordinate information which is information indicating a position of an instruction with respect to the third graphic;
A procedure for outputting luminous intensity information corresponding to the detected illuminance input value as illuminance information of an illuminance setting position corresponding to the first graphic that has received the instruction;
A lighting setting method characterized by comprising: The illumination setting method according to any one of claims 19 to 21, wherein a display corresponding to the illuminance input value is performed on or around the first graphic corresponding to the illuminance input. 23. The illumination setting method according to claim 22, wherein the display according to the illuminance input value on or around the first graphic is a highlight display according to the illuminance input value. The lighting setting method according to any one of claims 14 to 23, wherein the first graphic is a graphic of a lighting fixture.

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