JP7369451B2 - lighting system - Google Patents

Description

FIELD OF THE INVENTION The present invention relates to lighting systems.

Various lighting systems have been proposed that control multiple lighting fixtures using wireless communication. Patent Document 1 discloses an example of a conventional lighting system. The lighting system disclosed in this document includes a plurality of lighting fixtures capable of short-range communication. The plurality of lighting fixtures belong to one of the plurality of groups. One luminaire included in each group is capable of long-distance communication. This long distance communication allows wireless communication between each group. Moreover, one of the lighting equipment is equipped with a sensor. Measurement data from this sensor can be sent and received via wireless communication.

Special table 2017-533567 publication

A lighting fixture equipped with a sensor is for illuminating a place where it is installed, and is installed at a position suitable for illumination, such as indoors or outdoors. However, when a sensor measures a target physical quantity, the position where a lighting fixture is installed is not necessarily a position suitable for measuring the physical quantity. For this reason, there is a concern that measurements by the sensor may not be performed appropriately.

The present invention was conceived under the above circumstances, and an object of the present invention is to provide a lighting system that can be more appropriately measured by a sensor.

A lighting system provided by the present invention includes a plurality of lighting fixtures and a control device that controls the plurality of lighting fixtures, and the lighting fixture includes a first wireless communication device that performs wireless communication using a first protocol. and a second wireless communication unit that performs wireless communication using a second protocol, and the control device performs wireless communication with the plurality of lighting devices using the first protocol, and The lighting device further includes a sensor device that wirelessly communicates with one of the plurality of lighting devices using a protocol, and the lighting device transmits the measurement data received from the sensor device by the second wireless communication unit using the first protocol. The first communication unit converts the data into transfer data that can be transferred by wireless communication, and transfers the transfer data from the first communication unit to the control device directly or via another lighting device.

In a preferred embodiment of the present invention, the plurality of lighting fixtures include a first lighting fixture that receives first measurement data from a first sensor device, and a second lighting fixture that receives second measurement data from a second sensor device. , and a third lighting fixture that receives the transfer data from the first lighting fixture and the second lighting fixture, and the first measurement data and the second measurement data include each measurement value and measurement time. , the third lighting fixture receives the first transfer data from the first lighting fixture and the second transfer data from the second lighting fixture, and then transmits the first transfer data and the second transfer data. The information is transferred all at once to the control device.

In a preferred embodiment of the present invention, each of the sensor devices has a unique device ID, the control device has model attribute data for each sensor device, and the sensor device has a unique device ID. Only the measured value is transmitted as the measured data, and the control device stores the measured value of the measured data in association with the model attribute data based on the device ID.

In a preferred embodiment of the present invention, the control device further includes an electronic device that is associated with the sensor device and that performs wireless communication using the second protocol with the lighting fixture with which the sensor device wirelessly communicates. has reference data that serves as a control reference for the electronic device, determines whether or not to change the state of the electronic device based on the transferred data and the reference data, and determines whether or not the state of the electronic device needs to be changed. If necessary, a request signal for changing the state of the electronic device is transmitted via the plurality of lighting fixtures.

According to the present invention, it is possible to provide a lighting system that can be more appropriately measured by a sensor.

Other features and advantages of the invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

1 is a system configuration diagram showing a lighting system according to a first embodiment of the present invention. FIG. 1 is a block diagram showing a lighting fixture of a lighting system according to a first embodiment of the present invention. FIG. 1 is a block diagram showing sensor equipment of the lighting system according to the first embodiment of the present invention. FIG. 1 is a block diagram showing a control device for a lighting system according to a first embodiment of the present invention. FIG. 1 is a block diagram showing a mobile terminal of a lighting system according to a first embodiment of the present invention. 1 is a sequence diagram of a lighting system according to a first embodiment of the present invention. 1 is a sequence diagram of a lighting system according to a first embodiment of the present invention. FIG. 2 is a system configuration diagram showing a lighting system according to a second embodiment of the present invention. 3 is a sequence diagram of a lighting system according to a second embodiment of the present invention. It is a table showing model attribute data and measured values of a lighting system according to a third embodiment of the present invention. FIG. 7 is a system configuration diagram and a table showing a lighting system according to a fourth embodiment of the present invention. FIG. It is a block diagram showing the electronic equipment of the lighting system concerning a 4th embodiment of the present invention. It is a sequence diagram of the lighting system concerning a 4th embodiment of the present invention. It is a sequence diagram of the lighting system concerning a 4th embodiment of the present invention. It is a top view which shows the portable terminal of the illumination system based on 4th Embodiment of this invention. It is a system configuration diagram showing a lighting system according to a fifth embodiment of the present invention. It is a system configuration diagram showing a lighting system according to a sixth embodiment of the present invention. It is a system configuration diagram showing a lighting system according to a seventh embodiment of the present invention. It is a block diagram showing the relay unit of the lighting system concerning a 7th embodiment of the present invention. It is a system configuration diagram showing a modification of the lighting system according to the seventh embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings.

Terms such as "first," "second," "third," etc. in this disclosure are used merely as labels and are not intended to impose any permutation on those objects.

<First embodiment>
1 to 5 show a lighting system according to a first embodiment of the invention. The lighting system A1 of this embodiment includes a plurality of lighting fixtures L, a sensor device Es, a control device Ct, and a mobile terminal Md. Note that, unlike this embodiment, the configuration may not include the mobile terminal Md.

FIG. 1 is a system configuration diagram showing the lighting system A1. FIG. 2 is a block diagram showing the lighting fixtures of lighting system A1. FIG. 3 is a block diagram showing sensor equipment of lighting system A1. FIG. 4 is a block diagram showing a control device of lighting system A1. FIG. 5 is a block diagram showing a mobile terminal of lighting system A1.

[Lighting equipment L]
The plurality of lighting fixtures L are used for indoor lighting, for example, and are installed at various locations such as a ceiling, a wall surface, and a floor surface. Further, the lighting fixture L may have a configuration used for outdoor lighting. The specific form of the lighting fixture L is not limited at all, and various forms such as alternative lighting for straight tube fluorescent lamps, high ceiling lighting, ceiling lights, downlights, base lights, spotlights, etc. can be adopted as appropriate. In the following description, when describing the general configuration of the lighting fixture L, it will be referred to as a lighting fixture L, and when distinguishing between a plurality of lighting fixtures L, symbols such as lighting fixture L1, ... lighting fixture Ln, etc. will be used as appropriate. Sometimes used. The plurality of lighting fixtures L1 to Ln may each have the same configuration, may have a part in common, or may have different configurations from each other. In the following description, unless otherwise specified, an example will be described in which a plurality of lighting fixtures L1 to Ln have the same configuration.

FIG. 2 is a block diagram of the lighting fixture L. The lighting fixture L includes a light source section 11, a control section 12, a storage section 13, a wireless communication module 14, and a power supply section 15.

The light source section 11 is a part that performs a light emitting function in the lighting fixture L1. The specific configuration of the light source section 11 is not limited at all, and includes, for example, a substrate and a plurality of LEDs mounted on the substrate in a row. The lighting fixture L1 also has a transparent or semi-transparent cover (not shown) that allows light from the light source section 11 to pass therethrough.

The control unit 12 is for controlling each part of the lighting fixture L based on instructions etc. from the control device Ct. The specific configuration of the control unit 12 is not particularly limited, and includes, for example, a CPU. The storage unit 13 is for storing information necessary for controlling the control unit 12, and is made of, for example, a semiconductor memory. Note that the storage unit 13 is not limited to being built into the casing (not shown) of the lighting fixture L, but may be removably provided outside the casing of the lighting fixture L.

The wireless communication module 14 is for performing wireless communication with the control device Ct and the plurality of lighting fixtures L, and is a module that transmits and receives wireless signals. The wireless communication module 14 is connected to the control unit 12 by, for example, UART (Universal Asynchronous Receiver Transmitter) communication, but is not limited thereto. The wireless communication module 14 includes a first wireless communication section 141 and a second wireless communication section 142.

To illustrate the functions of the wireless communication module 14, it receives a signal from the control device Ct, and transmits data (for example, a lighting control signal) included in the received signal to the control unit 12. Furthermore, an acknowledge signal indicating that the lighting control signal has been received is transmitted to the control device Ct. Further, a status information signal indicating the operating status of the lighting fixture L may be transmitted to the control device Ct.

In this embodiment, a unique lamp ID of each of the plurality of lighting apparatuses L is stored in the wireless communication module 14. The information format of the lamp ID is not particularly limited, and for example, a MAC (Media Access Control) address is used. Note that the lamp ID may be stored in either the first wireless communication unit 141 or the second wireless communication unit 142 or other components of the wireless communication module 14, or may be stored in the storage unit 13, for example. You can leave it there.

The first wireless communication unit 141 is for performing wireless communication with the control device Ct and other lighting fixtures L using the first protocol. The communication frequency of wireless communication using the first protocol is not limited at all, and examples include a 920 MHz band, a 2.4 GHz band, a 5 GHz band, and the like. Further, specific examples of the first protocol are not particularly limited, and examples thereof include Bluetooth (registered trademark) including BLE (Bluetooth Low Energy), Zigbee (registered trademark), Wi-Fi (registered trademark), and the like. In this embodiment, a plurality of lighting fixtures L having the first wireless communication unit 141 and the control device Ct construct a communication network Cn1 that is a mesh network. The first protocol is used to transfer various data between multiple lighting fixtures L as described later, so it is possible to construct a mesh network while ensuring the transfer speed and reliability required for data transfer. A protocol is selected.

The second wireless communication unit 142 is for performing wireless communication with the sensor device Es using the second protocol. The communication frequency of wireless communication using the second protocol is not limited at all, and examples include a 920 MHz band, a 2.4 GHz band, a 5 GHz band, and the like. Further, specific examples of the second protocol are not particularly limited, and examples thereof include Bluetooth (registered trademark) including BLE (Bluetooth Low Energy), Zigbee (registered trademark), Wi-Fi (registered trademark), and the like. In the illustrated example, the second wireless communication unit 142 is connected to the first wireless communication unit 141 through SPI (Serial Peripheral Interface) communication, but the present invention is not limited thereto. In this embodiment, the lighting fixture L having the second wireless communication unit 142 and the corresponding sensor device Es construct a communication network Cn2. Since the second protocol is used for data transfer with the sensor device Es etc. as described later, BLE, Wi-Fi, etc., which are commonly installed in commercially available sensor devices, etc. are selected.

It is preferable that the first protocol and the second protocol have different communication frequencies so that their communications do not interfere with each other. Further, it is preferable that the wireless communication by the first wireless communication unit 141 and the wireless communication by the second wireless communication unit 142 have different communication timings. Note that wireless communication using the second protocol may have a shorter communication distance than wireless communication using the first protocol, for example.

For example, when the first wireless communication unit 141 receives a request signal requesting data acquisition of the sensor device Es from the control device Ct, the wireless communication module 14 converts the request signal from the first protocol to the second protocol. A transfer signal is generated and transmitted from the control unit 12 to the sensor device Es. Furthermore, when the second wireless communication unit 142 receives measurement data transmitted from the sensor device Es, it generates transfer data by converting the measurement data into the first protocol, and transmits it to the control device Ct. To give a specific example, the wireless communication module 14 detects from the protocol flag in the communication data that the measurement data from the sensor device Es is communication using the second protocol. Next, a predetermined process is performed in accordance with the second protocol, and the second wireless communication unit 142 receives the signal. Transfer data is then generated by converting the measurement data into a communication data format using the first protocol, and transferred to the adjacent lighting fixture L via the communication network Cn1.

The power supply section 15 is for supplying power necessary for operation to the light source section 11, the control section 12, the wireless communication module 14, and the like. The power supply section 15 has, for example, a function as an AC/DC converter that converts commercial AC 100V or 200V power into DC power, a transformer function, and the like.

[Sensor equipment Es]
The sensor device Es is a device that measures a physical quantity related to the environment in which it is installed and transmits the measurement result by wireless communication. FIG. 3 is a block diagram of the sensor device Es. The sensor device Es of this embodiment includes a sensor section 41, a control section 42, a storage section 43, a wireless communication section 44, and a power supply section 45. The specific configuration of the sensor device Es is not limited in any way, and in addition to the configuration installed as a dedicated device, it can also be used in buildings to which the lighting system A1 is applied (office buildings, logistics equipment, stores such as commercial facilities, condominiums, etc.). It may be in the form of a mobile terminal or an ID card owned by a user who enters and leaves a residence (such as a residence), or a control switch for an air conditioner, a lighting fixture, etc.

In the following description, when describing the general configuration of the sensor device Es, it will be referred to as a sensor device Es, and when distinguishing between a plurality of lighting fixtures L, symbols such as sensor device Es1 and sensor device Esn may be used as appropriate. be. The plurality of sensor devices Es1 and sensor devices Esn may each have the same configuration, may have a part in common with each other, or may have mutually different configurations. In the following description, unless otherwise specified, an example will be described in which the plurality of sensor devices Es1 and Esn have the same configuration.

The sensor unit 41 functions to measure physical quantities related to the environment of the sensor device Es. The functions of the sensor section 41 are not particularly limited, and include various functions such as a temperature sensor, humidity sensor, illuminance sensor, human sensor, and air volume sensor. The measurement principle of the sensor section 41 is not limited in any way, and may include a non-contact method using an optical method or an electromagnetic method, a contact method, or a method of measuring by monitoring the state of a specific part built into the sensor section 41. , various methods can be adopted.

The control unit 42 is for controlling each part of the sensor device Es. The specific configuration of the control unit 42 is not particularly limited, and includes, for example, a CPU. The storage unit 43 is for storing information such as programs and setting conditions necessary for controlling the control unit 42, and is made of, for example, a semiconductor memory.

The wireless communication unit 44 is for performing wireless communication with the corresponding lighting fixture L using the above-mentioned second protocol. The lighting fixture L having the second wireless communication unit 142 and the corresponding sensor device Es construct a communication network Cn2. Specifically, the lighting system A1 includes n lighting fixtures L1, L2, ... lighting fixtures Ln, and a sensor device Es1 corresponding to the lighting fixture L1 and a sensor device corresponding to the lighting fixture Ln. It is equipped with Esn. The lighting fixture L1 and the sensor device Es1 construct one communication network Cn2, and the lighting fixture Ln and the sensor device Esn construct yet another communication network Cn2.

In this embodiment, the sensor device Es has a unique device ID. A specific example of the device ID is not limited at all, and for example, a MAC (Media Access Control) address is used. Note that the device ID may be stored in the wireless communication unit 44 or, for example, in the storage unit 43.

The power supply section 45 is for supplying power necessary for operation to the sensor section 41, the control section 42, the wireless communication section 44, and the like. The power supply section 45 is, for example, a device having a function as an AC/DC converter that converts commercial AC 100V or 200V power into DC power, a transformer function, or the like, or a rechargeable battery.

When the request signal (transfer signal) received from the corresponding lighting fixture L via the communication network Cn2 includes the device ID of its own device, the wireless communication section 44 transmits the request signal to the control section 42. The control unit 42 transmits a measurement request to the sensor unit 41 in accordance with the request signal. The sensor section 41 outputs the measured value obtained as a result of the measurement to the control section 42 . The control unit 42 generates measurement data including the device ID, the position information of the sensor device Es, the type of the sensor device Es, the unit of measurement data, the measurement value, the measurement time (time stamp), etc., and transmits it from the wireless communication unit 44. do.

[Control device Ct]
The control device Ct controls the lighting of the plurality of lighting fixtures L1 to Ln and the measurement control of the plurality of sensor devices Es. In the case of this embodiment, the control device Ct may be installed in the same room where the plurality of lighting fixtures L1 to Ln are installed, or may be installed in another room or another floor of the same building. It may be located in a separate building. When the control device Ct and the plurality of lighting fixtures L1 to Ln are separated by a certain distance, the control device Ct and the plurality of lighting fixtures L1 to Ln communicate with each other not only by wireless communication but also by wired communication and wireless communication. It may also be configured to communicate. Note that the lighting system A1 only needs to include at least one control device Ct, and may include a plurality of control devices Ct in other configurations. Note that the control device Ct of this embodiment is capable of communicating with both the plurality of lighting fixtures L and the mobile terminal Md.

FIG. 4 is a block diagram of the control device Ct. In this embodiment, the control device Ct includes a display section 21, a control section 22, a storage section 23, a wireless communication section 24, and a power supply section 25.

The display unit 21 is used for initial settings, maintenance, etc. of the control device Ct, although it is not necessarily necessary in the lighting control method of the lighting system A1 described later. The display unit 21 is, for example, a liquid crystal display or the like, and may further have a touch panel function. Further, instead of the display unit 21 functioning as a touch panel, the control device Ct may be separately provided with an operation device such as a keyboard or a mouse.

The control unit 22 is a main component that performs lighting control of the plurality of lighting fixtures L1 to Ln and measurement control of the plurality of sensor devices Es, and is for controlling each part of the control device Ct. For example, the control unit 22 transmits a control signal to the wireless communication unit 24 so as to transmit the control signal to the target lighting fixture L based on the instruction signal that the wireless communication unit 24 receives from the mobile terminal Md. The specific configuration of the control unit 22 is not particularly limited, and includes, for example, a CPU. The storage unit 23 is for storing information such as programs and setting conditions necessary for controlling the control unit 22, and is composed of, for example, a semiconductor memory, a hard disk drive, or the like.

The wireless communication unit 24 is for performing wireless communication with the first wireless communication unit 141 of the wireless communication module 14 of the plurality of lighting fixtures L1 to Ln and the mobile terminal Md. The frequency band of the wireless communication unit 24 and the wireless communication standard to which it conforms are wireless communication using the first protocol described above. The wireless communication unit 24 transmits control signals from the control unit 22 to the plurality of lighting fixtures L1 to Ln, for example. It also transmits measurement request signals to the plurality of sensor devices Es. Alternatively, an instruction signal from the user transmitted from the mobile terminal Md is received. The received instruction signal is transmitted to the control section 22. In addition to the wireless communication unit 24, the control device Ct may include a wired or wireless communication circuit that connects to the Internet.

The power supply section 25 is for supplying power necessary for operation to the display section 21, the control section 22, the wireless communication section 24, and the like. The power supply section 25 has, for example, a function as an AC/DC converter that converts commercial AC 100V or 200V power into DC power, a transformer function, and the like.

The control device Ct has lamp IDs of a plurality of lighting fixtures L and device IDs of a plurality of sensor devices Es, and these are stored in the storage unit 43, for example. The lamp ID and device ID held by the control device Ct may be a MAC address as a lamp ID held by the lighting fixture L or a MAC address as a device ID held by the sensor device Es, or may be associated with these MAC addresses. It may also be another lamp ID or device ID.

Note that a clock unit (not shown) may be separately arranged within the lighting system A1. This clock unit receives FM radio waves and transmits time information to the control device Ct via the communication network Cn1. This time information is added to the data transmitted from the control device Ct to each lighting fixture L and sensor device Es. Each lighting fixture L and each sensor device Es counts the respective time based on the received clock information. Thereby, the time of the devices and devices that constitute the lighting system A1 can be more accurately set.

[Mobile terminal Md]
The mobile terminal Md is a terminal operated by a user in the lighting system A1. The mobile terminal Md is not particularly limited as long as it has portability, information processing ability, etc. that allow user operations, and may be, for example, a tablet, a smartphone, a notebook PC, or the like. Note that when the plurality of lighting fixtures L that constitute the lighting system A1 are installed in a wide area, the lighting system A1 may include a plurality of mobile terminals Md.

FIG. 5 is a block diagram of the mobile terminal Md. In this embodiment, the mobile terminal Md includes a display section 31, a control section 32, a storage section 33, a wireless communication section 35, and a power supply section 36.

The display unit 31 is for displaying information and images necessary for operating the mobile terminal Md. The display unit 31 is, for example, a liquid crystal display or an organic EL display, and has a touch panel function in this embodiment. Note that instead of the display unit 31 functioning as a touch panel, the mobile terminal Md may be separately provided with an operation device such as a keyboard or a mouse.

The control section 32 is for controlling each section of the mobile terminal Md. The specific configuration of the control unit 32 is not particularly limited, and includes, for example, a CPU. The storage unit 33 is for storing information such as programs and setting conditions necessary for controlling the control unit 32, and is composed of, for example, a semiconductor memory, a hard disk drive, or the like.

The wireless communication unit 35 transmits instruction signals such as turning on/off the plurality of lighting fixtures L1 to Ln to the control device Ct, and receives status information signals of the plurality of lighting fixtures L1 to Ln from the control device Ct. do. The wireless communication unit 35 also receives measurement data of the sensor device Es and a measurement data display request signal from the control device Ct. The frequency band and wireless communication standard of the wireless communication unit 35 may be the same as or different from those of the first wireless communication unit 141 and the wireless communication unit 24, for example, Wi-Fi (registered trademark). ) is selected. Note that the wireless communication unit 35 may be a wireless communication module built into a tablet or the like as the mobile terminal Md, or may be an external wireless communication module connected to a USB terminal or the like. In this embodiment, a communication network Cn3 is constructed by the mobile terminal Md and the control device Ct. Note that the communication network Cn3 may perform wireless communication using the same first protocol as the communication network Cn1.

The power supply section 36 is for supplying power necessary for operation to the display section 31, the control section 32, the wireless communication section 35, and the like. The power supply section 36 is, for example, a rechargeable battery.

Next, an example of a control method using the lighting system A1 will be described below. 6 and 7 are sequence diagrams showing an example of the operation of the lighting system A1.

First, as shown in FIG. 6, a request signal is transmitted from the mobile terminal Md to an arbitrary sensor device Es (sensor device Esn in the illustrated example) to obtain measurement data (step S1). Specifically, when the user operates the display unit 31 of the mobile terminal Md, the control unit 32 generates a command instructing the sensor device Es to acquire measurement data. The control unit 32 transmits the command as a request signal from the wireless communication unit 35 to the control device Ct via Wi-Fi.

The control device Ct receives a request signal from the mobile terminal Md through the wireless communication unit 24. The control unit 22 generates request data including the device ID, time information, etc. included in the command. This request data is transmitted from the wireless communication unit 24 to the lighting fixture L1 closest to the control device Ct, for example, among the plurality of lighting fixtures L, via the communication network Cn1 which is a mesh network (step S2).

In the lighting equipment L1 that has received the request data, the control unit 12 confirms that the operation request target of the received request data is not the lighting equipment itself. Then, the request data is transferred from the first wireless communication unit 141 of the wireless communication module 14 to the next lighting fixture L, such as another adjacent lighting fixture L (step S3). The lighting fixture L1 also converts the request data into a second protocol and transmits it to the sensor device Es1 via the communication network Cn2. The sensor device Es1 does not perform an operation such as measurement if the device ID that specifies the operation target included in the request signal does not match the device ID of its own device.

The request data is sequentially transferred between the plurality of lighting fixtures L in the communication network Cn1, and is received by the wireless communication module 14 of the lighting fixture Ln. The control unit 12 of the lighting fixture Ln converts the received request data into request data according to the second protocol, and transmits it from the second wireless communication unit 142 of the wireless communication module 14 to the sensor device Esn via the communication network Cn2. (Step S4).

When the sensor device Esn that has received the request data from the lighting fixture Ln via the communication network Cn2 recognizes that the device ID that specifies the operation target included in the request data is the device ID of its own device, the sensor device Esn responds to the supplied data. Performs processing. For example, when the sensor unit 41 of the sensor device Esn is a temperature sensor, the temperature of the environment in which the sensor device Esn is installed is measured (step S5). Next, the control unit 42 of the sensor device Esn, for example, the device ID of the sensor device Esn, the position information of the sensor device Esn, the type of the sensor device Esn, the unit of measurement data, the measurement value acquired from the sensor unit 41, the measurement time ( measurement data Dm including a time stamp) and the like are generated and transmitted from the wireless communication unit 44 via the communication network Cn2 (step S6).

In the communication network Cn1, for example, the lighting fixture Ln closest to the sensor device Esn receives the measurement data Dm via the communication network Cn2. The wireless communication module 14 of the lighting fixture Ln receives the measurement data Dm by detecting that it is the second protocol from the protocol flag in the measurement data Dm and performing processing according to the protocol. Transfer data Dt is then generated by converting the measurement data Dm into a data format for communication using the first protocol, and transferred to the adjacent lighting fixture L via the communication network Cn1 (step S7).

In the communication network Cn1, which is a mesh network, the transfer data Dt sequentially transferred between the plurality of lighting fixtures L is received by the wireless communication module 14 of the lighting fixture L1. The lighting fixture L1 transmits the transfer data Dt to the control device Ct (step S8).

When the control device Ct receives the transfer data Dt, the control device Ct inputs the device ID of the sensor device Esn, the position information of the sensor device Esn, the type of the sensor device Esn, the unit of measurement data, and the measurement acquired from the sensor unit 41 included in the transfer data Dt. The value, measurement time (time stamp), etc. are converted into a wireless signal and transmitted to the mobile terminal Md via the communication network Cn3 (step S9).

In the mobile terminal Md, the wireless communication unit 35 receives the wireless signal transmitted from the control device Ct. The control unit 32 displays, for example, the device ID of the sensor device Esn, the position information of the sensor device Esn, the type of the sensor device Esn, and the measurement data on the display unit 31 based on the information included in the wireless signal received by the wireless communication unit 35. The unit, the measured value obtained from the sensor unit 41, the measurement time (time stamp), etc. are displayed. Note that these displays may be displayed in a format that is easy for the user of the mobile terminal Md to understand, or any information may be intentionally omitted and displayed. Furthermore, the display format may be a text display, an icon display, a combination of these, or the like, as appropriate.

Note that each sensor device Es is not limited to taking measurements in response to a request from the control device Ct, but may take measurements periodically at predetermined time intervals, for example. The measurement data Dm obtained through this measurement may be transmitted through the processes of steps S6 to S10 described above.

Next, the operation of the lighting system A1 will be explained.

According to this embodiment, the sensor device Es wirelessly communicates with the lighting fixture L2 via the communication network Cn2, and the lighting fixture L is a separate device. Therefore, it is possible to relax the restriction on the installation position of the sensor device Es due to the installation position of the lighting fixture L, and it is possible to install the sensor device Es at a position more suitable for measurement of the sensor device Es. Therefore, it can be measured more appropriately by the sensor device Es.

8-20 illustrate other embodiments of the invention. In addition, in these figures, the same or similar elements as in the above embodiment are given the same reference numerals as in the above embodiment.

<Second embodiment>
8 and 9 show a lighting system according to a second embodiment of the invention. As shown in FIG. 8, the lighting system A2 of this embodiment includes lighting fixtures L1 to L3, sensor devices Es2 and Es3, a control device Ct, and a mobile terminal Md. Note that the lighting system A2 may be configured to further include lighting equipment L and sensor equipment Es other than the illustrated lighting equipment L and sensor equipment Es.

The sensor device Es2 is installed at a position closest to the lighting fixture L2 among the plurality of lighting fixtures L. Moreover, the sensor device Es3 is installed at the position closest to the lighting fixture L3. The sensor device Es2 and the lighting fixture L2 construct a communication network Cn2, and the sensor device Es3 and the lighting fixture L3 construct another communication network Cn2.

FIG. 9 is a sequence diagram showing an example of the operation of the lighting system A2. For example, steps S1 to S5 shown in FIG. 6 are executed, and sensor device Es2 and sensor device Es3 are selected as measurement targets based on an operation request from mobile terminal Md. First, the sensor device Es2 uses the sensor unit 41 to obtain measured values such as temperature. The control unit 42 generates measurement data Dm2 including the acquired measurement values, and transmits the measurement data Dm2 from the wireless communication unit 44 to the lighting fixture L2 via the communication network Cn2 (step S11).

The wireless communication module 14 of the lighting fixture L2, which has received the measurement data Dm2 by the second wireless communication unit 142, converts the measurement data Dm2 into the first protocol format and generates transfer data Dt2 according to the procedure described above. The wireless communication module 14 transfers the transfer data Dt2 from the first wireless communication unit 141 to the lighting fixture L1 via the communication network Cn1 (step S12).

Further, the sensor device Es3 obtains measured values such as temperature using the sensor unit 41. The control unit 42 generates measurement data Dm3 including the acquired measurement values, and transmits the measurement data Dm3 from the wireless communication unit 44 to the lighting fixture L3 via the communication network Cn2 (step S13).

The wireless communication module 14 of the lighting fixture L3, which has received the measurement data Dm3 by the second wireless communication unit 142, converts the measurement data Dm3 into the first protocol format according to the procedure described above, and generates transfer data Dt3. The wireless communication module 14 transfers the transfer data Dt3 from the first wireless communication unit 141 to the lighting fixture L1 via the communication network Cn1 (step S14).

The lighting fixture L1 that has received the transfer data Dt2 and the transfer data Dt3 transmits the transfer data Dt2 and the transfer data Dt3 together to the control device Ct (step S15). Such an operation of the lighting fixture L1 is performed, for example, in step S3 shown in FIG. 6, when the target devices of the data request include a plurality of sensor devices Es such as sensor device Es2 and sensor device Es3. This is executed by waiting to send the transfer data Dt to the control device Ct until all the data Dm (transfer data Dt) is received.

The control device Ct, which has received the transfer data Dt2 and the transfer data Dt3 together, obtains the device ID, the position information of the sensor device Es, the type of the sensor device Es, the unit of measurement data, the measurement value, from the transfer data Dt2 and the transfer data Dt3. The measurement time (time stamp) and the like are converted into a wireless signal and sent all together to the mobile terminal Md (step S16).

The mobile terminal Md that has received the wireless signal displays, for example, information regarding the sensor device Es2 and the measurement data of the sensor device Es2 on the display unit 31.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Further, in step S15, by transferring the transfer data Dt1 and the transfer data Dt2 together, it is possible to reduce the number of times of communication in the communication network Cn1, which is a mesh network.

<Third embodiment>
FIG. 10 shows model attribute data Da and measured values in the lighting system according to the third embodiment of the present invention. In this embodiment, after acquiring the measured value by the sensor unit 41 of the sensor device Es in step S5 in FIG. 6, in step S6 in FIG. Measurement data Dm including the value and measurement time (time stamp) is generated and transmitted from the wireless communication unit 44 via the communication network Cn2. This measurement data Dm does not include the position information of the sensor device Esn, the type of the sensor device Esn, or the unit of measurement data.

On the other hand, in step S8 in FIG. 7, the control device Ct that has received the transfer data Dt that does not include the position information of the sensor device Esn, the type of the sensor device Esn, and the unit of measurement data has the model attribute stored in the storage unit 23 in advance. The data Da is associated with the device ID and measurement value of the sensor device Esn included in the transfer data Dt. The model attribute data Da includes, for each device ID of the sensor device Esn, the corresponding sensor device Esn position information (location in the diagram), type of sensor device Esn (type in the diagram), and measurement data unit (in the diagram). (explanation inside) is recorded. The control device Ct selects the corresponding model attribute data Da from the device ID included in the transfer data Dt, and associates the measured value with the model attribute data Da.

The model attribute data Da of model ID=A1 in FIG. 10 is an example when the sensor device Es is an illuminance sensor. The model attribute data Da of model ID=A2 is an example where the sensor device Es is a human sensor. The model attribute data Da of model ID=A3 is an example where the sensor device Es is a temperature sensor. The model attribute data Da of model ID=A4 is an example where the sensor device Es is an operation switch.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Furthermore, by not including the position information of the sensor device Es, the type of the sensor device Es, and the unit of measurement data in the data transmitted from the sensor device Es, it is possible to reduce the amount of communication in the communication network Cn1 and the communication network Cn2. can.

<Fourth embodiment>
11 to 15 show a lighting system according to a fourth embodiment of the invention. The lighting system A4 of this embodiment includes a plurality of lighting fixtures L, a plurality of sensor devices Es, a plurality of electronic devices Eq, a control device Ct, and a mobile terminal Md.

The electronic device Eq is an electronic device whose operation can be controlled by an operation control signal from the control device Ct. The specific configuration of the electronic device Eq is not limited at all. Examples of electronic equipment Eq include air conditioning equipment, various housing equipment, and various production equipment. Examples of air conditioning equipment include electric fans, circulators, heating appliances, and air conditioners.

FIG. 12 is a block diagram showing the electronic device Eq. The electronic device Eq of this embodiment includes a functional section 51, a control section 52, a storage section 53, a wireless communication section 54, and a power supply section 55.

The functional unit 51 is a part for performing the main functions of the electronic device Eq. For example, when the electronic device Eq is a fan or a circulator, the functional unit 51 includes a motor for rotating the fan. Furthermore, when the electronic device Eq is a heating appliance, the functional unit 51 includes a heater. When the electronic device Eq is an air conditioner, the functional unit 51 includes various driving parts of the indoor unit and the outdoor unit.

The control section 52 is for controlling each section of the electronic device Eq. The specific configuration of the control unit 52 is not particularly limited, and includes, for example, a CPU. The storage unit 53 is for storing information such as programs and setting conditions necessary for controlling the control unit 52, and is made of, for example, a semiconductor memory.

The wireless communication unit 54 is for performing wireless communication with the corresponding lighting fixture L using the above-mentioned second protocol. The wireless communication unit 54 has a similar configuration to the wireless communication unit 44 of the sensor device Es, for example.

In this embodiment, the electronic device Eq has a unique device ID like the sensor device Es. A specific example of the device ID is not limited at all, and for example, a MAC (Media Access Control) address is used. Note that the device ID may be stored in the wireless communication unit 54 or, for example, in the storage unit 53.

The power supply section 55 is for supplying power necessary for operation to the functional section 51, the control section 52, the wireless communication section 54, and the like. The power supply unit 55 is, for example, an AC/DC converter that converts commercial AC 100 V or 200 V power into DC power, a transformer function, or the like, or a rechargeable battery.

As shown in FIG. 11, in the lighting system A4, the lighting fixture L2, the sensor device Es2, and the electronic device Eq2 construct one communication network Cn2. Furthermore, the lighting fixture Ln, the sensor device Esn, and the electronic device Eqn construct another communication network Cn2.

An example of the operation of the lighting system A4 will be described. For example, in steps S1 to S5 shown in FIG. 6, the sensor device Es2 and the sensor device Esn acquire measured values. Next, as shown in FIG. 13, the sensor device Esn generates measurement data Dmn and transmits it to the lighting fixture Ln via the communication network Cn2 (step S21). Furthermore, the sensor device Esn generates measurement data Dmn and transmits it to the lighting fixture Ln via the communication network Cn2 (step S22). The lighting fixture Ln converts the measurement data Dmn into transfer data Dtn, and transfers the transfer data Dtn to the lighting fixture L1 via the communication network Cn1 (step S23). The lighting fixture L2 converts the measurement data Dm2 into transfer data Dt2, and transfers the transfer data Dt2 to the lighting fixture L1 via the communication network Cn1 (step S24).

When the lighting fixture L1 receives the transfer data Dt2 and the transfer data Dtn (step S25), the lighting fixture L1 transfers the transfer data Dt2 and the transfer data Dtn together to the control device Ct (step S26). The control device Ct analyzes the received transfer data Dt2 and transfer data Dtn (step S27).

In step S27, the control device Ct analyzes the transfer data Dt2 and the transfer data Dtn to determine whether a state change is necessary for each electronic device Eq. A change in the state of the electronic device Eq mainly means changing the operation of the functional unit 51. If the electronic device Eq is an electric fan, it can be changed by turning on/off the rotation of the fan or changing the rotation speed (air volume). be. In this embodiment, as shown in FIG. 11, measured values such as temperature and humidity included in the transfer data Dt2 and the transfer data Dtn are stored in the storage unit 23 of the control device Ct as necessary. By comparing a predetermined table or the like, a WBGT (Wet Bulb Globe Temperature) value is calculated for each location where the sensor device Es is installed. The control device Ct has reference data that serves as a control reference for each electronic device Eq, and includes the transfer data (Dt2 and Dtn) transferred through the lighting network and the reference data (WBGT value, which is 27 as an example here). ) to determine whether to control the electronic device. In the illustrated example, the WBGT value calculated from the measurement data Dm2 (transfer data Dt2) transmitted from the sensor device Es2 is 25, which is smaller than the reference data of 27, and does not require a change in the state of the electronic device Eq2. For example, the electronic device Eq2 is kept in a stopped state. On the other hand, the WBGT value calculated from the measurement data Dmn (transfer data Dtn) transmitted from the sensor device Esn is 30, which is larger than the reference data of 27, and is of a size that requires a change in the state of the electronic device Eqn. For example, the electronic device Eqn is changed from an OFF state to an ON state to start blowing air.

As shown in FIG. 14, the control device sends a request signal to change the state of the electronic device Eqn, in this case, a command to control air blowing, to the electronic device Eqn at the location where control is required based on the WBGT value calculated in step S27. create. Control data is created by combining this command and the device ID of the electronic device Eqn to be instructed. Then, the control data is converted into a wireless signal and transferred to the lighting fixture L1 near the control device Ct via the communication network Cn1 (step S28).

The control data received by the lighting fixture L1 is sequentially transferred from the lighting fixture L1 to the plurality of lighting fixtures L in the communication network Cn1 (step S29). The lighting fixture L2 that has received the control data converts the control data into the second protocol format and transfers it to the electronic device Eq2 via the communication network Cn2 (step S30). The electronic device Eq2 that has received the control data maintains the current state without changing the state if the device ID indicating the controlled device included in the control data does not match the ID of the device itself (step S31).

The lighting fixture L2 transfers the control data from the lighting fixture L1 via the communication network Cn1 (step S32), and when the lighting fixture Ln receives it, the lighting fixture Ln converts the control data into a format of the second protocol, It is transferred to the electronic device Eqn via the communication network Cn2 (step S33). If the device ID indicating the device to be controlled included in the control data matches the ID of the device itself, the electronic device Eqn that has received the control data performs the function according to the instruction content that instructs the state change included in the control data. The state of the section 51 is changed (step S34). In this example, the electronic device Eqn, which is a fan, for example, starts blowing air. Thereby, the air conditioning of the location n where the electronic device Eqn is installed is controlled.

Further, the control device Ct converts a command for displaying the location of the electronic device Eqn that needs to be controlled into a wireless signal, converts it into, for example, WiFi, and transmits it to the mobile terminal Md (step S35). The mobile terminal Md that has received the wireless signal undergoes a state change under control, and displays the location n where the air blowing has started in a visually recognizable manner, as shown in FIG. 15, for example (step S36). In the illustrated example, the WBGT value at each location is displayed numerically. In this embodiment, the second protocol is used as the wireless communication protocol between the lighting fixture L and the electronic device Eq, but a third protocol different from the first protocol and the second protocol may be used. In this case, the lighting fixture L needs to be able to transmit and receive three protocols, which complicates the wireless communication module 14, but it has the advantage of expanding the choices of electronic devices Eq that make up the communication network.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Furthermore, since the sensor device Es and the electronic device Eq are included in the same communication network Cn2, the control device Ct can more appropriately control the operation of the electronic device Eq installed in a nearby position according to the measurement result of the sensor device Es. can be controlled.

<Fifth embodiment>
FIG. 16 shows a lighting system according to a fifth embodiment of the invention. The lighting system A5 of this embodiment includes a plurality of lighting fixtures L1 to L9, a sensor device Es2, electronic devices Eq1 and Eq3, a control device Ct, and a mobile terminal Md.

Each of the lighting fixtures L1, L2, and L3 of this embodiment functions as a gate module. The gate module functions as a module that forms a small network (cluster) together with some of the lighting fixtures L within the communication network Cn1 which is a mesh network. Wireless communication between the plurality of clusters is performed by gate modules. The lighting fixtures L1, L2, and L3 that function as gate modules can be constructed, for example, by appropriately changing the setting program of the wireless communication module 14 of the lighting fixture L having the above-described configuration.

In the illustrated example, a cluster Cn11 is constructed by lighting fixtures L1, L4, and L7 installed close to each other. Furthermore, a cluster Cn12 is constructed by lighting fixtures L2, L5, and L8 installed close to each other. Furthermore, a cluster Cn13 is constructed by lighting fixtures L3, L6, and L9 installed close to each other.

For example, request data for requesting measurement and control data for control from the control device Ct are transmitted from the control device Ct to the lighting fixtures L1, L2, and L3, respectively, in the communication network Cn1. Lighting fixture L1 transfers the received data to lighting fixture L4 and lighting fixture L7. Similarly, lighting fixture L2 forwards the received data to lighting fixture L5 and lighting fixture L8, and lighting fixture L3 forwards the received data to lighting fixture L6 and lighting fixture L9.

The lighting fixture L7 converts the received data into the second protocol format and transmits it to the electronic device Eq1 via the communication network Cn2. Similarly, the lighting fixture L8 converts the received data into a second protocol format and transmits it to the sensor device Es2 via the communication network Cn2, and the lighting fixture L9 converts the received data into a second protocol format. and transmits it to the electronic device Eq3 via the communication network Cn2.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Furthermore, by providing the lighting fixtures L1, L2, and L3 that function as gate modules, clusters Cn11, Cn12, and Cn13 can be constructed, and the communication efficiency of the communication network Cn1, which is a mesh network, can be further improved.

<Sixth embodiment>
FIG. 17 shows a lighting system according to a sixth embodiment of the invention. The lighting system A6 of this embodiment includes an external storage device Sd.

The external storage device Sd is installed outside the communication network Cn1, and is, for example, a server, a commercial cloud, or the like. For communication between the external storage device Sd and the control device Ct, a commercial Internet line, a dedicated line, or the like is used, for example. The external storage device Sd can be accessed by an external user Eu at any time at a location away from a location where a plurality of lighting fixtures L constituting the lighting system A6 are installed. The control device Ct may store the collected measurement data in the external storage device Sd, for example.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Furthermore, the external user Eu can remotely manage a plurality of lighting fixtures L, sensor devices Es, electronic devices Eq, etc. installed in a building, warehouse, factory, or business office that is a remote location. Further, by using a large screen such as a digital signage, the external user Eu can freely process and use the information collected from the sensor equipment Es.

<Seventh embodiment>
18 and 19 show a lighting system according to a seventh embodiment of the invention. The lighting system A7 of this embodiment includes a relay unit Ru.

As shown in FIG. 19, the relay unit Ru has a switch function to realize operation control of the connected electronic device Eq, and includes a relay switch 61, a control section 62, a wireless communication section 64, and a power supply section 65. ing.

The relay switch 61 is a part to which, for example, the electronic device Eq2 is connected, and has the function of switching ON/OFF the power supply to the electronic device Eq2. The control unit 62 controls the relay switch 61 based on the received control data. The wireless communication unit 64 is capable of wireless communication using the second protocol, and functions to construct a communication network Cn2 together with the lighting fixture L2. The power supply section 65 is for supplying power necessary for operation to the relay switch 61, control section 62, wireless communication section 64, etc., and further supplies necessary power to the electronic device Eq2. The power supply unit 65 is connected to, for example, commercial AC 100V or 200V power, and has a function as an AC/DC converter that converts this power into DC power, a voltage transformation function, and the like. Note that the electronic device Eq2 of this embodiment does not necessarily have a wireless communication function, and may have a configuration that does not include the wireless communication section 54 described above. Alternatively, the electronic device Eq may have a configuration in which the wireless communication section 54 is omitted from the electronic device Eq and the relay unit Ru is combined.

In this embodiment, control data from the control device Ct is transferred to the communication network Cn1 and received by the lighting fixture L2, and then transmitted to the relay unit Ru via the communication network Cn2. The relay unit Ru that has received the control data switches the electronic device Eq2 using the relay switch 61 according to the control command included in the control data.

According to this embodiment as well, it is possible to more appropriately measure using the sensor device Es. Furthermore, by employing the relay unit Ru, electronic equipment that does not have a wireless communication function can be appropriately remotely controlled by the control device Ct.

<Seventh Embodiment Modification>
FIG. 20 shows a modification of the lighting system A7. The lighting system A71 of this modification differs from the embodiment described above in that a plurality of electronic devices Eq1, Eq2, and Eq3 are connected to one relay unit Ru.

The plurality of electronic devices Eq1, Eq2, and Eq3 are connected so that switching and other controls are collectively performed by a relay unit Ru. Note that the plurality of electronic devices Eq1, Eq2, and Eq3 may be, for example, circulators of the same model, or may be different air conditioners, etc.

According to this modification as well, it is possible to more appropriately measure using the sensor device Es. Moreover, as understood from this modification, the combination of the relay unit Ru and the electronic device Eq is not limited at all.

The lighting system according to the present invention is not limited to the embodiments described above. The specific configuration of each part of the lighting system according to the present invention can be modified in various ways.

A1, A2, A4, A5, A6, A7, A71: Lighting system 11: Light source section 12: Control section 13: Storage section 14: Wireless communication module 15: Power supply section 21: Display section 22: Control section 23: Storage section 24 :Wireless communication section 25:Power supply section 31:Display section 32:Control section 33:Storage section 35:Wireless communication section 36:Power supply section 41:Sensor section 42:Control section 43:Storage section 44:Wireless communication section 45:Power supply section 51: Functional section 52: Control section 53: Storage section 54: Wireless communication section 55: Power supply section 61: Relay switch 62: Control section 64: Wireless communication section 65: Power supply section 141: First wireless communication section 142: Second wireless Communication unit Cn1Cn2, Cn3: Communication network Cn11, Cn12, Cn13: Cluster Ct: Control device Da: Model attribute data Dm, Dm2, Dm3, Dmn: Measurement data Dt, Dt1, Dt2, Dt3, Dtn: Transfer data Eq, Eq1, Eq2, Eq3, Eqn: Electronic equipment Es, Es1, Es2, Es3, Esn: Sensor equipment Eu: External user L, L1, L2, L3, L4, L5, L6, L7, L8, L9, Ln: Lighting equipment Md : Mobile terminal Ru : Relay unit Sd : External storage device

Claims (4)

multiple lighting fixtures,
a control device that controls the plurality of lighting fixtures;
Equipped with
The lighting equipment includes a first wireless communication unit that performs wireless communication using a first protocol, and a second wireless communication unit that performs wireless communication using a second protocol,
The control device performs wireless communication with the plurality of lighting fixtures using the first protocol,
further comprising a sensor device that wirelessly communicates with any of the plurality of lighting fixtures using the second protocol,
The lighting equipment converts the measurement data received from the sensor device by the second wireless communication unit into transfer data that can be transferred by wireless communication using the first protocol, and transfers the transfer data to the first wireless communication. from the unit directly or through other lighting equipment to the control device ,
Each of the sensor devices has a unique device ID,
The control device has, for each sensor device, model attribute data including position information of the sensor device, a type of the sensor device, and a unit of the measurement data,
The sensor device transmits the measurement data that includes a measurement value and the device ID, and does not include the model attribute data,
The control device is a lighting system in which the control device stores the measurement value of the measurement data in association with the model attribute data based on the device ID . The plurality of lighting fixtures include a first lighting fixture that receives first measurement data from a first sensor device, a second lighting fixture that receives second measurement data from a second sensor device, and the first lighting fixture and the first lighting fixture. a third lighting fixture that receives the transferred data from the second lighting fixture;
The first measurement data and the second measurement data include each measurement value and measurement time,
The third lighting fixture receives the first transfer data from the first lighting fixture and the second transfer data from the second lighting fixture, and then collectively transmits the first transfer data and the second transfer data. 2. The lighting system according to claim 1, wherein the lighting system is configured to transfer the information to the control device. further comprising an electronic device that is associated with the sensor device and that performs wireless communication using the second protocol with the lighting fixture with which the sensor device performs wireless communication;
The control device has reference data that serves as a control standard for the electronic device, and determines whether or not to change the state of the electronic device based on the transfer data and the reference data, and controls the electronic device. 3. The lighting system according to claim 1 , wherein a request signal for changing the state of the electronic device is transmitted via the plurality of lighting fixtures when a state change is required. further comprising a relay unit that performs wireless communication using the second protocol,
The relay unit has a relay switch, and switches ON/OFF of power supply to the electronic device connected to the relay switch according to control data transmitted from the control device.
A lighting system according to claim 1 or 2.

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