JP3382008B2 - Variable color lighting system - Google Patents

Abstract

PURPOSE:To provide a variable color illumination device which uses less data for hue control and dimming. CONSTITUTION:A light emission part is equipped with a plurality of light sources 2R, 2G, 2B emitting different colors. A data memory part 7 stores the emissive colors of the sources, their max. output fluxes, and the reference data consisting of the chromaticity coordinates corresponding to emissive colors of less types than the color sorts selectable by a color/quantity selection part 8. When the color is selected by the selection part 8, a calculation part 9 determines the chromaticity coordinates corresponding to the color on the basis of the stored reference data. The calculation part 9 further determines the mix proportion of the emissive colors from the light sources 2R, 2G, 2B on the basis of the given chromaticity coordinates and the emissive colors from the light sources and calculates the dimming ratio which generates the specified mix proportion as above on the basis of the max. output photo-quantities of the light sources.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting device used in a general living space such as a house or an office, which includes a light emitting section having a plurality of light sources of different emission colors. The present invention relates to a variable color lighting device capable of adjusting substantially continuously the light color and the light amount of illumination light obtained as mixed color light by adjusting the light emission amount of a light source.

[0002]

2. Description of the Related Art The present inventor has shown, as a variable color illumination device of this type, a light source 2R for three colors of red (R), green (G) and blue (B) as shown in FIG. A data storage unit 7 having a light emitting unit 1 in which 2G and 2B are housed in one instrument main body and having previously stored a dimming ratio corresponding to the dimming amount of each light source 2R, 2G, 2B according to the light color and the light amount. On the other hand, there has been previously proposed a device that adjusts the light emission amount of each of the light sources 2R, 2G, and 2B by instructing the light color and the light amount from the light color light amount selection unit 8 (for example, JP-A-4-4858).
4 publication). That is, in the variable color lighting device described in the above publication, when the up or down switch is operated in the light / color light amount selection unit 8 to select the increase or decrease of the color temperature, the address data output from the up / down counter is output. Is increased or decreased, and the address of the data storage unit 7 is designated by this address data.
Further, the data selection unit 5 reads out the dimming ratio of the designated address from the data storage unit 7 and passes it to the dimming signal generation unit 6. The dimming ratio is a set of three data corresponding to the dimming amount of each of the light sources 2R, 2G, 2B corresponding to the designated color temperature as described above, and the dimming signal generator 6 controls the dimming ratio. A dimmer signal having a dimming amount corresponding to is generated to generate dimmers 4R, 4G, 4
Then, the dimmers 4R, 4G, 4B control the dimming control of the light sources 2R, 2G, 2B according to the dimming signal. For example, if phase control is performed in the dimmers 4R, 4G, and 4B, a signal that gives a phase angle corresponding to the dimming ratio is generated as a dimming signal, and a resonant circuit is generated in the dimmers 4R, 4G, and 4B. If the power supplied to the light sources 2R, 2G, 2B is adjusted by supplying power to the light sources 2R, 2G, 2B via the resonant circuit, the dimming ratio corresponds to the dimming ratio. A frequency signal may be generated.

By the way, the data storage unit 7 stores the dimming ratio in the form as shown in Table 1. That is, the data storage unit 7 has three dimming ratios corresponding to each address according to the color temperature (in Table 1, only the color temperature is shown).
When the desired address is designated by the data selector 5, the dimming ratio of the address is read.

[0004]

[Table 1]

If the dimming ratio as shown in Table 1 is used, when the color temperature is continuously changed from 3000K to 3300K, the address is 00h in the data selecting section 5 (h at the end is a hexadecimal number). Is shown) to 19h (the color temperature becomes 3290K). Here, the dimming ratios corresponding to the color temperatures shown in Table 1 are set so that changes in the reciprocal of the color temperature (= 1 / color temperature) for each step are substantially equal. That is, the color temperature change is set for each step so that the color temperature is converted into milled at approximately equal intervals, and thus the color change for each step is perceived at approximately equal intervals. It has become.

[0006]

By the way, the dimming ratio shown in Table 1 is an example in the case where the color temperature is changed substantially continuously in 256 steps in the range of 3,000 to 30,000 K. Therefore, 256 sets of dimming ratios are required. Further, in the case of changing the light amount with a constant light color, for example, if the light amount is changed continuously in 256 steps for each color temperature,
A dimming ratio of 6 × 256 = 65536 sets is required. These dimming ratios are calculated in advance according to the maximum output luminous flux of the light sources 2R, 2G, 2B and stored in the data storage unit 7. Therefore, the data amount of the dimming ratio stored in the data storage unit 7 becomes very large, and the capacity of the storage element (RAM or ROM) used in the data storage unit 7 becomes large, which causes a problem of high cost. Further, since the number of data of the dimming ratio stored in the data storage unit 7 is large, there is a problem that it takes time to calculate and create the dimming ratio.

An object of the present invention is to solve the above-mentioned problems, and it is possible to significantly reduce the amount of data to be stored in the data storage unit while enabling color adjustment and light adjustment in a range substantially equal to that of the conventional configuration. It is an object of the present invention to provide a variable color lighting device that can be used.

[0008]

In order to achieve the above-mentioned object, the present invention selects a light emitting section provided with a plurality of light sources of different emission colors and a light color of mixed color light of the light sources provided in the light emitting section. a light color selection section, and the light intensity selector for selecting the quantity of mixed color light of the light source provided in the light emitting portion, the light color selected by the light color selector Oyo
A data storage unit which stores data for determining the dimming ratio of based on the selected optical amount each light source in the fine light amount selector,
Stored in the data storage unit with the light color selected by the light color selection unit
Required for the emission color of each light source obtained from the obtained data
A calculation unit for calculating a dimming ratio of each light source by using the stored in the optical amount and the data storage unit selected by the ratio and amount selected portion of the light flux data, each by dimming ratio calculated in the calculating portion It is provided with a dimmer that controls the dimming amount of the light source, and the computing unit calculates the dimming ratio of each light source for each selection of the light color in the light color selecting unit and the light amount in the light amount selecting unit. There is.

Further, the data storage section stores the luminescent color of each light source and the maximum output luminous flux, and the chromaticity coordinate values corresponding to a plurality of light colors of a type smaller than the types of light colors selectable by the light color selection section. Is stored in the calculation unit, and the arithmetic unit stores chromaticity coordinates corresponding to the light color selected based on the reference data when the light color selected by the light color selection unit is a light color other than the reference data. The value is calculated, and the mixture ratio in the emission color of each light source is calculated based on the obtained chromaticity coordinate value and the emission color of each light source.
It is desirable to calculate the dimming ratio that yields the above mixing ratio based on the output light flux .

It is desirable that the light emitting color of the light source forming the light emitting section is three or more colors, and one of the light emitting colors of the light source forming the light emitting section may be white.

[0011]

According to the configuration of the present invention, the data storage unit, based on the <br/> light amount selected by the light color and the light amount selector selected by the light color selector dimming of each light source It may be stored the data for determining the ratio, the calculating unit, for each selection of the amount of light in the light color and quantity selection unit in the optical color selection unit, selecting the light color selector
From the selected light color and the data stored in the data storage unit
The ratio of luminous flux and light quantity required for the emission color of each light source
The light quantity selected by the selector and the data stored in the data storage
The data is used to calculate the dimming ratio for each light source. Further, the difference from the conventional configuration is that the data after the calculation for obtaining the dimming ratio is stored in the storage unit or the dimming ratio is obtained based on the data stored in the storage unit. The dimming range can be set to the same range as the conventional configuration.

As data to be stored in the data storage unit, the luminescent color of each light source and the maximum output luminous flux, and chromaticity coordinates corresponding to a plurality of light colors less than the types of light colors selectable by the light color selection unit. When the light color selected by the light color selection unit is a light color other than the reference data, the chromaticity corresponding to the light color selected based on the reference data is adopted. If the coordinate values are obtained, it is possible to adjust a wide range with a small number of data. That is, the capacity of the data storage unit can be significantly reduced as compared with the conventional configuration. In addition, the light emission color and the maximum output light flux of each light source are stored in the data storage unit as data, and based on the chromaticity coordinate value corresponding to the light color selected by the light color selection unit and the emission color of each light source, Obtain the mixture ratio for each emission color to obtain the maximum output of each light source.
By calculating the dimming ratio that obtains the above-mentioned mixing ratio based on the power luminous flux , even if the specifications of the light emitting section (emission color of the light source or maximum output luminous flux) are changed, the data storage section By changing a small amount of data, it is possible to respond without affecting other data or configurations, and it is possible to flexibly respond to changes in specifications.

If the light emission color of the light source constituting the light emitting section is three or more, the range of toning is widened. In addition, if one of the light emission colors of the light source that constitutes the light emitting unit is white, the white illumination light used in general living lighting can be toned within the range of white while comparison is performed. It is possible to obtain a large amount of light with an extremely low electric power. That is, in the case of obtaining white illumination light, it is possible to secure a necessary amount of light by using an ordinary fluorescent lamp or an incandescent lamp as a light source, and to the extent that it can be warm-colored or cold-colored in the white range. It is sufficient to select a light source having a relatively small maximum output luminous flux for other light colors. As a result, even if the light emission efficiency of the light source other than the white light source is low, the power consumption of the light source is reduced and the power use efficiency is increased.

[0014]

Embodiment (Embodiment 1) In the present embodiment, the data selection unit 5 of the conventional configuration shown in FIG. 4 is used.
Is to read the dimming ratio from the data storage unit 7 and give the read dimming ratio to the dimming signal generation unit 6 in accordance with an instruction from the light color light amount selection unit 8, but as shown in FIG.
In this embodiment, an arithmetic unit 9 is provided instead of the data selection unit 5. That is, the data storage unit 7 includes the light sources 2R and 2R.
The emission colors and the maximum output luminous fluxes of G and 2B, and the coordinate values on the chromaticity diagram corresponding to the color temperature for each step by dividing the toning range into several steps are stored, and the arithmetic unit 9 selects the light color. Section and the light amount selection unit, which is also a light amount selection unit, reads out one or two required coordinate values among the coordinate values stored in the data storage unit 7 according to an instruction from the light color light amount selection unit 8 and the read coordinate values and the respective coordinate values. Light emission color and maximum for light sources 2R, 2G, 2B
Based on the output light flux , the dimming ratio corresponding to the instruction in the light color light amount selection unit 8 is calculated and obtained. Here, the dimming signal generation unit 6, the data storage unit 7, and the calculation unit 9 are realized as the control unit 3 including a microcomputer. The light color light amount selection unit 8 is provided with an up switch and a down switch for selecting a light color, and an up switch and a down switch for selecting a light amount. Also,
The emission colors of the respective light sources 2R, 2G, 2B stored in the data storage unit 7 are given as coordinate values on the chromaticity diagram, and are stored in the data storage unit 7 in the form shown in Table 2.

[0015]

[Table 2]

Further, the coordinate value on the chromaticity diagram for each stage of color temperature has a variable range of color temperature of 3000 to 30000K.
If it is, it is divided into, for example, 5 stages and set as shown in Table 3.

[0017]

[Table 3]

Here, the correspondence relationship between the color temperature stored in the data storage unit 7 and the address is the same as the conventional configuration.
In this way, the coordinate value on the chromaticity diagram corresponding to the color temperature stored in the data storage unit 7 is used as the reference data, and the arithmetic unit 9 uses the data relating to the light sources 2R, 2G, 2B and the reference data to perform the dimming. Calculate the ratio. When calculating the dimming ratio, if the color temperature instructed by the light / color light amount selection unit 8 matches the color temperature of the reference data (that is, the address obtained by the calculation unit 9 is the reference data of the data storage unit 7). (If it matches the address of 1), only one matching reference data is read out, and if they do not match, two reference data corresponding to the upper and lower color temperatures with respect to the designated color temperature are selected. When two pieces of reference data are selected, by interpolating the coordinate values on the chromaticity diagram based on the relationship between the address values of the two pieces of reference data and the designated address values, the target color Find the coordinate values on the diagram. This calculation is specifically as follows.

Now, it is shown that the color temperature selected by the light-color / light-amount selection unit 8 is 4900K, and the address value generated for this color temperature in the calculation unit 9 is 6Eh (h at the end is a hexadecimal number). ), This address value corresponds to 51h and 71 of the address values of the reference data.
It can be seen that it is a value between h and h. Since the change amount of the reciprocal of the color temperature when the address changes by 1 is set to be constant as in the conventional case, the coordinate value on the chromaticity diagram when the address changes by 1 is almost the same as the address. Proportional.
Therefore, the calculation unit 9 obtains the coordinate value (x ₀ , y ₀ ) on the chromaticity diagram corresponding to the color temperature given from the light / color light amount selection unit 8 by performing the following proportional calculation. (6Eh-51h) :( 71h- 51h) = (x 0 -0.373) :( 0.344-0.373)
(6Eh-51h) :( 71h- 51h) = (y 0 -0.376) :( 0.358-0.376) ∴x 0 ≒ 0.373 + (0.344-0.373) ×
0.91 ≈ 0.347 y ₀ ≈ 0.376+ (0.358-0.376) × 0.
91 ≈ 0.361 where (6Eh-51h) / (71h-51h) ≈
It was set to 0.91.

The data selection processing section 9 obtains coordinate values (x ₀ , y ₀ ) on the chromaticity diagram corresponding to the light color selected by the light color light quantity selection section 8, and then the light color light quantity selection section Table 2 regarding the light sources 2R, 2G, and 2B for the light amount selected in 8
The light control amount for each of the light sources 2R, 2G, and 2B is obtained by referring to the above data. By the way, each light source 2R, 2G, 2B
The coordinate values on the chromaticity diagram of the emission color of are respectively (x _R ,
y _R ), (x _G , y _G ), (x _B , y _B ), and the output luminous fluxes are Y _R , Y _G , and Y _B , respectively. Coordinate value (x
It is known that ₀ , y ₀ ) and the luminous flux Y ₀ have the relationship of Expression 1.

[0021]

[Equation 1]

Therefore, if the relational expression of equation 1 is used, the luminous fluxes Y _R , Y _G and Y of the respective light sources 2R, 2G and 2B for obtaining the desired light color (x ₀ , y ₀ ) and the luminous flux Y ₀ are obtained. You can ask for _B. For example, if the color temperature to be set is 4900K as described above and the luminous flux Y ₀ is set to 6000 lumens, the coordinate values on the chromaticity diagram corresponding to the color temperature 4900K are calculated by the proportional calculation described above. Therefore, it is possible to obtain (0.347, 0.360) by using the following formula. Therefore, the coordinate values (x _R , y _R ) corresponding to the emission colors of the light sources 2R, 2G, and 2B in Table 2 are (0.578, 0. 33
2), (x _G , y _G ) = (0.330, 0.531),
By substituting (x _B , y _B ) = (0.158, 0.143) and the luminous flux Y ₀ = 6000 into Equation 1, each light source 2
The luminous fluxes Y _R , Y _G and Y _B required for R, 2G and 2B can be obtained. That is, under the above conditions, Y _R : Y
_G : Y _B = 0.26: 0.63: 0.11 and the luminous flux Y ₀ is 6000 lumens. Therefore, Y _R = 6000 × 0.26 = 1560 lumens Y _G = 6000 × 0.63 = 3800 Lumen Y _B = 6000 × 0.11 = 660 lumens, and it is known from Table 2 that the maximum output luminous flux of each light source 2R, 2G, 2B is 2100 lumens, 3800 lumens, and 840 lumens, respectively. The dimming ratios for 2R, 2G, and 2B are 1560/2100 = 74% 3800/3800 = 100% 660/840 = 86%, respectively.

As described above, each light source 2R, 2G, 2B
If the dimming ratio for each is obtained, the dimming ratio created so as to obtain this dimming ratio is passed to the dimming signal generating unit 6, so that each of the dimmers 3R, 3G, 3B can be provided as in the conventional configuration. It is possible to control the dimming amount of each of the light sources 2R, 2G, 2B via the. The procedure of the arithmetic processing in the arithmetic unit 9 is summarized as shown in FIG. That is, when the light color and the light amount are designated as the address data by the light color light amount selection unit 8 (S1), the address corresponding to the designated light color is stored in the data storage unit 7 as shown in Table 3. It is determined whether or not it matches the address of the temperature reference data (S
2). If the determination result is a match, the coordinate value of the reference data corresponding to the matched address is read (S3), and if they are not the same, the address values of the reference data before and after the address are read (S4), and the above-described interpolation calculation is performed. Then, the corresponding coordinate value is obtained (S5). In this way, when the coordinate values on the chromaticity diagram corresponding to the light color instructed by the light-color / light-amount selecting unit 8 are obtained, the output light flux required for each of the light sources 2R, 2G, and 2B is based on Equation 1. Then, the dimming ratio is obtained by the ratio between the obtained luminous flux and the maximum output luminous flux of each light source 2R, 2G, 2B as shown in Table 2 (S7). When the dimming ratio is obtained in this way, the dimming ratio is created and passed to the dimming signal generator 6.

As described above, the process of creating the dimming ratio for the light color and the light amount selected by the light color light amount selection unit 8 is performed every time the selection (address) in the light color light amount selection unit 8 is changed. Therefore, compared with the case where the dimming ratios for all the options are stored in the data storage unit 7 in advance, the accuracy of the dimming ratio for the selection in the light color light amount selection unit 8 is not reduced, and the data The amount of data stored in the storage unit 7 is greatly reduced (1% or less). Further, in the above example, the adjacent reference data are interpolated with a straight line. However, when a section that cannot be interpolated with a straight line is generated due to a change in the toning range, the reference data as shown in Table 3 is used. It can be easily dealt with by changing. Furthermore, even when the specifications of the light sources 2R, 2G, 2B are changed, only the data relating to the light sources 2R, 2G, 2B shown in Table 2 need to be changed, and a small number of data changes are required for various specifications changes. Only by doing so, it is possible to respond easily. Here, instead of performing the interpolation using the straight line, the interpolation using the curve may be performed, and the interpolation method may be changed for each section between the reference data. For example, between the reference data, a section close to a straight line may be interpolated with a straight line, and a section close to a curve may be interpolated with a curve.

In the above embodiment, only the case where the light quantity is constant and the light color is changed has been described. However, the same applies to the case where the light color is constant and the light quantity is changed. When the light intensity is selected, each light source 2
The dimming ratio of R, 2G and 2B is determined. In addition,
Although the example in which the color temperature is variable has been described in the above embodiment, the light color may be arbitrarily changed without being limited to the color temperature, and the number of addresses and the data selectable by the light color / light amount selection unit 8 may be used. The number of reference data stored in the storage unit 7, the address of the reference data, and the like can be appropriately set according to the variable range of the light color and the light amount.

(Embodiment 2) In the embodiment 1, as the light emitting portion 1, light sources 2R, 2G, 2 of three colors of red, green and blue are used.
Although B was used, white light emission colors are often used in general living spaces. On the other hand, the blue light source 2B generally has a smaller maximum output light flux than the light sources 2R and 2G of other emission colors, and if the mixed color light is to be white, the maximum output light flux of the blue light source 2B causes the entire light flux to be emitted. Will be regulated. Therefore, in this embodiment, as shown in FIG.
An example is shown in which a white light source 2W is added to the light emitting unit 1 so that a sufficient luminous flux can be secured mainly when a white light emission color is obtained.

That is, each light source 2R, 2G, 2B, 2W
The coordinate values on the chromaticity diagram of the emission color of are respectively (x _R ,
y _R ), (x _G , y _G ), (x _B , y _B ), (x _W , y
_W ), and the output luminous fluxes are Y _R , Y _G , Y _B , and Y, respectively.
_When it is _W , the data selection processing unit 9 causes the coordinate value (x ₀ , y ₀ ) on the chromaticity diagram for the light color of the mixed color light and the light flux Y _0.
And are set as in Equation 2.

[0028]

[Equation 2]

Using Equation 2, the mixing ratio Y _R : Y _G :
Y _B : Y _W can be obtained, and the dimming ratio of each of the light sources 2R, 2G, 2B, 2W can be obtained in the same manner as in the first embodiment. That is, the procedure similar to that of the first embodiment except that the color temperature and the maximum output luminous flux of the white light source 2W are stored in the data storage unit 7, and the relational expression of Formula 2 is applied in the data selection processing unit 9. It is possible to determine the dimming ratio of each of the light sources 2R, 2G, 2B and 2W according to the light color and the light amount.

[0030]

According to the configuration of the present invention, the data storage unit, based on the light quantity selected in light colors selected by the light color selecting unit and the light amount selector dimming ratio of the light sources Data for determination is stored in advance, and in the calculation unit, the light color selection unit performs the light color selection unit for each selection of the light color in the light color selection unit and the light amount in the light amount selection unit.
The light color selected by and the data stored in the data storage unit.
The ratio of the luminous flux required for the emission color of each light source obtained from
And the amount of light selected by the light amount selection unit and the data storage unit.
Since the dimming ratio for each light source is calculated using the stored data, it is calculated for each selection of light color and light quantity when compared to the case where previously calculated data is stored in the data storage unit as in the past. By doing so, there is an advantage that the number of data to be stored in the data storage unit can be reduced. Further, the difference from the conventional configuration is that the data after the calculation for obtaining the dimming ratio is stored in the storage unit or the dimming ratio is obtained based on the data stored in the storage unit. The dimming range can be set to the same range as the conventional configuration.

As data to be stored in the data storage unit, the luminescent color of each light source and the maximum output luminous flux, and chromaticity coordinates corresponding to a plurality of light colors less than the types of light colors selectable by the light color selection unit. When the light color selected by the light color selection unit is a light color other than the reference data, the chromaticity corresponding to the light color selected based on the reference data is adopted. If the coordinate values are obtained, it is possible to adjust the color of a wide range with a small number of data, and it is possible to significantly reduce the capacity of the data storage unit as compared with the conventional configuration. In addition, the light emission color and the maximum output light flux of each light source are stored in the data storage unit as data, and based on the chromaticity coordinate value corresponding to the light color selected by the light color selection unit and the emission color of each light source, By calculating the dimming ratio that obtains the above-mentioned mixing ratio based on the maximum output luminous flux of each light source by calculating the mixing ratio of the luminous colors, the specifications of the light emitting part (the luminous color of the light source and the maximum output luminous flux) Even if there is a change in the specifications, it will be possible to respond without changing other data or configurations by simply changing a small amount of data regarding the light source in the data storage unit, and flexible response to specification changes will be possible. The effect is obtained.

If the light emission color of the light source constituting the light emitting portion is three or more, the range of toning is widened. In addition, if one of the light emission colors of the light source that constitutes the light emitting unit is white, the white illumination light used in general living lighting can be toned within the range of white while comparison is performed. This has the effect that a large amount of light can be obtained with a relatively small amount of power.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment.

FIG. 2 is an operation explanatory diagram of the first embodiment.

FIG. 3 is a block diagram showing a second embodiment.

FIG. 4 is a block diagram showing a conventional example.

[Explanation of symbols]

1 light emitting part 2R light source 2G light source 2B light source 2W light source 3 control unit 4R dimmer 4G dimmer 4B dimmer 4W dimmer 5 Data selection section 6 Dimming signal generator 7 Data storage 8 Light color light intensity selector 9 Operation part

Claims (4)

(57) [Claims] 1. A light emitting section having a plurality of light sources of different emission colors, a light color selecting section provided in the light emitting section for selecting a light color of the mixed color light of the light source, and a light color mixing section of the light source provided in the light emitting section. a light quantity selection unit for selecting a light amount, light color selected by the light color selector and
Storing a data storage unit which stores data for determining the dimming ratio of the light sources based on the light quantities selected by the light amount selector, a light color and a data storage unit that is selected by the light color selector It
The light required for the emission color of each light source obtained from the obtained data
A calculation unit for calculating a dimming ratio of each light source by using the stored in the optical amount and the data storage unit selected by the ratio and amount selected portion of the bundle data, each by dimming ratio calculated in the calculating portion And a dimmer for controlling the dimming amount of the light source, wherein the calculating unit calculates the dimming ratio of each light source for each selection of the light color in the light color selecting unit and the light amount in the light amount selecting unit. Variable color lighting device. 2. The data storage section stores the luminescent color and maximum output luminous flux of each light source, and chromaticity coordinate values corresponding to a plurality of light colors less than the types of light colors selectable by the light color selection section. When the light color selected by the light color selection unit is a light color other than the reference data, the calculation unit stores the chromaticity coordinates corresponding to the light color selected based on the reference data. obtains a value, determine the mixing ratio in emission color of each light source based on the chromaticity coordinate value calculated with the emission color of each light source exits up of each light source
2. The variable color lighting device according to claim 1 , wherein a dimming ratio with which the mixture ratio is obtained is calculated based on the power luminous flux . 3. The variable color lighting device according to claim 1, wherein the light source constituting the light emitting portion emits light in three or more colors. 4. The variable color lighting device according to claim 1, wherein one of the emission colors of the light source forming the light emitting portion is white.