JP2020107480A - Information setting device, lighting control system, and service providing system - Google Patents

Abstract

To provide a technology for simplifying a correspondence between the installation position of a beacon transmission unit on an image corresponding to a real space and beacon identification information.SOLUTION: An information setting device is a device applicable to the following system. In this system, a beacon transmitting unit is provided in a lighting device, and the beacon transmitting unit is installed at the installation position of the lighting device in a real space. Then, a control unit of the information setting device causes a display unit to display an image corresponding to the real space in which the lighting device is installed and a switch for turning on the lighting device at least once. In addition, the control unit generates at least a part of beacon identification information for identifying the beacon transmitting unit, and associates the designated installation position of the beacon transmitting unit with the beacon identification information for identifying the beacon transmitting unit when the installation position of the beacon transmitting unit on the image corresponding to the installation position of the beacon transmitting unit in the real space that can be confirmed by lighting the lighting device by operating the switch is designated by an input unit.SELECTED DRAWING: Figure 2

Description

The present invention relates to a system to which a beacon technology is applied and an information setting technology in the system.

In a system to which beacon technology is applied, the current position of a terminal device (such as a smartphone) in a real space such as an office or a store is calculated by using a beacon signal received by the terminal device and a reception intensity of the beacon signal. It can be specified (for example, see Patent Document 1). In recent years, it has been proposed to use such a technique to provide a service according to the current position of the terminal device (for example, refer to Patent Document 2).

In the technology for identifying the current position of the terminal device, after installing the beacon transmitter that transmits the beacon signal on the ceiling or wall in the real space, the installation position of the beacon transmitter in the real space and the beacon transmitter are set. Corresponding data in which the beacon identification information for identification is associated with each other needs to be created using a PC, a mobile terminal device, or the like. Such correspondence data makes the installation position of the beacon transmission unit in the real space correspond to the installation position of the beacon transmission unit on the map image corresponding to the real space, and also installs the beacon transmission unit on the image. It is created by associating the position with the beacon identification information. According to this correspondence data, the installation position in the real space of the beacon transmitter that is transmitting the beacon signal can be specified from the beacon identification information included in the beacon signal. Further, the distance from the beacon transmitting unit to the terminal device can be calculated from the reception intensity. Then, the current position of the terminal device in the real space can be specified based on the installation position of the beacon transmission unit in the real space and the distance from the beacon transmission unit.

JP, 2013-33423, A Patent No. 5650870

Conventionally, beacon identification information has been set in advance in a beacon transmitting unit before being installed on a ceiling or a wall in a real space. Therefore, in the step of creating the corresponding data performed after the installation of the beacon transmission unit in the real space, the creator confirms the beacon identification information of the beacon transmission unit or installs the beacon transmission unit in the real space. The complicated work of remembering the position and the beacon identification information of the beacon transmission unit, correctly specifying the installation position of the beacon transmission unit on the map image, and associating the beacon identification information with the installation position Had to do.

Therefore, an object of the present invention is to provide a technique for simplifying the correspondence between the installation position of the beacon transmission unit on the image corresponding to the real space and the beacon identification information.

An information setting device according to the present invention is a device applied to the following system, and includes a display unit, an input unit, and a control unit. Here, in this system, a beacon transmitting unit is provided in the lighting device, and the beacon transmitting unit is installed at the installation position of the lighting device in the real space. Then, the control unit causes the display unit to display an image corresponding to the real space in which the lighting device is installed and a switch for turning on the lighting device at least once. In addition, the control unit generates at least a part of the beacon identification information for identifying the beacon transmission unit, and on the image corresponding to the installation position of the beacon transmission unit in the real space that can be confirmed by lighting the lighting device by operating the switch. When the installation position of the beacon transmission unit is designated by the input unit, the installation position of the designated beacon transmission unit and the beacon identification information for identifying the beacon transmission unit are associated with each other.

According to the information setting device, the setting person can confirm the installation position of the lighting device in the real space and the installation position of the beacon transmission unit in the real space by turning on the lighting device by operating the switch. Thereby, the setter can specify the installation position of the beacon transmission unit on the image based on the confirmed installation position of the beacon transmission unit in the real space. Then, with the designation of the installation position of the beacon transmission unit on the image by the setter, the information setting device associates the beacon identification information with the specified installation position. Therefore, the configurator confirms the installation position of the beacon transmission unit in the real space by operating the switch, and specifies the installation position of the beacon transmission unit on the image based on the confirmation, and the setting operation is performed on the image. The installation position of the beacon transmission unit and the beacon identification information can be associated with each other.

According to the present invention, the association between the installation position of the beacon transmission unit on the image corresponding to the real space and the beacon identification information is simplified.

It is a conceptual diagram showing the lighting control system concerning an embodiment. It is a conceptual diagram which showed the (A) lighting device and the (B) information setting device with which a lighting control system is equipped. It is a figure showing an example of information corresponding data in which matching was recorded by information setting processing which an information setting device performs. 6 is a flowchart showing an information setting process and an operation performed by a setting person. It is the figure which showed the input screen of UUID. It is the figure which showed the screen where the map image was displayed. It is the figure which showed the drag operation which arranges the icon on the map picture. It is the figure which showed the state where the confirmation image of beacon identification information was displayed. 7 is a flowchart showing a position specifying process executed by the information management device. It is a flow chart which showed an example of the lighting control processing which a lighting control device performs. It is a figure showing each example of (A) control corresponding data, (B) lighting mode data, and (C) reception time data. It is a conceptual diagram which showed visually the illuminating device which exists in the predetermined area|region centering on the position of a terminal device. It is the flowchart which showed the other example of the lighting control processing which a lighting control device performs. It is the flowchart which showed a part of illumination control process which concerns on another example. It is the figure which showed each example of (A) specific time data and (B) setting change object data. It is a conceptual diagram which visually showed the apparatus identification information (object of setting change of illumination mode) matched by setting change target data. It is a conceptual diagram which showed the service provision system which is one of the modified examples of a lighting control system.

An embodiment in which the present invention is applied to a lighting control system will be specifically described.

[1] Configuration of Lighting Control System FIG. 1 is a conceptual diagram showing a lighting control system according to the embodiment. The lighting control system includes a plurality of lighting devices 1 having a function of transmitting a beacon signal Sb, a lighting control device 2 that controls the lighting device 1 by wireless communication, and a terminal device 3 that can receive the beacon signal Sb. The current position P1 of the terminal device 3 in the real space is specified based on the beacon signal Sb received by the terminal device 3, and the service corresponding to the specified current position P1 (illumination by the lighting control device 2 in the present embodiment is provided. Control) to the terminal device 3 or a user who owns the terminal device 3. Specifically, in the lighting control system, the terminal device 3 uses the information setting device 4 that associates various pieces of information (positional information, identification information, etc.) and the information associated by the information setting device 4. An information management device 5 for identifying the current position P1 of the terminal device 3 in the real space from the received beacon signal Sb is further provided.

The specific configuration of the lighting control system described below is not limited to the one having a plurality of lighting devices 1 (see FIG. 1), but can be applied to the one having only one lighting device 1. In addition, the lighting control device 2 and the information management device 5 are not limited to being configured as separate devices, but may be configured as a single device.

<Lighting device>
FIG. 2A is a conceptual diagram showing the lighting device 1. The lighting device 1 includes an LED light source 11A, a power supply unit 11B that supplies power to the LED light source 11A, a wireless module 12, a control unit 13 that controls the power supply unit 11B and the wireless module 12, and a storage unit 14. In this embodiment, the control unit 13 and the storage unit 14 are built in the wireless module 12. And the control part 13 controls the electric power supplied to the LED light source 11A from the said power supply part 11B by transmitting a control signal to the power supply part 11B, and by this, the illumination (lighting, light extinction, dimming) of the LED light source 11A. , Toning, etc.). At least one of the control unit 13 and the storage unit 14 may be built outside the wireless module 12 as a device separate from the wireless module 12.

The wireless module 12 functions as a communication unit 12A that enables bidirectional wireless communication with the lighting control device 2 and the like by wirelessly connecting the lighting device 1 and a network (WAN, LAN, etc.). Then, the illumination control for the illumination device 1 is executed by the illumination control device 2 via the wireless module 12 (communication unit 12A). The wireless module 12 may be removable.

In the lighting device 1, device identification information Ia for identifying the lighting device 1 is set. The device identification information Ia is set in the lighting device 1 by being stored in the storage unit 14 at the manufacturing stage of the lighting device 1 from the factory. The device identification information Ia is used to identify and control the lighting devices 1 individually and collectively manage the controls (lighting control, etc.). On the other hand, when the lighting device 1 is installed on the ceiling or the wall in the real space, the lighting device 1 is usually installed without being distinguished by the device identification information Ia. Therefore, in order to control the lighting devices 1 individually and collectively, the installation position of the lighting device 1 in the real space and the device identification information Ia of the lighting device 1 are installed after the lighting device 1 is installed. It is necessary to replace the correspondence with correspondence data (see FIG. 3) that can be managed by the lighting control device 2.

Therefore, in the present embodiment, the information setting device 4 executes a process of replacing the above-described correspondence relationship of the lighting device 1 with correspondence data (see steps S13 to S15 and S22 in FIG. 4). Although the details will be described later, the information setting device 4 determines the installation position of the lighting device 1 on the map image Mp (see FIG. 6) corresponding to the installation position of the lighting device 1 in the real space, and the lighting device 1. And the device identification information Ia of.

Here, the map image Mp (see FIG. 6) is an image showing the floor plan corresponding to the real space in which the lighting device 1 is installed, the position where the lighting device 1 should be installed, and the like, and is displayed in the information setting device 4. It is read and stored in the storage unit 44. A passage, an entrance, a shelf, etc. may be shown in the map image Mp, and in FIG. 6, a position where the lighting device 1 is to be installed is shown by a circle as the map image Mp, and the entrance e1 is shown. ˜e3 and the path r are illustrated.

Further, in the present embodiment, the communication method of the wireless module 12 is a communication method such as BLE (Bluetooth (registered trademark) Low Energy) capable of power-saving wireless communication. With this communication method, the wireless module 12 can directly perform short-distance wireless communication with one or a plurality of wireless modules 12 installed around the wireless module 12. Therefore, in a lighting control system in which a plurality of lighting devices 1 are installed, it is possible to construct a mesh network in which wireless modules 12 are wirelessly connected in a mesh shape.

Further, by using such a communication method, the wireless module 12 can be further provided with a function as a beacon transmission unit 12B that transmits the beacon signal Sb in one direction. The function as the beacon transmitting unit 12B is realized by the control unit 13 controlling the wireless module 12. By causing the wireless module 12 to function as the beacon transmission unit 12B in this manner, the lighting device 1 is provided with the beacon transmission unit 12B. According to such a lighting device 1, in various places (offices, stores, etc.) where the lighting device 1 is installed in the real space, at the same time as the installation of the lighting device 1, the installation position of the lighting device 1 in the real space. Beacon transmission part 12B is installed in the same position as.

The beacon signal Sb transmitted by the beacon transmission unit 12B includes beacon identification information Ib for identifying the beacon transmission unit 12B. The beacon identification information Ib is used to specify the source (beacon transmitter 12B) of the beacon signal Sb received by the terminal device 3 when specifying the current position P1 of the terminal device 3 in the real space. .. On the other hand, in order to identify the beacon transmission unit 12B based on the beacon signal Sb, after the beacon transmission unit 12B is installed (that is, after the lighting device 1 is installed), the beacon transmission unit 12B is installed in the real space. It is necessary to replace the correspondence relationship between the beacon transmission unit 12B and the beacon identification information Ib with correspondence data that can be managed by the information management device 5.

Therefore, in the present embodiment, the information setting device 4 executes a process of replacing the above-described correspondence relationship regarding the beacon transmission unit 12B with correspondence data (see FIG. 4). Although details will be described later, the information setting device 4 performs a process for associating the installation position of the lighting device 1 with the device identification information Ia on the above-described map image Mp and an operation performed by the setter in the process (see FIG. 4). By using steps S13 to S15 and S22), the installation position of the beacon transmission unit 12B on the map image Mp (see FIG. 6) corresponding to the installation position of the beacon transmission unit 12B in the real space, The beacon identification information Ib of the beacon transmission unit 12B is associated with it. Then, the information setting device 4 records these associations in the information correspondence data D1 (see FIG. 3).

As an example, the beacon identification information Ib includes a UUID (Universally Unique IDentifier) and a major value m1 and a minor value m2. Here, the UUID is an ID uniquely assigned to a specific group (company, organization, store, etc.) to which the beacon transmission unit 12B belongs. Therefore, by including the UUID in the beacon identification information Ib, the specific group to which the UUID is assigned and the beacon transmitting unit 12B identified by the beacon identification information Ib are associated with each other. On the other hand, the major value m1 and the minor value m2 are values used in combination with the UUID, and can be arbitrarily set by the setter (administrator) side. Then, the major value m1 and the minor value m2 are determined such that the beacon identification information Ib becomes unique when the beacon identification information Ib is configured by the combination with the UUID. Note that, if the beacon identification information Ib can be uniquely configured within a specific group, only one of the major value m1 and the minor value m2 may be combined with the UUID, or three or more values may be combined. It may be combined.

On the other hand, in the present embodiment, the beacon identification information Ib remains unset at the stage of shipping the lighting device 1 from the factory or at the stage of installing the lighting device 1 in the real space. Therefore, the information setting device 4 generates the beacon identification information Ib according to the operation of the configurator in the information setting process (see FIG. 4) described later, and uses the generated beacon identification information Ib on the map image Mp. It is associated with the installation position of the beacon transmission unit 12B. Further, the information setting device 4 causes the lighting device 1 to store the beacon identification information Ib in the storage unit 14 by transmitting the generated beacon identification information Ib to the lighting device 1. Thereby, the beacon identification information Ib is set in the beacon transmission unit 12B, and the beacon transmission unit 12B can transmit the beacon signal Sb including the beacon identification information Ib stored in the storage unit 14 at a predetermined time interval. become.

In the lighting device 1, identification information for identifying the wireless module 12 may be used as the device identification information Ia. The lighting device 1 and the network (WAN, LAN, etc.) perform wireless communication between the communication relay (gateway, etc.) connected to the network side and the wireless module 12, so that the communication relay and the wireless module 12 are connected. It may be connected via.

<Lighting control device>
The lighting control device 2 is a cloud server connected to a network (WAN, LAN, etc.), and can communicate with other devices (lighting device 1, information management device 5, etc.) via the network. it can. Then, the illumination control device 2 performs illumination control (control of lighting, extinction, light adjustment, color adjustment, etc.) on the illumination device 1 via the network (illumination control processing). In the present embodiment, the lighting control device 2 executes the lighting control process using the information correspondence data D1 (see FIG. 3) in which the correspondence is recorded by the information setting device 4. As a specific example of the lighting control process, the lighting control device 2 provides the lighting control as a service by executing the lighting control according to the current position P1 of the terminal device 3 in the real space. Details of a specific example of the lighting control process executed by the lighting control device 2 will be described later.

The lighting control process performed by the lighting control device 2 is performed by causing a processing device (such as a CPU or a microcomputer) included in the lighting control device 2 to execute a program. Then, such a program may be stored in a storage medium (for example, a flash memory or the like) in a readable state, or may be stored in a storage unit (not shown) included in the lighting control device 2.

<Terminal device>
The terminal device 3 is a mobile terminal device owned by the user, such as a smartphone. Here, in the lighting control system of the present embodiment, in order to provide the service according to the current position P1 of the terminal device 3 in the real space, the beacon signal Sb used for specifying the current position P1 is set to the terminal device. 3 need to receive. Further, the terminal device 3 needs to transmit the beacon information K including the information of the received beacon signal Sb and the terminal identification information Ic for identifying the terminal device 3 to the information management device 5. Here, the beacon information K transmitted by the terminal device 3 includes the beacon identification information Ib and the reception intensity when the beacon signal Sb is received as the information of the beacon signal Sb. Further, in order to accurately identify the current position P1 of the terminal device 3, the beacon information K includes information on the beacon signal Sb received from three or more beacon transmitting units 12B located around the terminal device 3. Preferably. The information transmitted by the terminal device 3 may further include information on the user who owns the terminal device 3.

Therefore, the terminal device 3 is installed with an application program for realizing a function as a transceiver that receives the beacon signal Sb and transmits the beacon information K including the information of the received beacon signal Sb. The application program may be stored in a storage medium (for example, a flash memory) or a cloud server in a readable state before being installed in the terminal device 3, and the terminal device 3 may read it. Further, the terminal device 3 may function as a transceiver that receives only the beacon signal Sb including the UUID designated by the user.

<Information setting device>
The information setting device 4 is, for example, a mobile terminal device such as a smartphone or a tablet PC, and is used for associating various kinds of information (positional information, identification information, etc.) at the installation place after the lighting device 1 is installed in the real space. Used. Specifically, the application program for executing the information setting process described above is installed in a mobile terminal device such as a smartphone or a tablet PC. When the application program is executed by the mobile terminal device, the mobile terminal device functions as the information setting device 4.

FIG. 2B is a conceptual diagram showing the information setting device 4. The information setting device 4 includes a touch panel 41, a communication unit 42, a control unit 43, and a storage unit 44. Here, the touch panel 41 has a function as a display unit in the information setting device 4 and a function as an input unit in the information setting device 4. The information setting device 4 may be, for example, a desktop PC or the like in which the display unit (monitor or the like) and the input unit (keyboard or the like) are separately configured.

The communication unit 42 wirelessly connects the information setting device 4 and a network (WAN, LAN, etc.) to enable bidirectional wireless communication with other devices (the lighting control device 2, the information management device 5, etc.). enable. Further, the communication unit 42 can directly perform wireless communication with the wireless module 12 by the same communication method as the transmission of the beacon signal Sb. In the present embodiment, the information setting device 4 performs direct wireless communication with the wireless module 12 via the communication unit 42 during execution of the information setting process.

In the information setting process, the information setting device 4 determines the installation position of the lighting device 1 on the map image Mp (see FIG. 6) corresponding to the installation position of the lighting device 1 in the real space, and the device of the lighting device 1. The identification information Ia is associated with.

Although the details of the information setting process (see FIG. 4) will be described later, the information setting device 4 further processes a process for associating the installation position of the lighting device 1 with the device identification information Ia on the map image Mp, and the process thereof. By using the operation performed by the configurator (see steps S13 to S15 and S22 in FIG. 4), the beacon identification information Ib of the beacon transmitting unit 12B is generated at a preferable timing, and the generated beacon identification information Ib is stored in the real space. It is made to correspond to the installation position of the beacon transmission unit 12B on the map image Mp (see FIG. 6) corresponding to the installation position of the beacon transmission unit 12B. Then, the information setting device 4 records these associations in the information correspondence data D1 (see FIG. 3). Further, the information setting device 4 transmits the information correspondence data D1 to the information management device 5 after the association is completed.

Here, the information correspondence data D1 includes the installation positions of the lighting device 1 and the beacon transmission unit 12B (positions of icons J described later in this embodiment) on the map image Mp, device identification information Ia, and beacon identification information Ib. The data (file or the like) in which the correspondence relationship with is recorded is stored in the storage unit 44. FIG. 4 is a diagram showing an example of the information correspondence data D1.

The information setting process executed by the information setting device 4 is executed by causing a control unit 43 (a processing device such as a CPU (Central Processing Unit) or a microcomputer) included in the information setting device 4 to execute a program. Then, such a program may be stored in a storage medium (for example, a flash memory or the like) in a readable state, or may be stored in the storage unit 44 of the information setting device 4.

<Information management device>
The information management device 5 is a cloud server connected to a network (WAN, LAN, etc.), and communicates with other devices (lighting control device 2, information setting device 4, etc.) via the network. You can Then, the information management device 5 adds and manages the information correspondence data D1 (see FIG. 3) in which the correspondence is recorded by the information setting device 4 to the database. Further, in the present embodiment, the information management device 5 uses the information in the database to determine the terminal device in the real space from the beacon information K (the information of the beacon signal Sb and the terminal identification information Ic) transmitted from the terminal device 3. The current position P1 of 3 is specified (position specifying process). Further, in this position specifying process, the information management device 5 transmits the specified current position P1 of the terminal device 3 to another device (such as the lighting control device 2) via the network. The details of the position specifying process executed by the information management device 5 will be described later.

The position specifying process executed by the information management device 5 is executed by causing a processing device (such as a CPU or a microcomputer) included in the information management device 5 to execute a program. Then, such a program may be stored in a storage medium (for example, a flash memory or the like) in a readable state, or may be stored in a storage unit (not shown) included in the information management device 5.

[2] Control in lighting control system [2-1] Control executed after installation of lighting device in real space <Information setting process executed by information setting device>
FIG. 4 is a flowchart showing the information setting process executed by the information setting device 4 and the operation performed by the setter. 5 to 8 are diagrams showing screens displayed on the touch panel 41 in relation to the information setting process.

When the information setting process is started by executing the application program in the information setting device 4, the control unit 43 displays the UUID input screen on the touch panel 41 (step S11 in FIG. 4, see FIG. 5). The UUID input on the input screen is used to generate the beacon identification information Ib, and this input screen is used to determine which group the beacon identification information Ib of the beacon transmitter 12B belongs to. , A screen requesting the configurator to input a UUID uniquely assigned to a group.

After executing step S11 (after displaying the input screen), the control unit 43 determines whether or not the UUID is input on the input screen (step S12 in FIG. 4). Then, the control unit 43 repeatedly executes step S12 until it can be determined that "input (Yes)" is made in step S12.

When the setter inputs the UUID on the input screen (step S21 of FIG. 4) and determines that the input is “input (Yes)” in step S12, the control unit 43 outputs the illumination device 1 in the real space. Processing for associating the installation position of the lighting device 1 on the map image Mp (see FIG. 6) corresponding to the installation position with the device identification information Ia of the lighting device 1 (step S13 in FIG. 4). ~S15).

First, in step S13, the control unit 43 reads the map image Mp stored in the storage unit 44 from the storage unit 44 and displays it on the touch panel 41 (see FIG. 6). At this time, the control unit 43 displays the map image Mp in association with the coordinate data defining the position on the map image Mp.

Further, in step S14, the control unit 43 acquires the device identification information Ia from the lighting device 1 already installed in the real space. Then, the control unit 43 displays the icon J associated with the acquired device identification information Ia on the touch panel 41 (see FIG. 6). At this time, the control unit 43 displays the icon J in a state where it can be moved onto the map image Mp by a drag operation. Moreover, the control unit 43 causes the icon J to function as a switch for turning on the lighting device 1 identified by the device identification information Ia associated with the icon J. The switch may be one that turns on the illumination device 1 at least once, such as a switch that can be turned off after the illumination device 1 is turned on. The switch may be displayed on the screen of the touch panel 41 as an icon different from the icon J in a state of being associated with the icon J.

In the present embodiment, the control unit 43 displays the icons J as a list on the screen of the touch panel 41 (see FIG. 6). Further, the control unit 43 further displays an end button for the configurator to end the information setting process on the screen of the touch panel 41.

After execution of step S14 by the control unit 43 (after displaying the screen of FIG. 6), the setter arranges the icon J on the map image Mp by a drag operation (step S22 of FIG. 4, see FIG. 7). Further, the control unit 43 determines whether or not the icon J is arranged on the map image Mp (step S15 in FIG. 4).

Specifically, the setter first identifies the device identification information Ia associated with the icon J by pressing the icon J to be arranged on the map image Mp (that is, operating the switch). The lighting device 1 is turned on. Thereby, the setter confirms the installation position in the real space of the lighting device 1 corresponding to the icon J to be arranged. At the same time, the setter can also confirm the installation position of the beacon transmission unit 12B provided in the illuminated lighting device 1. That is, the setter can confirm the installation position in the real space of the beacon transmission unit 12B that is the target of setting the beacon identification information Ib by turning on the lighting device 1. After that, the setter moves the icon J to the installation position on the map image Mp corresponding to the installation position by dragging based on the confirmed installation position of the lighting device 1 and the beacon transmission unit 12B in the real space. Let me place it.

By arranging the icon J on such a map image Mp (in the example of FIG. 7, the position (circle mark) where the lighting device 1 shown in the map image Mp is to be installed) is set, the setting person is in the real space. The installation position of the lighting device 1 on the map image Mp corresponding to the installation position of the lighting device 1 can be specified. Moreover, by setting the icon J, the setter also specifies the installation position of the beacon transmission unit 12B on the map image Mp corresponding to the installation position of the beacon transmission unit 12B in the real space, which is confirmed by turning on the lighting device 1. it can.

Further, the device identification information Ia is associated with the icon J. Therefore, when the icon J is placed on the map image Mp by the drag operation (step S22 in FIG. 4), the control unit 43 can determine “placed (Yes)” in step S15, The installation position (position coordinates based on the coordinate data) of the lighting device 1 on the map image Mp designated by the arrangement of the icon J and the device identification information Ia associated with the icon J have a correspondence relationship. It will be. That is, by arranging the icon J on the map image Mp, the correspondence relationship between the installation position of the lighting device 1 in the real space and the device identification information Ia of the lighting device 1 indicates the correspondence of the lighting device 1 on the map image Mp. It is replaced with the correspondence between the installation position (the position of the icon J on the map image Mp in the present embodiment. The position coordinate based on the coordinate data) and the device identification information Ia.

As described above, according to the processes of steps S13 to S15 and the operation of step S22 in FIG. 4, not only is it possible to associate the installation position of the lighting device 1 on the map image Mp with the device identification information Ia, By illuminating the lighting device 1 performed at that time, it is possible to confirm the installation position in the real space of the beacon transmitting unit 12B to which the beacon identification information Ib is set. Therefore, the present embodiment further generates the beacon identification information Ib of the beacon transmission unit 12B at a preferable timing by utilizing the merit obtained by turning on the lighting device 1, and the generated beacon identification information Ib in the real space. It is associated with the installation position of the beacon transmission unit 12B on the map image Mp (see FIG. 6) corresponding to the installation position of the beacon transmission unit 12B. The details will be described below.

When the control unit 43 determines that the icon J is placed on the map image Mp by the drag operation (step S22 in FIG. 4) and can be determined to be “placed (Yes)” in step S15, the timing thereof. Then, the beacon identification information Ib is generated (step S16 in FIG. 4). That is, the control unit 43 generates the beacon identification information Ib when the installation position of the beacon transmission unit 12B on the map image Mp is designated by the arrangement of the icon J.

More specifically, the control unit 43 determines the major value m1 and the minor value m2. At this time, when the control unit 43 configures the beacon identification information Ib by combining the UUID input on the input screen with the major value m1 and the minor value m2, the control unit 43 determines that the beacon identification information Ib is unique. The value m1 and the minor value m2 are determined. Then, the control unit 43 generates the beacon identification information Ib by combining the determined major value m1 and the determined minor value m2 with the UUID input on the input screen.

After execution of step S16 (after generation of the beacon identification information Ib), the control unit 43 is associated with the arrangement position (position coordinate based on the coordinate data) of the icon J on the map image Mp, with the icon J. The device identification information Ia and the beacon identification information Ib generated in step S16 are associated and recorded in the information correspondence data D1 (step S17 in FIG. 4, see FIG. 3). In the present embodiment, the arrangement position of the icon J on the map image Mp is the installation position of the lighting device 1 and the beacon transmission unit 12B on the map image Mp specified by the arrangement of the icon J, as described above. Equivalent to. Further, the control unit 43 further associates the information of the map image Mp with the arrangement position of the icon J so that it can specify which map image Mp the arrangement position (position coordinate) of the icon J corresponds to. And records it in the information corresponding data D1 (see FIG. 3).

After execution of step S17 (after execution of association), the control unit 43 determines whether or not the end button has been pressed (step S18 in FIG. 4). In addition, the control unit 43 also executes step S18 when it is determined in step S15 that “not arranged (No)”. Then, when the control unit 43 determines in step S18 that the button has not been pressed (No), the processing from step S15 is executed again. As a result, the setting person repeatedly arranges the icon J displayed on the screen of the touch panel 41 on the map image Mp, so that the arrangement position of the icon J on the map image Mp (illumination device 1 and beacon transmission). Information in which the installation position of the section 12B), the device identification information Ia, and the beacon identification information Ib are associated with each other is accumulated in the information correspondence data D1.

Then, when the control unit 43 determines that the button has been pressed (Yes) in step S18 by pressing the setting button, the control unit 43 uses the information correspondence data D1 in which the correspondences up to that time are recorded, The beacon identification information Ib is set for the beacon transmission unit 12B (step S19A in FIG. 4). Further, the control unit 43 transmits the information correspondence data D1 to the lighting control device 2 and the information management device 5 (step S19B in FIG. 4), and then ends the information setting process.

Specifically, in step S19A, the control unit 43 wirelessly communicates the beacon identification information Ib corresponding to the device identification information Ia to the lighting device 1 identified by the device identification information Ia recorded in the information correspondence data D1. Send. Then, when the lighting device 1 receives the beacon identification information Ib from the information setting device 4, the lighting device 1 stores the received beacon identification information Ib in the storage unit 14. As a result, the beacon identification information Ib is set in the beacon transmitter 12B. As a result, the beacon transmission unit 12B can transmit the beacon signal Sb including the beacon identification information Ib stored in the storage unit 14 at a predetermined time interval.

According to the above-described information setting process, the setting person can easily confirm the installation position of the lighting device 1 in the real space by operating the switch and arrange the icon J on the map image Mp based on the confirmation. The installation position of the lighting device 1 on the map image Mp and the device identification information Ia can be associated with each other. Therefore, according to the information setting process, association between the installation position of the lighting device 1 on the map image Mp corresponding to the real space and the device identification information Ia is simplified.

Moreover, according to the above-described information setting process, the setting person confirms the installation position of the lighting device 1 in the real space by turning on the lighting device 1 by operating the switch, and at the same time installs the beacon transmission unit 12B in the real space. You can check the position. As a result, the setter can specify the installation position of the beacon transmission unit 12B on the map image Mp based on the confirmed installation position of the beacon transmission unit 12B in the real space. In the present embodiment, the placement position of the beacon transmission unit 12B on the map image Mp is designated by the placement of the icon J on the map image Mp by the drag operation.

Further, the beacon identification information Ib is generated along with the designation of the installation position of the beacon transmission unit 12B on the map image Mp (arrangement of the icon J in the present embodiment) by the setter, and the beacon identification information Ib is generated. Is associated with the installation position of the beacon transmission unit 12B designated on the map image Mp. Therefore, the configurator performs simple operations such as confirming the installation position of the beacon transmission unit 12B in the real space by operating the switch and designating the installation position of the beacon transmission unit 12B on the map image Mp based on the confirmation. The installation position of the beacon transmission unit 12B on the map image Mp can be associated with the beacon identification information Ib. Therefore, according to the above information setting process, the association between the installation position of the beacon transmission unit 12B on the map image Mp corresponding to the real space and the beacon identification information Ib is simplified.

Further, the setting of the beacon identification information Ib for the beacon transmission unit 12B (step S19A of FIG. 4) is executed based on the above-mentioned association, whereby the installation position of the beacon transmission unit 12B and the beacon identification information Ib in the real space are set. A correspondence is formed between and. Then, according to the information setting process, the correspondence relationship is replaced with the correspondence relationship (information correspondence data D1) between the installation position of the beacon transmission unit 12B on the map image Mp and the beacon identification information Ib. Therefore, the information correspondence data D1 can be used as a database for identifying the current position P1 of the terminal device 3 in the real space.

Note that the information setting process is executed only for the purpose of associating the position of the beacon transmission unit 12B with the beacon identification information Ib, without assuming the association between the position of the lighting device 1 and the device identification information Ia. Good. That is, the lighting of the lighting device 1 by operating the switch may be used only for confirming the position of the beacon transmitting unit 12B. Further, the icon J may be used only for designating the position of the beacon transmitting unit 12B.

Further, in the above information setting process, the installation position of the beacon transmission unit 12B on the map image Mp is not limited to be specified by the arrangement of the icon J, but may be specified by a numerical input, or other means may be used. May be specified.

The determination method of the major value m1 and the minor value m2 executed by the control unit 43 at the time of generating the beacon identification information Ib in step S16 is a method of randomly determining, or a major value m1 or a minor value m2 of 1 for each determination. You can list things that go up one by one. However, as the method of determining the major value m1 and the minor value m2, various methods that are not limited to these can be used. In addition, when the map image Mp has information about the number of floors, divisions, etc. of the floor corresponding to the image, the control unit 43, based on that information, the control unit 43 measures the major value every time the icon J is arranged. The m1 and the minor value m2 may be determined.

Further, the control unit 43 is not limited to the case of generating a part of the beacon identification information Ib (in the present embodiment, the major value m1 and the minor value m2) and combining this with the UUID to create the beacon identification information Ib. The entire beacon identification information Ib may be generated including the UUID. In this case, in the above-described information setting process, it is not necessary to display the input screen in step S11 and input the UUID by the setter in step S21.

When generating the beacon identification information Ib in step 16, the control unit 43 may popup-display a confirmation image in which the content of the generated beacon identification information Ib is described on the touch panel 41 (see FIG. 8 ). Thereby, the setter can recognize that the beacon identification information Ib has been generated and its content. The confirmation image may be closed by the setting person pressing the confirmation button (see FIG. 8) displayed on the image, or may be closed after a lapse of a predetermined time without the setting person's operation. .. Further, the control unit 43 may notify the setting person of the generation of the beacon identification information Ib by emitting a sound or the like instead of displaying the confirmation image.

Further, the timing of generating the beacon identification information Ib is not limited to the timing at which the installation position of the beacon transmission unit 12B is specified on the map image Mp by the arrangement of the icon J, but the timing before the installation position is specified (for example, Other preferable timing, such as the timing when the setter selects the icon J to be the target of the drag operation), may be used.

Further, the transmission of the beacon identification information Ib to the lighting device 1 executed by the control unit 43 in step S19A is performed by the lighting control device 2 or the information management device 5 that has received the information correspondence data D1 based on the information correspondence data D1. You can go.

[2-2] Control executed when service is provided <Location specifying process executed by information management device>
When the transmission of the beacon signal Sb from the beacon transmission unit 12B is started after the setting of the beacon identification information Ib (step S19A in FIG. 4) for the beacon transmission unit 12B is completed, the information management device 5 causes the terminal device 3 or The position specifying process is executed to provide a service (in this embodiment, the lighting control by the lighting control device 2) to the user who owns the device. In the position specifying process, the information management device 5 adds the information corresponding data D1 received from the information setting device 4 to the database and manages it, while using the information in the database, the beacon transmitted from the terminal device 3 The current position P1 of the terminal device 3 in the real space is specified from the information K (information of the beacon signal Sb and terminal identification information Ic). Here, in the beacon information K, in order to accurately specify the current position P1 of the terminal device 3, a beacon signal Sb received from three or more beacon transmitting units 12B located around the terminal device 3 in the real space. It is preferable that the information of is included. Hereinafter, a case where the beacon information K includes information on three or more beacon signals Sb will be described.

FIG. 9 is a flowchart showing the position specifying process executed by the information management device 5. Note that FIG. 9 shows the flow of processing from the reception of the beacon information K from the terminal device 3 to the identification of the current position P1 of the terminal device 3.

When the information management device 5 receives the beacon information K from the terminal device 3, the information management device 5 uses the information of the managed database (specifically, the content of the information corresponding data D1 added to the database (see FIG. 3)). Thereby, based on the three or more beacon identification information Ib in the beacon information K received from the terminal device 3, the installation position on each map image Mp of the beacon transmission unit 12B identified by the beacon identification information Ib is determined. It is acquired (step S31 in FIG. 9). Then, the information management device 5 determines, based on the reception intensity in the beacon information K corresponding to the beacon identification information Ib, from the respective installation positions (three or more positions) of the beacon transmission unit 12B acquired in step S31 from the terminal device. The distances up to 3 on the map image Mp are acquired (step S32 in FIG. 9). At this time, the information management device 5 may acquire the distance on the map image Mp using correspondence data in which the reception intensity and the distance are associated with each other, or may be calculated from the relational expression between the reception intensity and the distance. Therefore, the distance on the map image Mp may be acquired.

After that, the information management device 5 determines the current position of the terminal device 3 in the real space based on the installation position of the beacon transmission unit 12B on the map image Mp acquired in steps S31 and S32 and the distance from the beacon transmission unit 12B. The current position P1m of the terminal device 3 in the map image Mp information corresponding to the position P1 is specified (step S33 in FIG. 9).

After performing step S33 (after specifying the current position P1m of the terminal device 3), the information management device 5 sends the specified current position P1m of the terminal device 3 to the lighting control device 2 together with the terminal identification information Ic of the terminal device 3. It is transmitted (step S34 in FIG. 9).

<Lighting control processing executed by the lighting control device>
The lighting control device 2 is a cloud server and performs lighting control on the lighting device 1 using the information correspondence data D1 in which the correspondence in the information setting device 4 is recorded. Then, as a specific example of the lighting control process, the lighting control device 2 determines the current position P1 of the terminal device 3 in the real space (specifically, the terminal device 3 of the terminal device 3 on the map image Mp specified by the information management device 5). Illumination control according to the current position P1m) is performed. Hereinafter, a specific example of the illumination control process will be described.

(1) Example of Illumination Control Processing for Brightly Illuminating Current Location of Terminal Device and Surroundings FIG. 10 is a flowchart showing an example of illumination control processing executed by the illumination control apparatus 2. In the example of FIG. 10, the lighting control device 2 increases the dimming rate of the lighting device 1 installed around the current position P1 according to the current position P1 of the terminal device 3 in the real space, Lighting control is performed to brightly illuminate the current position P1 of the terminal device 3 and its surroundings.

When the lighting control device 2 starts the lighting control process by receiving the information correspondence data D1 from the information setting device 4, first, the lighting control device 2 uses the received information correspondence data D1 to perform the control correspondence used for the lighting control on the lighting device 1. The data D2 is created (step S41 in FIG. 10). Here, the control correspondence data D2 is the information correspondence data D1 in which the device identification information Ia of the lighting device 1 is further associated with the details of illumination control (hereinafter, referred to as “illumination mode”). FIG. 11A is a diagram showing an example of the control correspondence data D2.

Specifically, the illumination mode includes a first mode (mode(1)) for controlling the dimming rate to 10% and a second mode (mode(2)) for controlling the dimming rate to 100%. It is prepared in advance. More specifically, the illumination mode data D3 in which the correspondence between these illumination modes and dimming ratios is recorded is stored in, for example, a storage unit (not shown) included in the illumination control device 2. FIG. 11B is a diagram showing an example of the illumination mode data D3.

Then, in step S41, the illumination control device 2 creates the control correspondence data D2 by associating the first mode (mode(1)) with all the device identification information Ia in the information correspondence data D1. After that, the lighting control device 2 stores the created control correspondence data D2 in, for example, a storage unit (not shown) included in the lighting control device 2.

After execution of step S41, the illumination control device 2 executes illumination control for the illumination device 1 based on the control correspondence data D2 and the illumination mode data D3 (step S42 of FIG. 10). Specifically, according to the illumination mode illustrated in FIG. 11B, the illumination control device 2 controls the dimming rate of all the illumination devices 1 to 10%.

After execution of step S42, the illumination control device 2 performs information for performing illumination control according to the current position P1 of the terminal device 3 in the real space (specifically, the current state of the terminal device 3 on the map image Mp. It is determined whether or not the position P1m and the terminal identification information Ic of the terminal device 3 thereof have been received from the information management device 5 (step S43 in FIG. 10). Then, when the illumination control device 2 determines “received (Yes)” in step S43, the received information and the reception time T1 at which the information is received are associated with each other and recorded in the reception time data D4. (Step S44 of FIG. 10). Here, the reception time data D4 is data (file or the like) in which the correspondence relationship between the information received from the information management device 5 (the current position P1m of the terminal device 3 and the terminal identification information Ic) and the reception time T1 is recorded. For example, it is stored in a storage unit (not shown) of the lighting control device 2. FIG. 11C is a diagram showing an example of the reception time data D4.

In the reception time data D4, the current position P1m of the terminal device 3 sequentially transmitted from the information management device 5 (for example, the current position on the map image Mp of the terminal device 3 moving in the real space such as an office or a store). ) Is added together with the reception time T1. Therefore, the information (the current position P1m of the terminal device 3 and the terminal identification information Ic) received earlier becomes old as time passes.

Therefore, the lighting control device 2 has passed the predetermined time T0 from the reception time T1 among the information (terminal identification information Ic, the current position P1m of the terminal device 3, and the reception time T1) recorded in the reception time data D4. By deleting the items from the reception time data D4, the information in the reception time data D4 is organized (step S45 in FIG. 10).

In addition, when the illumination control device 2 determines “not received (No)” in step S43, the lighting control device 2 refers to the reception time data D4 and determines whether or not information is recorded in the reception time data D4. It is determined (step S46 in FIG. 10). Then, the illumination control device 2 also executes step S45 when it determines in step S46 that “there is a recording (Yes)”. On the other hand, when the illumination control device 2 determines in step S46 that “no recording (No)”, the process proceeds to step S50.

After the execution of step S45, the lighting control device 2 identifies the lighting device 1 used for brightly illuminating the periphery of the terminal device 3 by using the current position P1m of the terminal device 3 recorded in the reception time data D4. (Step S47 of FIG. 10). Specifically, the illumination control device 2 illuminates the current position P1m of the terminal device 3 on the map image Mp and the map image Mp recorded in the control correspondence data D2 (see FIG. 11A). Using the installation position of the device 1, the lighting device 1 existing within the predetermined region Rt centered on the current position P1m is specified. Here, the predetermined region Rt is a region set in advance to determine a selection range on the map image Mp of the illumination device 1 that brightly illuminates the periphery of the terminal device 3.

FIG. 12 is a conceptual diagram visually showing the lighting device 1 existing in a predetermined region Rt centered on the current position P1m of the terminal device 3 on the map image Mp, and in FIG. 12, as the predetermined region Rt. A rectangular area centered on the current position P1m of the terminal device 3 is used. When a plurality of current positions P1m of the terminal devices 3 are recorded in the reception time data D4, the lighting control device 2 sets the current positions P1m of all the terminal devices 3 within a predetermined area Rt centered on each of them. The illuminating device 1 existing in 1 is specified.

Next, the illumination control device 2 changes the setting of the illumination mode associated with the illumination device 1 identified in step S47 in the control correspondence data D2 (step S48 in FIG. 10). Specifically, the illumination control device 2 sets the illumination mode for the illumination device 1 specified in step S47 in the control correspondence data D2 to the second mode (mode(2)=light control rate 100%), and The setting of the illumination mode is changed so that the illumination mode for the illumination devices 1 other than the illumination device 1 specified in step S47 becomes the first mode (mode(1)=light control rate 10%).

After execution of step S48, the illumination control device 2 executes illumination control for the illumination device 1 based on the control correspondence data D2 and the illumination mode data D3 (step S49 in FIG. 10). Specifically, according to the illumination mode illustrated in FIG. 11B, the illumination control device 2 sets the dimming rate of the illumination device 1 in which the illumination mode is set to the second mode (mode(2)) to 100. %, and the dimming rate of the lighting device 1 whose lighting mode is set to the first mode (mode (1)) is controlled to 10%.

Then, for example, until the switch provided in the office or the store is turned off by the user and the lighting control process does not need to be continued (step S50 in FIG. 10), the lighting control device 2 performs steps S43 to S49. Repeat the process.

According to the above lighting control processing, even if the user does not adjust the lighting, the current position of the user who owns the terminal device 3 in the real space (office, store, etc.) (that is, the current position of the terminal device 3 in the real space). The position P1) and its surroundings are brightly illuminated by the lighting device 1. Further, in step S45, the old information after a predetermined time T0 has elapsed from the reception time T1 is deleted from the reception time data D4, so that the illumination according to the current position of the user that changes due to the movement of the user in the real space. The device 1 can follow the brightly illuminated range. As described above, according to the lighting control, the lighting is adjusted according to the current position of the user who owns the terminal device 3 in the real space, so that the convenience for the user is enhanced.

In the above-described lighting control processing, the lighting mode used for the lighting control is not limited to the light control shown in FIG. 11B, and various controls regarding lighting (lighting, turning off, light control, color adjustment, Any one of these) or a combination thereof can be used. Further, as the illumination mode associated with the control correspondence data D2, three or more modes with different control contents may be prepared.

Further, the shape of the predetermined region Rt used for identifying the lighting device 1 in step S47 is not limited to a rectangle, but can be appropriately changed to a shape (circular shape or the like) according to the installation form of the lighting device 1. Further, the predetermined region Rt is not limited to one having the current position P1m of the terminal device 3 on the map image Mp as the center, and may include the current position P1m of the terminal device 3 at a position other than the center. ..

(2) Example of Illumination Control Process for Brightly Illuminating Path from Entrance to Target Position when Entering Room FIG. 13 is a flowchart showing another example of the illumination control process executed by the illumination control device 2. In the example of FIG. 13, when the user enters the room, the lighting control device 2 moves from the entrance Es used when entering the room to the position to which the user moves (for example, the position of the desk of the user. The terminal device 3 in the real space described later). The lighting control for illuminating the path brightly is performed by increasing the dimming ratio of the lighting device 1 installed on the path up to the target position P2 which is the destination of the movement.

In this example, the lighting control device 2 executes the processing up to step S43 as in the lighting control processing (see FIG. 10) described above. Then, when the illumination control device 2 determines “received (Yes)” in step S43, the reception time data D4 is used to determine whether the user has entered the room for the first time or has already entered the room at that time. By referring to, it is determined whether or not there is a record of the same information as the terminal identification information Ic received from the information management device 5 in the reception time data D4 (step S51 in FIG. 13).

Here, in the reception time data D4, as in the example of FIG. 10, the correspondence relationship between the received information (the current position P1m of the terminal device 3 and the terminal identification information Ic) and the reception time T1 at which the information is received is recorded. Data (file, etc.) (see FIG. 11C). When the user enters the room for the first time when the information is received from the information management device 5, the same information as the terminal identification information Ic included in the received information is not recorded in the reception time data D4. On the other hand, if the user has already entered the room when the information is received from the information management device 5, the same information as the terminal identification information Ic included in the received information is recorded in the reception time data D4. .. Therefore, by determining whether or not the same information as the terminal identification information Ic received from the information management device 5 is recorded in step S51, it is possible to determine whether or not the user first entered the room at that time.

When it is determined that there is no recording (No) in step S51, the illumination control device 2 records the received information in the reception time data D4 in association with the reception time T1 at which the information was received ( Step S52 in FIG. 13).

After that, the lighting control device 2 uses the current position P1m of the terminal device 3 on the received map image Mp to identify the entrance Es used by the user who owns the terminal device 3 when entering the room (FIG. 13). Step S53). As a specific example, the illumination control device 2 has information (position coordinates and the like) regarding the positions of the available entrances e1 to e3 on the map image Mp. Then, the illumination control device 2 is used by the user to enter the entrance that has the shortest distance on the map image Mp from the current position P1m of the terminal device 3 on the map image Mp among the entrances e1 to e3. It is specified as the entrance Es.

Then, the lighting control device 2 records the received terminal identification information Ic, the specified entrance Es, and the specified time T2 specifying the entrance Es in association with each other in the specified time data D5 (step S54 in FIG. 13). ). Here, the specific time data D5 is data (file or the like) in which the correspondence between the terminal identification information Ic, the specified entrance Es, and the specific time T2 is recorded, and is, for example, a storage unit (not shown) of the lighting control device 2. ) Is stored in. FIG. 15A is a diagram showing an example of the specific time data D5.

The specific time T2 corresponds to the time when the user enters the room. In the example of FIG. 13, when the user enters the room, it is sufficient if the user can move to the position by brightly illuminating the path to the destination position, so that the path remains brightly illuminated for a long time after entering the room. No need. Therefore, it is preferable to return the illumination to the original state when the predetermined time Ts0 has elapsed after the user entered the room. Therefore, in step S54, the specific time T2 corresponding to the time when the user enters the room is recorded in the specific time data D5, so that in a process described later (see FIG. 14), the illumination is based on the illumination after the predetermined time Ts0 has elapsed. It will be possible to return.

After the execution of step S54, the illumination control device 2 uses the terminal identification information Ic recorded in the specific time data D5 and the information on the identified entrance Es to change the setting of the illumination mode in the control correspondence data D2 ( Step S55 of FIG. 13).

Specifically, the illumination control device 2 first refers to the setting change target data D6. Here, in the setting change target data D6, the entrances e1 to e3 that can be used to enter the room are associated with each terminal identification information Ic, and the setting of the illumination mode is further changed for each of the available entrances e1 to e3. The data (file or the like) is associated with the device identification information Ia of the target lighting device 1, and is stored in, for example, a storage unit (not shown) of the lighting control device 2. FIG. 15B is a diagram showing an example of the setting change target data D6. Further, FIG. 16 is a conceptual diagram visually showing the device identification information Ia (target of the setting change of the illumination mode) associated with the setting change target data D6.

As an example, as shown in FIG. 16, the lighting device 1 which is the target of the setting change of the lighting mode is from the position of the entrances e1 to e3 on the map image Mp to the movement destination of the terminal device 3 in the real space. Routes r1 to r3 on the map image Mp up to the target position P2m on the map image Mp corresponding to a certain target position P2 (for example, the position of the desk of the user who owns the terminal device 3) (paths passing through the passage r) ) Is the lighting device 1 installed above (see also FIG. 15B). The device identification information Ia of the lighting device 1 associated with each of the available entrances e1 to e3 in the setting change target data D6 may be one or more.

Then, the illumination control device 2 acquires the device identification information Ia corresponding to the combination of the terminal identification information Ic recorded in the specific time data D5 and the specified entrance Es from the referred setting change target data D6. As a result, the lighting control device 2 acquires the device identification information Ia of the lighting device 1 that is the target of the setting change of the lighting mode.

After that, the illumination control device 2 sets the acquired device identification so that the illumination mode for the acquired device identification information Ia is the second mode (mode(2) = dimming rate 100%) in the control correspondence data D2. The setting of the illumination mode is changed so that the illumination mode for the device identification information Ia other than the information Ia becomes the first mode (mode(1)=light control rate 10%).

After execution of step S55, the illumination control device 2 executes illumination control for the illumination device 1 based on the control correspondence data D2 and the illumination mode data D3 (step S56 of FIG. 13). Specifically, according to the illumination mode illustrated in FIG. 11B, the illumination control device 2 sets the dimming rate of the illumination device 1 in which the illumination mode is set to the second mode (mode(2)) to 100. %, and the dimming rate of the lighting device 1 whose lighting mode is set to the first mode (mode (1)) is controlled to 10%.

Thus, when a user enters the room, the lighting device 1 installed on the route from the entrance Es used when entering the room to the target position P2 (for example, the position of the user's desk) is adjusted brightly for each user. To be done. As a result, the route from the entrance Es to the target position P2 is illuminated brightly, so that the user can recognize the position of the destination to which he/she is moving (corresponding to the target position P2) and easily move to that position. As described above, according to the lighting control, the lighting is adjusted according to the entrance Es used when entering the room and the target position P2, and thus convenience for the user is enhanced.

Further, in the example of FIG. 13, when the illumination control device 2 determines “not received (No)” in step S43, it refers to the reception time data D4 and records information in the reception time data D4. It is determined whether or not there is (step S57 in FIG. 13). Then, when it is determined in step S57 that “there is a recording (Yes)”, the illumination control device 2 moves to step S58. On the other hand, when the illumination control device 2 determines in step S57 that “no recording (No)”, the process proceeds to step S70.

In step S58, the illumination control device 2 has information (terminal identification information Ic, current position P1m of the terminal device 3, and reception time T1) recorded in the reception time data D4, as in the example of FIG. 10 (step S45). Among the above, the information in the reception time data D4 is organized by deleting the data after the predetermined time T0 has elapsed from the reception time T1 from the reception time data D4. In addition, the illumination control device 2 also executes step S58 when it is determined in step S51 that “there is a recording (Yes)”. After execution of step S58, the lighting control device 2 moves to step S70.

Then, for example, until the lighting control process is not required to be continued because the switch provided in the office or the store is turned off by the user (step S70 in FIG. 13), the lighting control device 2 performs steps S43 and S51. The process of S58 is repeatedly executed. Then, in the process of repeating these processes, the illumination control device 2 also performs a process (the process shown in the flowchart of FIG. 14) for returning the illumination that brightly illuminates the path to the original state after the elapse of the predetermined time Ts0. Execute. It should be noted that this process is executed between A and B in the flowchart of FIG. 13, for example. Specifically, it is as follows.

The illumination control device 2 first refers to the specific time data D5 and determines whether or not there is information recorded in the specific time data D5 (step S61 in FIG. 14). Then, when it is determined in step S61 that “there is recording (Yes)”, the illumination control device 2 determines whether or not the predetermined time Ts0 has elapsed from the specific time T2 recorded in the specific time data D5. (Step S62 of FIG. 14).

When the illumination control device 2 determines in step S62 that “the time has elapsed (Yes)”, the information (terminal identification information Ic, the specified entrance Es, and the specific time T2) recorded in the specific time data D5 is displayed. Among the above), the information in the specific time data D5 is organized by deleting the data after the predetermined time Ts0 has elapsed from the specific time T2 from the specific time data D5 (step S63 in FIG. 14).

After that, the illumination control device 2 uses the specific time data D5 organized in step S63 to change the setting of the illumination mode in the control corresponding data D2 (step S64 in FIG. 14). Specifically, when other information (terminal identification information Ic and entrance Es) remains in the specific time data D5, the lighting control device 2 uses the information remaining in the specific time data D5 to perform the step. The setting is changed in the same manner as S55. On the other hand, when other information (terminal identification information Ic and entrance Es) does not remain in the specific time data D5, the illumination control device 2 sets the illumination mode for all the device identification information Ia in the control correspondence data D2 to the first illumination mode. The setting of the illumination mode is changed so that the mode (mode(1)=10%) is obtained.

After execution of step S64, the illumination control device 2 executes illumination control for the illumination device 1 based on the control correspondence data D2 and the illumination mode data D3 (step S65 of FIG. 14). As a result, the control for brightly illuminating the path from the entrance Es to the target position P2, which is executed when the user enters the room, is terminated when the predetermined time Ts0 has elapsed. On the other hand, when the illumination control device 2 determines in step S61 that “no recording (No)” or in step S62 that “not elapsed (No)”, steps S63 to S65. The process returns to step S43 without executing.

In addition, in the process of identifying the target of the setting change of the illumination mode in step S55, if the map image Mp includes the position information such as the passage r, the illumination control device 2 preliminarily changes the setting. Instead of using the setting change target data D6 in which is set, the position information included in the map image Mp may be used to specify the illumination device 1 to be the setting change target.

Further, the target position P2, which is the movement destination of the terminal device 3, can be appropriately changed to various positions not limited to the position of the desk. Further, the illumination device 1 that is the target of the setting change of the illumination mode is not limited to the illumination device 1 installed on the routes r1 to r3 including the passage r from the available entrances e1 to e3 to the target position P2, For example, the lighting device 1 installed on the straight line from the entrances e1 to e3 to the target position P2 or the lighting device 1 set on the target position P2 may be used, and can be appropriately changed.

[3] Modified Example [3-1] Modified Example 1
In the first specific example of the illumination control process described above, the illumination control device 2 uses the information (current position P1m of the terminal device 3 and the terminal identification information Ic) received from the information management device 5 to determine the number density of the terminal devices 3. Illumination control may be performed based on generated distribution data. For example, the illumination control device 2 sets the illumination mode for the illumination device 1 existing in the region where the number density is equal to or higher than the first threshold value in the control correspondence data D2 to the second mode (mode(2)=light control rate 100%). In addition, the setting of the illumination mode can be changed so that the illumination mode for the illumination device 1 existing outside the area becomes the first mode (mode(1)=dimming rate 10%).

Further, when a region having a number density of the second threshold value (>the first threshold value) or more occurs, the illumination control device 2 exists in the region having the number density of the second threshold value or more in the control correspondence data D2. The lighting mode for the lighting device 1 may be changed from the second mode to the first mode. At this time, the illumination control device 2 changes the illumination mode for some or all of the illumination devices 1 existing in the region where the number density is smaller than the first threshold value in the control correspondence data D2 from the first mode to the second mode. You may. According to such lighting control, when the user (that is, the terminal device 3 owned by the user) is concentrated in a place where the lighting is bright, the lighting of the place becomes dark while the lighting of another place. Becomes brighter. This allows users concentrated in one place to be distributed to another bright place.

[3-2] Modification 2
FIG. 17 is a conceptual diagram showing a service providing system which is one modification of the lighting control system. This service providing system is a system that further includes the service providing device 6 in the above-described lighting control system.

<Service providing device>
The service providing device 6 is a cloud server connected to a network (WAN, LAN, etc.), and provides some service (such as coupon distribution) to the terminal device 3 via the network.

<Control processing executed by the service providing device>
In this modification, the current position P1m of the terminal device 3 on the map image Mp specified by the information management device 5 is also transmitted to the service providing device 6 together with the terminal identification information Ic of the terminal device 3. Then, the service providing device 6 provides the terminal device 3 identified by the received terminal identification information Ic with a service according to the current position P1m of the terminal device 3. For example, when the received current position P1m of the terminal device 3 corresponds to the position in the store, the service providing device 6 transmits to the terminal device 3 a coupon or the like that can be used in that store.

In this modified example as well, similar to the above-described embodiment, in various places (stores and the like) where the lighting device 1 is installed, at the same time as the installation of the lighting device 1, the same position as the installation position of the lighting device 1 in the real space. Beacon transmitter 12B is installed in. In addition, information setting (correspondence or the like) for making it possible to specify the current position P1 of the terminal device 3 in the real space using the beacon signal Sb can be easily performed. Then, by using such a system, the construction of a system for providing a service according to the current position P1 of the terminal device 3 in the real space is simplified.

The service providing system may be constructed as a system that does not include the lighting control device 2.

The description of the above embodiments is to be considered as illustrative in all points and not restrictive. The scope of the invention is indicated by the claims rather than by the embodiments described above. Further, the scope of the present invention is intended to include meanings equivalent to the claims and all modifications within the scope.

For example, the present invention is not limited to the information setting device 4 and the lighting control system described above, but also includes those in which the configuration of each device included in the lighting control system and the control processing executed by the device are individually considered as inventions. Be done.

The illumination control system described above is not limited to the case where the lighting device 1 includes the LED light source 11A, but can be applied to the case where the lighting device 1 includes another light source. Further, in the above-described lighting control system, the beacon transmission unit 12B is not limited to being realized as a function of the wireless module 12, and is a device separate from the wireless module 12, and the beacon identification information Ib is not set and the lighting device is not set. 1 may be provided.

1 Lighting device 2 Lighting control device 3 Terminal device 4 Information setting device 5 Information management device 6 Service providing device 11A LED light source 11B Power supply unit 12 Wireless module 12A Communication unit 12B Beacon transmission unit 13 Control unit 14 Storage unit 41 Touch panel 42 Communication unit 43 Control unit 44 Storage unit D1 Information corresponding data D2 Control corresponding data D3 Lighting mode data D4 Reception time data D5 Specific time data D6 Setting change target data e1, e2, e3, Es Entrance Ia Device identification information Ib Beacon identification information Ic Terminal identification information J icon K beacon information m1 major value m2 minor value Mp map image P1, P1m current position P2, P2m target position r passage r1, r2, r3 route Rt predetermined area Sb beacon signal T0, Ts0 predetermined time T1 reception time T2 specific time

Claims (7)

Beacon transmitter is provided in the lighting device, an information setting device applied to a system in which the beacon transmitter is installed at the installation position of the lighting device in the real space, a display unit, an input unit, And a control unit,
The control unit is
An image corresponding to the real space in which the lighting device is installed, and a switch for turning on the lighting device at least once, are displayed on a display unit,
Generating at least a part of beacon identification information for identifying the beacon transmitter,
When the installation position of the beacon transmission unit on the image corresponding to the installation position of the beacon transmission unit in the real space that can be confirmed by turning on the lighting device by operating the switch is designated by the input unit, An information setting device that associates the specified installation position of the beacon transmission unit with the beacon identification information that identifies the beacon transmission unit. The information setting device according to claim 1, wherein the installation position of the beacon transmission unit on the image is specified by the arrangement of an icon on the image on the display unit by an operation from the input unit. The icon is associated with device identification information for identifying the lighting device acquired from the lighting device,
The information setting device according to claim 2, wherein the switch is displayed on the display unit in association with the icon, and turns on the illumination device identified by the device identification information associated with the icon. Obtain the information of the beacon signal received by the terminal device,
Using the installation position and the beacon identification information of the beacon transmission unit on the image associated with the information setting device according to any one of claims 1 to 3, from the information of the acquired beacon signal Identify the current location of the terminal device,
A lighting control system for performing lighting control according to the current position of the specified terminal device. The lighting device existing in a predetermined area including the current position of the specified terminal device is specified,
The lighting control system according to claim 4, wherein lighting control is performed on the specified lighting device. The lighting control system according to claim 4, wherein lighting control is performed according to the current position of the terminal device and a target position to which the terminal device is moved. Obtain the information of the beacon signal received by the terminal device,
Using the installation position and the beacon identification information of the beacon transmission unit on the image associated with the information setting device according to any one of claims 1 to 3, from the information of the acquired beacon signal Identify the current location of the terminal device,
A service providing system for providing a service according to the current position of the identified terminal device.

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