JPH07211462A - Variable color lighting device and variable color lighting system - Google Patents

Abstract

PURPOSE:To simplify wiring using simple constitution. CONSTITUTION:The constitution of a variable color lighting system except for a control part 3 is enclosed in a light main body A. Dimming signals for lamps 1R, 1G, 1B are not directly transmitted from the control part 3 corresponding to a control unit, but signals by which the dimming signals for the lamps 1R, 1G, 1B can be determined are transmitted. The dimming data computing portion 14 of the light main body A computes the dimming signals for the lamps 1R, 1G, 1B. Therefore the kinds of signals to be transmitted to the light main body A from the control pant 3, and thus the number of wires, are reduced. Also, the constitution does not become complex since special transmission signals such as those for a multiplex transmission system are not employed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is provided with a plurality of light sources having different emission colors, and emits illumination light obtained by mixing lights from the light sources.
The present invention relates to a variable color lighting device capable of changing the light color of the illumination light, and a variable color lighting system configured by using a plurality of the variable color lighting devices.

[0002]

2. Description of the Related Art The structure of a conventional variable color lighting device is shown in FIG. This variable color lighting device includes a lamp body A and a control device B that adjusts the light color of the illumination light of the lamp body A. The lamp body A is composed of a plurality of lamps 1 as light sources having different emission colors, and a lighting circuit 2 for individually lighting the respective lamps 1. Here, the lighting circuit 2 can perform so-called dimming lighting in which the power supplied to the lamp 1 is adjusted to change the light amount of the lamp 1. In the case of FIG. 15, for example, the following description will be made assuming that a lamp that emits each of the three primary colors of red, green, and blue light is provided. Therefore, if necessary, red, green, lamp 1 1 _R, 1 _G that emits blue light, 1 _B and called, respectively lamp 1 _R, 1 _G, 1 a lighting circuit 2 for lighting the _B 2 _R,
Called 2 _G and 2 _B.

The control unit B is the lamp 1 of the lamp body A._R，
1_G, 1_BOperation to set the light color of the illumination light that mixed the light of
Each lamp 1 based on the settings of the section 3 and the operation section 3._R，
1_G, 1 _BDimming data storage unit 4 for outputting dimming data of
And converting the output of the dimming data storage unit 4 into a dimming signal
Light circuit 2_R, 2_G, 2_BDimming signal converter that outputs to each
It is composed of 5 and 5.

In the operation section 3, in order to obtain desired illumination light.
In addition, the color temperature and brightness are set. Dimming
In the data storage unit 4, the color temperature and brightness set by the operation unit 3
Each lamp 1 from the address determined according to_R, 1_G，
1_BRead out the dimming data of. In addition, it is set by the operation unit 3.
The means for determining the address from the color temperature and brightness
The working unit 3 or the dimming data storage unit 4 is provided. Dimming
The dimming data read out by the data storage unit 4 is converted into a dimming signal.
It is converted into a dimming signal in the unit 5. As this dimming signal
Include a duty signal that indicates the dimming degree in terms of duty, and
Lighting in the form of a voltage signal that indicates the luminous intensity at a DC voltage level
Circuit 2_R, 2_G, 2_BGiven to. Each lighting circuit 2_R，
Two_G, 2_BThen, run based on the dimming signal given to each.
1_R, 1 _G, 1_BLights up. These lamps 1_R, 1
_G, 1_BLights are mixed, and the illumination light of the desired light color is supplied to the lamp.
Obtained from Body A.

FIG. 1 shows another variable color lighting device of this type.
Some are shown in 6. In this variable color lighting device, the lamp body A has a function of correcting a deviation in the color performance of the lamp 1 due to a change over time, and the three primary colors (RG
B) Color sensor 6 for detecting the component, and color sensor 6
A color signal conversion unit 7 for obtaining a light amount ratio of R / G and B / G from the RGB components detected in step S, a color temperature detection unit 8 for detecting a color temperature from a dimming signal provided from the control device B, and a color temperature Each lamp 1 _R corresponding to the color temperature detected by the detector 8
From the reference voltage storage unit 9 that stores the reference light amount ratio (R / G, B / G) of 1 _G and 1 _B , and from the reference voltage storage unit 9 according to the color temperature detected by the color temperature detection unit 8. A comparison unit 10 that compares the read reference light amount ratio with the light amount ratio obtained by the color signal conversion unit 7, and a dimming signal correction unit 11 that corrects the dimming signal based on the output of the comparison unit 10. , A dimming signal storage unit 12 that stores a dimming signal provided from the control device B for correcting the dimming signal.

Incidentally, the dimming signal storage section 12 and the dimming signal correcting section 11 of the lamp body A are deleted, and instead the dimming signal converting section 5 is provided on the lamp body A side, and the control device B to the lamp body A is used. Dimming data is applied to the dimming data, the dimming data itself is corrected by the dimming data correcting unit instead of the dimming signal correcting unit 11 according to the comparison output of the comparing unit 10, and the corrected data is dimmed Alternatively, the signal conversion unit 5 may convert the light control signal into a dimming signal and apply the light control signal to each of the lighting circuits 2 _R , 2 _G , and 2 _B.

In this variable color lighting device, when the color temperature and the brightness are set in the operation unit 3, the dimming data of each of the lamps 1 _R , 1 _G and 1 _B is read from the dimming data storage unit 4. Then, the dimming data is converted into a dimming signal by the dimming signal converter 5 and given to the lamp body A. At this time, assuming that the lamps 1 _R , 1 _G , and 1 _{B of} the lamp body A are not turned on, the color sensor 6 does not detect the RGB components of the illumination light, and the dimming signal correction unit 11 does not operate. Therefore, at this time, the lamps 1 _R , 1 _G , and 1 _B are turned on by the dimming signal stored in the dimming signal storage unit 12. In short,
Lamp 1 with the dimming signal provided from controller B as it is
_R , 1 _G , 1 _B lights up.

As described above, the lamps 1 _R , 1 _G and 1 _B
When is turned on, the color sensor 6 detects RGB components from the mixed illumination light, and the color signal conversion unit 7 outputs R / G,
It is converted into a signal indicating the B / G light amount ratio. On the other hand, the color temperature detector 8 detects the color temperature information currently given from the control device B from the dimming signal. In response to the output of the color temperature detection unit 8, the reference voltage storage unit 9 outputs the reference light amount ratio of each of the lamps 1 _R , 1 _G and 1 _B at that time. Then, the output of the reference voltage storage unit 9 and the color signal conversion unit 7
The outputs of and are compared by the comparison unit 10, and the dimming signal correction unit 11 corrects the dimming signal stored in the dimming signal storage unit 12 according to the difference. After that, the corrected dimming signal is given to the lighting circuits 2 _R , 2 _G , 2 _B , and the lamps 1 _R , 1 _G ,
The lighting state of 1 _B is corrected. By repeating the above operation all the time, the lighting states of the lamps 1 _R , 1 _G and 1 _B are corrected so as to approach the color temperature and the brightness given from the control device B.

[0009]

However, in the above-mentioned variable color lighting device, at least two types of lamps 1 having different emission colors are required in order to mix the light of the lamps 1 and change the light color to a desired light color. is there. Moreover, when the light color is changed over a wide range, three or more types of lamps 1 are required as described above.

When a plurality of lamps 1 are provided in this way,
Since it is necessary to individually apply the dimming signal from the control device B to each lighting circuit 2 of the lamp body A, one line of the signal line for transmitting the dimming signal to each lighting circuit 2 is common. Also, if there are n types of lamps 1 having different emission colors, it is necessary to wire n + 1 signal lines between the control device B and the lamp body A. For example, when the lamp 1 has three types as described above, four signal lines are required.

Here, when the variable color lighting device is installed in a wide space, a large number of lamp bodies A are required, and the number of wirings to be sent between the lamp bodies A also increases accordingly, which requires time and effort for construction. , The construction time will be longer. Moreover, in this case, there is a high possibility that a wiring error will occur. By the way, as a lighting control device for reducing the number of wirings, a master unit and a plurality of terminals incorporated in each lamp body A are connected by a signal line, and the master unit is connected to the master unit using multiplex transmission such as time division multiplexing. It has been proposed to transmit a digital signal to and from a terminal to control the operation of each lamp body. That is, in this lighting control device, a signal for controlling the lighting of the lamp body can be transmitted by two lines. However, in this case, there is a drawback that an expensive and complicated device such as a master and a terminal is required.

The present invention has been made in view of the above points, and an object thereof is to provide a variable color lighting device and a variable color lighting system which have a simple structure and can simplify wiring. is there.

[0013]

In order to achieve the above object, the invention of claim 1 comprises a plurality of light sources of different emission colors,
The light source includes a lighting circuit that dimmes and lights each light source, a setting unit that sets a desired color and brightness, and a dimming amount determination unit that determines the dimming amount of each light source based on the setting of the setting unit. ,
The lighting circuit and the dimming amount determination means are housed in the lamp body.

As described in claim 2, the output signal provided from the setting means to the dimming amount determining means is a dimming signal indicating the dimming amount of the one light source and a color indicating the color of illumination light. It may be a temperature signal. Moreover, as shown in claim 3,
The output signal given from the setting means to the dimming amount determination means is
It may be a dimming signal of a light source in which the dimming amount monotonously increases or monotonically decreases when the color changes.

Further, as described in claim 4, the output signal given from the setting means to the dimming amount determination means may be a signal indicating the color temperature and a signal indicating the brightness. It is to be noted that, in the variable color lighting device according to any one of claims 2 to 4, as described in claim 5, in order to correct the deviation of the color performance of the lamp due to a change over time, color detection for detecting the color temperature of the illumination light. It is preferable that a means and a color correction means for correcting the color temperature so as to match the color temperature detected by the color detection means with the color temperature set by the operation unit are provided in the lamp body.

According to the invention of claim 6, a plurality of lamp main bodies provided with a plurality of light sources of different emission colors and a lighting circuit for dimming and lighting the respective light sources, and the color and brightness of the illumination light of these lamp main bodies are set. In the variable color lighting system including the operation unit, the reference of the lamp body 1 is provided in order to provide a function of correcting a deviation in the color performance of the lamp due to a change over time.
Detecting means for detecting the luminescent color mixed in one lamp main body, comparing means for comparing the luminescent color detected by the detecting means and the set color set by the operation section, and all the lamps according to the comparison result A correction means for correcting the light quantity of each light source of the main body is provided.

When there are variations in the color temperature performance of each lamp body, in order to satisfactorily correct the deviation of the color performance of the lamp due to aging, as shown in claim 7, color mixing is performed by a plurality of lamp bodies. A plurality of detecting means for detecting the respective emitted light colors, and an average calculating means for obtaining an average of the emitting colors detected by these detecting means are provided. You may make it compare with the set color set.

Further, in order to simplify the structure, the invention as set forth in claim 8
As described above, it is desirable that the detection means, the comparison means, and the correction means are integrally provided with the operation portion outside the lamp body. Further, in order to simplify the configuration, as shown in claim 9, at least the comparing means and the correcting means may be provided in the lamp body as a reference. According to the invention of claim 10, in order to correct the deviation of the color performance of the lamp due to a change over time without using a means for detecting illumination light such as a color sensor, a plurality of light sources of different emission colors and a plurality of light sources are adjusted. A lighting circuit for turning on light, setting means for setting a desired color and brightness, dimming quantity determining means for deciding the dimming quantity of each light source, and dimming quantity and lighting time of each light source converted into a full lighting state And a light flux calculating means for calculating the current light flux decay rate of each light source from the lighting time, and the light control determined by the light control amount forming means based on the light flux decay rate calculated by the light flux computing means. And a dimming amount correction means for correcting the amount.

[0019]

According to the invention of claim 1, the structure excluding the setting means is housed in the lamp body as described above, and the dimming signal of each lamp is not sent directly from the setting means corresponding to the control device, but the dimming signal of each lamp is adjusted. The optical signal can be determined and signaled. This reduces the number of types of signals sent from the setting means to the lamp body and reduces the number of wires. In addition, the structure does not become complicated by not using a special transmission signal such as a multiplex transmission system.

According to a fifth aspect of the present invention, a function of matching the illumination light with the color temperature set by the operation unit is provided to correct the deviation of the color performance of the lamp due to a change with time. According to the invention of claim 6, with the above-mentioned configuration, it is possible to correct the deviation of the color performance of the lamp due to a change with time in the variable color illumination system including a plurality of lamp main bodies.

According to the seventh aspect of the invention, the average of the mixed emission colors of the plurality of lamp main bodies is obtained, and the deviation of the color performance of the lamp due to the change with time is corrected based on the average emission color. This makes it possible to satisfactorily correct the deviation of the color performance of the lamp due to a change over time when the color temperature performance of each lamp body has variations. According to the invention of claim 8, it is not necessary to provide each lamp body with a structure for correcting the deviation of the color performance of the lamp due to a change over time, and the structure is simplified.

According to the ninth aspect of the invention, there is no need to provide a lamp body other than the reference lamp body with a structure for correcting the deviation of the color performance of the lamp due to a change with time.
Simplify the configuration. According to the tenth aspect of the invention, with the above-described configuration, the luminous flux decline rate of each light source is obtained from the dimming amount of each light source and the lighting time, and the dimming amount is corrected. As a result, the deviation of the color performance of the lamp due to a change with time is corrected without using a means for detecting illumination light such as a color sensor.

[0023]

【Example】

(Embodiment 1) FIG. 1 shows a first embodiment of the present invention. In the present embodiment, the dimming signal and the illumination light of the lamps 1 _R , 1 _G , and 1 _B that emit different colors of red, green, and blue, and one lamp 1 (red lamp 1 _R in this embodiment). Operating unit 3 for setting a color temperature signal indicating the light color of A, an A / D converting unit 13 for converting an analog signal given from the operating unit 3 into a digital signal, a dimming signal of one lamp 1 and an illumination light. In the dimming data calculation unit 14 for calculating the dimming amount of the other lamps 1 (green lamp 1 _G , blue lamp 1 _{B in} this embodiment) from the color temperature signal indicating the light color of Other required lamps 1 (green lamp 1 _G , blue lamp 1 _B )
Dimming signal conversion unit 5 for converting the dimming data of
And a lighting circuit 2 _R , 2 _G , 2 _B for dimming the lamps 1 _R , 1 _G , 1 _{B respectively} based on the dimming signal provided from the operation unit 3 and the dimming signal conversion unit 5. There is. The respective components except the operation unit 3 are housed in the lamp body A.

In this embodiment, when the color temperature is set by the operation unit 3, the operation unit 3 outputs the dimming signal of the red lamp 1 _{R and} the color temperature signal indicating the light color of the illumination light. here,
The dimming signal is output as a duty signal or a DC voltage signal. The color temperature signal may be any signal that corresponds to the color temperature, and the signal form is not particularly limited. For example, a duty signal or a DC voltage signal similar to the dimming signal may be used, or a pulse signal having a variable frequency may be used.

The dimming signal and the color temperature signal are A / D conversion signals.
The conversion unit 13 converts the signal into a digital signal, and the dimming data calculation unit
Two other lamps at 14 1_G, 1_BThe dimming amount of
It The calculation method will be described below. Each lamp 1_R, 1
_G, 1_BIs the chromaticity coordinate of each (x_R, Y_R),
(X_G, Y_G), (X_B, Y_B), And each lamp
1_R, 1_G, 1_BThe total luminous flux of Y _R, Y_G, Y_B, Dimming ratio
Is k_R, K_G, K_BIf you set all lights to 1
Color of light (x₀, Y₀) And the amount of light Y₀Is given by
To be

[0026]

[Equation 1]

As a concrete example, it is assumed that the lamp 1 _R is a red lamp, the lamp 1 _G is a green lamp, and the lamp 1 _B is a blue lamp, and their chromaticity coordinates and total luminous flux are as follows.

[0028]

[Table 1]

At this time, for the signal, all the red lamps 1 _R are turned on (100%), and the color temperature signal is set to 3000K. Here, 3000K is (0.437, 0.
404). From the above, among formulas (1) and (2),
(X _R , y _R ), (x _G , y _G ), (x _B , y _B ), Y
_R , Y _G , Y _B , k _R (= 1), (x ₀ , y ₀ ) are known, and the unknowns are only k _G and k _B. Therefore,
By calculating the equations (1) and (2), k _G and k _B can be obtained. The result in the above case is k _G = 0.78, k _B =
It becomes 0.08. Therefore, the dimming data calculation unit 3 outputs 0.7 mm as dimming data for the respective lighting circuits 2 _G and 2 _B.
8 (78%) and 0.08 (8%) are provided to the dimming signal conversion unit 5. The dimming signal conversion unit 5 converts the dimming data supplied from the arithmetic unit 3 into a dimming signal suitable for the lighting circuits 2 _G and 2 _B , and lights at a desired color temperature of 3000K.

With the configuration of this embodiment, the A / D converter 1
3. By incorporating the dimming data calculation unit 14 and the dimming signal converting unit 5 in the lamp body A, when one signal line is shared, the number of signal lines can be reduced from four to three. . (Embodiment 2) FIG. 2 shows a second embodiment of the present invention. The present embodiment is basically the same as the first embodiment, and instead of the dimming data calculation unit 14 in the first embodiment, the lamp 1 corresponding to each color temperature and brightness calculated in advance is obtained. It is provided with a dimming data storage unit 4 having _G , 1 _B dimming data as a table. In the present embodiment, instead of performing the calculation, the dimming data for the lamps 1 _G and 1 _B is read at the address corresponding to the color temperature and the brightness as described in the section of the prior art.

(Embodiment 3) FIG. 3 shows a third embodiment of the present invention. In the present embodiment, attention is paid to the fact that the lamp dimming ratio of the red lamp 1 _R and the blue lamp 1 _B among different emission colors monotonically increases or monotonically decreases with a change in color temperature.
One of the features is that one signal is used as the dimming signal and the color temperature signal in the first embodiment.

For example, when the lamp 1 having the characteristics shown in Table 1 of the first embodiment is used, the dimming ratio of each of the lamps 1 _R , 1 _G and 1 _B when the color temperature changes is as follows. . The luminous flux is 5100 (lm).

[0033]

[Table 2]

Now, regarding the red lamp 1 _R , when the color temperature of the illumination light is changed to 3000 K to 1000 K, the dimming ratio may be changed to 100 to 39. A dimming signal such as a duty signal or a DC voltage signal is output from the operation unit 3 so as to achieve this dimming ratio. When the dimming signal is a DC voltage signal, for example, a dimming ratio of 100
In this case, DC10V can be set, and when the dimming ratio is 39, 3.9V can be set. When this signal is output, the A / D converter 13 converts it into a digital signal. A
The color temperature detection unit 8 converts the digital amount of the dimming signal output from the / D conversion unit 13 into color temperature data. In addition,
In this case, it is preferable that the color temperature detection unit 8 convert the chromaticity coordinates corresponding to the color temperature. The outputs of the A / D converter 13 and the color temperature detector 8, that is, the dimming ratio of the red lamp 1 _R obtained as the output of the A / D converter 13 and the output of the color temperature detector 8 are obtained. Based on the chromaticity coordinates obtained, the dimming data calculation unit 1 is used as described in the first embodiment.
4 calculates the dimming ratio data of the lamps 1 _G and 1 _B , converts the dimming data which is the calculation result into a dimming signal in the dimming signal converter 5, and lights the lamp body A at a desired color temperature. Let

The configurations of the first to third embodiments described above are convenient when changing only the color temperature while keeping the brightness as it is. (Embodiment 4) FIG. 4 shows a fourth embodiment of the present invention. This embodiment also controls lighting of the lamp body A with two wires as in the third embodiment, but in the case of this embodiment, the color temperature and brightness signals are output. There are features. Specifically, the duty ratio of the duty signal indicates the color temperature, and the amplitude indicates the brightness level.

[0036]

[Table 3]

FIGS. 5 (a) and 5 (b) show that the brightness level is expressed by making the amplitudes different, and the duty ratio is changed as shown by the broken line in each drawing to represent the color temperature. The color temperature detector 8 converts this signal into a set color temperature, and the light amount detector 15 converts it into a brightness level. Then, the dimming data computing unit 14 computes the dimming ratio of each of the lamps 1 _R , 1 _G , 1 _B from the output of the color temperature detecting unit 8 and the output of the light amount detecting unit 15.

In the above description, the signals indicating the color temperature and the brightness are collectively transmitted via one signal line, but of course, the signals indicating the color temperature and the brightness are individually transmitted to the individual signal lines. You may send it by. In this case, the respective signal forms do not need to be interlocked as shown in FIGS. 5A and 5B and may be completely independent signals. (Embodiment 5) FIG. 6 shows a fifth embodiment of the present invention. This embodiment is based on the above-mentioned fourth embodiment and is provided with a function of correcting a deviation in the color performance of the lamp 1 due to a change over time.
In addition to the configuration of the fourth embodiment, the three primary colors (R
GB) component, a color sensor 6 for detecting the RGB component, a color signal converter 7 for obtaining a light amount ratio of R / G and B / G from RGB components detected by the color sensor 6, and a color detected by a color temperature detector 8. A reference voltage storage unit 9 that stores a reference light amount ratio (R / G, B / G) of each of the lamps 1 _R , 1 _G , and 1 _B corresponding to the temperature, and a color temperature detected by the color temperature detection unit 8. A comparison unit 10 that compares the reference light amount ratio read from the reference voltage storage unit 9 in accordance with the above with the light amount ratio obtained by the color signal conversion unit 7.
And the dimming data calculation unit 14 based on the output of the comparison unit 10.
Dimming data correction unit 1 that corrects the dimming data obtained in
6 and are provided.

In this embodiment, the color temperature and
When the brightness is set, the output of the color temperature detection unit 8 and the light
Each run is controlled by the dimming data calculation unit 14 from the output of the amount detection unit 15.
1 _R, 1_G, 1_BThe dimming ratio of is calculated. At this time,
Lamp 1 of lamp body A_R, 1 _G, 1_BBefore lights up
Then, the color sensor 6 detects the RGB components of the illumination light.
Since it is not output, the dimming data correction unit 16 does not operate.
Therefore, the dimming data calculated by the dimming data calculator 14
Is converted into a dimming signal by the dimming signal converter 5, and the dimming signal is
Lighting circuit 2 based on the number_R, 2_G, 2_BIs lamp 1
_R, 1_G, 1_BLight up. In other words, at this time
The color temperature and brightness given from the operation unit 3 are not changed.
Pump 1_R, 1_G, 1_BLights up.

When the lamps 1 _R , 1 _G , and 1 _B are turned on, the color sensor 6 detects the RGB components from the mixed illumination light, and the color signal conversion unit 7 determines the light amount ratio of R / G and B / G. Is converted into the signal shown. On the other hand, in accordance with the currently applied color temperature detected by the color temperature detection unit 8, the reference voltage storage unit 9 outputs the light amount ratio serving as the reference of each lamp 1 _R , 1 _G , 1 _B at that time. . Then, the reference voltage storage unit 9
And the output of the color temperature conversion unit 7 are compared by the comparison unit 10, and the dimming data correction unit 16 according to the difference,
The dimming data calculated by the dimming data calculator 14 is corrected. The corrected dimming data is converted into a dimming signal by the dimming signal conversion unit 5 and given to the lighting circuits 2 _R , 2 _G and 2 _B, and the lighting states of the lamps 1 _R , 1 _G and 1 _B are corrected. To be done.
By repeating the above operation all the time, the lighting states of the lamps 1 _R , 1 _G , and 1 _B are corrected so as to approach the color temperature and the brightness given from the operation unit 3.

(Embodiment 6) FIG. 7 shows a sixth embodiment of the present invention. In this embodiment, the dimming signal of the lamp 1 from which the dimming amount monotonously increases or monotonically decreases when the color changes from the operation unit 3,
Basic to the third embodiment of Figure 3 gives a dimming signal of the red lamp 1 _R Specifically, it lamp 1 due to aging
It is provided with a function of correcting the deviation of the color performance of.

In this embodiment, instead of the dimming data calculation unit 14 in the third embodiment of FIG. 3, a color sensor 6, a color signal conversion unit 7, a reference voltage storage unit 9, a comparison unit 10, and a dimming data correction unit. 16 is provided, and a fixed signal generator 1 that newly generates a constant dimming signal as a dimming signal for the lamps 1 _G and 1 _B
7 and the lighting circuit 2 _R are selectively connected to the output of the operation unit 3 and the output of the dimming signal conversion unit 5, and the lighting circuit 2 _G ,
A switch SW ₁ for selectively connecting 2 _B to the output of the fixed signal generator 17 and the output of the dimming signal converter 5 is provided. The color temperature detection unit 8 of this embodiment is the A / D conversion unit 1.
Includes 3 functions.

In this embodiment, when the color temperature is set by the operation unit 3, the dimming signal of the lamp 1 _R corresponding to the color temperature is output. At this time, the switch SW ₁ is connected to the lighting circuit 2 _R to the output of the operation unit 3, and the lighting circuits 2 _G and 2 _B are connected.
Is switched to be connected to the output of the fixed signal generator 17. In this case, since the lamp 1 _G, 1 _B is given a certain dimming signal, a color temperature different from the set color temperature, the lamp 1 _R, 1 _G, 1 _B are turned on.

When the lamps 1 _R , 1 _G and 1 _B are lit in this way, the color sensor 6 detects the RGB components of the mixed color light, and the light amount ratio obtained by converting the RGB components is converted into the reference voltage storage unit 9. Light amount ratio and reference unit 10
And the dimming data correction unit 16 obtains dimming data for obtaining a desired color temperature according to the difference. That is, in this case, the dimming data correction unit 16 obtains the dimming data of the lamps 1 _G and 1 _B with reference to the dimming signal of the fixed signal generating unit 17.

After that, switch SW ₁ is turned on for each lighting circuit 2
_By switching _R , 2 _G , and 2 _B so as to be connected to the dimming signal converter 5, the lamp body A lights up at a desired color temperature. In this embodiment, when the setting is made on the operation unit 3,
Although the color temperature of the illumination light is slightly deviated, when the switch SW ₁ is switched, the color temperature is immediately corrected to a desired color temperature, so there is no problem in practical use. Also, with the configuration of the present embodiment, it is not necessary to calculate the dimming data of the lamps 1 _G and 1 _B from the dimming signal provided from the operation unit 3, so the configuration is simplified.

(Embodiment 7) FIG. 8 shows a seventh embodiment of the present invention. By the way, when the variable color lighting device having the function of correcting the deviation of the color performance of the lamp 1 due to the change with time described in FIG. 16 is used in an office or a store, since there is a large space, one lamp body A is used. That is not enough, and a large number of lamp bodies A are required as shown in FIG. In this case, a color correction unit including a color sensor 6 for performing color correction, a color signal conversion unit 7, a color temperature detection unit 8, a reference voltage storage unit 9, a comparison unit 10, and a dimming signal correction unit 11 is provided in each lamp body. As A has,
It has the drawback of being expensive and having a complicated structure.

Therefore, in the present embodiment, as shown in FIG. 8, the respective lamp bodies A are replaced by lamps 1 _R , 1 _G and 1 _B.
Each of the lamps 1 _R , 1 _G , and 1 _B is composed of a lighting circuit 2 _R , 2 _G , and 2 _B for individually dimming and lighting, and one lamp body A
Only, the color sensor 6 for detecting the three primary color (RGB) components of the light of the illumination light is provided, and R detected by the color sensor 6 is provided.
It serves as a reference for the color signal conversion unit 7 for obtaining the R / G, B / G light amount ratio from the GB component, and for each lamp 1 _R , 1 _G , 1 _B corresponding to the color temperature given from the dimming data storage unit 2. The reference voltage storage unit 9 that stores the light amount ratio (R / G, B / G), the reference light amount ratio read from the reference voltage storage unit 9 according to the color temperature, and the value of the color signal conversion unit 7. Comparison unit 1 for comparing
0, and a dimming data correction unit 16 that corrects dimming data based on the output of the comparison unit 10 is provided in the control device B.

In the case of this embodiment, the color sensor 6 of one lamp body A detects the color temperature of the mixed illumination light, and all the lamp bodies A are detected according to the detected color temperature.
It operates so as to perform color correction of the illumination light. According to this embodiment, since the color correction unit is not built in each lamp body A but is built in the control device B, the configuration on the lamp body A side is not complicated. Further, as described above, since the color correction unit is provided on the control device B side, it is possible to directly obtain the current set color temperature from the dimming data storage unit 2 and to detect the present set color temperature. There is also an advantage that the color temperature detection unit 8 which is the above becomes unnecessary.

(Embodiment 8) FIG. 9 shows an eighth embodiment of the present invention.
Indicates. In this embodiment, the lamp body A is the lamp 1 _R, 1
_G, 1_BAnd lighting circuit 2_R, 2_G, 2_BMultiple as one set
Shows the case of a large size with a set (two sets in FIG. 9)
It is a thing. Also in this case, basically, the seventh embodiment
In the same way, the configuration of the lighting system as a whole is complicated.
Deviation of the color performance of the lamp 1 due to aging without
It is possible to add a function to correct the.

(Embodiment 9) FIG. 10 shows a ninth embodiment of the present invention. In this embodiment, the color sensor 6 is provided in the two lamp bodies A, and the color temperature of each of them is detected by each color sensor 6. Then, the averaging unit 1 for averaging the color temperatures detected by the respective color sensors 6
8 is provided, and in the color signal conversion unit 7, R / G and B / G are calculated from the average values of the color temperatures detected by the respective color sensors 6.
The light quantity ratio of is calculated.

In this way, when there is some variation in the color temperature performance of the lamp body A, the color temperature is corrected in the middle, and the deviation of the color performance of the lamp 1 due to aging can be corrected well. Can be expected. (Embodiment 10) FIG. 11 shows a tenth embodiment of the present invention. In the present embodiment, a variable color lighting system is constructed by the conventional variable color lighting device of FIG. 17 and a plurality of lamp main bodies A including a lamp 1 and a lighting circuit 2. In the case of the present embodiment, The lighting circuit 2 of all the lamp bodies A is provided with a dimming signal from the dimming signal storage section 12 of the basic lamp body A. With this configuration, an illumination system capable of correcting the color performance deviation can be configured by simply exchanging the variable color illumination device A having no color correction and the variable color illumination device A having the color correction function shown in FIG. Moreover, there is an advantage that the cost required for replacement is small.

(Embodiment 11) FIG. 12 shows an eleventh embodiment of the present invention. In this embodiment, the lamp 1 due to changes with time
The function of correcting the deviation of the color performance of No. 1 is realized without using the color sensor 6, and the light flux reduction amount of each lamp 1 at present is calculated from the dimming amount and the elapsed time from the start of use. There is provided a lamp luminous flux calculation unit C that makes a prediction by calculation and causes the dimming data calculation unit 14 to perform a calculation for correction in accordance with the luminous flux decline amount according to the prediction result.

In this embodiment, the lamp luminous flux calculating section C is used.
, A dimming amount-weighting coefficient conversion unit 19 for converting the dimming amount for each of the lamps 1 _R , 1 _G , 1 _B into a weighting coefficient, a counter 20 for counting a fixed time, and the dimming amount-weighting coefficient. Converter 1
A multiplier 27 that multiplies the weighting factor corresponding to each of the lamps 1 _R , 1 _G , and 1 _B set in 9 by the time measured by the counter 20, and an adder unit 2 that integrates the output of the multiplier 27.
1 and a data holding unit 22, and a lighting time-light flux correction coefficient conversion unit 23 for converting the lighting time of all lighting conversion obtained as the integration result of the integration unit into a light flux correction coefficient.
And a lamp light flux correction unit 2 for performing light flux correction by an operation for obtaining light control data by the light control data calculation unit 14 based on the light flux correction coefficient obtained by the lighting time-light flux correction coefficient conversion unit 23.
5 and a timer 24 for measuring a fixed period for correcting the luminous flux
And a switch means SW ₂ for outputting the luminous flux correction coefficient from the lighting time-luminous flux correction coefficient conversion unit 23 to the lamp luminous flux correction unit 25 at a regular time point.

The nature of the lamp 1 is such that the luminous flux decreases as the lighting time increases. The situation is shown in FIG. Figure 1
Curve A in 3 shows a luminous flux decay curve when all lighting (100%) is turned on, curve B shows a luminous flux decay curve when 50% dimming lighting is performed, and curve C shows a luminous flux decay curve when 20% dimming lighting is performed. As is clear from FIG. 13, the light flux reduction changes depending on the dimming amount, and the light flux diminishes as the light adjustment is performed.
For example, the time during which the luminous flux is 80% of the initial value is t ₁ at the time of full lighting, t ₂ at the time of 50% dimming lighting, and t ₃ at the time of 20% dimming lighting (t ₁ , t ₂ , t ₃ is time, t ₁ ＞ t ₂ ＞
t ₃ ).

Table 1 shows the relationship between the dimming amount and the weighting coefficient set in the dimming amount-weighting coefficient conversion section 19.

[0056]

[Table 4]

In Table 4, when the dimming amount is 100 (all lighting), it is set to 1.0, and the value is reduced as the dimming amount decreases (the lamp output decreases). Then, the weighting coefficient corresponding to each of the lamps 1 _R , 1 _G , and 1 _B set in the dimming amount-weighting coefficient conversion unit 19 and the time measured by the counter 20 are multiplied by the multiplier 27, and The total lighting conversion lighting time can be obtained by integrating the output of the multiplier 27 by the integrating means including the adding unit 21 and the data holding unit 22. That is, when 100% is 100 h, 1.0 × 100 h = 100 h, and 50% is 10 h.
At 0h lighting, 0.6 × 100 = 60h, that is, 100% lighting corresponds to 60h, and 20% lighting corresponds to 100h.
When, 0.3 × 100 = 30 h, that is, 100
% Lighting corresponds to 30 hours.

Then, the integrated lighting time is input to the lighting time-luminous flux correction coefficient conversion unit 23, and the luminous flux maintenance factor of the lighting time when the lighting time is 100% is calculated. This is shown in Table 5.

[0059]

[Table 5]

For example, when the lighting time of the lamp 1 _R is converted into 100% lighting and is 1000 h, the luminous flux correction coefficient is 0.
It is 95, which means that the luminous flux is reduced by 5% from the initial stage. Similarly for the lamps 1 _G and 1 _B , the luminous flux correction coefficient is obtained based on the time converted into 100% lighting. The luminous flux correction coefficient obtained by the lighting time-luminous flux correction coefficient conversion unit 23 is periodically input to the lamp luminous flux correction unit 25 by the timer 24, and the luminous flux of each lamp 1 is corrected. This new luminous flux value is input to the dimming data calculation unit 14 and is corrected to the optimum dimming amount at the present time, and the color temperature at the time of lighting is corrected.

(Embodiment 12) A twelfth embodiment of the present invention shown in FIG. 14 is shown. In the present embodiment, instead of the dimming amount-weighting coefficient conversion unit 19 and the multiplier 27 in the eleventh embodiment, the weighting coefficient is obtained from the color temperature, and the fixed time measured by the counter 20 is converted into the total lighting conversion time. The color temperature lighting time calculation unit 26 for conversion is used.

In the color temperature lighting time calculation unit 26 of this embodiment, the dimming amount and the weighting coefficient at each color temperature are made to correspond in advance in the table of Table 6 as in the eleventh embodiment.
The constant time counted by the counter 16 is converted into the lighting time of the total lighting conversion of each lamp by the color temperature lighting time calculation unit 26,
The conversion results are integrated by the addition unit 21 and the data storage unit 22 to obtain the lighting time in terms of all lighting up to the present time. After that, the lighting time-light flux correction coefficient conversion unit 23 calculates the light flux correction coefficient in the same manner as in the eleventh embodiment.

[0063]

[Table 6]

By the way, the type of the lamp in each of the above-mentioned embodiments may be any of a fluorescent lamp, a high pressure discharge lamp, an incandescent lamp, and the type is not limited. Further, the signal form of the load power supplied to the lamp or the shape of the lamp itself does not matter. Further, the light color may be a light bulb color, a white color, a yellow color or the like as long as a variable color can be achieved, and the light color of each lamp is not necessarily the three primary colors of RGB. Furthermore, the present invention can be applied to a white lamp provided with a color filter. Further, the types and the number of lamps are not limited to three and three, and can be applied to the case where yellow is added to make four or two or more lamps of the same color are provided.

The color temperature / brightness signal also serves as a dimming signal and may be a duty signal or a DC voltage signal, or may be any combination such as a frequency variable signal. Further, the calculation of the RGB signal may be performed by either digital calculation or analog calculation. Furthermore, the color sensor is not limited to the integrated type, but may be a type in which three photodiodes are separated, or a configuration in which a photodiode is installed for each lamp. Further, the lighting circuit does not have to be individual for each lamp, but may be an integrated type that collectively lights three lights as long as dimming lighting of each lamp can be performed. Alternatively, the dimming data calculation unit and the lighting unit may be mounted on the same substrate as a lighting unit dedicated to variable colors.

[0066]

As described above, the invention of claim 1 has a plurality of light sources of different emission colors, a lighting circuit for dimming and lighting each light source, a setting means for setting a desired color and brightness, and a setting. Since the light source, the lighting circuit, and the dimming amount determining means are housed in the lamp body, the dimming amount determining means for determining the dimming amount of each light source based on the setting of the means is set in the lamp body. Instead of sending the dimming signal of each lamp as it is from the means, it is possible to send a signal that the dimming signal of each lamp can be determined. Therefore, it is possible to reduce the number of types of signals sent from the setting means to the lamp body, and the number of wires. Can be reduced. Moreover, since a special transmission signal such as a multiplex transmission system is not used, the configuration does not become complicated.

According to the invention of claim 5, the color temperature is corrected so that the color temperature detected by the color detection means for detecting the color temperature of the illumination light and the color temperature detected by the color detection means coincide with the color temperature set by the operation section. By arranging the color correction means for controlling the color temperature in the lamp body, it is possible to match the illumination light with the color temperature set by the operation unit and correct the deviation of the color performance of the lamp due to a change with time.

According to the sixth aspect of the invention, a plurality of lamp bodies including a plurality of light sources of different emission colors and a lighting circuit for dimming and lighting the respective light sources, and the color and brightness of the illumination light of these lamp bodies are set. In the variable color lighting system including an operating unit, a detecting unit that detects an emission color mixed in one of the above-described lamp main bodies, which is a reference, and an emission color detected by the detecting unit and the operation unit set In the variable color illumination system including a plurality of lamp bodies, the comparison means for comparing the set color and the correction means for correcting the light amount of each light source of all the lamp bodies according to the comparison result are provided. The deviation of the color performance of the lamp due to the change over time can be corrected.

According to a seventh aspect of the present invention, a plurality of detecting means for respectively detecting the emission colors mixed in the plurality of lamp bodies and an average calculating means for obtaining an average of the emission colors detected by these detecting means are provided. Since the average light emission color obtained by the average calculation means by the comparison means is compared with the set color set by the operation unit, the average of the mixed emission colors of the plurality of lamp bodies is obtained, and the average emission color is obtained. The deviation of the color performance of the lamp due to aging can be corrected based on the above, and the deviation of the color performance of the lamp due to aging can be excellently corrected when the color temperature performance of each lamp main body varies. .

According to the invention of claim 8, since the detecting means, the comparing means and the correcting means are provided outside the lamp body integrally with the operation portion, the deviation of the color performance of the lamp due to the aging of each lamp body is corrected. It is not necessary to provide a configuration that fulfills the function of performing, and the configuration can be simplified. According to the invention of claim 9, since at least the comparing means and the correcting means are provided in the reference lamp body, the deviation of the color performance of the lamp due to aging is corrected in the lamp body other than the reference lamp body. The configuration can be simplified without the need to provide a configuration that fulfills the function.

According to a tenth aspect of the present invention, a plurality of light sources having different emission colors, a lighting circuit for dimming and lighting each light source, a setting means for setting a desired color and brightness, and a dimming amount of each light source are set. The light flux determining means for determining, and the light flux calculating means for calculating the lighting time converted from the lighting time and the lighting time of each light source as a full lighting state to calculate the luminous flux decay rate of each light source at the present time from the lighting time, Since a dimming amount correction unit that corrects the dimming amount determined by the dimming amount forming unit based on the luminous flux decline rate calculated by the computing unit is provided, each dimming amount and lighting time of each light source The luminous flux decay rate of the light source can be obtained to correct the dimming amount, and the deviation of the color performance of the lamp due to aging can be corrected without using a means for detecting the illumination light such as a color sensor.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a block diagram showing a circuit configuration of a second embodiment.

FIG. 3 is a block diagram showing a circuit configuration of a third embodiment.

FIG. 4 is a block diagram showing a circuit configuration of a fourth embodiment.

5A and 5B are explanatory diagrams showing signal waveforms of output signals output from the operation unit.

FIG. 6 is a block diagram showing a circuit configuration of a fifth embodiment.

FIG. 7 is a block diagram showing a circuit configuration of a sixth embodiment.

FIG. 8 is a block diagram showing a circuit configuration of a seventh embodiment.

FIG. 9 is a block diagram showing a circuit configuration of an eighth embodiment.

FIG. 10 is a block diagram showing a circuit configuration of a ninth embodiment.

FIG. 11 is a block diagram showing a circuit configuration of a tenth embodiment.

FIG. 12 is a block diagram showing a circuit configuration of an eleventh embodiment.

FIG. 13 is an explanatory diagram showing luminous flux decay characteristics with respect to lighting time.

FIG. 14 is a block diagram showing a circuit configuration of a twelfth embodiment.

FIG. 15 is a block diagram showing a circuit configuration of a conventional example.

FIG. 16 is a block diagram showing a circuit configuration of another conventional example.

FIG. 17 is a system configuration diagram of an illumination system constructed using the variable color illumination device of the above.

[Explanation of symbols]

A lamp body B control device C lamp luminous flux calculation unit 1 _R , 1 _G , 1 _B lamp 2 _R , 2 _G , 2 _B lighting circuit 3 operation unit 4 dimming data storage unit 5 dimming signal conversion unit 6 color sensor 7 colors Signal conversion unit 8 Color temperature detection unit 9 Reference voltage storage unit 10 Comparison unit 11 Dimming signal correction unit 13 A / D conversion unit 14 Dimming data calculation unit 15 Light intensity detection unit 16 Dimming data correction unit 17 Fixed signal generation unit

Claims (10)

[Claims] 1. A plurality of light sources having different emission colors, a lighting circuit for dimming and lighting each light source, setting means for setting a desired color and brightness, and dimming of each light source based on the setting of the setting means. A variable color lighting device, comprising: a light control amount determining means for determining an amount; and the light source, the lighting circuit, and the light control amount determining means being housed in a lamp body. 2. The output signal supplied from the setting means to the dimming amount determining means is a dimming signal indicating the dimming amount of the one light source and a color temperature signal indicating the color of illumination light. The variable color lighting device according to claim 1. 3. The output signal provided from the setting means to the dimming amount determining means is a dimming signal of a light source whose dimming amount monotonically increases or monotonically decreases when a color changes. Variable color lighting device. 4. The variable color lighting device according to claim 1, wherein the output signals supplied from the setting means to the dimming amount determination means are a signal indicating color temperature and a signal indicating brightness. 5. Color detection means for detecting the color temperature of the illumination light, and color correction means for correcting the color temperature so that the color temperature detected by the color detection means matches the color temperature set by the operating section. 5. The variable color lighting device according to claim 2, wherein the variable color lighting device is provided in the lamp body. 6. A plurality of lamp main bodies provided with a plurality of light sources of different emission colors and a lighting circuit for dimming and lighting the respective light sources, and an operation section for setting the color and brightness of the illumination light of these lamp main bodies. In a variable color illumination system provided with, a detection unit that detects a light emission color mixed in one of the above-mentioned lamp main bodies, which is a reference, a light emission color detected by the detection unit, and a set color set by an operation unit. A variable color illumination system, comprising: a comparison unit that compares the light sources and a correction unit that corrects the light amount of each light source of all the lamp bodies according to the comparison result. 7. A plurality of detecting means for respectively detecting the luminescent colors mixed in a plurality of lamp bodies, and an averaging means for obtaining an average of the luminescent colors detected by these detecting means are provided, and the averaging means is provided by the comparing means. 7. The variable color illumination system according to claim 6, wherein the average luminescent color obtained by the calculation means is compared with the set color set by the operation unit. 8. The variable color illumination system according to claim 6, wherein the detecting means, the comparing means, and the correcting means are provided outside the lamp body integrally with the operating portion. 9. The variable color illumination system according to claim 6, wherein at least the comparison means and the correction means are provided in a lamp body serving as a reference. 10. A plurality of light sources of different emission colors, a lighting circuit for dimming and lighting each light source, setting means for setting a desired color and brightness, and a dimming amount determination for determining a dimming amount of each light source. Means and a light flux calculating means for calculating a lighting time converted from the dimming amount of each light source and a lighting time as a full lighting state to calculate a luminous flux decline rate of each light source at the present time from the lighting time. And a dimming amount correcting unit that corrects the dimming amount determined by the dimming amount forming unit based on the luminous flux decline rate.