JP6665626B2 - Lighting control device, lighting system and lighting control method - Google Patents

Description

  Embodiments described herein relate generally to a lighting control device, a lighting system, and a lighting control method.

  Some lighting systems turn off the lighting when a person leaves a predetermined area. The lighting system turns off the lighting after a predetermined holding time has elapsed since the person left the area.

  Conventionally, the setting of the holding time is performed by the motion sensor itself, and the lighting system generally does not set, change, or manage the holding time of each motion sensor.

JP 2008-10370 A

  In order to solve the above-described problems, an illumination control device, an illumination system, and an illumination control method capable of effectively setting a holding time are provided.

According to the embodiment, the lighting control device includes a communication unit, a stay time acquisition unit, an average stay time acquisition unit, a determination unit, and a transmission processing unit . The communication unit communicates with a human sensor that outputs a signal according to a detection result of a person. The stay time acquisition unit acquires a stay time during which a person stays based on a signal from the human sensor through the communication unit. The average stay time acquiring unit acquires an average stay time obtained by averaging the stay times. The deciding unit decides a holding time for keeping the lighting ON state after the person is no longer detected based on the average stay time. The transmission processing unit transmits, via the communication unit, a setting signal for setting the holding time as a time from when a person is no longer detected to when a holding time elapse signal is transmitted to the human sensor.

  According to the present invention, it is possible to provide a lighting control device, a lighting system, and a lighting control method that can effectively set a holding time.

FIG. 1 is a diagram illustrating a configuration example of a lighting system according to the first, second, and third embodiments. FIG. 2 is a diagram illustrating a configuration example of a higher-level device according to the first, second, and third embodiments. FIG. 3 is a flowchart illustrating an operation example of the host device according to the first and second embodiments. FIG. 4 is a flowchart illustrating an operation example of the higher-level device according to the third embodiment.

Hereinafter, embodiments will be described with reference to the drawings.
A lighting control device (10a to 10c) according to an embodiment described below includes a communication unit (13), a stay time acquisition unit (11a to 11c), an average stay time acquisition unit (11a to 11c), and a determination unit. (11a to 11c). The communication unit communicates with human sensors (101a to 106a, 101b to 106c, and 101c to 106c) that output signals according to the detection result of a person. The stay time acquisition unit acquires a stay time during which a person stays based on a signal from the human sensor through the communication unit. The average stay time acquiring unit acquires an average stay time obtained by averaging the stay times. The deciding unit decides a holding time for keeping the lighting ON state after the person is no longer detected based on the average stay time.

  The human sensor (101a to 106a) according to the embodiment described below includes a human detection signal indicating that a person has been detected in a predetermined area, and a retention time that has elapsed since the person left the predetermined area. And a holding time elapse signal indicating that the operation has been performed. The stay time acquisition unit (11a) acquires, as the stay time, a time obtained by subtracting the hold time from the time from receiving the human detection signal to receiving the hold time elapse signal.

  The human sensors (101b to 106b and 101c and 106c) according to the embodiments described below output a human detection signal indicating that a person has been detected and a human departure signal indicating that a person has left. . The stay time acquisition units (11b and 11c) acquire, as the stay time, a time from when the person detection signal is received to when the person leaving signal is received.

  Illumination control devices (10a to 10b) according to embodiments described below include transmission processing units (11a and 11b). The transmission processing unit transmits, via the communication unit, a setting signal for setting the holding time determined by the determination unit to the human sensor.

  The lighting control device according to the embodiment described below includes a presentation processing unit. The presentation processing unit presents the average stay time.

The lighting control device according to the embodiment described below includes a total stay time acquisition unit. The total stay time obtaining unit obtains a total stay time, which is a total time of a person staying in the predetermined area during a predetermined period. The presentation processing unit presents the total stay time,
The lighting system (1a to 1c) according to the embodiment described below includes a lighting control device (10a to 10c), a human sensor (101a to 106a, 101b to 106b, and 101c to 106c), and a lighting (201 to 206). ).

  The lighting control device includes a communication unit (13), stay time acquisition units (11a to 11c), average stay time acquisition units (11a to 11c), and a determination unit (11a to 11c). The communication unit communicates with the motion sensor. The stay time acquisition unit acquires a stay time during which a person stays based on a signal from the human sensor through the communication unit. The average stay time acquiring unit acquires an average stay time obtained by averaging the stay times. The deciding unit decides a holding time for keeping the lighting ON state after the person is no longer detected based on the average stay time. The human sensor outputs a signal corresponding to a detection result of a person to the lighting control device. The lighting is turned on when the motion sensor detects that a person is staying, and is turned off when a holding time has elapsed after the motion sensor detects that the person has left.

The lighting control devices (10a and 10b) according to the embodiments described below include a transmission processing unit. The transmission processing unit transmits, via the communication unit, a setting signal for setting the holding time determined by the determination unit to the human sensors (101a to 106a and 101b to 106b). The human sensor sets the holding time based on the setting signal, and transmits a holding time elapse signal when the holding time elapses after the person leaves. The lighting is turned off when the motion sensor transmits the hold time elapsed signal,
In the lighting control method according to the embodiment described below, a person stays based on signals from motion sensors (101a to 106a, 101b to 106b, and 101c to 106c) that output signals according to the detection result of the person. Obtaining the stay time, obtaining the average stay time obtained by averaging the stay time, and determining the holding time for keeping the lighting (201 to 206) on after the person is no longer detected based on the average stay time. I do.
(1st Embodiment)
First, a first embodiment will be described.
FIG. 1 is a diagram illustrating a configuration example of a lighting system 1a according to the embodiment.
The lighting system 1a is a system that emits light using electric power from a predetermined power supply. The lighting system 1a turns on the lighting when a person stays in a predetermined area. Further, the lighting system 1a turns off the lighting when a predetermined holding time elapses after a person leaves the predetermined area. The lighting system 1a is installed in, for example, a house, an office, a commercial facility, or the like.

  As shown in FIG. 1, the lighting system 1a includes a host device 10a (lighting control device), lighting controllers 21a and 22a, human sensors 101a to 106a, lights 201 to 206, and the like. The host device 10a is communicably connected to the lighting controllers 21a and 22a. The illumination controller 21a is communicably connected to the human sensors 101a to 103a and the illuminations 201 to 203. The lighting controller 22a is communicably connected to the human sensors 104a to 106a and the lights 204 to 206. Further, the group 100 includes a human sensor 101a and a light 201. Similarly, the groups 200 to 600 include the motion sensor 102a and the light 202 and the motion sensor 106a and the light 206, respectively.

  The host device 10 controls the entire lighting system 1a. For example, the host device 10 transmits and receives data to and from the lighting controllers 21a and 22a, and controls the lighting controllers 21a and 22a. In addition, the host device 10 transmits and receives data to and from the human sensors 101a to 106a through the illumination controller 21a or 22a, and controls the human sensors 101a to 106a. In addition, the host device 10 transmits and receives data to and from the lightings 201 to 206 through the lighting controller 21a or 22a, and controls the lightings 201 to 206. The configuration of the host device 10 will be described later in detail.

  The lighting controller 21a controls the groups 100 to 300. The lighting controller 22a controls the groups 400 to 600. The group is a unit for uniformly controlling the human sensor and the lighting. For example, the group is set to a human sensor and lighting at a predetermined location. For example, a group is set to a motion sensor and a light in a predetermined room, corridor, or warehouse, respectively.

  The human sensor 101a detects that a person stays in a predetermined area where the lighting 201 is turned on when the person stays. The human sensor 101a transmits a control signal corresponding to the detection result of the person to the host device 10a.

  The human sensor 101a detects that a person stays in a predetermined area. For example, the motion sensor 101a detects that a person stays in an area illuminated by the light 201. When detecting a person in the area, the human sensor 101 transmits a signal (person detection signal) indicating that the person will stay in a predetermined area to the lighting controller 21a.

Further, when the human sensor 101a detects that a person has left from within a predetermined area, when the holding time has elapsed since the person left, the human sensor 101a determines that the holding time has elapsed since the person left the area. Is transmitted to the lighting controller 21a. For example, the human sensor 101a starts a timer after detecting that a person has left the area. When the timer reaches the holding time, the human sensor 101a transmits a holding time elapse signal to the illumination controller 21a.
The human sensor 101a detects a person using infrared rays, for example. The method by which the human sensor 101a detects a person is not limited to a specific method.

  The human sensor 101a sets a holding time. The holding time is the time from when a person leaves a predetermined area to when the light 201 is turned off. That is, the holding time is a time during which the lighting 201 is kept on after the person is no longer detected in the predetermined area. The human sensor 101a sets a holding time in advance.

  In addition, the human sensor 101a appropriately sets the holding time based on a signal from an external device. For example, the human sensor 101a sets the holding time based on a signal transmitted from the host device 10a through the illumination controller 21a.

  For example, the human sensor 101a receives a setting signal for setting a holding time from the host device 10a. The setting signal indicates the holding time. When receiving the setting signal, the human sensor 101a sets the holding time indicated by the setting signal according to the setting signal. For example, the human sensor 101a stores the holding time in an internal memory or the like.

  The motion sensors 102a to 106a have the same configuration as the motion sensor 101a, and thus the description is omitted. Note that the holding time set by the human sensors 102a to 106a is the time from when the human sensors 102a to 106a detect that a person has left the area where the human is detected to when the lights 202 to 206 are turned off. It is. Further, the human sensors 104a to 106a transmit control signals to the lighting controller 22a.

  The lighting 201 is turned on or off based on a signal from the lighting controller 21a. For example, the lighting 201 includes a lighting load and the like. The lighting load emits light according to the supplied power. For example, the lighting load is a light emitting diode, a fluorescent light, or an incandescent light bulb. The lighting load of the lighting 201 is not limited to a specific configuration. Note that the lighting 201 may include a plurality of lighting loads. The number of lighting loads included in the lighting 201 is not limited to a specific number.

The lighting 201 supplies power to a lighting load using internal or external power. Further, the lighting 201 may receive supply of electric power from the lighting controller 21a.
When receiving the control signal for turning on the illumination from the illumination controller 21a, the illumination 201 supplies power to the illumination load and causes the illumination load to emit light. Further, when receiving a control signal for turning off the lighting from the lighting controller 21a, the lighting 201 stops supplying power to the lighting load and turns off the lighting load.

The illuminations 202 to 206 have the same configuration as the illumination 201, and a description thereof will be omitted. The lights 204 to 206 are turned on or off based on a control signal from the lighting controller 22a.
In addition, the illumination system 1a may be provided with a configuration as needed in addition to the configuration shown in FIG. 1, or may exclude a specific configuration.

Next, the function of the lighting controller 21a will be described.
The lighting controller 21a has a function of turning on or off the lighting based on a control signal from the human sensor. Here, the control of the human sensor 101a and the lighting 201 of the group 100 will be described.

  The lighting controller 21a waits until a human detection signal is received from the human sensor 101a. When receiving the human detection signal from the human sensor 101a, the illumination controller 21a transmits a control signal for turning on the illumination to the illumination 201.

  When the control signal is transmitted to the lighting 201, the lighting controller 21a waits until a holding time elapsed signal is received from the human sensor 101a. When receiving the holding time elapsed signal from the human sensor 101a, the illumination controller 21a transmits a control signal to turn off the illumination 201 to the illumination 201.

  The lighting controller 21a has a function of transmitting a control signal from the human sensor 101a to the host device 10a. For example, the lighting controller 21a transmits a human detection signal or a holding time elapse signal from the human sensor 101a to the host device 10a.

  The lighting controller 21a transmits a control signal from the host device 10 to the human sensor 101a. For example, the lighting controller 21a transmits a setting signal from the host device 10 to the human sensor 101a.

Note that the lighting controller 21a may further perform control necessary for controlling the motion sensor 101a or the lighting 201. The lighting controller 21a performs the same control on the groups 200 and 300.
In addition, since the lighting controller 22a realizes the same function as the lighting controller 21a, the description of the function of the lighting controller 22a is omitted.

Next, the host device 10a will be described.
FIG. 2 is a diagram illustrating a configuration example of the higher-level device 10a.
As shown in FIG. 2, the host device 10a includes a CPU 11a, a memory 12, an interface 13 (communication unit), an operation unit 14, a display unit 15, and the like.

  The CPU 11a has a function of controlling the operation of the host device 10a as a whole. The CPU 11a may include an internal cache and various interfaces. The CPU 11a realizes various processes by executing a program stored in the internal memory or the memory 12 in advance. The CPU 11a is, for example, a processor.

  A part of various functions realized by the CPU 11a executing the program may be realized by a hardware circuit. In this case, the CPU 11a controls a function executed by the hardware circuit.

The memory 12 includes a volatile memory and a nonvolatile memory. For example, the memory 12 stores a control program and control data in advance. The memory 12 temporarily stores data being processed by the CPU 11a. For example, the memory 12 stores various running application programs based on instructions from the CPU 11a. Further, the memory 12 may store data necessary for executing the application program, an execution result of the application program, and the like.
Further, the memory 12 stores the holding time set by each of the human sensors 101a to 106a.

  The interface 13 is an interface for transmitting and receiving data to and from the lighting controllers 21a and 22a. The interface 13 may support, for example, a LAN connection.

  Various operation instructions are input to the operation unit 14 by an operator of the host device 10a. The operation unit 14 transmits data of an operation instruction input to the operator to the CPU 11a. The operation unit 14 is, for example, a keyboard, a numeric keypad, and a touch panel.

The display unit 15 is a display device that displays various information under the control of the CPU 11a. The display unit 15 is, for example, a liquid crystal monitor. When the operation unit 14 is configured by a touch panel or the like, the display unit 15 may be formed integrally with the operation unit 14.
Further, the higher-level device 10a may have a configuration as necessary in addition to the configuration shown in FIG. 2, or may exclude a specific configuration.

Next, functions realized by the CPU 11a will be described. Here, a function realized by the CPU 11a for controlling the group 100 will be described.
The CPU 11a has a function of acquiring a time during which a person stays in a region where the human sensor 101a detects a person (residence time) based on the human detection signal from the human sensor 101a and the holding time elapsed signal (residence time). Acquisition section).

  For example, the CPU 11a acquires the time when a human detection signal is received from the human sensor 101a. In addition, the CPU 11a obtains the time at which the holding time elapsed signal is received. The CPU 11a calculates the time from receiving the human detection signal to receiving the holding time elapsed signal from both times. The CPU 11a acquires, as the stay time, a time obtained by subtracting the holding time set by the motion sensor 101a from the calculated time. That is, the CPU 11a acquires, as the stay time, a time obtained by subtracting the hold time from the time from receiving the human detection signal to receiving the hold time elapse signal.

Further, the CPU 11a has a function of acquiring an average stay time obtained by averaging the stay times (average stay time acquisition unit).
For example, the CPU 11a acquires the stay time during a predetermined period (for example, one month) and stores the stay time in the memory 12 or the like. The CPU 11a acquires and averages the stay time stored in the memory 12 or the like. The CPU 11a acquires the averaged value as the average stay time.

Further, the CPU 11a has a function of determining the holding time based on the average stay time (determining unit).
For example, the CPU 11a determines the holding time based on a predetermined function. For example, the CPU 11a calculates the holding time by substituting the average stay time into a predetermined function.

Further, the CPU 11a may determine the holding time by integrating a predetermined coefficient of the average stay time. The predetermined coefficient may be one or more or less than one.
Further, the CPU 11a may determine the holding time according to a predetermined table. For example, the CPU 11a may determine the holding time with reference to a table in which the average staying time and the holding time are associated.

  Further, the CPU 11a may receive an input of a parameter for determining a holding time through the operation unit 14. For example, the CPU 11a receives an input of a value used for a function for determining a holding time. In addition, the CPU 11a may receive an input of a coefficient for calculating the holding time by integrating the average staying time. The CPU 11a determines the holding time further based on the input parameters.

Further, the CPU 11a has a function of transmitting the determined holding time to the human sensor 101a (transmission processing unit).
For example, the CPU 11a generates a setting signal indicating the determined holding time. For example, the CPU 11a may generate a bit string indicating the holding time and store the bit string in the setting signal. Further, the CPU 11a may store, in the setting signal, a bit string indicating a setting signal to the human sensor 101a.

  The CPU 11a transmits the generated setting signal to the human sensor 101a via the interface 13. That is, the CPU 11a transmits a setting signal to the human sensor 101a via the illumination controller 21a.

  Note that the CPU 11a performs the same control on the groups 200 to 600. The CPU 11a transmits and receives data to and from each unit of the groups 400 to 600 via the lighting controller 22a.

In addition, the CPU 11a has a function of calculating a total time (total stay time) of the stay times of the persons in the area where the human sensor 101a detects the person during a predetermined period (total stay time acquisition unit).
For example, the CPU 11a calculates the total stay time by adding the acquired stay times.

Further, the CPU 11a has a function of presenting at least one of the average stay time and the total stay time to the outside (presentation processing unit).
For example, the CPU 11a generates a screen indicating at least one of the average stay time and the total stay time, and displays the screen on the display unit 15. In addition, the CPU 11a may transmit a signal indicating at least one of the average stay time and the total stay time to the external device.

Next, an operation example of the CPU 11a will be described. Here, an operation example in which the CPU 11a sets the holding time for the human sensor 101a will be described.
FIG. 3 is a flowchart for explaining an operation example of the CPU 11a.

  First, the CPU 11a acquires a stay time in an area where the human sensor 101a detects a person (S11). For example, the CPU 11a acquires a stay time in a predetermined period.

  When the stay time is acquired, the CPU 11a calculates an average stay time of the acquired stay time (S12). After calculating the average stay time, the CPU 11a determines a holding time based on the calculated average stay time (S13).

  When the holding time is determined, the CPU 11a transmits a setting signal indicating the determined holding time to the human sensor 101a (S14). When the setting signal is transmitted to the human sensor 101a, the CPU 11a ends the operation.

The human sensor 101a receives a setting signal from the CPU 11a. The human presence sensor 101a sets a holding time indicated by the received setting signal.
Further, the CPU 11a similarly sets the holding time for the human sensors 102a to 106a.

  Note that the CPU 11a may realize the function of the lighting controller 21a or 22a. When the CPU 11a realizes the function of the lighting controller 21a or 22a, the lighting system 1a may not include the lighting controller 21a or 22a. When the CPU 11a realizes the function of the illumination controller 21a or 22a, the host device 10a may be directly connected to the human sensors 101a to 106a and the illuminations 201 to 206.

  The lighting may belong to a plurality of groups in an overlapping manner. For example, when the predetermined lighting belongs to a plurality of groups, the CPU 11a determines the average time of the average stay time of each group (for example, the average time of the average stay time of the group 100 and the average stay time of the group 200). The holding time of the illumination may be determined based on the illumination.

The lighting system configured as described above calculates an average stay time during which a person stays in an area where the motion sensor detects a person. The lighting system determines a holding time based on the average stay time, and sets the determined holding time in the motion sensor. Therefore, in the lighting system, the host device can set the holding time according to the average stay time. As a result, the lighting system can effectively set the holding time.
(2nd Embodiment)
Next, a second embodiment will be described.
The lighting system according to the second embodiment is different from the lighting system according to the first embodiment in that a human sensor outputs a control signal indicating that a person has exited a predetermined area.
Therefore, the same reference numerals are given to the other points, and the detailed description is omitted.

FIG. 1 shows a configuration example of a lighting system 1b according to the second embodiment.
As shown in FIG. 1, the lighting system 1b includes a higher-level device 10b, lighting controllers 21b and 22b, human sensors 101b to 106b, lights 201 to 206, and the like. The host device 10b is communicably connected to the lighting controllers 21b and 22b. The lighting controller 21b is communicably connected to the human sensors 101b to 103b and the lightings 201 to 203. The lighting controller 22b is communicably connected to the human sensors 104b to 106b and the lights 204 to 206. The group 100 includes a human sensor 101b and a light 201. Similarly, the groups 200 to 600 include the motion sensor 102b and the light 202 and the motion sensor 106b and the light 206, respectively.
The lighting controllers 21b and 22b have the same configuration as the lighting controllers 21a and 22b, and thus the description is omitted.

The human sensor 101b has the following functions in addition to the functions of the human sensor 101a.
When detecting that a person has left the predetermined area, the human sensor 101b transmits a control signal (a person leaving signal) indicating that the person has left the predetermined area to the lighting controller 21a. For example, the human sensor 101b transmits a person leaving signal to the lighting controller 21a when the detection of the presence of a person in a predetermined area stops detecting the person.
Note that the lighting controller 21a transmits a person leaving signal to the host device 10b.

Next, the host device 10b will be described.
FIG. 2 is a diagram illustrating a configuration example of the higher-level device 10b.
As shown in FIG. 2, the host device 10b includes a CPU 11b, a memory 12, an interface 13, an operation unit 14, a display unit 15, and the like.

The CPU 11b has a function of controlling the operation of the host device 10b as a whole.
Next, functions realized by the CPU 11b will be described.
The CPU 11b has a function of acquiring a time during which a person stays in a region where the human sensor 101a detects a person (residence time) based on the human detection signal and the human departure signal from the human sensor 101b.

  For example, the CPU 11b acquires the time when a human detection signal is received from the human sensor 101a. Further, the CPU 11b acquires the time at which the person leaving signal is received. The CPU 11b calculates the time from the reception of the human detection signal to the reception of the human departure signal from both times. The CPU 11b acquires the calculated time as a stay time.

In addition, the CPU 11b has a function of calculating an average stay time by averaging the stay time, a function of determining a holding time based on the average stay time, a function of transmitting the determined holding time to the human sensor 101b, and a function of calculating the total stay time. It has a function of calculating and a function of presenting at least one of the average stay time and the total stay time to the outside. Each function is the same as that of the first embodiment, and the description is omitted.
The operation example of the CPU 11b is the same as the operation example of the CPU 11a, and thus the description is omitted.

  The lighting system configured as described above transmits a person leaving signal from the human sensor to the host device. Therefore, the lighting system acquires the timing at which the person has left the predetermined area based on the person leaving signal. Further, the lighting system calculates the time from the human detection signal to the human departure signal to acquire the stay time. As a result, the lighting system can acquire the stay time without subtracting the holding time.

The lighting system also transmits a human detection signal to the host device even when a person enters a predetermined area during the holding time. Therefore, the lighting system can acquire the staying time of each person even when the person enters the predetermined area during the holding time. Therefore, the lighting system can calculate a more accurate average stay time. As a result, the lighting system can set the holding time more effectively.
(Third embodiment)
Next, a third embodiment will be described.
The lighting system according to the third embodiment is different from the lighting system according to the second embodiment in that a host device sets a holding time in a lighting controller.
Therefore, the same reference numerals are given to the other points, and the detailed description is omitted.

FIG. 1 shows a configuration example of a lighting system 1c according to a third embodiment.
As shown in FIG. 1, the lighting system 1c includes a host device 10c, lighting controllers 21c and 22c, motion sensors 101c to 106c, lights 201 to 206, and the like. The host device 10c is communicably connected to the lighting controllers 21c and 22c. The lighting controller 21c is communicably connected to the human sensors 101c to 10cb and the lightings 201 to 203. The lighting controller 22c is communicably connected to the motion sensors 104c to 106c and the lights 204 to 206. The group 100 includes a human sensor 101c and a light 201. Similarly, the groups 200 to 600 include the motion sensor 102c and the light 202 and the motion sensor 106c and the light 206, respectively.

First, the lighting controller 21c will be described.
The lighting controller 21c has a function of setting a holding time based on a setting signal from the host device 10c. The setting signal is a signal that causes the lighting controller 21c to set the holding time. The setting signal indicates a holding time.

For example, when receiving the setting signal, the lighting controller 21c stores the holding time indicated by the setting signal in an internal memory or the like.
The lighting controller 21c sets a holding time for each of the human sensors 101c to 103c. For example, the setting signal may be one for setting a holding time corresponding to one of the human sensors 101c to 103c. Further, the setting signal may be a signal for setting each holding time corresponding to the motion sensors 101c to 103c.

  The illumination controller 21c has a function of turning on or off the illumination based on a control signal from a human sensor or the like. Here, control of the human sensor 101c and the lighting 201 of the group 100 will be described.

  The lighting controller 21c waits until a human detection signal is received from the human sensor 101c. When receiving the human detection signal from the human sensor 101c, the illumination controller 21c transmits a control signal for turning on the illumination to the illumination 201.

  When the control signal is transmitted to the lighting 201, the lighting controller 21c waits until receiving a person leaving signal from the human sensor 101c. The illumination controller 21c starts a timer when receiving the person leaving signal from the human sensor 101c.

  When the timer is started, the lighting controller 21c waits until the time measured by the timer reaches the holding time (holding time α) corresponding to the motion sensor 101c. For example, the lighting controller 21c acquires the holding time α from an internal memory or the like and compares it with the time measured by the timer.

When the time measured by the timer reaches the holding time α, the lighting controller 21c transmits a control signal to turn off the lighting to the lighting 201.
The lighting controller 21c has a function of transmitting a control signal from the human sensor 101c to the host device 10c.

Note that the lighting controller 21c may further perform control necessary for controlling the motion sensor 101c or the lighting 201. The lighting controller 21c performs the same control on the groups 200 and 300.
In addition, since the lighting controller 22c realizes the same function as the lighting controller 21c, the description of the function of the lighting controller 22c is omitted.
The human sensor 101c does not need to transmit the holding time elapsed signal to the illumination controller 21c. The same applies to the human sensors 102c to 106c.

Next, the host device 10c will be described.
FIG. 2 is a diagram illustrating a configuration example of the higher-level device 10c.
As shown in FIG. 2, the host device 10c includes a CPU 11c, a memory 12, an interface 13, an operation unit 14, a display unit 15, and the like.
The CPU 11c has a function of controlling the operation of the host device 10c as a whole.

  The CPU 11c has a function of acquiring a time during which a person stays in an area where the human sensor 101a detects a person (residence time) based on a control signal from the human sensor 101c. The method by which the CPU 11c acquires the staying time is the same as the operation of the CPU 11a of the first or second embodiment, and thus the description is omitted. When the human sensor 101c does not transmit the holding time elapsed signal, the CPU 11c acquires the stay time similarly to the operation of the CPU 11b of the second embodiment.

  The CPU 11c has a function of calculating an average stay time by averaging the stay times, and a function of determining a holding time based on the average stay time. Each function is the same as that of the first embodiment, and the description is omitted.

Further, the CPU 11c has a function of transmitting the determined holding time to the illumination controller 21a.
For example, the CPU 11c generates a setting signal indicating the determined holding time. For example, the CPU 11c may generate a bit string indicating the holding time and store the bit string in the setting signal. Further, the CPU 11c may store a bit string or the like indicating that the signal is a setting signal to the lighting controller 21c in the setting signal.

The CPU 11c transmits the generated setting signal to the lighting controller 21c through the interface 13.
The CPU 11c has a function of calculating the total stay time and a function of presenting at least one of the average stay time and the total stay time to the outside. Each function is the same as that of the first embodiment, and the description is omitted.

Next, an operation example of the CPU 11c will be described. Here, an operation example in which the CPU 11c sets the holding time for the illumination controller 21c will be described. The CPU 11c sets a holding time corresponding to the motion sensor 101c.
FIG. 4 is a flowchart for explaining an operation example of the CPU 11c.

Steps S11 to S13 are the same as those in the first embodiment, and a description thereof will not be repeated.
When the holding time is determined (S13), the CPU 11c transmits a setting signal indicating the determined holding time to the illumination controller 21c (S21). When the setting signal is transmitted to the illumination controller 21c, the CPU 11c ends the operation.

The lighting controller 21c receives a setting signal from the CPU 11c. The lighting controller 21c sets the holding time indicated by the received setting signal.
Similarly, the CPU 11c sets the holding time corresponding to the motion sensors 102c and 103c in the illumination controller 21c. Further, the CPU 11c sets the holding time corresponding to the motion sensors 104c to 106c in the illumination controller 22c.

  In the lighting system configured as described above, the holding time is set in the lighting controller by the host device. The lighting controller turns off the lighting when the holding time elapses after receiving the person leaving signal from the human sensor. As a result, the lighting system can appropriately control the lighting without using the holding time elapsed signal from the human sensor.

Although several embodiments of the present invention have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These new embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.
Hereinafter, the inventions described in the claims at the beginning of the present application are additionally described.
[C1]
A communication unit that communicates with a human sensor that outputs a signal corresponding to a human detection result;
A stay time acquisition unit that acquires a stay time in which a person stays based on a signal from the human sensor through the communication unit;
An average stay time acquisition unit that acquires an average stay time obtained by averaging the stay times,
Based on the average stay time, a determination unit that determines a holding time to hold the lighting on state after the person is no longer detected,
A lighting control device comprising:
[C2]
The human sensor outputs a human detection signal indicating that a person has been detected in a predetermined area and a holding time elapse signal indicating that a holding time has elapsed since the person left the predetermined area. ,
The stay time obtaining unit obtains, as the stay time, a time obtained by subtracting the hold time from a time from receiving the human detection signal to receiving the hold time elapse signal,
The lighting control device according to C1.
[C3]
The human sensor outputs a human detection signal indicating that a human has been detected, and a human departure signal indicating that a human has left,
The stay time acquisition unit acquires a time from receiving the person detection signal to receiving the person leaving signal as the stay time,
The lighting control device according to C1.
[C4]
The communication unit, comprising a transmission processing unit that transmits a setting signal to set the holding time determined by the determination unit to the human sensor,
The lighting control device according to any one of C1 to C3.
[C5]
Comprising a presentation processing unit for presenting the average stay time,
The lighting control device according to any one of C1 to C4.
[C6]
In a predetermined period, comprising a total stay time acquisition unit that obtains a total stay time that is the total time the person stayed in the predetermined area,
The presentation processing unit presents the total stay time,
The lighting control device according to C5.
[C7]
A lighting system including a lighting control device, a human sensor, and lighting,
The lighting control device,
A communication unit that communicates with the human sensor;
A stay time acquisition unit that acquires a stay time in which a person stays based on a signal from the human sensor through the communication unit;
An average stay time acquisition unit that acquires an average stay time obtained by averaging the stay times,
Based on the average stay time, a determination unit that determines a holding time to hold the lighting on state after the person is no longer detected,
With
The human sensor outputs a signal corresponding to a detection result of a person to the lighting control device,
The lighting is turned on when the motion sensor detects that a person is staying, and is turned off when a holding time has elapsed after the motion sensor has detected that the person has left.
Lighting system.
[C8]
The lighting control device,
The communication unit, comprising a transmission processing unit that transmits a setting signal for setting the holding time determined by the determination unit to the human sensor,
The human sensor sets the holding time based on the setting signal, and transmits a holding time elapsed signal when the holding time elapses after the person leaves,
The lighting is turned off when the motion sensor transmits the holding time elapsed signal,
The lighting system according to C7.
[C9]
Based on a signal from a human sensor that outputs a signal corresponding to a detection result of a person, a stay time at which the person stays is acquired,
Obtain an average stay time by averaging the stay time,
Based on the average staying time, determine a holding time to hold the lighting on state after the person is no longer detected,
Lighting control method.

  1a to 1c: lighting system, 10a to 10c: host device, 11a to 11c: CPU, 21a to 21c: lighting controller, 22a to 22c: lighting controller, 101a to 106a: human sensor, 101b to 106b: human sensor, 101c to 106c: human sensor, 201 to 206: illumination, 100 to 600: group.

Claims (7)

A communication unit that communicates with a human sensor that outputs a signal corresponding to a human detection result;
A stay time acquisition unit that acquires a stay time in which a person stays based on a signal from the human sensor through the communication unit;
An average stay time acquisition unit that acquires an average stay time obtained by averaging the stay times,
Based on the average stay time, a determination unit that determines a holding time to hold the lighting on state after the person is no longer detected,
Through the communication unit, a transmission processing unit that transmits to the human sensor a setting signal that sets the holding time as a time from when a person is no longer detected until a holding time elapsed signal is transmitted,
A lighting control device comprising: The human sensor is output and human detection signal indicating the detection of the human in a predetermined area, and the retention time elapse signal indicating that a person from the predetermined region has elapsed the holding time from leave, the And
The stay time obtaining unit obtains, as the stay time, a time obtained by subtracting the hold time from a time from receiving the human detection signal to receiving the hold time elapse signal,
The lighting control device according to claim 1. The human sensor outputs a human detection signal indicating that a human has been detected, and a human departure signal indicating that a human has left,
The stay time acquisition unit acquires a time from receiving the person detection signal to receiving the person leaving signal as the stay time,
The lighting control device according to claim 1. Comprising a presentation processing unit for presenting the average stay time,
Lighting control device according to any one of claims 1 to 3. In a predetermined period, comprising a total stay time acquisition unit that obtains a total stay time that is the total time the person stayed in the predetermined area,
The presentation processing unit presents the total stay time,
The lighting control device according to claim 4 . A lighting system including a lighting control device, a human sensor, and lighting,
The lighting control device,
A communication unit that communicates with the human sensor;
A stay time acquisition unit that acquires a stay time in which a person stays based on a signal from the human sensor through the communication unit;
An average stay time acquisition unit that acquires an average stay time obtained by averaging the stay times,
Based on the average stay time, a determination unit that determines a holding time to hold the lighting on state after the person is no longer detected,
Through the communication unit, a transmission processing unit that transmits to the human sensor a setting signal that sets the holding time as a time from when a person is no longer detected until a holding time elapsed signal is transmitted,
With
The human sensor outputs a signal corresponding to a detection result of a person to the lighting control device,
The illumination, upon detecting that the human sensor to stay person turns on, turns off when the human sensor has passed the holding time after detecting that a person has vacated,
The human sensor sets the holding time according to the setting signal, and transmits a holding time elapse signal indicating that the holding time has elapsed since the person left the predetermined area.
The lighting is turned off when the motion sensor transmits the hold time elapsed signal,
Lighting system. Based on a signal from a human sensor that outputs a signal corresponding to a detection result of a person, a stay time at which the person stays is acquired,
Obtain an average stay time by averaging the stay time,
Based on the average stay time, determine the holding time to keep the lighting on state after the person is no longer detected,
A setting signal for setting the holding time as a time until a holding time elapse signal is transmitted after the person is no longer detected is transmitted to the human sensor.
Lighting control method.