JP6493951B2 - Lighting control apparatus, lighting system, lighting control method and program - Google Patents

Description

  The present invention relates to an illumination control device, an illumination system, an illumination control method, and a program.

  LED (Light Emitting Diode) illumination can be dimmed and can be used with optimum brightness (illuminance). In recent years, LED illumination is provided with an illuminance sensor, so that the illuminance in the room can be kept constant by adjusting the light emission intensity in accordance with the change in external light.

  The optimum illuminance of the LED illumination varies depending on the environment of the installation location. Therefore, in order to efficiently use the LED illumination, it is necessary to perform dimming control in advance according to the environment of the installation location. For LED lighting that does not have an external interface, when changing the dimming control value, for example, the control box attached to the ceiling is removed, the cover is opened, and the firmware is rewritten. Therefore, a large-scale construction is required to change the dimming control value, and the repair time and cost increase. For example, as an example where the dimming control value needs to be changed, when the user does not have enough brightness at the initially set illuminance and wants to optimize the illuminance (increase the dimming control value) by himself / herself Is assumed.

  As a method for easily performing this operation, for example, an LED illumination in which a wireless communication module or an infrared light receiving module is mounted in a control box or the like and the dimming control value can be adjusted by remote control with a remote controller has been proposed.

JP 2013-239359 A

  However, the above-described wireless module is expensive and has a problem of mounting space. In addition, in the case of infrared remote control communication, although it is not as expensive as a wireless module, it is necessary to separately develop a remote control as a transmitter. In addition, LED lighting dimming control values are not frequently changed on a daily basis, and it is not only in terms of development costs that a remote controller is provided only for dimming control, but also on the user side ( Storage, management) and cost burden.

  An object of the present invention is to provide an illumination control device, an illumination system, an illumination control method, and a program that are made in view of the above-described problems and that can reduce the burden on the user for dimming control at low cost. It is in.

  In order to solve the above-described problem, one embodiment of the present invention provides an illumination source based on an illuminance sensor capable of detecting ambient illuminance, an illuminance detected by the illuminance sensor, and a prescribed dimming control value. A light emission intensity determining unit that determines the light emission intensity; and a light control value changing unit that changes the light control value when the illuminance sensor detects illuminance corresponding to a predetermined irradiation condition defined in advance; It is an illumination control apparatus provided with.

  Another embodiment of the present invention is an illumination system including the illumination control device described above and the light emission source that emits light with light emission intensity determined by the illumination control device.

  According to another aspect of the present invention, there is provided a step of determining light emission intensity in a light source based on illuminance detected by an illuminance sensor capable of detecting ambient illuminance and a prescribed dimming control value; Is a lighting control method comprising: changing the dimming control value when illuminance corresponding to a predetermined irradiation condition defined in advance is detected.

  Another embodiment of the present invention is a lighting control device including an illuminance sensor that can detect ambient illuminance, based on the illuminance detected by the illuminance sensor and a prescribed dimming control value. Luminescence intensity determining means for determining the luminescence intensity in the light source, functioning as control value changing means for changing the dimming control value when the illuminance sensor detects illuminance corresponding to a predetermined irradiation condition defined in advance It is a program.

  According to the above-described illumination control device, illumination system, illumination control method, and program, the burden on the user for light control can be reduced at low cost.

It is a figure which shows the illumination control apparatus which concerns on 1st Embodiment. It is a figure which shows the function structure of the illumination system which concerns on 1st Embodiment. It is a 1st figure explaining the function of the dimming control value change part which concerns on 1st Embodiment. It is a 2nd figure explaining the function of the light control value change part which concerns on 1st Embodiment. The mode that an operator performs light control work with respect to the illumination system which concerns on 1st Embodiment is shown. It is a 3rd figure explaining the function of the dimming control value change part which concerns on 1st Embodiment. It is a 4th figure explaining the function of the dimming control value change part which concerns on 1st Embodiment. It is a figure which shows the processing flow of CPU which concerns on 1st Embodiment.

<First Embodiment>
Hereinafter, a first embodiment will be described in detail with reference to the drawings.
FIG. 1 is a diagram illustrating a functional configuration of the illumination control apparatus according to the first embodiment.
The illumination control device 10 shown in FIG. 1 is a device that controls the light emission intensity of LED illumination that is a light emission source. As shown in FIG. 1, the illumination control device 10 emits light from a light source based on an illuminance sensor 110 that can detect ambient illuminance, an illuminance detected by the illuminance sensor 110, and a prescribed dimming control value. A light emission intensity determining unit 101 that determines the intensity; a light control value changing unit 102 that changes the light control value when the illuminance sensor 110 detects illuminance corresponding to a predetermined irradiation condition defined in advance; It has.

FIG. 2 is a diagram illustrating a functional configuration of the illumination system according to the first embodiment.
As shown in FIG. 2, the illumination system 1 includes an illumination control device 10, a power supply unit 11, and an LED illumination 12 (light emission source).
The power supply unit 11 receives input of predetermined power (AC power supply 100 V) from a power supply system previously laid in a building or the like, and supplies power to the lighting control device 10 and the LED lighting 12.
The LED illumination 12 receives a control signal output from the illumination control device 10 via the power supply unit 11, and emits light with a light emission intensity corresponding to the control signal.

Next, the functional configuration of the illumination control device 10 will be described.
As illustrated in FIG. 2, the illumination control device 10 includes a CPU (Central Processing Unit) 100, an illuminance sensor 110, an LED lamp 120 (notification unit), and a dimming control value holding unit 130.
The CPU 100 governs the overall operation of the illumination control device 10. The CPU 100 according to the present embodiment executes operations according to two types of operation modes (a sensor mode and a remote control mode described later).
The illuminance sensor 110 detects illuminance, which is the degree of ambient brightness, and outputs a detection result (detected illuminance) to the CPU 100. The illuminance sensor 110 is a sensor provided for the purpose of realizing an automatic light adjustment (automatic adjustment of illuminance) function of the illumination system 1.
The LED lamp 120 functions as a notification unit for notifying the user of switching of the operation mode (sensor mode or remote control mode). In addition, the said notification part is not limited to the aspect as the LED lamp 120, For example, the aspect notified to a user based on an audio | voice output may be sufficient.
The dimming control value holding unit 130 is a storage area for storing the dimming control value at the present time. The dimming control value holding unit 130 is implemented by firmware, for example.

  The CPU 100 functions as the light emission intensity determination unit 101 and the dimming control value change unit 102 by reading a predetermined program.

The light emission intensity determination unit 101 sequentially receives an illuminance detection value indicating ambient illuminance detected by the illuminance sensor 110 and refers to a dimming control value held in advance in the dimming control value holding unit 130. Then, the light emission intensity determination unit 101 determines the light emission intensity of the LED illumination 12 so that the illuminance detection value output from the illuminance sensor 110 matches the dimming control value held in the dimming control value holding unit 130. The light emission intensity determination unit 101 outputs a control signal toward the LED illumination 12 so that the light emitted from the LED illumination 12 has the determined light emission intensity.
For example, when the room is sufficiently bright due to external light incident from a window or the like, the light emission intensity determining unit 101 controls the light emission intensity of the LED illumination 12 to be relatively low. On the other hand, when there is almost no external light and the room becomes dark without irradiation by the LED illumination 12, the emission intensity determining unit 101 controls the emission intensity of the LED illumination 12 to be relatively high. To do. Thus, the operation mode in which the CPU 100 controls the light emission intensity of the LED illumination 12 based on the detected illuminance value of the illuminance sensor 110 and the prescribed dimming control value is referred to as “sensor mode”.

  The dimming control value changing unit 102 sequentially receives the illuminance detection values detected by the illuminance sensor 110, and holds the dimming control value holding unit 130 when the illuminance detection value satisfies a predetermined irradiation condition. The process which changes the light control value currently performed is performed. Thus, the operation mode in which the CPU 100 (the dimming control value changing unit 102) changes the dimming control value is referred to as a “remote control mode”.

FIG. 3 is a first diagram illustrating the function of the dimming control value changing unit according to the first embodiment.
FIG. 3 schematically shows a range of illuminance detected by the illuminance sensor 110. Here, the dimming control value changing unit 102 stores a predetermined determination illuminance threshold Lth. This determination illuminance threshold Lth is defined by the maximum illuminance that is assumed to be detected by receiving external light (environmental light incident from a window or the like).
Here, it is assumed that the illumination system 1 according to the present embodiment is installed on a ceiling in a general building or school. When the illumination system 1 is installed on an indoor ceiling, the illuminance sensor 110 of the illumination system 1 does not directly receive sunlight, but receives reflected light reflected on the floor surface or the like. In this case, for example, it is assumed that the illuminance sensor 110 does not exceed 1000 lx only by receiving external light. Therefore, in the present embodiment, the dimming control value changing unit 102 stores the determination illuminance threshold Lth = 1000 lx in advance. The determination illuminance threshold Lth is thus defined based on the maximum illuminance that is assumed to be detected by receiving ambient light.

  The dimming control value changing unit 102 does not perform a special operation while an illuminance lower than the determination illuminance threshold Lth is detected. That is, when the illuminance sensor 110 merely receives external light, the CPU 100 operates in the sensor mode and controls the light emission intensity of the LED illumination 12 so that the detected illuminance is constant.

On the other hand, the dimming control value changing unit 102 according to the present embodiment performs dimming when detecting an illuminance that exceeds the determination illuminance threshold Lth through the illuminance sensor 110 (and coincides with a temporal change pattern described later). The operation for changing the control value is started (that is, the operation in the remote control mode is started).
Hereinafter, the operation of the dimming control value changing unit 102 will be described more specifically.

FIG. 4 is a second diagram illustrating the function of the dimming control value changing unit according to the first embodiment.
In FIG. 4, the horizontal axis indicates time, and the vertical axis indicates detected illuminance detected by the illuminance sensor 110. Here, the dimming control value changing unit 102 according to the present embodiment changes the dimming control value when the detected illuminance exceeding the determination illuminance threshold Lth matches the predefined temporal change pattern P1. To start.

For example, the dimming control value changing unit 102 predefines a change pattern P1 of the detected illuminance with time as shown in FIG. Specifically, the temporal change pattern P1 is similar to the first irradiation period q1 in which continuous irradiation exceeding 1000 lx (determination illuminance threshold Lth) is performed from a certain time t0 to a time t1, and from the certain time t2 to the time t3. It is defined by a second irradiation period q3 in which continuous irradiation is performed and a non-irradiation period q2 in which the period from time t1 to time t2 is 1000 lx or less.
Here, the first irradiation period q1 and the non-irradiation period q2 are defined, for example, as 5 seconds or more and less than 10 seconds, and the second irradiation feedback q3 is defined as, for example, 1 second or more and less than 3 seconds.
That is, the CPU 100 transitions from the sensor mode to the remote control mode when receiving illuminance that matches the temporal change pattern P1 defined based on the first irradiation period q1, the second irradiation period q3, and the non-irradiation period q2. . When transitioning to the remote control mode, the CPU 100 turns on the LED lamp 120 to notify the operator that the operation is in the remote control mode.

FIG. 5 shows a state where an operator performs dimming work on the illumination system according to the first embodiment.
As shown in FIG. 5, the worker G performs light irradiation toward the illuminance sensor 110 attached to the ceiling using a predetermined portable lighting fixture g1. Here, the portable lighting fixture g1 may be, for example, a portable terminal device (such as a smartphone) owned by the worker G itself. Even if it is the illumination function attached to a general smart phone, it is possible to irradiate light exceeding 1000 lx by making the light emission source of the smart phone close to the illuminance sensor 110. The portable lighting fixture g1 may be in any form as long as it is a device such as a flashlight that can project light having an illuminance exceeding the determination illuminance threshold Lth (1000 lx) in the illuminance sensor 110.

The worker G performs ON / OFF operation of light irradiation at a timing according to the temporal change pattern P1 while bringing the light source of the portable lighting fixture g1 close to the illuminance sensor 110. In the present embodiment, the operator G operates the portable lighting fixture g1 to turn on the light irradiation toward the illuminance sensor 110 for 5 to 10 seconds (corresponding to the first irradiation period q1 ( (See FIG. 4)). Thereafter, the worker G turns off the light irradiation and waits for 5 to 10 seconds as it is (corresponding to the non-irradiation period q2). After that, the worker G continues the light irradiation ON again for 1 to 3 seconds (corresponding to the second irradiation period q3). At this time, the dimming control value changing unit 102 detects that the change pattern of the illuminance detection value received through the illuminance sensor 110 matches the predefined temporal change pattern P1 (see FIG. 4). The process for changing the dimming control value is started.
The worker G can recognize that the operation has shifted to the remote control mode as intended by his / her operation by visually confirming the lighting of the LED lamp 120.

FIG. 6 is a third diagram illustrating the function of the dimming control value changing unit according to the first embodiment.
In FIG. 6A, the horizontal axis indicates time, and the vertical axis indicates the dimming control value set by the dimming control value changing unit 102.
When the dimming control value changing unit 102 according to the present embodiment detects the first illuminance corresponding to a predetermined irradiation condition (temporal change pattern P1) defined in advance at time t3, FIG. As shown, the dimming control value is changed over time. Specifically, as shown in FIG. 6A, the dimming control value changing unit 102 gradually increases the dimming control value over time from the time t3 when the remote control mode is started. In the present embodiment, the dimming control value changing unit 102 increases the dimming control value in a stepped manner from the minimum level (dimming control value = 350 lx) every elapse of a certain time Δt. Then, after reaching the maximum level (dimming control value = 700 lx), the process returns to the minimum level, and the process of gradually increasing the dimming control value every time the predetermined time Δt elapses is repeated. In this way, the dimming control value changing unit 102 repeats the process of gradually changing the dimming control value from the minimum level to the maximum level for every fixed period (period T).

In FIG. 6B, the horizontal axis indicates time, and the vertical axis indicates detected illuminance detected by the illuminance sensor 110.
While the dimming control value changing unit 102 repeats the dimming control value changing process as shown in FIG. 6A, the worker G (see FIG. 5) performs dimming that sequentially changes at a desired timing. A signal (decision signal q4) for determining the control value is input. For example, the worker G irradiates light of illuminance exceeding the determination illuminance threshold Lth (= 1000 lx) for one pulse (for example, about 1 second) at time t5 when the dimming control value reaches the maximum level (700 lx). The dimming control value changing unit 102 holds the dimming control value at time t5 in the dimming control value holding unit 130 when detecting the illuminance based on the one-pulse signal (decision signal q4) exceeding the determination illuminance threshold Lth. That is, the dimming control value changing unit 102 sets the dimming control value at the time when the second illuminance (decision signal q4) corresponding to the predetermined irradiation condition defined in advance is detected as a new dimming control value. To do.

  The worker G arranges a separately prepared illuminance sensor near the LED illumination 12 and observes the actual illuminance of the LED illumination 12 in order to determine a dimming control value that changes sequentially as a desired value. However, the determination signal q4 may be input. For example, the worker G directs the light that makes the determination signal q4 to the illuminance sensor 110 when the illuminance observed by the separately installed illuminance sensor becomes a desired value (for example, 700 lx) by irradiation of the LED illumination 12. To light up.

FIG. 7 is a fourth diagram illustrating the function of the dimming control value changing unit according to the first embodiment.
In FIG. 7, the horizontal axis indicates time, and the vertical axis indicates detected illuminance detected by the illuminance sensor 110. The dimming control value changing unit 102 according to the present embodiment ends the operation of changing the dimming control value when the detected illuminance exceeding the determination illuminance threshold Lth matches the predetermined temporal change pattern P2. .

For example, the dimming control value changing unit 102 predefines a temporal change pattern P2 of the detected illuminance as shown in FIG. Specifically, the temporal change pattern P2 is the same as the temporal change pattern P1 (see FIG. 4), in which continuous irradiation exceeding 1000 lx (determination illuminance threshold Lth) is performed from time t6 to time t7. One irradiation period q5, a second irradiation period q7 in which similar continuous irradiation is performed from a certain time t8 to time t9, and a non-irradiation period q6 in which the period from time t7 to time t8 is 1000 lx or less.
Here, the lengths of time defined as the first irradiation period q5, the second irradiation time q7, and the non-irradiation period q6 are the first irradiation period q1, the second irradiation time q3, and the non-irradiation period in the temporal change pattern P1. It is the same as q5.
That is, when the CPU 100 receives illuminance that matches the temporal change pattern P2 defined based on the first irradiation period q5, the second irradiation period q7, and the non-irradiation period q6, the CPU 100 transitions from the remote control mode to the sensor mode again. To do. When transitioning to the sensor mode, the CPU 100 turns off the LED lamp 120 to notify the operator that the sensor mode is operating.

  The operator G sets the dimming control value to a desired value by inputting the determination signal q4 (see FIG. 6), and then performs an input operation of the temporal change pattern P2, thereby allowing the lighting control device 10 to Return the operation mode from the remote control mode to the sensor mode. Thereby, the light emission intensity determination unit 101 determines the light emission intensity of the LED illumination 12 while referring to the newly set dimming control value.

FIG. 8 is a diagram illustrating a processing flow of the CPU according to the first embodiment.
Next, the processing flow of the CPU 100 according to the present embodiment will be described step by step with reference to FIG. The processing flow shown in FIG. 8 shows an example of operating in the sensor mode in step S01.
CPU 100 sets '0' to the remote control mode flag and the state monitoring timer flag in the internal memory (step S01). Here, the “remote control mode flag” is a flag indicating whether or not the CPU 100 is operating in the remote control mode (sensor mode when “0”, remote control mode when “1”). “Status monitor timer flag” means whether or not the CPU 100 is operating a status monitor timer for performing a process of switching the operation mode after a predetermined time has elapsed (when “0”, the status monitor timer is This flag indicates non-operation and when the state monitoring timer is “1”. The “state monitoring timer” is a timer used for processing for switching the operation mode when, for example, an operation by the worker G is not continuously detected for a predetermined time.

Next, the dimming control value changing unit 102 is a predetermined pattern in which the illuminance detected through the illuminance sensor 110 exceeds 1000 lx (determination illuminance threshold Lth) (a temporal change pattern P1 (see FIG. 4)). It is determined whether or not (step S02). When the illuminance sensor 110 does not detect an illuminance change pattern that matches the temporal change pattern P1 (step S02: N), the dimming control value changing unit 102 sets the state monitoring timer flag to “1” and the predetermined time. It is determined whether or not it has elapsed (whether or not the count for a predetermined time has “finished”) (step S03). When operating in the sensor mode after step S01, since the state monitoring timer flag is “0” (step S03: N), the CPU 100 continues to operate in the sensor mode by repeating steps S02 to S03.
In the sensor mode, the CPU 100 (light emission intensity determining unit 101) determines the light emission intensity of the LED illumination 12 according to the light control value specified in advance in the light control value holding unit 130. Specifically, the light emission intensity determination unit 101 determines the light emission intensity of the LED illumination 12 so that the illuminance detected through the illuminance sensor 110 matches the dimming control value, and outputs a control signal indicating the determined light emission intensity. Output toward the LED illumination 12.

On the other hand, when an illuminance change pattern that matches the temporal change pattern P1 is detected through the illuminance sensor 110 (step S02: Y), the CPU 100 determines whether or not the remote control mode flag is currently “0” (step S02). S04). When the remote control mode flag is “0” (step S04: Y), the CPU 100 sets the remote control mode flag to “1” and switches the operation mode from the sensor mode to the remote control mode (step S05). At this time, the CPU 100 turns on the LED lamp 120 to notify the worker G that the sensor mode has changed to the remote control mode.
At the same time as the transition to the remote control mode, the CPU 100 sets “1” to the state monitoring timer flag and starts the elapsed time counting process by the state monitoring timer (step S06).

The CPU 100 determines whether or not a predetermined time has elapsed since the start of the state monitoring timer (step S07). The CPU 100 repeats the operation in the remote control mode (steps S08 and S09 described later) while the state monitoring timer does not pass the predetermined time (step S07: N).
In the remote control mode, the dimming control value changing unit 102 performs a process of gradually changing the dimming control value over time (see FIG. 6A) as the dimming control value changing process (step S08). At this time, the dimming control value changing unit 102 determines whether or not irradiation (light that makes the determination signal q4) exceeding the determination illuminance threshold Lth by the worker G has been detected (step S09). When the determination signal q4 is not detected (step S09: N), the dimming control value changing unit 102 continues to change the dimming control value over time shown in FIG. 6A through step S08.
When the determination signal q4 is detected (step S09: Y), the dimming control value changing unit 102 writes the dimming control value at that time in the dimming control value holding unit 130 and sets it as a new dimming control value. (Step S10).
When a predetermined time has elapsed without detecting the determination signal q4 in the remote control mode (step S07: Y), the CPU 100 performs a process for forcibly returning to the sensor mode (steps S11 and S12 described later).

When a new dimming control value is set in step S10, the CPU 100 returns to the processes in steps S02 to S03. Specifically, in step S02, the dimming control value changing unit 102 determines whether or not the illuminance change pattern detected through the illuminance sensor 110 matches the temporal change pattern P2.
When the illuminance change pattern that matches the temporal change pattern P2 is not detected (step S02: N), in step S03, the CPU 100 has passed a predetermined time that is predetermined by the state monitoring timer. Or not (whether or not the count for a predetermined time is “finished”).
If the predetermined time has not elapsed since the start of the operation of the state monitoring timer (step S03: N), the process waits until the temporal change pattern P2 is detected in step S02.
When the predetermined time has passed without detecting the temporal change pattern P2 (step S03: Y), the CPU 100 stops the operation of the state monitoring timer and initializes the count time (step S11). Subsequently, the CPU 100 sets “0” in the remote control mode flag and the state monitoring timer flag, and transitions to the sensor mode (step S12).

  When the illuminance change pattern that matches the temporal change pattern P2 is detected (step S02: Y), the CPU 100 determines whether or not the remote control mode flag is currently “0” in step S04. In step S10, since the CPU 100 is in the remote control mode (step S04: N), the CPU 100 returns to the sensor mode by the processes in steps S11 and S12, and ends the series of processes. At this time, the CPU turns off the LED lamp 120 and notifies the worker G that the remote control mode has changed to the sensor mode.

As described above, the illumination control apparatus 10 according to the first embodiment determines the emission intensity of the LED illumination 12 based on the deviation between the illuminance detected by the illuminance sensor 110 and the dimming control value specified separately. A dimming control value changing unit 102 that changes a dimming control value when an illuminance corresponding to a predetermined irradiation condition (temporal change pattern P1) defined in advance through the illuminance sensor 110 is detected; Have
Thereby, the worker G can remotely perform a work of changing the light control value by intentional irradiation to the illuminance sensor 110 provided for realizing the automatic light control function. Accordingly, it is not necessary to open the box cover and perform firmware rewriting work as before, and the work load related to changing the dimming control value can be reduced.
In addition, since it is not necessary to mount a wireless communication module or an infrared remote control communication module that has been conventionally used for remote operation, it contributes to a reduction in the number of parts as an illumination control device, and manufacturing costs can be reduced.

In addition, the dimming control value changing unit 102 according to the present embodiment sets the dimming control value over time when the first illuminance corresponding to a predetermined irradiation condition (time-varying change pattern P1) defined in advance is detected. (Step S08) and the dimming control value at the time when the second illuminance (decision signal q4) corresponding to the predetermined irradiation condition defined in advance is detected is set as a new dimming control value. To do.
By doing in this way, the operator G can set a dimming control value as desired by simple operation using the portable lighting fixture g1 which he owns. Therefore, it is not necessary to separately develop a remote control for remote operation, and the development cost can be further reduced.

In addition, the dimming control value changing unit 102 according to the present embodiment changes the dimming control value when detecting an illuminance exceeding a determination illuminance threshold Lth indicating the maximum illuminance expected to be detected by receiving ambient light. Transition to the operation mode (remote control mode).
By doing so, it is possible to suppress unintentional transition to the remote control mode during normal operation (sensor mode).

In addition, the dimming control value changing unit 102 according to the present embodiment enters an operation mode in which the dimming control value is changed when the illuminance detected by the illuminance sensor 110 matches a predefined temporal change pattern P1. Transition.
In this way, even if the illuminance sensor 110 unintentionally detects illuminance exceeding the determination illuminance threshold Lth, the dimming control value changing unit 102 does not match the temporal change pattern P1 unless the illuminance sensor 110 matches the temporal change pattern P1. Does not transition to mode. Therefore, unintentional transition to the remote control mode during normal operation (in sensor mode) can be further suppressed.

As mentioned above, although the illumination system 1 which concerns on 1st Embodiment was demonstrated in detail, the specific aspect of the illumination system 1 which concerns on this embodiment is not limited to the above-mentioned thing, and does not deviate from a summary. It is possible to make various design changes within the range.
For example, the temporal change pattern P1 defined by the dimming control value changing unit 102 is not limited to the mode shown in FIG. For example, the temporal change pattern P1 according to another embodiment may transition to the remote control mode when a single irradiation period (one pulse) exceeding the determination illuminance threshold Lth is detected.
In addition, the dimming control value changing unit 102 according to another embodiment is a part of a plurality of irradiation periods (a first irradiation period q1 and a second irradiation period q3) that define a predetermined temporal change pattern P1 or All may be defined as illuminance that is equal to or less than the determination threshold Lth.

  In addition, the dimming control value changing unit 102 according to the present embodiment uses the temporal change pattern P1 (see FIG. 4) used for shifting from the sensor mode to the remote control mode, and returning from the remote control mode to the sensor mode. It has been described that it is the same as the temporal change pattern P2 (see FIG. 7) used. However, the dimming control value changing unit 102 according to another embodiment is not limited to this mode, and the temporal change pattern P1 and the temporal change pattern P2 are defined by different change patterns. There may be.

  In addition, the dimming control value changing unit 102 according to the present embodiment changes the dimming control value over time when detecting the first illuminance corresponding to the temporal change pattern P1, and is specified in advance. It has been described that the dimming control value at the time when the second illuminance (decision signal q4) corresponding to the predetermined irradiation condition is detected is set as a new dimming control value. However, the operation of the dimming control value changing unit 102 is not limited to this mode, and can be changed to various modes. For example, the dimming control value changing unit 102 according to another embodiment may preliminarily define a plurality of different temporal change patterns P11, P12, P13,. In this case, when the illuminance control value changing unit 102 detects the illuminance corresponding to any of the temporal change patterns P11, P12,... Change to values corresponding to each of the patterns P11, P12,. By doing in this way, the worker G does not need to wait until the desired dimming control value is reached, so the time required for the work of changing the dimming control value can be shortened.

In addition, while the CPU 100 according to the present embodiment is operating in the remote control mode, the LED lamp 120 is turned on so that the worker G can recognize that it is operating in the remote control mode. Other embodiments are not limited to this aspect.
For example, the LED lamp 120 (notification unit) according to another embodiment may detect illuminance exceeding a determination illuminance threshold. For example, the CPU 100 causes the LED lamp 120 to blink and display when the illuminance sensor 110 detects an illuminance exceeding the determination illuminance threshold. By doing in this way, the worker G can recognize whether or not the amount of light to be irradiated is sufficient when projecting light toward the illuminance sensor 110 with the portable lighting fixture g1. Therefore, workability at the time of performing the work of changing the dimming control value is improved.

In each of the above-described embodiments, a program for realizing the function of the CPU 100 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. Each procedure is to be performed. Here, each process of the CPU 100 described above is stored in a computer-readable recording medium in the form of a program, and the above-described various processes are performed by the computer reading and executing the program. Here, the computer-readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, and the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.
Moreover, the aspect with which each function structure of CPU100 is comprised over several apparatuses connected with a network may be sufficient.

  As mentioned above, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof, as long as they are included in the scope and gist of the invention.

1 Lighting System 10 Lighting Control Device 100 CPU
101 Light emission intensity determination unit 102 Dimming control value change unit 110 Illuminance sensor 120 LED lamp (notification unit)
130 Light control value holding unit 11 Power supply unit 12 LED illumination (light source)

Claims (7)

An illuminance sensor capable of detecting ambient illuminance;
Illuminance said illuminance sensor detects is to match the defined dimming control value, and the emission intensity determining portion which determines the emission intensity at the light emitting source,
A dimming control value changing unit for changing the dimming control value when the illuminance sensor detects illuminance corresponding to a predetermined irradiation condition defined in advance;
Equipped with a,
The dimming control value changing unit changes the dimming control value when the illuminance sensor detects an illuminance exceeding a determination illuminance threshold that is assumed to be a maximum illuminance that is assumed to be detected by receiving ambient light. Lighting control device. A notification unit for notifying that illuminance exceeding the determination illuminance threshold is detected;
The illumination control device according to claim 1 , comprising: The dimming control value changing unit is
When detecting the first illuminance corresponding to predefined predetermined irradiation conditions, it causes over time changes the dimming control value, a second illuminance corresponding to predefined predetermined irradiation conditions The lighting control device according to claim 1 or 2 , wherein the dimming control value at the time of detection is set to a new dimming control value. The dimming control value changing unit is
Illuminance said illuminance sensor detects that, when matching the temporal change pattern defined in advance, according to any one of claims 1 to 3, characterized in that changes the dimming control value Lighting control device. The lighting control device according to any one of claims 1 to 4 ,
The light source that emits light at a light emission intensity determined by the illumination control device;
A lighting system comprising: As the illuminance detected by the detectable illuminance sensor the illuminance of the ambient matches the defined dimming control value, determining the emission intensity at the light emitting source,
Changing the dimming control value when the illuminance sensor detects illuminance corresponding to a predetermined irradiation condition defined in advance;
I have a,
In the step of changing the dimming control value, when the illuminance sensor detects an illuminance exceeding a determination illuminance threshold that is assumed to be a maximum illuminance that is assumed to be detected by reception of ambient light, the dimming control value is set. Lighting control method to change . A computer of an illumination control device having an illuminance sensor capable of detecting ambient illuminance,
Illuminance said illuminance sensor detects is to match the defined dimming control value, the emission intensity determining means for determining the luminous intensity in a light emitting source,
Control value changing means for changing the dimming control value when the illuminance sensor detects illuminance corresponding to a predetermined irradiation condition defined in advance;
Function as
The control value changing means is a program that changes the dimming control value when the illuminance sensor detects an illuminance exceeding a determination illuminance threshold that is assumed to be a maximum illuminance that is assumed to be detected by receiving ambient light .