JP2018055792A - Lighting device and illumination apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device capable of storing a dimming degree that is set optimal, and easily reproducing the optimal dimming degree even after a power source is turned on again, and an illumination apparatus.SOLUTION: A lighting device comprises: a power conversion part by which first power is inputted and converted into second power to be supplied to an illumination load, and lights the illumination load; a nonvolatile storage part in which a storage value relating to a dimming degree of the illumination load is stored; and a dimming control part by which, a present dimming degree of the illumination load at a lighting time is stored in the storage part as a storage value on the basis of an instruction from the outside and when the first power is put in again, the power conversion part is commanded to light the illumination load at the dimming degree of the storage value stored in the storage part.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a lighting device and a lighting device.

  There is a lighting device with a dimming function that can adjust the brightness at the time of lighting by operating a remote controller or the like. When such a lighting device is operated by a remote controller, the lighting control degree at the time of lighting is determined by an operation signal from the remote controller when the lighting apparatus is turned on from being turned off. Also, once the power is turned off and the power is turned on again, most of the lights are turned on at the factory-set dimming level such as full lighting. Therefore, if there is a difference between the dimming level set at the time of shipment and the dimming level to be realized after the power is turned on, it is necessary to set the dimming level with a remote controller or the like each time.

  For example, in the case of illumination for exhibits such as art museums and museums, there is an optimum dimming degree for each object to be illuminated, and an optimum dimming degree is set for each lighting device.

  In an illumination device to which a dimmer is connected, if the dimmer is set to an optimum dimming degree, the dimming level before turning off can be reproduced even when the lighting is turned off. However, an illuminating device that sets the dimming level using a remote controller or the like requires a great deal of time because readjustment is required to reproduce the desired dimming level when the lamp is turned on again.

JP, 2006-031864, A

  Embodiments provide a lighting device and a lighting device that store an optimally set dimming degree and can easily reproduce the optimal dimming degree even after the power is turned on again.

  The lighting device according to the embodiment receives first power, converts it into second power supplied to the lighting load, stores a power conversion unit that turns on the lighting load, and a stored value related to the dimming degree of the lighting load. Based on a non-volatile storage unit and an instruction from the outside, the current dimming level when the lighting load is turned on is stored as a stored value in the storage unit, and when the first power is turned on again, the storage A dimming control unit that commands the power conversion unit to turn on the lighting load with the dimming degree of the stored value stored in the unit.

  The present embodiment includes a dimming control unit having a storage unit including an electrically rewritable non-volatile memory. Therefore, the optimal dimming degree is stored, and the optimal dimming level is maintained even after the power is turned on again. The luminous intensity can be easily reproduced.

It is a block diagram which illustrates the lighting device concerning a 1st embodiment. It is a schematic diagram for demonstrating operation | movement of the lighting device of 1st Embodiment. It is an example of the flowchart for demonstrating operation | movement of the lighting device of 1st Embodiment. It is an example of the flowchart for demonstrating operation | movement of the lighting device of 1st Embodiment. It is a block diagram which illustrates the illuminating device which concerns on 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the size ratio between the parts, and the like are not necessarily the same as actual ones. Further, even when the same part is represented, the dimensions and ratios may be represented differently depending on the drawings.
In the present specification and drawings, the same elements as those described above with reference to the previous drawings are denoted by the same reference numerals, and detailed description thereof is omitted as appropriate.

(First embodiment)
FIG. 1 is a block diagram illustrating a lighting device according to this embodiment.
As shown in FIG. 1, the lighting device 20 of the present embodiment includes a power conversion unit 22 and a dimming control unit 30. The lighting device 20 includes power supply terminals 21a and 21b and output terminals 21c and 21d.

  The lighting device 20 is connected to the input power source 1 through power terminals 21a and 21b. The input power source 1 is, for example, a commercial AC power source. The lighting device 20 is connected to the light emitting module 50 via the output terminals 21c and 21d. The lighting device 20 receives power supplied from the input power supply 1 and performs power conversion appropriately to supply power for lighting the light emitting module 50.

  A switch 2 is provided between the input power source 1 and the lighting device 20. When the switch 2 is closed, power is supplied from the input power source 1 to the lighting device 20. When the switch 2 is opened, the power for operating the lighting device 20 is cut off. The switch 2 is a wall switch, for example. Alternatively, the switch 2 is a switch such as a distribution board. The lighting device 20 can adjust the dimming degree, for example, from extinction to full lighting, but the power supply to the lighting device 20 is interrupted by the switch 2 to prevent an accident at the time of extinction. Reduce power consumption.

  The light emitting module 50 includes a light emitting element 52. The light emitting module 50 may include a plurality of light emitting elements 52. In that case, the light emitting elements 52 are connected in series. Moreover, you may make it connect the serial connection body of the light emitting element connected in series in parallel. The light emitting element 52 is, for example, a light emitting diode (LED) or an organic light emitting diode (OLED).

  For example, the lighting device 20 and the light emitting module 50 are integrally formed to form the lighting device 10. In addition, the illuminating device 10 should just be provided with the lighting device 20 and the light emission module 50, and does not necessarily need to be comprised integrally. For example, the light emitting module 50 may be detachably connected to the lighting device 20.

  The power converter 22 includes a rectifying / smoothing circuit 23, a DC-DC converter 24, and a dimming circuit 25.

  The rectifying / smoothing circuit 23 rectifies and smoothes the AC voltage of the input power supply 1 and converts it into a DC voltage for output. The rectifying / smoothing circuit 23 includes, for example, a rectifying diode bridge and a smoothing capacitor. According to the output power capacity of the lighting device 20, the rectifying / smoothing circuit 23 may include a power factor correction circuit.

  The DC-DC converter 24 is connected to the output of the rectifying / smoothing circuit 23. The DC-DC converter 24 converts the DC voltage supplied from the rectifying / smoothing circuit 23 into a DC current or a DC voltage supplied to the light emitting module 50. The DC-DC converter 24 supplies a constant current to the light emitting module 50, for example. The constant current value supplied to the light emitting module 50 is set according to the output from the dimming circuit 25.

  The DC-DC converter 24 is, for example, a step-down chopper circuit. The optimum circuit format of the DC-DC converter is selected according to input / output voltage, output power capacity, and the like.

  The dimming circuit 25 is connected to the output of the dimming control unit 30. The output of the dimming circuit 25 is connected to the DC-DC converter 24. The dimming circuit 25 sets a current value to be supplied to the light emitting module 50 based on the PWM signal supplied from the dimming control unit 30. The dimming circuit 25 detects the output voltage, output current, output power, and the like supplied from the DC-DC converter 24 to the light emitting module, and supplies it to the DC-DC converter 24 so as to match the current value set based on the PWM signal. Supply control signals. That is, feedback control is performed by the DC-DC converter 24 and the dimming circuit 25.

  The dimming control unit 30 includes a control unit 31 and a storage unit 32. The dimming control unit 30 further includes a communication unit 33.

  The dimming control unit 30 generates a PWM signal according to the dimming degree stored in the storage unit 32 and supplies the PWM signal to the power conversion unit 22. The dimming control unit 30 exchanges data with the external communication device 60 via the communication unit 33. The dimming control unit 30 transmits data related to the dimming degree currently set in the communication device 60 via the communication unit 33. The dimming control unit 30 stores data transmitted from the communication device 60 via the communication unit 33 in the storage unit 32.

  The control unit 31 comprehensively controls the operation of the dimming control unit 30. Specifically, the control unit 31 reads data relating to the dimming degree stored in the storage unit 32. The control unit 31 generates a PWM signal based on the read data regarding the dimming degree. The control unit 31 supplies the generated PWM signal to the dimming circuit 25 of the DC-DC converter 24.

  In addition, the control unit 31 supplies data related to the dimming degree stored in the storage unit 32 to the communication unit 33. The supplied data relating to the dimming degree is converted by the communication unit 33 into data of a predetermined communication format. The control unit 31 instructs the communication unit 33 to transmit the converted data in the predetermined communication format.

  Furthermore, the control unit 31 acquires data received by the communication unit 33. The data received by the communication unit 33 is data in a predetermined communication format and includes data related to the dimming degree. The control unit 31 extracts data relating to the dimming degree from the data received by the communication unit 33, supplies a PWM signal corresponding to the dimming degree to the dimming circuit 25, and stores the received dimming degree as the current lighting state. Stored in the unit 32.

  The storage unit 32 includes a volatile memory and a nonvolatile memory. All or part of the nonvolatile memory is an electrically rewritable memory, that is, an EEPROM (Electrically Erasable Programmable Read-Only Memory). The storage unit 32 may be integrated (incorporated) with the control unit 31 or may be separately connected to the control unit 31 by a bus or the like.

  For the dimming degree corresponding to the PWM signal supplied to the dimming circuit 25, the current dimming degree is stored in the volatile memory of the storage unit 32, for example, as the current lighting state. In addition, the storage unit 32 stores the current dimming degree as the current lighting state stored in the volatile memory as data (stored value) regarding the dimming degree in the nonvolatile memory in accordance with an instruction from the control unit 31. Data relating to the dimming degree is stored, for example, in the EEPROM portion, and is rewritten by a command from the control unit 31. Data relating to the dimming degree stored in the storage unit 32 may be overwritten when the data is rewritten. That is, when the control unit 31 reads out data related to the dimming degree, the dimming degree data immediately after rewriting is read out to the storage unit 32.

  The control unit 31 is a control device that operates by a program such as a microcomputer or a microcontroller. The control unit 31 operates according to each step of the program stored in the storage unit 32, for example. A program for the operation of the control unit 31 may be stored in the storage unit 32 or may be stored in another storage device.

  The communication unit 33 preferably includes a wireless communication interface. The communication unit 33 includes a modulation circuit, a transmission circuit, a reception circuit, a demodulation circuit, and the like for a wireless communication interface. The communication unit 33 is, for example, a BLUETOOTH (registered trademark) communication module. The communication unit 33, which is a BLUETOOTH (registered trademark) communication module, operates intermittently at predetermined intervals in order to search for communication connection targets even when the connection is not established. Yes.

  By setting the communication protocol of the communication unit 33 to BLUETOOTH (registered trademark), it is possible to easily find a connection partner and establish a mutual connection.

  Of course, the communication unit 33 may include other communication interfaces as long as the communication unit 33 can perform bidirectional communication. The communication unit 33 may be connected to, for example, a public communication network and connected to the communication device 60 via the Internet.

  The dimming control unit 30 includes an auxiliary power supply unit 35. In this example, the auxiliary power supply unit 35 is connected to the output of the rectifying / smoothing circuit 23 of the power conversion unit 22.

  Local power supplies 36 and 37 are connected to the output of the auxiliary power supply unit 35. The local power supply 36 further steps down the output of the auxiliary power supply unit 35 and supplies it to the dimming circuit 25, the control unit 31, and the storage unit 32. The control unit 31 and the storage unit 32 operate with power supplied from the local power supply 36. That is, the PWM signal supplied from the control unit 31 to the dimming circuit 25 of the power conversion unit 22 is generated based on the power supply by the local power supply 36. The local power supply 36 supplies power to the dimming circuit 25. The dimming circuit 25 receives the PWM signal as the dimming signal from the control unit 31 and feedback-controls the DC-DC converter 24.

  The local power supply 37 further steps down the output of the auxiliary power supply unit 35 and supplies it to the communication unit 33. The communication unit 33 operates with power supplied from the local power supply 37.

  Local power supplies 36 and 37 both output 3.3V, for example. The power source of the control unit 31 and the storage unit 32 is separate from the power source of the communication unit 33 and is separated. The local power supply 36 also supplies a power supply different from that of the communication unit 33 to the dimming circuit 25 that performs feedback control of the DC-DC converter 24. For example, even when the communication unit 33 searches for a communication connection partner or operates intermittently to perform communication, the influence on the dimming circuit 25, the control unit 31, and the storage unit 32 can be reduced. . In particular, by separating the power supplied to the dimming circuit 25 that performs feedback control from the power supplied to the communication unit 33, the intermittent operation of the communication unit 33 affects the feedback system and prevents the light emitting element 52 from flickering during lighting. can do.

Operation | movement of the lighting device 20 of this embodiment is demonstrated.
FIG. 2 is a schematic diagram for explaining the operation of the lighting device of the present embodiment.
FIG. 2 shows, as an example, a state in the exhibition room of a museum. Exhibits E1 to E4 are displayed in the exhibition room. A plurality of light fixing rails 55 are provided on the ceiling of the exhibition room. A plurality of lighting devices 20 are installed on one rail 55, and each lighting device 20 is directed to one of the exhibits E1 to E4.

  One or a plurality of lighting devices 20 are directed to each of the exhibits E1 to E4. In this example, three lighting devices 20a to 20c are directed to the exhibit E1, and other exhibits are displayed. One lighting device 20 is directed to the objects E2 to E4. In this example, for convenience of explanation, it is assumed that the lighting devices 20, 20a to 20c are all the same lighting device, but it is needless to say that the lighting device is not limited to this. Of course, it is possible to have output power capacities that are all or partly different.

  The lighting devices 20, 20 a to 20 c are set for dimming degree by the communication device 60. The communication device 60 is a wireless communication terminal, for example. The communication device 60 is, for example, a smartphone, and includes dedicated application software for setting the dimming degree of the lighting device 20, and is used as a dedicated wireless communication terminal.

  The communication protocol is preferably BLUETOOTH (registered trademark). When the lighting devices 20, 20a to 20c and the communication device 60 reach the communicable distance, connection is attempted by pairing, and mutual connection can be established. Each time a mutual connection is established, the display screen of the communication device 60 displays the addresses, names, and current dimming levels of the lighting devices 20 and 20a to 20c.

  When the names of lighting devices for the exhibition E1 are E1a, E1b, E1c, as shown in FIG. The light intensity is displayed. Although not shown, the dimming degree is displayed for each exhibit in the same manner for other exhibits.

  The operator of the communication device 60 can set the dimming level of each lighting device on the application software of the communication device 60, and can transmit the setting value of the dimming level to each lighting device. For example, when the dimming degree, which was 50% at the beginning, is changed to 70% with respect to the lighting device E1a and is transmitted to the lighting device E1a as a new set value, the lighting device E1a is turned on with a dimming degree of 70%. .

  When a plurality of lighting devices are assigned to one exhibit as in this example, the dimming degree can be adjusted for each of the plurality of lighting devices.

This will be described in detail with reference to a flowchart.
3 and 4 are examples of flowcharts for explaining the operation of the lighting device of the present embodiment.
As shown in FIG. 3, in step S <b> 1, the switch 2 is turned on to supply power to the power conversion unit 22. The rectifying / smoothing circuit 23 outputs a DC voltage corresponding to the input voltage. When the DC voltage reaches a predetermined voltage, the DC-DC converter 24 is activated.

  Here, since an operable power supply is not supplied to the dimming control unit 30, the input of the dimming circuit 25 of the power conversion unit 22 is pulled down or the like, and is set to have a dimming degree of 0%, for example. Yes. The dimming circuit 25 outputs a low level (0 V), for example. Therefore, at this time, the light emitting module 50 is turned off.

  Power is supplied to the control unit 31 and the storage unit 32 via the auxiliary power supply unit 35 and the local power supply 36. In step S2, the control unit 31 waits until the supplied voltage reaches a predetermined value, performs an initialization operation after reaching the predetermined voltage, and proceeds to the next step. Here, the predetermined voltage is a voltage for a power-on reset of the control unit 31, and when the power-on reset voltage is exceeded, the control unit 31 performs an initialization operation. The controller 31 operates according to the program after the initialization operation is completed.

  In step S <b> 3, the control unit 31 reads data relating to the dimming degree from the storage unit 32. The control unit 31 generates a corresponding PWM signal using the read data regarding the dimming degree.

  In step S4, the control unit 31 outputs the generated PWM signal. The output PWM signal is supplied to the dimming circuit 25 of the power converter 22.

  In step S5, the dimming circuit 25 sets a current value according to the dimming degree based on the supplied PWM signal, and controls the DC-DC converter 24 so that the output current to the light emitting module becomes the set current value. .

  In this way, the lighting device 20 can be lit at a dimming degree according to the stored value stored in the storage unit 32.

Next, the operation when the current dimming level and the stored value are displayed and the current dimming level and the stored value are changed by communication between the communication device 60 and the lighting device 20 will be described.
As shown in FIG. 4, the lighting device 20 starts lighting at the dimming degree of the stored value as described above when the power is turned on. Next, either the communication device 60 or the lighting device 20 searches for a communication partner. In this embodiment, after the lighting device 20 is turned on, the lighting device searches for a communication partner, the communication device 60 reaches a communicable distance, and starts the connection operation when receiving the partner identification data (connection request). . In step S10, the communication device 60 and the lighting device 20 establish a connection in response to either one of the connection requests.

  In step S11, the communication device 60 requests the lighting device 20 for the current dimming level and the stored value, respectively.

  In step S <b> 12, the communication unit 33 of the lighting device 20 returns a flag indicating that the data request has been received to the communication device 60. The control unit 31 of the lighting device 20 that has recognized that the data request has been received via the communication unit 33 reads the current dimming degree and the stored value from the storage unit 32. When the lighting device 20 is turned on, the lighting device 20 is lit based on the stored value stored in the storage unit 32. Therefore, the current dimming degree and the stored value are the same dimming degree. The control unit 31 transmits the read current dimming level and stored value via the communication unit 33. The current dimming level and the stored value stored in the storage unit 32 are 50%, respectively, and the lighting device 20 is lit at a dimming level of 50%.

  In step S13, the communication device 60 receives the current dimming degree and the stored value, and displays the received data. The display screen of the communication device 60 displays that the current dimming level and the stored value of the lighting device 20 are 50%.

  When the operator of the communication device 60 changes the dimming level, in step S14, the communication device 60 changes the current dimming level display to a new dimming level display and requests to turn on at the new dimming level. It transmits to the lighting device 20. The new dimming degree is, for example, 70%. At this time, the stored value (50%) is displayed as it is on the display unit of the communication device 60.

  In step S <b> 15, the communication unit 33 of the lighting device 20 returns a flag indicating that the data change request has been received to the communication device 60. The control unit 31 of the lighting device 20 that has received a lighting request with a new dimming degree via the communication unit 33 stores the changed dimming degree 70% as the current dimming degree in the volatile memory of the storage unit 32. Note that the current dimming level once disappears when the power is turned off, but it may be stored in a non-volatile memory and updated each time. The dimming control unit 31 generates a PWM signal according to the changed dimming degree. Here, the lighting device 20 is lit at a new dimming degree of 70%, but the stored value remains 50%. Therefore, when the power supply is once shut down and turned on again in this state, the lighting device 20 is lit at a dimming degree of 50% according to the flowchart of FIG. When the current dimming level and the dimming level of the stored value are inconsistent, the current dimming level is changed to the dimming level of the stored value based on a predetermined signal from the communication device 60. Also good.

  Next, in step S <b> 16, the communication device 60 issues a stored value update instruction as an external instruction to update the stored value of the lighting device 20. First, the communication device 60 changes the display so that the current dimming level becomes a stored value, and transmits a change instruction to the lighting device 20. In step S16, the current dimming degree is displayed on the communication device 60 as 70% and the stored value is 70%.

  In step S <b> 17, the lighting device 20 that has received the update instruction reads the current dimming degree stored in the volatile memory and stores it as a stored value in the nonvolatile memory. That is, the current dimming degree of 70% is stored as a stored value of 70%. Thus, the stored value of the lighting device 20 is updated according to the instruction of the communication device 60. The lighting device 20 transmits a flag indicating that the stored value has been changed to the communication device 60.

  The operator who sets the dimming degree by the communication device 60 repeats the above-described operation in order to adjust all the lighting devices so as to obtain an appropriate dimming degree.

The effect of the lighting device of this embodiment will be described.
The lighting device 20 of the present embodiment stores data relating to the dimming degree as a stored value in an electrically rewritable nonvolatile memory. Therefore, the dimming degree of the lighting device can be adjusted, and the once set state can be stored in the lighting device as a stored value. For this reason, even if the dimming degree is changed after setting, when the input power source 1 is shut off and restarted, the dimming degree stored in the stored value, that is, the dimming degree once set can be turned on. Thus, a desired lighting state can be easily set by updating the stored value while changing the dimming degree. Moreover, since the lighting device 20 stores the dimming degree as a stored value, it is possible to light the stored value after the power is turned on and before bidirectional communication with the communication device is established.

  In addition, since the lighting device 20 of the present embodiment includes the communication unit 33 that can bidirectionally communicate with the external communication device 60, it is possible to transmit the data of the currently set dimming degree to the communication device 60. . In addition, the lighting device 20 can receive a dimming degree setting change request from the communication device 60 via the communication unit 33. Therefore, the lighting device 20 can set the dimming degree in accordance with a request from the communication device 60 and can cause the communication device 60 to recognize the set dimming degree.

  When the communication protocol is BLUETOOTH (registered trademark), the communication device 60 and the lighting device 20 can be connected within a range of several m to 10 m. The communication device 60 can be connected simultaneously with the plurality of lighting devices 20.

  As explained above, lighting for exhibits such as museums and museums must be set at the optimal dimming level for each exhibit, and the operator can adjust the dimming level while checking the exhibits and their lighting effects. Must be set. In the lighting device 20 of the present embodiment, by using a smartphone or the like, it is possible to set the dimming degree while confirming the lighting effect on the exhibit by the plurality of lighting devices.

  By using a short-range communication protocol such as BLUETOOTH (registered trademark) as the communication protocol, it is possible to set the dimming degree of a plurality of lighting devices at the same time, and it is simple without providing a special communication line. Mutual data communication becomes possible.

  By storing data on dimming degree in an electrically rewritable non-volatile memory, the power can be shut off after the museum or museum is closed, and the dimming degree set after the next opening can be easily reproduced. .

(Second Embodiment)
In the case of the first embodiment, the example in which the dimming degree of monochromatic light is set and changed has been described. In the present embodiment, a lighting device having high color rendering properties is provided by performing color adjustment together with light adjustment by mixing light emitting modules of a plurality of light emission colors.
FIG. 5 is a block diagram illustrating a lighting device according to this embodiment.
In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
As illustrated in FIG. 5, the illumination device 100 according to the present embodiment includes a plurality of power conversion units 22. Each power converter 22 is connected to light emitting modules 50R, 50G, and 50B having different emission colors. The light emitting modules 50R, 50G, and 50B include light emitting elements that emit red, green, and blue, respectively. The light emission color of the light emitting module can be set arbitrarily.

  The lighting device 100 includes a dimming control unit 130. The dimming control unit 130 includes a control unit 131, a storage unit 132, and a communication unit 133.

  The control unit 131 supplies a PWM signal based on the dimming degree to each of the plurality of power conversion units 22. The control unit 131 can be connected to the external communication device 60 via the communication unit 33. The control unit 131 reads data related to the dimming degree from one storage unit 132 and generates a PWM signal for setting the dimming degree for each of the light emitting modules 50R, 50G, and 50B.

  The control unit 131 receives the dimming degree setting values for the light emitting modules 50R, 50G, and 50B transmitted from the communication device 60 via the communication unit 133, and stores them in the storage unit 132, respectively.

  The control unit 131 reads out the dimming degree data for the light emitting modules 50R, 50G, and 50B stored in the storage unit 132 and transmits the data to the communication device 60.

  The communication unit 133 is supplied separately from the power of the control unit 131 and the storage unit 132.

  According to the illuminating device 100 of the present embodiment, the dimming degree of each color of the light emitting modules 50R, 50G, and 50B can be set, so that a more advanced color rendering effect is realized for exhibits such as museums and museums. be able to.

It is possible to realize a lighting device and a lighting device that can store the optimally set dimming degree and can easily reproduce the optimal dimming degree even after the power is turned on again.

  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 novel 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 scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalents thereof. Further, the above-described embodiments can be implemented in combination with each other.

  1 input power supply, 2 switch, 10,100 lighting device, 20 lighting device, 22 power conversion unit, 23 rectification smoothing circuit, 24 DC-DC converter, 25 dimming circuit, 30, 130 dimming control unit, 31, 131 control Unit, 32, 132 storage unit, 33, 133 communication unit, 35 auxiliary power unit, 36, 37 local power source, 50, 50R, 50G, 50B light emitting module, 52 light emitting element, 60 communication device

Claims (5)

A power converter that inputs first power and converts it to second power to be supplied to the lighting load, and turns on the lighting load;
A non-volatile storage unit that stores a stored value related to the dimming degree of the illumination load;
The current dimming level when the lighting load is turned on is stored as a stored value in the storage unit based on an instruction from the outside, and the storage stored in the storage unit when the first power is turned on again. A dimming control unit that commands the power conversion unit to turn on the lighting load with a dimming value of the value;
A lighting device comprising: A communication unit capable of bidirectional communication with an external communication device;
The lighting device according to claim 1, wherein the communication unit receives a control signal from the communication device as an instruction from the outside.   The power conversion unit includes a dimming circuit that receives a command from the dimming control unit, and power is supplied from a power source unit different from the communication unit and the dimming circuit. Or the lighting device of 2. A lighting device according to any one of claims 1 to 3,
A lighting load that is lit by the lighting device;
A lighting device comprising: A first power conversion unit that inputs first power and converts the second power to be supplied to the first lighting load, and turns on the first lighting load;
A second power converter that inputs the first power, converts the power into a third power supplied to a second lighting load different from the first lighting load, and turns on the second lighting load;
A non-volatile storage unit that stores a first stored value related to the dimming degree of the first lighting load and a second stored value related to the dimming degree of the second lighting load;
Based on an instruction from the outside, the current first dimming level at the time of lighting of the first lighting load is stored as a first stored value, and the current second dimming level at the time of lighting of the second lighting load is stored as a second value. When stored as a stored value and the first power is turned on again, the first lighting load is turned on at the first dimming level stored in the storage unit, and the second lighting load is set at the second dimming level. A dimming control unit that commands the power conversion unit to turn on
A lighting device comprising:

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