JP5738107B2 - Lighting device, lighting device and measuring device - Google Patents

Description

  The present invention relates to a light source module having a light source such as an LED.

  There is an illumination device configured by connecting a light source module including a light source such as an LED and a lighting device that supplies power to the light source module.

JP 2006-318773 A JP 2004-158840 A

Light sources such as LEDs have large variations in characteristics such as chromaticity coordinates and luminous flux of emitted light. To prevent this variation from affecting the light emitted by the lighting device, for example, measure the characteristics of the light source in advance, and select multiple light sources so that the variation in characteristics can be offset. It is possible to do. However, in this method, it takes time to measure the characteristics of the light source and to manage the light source for which the characteristics have been measured, which may increase the manufacturing cost of the lighting device.
The present invention has been made to solve the above-described problems, for example, so that the light emitted from the lighting device is not affected by the variation in the characteristics of the light source while suppressing the manufacturing cost of the lighting device. The purpose is to do.

  The light source module according to the present invention includes a light source and a storage unit that stores a value based on characteristics of the light source measured by turning on the light source.

  According to the light source module of the present invention, since the storage unit stores a value based on the characteristics of the light source measured by actually turning on the mounted light source, the light source is turned on based on this value. It is possible to prevent the light emitted from the lighting device from being affected by variations in the characteristics of the light source.

FIG. 3 is a block configuration diagram illustrating a configuration of lighting apparatus 800 according to Embodiment 1. FIG. 3 shows a structure of data stored in a storage unit 120 in the first embodiment. FIG. 6 is a flowchart showing a flow of lighting processing S610 in the first embodiment. The figure for demonstrating the process of target value calculation process S613 in Embodiment 1. FIG. FIG. 2 is a block configuration diagram showing a configuration of a measuring apparatus 300 in the first embodiment. FIG. 6 is a flowchart showing a flow of write processing S630 in the first embodiment. FIG. 6 is a block configuration diagram illustrating configurations of an illumination device 800 and a measurement device 300 according to Embodiment 2. FIG. 6 shows a structure of data stored in a storage unit 120 according to Embodiment 3. The figure for demonstrating the process of target value calculation process S613 in Embodiment 3. FIG. FIG. 14 shows a structure of data stored in a storage unit 120 according to Embodiment 4. FIG. 6 is a chromaticity diagram illustrating light emitted from lighting apparatus 800 according to Embodiment 4. The flowchart figure which shows the flow of target value calculation process S613 in Embodiment 4. FIG. FIG. 6 is a block configuration diagram showing a configuration of a measuring apparatus 300 in a fourth embodiment. The flowchart figure which shows the flow of write-in process S630 in Embodiment 4. FIG.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.
A plurality of elements may be distinguished from each other by adding an alphabet after the reference numeral.

FIG. 1 is a block configuration diagram showing a configuration of an illumination device 800 according to this embodiment.
The lighting device 800 (LED lighting device) turns on a light source such as an LED or an organic EL by power supplied from a power source AC such as a commercial power source. The lighting device 800 can change a correlated color temperature of emitted light or the like. The illumination device 800 receives an instruction signal from an instruction device 810 such as a remote controller, for example, and changes a correlated color temperature of emitted light in accordance with the input instruction signal. The lighting device 800 includes, for example, the light source module 100, the lighting device 200, and a harness 290.

  The harness 290 (connection harness part, connecting part) connects (links) the light source module 100 and the lighting device 200 physically and electrically. The harness 290 includes, for example, two connectors 291 and 292 and a cable 293. The cable 293 connects the two connectors 291 and 292 physically and electrically. The harness 290 may be formed integrally with the lighting device 200 or the light source module 100.

The light source module 100 (LED module) is configured by, for example, a printed wiring board (substrate) and components such as electronic components mounted thereon. The light source module 100 includes a plurality of light source circuits 110, a storage unit 120, and a connector 180.
The light source circuit 110 has one or more light sources. The light source circuit 110 is a circuit for lighting the light source with the power supplied from the lighting device 200. The light source circuit 110 is, for example, a circuit in which a plurality of light sources are electrically connected in series. The light source circuit 110 emits light emitted from the light source. The light emitted from one light source circuit 110 is different in chromaticity coordinates from the light emitted from another light source circuit 110. For example, the light source circuit 110a has a light source (first LED group) that emits daylight white light having a correlated color temperature of about 5000K, and the light source circuit 110b emits light bulb color light having a correlated color temperature of about 3000K. A light source (second LED group). The lighting device 800 emits light obtained by mixing light emitted from the plurality of light source circuits 110. The lighting device 800 adjusts the intensity of light emitted from the light source of the light source circuit 110a and the intensity of light emitted from the light source of the light source circuit 110b to change the correlated color temperature of the emitted light. The illuminating device 800 emits light having a correlated color temperature indicated between 3000K and 5000K, for example. In addition, when one light source circuit 110 includes a plurality of light sources, light sources having different chromaticity coordinates may be included therein, and a plurality of light sources included in one light source circuit 110 may include chromaticity coordinates. May be substantially the same.
The storage unit 120 (memory device) stores data (value), holds the stored data without power supply, and can electrically read the stored data. The storage unit 120 is, for example, a nonvolatile memory such as an EEPROM, a dip switch, a jumper line, or a semi-fixed resistor. A nonvolatile memory such as an EEPROM is desirable because it can electrically write data and store a relatively large amount of data. The storage unit 120 stores data based on the characteristics of the light source of the light source circuit 110. The characteristics of the light source include, for example, a light flux emitted from the light source, correlated color temperature, chromaticity coordinates, and the like. When a single light source circuit 110 includes a plurality of light sources, the data stored in the storage unit 120 is based on the overall characteristics of the characteristics of the light sources included in the single light source circuit 110. . The characteristics of the light source vary from one light source to another due to the influence of manufacturing errors and the like. Therefore, after the light source module 100 is assembled, the light source of the light source circuit 110 is actually turned on to measure the characteristics of the light source. The data stored in the storage unit 120 is calculated based on the characteristics of the light source actually measured in this way.
The connector 180 engages with the connector 291 of the harness 290 to be physically and electrically connected. The connector 180 is electrically connected to each of the light source circuits 110 and the storage unit 120. Each light source circuit 110 is supplied with electric power from the lighting device 200 via a harness 290 connected to the connector 180. In addition, the lighting device 200 reads the data stored in the storage unit 120 via the harness 290 connected to the connector 180.

The lighting device 200 (LED power supply device) converts the power supplied from the power supply AC into power (DC power) supplied to each light source circuit 110. The lighting device 200 includes, for example, a plurality of power supply circuits 210, a control circuit 220, and a connector 280.
The power supply circuit 210 (DC power supply circuit) is, for example, a switching power supply circuit, and converts power supplied from the power supply AC into power supplied to the light source circuit 110. The power supply circuit 210a generates power to be supplied to the light source circuit 110a, and the power supply circuit 210b generates power to be supplied to the light source circuit 110b. Each power supply circuit 210 operates (constant current control) so that the output current matches the current target value. For example, the power supply circuit 210 adjusts the output current by controlling the on-time of the built-in switching element. Each power supply circuit 210 receives a control signal indicating a current target value from the control circuit 220 and operates in accordance with the input control signal.
The control circuit 220 (control device) controls the power supply circuit 210 based on the instruction signal from the instruction device 810 and the data stored in the storage unit 120. The control circuit 220 is a microcomputer, for example. The control circuit 220 includes, for example, an instruction acquisition unit 221, a reading unit 222, a target value calculation unit 223, and a control unit 224. The instruction acquisition unit 221 receives the instruction signal output from the instruction device 810. The reading unit 222 reads the data stored in the storage unit 120. The target value calculation unit 223 calculates the target value of the current flowing through each light source circuit 110 based on the instruction signal input by the instruction acquisition unit 221 and the data stored in the storage unit 120. The control unit 224 generates and outputs a control signal representing the current target value calculated by the target value calculation unit 223.
The connector 280 (light source connection portion) engages with the connector 292 of the harness 290 to be physically and electrically connected. The connector 280 is electrically connected to the plurality of power supply circuits 210 and the control circuit 220, respectively. The electric power generated by the power supply circuit 210a is supplied to the light source circuit 110a via the harness 290 connected to the connector 280. The electric power generated by the power supply circuit 210b is supplied to the light source circuit 110b via the harness 290 connected to the connector 280. The reading unit 222 reads the data stored in the storage unit 120 via the harness 290 connected to the connector 280.

FIG. 2 is a diagram showing the structure of data stored in the storage unit 120 in this embodiment.
For example, the storage unit 120 stores a plurality of records 410. Each record 410 includes correlated color temperature data 411 and a plurality of current target value data 413. The correlated color temperature data 411 represents the correlated color temperature of the light emitted from the lighting device 800. The current target value data 413 represents a target value of a current to be passed through the light source circuit 110 so that the correlated color temperature of the light emitted from the lighting device 800 becomes the correlated color temperature represented by the correlated color temperature data 411. The current target value data 413a represents the target value of the current that should flow through the light source circuit 110a, and the current target value data 413b represents the target value of the current that should flow through the light source circuit 110b.
For example, the record 410a indicates that when the current flowing through the light source circuit 110a is 0 mA and the current flowing through the light source circuit 110b is 450 mA, the correlated color temperature of the light emitted from the lighting device 800 is 3000K. The record 410b indicates that when the current flowing through the light source circuit 110a is 200 mA and the current flowing through the light source circuit 110b is 250 mA, the correlated color temperature of the light emitted from the lighting device 800 is 4000K. The record 410c indicates that the correlated color temperature of the light emitted from the lighting device 800 is 5000K when the current flowing through the light source circuit 110a is 450 mA and the current flowing through the light source circuit 110b is 0 mA.
Note that the structure of the data stored in the storage unit 120 is an example, and other structures may be used. For example, a correlated color temperature corresponding to each record 410 may be determined in advance, and each record 410 may include only the current target value data 413 without including the correlated color temperature data 411.

FIG. 3 is a flowchart showing the flow of the lighting process S610 in this embodiment.
In the lighting process S610, the control circuit 220 controls the power supply circuit 210 to turn on the light source of the light source circuit 110. The lighting process S610 includes, for example, an instruction acquisition process S611, a reading process S612, a target value calculation process S613, and a control process S614.
In the instruction acquisition step S611, the instruction acquisition unit 221 receives the instruction signal output from the instruction device 810, and acquires the correlated color temperature T represented by the input instruction signal.
In the reading step S612, the reading unit 222 reads the data stored in the storage unit 120.
In the target value calculation step S613, the target value calculation unit 223 calculates the correlated color temperature of the light emitted from the lighting device 800 based on the data read by the reading unit 222 in the reading step S612, and the instruction acquisition unit in the instruction acquisition step S611. In order to match the correlated color temperature T acquired by 221, the target value of the current to be passed through each light source circuit 110 is calculated.
In the control step S614, the control unit 224 generates a control signal for controlling each power supply circuit 210 based on the current target value calculated by the target value calculation unit 223 in the target value calculation step S613. When the power supply circuits 210a and 210b operate according to the control signal generated by the control unit 224, a current that substantially matches the target value calculated by the target value calculation unit 223 flows through the light source circuits 110a and 110b. Thus, the lighting device 800 emits light having a correlated color temperature that substantially matches the correlated color temperature T indicated by the instruction signal.

The control unit 224 gradually increases the target value of the current indicated by the control signal to each power supply circuit 310, for example, starting from 0, and after a predetermined time has elapsed, the target value calculation unit 223 It may be configured to match the calculated target value of current. By performing the fade-in operation in this manner, the lighting can be started without waiting for the target value calculation unit 223 to calculate the target value, so that the delay time until the lighting device 800 starts lighting can be reduced and the lighting can be performed. A sense of discomfort at the time can be reduced.
Similarly, when the dimming degree or the correlated color temperature is changed by the instruction signal, the control unit 224 also gradually and gradually changes the target value of the current indicated by the control signal to each power supply circuit 310. It may be a configuration.

FIG. 4 is a diagram for explaining the processing of the target value calculation step S613 in this embodiment.
The horizontal axis represents the correlated color temperature. The vertical axis represents the target current value. A white square indicates a target value of a current to be supplied to the light source circuit 110a represented by data stored in the storage unit 120. A white circle indicates a target value of the current to be passed through the light source circuit 110b represented by the data stored in the storage unit 120. A solid line 511 is a line segment connecting the white squares. A broken line 512 is a line segment connecting white circles.

The target value calculation unit 223 calculates the target value of the current to be passed through each light source circuit 110 by, for example, linear interpolation. That is, the target value calculation unit 223 calculates the target value of the current that should flow through the light source circuit 110 a based on the solid line 511, and calculates the target value of the current that should flow through the light source circuit 110 b based on the broken line 512.
Specifically, for example, the target value calculating unit 223 matches the correlated color temperature represented by the correlated color temperature data 411 with the correlated color temperature T acquired by the instruction acquiring unit 221 from the data read by the reading unit 222. The record 410 to be searched is searched.
When the record 410 with the correlated color temperature is found, the target value calculation unit 223 sets the current target value represented by the current target value data 413 included in the record 410 to the current value to be supplied to each light source circuit 110. And
When the record 410 having the same correlated color temperature is not found, the target value calculation unit 223 reads from the data read by the reading unit 222 the record 410 whose correlated color temperature represented by the correlated color temperature data 411 is smaller than the correlated color temperature T. Among them, the record 410 having the maximum correlated color temperature represented by the correlated color temperature data 411 is searched. Assume that the correlated color temperature represented by the correlated color temperature data 411 included in the record 410 is T ₁ and the current target value represented by the current target value data 413a is I ₁ . The target value calculation unit 223 includes the correlated color temperature represented by the correlated color temperature data 411 in the record 410 in which the correlated color temperature represented by the correlated color temperature data 411 is greater than the correlated color temperature T from the data read by the reading unit 222. Look for the record 410 with the smallest. Assume that the correlated color temperature represented by the correlated color temperature data 411 included in the record 410 is T ₂ , and the current target value represented by the current target value data 413 a is I ₂ . Target value calculation unit 223, the product _(T 2 -T) _{I 1} of the difference obtained by subtracting the correlated color temperature T from correlated color temperature _{T 2} and _(T 2 -T) and a current target value _{I 1,} the correlated color temperature T The sum of the difference (T−T ₁ ) obtained by subtracting the correlated color temperature T ₁ from the product (T−T ₁ ) I ₂ of the current target value I ₂ and the correlated color temperature T ₁ from the correlated color temperature T ₂ The quotient divided by the subtracted difference (T ₂ −T ₁ ) is calculated and set as the target value I of the current to be passed through the light source circuit 110a. The target value calculation unit 223 calculates the target value of the current to be passed through the light source circuit 110b in the same manner for the light source circuit 110b.

The target value calculation unit 223 calculates the target value of the current in this manner, so that the light source circuit 110 can be used even when the storage unit 120 does not store the record 410 corresponding to the correlated color temperature indicated by the instruction signal. It is possible to calculate a target value of the current to be supplied to the current. Thereby, the amount of data to be stored in the storage unit 120 can be suppressed.
The interpolation method is not limited to linear interpolation, and may be other methods such as parabolic interpolation.

  Next, a method for manufacturing the light source module 100 will be described.

First, the light source module 100 is assembled by mounting a light source such as an LED element constituting the light source circuit 110, an EEPROM serving as the storage unit 120, a connector 180, and the like on the printed wiring board.
Next, power is supplied to the assembled light source module 100, the light source is actually turned on, and the characteristics of the light emitted from the light source module 100 are measured.
Finally, based on the measured light characteristics, data to be stored in the storage unit 120 is calculated, and the calculated data is written in the storage unit 120.

FIG. 5 is a block configuration diagram showing the configuration of the measuring apparatus 300 in this embodiment.
The measuring device 300 (manufacturing device) supplies power to the light source module 100 and measures the characteristics of light emitted from the light source module 100. The measuring apparatus 300 calculates data to be stored in the storage unit 120 based on the measurement result, and writes the calculated data in the storage unit 120.

  The harness 390 physically and electrically connects the light source module 100 and the measurement apparatus 300. The harness 390 corresponds to the harness 290 of the lighting device 800. The harness 390 includes, for example, two connectors 391 and 392 and a cable 393. The connector 391 engages with the connector 180 of the light source module 100 to be physically and electrically connected. The cable 393 physically and electrically connects the two connectors 391 and 392. The harness 390 may be formed integrally with the measuring device 300 or the light source module 100.

The measurement apparatus 300 includes, for example, a plurality of power supply circuits 310, a control circuit 320, a measurement unit 330, and a connector 380.
The power supply circuit 310 converts the power supplied from the power supply AC into power supplied to the light source circuit 110. The power supply circuit 310 corresponds to the power supply circuit 210 of the lighting device 800. The power supply circuit 310a generates power to be supplied to the light source circuit 110a, and the power supply circuit 310b generates power to be supplied to the light source circuit 110b. Each power supply circuit 310 operates so that the output current matches the current target value.
The measuring unit 330 measures the light flux emitted from the light source module 100, the correlated color temperature, the chromaticity coordinates, and the like. The measurement unit 330 outputs a measurement result signal representing the measurement result.
The control circuit 320 controls the power supply circuit 310 to turn on the light source of the light source module 100, calculates data to be stored in the storage unit 120 based on the result measured by the measurement unit 330, and stores the calculated data in the storage unit Write to 120. The control circuit 320 includes, for example, a target setting unit 321, a target value calculation unit 323, a control unit 324, and a writing unit 325. The target setting unit 321 sets targets such as a luminous flux of light emitted from the light source module 100, a correlated color temperature, and chromaticity coordinates. The target value calculation unit 323 (data calculation unit) calculates a target value of a current to be passed through each light source circuit 110. The target value calculation unit 323 receives the measurement result signal output from the measurement unit 330, changes the target value based on the input measurement result signal, and the target setting unit 321 sets the result measured by the measurement unit 330. Find the target value that matches the target you set. The control unit 324 generates a control signal for controlling each power supply circuit 310 based on the current target value calculated by the target value calculation unit 323. When the result measured by the measurement unit 330 matches the target set by the target setting unit 321, the writing unit 325 stores the result in the storage unit 120 based on the current target value calculated by the target value calculation unit 323. Data is generated, and the generated data is stored in the storage unit 120.
The connector 380 engages with the connector 392 of the harness 390 to be physically and electrically connected. The connector 380 is electrically connected to the plurality of power supply circuits 310 and the control circuit 320, respectively. The electric power generated by the power supply circuit 310a is supplied to the light source circuit 110a via the harness 390 connected to the connector 380. The electric power generated by the power supply circuit 310b is supplied to the light source circuit 110b via the harness 390 connected to the connector 380. In addition, the storage unit 120 acquires and stores the data sent by the writing unit 325 via the harness 390 connected to the connector 380.

FIG. 6 is a flowchart showing the flow of the writing process S630 in this embodiment.
In the writing process S630, the measuring apparatus 300 supplies power to the light source module 100 to turn on the light source, calculates data to be stored in the storage unit 120, and writes the data to the storage unit 120. For example, the writing process S630 compares the light source selection step S631, the two target value calculation steps S632 and S642, the two lighting steps S633 and S643, the two measurement steps S634 and S644, and the target setting step S641. It has process S645, target value adjustment process S646, and writing process S647.

In the light source selection step S <b> 631, the target value calculation unit 323 selects one light source circuit 110 to be lit from the plurality of light source circuits 110. When all the light source circuits 110 have been selected and there is no light source circuit 110 that has not yet been selected, the target value calculation unit 323 advances the writing process S630 to the target setting step S641. When there is a light source circuit 110 that has not yet been selected, the target value calculation unit 323 selects one light source circuit 110 from among the light source circuits 110 that have not yet been selected, and the writing process S630 proceeds to the target value calculation step S632. Proceed.
In the target value calculation step S632, the target value calculation unit 323 sets the target value of the current to be supplied to the light source circuit 110 selected in the light source selection step S631 to a predetermined value, and the current value to be supplied to the other light source circuits 110. Set the target value to 0.
In the lighting step S633, the control unit 324 generates a control signal for controlling each power supply circuit 310 based on the target value set by the target value calculation unit 323 in the target value calculation step S632. Each power supply circuit 310 operates in accordance with a control signal generated by the control unit 324. As a result, only the light source circuit 110 selected in the light source selection step S631 is turned on.
In the measurement step S634, the measurement unit 330 measures a light flux emitted from the light source module 100, a correlated color temperature, and the like. The target value calculation unit 323 stores the result measured by the measurement unit 330. The target value calculation unit 323 returns the writing process S630 to the light source selection step S631, and selects the next light source circuit 110.

In the target setting step S641, the target setting unit 321 selects one correlated color temperature from a plurality of predetermined correlated color temperatures. When all of the plurality of correlated color temperatures have been selected and there is no correlated color temperature that has not yet been selected, the target setting unit 321 ends the writing process S630. If there is a correlated color temperature that has not yet been selected, the target setting unit 321 selects one correlated color temperature from among the correlated color temperatures, and uses the selected correlated color temperature as a target for the correlated color temperature of the light emitted from the light source module 100. Set to.
In the target value calculation step S642, the target value calculation unit 323 calculates the target value of the current that flows to each light source circuit 110 based on the result measured by the measurement unit 330 in the measurement step S634. In addition, since it adjusts later, the target value which the target value calculation part 323 calculates in target value calculation process S642 may be approximate. For example, the current flowing through the light source circuit 110a _{I a,} when the current flowing through the light source circuit 110b to 0, the light flux [Phi _a measurement unit 330 is measured, correlated color temperature and a _{T a.} When the current flowing through the light source circuit 110a is 0 and the current flowing through the light source circuit 110b is _Ib , the light flux measured by the measurement unit 330 is Φ _b , and the correlated color temperature is T _b . Further, it is assumed that the target value of the light flux emitted from the light source module 100 is Φ and the target value of the correlated color temperature is T. Target value calculation unit 323, correlated color temperature difference of _{(T-T b)} obtained by subtracting the correlated color temperature _{T b} from T, correlated color temperature _T difference obtained by subtracting the correlated color temperature _{T b} from _{a (T a} -T _b and divided by), and the quotient [Phi / [Phi _a divided by light beam [Phi _a light flux [Phi, the product of the current _{I a [(T-T b} ) / (T a -T b) · Φ / Φ a · I _a ] is calculated and set as a target value of the current to be passed through the light source circuit 110a. The target value calculation unit 323, a difference a difference obtained by subtracting the correlated color temperature T from correlated color temperature _{T a} and _(T a -T), obtained by subtracting the correlated color temperature _{T b} from the correlated color temperature _{T a (T a} - and divided by T _b), and the quotient [Phi / [Phi _b divided by light beam [Phi _b the light flux [Phi, the product of the current _{I b [(T a -T)} / (T a -T b) · Φ / Φ _b · I _b ] is calculated and set as the target value of the current to be passed through the light source circuit 110b.
In the lighting step S643, the control unit 324 controls each power supply circuit 310 based on the current target value calculated by the target value calculation unit 323 in the target value calculation step S642 (or target value adjustment step S646 described later). Generate a signal. Each power supply circuit 310 operates in accordance with a control signal generated by the control unit 324. As a result, a current that substantially matches the current target value calculated by the target value calculation unit 323 flows through each light source circuit 110.
In the measurement step S644, the measurement unit 330 measures the luminous flux of the light emitted from the light source module 100, the correlated color temperature, and the like.
In the comparison step S645, the target value calculation unit 323 compares the target set by the target setting unit 321 in the target setting step S641 with the result measured by the measurement unit 330 in the measurement step S644, and the light source module 100 emits. It is determined whether the luminous flux of the light and the correlated color temperature match the target. For example, an allowable error of the luminous flux or the correlated color temperature is determined in advance, and the target value calculation unit 323 determines that the difference between the luminous flux or the correlated color temperature measured by the measurement unit 330 and the target value of the luminous flux or the correlated color temperature is an allowable error. If it is within, it is determined that they match. When it is determined that they match, the target value calculation unit 323 advances the writing process S630 to the writing process S647. When it is determined that they do not match, the target value calculation unit 323 advances the writing process S630 to the target value adjustment step S646.
In the target value adjustment step S646, the target value calculation unit 323 determines each light source circuit 110 based on the target set by the target setting unit 321 in the target setting step S641 and the result measured by the measurement unit 330 in the measurement step S644. Adjust the target value of the current to be passed through. For example, when the correlated color temperature of the light emitted from the light source module 100 is lower than the target, the target value calculation unit 323 increases the target value of the current to be passed through the light source circuit 110 having the high correlated color temperature of the emitted light and emits the target value. The target value of the current to be passed through the light source circuit 110 having a low correlated color temperature of light is reduced. Conversely, when the correlated color temperature of the light emitted from the light source module 100 is higher than the target, the target value calculation unit 323 reduces the target value of the current to be passed through the light source circuit 110 having the high correlated color temperature of the emitted light, and emits the light. The target value of the current to be passed through the light source circuit 110 having a low correlated color temperature of the light to be increased is increased. When the light flux emitted from the light source circuit 110 is less than the target, the target value calculation unit 323 increases the target value of the current to be passed through each light source circuit 110. Conversely, when the light flux emitted from the light source circuit 110 is greater than the target, the target value calculation unit 323 decreases the target value of the current to be passed through each light source circuit 110. The target value calculation unit 323 returns the writing process S630 to the lighting step S643, and the light source circuit 110 is turned on based on the new target value.

  In the writing step S647, the writing unit 325 causes the storage unit 120 to store based on the target set by the target setting unit 321 in the target setting step S641 and the target value of the current calculated by the target value calculation unit 323. A record 410 is generated. For example, the correlated color temperature data 411 of the record 410 generated by the writing unit 325 represents the target of the correlated color temperature set by the target setting unit 321. The current target value data 413a represents the target value of the current to be passed through the light source circuit 110a calculated by the target value calculation unit 323. The current target value data 413b represents the target value of the current to be passed through the light source circuit 110b calculated by the target value calculation unit 323. The writing unit 325 stores the generated record 410 in the storage unit 120. The writing unit 325 returns the writing process S630 to the target setting step S641, and the target setting unit 321 sets the next target.

  In this way, while changing the current flowing to each light source circuit 110, the luminous flux of the light emitted by the light source module 100 and the correlated color temperature are measured, and the current flowing to each light source circuit 110 when it matches the target, The current value is stored in the storage unit 120 as a target current value. Since it is based on the actual measurement results, even if there are variations in the characteristics of the light source of the light source circuit 110, if the current of the target value stored in the storage unit 120 is supplied to each light source circuit 110, the desired light flux or Correlated color temperature can be obtained.

  The writing unit 325 does not write the generated records 410 one by one in the storage unit 120, but temporarily stores (buffers) the generated records 410 to generate the records 410 for all targets. After that, the configuration may be such that the generated records 410 are collectively written in the storage unit 120.

  As described above, since the storage unit 120 stores values based on the characteristics measured by actually turning on the light source, the illuminating device 800 has a desired light flux and correlated color temperature regardless of variations in the characteristics of the light source. Can emit light.

  In addition, a method of measuring the characteristics of each light source before assembling the light source module 100 and manufacturing the light source circuit 110 and the light source module 100 by combining a plurality of light sources selected so as to cancel the variation in the characteristics of the light sources. In comparison, the number of times of measuring the characteristics of the light source can be reduced. In addition, if a value is written in the storage unit 120, it is not necessary to classify and manage the light source modules 100 according to the difference in characteristics, so that it is not necessary to manage the light source modules 100 in the manufacturing process of the lighting device 800. For this reason, the manufacturing cost of the illuminating device 800 can be held down.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  In this embodiment, a configuration will be described in which data is written to the storage unit 120 not after the light source module 100 is manufactured but after the lighting device 800 is assembled. For example, in the final stage of the manufacturing process of the lighting device 800, data may be written in the storage unit 120, or the lighting device 800 is shipped without writing data in the storage unit 120, and the lighting device 800 is actually used. Data may be written in the storage unit 120 after the lighting device 800 is installed.

FIG. 7 is a block configuration diagram showing the configuration of the illumination device 800 and the measurement device 300 in this embodiment.
The measuring apparatus 300 (chromaticity measuring device) includes a measuring unit 330 and a control circuit 320. The control circuit 320 includes a target setting unit 321, a target value calculation unit 323, and a target value notification unit 326. The measurement unit 330, the target setting unit 321 and the target value calculation unit 323 are the same as those described in the first embodiment. The target value notification unit 326 (measurement notification unit) notifies the lighting device 200 of the current target value calculated by the target value calculation unit 323.
The control circuit 220 includes a writing unit 225 and a target value acquisition unit 226 in addition to the configuration described in the first embodiment. The target value acquisition unit 226 (measurement acquisition unit) acquires the current target value notified by the measurement apparatus 300. When the target value acquisition unit 226 acquires the current target value, the target value calculation unit 223 uses the current target value acquired by the target value acquisition unit 226 as it is as the target value of the current to be passed through each light source circuit 110. When the measurement result measured by the measurement unit 330 matches the target set by the target setting unit 321, the writing unit 225 stores the storage unit 120 based on the current target value acquired by the target value acquisition unit 226. Power data is generated, and the generated data is written into the storage unit 120 and stored. For example, when the measurement result measured by the measurement unit 330 matches the target set by the target setting unit 321, the target value notification unit 326 sends a special current target value that means that to the lighting device 200. Notify them. If the acquired current target value is the special value, the target value acquisition unit 226 determines that the measurement result measured by the measurement unit 330 matches the target set by the target setting unit 321. The writing unit 225 generates data to be stored in the storage unit 120 based on the current target value acquired by the target value acquisition unit 226 immediately before that.

  Thus, by measuring the light emitted from the light source module 100 after the assembly of the lighting device 800, not in the manufacturing process of the light source module 100, measurement in an environment closer to the actual use environment can be performed. For this reason, the error resulting from the difference between a measurement environment and a use environment can be suppressed, and the illuminating device 800 can radiate | emit the light of a desired light beam and correlation color temperature.

Embodiment 3 FIG.
A third embodiment will be described with reference to FIGS.
Note that portions common to Embodiment 1 or Embodiment 2 are denoted by the same reference numerals and description thereof is omitted.

  In this embodiment, when the dimming degree of the lighting device 800 is changed by appropriately dealing with the case where the correlated color temperature of the light emitted from the light source of the light source circuit 110 changes due to the current flowing through the light source circuit 110 However, a configuration for emitting light having a desired correlated color temperature will be described.

The configuration of lighting apparatus 800 in this embodiment is the same as that described in Embodiment 1 or Embodiment 2.
The indication device 810 outputs an indication signal that indicates the dimming degree of the light emitted from the lighting device 800 and the correlated color temperature.

FIG. 8 is a diagram showing the structure of data stored in the storage unit 120 in this embodiment.
The record 410 includes dimming degree data 412 in addition to the data described in the first embodiment. The dimming degree data 412 represents the dimming degree of light emitted from the lighting device 800. For example, the record 410a indicates that when the current flowing through the light source circuit 110a is 5 mA and the current flowing through the light source circuit 110b is 40 mA, the illumination device 800 emits light having a dimming degree of 10% and a correlated color temperature of 3000K. The record 410b indicates that when the current flowing through the light source circuit 110a is 0 mA and the current flowing through the light source circuit 110b is 450 mA, the lighting device 800 emits light having a correlated color temperature of 3000K with a dimming degree of 100%.

The flow of the lighting process S610 in this embodiment is the same as that described in the first embodiment.
In the instruction acquisition step S611, the instruction acquisition unit 221 receives the instruction signal output from the instruction device 810. The instruction acquisition unit 221 acquires the dimming degree d and the correlated color temperature T represented by the input instruction signal.

FIG. 9 is a diagram for explaining the processing of the target value calculation step S613 in this embodiment.
The horizontal axis represents the correlated color temperature. The vertical axis represents the target current value. A white square indicates a target value (a dimming degree of 100%) of a current to be supplied to the light source circuit 110a represented by data stored in the storage unit 120. A white triangle indicates a target value (a dimming degree of 10%) of a current to be passed through the light source circuit 110a represented by data stored in the storage unit 120. A solid line 511 is a line segment connecting the white squares. A broken line 513 is a line segment connecting white triangles.

The target value calculation unit 223 calculates the target value of the current to be passed through each light source circuit 110 by linear interpolation, for example, as in the first embodiment. Unlike Embodiment 1, there are two variables: correlated color temperature and dimming degree.
For example, the target value calculation unit 223 has the maximum correlation color temperature represented by the correlation color temperature data 411 from the data read by the reading unit 222 among the correlation color temperatures T acquired by the instruction acquisition unit 221, and The record 410 having the maximum dimming degree represented by the dimming degree data 412 is smaller than the dimming degree d acquired by the instruction acquisition unit 221. Assume that the correlated color temperature represented by the correlated color temperature data 411 included in the record 410 is T ₁ , the dimming degree represented by the dimming degree data 412 is d ₁ , and the current target value represented by the current target value data 413 a is I ₁₁ . Further, the target value calculation unit 223 is the largest among the data read by the reading unit 222 and the correlated color temperature represented by the correlated color temperature data 411 is smaller than the correlated color temperature T acquired by the instruction acquisition unit 221. In addition, the record 410 that has the smallest dimming degree represented by the dimming degree data 412 is larger than the dimming degree d acquired by the instruction acquisition unit 221. Correlated color temperature correlated color temperature data 411 included in the record 410 represented is assumed to be T _1. Further, the dimming degree represented by the dimming degree data 412 included in the record 410 is d ₂ , and the current target value represented by the current target value data 413 a is I ₁₂ . Furthermore, the target value calculation unit 223 is the smallest among the data read by the reading unit 222 and the correlated color temperature represented by the correlated color temperature data 411 is greater than the correlated color temperature T acquired by the instruction acquisition unit 221. In addition, the record 410 having the maximum dimming degree represented by the dimming degree data 412 is smaller than the dimming degree d acquired by the instruction acquisition unit 221. Dimming represented dimming data 412 included in this record 410 is assumed to be d _1. Further, the correlated color temperature represented by the correlated color temperature data 411 included in the record 410 is T ₂ , and the current target value represented by the current target value data 413a is I ₂₁ . Further, the target value calculation unit 223 is the smallest among the data read by the reading unit 222 and the correlated color temperature represented by the correlated color temperature data 411 is greater than the correlated color temperature T acquired by the instruction acquisition unit 221. In addition, the record 410 that has the smallest dimming degree represented by the dimming degree data 412 is larger than the dimming degree d acquired by the instruction acquisition unit 221. Assume that the correlated color temperature represented by the correlated color temperature data 411 included in this record 410 is T ₂ , and the dimming degree represented by the dimming degree data 412 is d ₂ . Moreover, the current target value representing the current target value data 413a included in the record 410 and _{I 22.} Target value calculation unit 223, dimming _d difference obtained by subtracting the ₂ color dimming ratio d _(d 2 -d) the difference obtained by subtracting the correlated color temperature T from correlated color temperature _{T 2 (T} 2 -T) and a current target value and the product of the I _11, dimming difference obtained by subtracting the dimming degree _{d 1} from d _{(d-d 1)} and the difference obtained by subtracting the correlated color temperature T from correlated color temperature _{T 2 (T} 2 -T) and a current target value and the product of the I _12, dimming _d difference obtained by subtracting the ₂ color dimming ratio d _(d 2 -d) the difference obtained by subtracting the correlated color temperature _{T 1} of the correlated color temperature _T (T-T ₁₎ and the current target value Product of I ₂₁ , difference (d−d ₁ ) obtained by subtracting dimming degree d ₁ from dimming degree d, difference (T−T ₁ ) obtained by subtracting correlated color temperature T ₁ from correlated color temperature T, and current target value total, dimming degree _d difference obtained by subtracting the ₂ color dimming ratio _{d 1 (d} 2 -d ₁₎ and the correlation from the correlation color temperature _{T 2} of the product of the I ₂₂ By calculating the quotient obtained by dividing the product of the difference obtained by subtracting the temperature _{T 1 (T 2 -T 1)} , the target value I of the current to be supplied to the light source circuit 110a. The target value calculation unit 223 calculates the target value of the current to be passed through the light source circuit 110b in the same manner for the light source circuit 110b.

When the target value calculation unit 223 calculates the target value of the current in this way, the storage unit 120 does not store the record 410 corresponding to the combination of the dimming degree indicated by the instruction signal and the correlated color temperature. Even in this case, the target value of the current to be passed through the light source circuit 110 can be calculated. Thereby, the amount of data to be stored in the storage unit 120 can be suppressed.
Note that the interpolation method is not limited to linear interpolation, and may be other methods such as parabolic interpolation.

The configuration of measuring apparatus 300 in this embodiment is the same as that described in Embodiment 1 or Embodiment 2. In addition, the flow of the writing process S630 in this embodiment is the same as that described in the first embodiment.
In the target setting step S641, the target setting unit 321 selects one correlated color temperature from a plurality of predetermined correlated color temperatures, and sets the dimming degree from the plurality of predetermined dimming degrees. Select one. When all the combinations of the correlated color temperature and the dimming degree have been selected and there is no combination that has not been selected, the target setting unit 321 ends the writing process S630. When there is a combination that has not yet been selected, the target setting unit 321 selects one of the combinations of the correlated color temperature and the dimming degree from among the combinations, and the selected combination is the correlated color of the light emitted by the light source module 100. Set temperature and dimming targets.

  In this way, while changing the current flowing to each light source circuit 110, the luminous flux of the light emitted by the light source module 100 and the correlated color temperature are measured, and the current flowing to each light source circuit 110 when it matches the target, The current value is stored in the storage unit 120 as a target current value. Since it is based on the actual measurement results, even if there are variations in the characteristics of the light source of the light source circuit 110, if the current of the target value stored in the storage unit 120 is supplied to each light source circuit 110, the desired light flux or Correlated color temperature can be obtained.

  Further, not only the correlated color temperature is matched with the target, but also the current when the dimming degree is matched with the target is measured and stored in the storage unit 120, so that the light source circuit 110 is caused by the difference in the current flowing through the light source circuit 110. Even if the luminous flux of light radiated, the correlated color temperature, the chromaticity coordinates, etc. change, if the current of the target value stored in the storage unit 120 is supplied to each light source circuit 110, the desired luminous flux or correlated color The temperature can be obtained.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 3, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  In this embodiment, a configuration is described in which the storage unit 120 stores data representing the relationship between the chromaticity coordinates of light emitted from the light source circuit 110 and the luminous flux with reference to the current flowing through the light source circuit 110. To do.

  The configuration of lighting apparatus 800 in this embodiment is the same as that described in Embodiment 1 or Embodiment 2.

FIG. 10 is a diagram showing the structure of data stored in the storage unit 120 in this embodiment.
The storage unit 120 stores a plurality of records 410. The record 410 includes light source circuit number data 414, current data 415, chromaticity coordinate x data 416, chromaticity coordinate y data 417, and luminous flux data 418. The light source circuit number data 414 represents the number of the light source circuit 110. For example, “1” means the light source circuit 110a, and “2” means the light source circuit 110b. Current data 415 represents a current flowing through the light source circuit 110. The chromaticity coordinate x data 416 represents the x coordinate of the chromaticity coordinate of the light emitted from the light source circuit 110. The chromaticity coordinate y data 417 represents the y coordinate of the chromaticity coordinates of the light emitted from the light source circuit 110. The luminous flux data 418 represents the luminous flux of light emitted from the light source circuit 110.
For example, the record 410a indicates that when the current flowing through the light source circuit 110a is 300 mA, the chromaticity coordinates of the light emitted from the light source circuit 110a are (0.346, 0.359) and the luminous flux is 300 lm. . The record 410b indicates that when the current flowing through the light source circuit 110a is 700 mA, the chromaticity coordinates of the light emitted from the light source circuit 110a are (0.345, 0.356) and the luminous flux is 800 lm.

FIG. 11 is a chromaticity diagram showing the light emitted by the illumination device 800 in this embodiment.
The horizontal axis represents the x coordinate of chromaticity coordinates. The vertical axis represents the y coordinate of the chromaticity coordinate. A broken line 521 represents a black body radiation locus. Dashed lines 522 are line segments that connect fixed points with a predetermined correlation color temperature. White circles represent the chromaticity coordinates of the light emitted from the light source circuit 110a represented by the data stored in the storage unit 120. A white square represents the chromaticity coordinates of the light emitted from the light source circuit 110b represented by the data stored in the storage unit 120. A solid line 523 is a line segment connecting white circles. A solid line 524 is a line segment connecting the white squares. Each thin line 525 is a curve connecting a certain point with a predetermined value of the light flux emitted from the lighting device 800.
If the current passed through the light source circuit 110 is changed in order to change the luminous flux of the light emitted from the light source circuit 110, the chromaticity coordinates of the light emitted from the light source circuit 110 slightly change. For example, when the light source circuit 110a increases the flowing current to increase the luminous flux, the color of the emitted light becomes slightly bluish white.
The lighting device 800 emits light having a chromaticity coordinate at the intersection of a broken line 522 corresponding to the correlated color temperature indicated by the instruction signal and a thin line 525 corresponding to the dimming degree (light beam) indicated by the instruction signal. .

FIG. 12 is a flowchart showing the flow of the target value calculation step S613 in this embodiment.
The target value calculation step S613 includes, for example, a provisional target value setting step S621, a chromaticity coordinate calculation step S622, a luminous flux calculation step S623, a correlated color temperature calculation step S624, a dimming degree calculation step S625, and a convergence determination step S626. And a target value adjustment step S627.
In the provisional target value setting step S <b> 621, the target value calculation unit 223 provisionally determines a target value of a current that flows through each light source circuit 110.
In the chromaticity coordinate calculation step S622, the target value calculation unit 223 uses the target value calculated in the provisional target value setting step S621 (or the target value adjustment step S627) to chromaticity of light emitted from each light source circuit 110. Calculate the coordinates.
In the luminous flux calculation step S623, the target value calculation unit 223 calculates the luminous flux of light emitted by each light source circuit 110 based on the target value calculated in the provisional target value setting step S621 (or target value adjustment step S627). .
In the correlated color temperature calculation step S624, the target value calculation unit 223 uses the chromaticity coordinates calculated in the chromaticity coordinate calculation step S622 and the light emitted from the light source circuit 110 based on the light flux calculated in the light flux calculation step S623. Calculate the chromaticity coordinates of the mixed light. The target value calculation unit 223 converts the calculated chromaticity coordinates into a correlated color temperature using a predetermined conversion formula.
In the dimming degree calculation step S625, the target value calculation unit 223 calculates the light flux of the light emitted from the lighting device 800 based on the light flux calculated in the light flux calculation step S623. The target value calculation unit 223 calculates the ratio of the calculated light flux to the predetermined maximum light flux as the dimming degree.
In the convergence determination step S626, the target value calculation unit 223 determines whether the calculation has converged. For example, the target value calculator 223 has a difference between the correlated color temperature calculated in the correlated color temperature calculation step S624 and the correlated color temperature indicated by the instruction signal within a predetermined tolerance, and calculates the dimming degree. When the dimming degree calculated in step S625 and the dimming degree instructed by the instruction signal are within a predetermined allowable error, it is determined that the light has converged. When it determines with having converged, the target value calculation part 223 complete | finishes target value calculation process S613. When it determines with having not yet converged, the target value calculation part 223 advances target value calculation process S613 to target value adjustment process S627.
In the target value adjustment step S627, the target value calculation unit 223 adjusts the target value of the current to be passed through each light source circuit 110. For example, when the correlated color temperature calculated in the correlated color temperature calculation step S624 is lower than the instructed correlated color temperature, the target value calculation unit 223 calculates the current to be supplied to the light source circuit 110 having a high correlated color temperature of emitted light. The target value is increased, and the target value of the current to be passed through the light source circuit 110 having a low correlated color temperature of emitted light is decreased. Conversely, when the correlated color temperature calculated in the correlated color temperature calculation step S624 is higher than the instructed correlated color temperature, the target value calculation unit 223 causes the current to flow through the light source circuit 110 having a high correlated color temperature of emitted light. The target value of the current to be passed through the light source circuit 110 having a low correlated color temperature of the emitted light is increased. When the dimming degree calculated in the dimming degree calculating step S625 is lower than the instructed dimming degree, the target value calculation unit 223 increases the target value of the current to be passed through each light source circuit 110. Conversely, when the dimming degree calculated in the dimming degree calculating step S625 is higher than the instructed dimming degree, the target value calculation unit 223 decreases the target value of the current to be passed through each light source circuit 110. The target value calculation unit 223 returns the target value calculation step S613 to the chromaticity coordinate calculation step S622, and calculates chromaticity coordinates and the like based on the adjusted target value.

  In addition, when processing of target value calculation process S613 takes time, the control part 224 produces | generates a control signal based on a provisional target value without waiting for a target value to converge, and the light source circuit 110 is turned on. The structure to be made may be sufficient. Thereby, the delay time until the lighting device 800 starts lighting can be reduced.

FIG. 13 is a block configuration diagram showing the configuration of the measuring apparatus 300 in this embodiment.
The control circuit 320 includes a target value calculation unit 323, a control unit 324, and a writing unit 325.
The target value calculation unit 323 selects the light source circuit 110 one by one, selects the current target value one by one from the plurality of current target values, and sets the target value of the current to be passed through the selected light source circuit 110, The target value of the current to be passed through the other light source circuit 110 is set to zero.
The control unit 324 generates a control signal for controlling the power supply circuit 310 based on the current target value calculated by the target value calculation unit 323.
The writing unit 325 sends the target value calculated by the target value calculating unit 323 and the measurement result such as the luminous flux and chromaticity coordinates measured by the measuring unit 330 by causing the current of the target value to flow through the light source circuit 110 of the light source module 100. Based on the above, the data stored in the storage unit 120 is generated. The writing unit 325 writes the generated data in the storage unit 120 and stores it.

FIG. 14 is a flowchart showing the flow of the writing process S630 in this embodiment.
The writing process S630 includes a light source selection step S631, a target value calculation step S632, a lighting step S633, a measurement step S634, and a writing step S647.

In the light source selection step S <b> 631, the target value calculation unit 323 selects one light source circuit 110 to be lit from the plurality of light source circuits 110. When all the light source circuits 110 have been selected and there is no light source circuit 110 that has not yet been selected, the target value calculation unit 323 ends the writing process S630. When there is a light source circuit 110 that has not yet been selected, the target value calculation unit 323 selects one light source circuit 110 from among the light source circuits 110 that have not yet been selected, and the writing process S630 proceeds to the target value calculation step S632. Proceed.
In the target value calculation step S632, the target value calculation unit 323 selects one target value of the current to be passed through the light source circuit 110 selected in the light source selection step S631 from the plurality of current target values. If all current target values have been selected for the light source circuit 110 and there is no current target value that has not yet been selected, the target value calculation unit 323 returns the writing process S630 to the light source selection step S631, and the next light source The circuit 110 is selected. If there is a current target value that has not yet been selected, the target value calculation unit 323 selects one current target value from among the current target values that have not yet been selected, and the light source circuit 110 selected in the light source selection step S631. The target value of the current to be passed. The target value calculation unit 323 sets the target value of the current to be supplied to the light source circuits 110 other than the light source circuit 110 selected in the light source selection step S631 to zero.
In the lighting step S633, the control unit 324 generates a control signal for controlling each power supply circuit 310 based on the target value set by the target value calculation unit 323 in the target value calculation step S632. Each power supply circuit 310 operates in accordance with a control signal generated by the control unit 324. As a result, only the light source circuit 110 selected in the light source selection step S631 is turned on.
In the measurement step S634, the measurement unit 330 measures the light flux, chromaticity coordinates, and the like of the light emitted from the light source module 100.
In the writing step S647, the writing unit 325 stores the storage unit based on the target value of the current calculated by the target value calculating unit 323 in the target value calculating step S632 and the result measured by the measuring unit 330 in the measuring step S634. A record 410 to be stored in 120 is generated. For example, the light source circuit number data 414 of the record 410 generated by the writing unit 325 represents the number of the light source circuit 110 selected by the target value calculation unit 323 in the light source selection step S631. The current data 415 represents the current target value selected by the target value calculation unit 323 in the target value calculation step S632. The chromaticity coordinate x data 416 and the chromaticity coordinate y data 417 represent the chromaticity coordinates measured by the measurement unit 330 in the measurement step S634. The luminous flux data 418 represents the luminous flux measured by the measurement unit 330 in the measurement step S634. The writing unit 325 stores the generated record 410 in the storage unit 120. The writing unit 325 returns the writing process S630 to the target value calculating step S632, and the target value calculating unit 323 selects the next current target value.

  In this manner, a current is supplied to each light source circuit 110 to actually measure the luminous flux and chromaticity coordinates of the emitted light, and the measurement result is stored in the storage unit 120. Based on the actual measurement results, even if there are variations in the characteristics of the light source of the light source circuit 110, if the currents flowing through the respective light source circuits 110 are calculated based on the data stored in the storage unit 120, A desired dimming degree and correlated color temperature can be obtained.

As described above, the configuration described in each embodiment is an example, and another configuration may be used. For example, the structure which combined the structure demonstrated in different embodiment may be sufficient, and the structure which replaced the structure of the non-essential part with the other structure may be sufficient.
For example, the lighting device 800 may be configured to emit light having a predetermined correlated color temperature with a predetermined brightness without having a light control function or a function of changing the correlated color temperature.
Further, the structure of data stored in the storage unit 120 is not limited to the record format, and may be, for example, a table format (LED current setting table). The data stored in the storage unit 120 may include data representing the value of the voltage applied to both ends of the light source circuit 110 instead of the target value of the current passed through the light source circuit 110. Further, the data stored in the storage unit 120 may include data representing the number of light sources (the number of LEDs mounted) included in the light source circuit 110. When the data stored in the storage unit 120 includes the value of the voltage applied to both ends of the light source circuit 110 and the number of light sources, the control unit 224 determines the voltage generated by the power supply circuit 310 based on the data by the control signal If the instruction is given, the power supply circuit 310 can generate a voltage suitable for the light source circuit 110, so that it is possible to prevent failure due to overvoltage, overcurrent, or the like, or shortening the life.

  100 light source module, 110 light source circuit, 120 storage unit, 180, 280, 291, 292, 380, 391, 392 connector, 200 lighting device, 210, 310 power supply circuit, 220, 320 control circuit, 221 instruction acquisition unit, 222 reading Unit, 223, 323 target value calculation unit, 224, 324 control unit, 225, 325 writing unit, 226 target value acquisition unit, 290, 390 harness, 293, 393 cable, 300 measuring device, 321 target setting unit, 326 target Value notification unit, 330 measurement unit, 410 record, 411 correlated color temperature data, 412 dimming degree data, 413 current target value data, 414 light source circuit number data, 415 current data, 416 chromaticity coordinate x data, 417 chromaticity coordinate y Data, 418 Luminous flux data, 511, 523 524 Solid line, 512, 513, 521, 522 Broken line, 525 Thin line, 800 Illumination device, 810 Indicating device, AC power supply, S610 lighting processing, S611 instruction obtaining step, S612 reading step, S613, S632, S642 Target value calculating step, S614 Control step, S621 provisional target value setting step, S622 chromaticity coordinate calculation step, S623 luminous flux calculation step, S624 correlated color temperature calculation step, S625 dimming degree calculation step, S626 convergence determination step, S627, S646 target value adjustment step, S630 Process, S631 light source selection process, S633, S643 lighting process, S634, S644 measurement process, S641 target setting process, S645 comparison process, S647 writing process.

Claims (7)

A light source connection unit that connects a light source module having a light source and a storage unit that stores a value based on characteristics of the light source measured by turning on the light source;
A power supply circuit for supplying power to the light source module connected to the light source connection section;
A reading unit that reads and acquires the value stored in the storage unit of the light source module connected to the light source connection unit;
Based on the value acquired by the reading unit, a target value calculation unit that calculates a target value of a current that flows to the light source of the light source module connected to the light source connection unit;
Until a predetermined time for the target value calculation unit to calculate the target value of current elapses, a current gradually increased from the initial value current flows through the light source of the light source module connected to the light source connection unit. The power supply circuit is controlled, and after the predetermined time has elapsed , the power supply circuit is controlled so that the current of the target value calculated by the target value calculation unit flows through the light source of the light source module connected to the light source connection unit. A lighting device comprising: a control unit. The value stored in the storage unit represents a relationship between a value of a current passed through the light source and at least one of a luminous flux of light emitted from the light source, a chromaticity coordinate, and a correlated color temperature. Item 2. The lighting device according to Item 1. The light source module has a plurality of types of light sources having different chromaticity coordinates of emitted light,
The values stored in the storage unit are the types when at least one of the luminous flux of light mixed with the light emitted from the plurality of types of light sources, the chromaticity coordinates, and the correlated color temperature matches a predetermined target value. The lighting device according to claim 1, wherein the lighting device represents a value of a current passed through the light source. The lighting device is
Obtain the value calculated by the measurement device from the measurement device that measures the characteristics of the light source of the light source module connected to the light source connection unit and calculates the value to be stored in the storage unit of the light source module connected to the light source connection unit A measurement acquisition unit to
The value which the measurement acquisition unit has acquired, any one of claims 1 to 3, characterized in that it comprises a writing section for storing written in the storage unit of the light source module connected to the light source connection portion The lighting device described in 1. And a light source module,
An illuminating device comprising the lighting device according to any one of claims 1 to 4 . A measuring unit for measuring the characteristics of the light source of the light source module,
A data calculation unit that calculates a value to be stored in the storage unit of the light source module based on the measurement result of the measurement unit;
5. A measuring apparatus comprising: a measurement notifying unit that notifies the lighting device according to claim 4 of a value calculated by the data calculating unit. The measuring device is
The measuring apparatus according to claim 6 , further comprising a writing unit that writes and stores the value calculated by the data calculation unit in the storage unit of the light source module.

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