JP2020161506A - Lighting device, communication device, and communication system - Google Patents

Abstract

To provide a lighting system that suppresses increase in a communication load and thereby suppresses increase in power consumption.SOLUTION: A lighting system comprises a lighting device, a transmitter, a radio communication device, and a monitoring device. The transmitter is arranged at a position corresponding to the lighting device, and operates in a one-way mode to transmit information. The radio communication device transmits to transmitter connection request information to switch the transmitter from the one-way mode to a two-way mode to transmit and receive information. The monitoring device communicates information with the transmitter via the radio communication device. For example, the transmitters are installed at a prescribed interval, and if they receive the connection request information, they switch from the one-way mode to the two-way mode and then transmit the received connection request information.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to lighting devices, communication devices and communication systems.

Conventionally, there has been provided a lighting device including a wireless repeater that operates using an emergency power supply in an emergency and always operates using a part of the power supply supplied from a commercial power supply to the emergency lighting control unit.

Japanese Unexamined Patent Publication No. 2004-185978

By the way, when a plurality of such lighting devices are installed at predetermined intervals, for example, there is a problem that the communication load by the wireless repeater increases and the power consumption increases.

An object of the present invention is to provide a lighting device, a communication device, and a communication system that suppress an increase in communication load and suppress an increase in power consumption.

The lighting device of the present embodiment includes a transmitter capable of switching whether or not to relay information to another lighting device located within a communicable range. This transmitter can switch based on the signal of the communication device transmitted using the same communication standard as the communication standard for communicating with other lighting devices.

The lighting device of the embodiment includes a ceiling-side structure mounted on the ceiling side; and a substructure mounted on a mounting surface different from the ceiling-side structure. The ceiling-side structure includes a mounting portion mounted on the ceiling side; a light source provided on the mounting portion and having a substrate on which a light emitting element is mounted, and a translucent cover member covering the substrate; A lamp body to be held and a lamp having; The substructure includes a normal lighting power source that is connected to the lamp and uses the light source as a normal lighting light source; and a unit that receives an input of an instruction by a user's operation.

FIG. 1 is a diagram showing a lighting system according to an embodiment. FIG. 2 is a diagram showing a configuration of a lighting device according to an embodiment. FIG. 3 is a sequence diagram showing an example of switching to the bidirectional mode in the lighting device according to the embodiment. FIG. 4 is a flowchart showing an example of switching to the bidirectional mode in the lighting device according to the embodiment. FIG. 5 is a sequence diagram showing an example of collecting inspection information according to the embodiment. FIG. 6 is a flowchart showing an example of communication of request information according to the embodiment. FIG. 7 is a flowchart showing an example of transmission of received inspection information in the lighting device according to the embodiment. FIG. 8 is a sequence diagram showing an example of switching to the unidirectional mode in the lighting device according to the embodiment. FIG. 9 is a flowchart showing an example of switching to the one-way mode in the lighting device according to the embodiment.

The lighting system 100 according to the embodiment described below is a transmitter (hereinafter referred to as “beacon 5”) that is arranged at a position corresponding to the lighting device 1 and the lighting device 1 and operates in a one-way mode for transmitting information. A wireless communication device 9 that transmits connection request information to the beacon 5 to switch the beacon 5 from a one-way mode to a two-way mode for transmitting and receiving information, and monitoring for transmitting and receiving information to and from the beacon 5 via the wireless communication device 9. The device 10 is provided.

Further, in the lighting system 100 according to the embodiment described below, the beacons 5 are installed at predetermined intervals, and when the connection request information is received, the connection request information is received after switching from the one-way mode to the two-way mode. To send.

Further, in the lighting system 100 according to the embodiment described below, when the beacon 5 receives the disconnection request information for switching from the bidirectional mode to the unidirectional mode from the wireless communication device 9, after transmitting the received disconnection request information. , Switch from bidirectional mode to unidirectional mode.

Further, in the lighting system 100 according to the embodiment described below, when the beacon 5 does not receive the request information requesting the predetermined information, the disconnection request information, or the connection request information for a predetermined period in the bidirectional mode, both of them. Switch from directional mode to unidirectional mode.

Further, in the lighting system 100 according to the embodiment described below, the lighting device 1 is an emergency lighting device, and the beacon 5 receives request information requesting inspection information of its own device in the bidirectional mode. If so, send inspection information.

Further, in the lighting system 100 according to the embodiment described below, the beacon 5 transmits inspection information received from another beacon 5 in the bidirectional mode.

[Embodiment]
First, the lighting system 100 according to the embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a lighting system according to an embodiment. FIG. 1 illustrates a case where the wireless communication device 9 transmits the inspection information received from the lighting device 1 to the monitoring device 10. The inspection information is information indicating the state of each part of the lighting device 1, but the details will be described later.

The lighting system 100 shown in FIG. 1 includes a plurality of lighting devices 1A, 1B, and 1C. FIG. 1 shows a case where the lighting device 1A is equipped with the beacon 5A which is a transmitter. That is, the lighting device 1A includes a beacon 5A and an emergency lamp 2A which is a light source. Further, the lighting device 1B includes a beacon 5B and an emergency lamp 2B. Further, the lighting device 1C includes a beacon 5C and an emergency lamp 2C. In the following, when the lighting devices 1A, 1B, and 1C will be described without particular distinction, they will be referred to as the lighting device 1. Further, when the beacons 5A, 5B, and 5C are described without particular distinction, they are described as beacon 5. Further, when the emergency lamps 2A, 2B and 2C are described without particular distinction, they are described as the emergency lamp 2.

For example, the lighting device 1 is an emergency lighting device such as an emergency light. In this case, the lighting device 1 illuminates the room or the corridor for evacuation guidance in the event of a power failure. The lighting device 1 may be a guide light installed to indicate an emergency exit or an evacuation passage. Further, the lighting device 1 may be a lighting device that always lights up as a lighting device and illuminates a room or a corridor for evacuation guidance in the event of a power failure.

Beacon 5 may be referred to as a bidirectional mode (“CONNECTION MODE”) in which information is transmitted and received from a one-way mode (sometimes referred to as “ADVERTISING MODE”) in response to an external request. ). Further, the beacon 5 switches from the bidirectional mode to the unidirectional mode in response to a request from the outside. Further, the beacon 5 switches from the bidirectional mode to the unidirectional mode when a predetermined condition is satisfied. The unidirectional mode referred to here refers to a mode in which identification information of the own device is transmitted at predetermined intervals and predetermined information such as connection request information described later can be received. Further, the bidirectional mode referred to here is a mode in which a larger amount of information can be transmitted and received than in the one-way mode, and inspection information is transmitted in response to reception of information from the outside. Further, it is assumed that the bidirectional mode consumes more power than the unidirectional mode.

In addition, the beacon 5 transmits identification information of its own device at predetermined intervals in the one-way mode. In addition, the beacon 5 transmits inspection information of its own device in response to request information from an external device in the bidirectional mode. In the following description, it may be described that the beacon 5 of the lighting device 1 transmits and receives various information, and the lighting device 1 transmits and receives various information. Further, it may be described that the beacon 5 of the lighting device 1 switches the mode when the lighting device 1 switches the mode.

The lighting system 100 includes the above-mentioned lighting device 1, a monitoring device 10, and a wireless communication device 9 capable of communicating with the lighting device 1 and the monitoring device 10. For example, the wireless communication device 9 communicates with the monitoring device 10 by a predetermined network N11. For example, the network N11 is a wired communication. Further, for example, the network N11 may be wireless communication according to a mobile data communication standard such as 3G (Generation) or 4G or LTE (Long Term Evolution). Further, for example, the wireless communication device 9 communicates with the beacon 5 included in the lighting device 1 by the wireless communication C11. For example, wireless communication C11 is communication according to the 2.4 GHz band Bluetooth (registered trademark) Low Energy (hereinafter referred to as “BLE”) wireless communication standard. In FIG. 1, it is assumed that the wireless communication device 9 is in a position where the lighting device 1A and the wireless communication C11 are possible.

As shown in FIG. 1, the lighting device 1A can perform wireless communication C12-1 with another lighting device 1 located within the range of the communication area R11. For example, wireless communication C12-1 is communication according to the BLE wireless communication standard.

Here, in the example shown in FIG. 1, the lighting device 1B located in the central portion is located within the range of the communication area R11, and the lighting device 1C located on the left side is located outside the range of the communication area R11. That is, in the example shown in FIG. 1, the lighting device 1A can wirelessly communicate with the lighting device 1B. Therefore, the lighting device 1A and the lighting device 1B can receive various information transmitted from each other by the wireless communication C12-1. On the other hand, the lighting device 1A and the lighting device 1C cannot directly receive various information transmitted by the other lighting devices 1 from each other.

Further, as shown in FIG. 1, the lighting device 1B can perform wireless communication C12-2 with another lighting device 1 located within the range of the communication area R12. For example, wireless communication C12-2 is communication according to the BLE wireless communication standard. Here, in the example shown in FIG. 1, the lighting device 1C located on the left side is located within the range of the communication area R12. That is, in the example shown in FIG. 1, the lighting device 1B can also perform wireless communication with the lighting device 1C. Therefore, the lighting device 1B and the lighting device 1C can receive various information transmitted from each other by the other lighting device 1 by the wireless communication C12-2.

The monitoring device 10 is a device that manages and controls the lighting device 1. For example, the monitoring device 10 manages the state of the lighting device 1 based on the inspection information acquired from the lighting device 1. The monitoring device 10 manages, for example, the installation position of each lighting device 1 and the identification information transmitted by the beacon 5 of each lighting device 1 in association with each other. Thereby, the monitoring device 10 can identify the information about the lighting device 1 installed at which position by receiving the identification information.

The wireless communication device 9 is a mobile terminal used by an administrator or the like of a lighting system 100 that inspects the lighting device 1. For example, the wireless communication device 9 is a smartphone, a tablet terminal, or the like. For example, an application for inspecting the lighting device 1 (hereinafter, simply referred to as “application”) is installed in the wireless communication device 9. Further, the wireless communication device 9 transmits various information to the lighting device 1. For example, the wireless communication device 9 transmits the request information received from the monitoring device 10 to the lighting device 1. Further, the wireless communication device 9 transmits various information to the monitoring device 10. For example, the wireless communication device 9 transmits the identification information and the inspection information received from the lighting device 1 to the monitoring device 10.

Here, the lighting device 1 operates in the one-way mode until the connection request information for switching from the one-way mode to the two-way mode for transmitting and receiving information is received from the outside, and transmits the identification information of the own device at predetermined intervals. .. As a result, the lighting device 1 operates in the unidirectional mode, which saves more power than the bidirectional mode, until the connection request information is received, so that an increase in power consumption can be suppressed.

When the lighting device 1 receives the connection request information from the outside, the lighting device 1 switches from the one-way mode to the two-way mode. Then, the lighting device 1 transmits the received connection request information after switching from the one-way mode to the two-way mode.

In the example shown in FIG. 1, the lighting device 1A receives the connection request information transmitted by the monitoring device 10 to the wireless communication device 9 from the wireless communication device 9 by the wireless communication C11. The lighting device 1A that has received the connection request information transmits the received connection request information after switching from the one-way mode to the two-way mode.

Then, the lighting device 1B receives the connection request information transmitted by the lighting device 1A by the wireless communication C12-1. The lighting device 1B that has received the connection request information transmits the received connection request information after switching from the one-way mode to the two-way mode.

Further, the lighting device 1C receives the connection request information transmitted by the lighting device 1B by the wireless communication C12-2. The lighting device 1C that has received the connection request information switches from the one-way mode to the two-way mode. As a result, each lighting device 1 switches from the one-way mode to the two-way mode, relays information to another lighting device 1 located within a communicable range, and forms a mesh network. As a result, the administrator of the lighting system 100 using the wireless communication device 9 can expand the range in which information can be collected without moving. As a result, the lighting system 100 can reduce the burden on the administrator of the lighting system 100 and the like. Then, the lighting device 1 relays information based on the instruction from the wireless communication device 9. An example in which the lighting device 1 forming the mesh network in the lighting system 100 relays information will be described later.

Further, when the lighting device 1 receives the disconnection request information for switching from the bidirectional mode to the unidirectional mode from the outside, the lighting device 1 transmits the received disconnection request information and switches from the bidirectional mode to the unidirectional mode.

In the example shown in FIG. 1, the lighting device 1A receives the disconnection request information transmitted by the monitoring device 10 to the wireless communication device 9 from the wireless communication device 9 by the wireless communication C11. The lighting device 1A that has received the disconnection request information transmits the received disconnection request information, and switches from the bidirectional mode to the unidirectional mode.

Then, the lighting device 1B receives the disconnection request information transmitted by the lighting device 1A by the wireless communication C12-1. The lighting device 1B that has received the disconnection request information transmits the received disconnection request information and switches from the bidirectional mode to the unidirectional mode.

Further, the lighting device 1C receives the disconnection request information transmitted by the lighting device 1B by the wireless communication C12-2. The lighting device 1C that has received the disconnection request information switches from the bidirectional mode to the unidirectional mode. As a result, the lighting system 100 returns the lighting device 1 to the unidirectional mode when it is no longer necessary to set the lighting device 1 in the bidirectional mode to form a mesh network. Therefore, the lighting system 100 can suppress an increase in communication load and suppress an increase in power consumption.

Further, when the lighting device 1 does not receive the request information requesting the predetermined information, the disconnection request information, or the disconnection request information for a predetermined period, the lighting device 1 automatically switches from the bidirectional mode to the one-way mode. As a result, the lighting system 100 can autonomously determine and switch to the one-way mode, which saves more power than the two-way mode, so that the burden on the administrator and the like can be reduced. As described above, the lighting system 100 automatically returns the lighting device 1 to the unidirectional mode when it is no longer necessary to set the lighting device 1 in the bidirectional mode to form a mesh network. Therefore, the lighting system 100 can suppress an increase in communication load and suppress an increase in power consumption.

[Configuration example of lighting device]
Next, the configuration of the lighting device 1 according to the embodiment will be described with reference to FIG. FIG. 2 is a diagram showing a configuration of a lighting device according to an embodiment. As shown in FIG. 2, the lighting device 1 includes an emergency lamp 2, an emergency power supply 3, an emergency lighting control unit 4, a beacon 5, a commercial power supply 6, an inspection unit 7, and a storage unit 8. Has.

The emergency lamp 2 is a light source that at least lights up during a so-called power failure when the power supply by the commercial power source 6 is stopped. In the following, the state in which the power supply by the commercial power source 6 is stopped may be referred to as “emergency”, and the state in which the power supply by the commercial power source 6 may be referred to as “always”. Further, as the emergency lamp 2, various light sources such as a fluorescent lamp and an LED (Light Emitting Diode) may be used depending on the purpose.

The emergency power supply 3 is a storage battery (secondary battery) that supplies power to the emergency lamp 2 when the power supply by the commercial power supply 6 is stopped. As the emergency power supply 3, various storage batteries may be used depending on the purpose. Further, the emergency power supply 3 is charged when the power is supplied by the commercial power supply 6. That is, the emergency power supply 3 is always charged by the power supply from the commercial power supply 6. The emergency power supply 3 may be charged by appropriately using various charging methods such as trickle charging and intermittent charging.

The emergency lighting control unit 4 constantly charges the emergency power supply 3, and lights the emergency lamp 2 by the emergency power supply 3 in an emergency. For example, the emergency lamp 2 is powered by the emergency lighting control unit 4 and lights only in an emergency. Further, the emergency lighting control unit 4 has an internal memory for storing a program defining various processing procedures and the like and required data, and various processing may be executed by these.

The beacon 5 is a transmitter that transmits identification information of its own device at predetermined intervals by a wireless communication function. As described above, the beacon 5 can switch between the one-way mode and the two-way mode. In addition, the beacon 5 transmits inspection information of its own device in the bidirectional mode.

In addition, the beacon 5 receives predetermined information. For example, the beacon 5 receives request information requesting inspection information. For example, when the beacon 5 receives the request information requesting the inspection information in the bidirectional mode, the beacon 5 transmits the inspection information stored in the storage unit 8. When the beacon 5 receives the request information requesting the inspection information, the beacon 5 may switch to the bidirectional mode and transmit the inspection information stored in the storage unit 8.

Further, the beacon 5 operates by using a part of the power supply supplied from the commercial power supply 6 to the emergency lighting control unit 4 at all times. Further, the beacon 5 operates by using a part of the power supply supplied from the emergency power supply 3 to the emergency lighting control unit 4 in an emergency.

The commercial power source 6 is, for example, a power source supplied from a predetermined power company. The commercial power supply 6 constantly charges the emergency power supply 3 and supplies power to the emergency lighting control unit 4 via the emergency lighting control unit 4. Further, the commercial power supply 6 may be any power supply means other than the power supply from the emergency power supply 3.

The inspection unit 7 inspects the own device, for example, and collects inspection information of the own device. Specifically, the inspection unit 7 monitors and collects the status of each device necessary for inspection of the emergency lamp 2, the emergency power supply 3, the emergency lighting control unit 4, the beacon 5, and the like as inspection information. Further, the inspection unit 7 always operates by using a part of the power supply supplied from the commercial power supply 6 to the emergency lighting control unit 4.

The storage unit 8 stores the inspection information collected by the inspection unit 7. Further, the storage unit 8 reads out the inspection information stored by the beacon 5 that has received the request information. Further, the storage unit 8 may store data and programs necessary for various processes by the emergency lighting control unit 4. The storage unit 8 may be a storage device such as a semiconductor memory element such as a RAM (Random Access Memory), a ROM (Read Only Memory), or a flash memory (Flash Memory). Further, the storage unit 8 always operates by using a part of the power supply supplied from the commercial power supply 6 to the emergency lighting control unit 4.

[Switching from one-way mode to two-way mode]
Here, a specific example of switching the lighting device 1 from the unidirectional mode to the bidirectional mode in the lighting system 100 will be described with reference to the drawings. FIG. 3 is a sequence diagram showing an example of switching to the bidirectional mode in the lighting device according to the embodiment. The lighting devices 1A to 1C in the example shown in FIG. 3 correspond to the lighting devices 1A to 1C in the example shown in FIG.

As shown in FIG. 3, the monitoring device 10 transmits the connection request information for switching the lighting device 1 from the unidirectional mode to the bidirectional mode to the wireless communication device 9 (step S11).

Here, the wireless communication device 9 that has received the connection request information from the monitoring device 10 scans the surrounding lighting device 1 (beacon 5). When the wireless communication device 9 scans and receives the identification information transmitted by the beacon 5, the connection request information is transmitted to the beacon 5 corresponding to the received identification information. In the example shown in FIG. 3, the wireless communication device 9 transmits the connection request information received from the monitoring device 10 to the lighting device 1A (step S12).

The lighting device 1A that has received the connection request information from the wireless communication device 9 switches from the one-way mode to the two-way mode (step S13). Then, the lighting device 1A transmits the connection request information received from the wireless communication device 9 (step S14). Then, the lighting device 1B located within a communicable range with the lighting device 1A receives the connection request information transmitted by the lighting device 1A.

Upon receiving the connection request information transmitted by the lighting device 1A, the lighting device 1B switches from the unidirectional mode to the bidirectional mode (step S15). Then, the lighting device 1B transmits the connection request information received from the lighting device 1A (step S16). Then, the lighting device 1C located within a communicable range with the lighting device 1B receives the connection request information transmitted by the lighting device 1B.

Upon receiving the connection request information transmitted by the lighting device 1B, the lighting device 1C switches from the unidirectional mode to the bidirectional mode (step S17). As a result, the lighting devices 1A to 1C switch from the one-way mode to the two-way mode. Further, the lighting device 1C transmits the connection request information received from the lighting device 1B. Then, another lighting device 1 located within a communicable range with the lighting device 1C receives the connection request information transmitted by the lighting device 1C.

[Flow related to switching to bidirectional mode]
Next, switching to the bidirectional mode in the lighting device 1 will be described. FIG. 4 is a flowchart showing an example of switching to the bidirectional mode in the lighting device according to the embodiment.

First, the lighting device 1 determines whether or not the connection request information has been received (step S101). When the lighting device 1 has not received the connection request information (step S101: No), the lighting device 1 repeats the determination in step S101. In the one-way mode, the lighting device 1 transmits identification information of its own device at predetermined intervals.

Further, when the lighting device 1 receives the connection request information (step S101: Yes), the lighting device 1 switches to the bidirectional mode (step S102). After that, the lighting device 1 transmits the received connection request information (step S103).

[Collection of inspection information]
Next, a specific example of collecting inspection information in the lighting system 100 will be described with reference to the drawings. FIG. 5 is a sequence diagram showing an example of collecting inspection information according to the embodiment. The lighting devices 1A to 1C in the example shown in FIG. 5 correspond to the lighting devices 1A to 1C in the example shown in FIG. Further, in the example shown in FIG. 5, the case where the monitoring device 10 collects the inspection information of the lighting device 1C is shown. Further, in the example shown in FIG. 5, it is assumed that the lighting device 1 is operating in the bidirectional mode.

As shown in FIG. 5, the monitoring device 10 transmits the request information requesting the inspection information of the lighting device 1C to the wireless communication device 9 (step S21). For example, the monitoring device 10 transmits request information including information for identifying the lighting device 1C to the wireless communication device 9.

Here, the wireless communication device 9 that has received the request information from the monitoring device 10 scans the lighting device 1 (beacon 5) in the vicinity. When the wireless communication device 9 scans and receives the identification information transmitted from the beacon 5, the request information is transmitted to the beacon 5 corresponding to the received identification information. In the example shown in FIG. 5, the wireless communication device 9 transmits the request information received from the monitoring device 10 to the lighting device 1A (step S22).

The lighting device 1A that has received the request information from the wireless communication device 9 determines whether the request information is addressed to the own device, and if the request information is not addressed to the own device, transmits the received request information (step S23). .. In the example shown in FIG. 5, since the request information is the request information for requesting the inspection information of the lighting device 1C, the lighting device 1A determines that the request information is not addressed to the own device and transmits the received request information. ..

The lighting device 1B that has received the request information transmitted by the lighting device 1A determines whether the request information is addressed to the own device, and if the request information is not addressed to the own device, transmits the received request information (step S24). ). In the example shown in FIG. 5, since the request information is the request information for requesting the inspection information of the lighting device 1C, the lighting device 1B determines that the request information is not addressed to the own device and transmits the received request information. ..

Upon receiving the request information transmitted by the lighting device 1B, the lighting device 1C determines whether the request information is addressed to the own device, and if the request information is not addressed to the own device, reads out the inspection information of the own device (step S25). ). In the example shown in FIG. 5, since the request information is the request information for requesting the inspection information of the lighting device 1C, the lighting device 1C determines that the request information is addressed to the own device and performs the inspection information of the own device. Read from the storage unit 8. Then, the lighting device 1C transmits the read inspection information (step S26).

The lighting device 1B that has received the inspection information transmitted by the lighting device 1C transmits the received inspection information (step S27). Further, the lighting device 1A that has received the inspection information transmitted by the lighting device 1B transmits the received inspection information (step S28).

Then, the wireless communication device 9 that has received the inspection information transmitted by the lighting device 1A transmits the received inspection information to the monitoring device 10 (step S29). As a result, the monitoring device 10 can collect inspection information of the lighting device 1C. That is, the administrator or the like using the wireless communication device 9 can move to the position where the lighting device 1C is installed and collect the inspection information of the lighting device 1C without collecting the inspection information of the lighting device 1C. Thereby, the lighting system 100 can facilitate the inspection.

[Flow for collecting inspection information]
Next, communication of request information in the lighting system 100 will be described. FIG. 6 is a flowchart showing an example of communication of request information according to the embodiment.

First, the lighting device 1 determines whether or not the request information has been received (step S201). When the lighting device 1 has not received the request information (step S201: No), step S
The determination of 201 is repeated.

When the lighting device 1 receives the request information (step S201: Yes), the lighting device 1 determines whether or not the request information is addressed to the own device (step S202).

When the request information is not addressed to the own device (step S202: No), the lighting device 1 transmits the received request information (step S203).

On the other hand, when the request information is addressed to the own device (step S202: Yes), the lighting device 1 reads out the inspection information (step S204). Then, the lighting device 1 transmits the read inspection information (step S205).

Next, transmission of the received inspection information in the lighting device 1 will be described. FIG. 7 is a flowchart showing an example of transmission of received inspection information in the lighting device according to the embodiment.

First, the lighting device 1 determines whether or not the inspection information has been received (step S211). When the lighting device 1 has not received the inspection information (step S211: No), the lighting device 1 repeats the determination in step S211.

When the lighting device 1 receives the inspection information (step S211: Yes), the lighting device 1 transmits the received inspection information (step S212).

[Switching from bidirectional mode to unidirectional mode]
Next, a specific example of switching the lighting device 1 from the bidirectional mode to the unidirectional mode in the lighting system 100 will be described with reference to the drawings. FIG. 8 is a sequence diagram showing an example of switching to the unidirectional mode in the lighting device according to the embodiment. The lighting devices 1A to 1C in the example shown in FIG. 8 correspond to the lighting devices 1A to 1C in the example shown in FIG.

As shown in FIG. 8, the monitoring device 10 transmits the disconnection request information for switching the lighting device 1 from the bidirectional mode to the unidirectional mode to the wireless communication device 9 (step S31).

Here, the wireless communication device 9 that has received the disconnection request information from the monitoring device 10 scans the surrounding lighting device 1 (beacon 5). When the wireless communication device 9 scans and receives the identification information transmitted by the beacon 5, the disconnection request information is transmitted to the beacon 5 corresponding to the received identification information. In the example shown in FIG. 8, the wireless communication device 9 transmits the disconnection request information received from the monitoring device 10 to the lighting device 1A (step S32).

The lighting device 1A that has received the disconnection request information from the wireless communication device 9 transmits the disconnection request information received from the wireless communication device 9 (step S33). Further, the lighting device 1A switches from the bidirectional mode to the unidirectional mode (step S34). In addition, step S33 and step S34 may be simultaneous. After that, the lighting device 1B located within a communicable range with the lighting device 1A receives the disconnection request information transmitted by the lighting device 1A.

The lighting device 1B that has received the disconnection request information transmitted by the lighting device 1A transmits the disconnection request information received from the lighting device 1A (step S35). Further, the lighting device 1B switches from the bidirectional mode to the unidirectional mode (step S36). In addition, step S35 and step S36 may be performed at the same time. After that, the lighting device 1C located within a communicable range with the lighting device 1B receives the disconnection request information transmitted by the lighting device 1B.

Upon receiving the disconnection request information transmitted by the lighting device 1B, the lighting device 1C switches from the bidirectional mode to the unidirectional mode (step S37). As a result, the lighting devices 1A to 1C switch from the bidirectional mode to the unidirectional mode. Further, the lighting device 1C transmits the disconnection request information received from the lighting device 1B. Then, another lighting device 1 located within a communicable range with the lighting device 1C receives the disconnection request information transmitted by the lighting device 1C.

[Flow related to switching to one-way mode]
Next, switching to the one-way mode in the lighting device 1 will be described. FIG. 9 is a flowchart showing an example of switching to the one-way mode in the lighting device according to the embodiment.

First, the lighting device 1 determines whether or not the disconnection request information has been received (step S301). When the lighting device 1 has not received the disconnection request information (step S301: No), the illuminating device 1 repeats the determination in step S301.

Further, when the lighting device 1 receives the disconnection request information (step S301: Yes), the lighting device 1 transmits the received disconnection request information (step S302). After that, the lighting device 1 switches to the one-way mode (step S303). The lighting device 1 may switch to the one-way mode when the information is not received within a predetermined period.

As described above, the lighting system 100 according to the embodiment is arranged at a position corresponding to the lighting device 1 and the lighting device 1, and operates in a one-way mode for transmitting information (in the embodiment, "beacon 5". The same applies hereinafter), the wireless communication device 9 that transmits the connection request information for switching the beacon 5 from the one-way mode to the two-way mode for transmitting and receiving information to the beacon 5, and the beacon 5 via the wireless communication device 9. A monitoring device 10 for transmitting and receiving information is provided.

As a result, for example, in the lighting system 100, each lighting device 1 switches from the unidirectional mode to the bidirectional mode, relays information to another lighting device 1 located within a communicable range, and forms a mesh network. .. As a result, the administrator or the like using the wireless communication device 9 can expand the range in which information can be collected without moving. Further, the lighting system 100 operates the lighting device 1 in the unidirectional mode when it is no longer necessary to set the lighting device 1 in the bidirectional mode to form a mesh network. Therefore, the lighting system 100 can suppress an increase in communication load and suppress an increase in power consumption.

Further, in the lighting system 100 according to the above-described embodiment, the beacons 5 are installed at predetermined intervals, and when the connection request information is received, after switching from the one-way mode to the two-way mode, the received connection request information is transmitted. To do.

As a result, for example, in the lighting system 100, each lighting device 1 switches from the unidirectional mode to the bidirectional mode, relays information to another lighting device 1 located within a communicable range, and forms a mesh network. .. As a result, the administrator of the lighting system 100 using the wireless communication device 9 can expand the range in which information can be collected without moving. Therefore, the lighting system 100 can reduce the burden on the administrator of the lighting system 100 and the like.

Further, in the lighting system 100 according to the above-described embodiment, when the beacon 5 receives the disconnection request information for switching from the two-way mode to the one-way mode from the wireless communication device 9, after transmitting the received disconnection request information, both of them. Switch from directional mode to unidirectional mode.

As a result, for example, in the lighting system 100, the lighting device 1 returns to the one-way mode, which saves more power than the two-way mode, by receiving the connection request information, so that an increase in power consumption can be suppressed.

Further, in the lighting system 100 according to the above-described embodiment, when the beacon 5 does not receive the request information requesting the predetermined information, the disconnection request information, or the connection request information for a predetermined period in the bidirectional mode, the beacon 5 is in the bidirectional mode. Switch to one-way mode.

As a result, for example, the lighting system 100 can autonomously determine and switch to the one-way mode, which saves more power than the two-way mode, so that the burden on the administrator and the like can be reduced. As described above, the lighting system 100 automatically returns the lighting device 1 to the unidirectional mode when it is no longer necessary to set the lighting device 1 in the bidirectional mode to form a mesh network. Therefore, the lighting system 100 can suppress an increase in communication load and suppress an increase in power consumption.

In the lighting system 100 according to the above-described embodiment, the lighting device 1 is an emergency lighting device. Further, the beacon 5 transmits the inspection information when it receives the request information requesting the inspection information of the own device in the bidirectional mode.

Thereby, for example, in the lighting system 100, the monitoring device 10 can collect the inspection information of the lighting device 1C. That is, the administrator of the lighting system 100 using the wireless communication device 9 moves to the position where the lighting device 1C is installed and collects the inspection information of the lighting device 1C without collecting the inspection information of the lighting device 1C. Can be collected. Thereby, the lighting system 100 can facilitate the inspection.

In the lighting system 100 according to the above-described embodiment, the beacon 5 transmits inspection information received from another beacon 5 in the bidirectional mode.

Thereby, for example, in the lighting system 100, the monitoring device 10 can collect the inspection information of the lighting device 1C. That is, the administrator of the lighting system 100 using the wireless communication device 9 moves to the position where the lighting device 1C is installed and collects the inspection information of the lighting device 1C without collecting the inspection information of the lighting device 1C. Can be collected. Thereby, the lighting system 100 can facilitate the inspection.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof. Further, these embodiments and modifications thereof can be appropriately combined as long as the processing contents do not contradict each other.

100 Lighting system 1 Lighting device 2 Emergency lamp 3 Emergency power supply 4 Emergency lighting control unit 5 Beacon 6 Commercial power supply 7 Inspection unit 8 Storage unit 9 Wireless communication device 10 Monitoring device

Claims (3)

With a transmitter that can switch whether to relay information to other lighting devices located within the communicable range;
The lighting device is characterized in that the switching is performed based on the signal of the communication device transmitted by using the same communication standard as the communication standard for communicating with other lighting devices. A signal that has a transmitter that can switch whether to relay information to other lighting devices located within the communicable range and is transmitted using the same communication standard as the communication standard that communicates with other lighting devices. A communication device having a transmission unit capable of communicating with a lighting device that performs the switching based on the above, and transmitting a signal using the same communication standard as the communication standard for the lighting device to communicate with another lighting device. With a transmitter that can switch whether to relay information to other lighting devices located within the communicable range;
The communication system is characterized in that the switching is performed based on the signal of the communication device transmitted by using the same communication standard as the communication standard for communicating with other lighting devices.

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