JP5112170B2 - Lighting control system - Google Patents

Description

  The present invention relates to a lighting control system that controls lighting of a plurality of lighting fixtures.

  Conventionally, a plurality of lighting fixtures are arranged in a predetermined area, the area is divided into a plurality of areas, a brightness sensor is installed in each area, and the average value of the brightness of all the areas is set as a preset target value. There is known an illumination control system that performs dimming control of a luminaire for each area so as to substantially match (see, for example, Patent Document 1). In this illumination control system, since the number of brightness sensors can be reduced compared to the case where a brightness sensor is attached to each lighting fixture and the lighting fixture is controlled based on the measurement result, the cost can be reduced. .

  However, in the lighting control system as described above, when the ambient environment of the brightness sensor is different for each area, for example, even if light of the same brightness is emitted from all the lighting fixtures, the measurement is performed due to the influence of the ambient environment. The value may be different.

  For example, it is assumed that the brightness sensor is mounted on a lighting fixture installed on the ceiling, and the material of the floor surface below the fixture varies depending on the position, and is composed of flooring and a carpet as an example. The brightness sensor detects the direct light from the lighting fixture, the reflected light emitted from the lighting fixture and reflected from the floor surface below the fixture, and the outside light. In this case, even if all the lighting fixtures are lit at the same brightness, the reflectance of the illumination light differs depending on the material of the floor surface, and the detection value by the brightness sensor may vary depending on the position. The reflectance of the illumination light varies depending not only on the floor surface material but also on whether a table or a shelf is placed below the lighting fixture.

  The change in the detection value by the above-described brightness sensor will be described with reference to FIG. 14 with specific numerical examples. Even if the surface illuminance of all the luminaires 10 is approximately 750 lx, the material of the floor surface F1 is the flooring F2. , The output voltage of the brightness sensor 11 above is 4V. When the material of the floor surface F1 is the carpet F3, the light reflectance is lower than that of the flooring F2, so the brightness above The output voltage of the sensor 11 may be lowered to 3V.

For this reason, in the illumination control system as shown in Patent Document 1, the cost can be reduced by reducing the number of brightness sensors as described above, but the average value of the detection values by the brightness sensor is the material of the floor surface, etc. Therefore, even if dimming control is performed so that the average value matches the target detection value set in advance corresponding to the target value of brightness, the target detection value is If it is not set to match the actual brightness, the actual brightness does not become the target value, and high-precision light control may be difficult.
JP-A-2005-85588

  The present invention has been made to solve the above-described conventional problems. A target detection value by a brightness sensor is set in accordance with the surrounding environment, and the detection value by the brightness sensor matches the target detection value. A lighting control system that enables highly accurate dimming control according to the surrounding environment by dimming the lighting fixture in this way, and reducing the cost by reducing the number of brightness sensors. The purpose is to provide.

To achieve the above object, according to a first aspect of the present invention, there is provided a grouped lighting fixture group including a plurality of lighting fixtures, and a brightness sensor is mounted in the lighting fixture group, and the brightness sensor is provided. In the lighting control system that controls lighting of the lighting fixtures in the lighting fixture group according to the detection value by the brightness sensor, the brightness sensor is mounted on each of at least two lighting fixtures in the same lighting fixture group, and the brightness Among lighting fixtures equipped with sensors, one lighting fixture is set as a master unit, and the other lighting fixtures are allocated to slave units, and the slave unit is based on a brightness sensor mounted on the slave unit. The detected value information and the attribute information of the slave unit are transmitted to the master unit, and the master unit is set according to the ambient environment of each brightness sensor, and the average of the target detection values by the brightness sensor Value is stored in advance, the slave unit Based on the detected value information and attribute information transmitted by the sensor and the detected value information by the brightness sensor mounted on the parent device, the sum of the detected values by each brightness sensor is divided by the number of brightness sensors. The dimming control of each lighting fixture is performed such that the value obtained by dividing the lighting device substantially coincides with the average value, and when the mounting state of the brightness sensor is changed, Instructing to transmit the target detection value by the brightness sensor to the base unit, confirming the number of brightness sensors, and resetting the average value of the target detection value by each brightness sensor. And

If the previous Noriko machine does not receive a control signal from the base unit under predetermined conditions, any luminaire of the lighting fixture in which the brightness sensor is attached is set to the newly master unit that it is preferable.

Before SL brightness sensor, which is preferably constructed telescopically in the luminaire.

According to a second aspect of the present invention, a grouped lighting fixture group including a plurality of lighting fixtures is provided, a brightness sensor is mounted in the lighting fixture group, and depending on a detection value by the brightness sensor. In the lighting control system that controls lighting of the lighting fixtures in the lighting fixture group, the brightness sensor is mounted on each of at least two lighting fixtures in the same lighting fixture group, and the brightness sensor is mounted. Among the lighting fixtures, one lighting fixture is set as a master unit, the other lighting fixtures are allocated to slave units, the slave unit is detected value information by a brightness sensor mounted on the slave unit, The attribute information of the slave unit is transmitted to the master unit, and the master unit stores in advance an average value of target detection values by the brightness sensor set according to the surrounding environment of each brightness sensor. And the test sent by the slave unit Based on the value information and attribute information, and the detected value information by the brightness sensor mounted on the parent device, the sum of the detected values by each brightness sensor is divided by the number of brightness sensors, and obtained by dividing the sum. The dimming control is performed on each luminaire so that the value substantially matches the average value, and the master unit obtains a target detection value by the brightness sensor when the brightness sensor is mounted on the luminaire, respectively. If it is stored in advance corresponding to each luminaire, and the mounting status of the brightness sensor is changed, the average value of the target detection values from the target detection value corresponding to each luminaire on which the brightness sensor is mounted The recalculation is performed .

According to the first aspect of the present invention , the master unit stores in advance the average value of the target detection value set by the brightness sensor, which is set according to the surrounding environment of each brightness sensor. Since each luminaire is dimmed and controlled so that the value obtained by dividing the sum of the detected values by the number of brightness sensors substantially coincides with the average value, highly accurate dimming control according to the surrounding environment becomes possible . Also, by mounting one brightness sensor to all luminaire, as compared with the case where those measurement results controlled dimming each luminaire based on, since it is sufficient that at least two provided within the luminaire group In addition, the number of brightness sensors can be reduced to reduce the cost. Also, even if the brightness sensor mounting status is changed, the average value of the target detection value by the brightness sensor is automatically reset, so it is necessary to manually reset the average value as described above. Disappears.

According to the second aspect of the present invention, the master unit stores in advance an average value of target detection values set by the brightness sensor, which is set in accordance with the surrounding environment of each brightness sensor. Since each luminaire is dimmed and controlled so that the value obtained by dividing the sum of the detected values by the number of brightness sensors substantially coincides with the average value, highly accurate dimming control according to the surrounding environment becomes possible. In addition, it is sufficient that at least two brightness sensors are provided in the luminaire group as compared with the case where the brightness sensors are attached to all the luminaires one by one, and dimming control of each luminaire is performed based on the measurement results. The cost can be reduced by reducing the number of brightness sensors. Further, since the slave unit does not transmit the target detection value information to the master unit when the installation state of the brightness sensor is changed, communication traffic can be reduced and the system performance can be improved.

Hereinafter, lighting control systems according to various embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 shows a configuration of a lighting control system according to the first embodiment of the present invention. The lighting control system 1 of the present embodiment includes a grouped lighting fixture group 3 including a plurality of lighting fixtures 2, a brightness sensor 4 is mounted in the lighting fixture group 3, and an output voltage ( The lighting fixture 2 in the lighting fixture group 3 is controlled to be turned on in accordance with the detection value of the brightness sensor. The luminaires 2 are connected to each other by, for example, one system of communication signal lines 5. The luminaires 3 are grouped by being remotely operated by the remote controller 6. The number of the lighting fixture groups 3 may be plural or one as illustrated. The brightness sensor 4 is mounted on each of the two lighting fixtures 2 in the same lighting fixture group 3.

  Of the luminaires 2 on which the brightness sensor 4 is mounted, one luminaire 2 is set as the master unit 2A, and the other luminaires 2 are allocated to the slave unit 2B. The subunit | mobile_unit 2B transmits the output voltage information (detection value information) of the brightness sensor 4 mounted in the subunit | mobile_unit 2B, and the attribute information of the subunit | mobile_unit 2B to the main | base station 2A via the communication signal line 5. Master unit 2A stores in advance an average value of target output voltages (target detection values) set according to the surrounding environment of each brightness sensor 4, and outputs voltage information and attribute information from slave unit 2B; Based on the output voltage information from the brightness sensor 4 mounted on the parent device 2 </ b> A, the total output voltage of each brightness sensor 4 is divided by the number of brightness sensors 4. Then, base unit 2A performs dimming control of the lighting fixtures 2 in the same lighting fixture group 3 in a lump so that the voltage obtained by the division substantially matches the average value.

  FIG. 2 shows an electrical configuration of the lighting fixture 2, the brightness sensor 4, and the remote controller 6. The lighting fixture 2 communicates with a light source 20, a lighting circuit 21 that turns on the light source 20, a dimming signal output unit 22 that outputs a dimming signal to the lighting circuit 21, and a brightness sensor 4 attached to the lighting fixture 2. A sensor communication unit 23, a communication unit 24 that communicates with another lighting fixture 2 via the communication signal line 5, and a remote control reception unit 25 that receives a radio signal from the remote control 6 are provided. The light source 20 can be composed of a fluorescent lamp or an LED. The brightness sensor 4 is attached to the sensor fixture 26 of the lighting fixture 2, and the sensor communication unit 23 is configured by a two-wire serial communication circuit compliant with RS485 or the like, and the brightness sensor 4 is connected to the brightness sensor 4 via the sensor fixture 26. connect. The communication unit 24 has the same type of communication circuit configuration as that of the sensor communication unit 23, and a serial communication cable is used as the communication signal line 5 in accordance therewith. It is desirable that the communication unit 24 has a function of avoiding communication signal collision. The remote control receiving unit 25 is configured by a wireless reception circuit including an infrared light receiving IC or an RF radio wave module according to the type of wireless signal from the remote control 5.

  Moreover, the lighting fixture 2 is based on the calculation part 27 which calculates a light control rate, the memory | storage part 28 which memorize | stores various information, the detected value information by the brightness sensor 4, or the information from the other lighting fixture 2 or the remote control 6. And a control unit 29 for controlling the above-described units. The calculation unit 27 and the control unit 29 can be configured by a microprocessor or the like, the storage unit 28 can be configured by a memory such as a flash memory, ROM, RAM, or EEPROM, and the storage unit 28 has an address and group of the lighting fixture 2 as attribute information. A number is stored in advance.

  The control unit 29 receives a signal from the brightness sensor 4 via the sensor communication unit 23 and controls the lighting circuit 21 according to the signal to control the light source 20 to be dimmed. Further, the control unit 29 controls communication by the communication unit 24 and exchanges output voltage information and the like of the other lighting fixtures 2 and the brightness sensor 4. Communication between the luminaires 2 is performed using an address or a group number. When transmitting various types of information, the control unit 29 superimposes the address or group number of the transmission partner on the information, and when receiving various types of information, It is determined whether or not the destination address or group number superimposed on the information received by the device matches that of the own device, and the received information is treated as valid only when they match. The control unit 29 receives a signal from the remote control 6 via the remote control receiving unit 25. The calculation unit 27 and the control unit 29 may be configured by the same microprocessor or may be configured by different units.

  The brightness sensor 4 controls the light detection unit 40 configured by a light receiving element that performs photoelectric conversion, the communication unit 41 that communicates with the lighting fixture 2, and the communication unit 41, and detects information detected by the light detection unit 40 as a voltage. And a control unit 42 that outputs the signal to the luminaire 2 as a signal. The communication unit 41 has the same type of communication circuit configuration as that of the sensor communication unit 23 of the lighting fixture 2, and the control unit 42 can be configured by a microprocessor or the like.

  The remote controller 6 includes an operation unit 60 including buttons and the like operated by the user, a control unit 61 that generates operation signals for various remote operations of the lighting fixture 2 based on operations of the operation unit 60 by the user, and operations thereof A wireless transmission unit 62 that wirelessly transmits a signal to the lighting fixture 2. By operating the operation unit 60, it is possible to assign a group to the lighting fixture 2, set a master unit and a slave unit, adjust a dimming rate, set a target value of an output voltage of a brightness sensor, and the like. The control unit 61 can be configured by a microprocessor or the like, and the operation signals generated thereby include a group assignment signal including a group number and a parent device or a child device setting signal. The wireless transmission unit 62 can be configured by a wireless transmission circuit including an infrared light receiving IC or an RF radio module.

  FIGS. 3A and 3B show the luminaire 2 and the state when the brightness sensor 4 is attached thereto. As shown in FIG. 2A, the sensor fixture 26 is installed around the light source 20, and reflects direct light from the light source 20, reflected light reflected by the floor surface below the instrument, and external light. The brightness sensor 4 is arranged at a position where it can be detected together. Moreover, the sensor fixture 26 has a female connection terminal 26a into which the male connection terminal 4a of the brightness sensor 4 is inserted, as shown in FIG. The device 2 can be inserted and removed freely. The brightness sensor 4 can be attached to any of the lighting fixtures 2. The detailed configurations of the sensor fixture 26 and the brightness sensor 4 are substantially the same as, for example, the function expansion terminals and function plugs described in JP-A No. 2002-110376.

  Next, (1) grouping of the lighting fixtures 2 performed in the lighting control system 1 having the above configuration, (2) setting of the master unit 2A and the slave unit 2B in the grouped lighting fixture group 3, and (3 ) Setting of the target output voltage of the brightness sensor 4 of the master unit 2A and the slave unit 2B and calculation of the average value thereof, and (4) dimming control of the lighting fixture group 3 by the master unit 2A based on the average value, The description will be given with reference to FIGS. 4 to 8 in addition to FIGS. 1 and 2 described above.

(Grouping of lighting fixtures)
As shown in FIG. 1 described above, the lighting fixtures 2 are grouped by setting a group number one by one from the remote controller 6 to form a lighting fixture group 3. Specifically, when the user performs an operation for group assignment on the remote controller 6 in the vicinity of the lighting fixture 2, the control unit 61 of the remote controller 6 transmits a group assignment signal including a group number to the wireless transmission unit based on the operation. 62 to the lighting fixture 2. The remote control receiving unit 25 of the lighting fixture 2 receives it. The control unit 29 of the lighting fixture 2 extracts the group number from the signal and writes it in the storage unit 28.

(Setting of master unit and slave unit)
The setting procedure of the main unit 2A and the sub unit 2B in each lighting fixture group 3 will be described with reference to FIG. When the user 7 performs an operation for setting the master unit on the operation unit 60 of the remote controller 6 in the vicinity of any one of the luminaires 2 to which the brightness sensor 4 is attached in the luminaire group 3, the control unit 61 A base unit setting signal is sent from the wireless transmission unit 62 to the lighting fixture 2. The remote control receiving unit 25 of the lighting fixture 2 receives it, and the control unit 29 of the lighting fixture 2 recognizes the own device as the base unit 2A and writes the information as the base unit information in the storage unit 28. The slave unit setting is performed in the same manner.

(Set the target output voltage of each brightness sensor and calculate their average value)
FIG. 5 shows a state of setting the target output voltage of the brightness sensor 4 of each of the parent device 2A and the child device 2B, and FIG. 6 shows a setting flow of these target output voltages and an average value calculation flow. After the lighting control system 1 is constructed, first, the brightness of the lighting fixture 2 is adjusted to the target value while being measured by the separately prepared illuminometer 8 in a state where the external light is blocked. The ambient environment at the time of measurement is substantially the same as that at the time of use except that external light is blocked. The dimming rate of the lighting fixture group 3 is adjusted by operating the remote controller 6 so that the brightness of each lighting fixture 2 becomes the target value.

  When the brightness substantially matches the predetermined value, when the user 7 performs an operation for target setting on the operation unit 60 of the remote controller 6 in the vicinity of the master unit 2A, the control unit 61 transmits a target setting signal to the wireless transmission unit 62. To the master unit 2A. The remote control receiving unit 25 of the parent device 2A receives the notification, and the control unit 29 transmits a notification request signal for requesting notification of the output voltage to the child device 2B (S101). The address of master unit 2A is superimposed on this notification request signal.

  The control unit 29 of the slave unit 2B receives the above notification request signal via the communication unit 24 (S201), sets the output voltage of the brightness sensor 4 at that time as the target output voltage, and refers to the storage unit 28. Then, the address and group number of the own device are read out, and these and the target output voltage information are collected and transmitted as one information from the communication unit 24 (S202). The transmission destination refers to the notification request signal and is set as the address of base unit 2A.

  The control unit 29 of the parent device 2A receives the information transmitted from the child device 2B by the communication unit 24 (S102), compares the group number included in the information with that of its own device, and if they match, (Yes in S103), the target output voltage and address included in the information are stored in the storage unit 28 (S104). At this time, the number of slave units 2B, that is, the number of brightness sensors 4 attached to the slave units 2B is determined from the number of sets of address information received from the slave units 2B in the same lighting fixture group 3 and the group number information. Be grasped.

  Further, the control unit 29 of the base unit 2A recognizes the output voltage of the brightness sensor 4 of the own device at the time of transmitting the above notification request signal as the target output voltage, and stores it in the storage unit 28 (S105). The average value of the target output voltage and the target output voltage of the brightness sensor 4 of the handset 2B is calculated by the computing unit 27 (S106). When calculating the average value, the total target output voltage is divided by the number of brightness sensors 4 of the slave unit 2B in the same luminaire group 3 plus 1 as the brightness sensor 4 of the master unit 2A. The average value is calculated. The calculated average value is stored in the storage unit 28 (S107). Thus, the average value of the target output voltage set according to the surrounding environment of each brightness sensor 4 is stored in advance in base unit 2A.

  The above average value calculation will be described with specific numerical values. As shown in FIG. 5 described above, for example, the master unit 2A and the slave unit 2B have a brightness of about 750 lx, which is the target value. When the output voltage of the brightness sensor 4 is 3 V and 2 V, respectively, when they are controlled, they are set as target output voltages, and the average value thereof is calculated by the calculation unit 27. 5V is stored in the storage unit 28 as an average value of the target output voltage. Even if the master unit 2A and the slave unit 2B are lit at the same brightness, the output voltage of the brightness sensor 4 is different because the floor surface F1 below the master unit 2A consists of the flooring F2, and the floor surface below the slave unit 2B. This is because F1 is made of the carpet F3 and the reflectance of the light is different. If the group numbers do not match in S103 described above (No in S103), the received information is discarded (S108).

  As shown in FIG. 7A, the storage unit 28 of the master unit 2A has its own address 28a, group number 28b, master device information 28c, child device, as shown in FIG. 7A, according to the settings (1) to (3) above. The address 28d of the machine 2B, the target output voltage 28e of the brightness sensor 4 of the own device, and the average value 28f of the target output voltages of the parent device 2A and the child device 2B are stored. Further, as shown in FIG. 7B, the storage unit 28 of the slave unit 2B has its own device address 28a, group number 28b, and the target of the brightness sensor 4 of its own device, as in the master unit 2A. The output voltage 28e and the slave unit information 28g are stored.

(Dimming control of lighting fixtures)
By the way, the amount of light emitted from a light source generally decreases due to various reasons such as temperature characteristics and aging. Therefore, in order to keep the light emission amount substantially constant, it is necessary to perform feedback control in which the light intensity is measured by the brightness sensor and the applied voltage or supply current to the light source is increased. Therefore, in this embodiment, the dimming rate of the lighting fixture group 3 is controlled by feedback control based on the output voltage of the brightness sensor 4.

  FIG. 8 shows a flow of the above dimming rate control. First, the brightness sensor 4 of each of the parent device 2A and the child device 2B measures the brightness synchronously at a predetermined interval (S301, 401). After measuring the brightness, the control unit 29 of the parent device 2A sends a notification request signal for requesting notification of the output voltage to the child device 2B (S302). The control part 29 of the subunit | mobile_unit 2B receives the notification request signal from the main | base station 2A (S402), and transmits output voltage information to the main | base station 2A (S403). The master unit 2 receives the output voltage information from the slave unit 2B (S303). When the master unit 2 receives the information from all the slave units 2B known at the time of setting the target output voltage, the output of the brightness sensor 4 of the own unit 2 The computing unit 27 is caused to calculate the average value of the voltage and the output voltage of the brightness sensor 4 of the handset 2B (S304). This average value is calculated by the same calculation method as that used when calculating the average value of the target output voltage.

  The control unit 29 of the parent device 2A compares the calculated average value with the average value of the target output voltage (hereinafter referred to as the target average value) stored in the storage unit 28 (S305). As a result of the comparison, if the calculated average value (hereinafter referred to as the calculated average value) is higher than the target average value (Yes in S306), the calculation unit 27 calculates the dimming rate according to the difference between them. In other words, the dimming rate of the entire lighting fixture group 3 is lowered (S307). For example, when the original dimming rate is 70%, the dimming rate is lowered by 1% to 69%. When the calculated average value is lower than the target average value (No in S306 and Yes in S308), the dimming rate of the entire lighting fixture group 3 is increased according to the difference (S309), for example, the original When the dimming rate is 70%, it is increased by 1% to 71%. When the calculated average value is equal to the target average value (No in S308), the current dimming rate is maintained (S310).

  The control unit 29 of the master unit 2A sends the adjusted dimming rate information to the other lighting fixtures 2 (S311). At this time, the storage unit 28 is referred to, and a group number is added in addition to the dimming rate information. The other lighting fixtures 2 receive the information from the base unit 2A, and when the group number in the information matches the group number of the own device, the dimming rate information in the information is reflected. Adjust the dimming rate of your device. In this way, the lighting fixtures 2 in the lighting fixture group 3 having the same group number are controlled in a dimming manner.

  In the present embodiment, the storage unit 28 of the base unit 2A is a brightness sensor that is set according to the surrounding environment of each brightness sensor 4 attached to the luminaire 2, as a specific example, the material of the floor surface F1. The average value of the four target output voltages is stored in advance. The control unit 29 of the base unit 2A divides the total output voltage of the brightness sensor 4 by the number of brightness sensors 4, and the storage unit 28 so that the value obtained by the division substantially matches the above-described average value. , Each light fixture 2 is dimmed and controlled. As a result, high-precision light control that matches the surrounding environment is possible, and the brightness of the luminaire 2 can be substantially matched with the target value with high accuracy.

  Moreover, if at least two brightness sensors 4 are attached to all the lighting fixtures 2 and each lighting fixture 2 is dimmed and controlled based on the measurement results, at least two lighting fixtures 4 are provided. Since it is good, the number of brightness sensors 4 can be reduced and cost reduction can be aimed at. Moreover, since the lighting fixture 2 can be set to the main | base station 2A or the subunit | mobile_unit 2B only by removing / inserting the brightness sensor 4 with respect to the lighting fixture 2, a setting becomes easy.

  Further, the brightness sensor 4 detects the illumination light and the outside light together, and the lighting fixture 2 is dimmed based on the detection result. Therefore, only the illumination light is detected and adjusted according to the detection result. Compared with light control, the dimming rate of the lighting fixture 2 can be lowered, and energy saving can be achieved.

  In the lighting control system 1, even if the number of the brightness sensors 4 in the lighting fixture group 3 is one, the dimming control described above can be performed based on the output voltage. Further, the settings of the master unit 2A and the slave unit 2B are not limited to the above. For example, among the luminaires 2 to which the brightness sensor 4 is attached, the luminaire 2 that has received the target setting signal from the remote controller 6 may be set as the master unit 2A. In this case, the lighting fixture 2 sends a slave unit setting signal into the lighting fixture group 3, and the other lighting fixture 2 to which the brightness sensor 4 is attached is set as the slave unit 2B.

  Moreover, the number of the subunit | mobile_unit 2B in the lighting fixture group 3 is not limited to one, Two may be sufficient as FIG. 9 shows. In this case, for example, it is assumed that the floor surface F1 is composed of the flooring F2 below the master unit 2A, the carpet F3 is below one slave unit 2B, and the mat F4 is below the other slave unit 2B. In this ambient environment, when the master unit 2A and the two slave units 2B are controlled so that each brightness is approximately 750 lx, the output voltage of the brightness sensor 4 is caused by the influence of the material of the floor surface, When they become 4V, 2V, and 3V, respectively, they are set as target output voltages, the average value thereof is calculated by the calculation unit 27, and the average value 3V is stored in the storage unit 28 as the average value of the target output voltage. .

(Second Embodiment)
In the illumination control system according to the second embodiment of the present invention, the constituent members are substantially the same as those in the first embodiment. Therefore, the configuration will be described with reference to FIGS. 1 and 2 described above. In the lighting control system 1 of the present embodiment, the slave unit 2B receives dimming rate information (control signal) for instructing the dimming rate from the master unit 2A, for example, for a predetermined period under predetermined conditions. If not, one of the slave units 2B automatically becomes the master unit 2A.

  Based on the output voltage information of the brightness sensor 4 transmitted from the slave unit 4, the control unit 29 of the master unit 2 </ b> A sets the dimming rate of the luminaire group 3 during normal operation. The control unit 29 of the master unit 2A has a timer function, which measures the time by using the timer function, and transmits the dimming rate information to the lighting fixtures 2 in the same lighting fixture group 3 including the slave unit 2B at a predetermined time interval. The data is transmitted via the communication unit 24.

  The control part 29 of the subunit | mobile_unit 2B has a timer function, time-measures from the time of receiving the said light control rate information, and does not receive the next light control rate information even if predetermined time passes. In the case of the failure, the base unit change signal indicating that the self unit becomes the base unit 2A is sent from the communication unit 24 to the other lighting apparatus 2. The group number and address of the own device are superimposed on the parent device change signal. The other lighting fixtures 2 in the same lighting fixture group 3 that have received the parent device change signal recognize that the parent device 2A has been switched.

  When there are a plurality of slave units 2B in one lighting fixture group 3, all the slave units 2B send out the above-mentioned master unit change signal, receive the signals from the other slave units 2B, The address of the other slave unit 2B is compared with the address of its own device. For example, when the address is represented by a number, the child device 2B having the largest or smallest address is reset as the parent device 2A.

  In the present embodiment, even when the master unit 2A does not function as a master unit and the dimming rate information is not transmitted to the slave unit 2B, a new master unit 2A is automatically set. The lighting fixture group 3 can be controlled by the simple master unit 2A. For this reason, even if a failure occurs in the parent device 2A, a new parent device 2A can be set immediately to restore the system, and so-called system availability can be increased.

(Third embodiment)
In the illumination control system according to the third embodiment of the present invention, the constituent members are substantially the same as those in the first embodiment, and the configuration will be described with reference to FIGS. 1 and 2 described above. In the illumination control system 1 of the present embodiment, when the mounting state of the brightness sensor 4 is changed in the lighting fixture group 3, the control unit 29 of the parent device 2A controls the brightness sensor 4 with respect to the child device 2B. The target output voltage information is transmitted via the communication unit 24 to the base unit 2A, the number of brightness sensors 4 in the lighting fixture group 3 is confirmed, and the average of the target output voltage of each brightness sensor 4 is determined. Reset the value. In each luminaire group 3, the target output voltage of the brightness sensor 4 of each luminaire 2 is obtained in advance, and the storage 28 of each luminaire 2 stores the target output voltage in advance.

  The change in the mounting state of the brightness sensor 4 includes a change in the number of brightness sensors 4 in the luminaire group 3 or a change in attachment target. In addition, even if the brightness sensor 4 remains attached to the luminaire 2, when the brightness cannot be measured due to turning off by a user operation or the like, the brightness sensor 4 is removed and the above-described changes are made. It is considered. The lighting device 2 may be turned off based on non-detection of a person by a human sensor other than a user operation.

  When the master unit 2A instructs the slave unit 2B to transmit the target output voltage information, the master unit 2A attaches its own address and group number. When receiving the instruction signal from the parent device 2A, the child device 2B compares the group number attached to the signal with the group number of its own device. If they match, the slave unit 2B transmits the target output voltage information to the address of the master unit 2A attached to the above-described instruction signal. If they do not match, the slave unit 2B discards the received information.

  FIG. 10 shows a flow for resetting the average value of the target output voltage of the brightness sensor 4 when one of the slave units 2B is turned off without being controlled by the master unit 2A as an example in the lighting control system of the present embodiment. Show. FIGS. 11A and 11B show transmission contents from the slave unit 2B to the master unit 2A before and after turning off.

  The control unit 29 of the slave unit 2B, when the own unit is turned off without a command from the master unit 2A, transmits the turn-off information indicating that to the master unit 2A (S501), and performs brightness measurement by the brightness sensor 4 Stop (S502).

  When receiving the light-off information transmitted from the child device 2B (S601), the control unit 29 of the parent device 2A sends a re-transmission command of the target output voltage information to the lighting devices 2 in the lighting device group 3 (S602). . At this time, the address of base unit 2A is superimposed on the target output voltage information.

  The control unit 29 of the slave unit 2B receives a re-transmission command from the master unit 2A (S503), refers to the storage unit 28 superimposed on the target output voltage information, and sets the address of the master unit 2A as the transmission destination to the target output voltage Information is transmitted (S504).

  The control unit 29 of the parent device 2A receives the target output voltage information transmitted from the child device 2B (S603), and based on the number of information, a new number of the child devices 2B, that is, the brightness attached to the child device 2B. Check the number of sensors 4.

  Further, the control unit 29 of the parent device 2A calculates an average value of the target output voltage of the brightness sensor 4 of the own device and the target output voltage of the brightness sensor 4 of the child device 2B stored in the storage unit 28 in advance. 27 (S604). At the time of calculating the average value, the total target output voltage is divided by the number of brightness sensors 4 in the same luminaire group 3 plus 1 as the brightness sensor 4 of the main unit 2A, and the average value is calculated. Is calculated. Then, the calculated new average value is stored in the storage unit 28 (S605). In this way, the new average value of the target output voltage of each brightness sensor 4 is stored in advance in the base unit 2A.

  The average value calculation operation will be described with reference to FIGS. 11A and 11B and specific numerical values. For example, one master unit 2A is set so that each brightness is approximately 750 lx. When the two child devices 2B are controlled, the target output voltage of the brightness sensor 4 in each is 3V, 4V, and 2V, and the child device 2B corresponding to 2V is turned off, the previous average value is Although it is 3V, recalculation is performed, and the average value of the target output voltage is (3 + 4) /2=3.5V. Similar resetting of the average value is performed even when the extinguished handset 2B is turned on again.

  In the present embodiment, even if the installation state of the brightness sensor 4 is changed, the average value of the target detection values by the brightness sensor 4 is automatically reset. This eliminates the need to manually reset the average value described above. Further, for example, when the number of brightness sensors 4 decreases, the total value of the output voltages decreases and the average value thereof decreases, the average value is substantially the same as the average value of the target output voltage before resetting. It is possible to prevent the light control rate from being increased so that the energy saving effect is not obtained.

(Fourth embodiment)
In the illumination control system according to the fourth embodiment of the present invention, the constituent members are substantially the same as those in the first embodiment, and therefore the configuration will be described with reference to FIGS. 1 and 2 described above. FIG. 12 shows information stored in advance in the storage unit 28 of the base unit 2A of the present embodiment. When the storage unit 28 of the main unit 2A according to the present embodiment is equipped with the brightness sensors 4 for all the lighting fixtures 2 as compared with the first embodiment (see FIG. 7A described above). The target output voltage information 28h of the brightness sensor 4 is further stored in association with the address of each lighting fixture 2. When the mounting state of the brightness sensor 4 is changed in the lighting device group 3, the base unit 2A determines the target output from the target output voltage information 28h corresponding to each lighting device 2 on which the brightness sensor 4 is mounted. Recalculate the average value of the voltage. In addition, the change in the mounting state of the brightness sensor 4 includes a change in the number of brightness sensors 4 in the lighting fixture group 3 or a change in attachment target.

  FIG. 13 illustrates an operation when one of the slave units 2B is turned off regardless of the master unit 2A as an example in the lighting control system of the present embodiment.

  The control unit 29 of the child device 2B transmits the turn-off information indicating that when the own device is turned off without a command from the parent device 2A to the parent device 2A (S701), and the brightness sensor 4 measures the brightness. Stop (S702). At the time of transmission, the storage unit 28 is referred to, and the address of the slave unit 2B is attached to the turn-off information.

  When the control unit 29 of the master unit 2A receives the extinguishing information transmitted from the slave unit 2B (S801), the control unit 29 compares the address of the slave unit 2B with the address of the lighting fixture 2 stored in the storage unit 28 in advance. The target output voltage information corresponding to the matched address is further read from the storage unit 28 (S802). The control unit 29 subtracts the read target output voltage from the sum of the target output voltages of all the slave units 2B, and divides it by the number of slave units 2B other than the extinguished slave unit 2B to obtain an average value. The operation unit 27 is instructed to recalculate (S804). The calculated average value is reset as the average value of the target output voltage and stored in the storage unit 28 (S804).

  In the present embodiment, in addition to obtaining the effects of the third embodiment, when the installation state of the brightness sensor 4 is changed, the slave unit 2B is compared with the third embodiment in that the target output voltage is Since information is not transmitted to base unit 2A, communication traffic can be reduced. For this reason, the performance of the illumination control system 1 can be improved.

  In addition, this invention is not limited to the structure of the said 1st thru | or 4th embodiment, A various deformation | transformation is possible according to the intended purpose. For example, the communication unit 24 may be a communication circuit that uses a LAN cable as the communication signal line 5 according to the Ethernet standard, or a communication circuit that uses a wireless LAN as the communication signal line 5 according to the wireless LAN standard. It may be configured to comply with a dedicated communication standard specialized for the system. When the communication unit 24 conforms to the wireless LAN standard, an access control method such as CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance) is used as a communication signal collision avoidance function.

  The setting of the master unit 2A and the slave unit 2B is not limited to the operation of the remote controller 6, and may be automatically performed when the brightness sensor 4 is attached. Specifically, when one brightness sensor 4 is attached to each of two lighting fixtures 2 in one lighting fixture group 3, the control unit 29 of the lighting fixtures 2 detects the output of the brightness sensor 4. Thus, the attachment of the brightness sensor 4 is detected. Those control units 29 refer to the storage unit 28, read the group number and address of the lighting fixture 2, and send them out from the communication unit 24. Each control unit 29 receives the transmitted information through the communication unit 24 and compares the address in the storage unit 28 with the received address of the other lighting fixture 2. Then, when the address in the storage unit 28 is larger, the control unit 29 recognizes its own device as the parent device 2A, and stores the received address in the storage unit 28 as the address of the child device 2B. When the received address is larger, the control unit 29 recognizes the own device as the child device 2B, and stores the received address in the storage unit 28 as the address of the parent device 2A.

The block diagram of the illumination control system which concerns on the 1st Embodiment of this invention. The block diagram of the lighting fixture of the said system, a brightness sensor, and a remote control. (A) is a perspective view when a brightness sensor is attached to the lighting fixture, and (b) is a perspective view when a brightness sensor is attached to a sensor fixture of the lighting fixture. The figure for demonstrating the setting procedure of the main | base station and a subunit | mobile_unit in the said lighting fixture group. The figure which shows the mode at the time of the setting of the target output voltage of the said brightness sensor. The flowchart which shows the setting procedure of the target output voltage of the brightness sensor by the said main | base station and a subunit | mobile_unit, and its average value calculation procedure. (A) is a block diagram which shows the various information previously stored in the memory | storage part of the said main | base station, (b) is a block diagram which shows the various information previously stored in the memory | storage part of the said subunit | mobile_unit. The flowchart which shows the dimming control procedure by the said main | base station and a subunit | mobile_unit. The figure which shows the modification of the said system. The flowchart which shows the setting procedure of the target output voltage of the brightness sensor by the main | base station of a lighting control system and the subunit | mobile_unit which concerns on the 3rd Embodiment of this invention, and the average value calculation procedure. (A) and (b) are electrical block diagrams showing transmission contents of one of the slave units before and after the extinguishing of one of the slave units. The block diagram which shows the various information previously stored in the memory | storage part of the main | base station of the illumination control system which concerns on the 5th Embodiment of this invention. The flowchart which shows the setting procedure of the target output voltage of the brightness sensor by the said main | base station and a subunit | mobile_unit, and its average value calculation procedure. The figure for demonstrating that the detection value by the brightness sensor of a lighting fixture changes according to the raw material of a floor surface.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Lighting control system 2 Lighting fixture 2A Master unit 2B Slave unit 3 Lighting fixture group 4 Brightness sensor

Claims (4)

A group of luminaires including a plurality of luminaires is provided, and a brightness sensor is mounted in the luminaire group, and lighting control of the luminaires in the luminaire group is controlled according to a detection value by the brightness sensor. In the lighting control system to
The brightness sensor is mounted on each of at least two lighting fixtures in the same lighting fixture group,
Among the lighting fixtures equipped with the brightness sensor, one lighting fixture is set as a parent device, and the other lighting fixtures are allocated to a child device,
The slave unit transmits detection value information by a brightness sensor mounted on the slave unit and attribute information of the slave unit to the master unit,
The master unit stores in advance an average value of target detection values set by the brightness sensor, which is set according to the surrounding environment of each brightness sensor, and detection value information and attributes transmitted by the slave unit Based on the information and the detected value information by the brightness sensor mounted on the parent device, the sum of the detected values by each brightness sensor is divided by the number of brightness sensors, and the value obtained by dividing that value is the average Dimming control of each lighting fixture to approximately match the value ,
Further, when the mounting state of the brightness sensor is changed, the master unit instructs the slave unit to transmit a target detection value by the brightness sensor to the master unit. A lighting control system characterized by checking the number and resetting an average value of target detection values by each brightness sensor .   When the slave unit does not receive a control signal from the master unit under a predetermined condition, an arbitrary lighting fixture among the lighting fixtures to which the brightness sensor is attached is newly set as the master unit. The lighting control system according to claim 1.   The illumination control system according to claim 1, wherein the brightness sensor is configured to be freely inserted into and removed from the lighting fixture. A group of luminaires including a plurality of luminaires is provided, a brightness sensor is mounted in the luminaire group, and lighting control of the luminaires in the luminaire group is controlled according to a detection value by the brightness sensor. In the lighting control system to
The brightness sensor is mounted on each of at least two lighting fixtures in the same lighting fixture group,
Among the lighting fixtures equipped with the brightness sensor, one lighting fixture is set as a parent device, and the other lighting fixtures are allocated to a child device,
The slave unit transmits detection value information by a brightness sensor mounted on the slave unit and attribute information of the slave unit to the master unit,
The master unit stores in advance an average value of target detection values set by the brightness sensor, which is set according to the surrounding environment of each brightness sensor, and detection value information and attributes transmitted by the slave unit Based on the information and the detected value information by the brightness sensor mounted on the parent device, the sum of the detected values by each brightness sensor is divided by the number of brightness sensors, and the value obtained by dividing that value is the average Dimming control of each lighting fixture to approximately match the value,
Further, the base unit stores in advance the target detection value by the brightness sensor when the brightness sensor is mounted on the lighting fixture corresponding to each lighting fixture, and the mounting status of the brightness sensor is An illumination control system that, when changed, recalculates an average value of target detection values from target detection values corresponding to each luminaire equipped with a brightness sensor .

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