JP2007036041A - Light-emitting apparatus and optical apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress deterioration in luminous efficiency due to light absorption by a phosphor. <P>SOLUTION: This apparatus has a first light source 3, a second light source 4 having a main luminescence wavelength band on a long wavelength side compared to the first light source 3, and a phosphor 8. The excitation wavelength band of the phosphor 8 is selected in a band nearer to the main luminescence wavelength band of the first light source 3 than to the main luminescence wavelength band of the second light source 4 for at least a central wavelength. The phosphor 8 is at least optically separated from the second light source 4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a light emitting device and an optical device having the light emitting device.

An LED (Light Emitting Diode) is known as a solid-state device that has a peak wavelength in a specific region of a light spectrum, that is, can emit light that is selectively enhanced only in a specific wavelength band. .
In recent years, LEDs based on gallium nitride that can efficiently emit only light in the blue wavelength band have been developed and widely used.

In addition, a light-emitting device capable of forming white light as shown in FIG. 7 by combining the blue LED and a phosphor that emits yellow light when excited by blue light, a so-called white LED is also proposed. Has been.
In this conventional light emitting device 101, a light source 103 containing InGaN that emits blue primary light by activation is provided by lead wires inside a housing 102 such as a reflector cup frame that improves the directivity of light emission by reflection. It is mounted while connected to an external power source. The light source 103 is covered with a filler 104 made of, for example, a transparent epoxy resin. A large number of yellow light-emitting phosphors 105 are embedded in the filler 104, and a lens 106 for adjusting the divergence angle of light emission is provided on the upper surface of the filler 104 and the casing 102 as necessary. .

Such a white LED, which is a combination of a blue LED and a yellow phosphor, has a spectral shape that covers a wide wavelength region, and therefore has a high luminance considering the visibility curve, and is currently attached to a mobile phone or a camcorder. It is used for LCD backlights.
However, since this white LED uses a combination of a blue LED and a yellow phosphor, the coloration such as pure green and red completely depends on the color filter, which is sufficient in terms of color purity. It is hard to say that it has the special characteristics.

Further, for example, as shown in FIG. 8, a first light source 203 and a second light source 204 having a main light emission wavelength band on the longer wavelength side than the first light source are respectively provided in a housing 202. The light emitting device is mounted in a state where it is connected to an external power source, and has a configuration in which a filler 205 is filled with a plurality of phosphors 206 dispersed and embedded so as to cover these light sources 203 and 204. 201 is proposed (for example, refer to Patent Document 1).
In the light emitting device 201, for example, a configuration in which a phosphor 206 having a light emission wavelength band in a green region and a first light source 203 using a blue LED that also serves as an excitation light source, as well as a second light source 204 using a red LED is provided. Thus, improvement in luminance and color purity in the white LED configuration is achieved.

However, if the green phosphor 206 is dispersed on and around the second light source 204 by a red LED, a for example as the phosphor _{206 (Sr (1-xy)} Ca x Ba y) Ga 2 S 4: Eu phosphor In the configuration using (0 ≦ x ≦ 1, 0 ≦ y ≦ 1, 0 ≦ x + y ≦ 1), the amount of the green phosphor is 3 wt% or more with respect to the resin when adjusting the white color temperature of 6000K to 12000K. Therefore, the phosphor particles absorb the red light from the second light source 204 as long as they are not perfect diffusion particles in an ideal state (particles that do not absorb red light emission and 100% completely scatter). In this case, not only the light emission efficiency at the time of coloration of white and red decreases, but also the red light does not contain sufficient energy for excitation of the phosphor, so the absorbed red light becomes heat and becomes the light emitting device 201. It diffuses in and causes the temperature of the entire device to rise.

As a technique for avoiding absorption (thermal conversion) of red light or the like that does not contribute to excitation of the phosphor, for example, in an illumination application intended for an indoor space, the first light source 203 and the second light source 204 By arranging the luminescent materials having different luminescent colors apart by increasing the distance, that is, by arranging the phosphors 206 in a distributed manner only in the vicinity of the first light source 203, the light is sufficiently mixed and the white color without unevenness. A technique for obtaining light has been proposed (see, for example, Patent Document 2).
JP 2004-80046 A JP 2003-529889 A

  However, for example, in an optical device having a back-illuminated pixel display unit, unlike the case of the above-described illumination application, the distance from the light emitting materials (light source and phosphor) constituting the backlight is mixed. It is difficult to widen the distance between the first light source 203 and the second light source 204 beyond a certain level due to restrictions and the demand for higher density in unit pixels.

  In an optical device such as a display device that requires color mixing at a short distance (color uniformity within a specific range), white uniformity is particularly important. When the green LEDs are arranged apart from each other, the light cannot be mixed sufficiently, so that white unevenness may occur, which is a serious problem.

  The present invention has been made in view of such a situation, and an object of the present invention is to provide a light emitting device in which color unevenness is suppressed without increasing the distance between the first light source and the second light source. It is in.

  The light emitting device according to the present invention includes a first light source, a second light source having a main light emission wavelength band on a longer wavelength side than the first light source, and a phosphor, and an excitation wavelength band of the phosphor. However, at least the central wavelength is selected to be closer to the main light emission wavelength band of the first light source than the main light emission wavelength band of the second light source, and the phosphor is at least optically separated from the second light source. It is characterized by being.

  The optical device according to the present invention is an optical device having a configuration for outputting light from the light emitting device to the outside, and the light emitting device is mainly on the longer wavelength side than the first light source and the first light source. A first light source having a second light source having a light emission wavelength band and a phosphor, the excitation wavelength band of the phosphor being at least the central wavelength of the first light source than the main light emission wavelength band of the second light source; A band close to a wavelength band is selected, and the phosphor is at least optically separated from the second light source.

  According to the light emitting device of the present invention, the first light source, the second light source having a main light emission wavelength band on the long wavelength side as compared with the first light source, and the phosphor, the phosphor is excited. The wavelength band is selected to be a band closer to the main light emission wavelength band of the first light source than the main light emission wavelength band of the second light source at least for the center wavelength, and the phosphor is at least optically from the second light source. Therefore, the absorption of light from the second light source by the phosphor is suppressed, and the light emission efficiency is maintained or improved.

  According to the optical device of the present invention, the light emitting device constituting the optical device includes a first light source, a second light source having a light emission wavelength band mainly on the longer wavelength side than the first light source, and a phosphor. The excitation wavelength band of the phosphor is selected to be closer to the main emission wavelength band of the first light source than the main emission wavelength band of the second light source at least for the central wavelength, and the phosphor However, since it is optically separated from the second light source, it is possible to reduce power consumption in the intended color display.

  Embodiments of the present invention will be described below with reference to the drawings.

<Embodiment of Light Emitting Device>
Embodiments of a light emitting device according to the present invention will be described.
As shown in FIG. 1, the light emitting device 1 according to the present embodiment includes a first light source 3 and a second light source having a light emission wavelength band mainly on the longer wavelength side than the first light source in the housing 2. 4 and 4 are placed in a state of being connected to an external power source by lead wires, and the first and second fillers 5 and 6 are so covered as to cover the first light source 3 and the second light source 4 respectively. , And filled with the partition wall 7 being separated and partitioned. Among these fillers, a large number of phosphors 8 are dispersed and embedded only in the first filler 5, and the phosphors 8 are at least optically separated from the second light source 4. . Except that the phosphor 8 is arranged, the first and second fillers 5 and 6 have a common composition.

As the first and second light sources 3 and 4, a blue LED and a red LED can be used, respectively. In this configuration, by applying a green phosphor as the phosphor 8 only on the blue LED side, it is possible to obtain a device configuration capable of obtaining three colors by two types of LEDs.
In addition, green LEDs, which have a wavelength band that has a large effect on visual sensitivity, form a light-emitting layer by mixing a large amount of impurities such as In into the crystals that make up a blue LED. Although it has been pointed out that the reproducibility of the wavelength and the luminance is lowered, according to the configuration of the light emitting device according to the present embodiment, since the green phosphor is used, the backlight configured to reduce the emission characteristic variation in the green region is configured. Is done.

  The red LED constituting the second light source 4 generally has a light emitting layer made of GaAs, and a predetermined light emission color can be obtained by adjusting the degree to which Al is dissolved in the manufacturing process. In addition, depending on the target emission color, a light-emitting layer configuration with AlInGaP is also possible, and red LEDs with these light-emitting layer configurations have less emission color variation than green LEDs, and the color area also affects the visibility. Therefore, the color purity and luminance of the light emitting device as a white LED are maintained well.

  The blue LED constituting the first light source 3 generally has a light emitting layer made of GaN, and a predetermined light emission wavelength band is selected by mixing In. Because it is less than green LEDs, it can be controlled with less variation, and the color area is less affected by visibility as well as red LEDs. Get smaller.

Also, as the green phosphor _{8, (Sr 1-xy Ca} x Ba y) Ga 2 S 4: be configured by Eu (0 ≦ x ≦ 1, 0 ≦ y ≦ 1, x + y ≦ 1) it can. In addition, when the (Sr _1-xy Ca _x Ba _y ) Ga ₂ S ₄ : Eu phosphor was synthesized 10 times and compared, it was found that the dispersion of the dominant wavelength (emission central wavelength) was ± 1 nm or less. . Each phosphor particle is a single crystal, and it is not surprising that the light emission characteristics vary. However, since phosphors generally have small variations in production (for example, from lot to lot), phosphors are used as a large number of particles (depending on the device; for example, thousands or tens of thousands). The characteristic variation of each phosphor is offset. Therefore, according to the light emitting device according to the present embodiment, the phosphor 8 and the entire device 1 can be configured to reduce variations in the light emission characteristics.

  As described above, the first and second fillers 5 and 6 can be made of a common composition, that is, a common material, except that the phosphor 8 is dispersed. This material is not limited to an epoxy resin, and it is also possible to use a silicone or a hybrid agent of silicone and epoxy resin.

The partition wall 7 is made of a material whose reflectance is larger than the transmittance at least in the main light emission wavelength band of the second light source 4. Examples of this material include acrylic resin, polycarbonate, and vinyl chloride. Various materials including white can be used, and the manufacturing process can be simplified as a material common to the housing 2. Is possible.
The height of the partition wall 7 (y in the figure) is preferably larger than the thicknesses of the first and second fillers 6 and 7. In this case, the phosphors 8 are more reliably distributed only on the first light source 3 side, and absorption of light from the second light source 4 by the phosphors 8 can be avoided.

  As described above, according to the light emitting device 1 having this configuration, the color purity by the three-color emission is obtained by using the blue LED, the red LED, and the green phosphor with little variation in structure and characteristics as the light source and the phosphor. Thus, a light emitting device with high and little variation can be formed.

<Embodiment of Optical Device>
An embodiment of an optical device according to the present invention will be described. For the sake of explanation, the same reference numerals are given to the same components as those of the embodiment of the light emitting device, and the duplicate description is omitted.

As shown in FIG. 2, the optical device 11 according to the present embodiment includes four light emitting devices 1 (thickness 0.6 mm, width 5 mm, chip size 0.3 mm square) on the edge of the light guide plate 12 ( A display device structure is provided adjacent to each other, and a first prism sheet (vertical direction) 13, a second prism sheet (horizontal direction) 14, and a diffusion sheet 15 are provided on the surface side of the light guide plate 12. The liquid crystal display has an edge type liquid crystal display configuration with a backlight in which the light guide plate 12 is laminated in this order and the reflection sheet 16 is formed on the back surface side of the light guide plate 12.
The first and second prism sheets 13 and 14 suppress the spread of light introduced from the reflection sheet 16 toward a liquid crystal element (not shown) in a direction perpendicular to each other (for example, perpendicular to the optical axis), Thereby, the light introduced into the liquid crystal element is sufficiently condensed in both the vertical direction and the horizontal direction.

In the present embodiment, the light source device 1 that constitutes the optical device 11 first prepares the housing 2 provided with the partition wall 7, and the emission center wavelength at a wavelength of 500 nm to 560 nm on the first light source 3 side by the blue LED. green phosphor having a _{(Sr 1-xy Ca x Ba} y) Ga 2 S 4: Eu phosphor is potted those dispersed 1 wt% 10 wt% to the resin and only resin in the second light source 4 side by the red LED Was prepared by potting and thermosetting at 100 to 160 ° C.
_{(Sr 1-xy Ca x Ba} y) Ga 2 S 4: Eu phosphor was extinguished blue emission spectrum of the blue LED when mixed least 30 wt%, since only the green emission spectrum is observed, the dispersion concentration of the above Selected.

  The measurement results of luminance, color gamut, and chromaticity in the optical device 11 in the case of this configuration will be described.

FIG. 3 shows the measurement result of luminance. The luminance measurement was performed in a state where a current of 20 mA was applied to each of the light sources 3 and 4 of the light emitting device 1.
As shown in FIG. 3, in the (Sr _1-xy Ca _x Ba _y ) Ga ₂ S ₄ : Eu phosphor, the composition changes in the range of 0 ≦ x ≦ 1, 0 ≦ y ≦ 1, and x + y ≦ 1. By doing so, the center wavelength (main wavelength) can be selected between 501 nm and 558 nm (solid line a to chain line e). In any composition, a luminance of about 1.0 could be obtained.
Although not shown, in the light emitting device according to the present embodiment, when the concentration of Eu was examined, the preferable Eu concentration in terms of light emission efficiency was 3 to 7 wt%.

  FIG. 4 shows the measurement results of the color gamut. In the figure, solid line a ′ to chain line e ′ correspond to solid line a to chain line e in FIG. 3. The target white chromaticity was (0.300, 0.300). As a comparative example, a color gamut in the case of a conventional optical device configuration by a conventional optical device is indicated as O. The chromaticity in the case of the conventional configuration is red (0.574, 0.338), green (0.319, 0.566), and blue (0.142, 0.128), and the white chromaticity is (0.315, 0.305). The area connecting these three points is the color gamut. The size of this color gamut is generally expressed by the area ratio that connects the three points of NTSC (National Television System Committee), which is the broadcasting standard, and the color gamut is the conventional device configuration. 48%.

In the optical device according to the present embodiment, as shown in FIG. 4, the color gamut changes between 62% and 70% corresponding to each measurement result having the center wavelength of 501 nm to 558 nm shown in FIG. I was able to confirm. However, as the emission wavelength of the green phosphor is closer to the short wavelength side, the green emission spectrum is mixed into a blue color filter (not shown) constituting the optical device 11, and the y value of the chromaticity of blue becomes larger. Since there is a tendency to increase, it is desirable to select a phosphor composition having a wavelength of 530 to 545 nm in terms of color purity among green. Considering efficiency and emission wavelength, SrGa ₂ S ₄ : Eu with x = 0 and y = 0 is considered most preferable.

In addition, the chromaticity of each color of red, green, and blue was measured for the optical device according to the present embodiment. As a result of the measurement, the chromaticity of each color was red (0.632,0292), green (0.252,0.627), and blue (0.142,0.142). When this color gamut was calculated, the NTSC ratio was 70%. It was also confirmed that the green and red colors were bright enough to clearly show a difference as compared with the conventional light emitting device.
Further, when the white chromaticity in the optical device according to the present embodiment was measured (0.305, 0.310), it can be confirmed that the luminance is 1.22 times compared to the case of the conventional optical device configuration, A 22% improvement in luminous efficiency was confirmed.

In order to investigate the cause of the improvement in luminous efficiency only in spite of no change in chromaticity, the characteristics of the green phosphor were evaluated. The evaluation was carried out by dispersing 4 wt% phosphor in the resin and setting its film thickness to 200 μm using a stainless steel spacer, and then measuring the transmittance of light having a wavelength of 600 to 670 nm. JASCO V-560 was used as the measurement device, and measurement including diffused light due to particles was performed by using an integrating sphere in the measurement system.
As a result of the measurement, it was confirmed that the transmittance of light having a wavelength of 600 to 670 nm was 71%. That is, when the green phosphor is used, it is considered that the particles are not completely white matter even in the red region, and thus are absorbed.

  As described above, in the configuration in which red light emission is absorbed, since it is necessary to reduce the content of the green phosphor in order to adjust the white chromaticity, the luminance is affected. For example, when the emission intensity of a red LED is reduced by 15%, the emission intensity of a blue-green LED must be reduced by about 15% in order to match the chromaticity during white emission. In this case, the luminance of the backlight is reduced by nearly 15%, so that the light emission efficiency is reduced as long as there is light absorption in the red region.

Although not shown, when other phosphors such as BaGa ₂ S ₄ : Eu (emission center wavelength 501 nm) and CaGa ₂ S ₄ : Eu (emission center wavelength 558 nm) were measured in the same manner, 4 wt% The transmittance of light having a wavelength of 600 nm to 670 nm under the condition of a film thickness of 200 μm was 73% and 74%, respectively.
Therefore, according to the optical device according to the present invention, the transmission characteristics have the above-described characteristics even when other materials are used as the green phosphor or when a newly known green light emitter is used in the future. It is possible to avoid or reduce a decrease in luminance that is difficult to avoid as long as it is held.

  In the optical device according to this embodiment, since the phosphor layer is about 400 μm, the film thickness is 51% when converted to 400 μm based on the Lambert-Beer law. The Lambert-Beer law is not intended for fitting in suspension, but is applied in a solution, but it is also suitable for a system in suspension state for a rough study. In the optical device according to the present embodiment, the transmittance at a film thickness of 200 μm is a true value (actual value), and the transmittance at a film thickness of 400 μm is a reference value (calculated value).

Next, the measurement result of the emission spectrum in the optical device 11 according to the present embodiment will be described.
As shown in FIG. 5, when white light is emitted, since the spectrum is split into blue, green, and red, it is considered that there is little color mixing of other colors into the blue, green, and red color filters.
As a comparative example, the measurement result of the emission spectrum in the conventional optical device (white LED) is shown in FIG. As is clear from the figure, the spectrum exists in a wide wavelength range, and the spectrum is not split into green and red, so other colors are mixed in the blue, green and red color filters. it is conceivable that.
From this result, it was confirmed that the optical device according to the present invention can also reduce color mixing.

  Next, the result of examining the distance (x in FIG. 3) between the first light source 3 and the second light source 4 will be described. The measurement was performed using a 2.2-inch (4: 3) size backlight. This size is recently used for mobile phone displays. In electronic devices such as mobile phones, the distance until light emitted from each light source is color-mixed inevitably tends to become shorter due to the demands of both miniaturization of the phone body and increase in display area. For example, since the size in this example is limited to a distance of about 4 mm, only four of the first light source 3 and the second light source 4 can be arranged on the short side. Therefore, the size in this example is considered to be the size that is the strictest evaluation standard from the viewpoint of color mixing.

The examination was conducted by subjective evaluation. The color unevenness evaluation on the display may be measured with an unevenness measuring device, but even when this measuring device is used, it is ultimately necessary to evaluate with the human eye. went.
The evaluation of color unevenness in white is 1 point (blue-green and red can be clearly recognized), 2 points (blue-green and red can be recognized by looking closely), 3 points (blue-green and red are difficult to recognize, 4 points (not interested at all). Three samples each having the same configuration were produced. From the viewpoint of yield, it is preferable that all three samples according to each configuration have 4 points.
In addition, since this test is for investigating the relationship between the LED interval and the white unevenness, the red unevenness and the blue-green LED were separately prepared and evaluated for the white unevenness until the LED interval was 6 mm. However, when the interval is smaller than 6 mm, the integrated device configuration according to the present embodiment shown in FIG. 1 is used, and the white unevenness is evaluated by changing the interval between the blue and red LED chips. This is because it is difficult to make the interval extremely short when arranging and arranging the LEDs separately, and the backlight of the mobile phone display which is an example of the optical device is several cm in length. On the other hand, since the size of each LED and electrode is several mm, the evaluation corresponding to the configuration on mounting is preferable.

When red LEDs and blue-green LEDs were alternately arranged at intervals of 7 mm and white unevenness was evaluated, it was confirmed that no color was mixed at all in one of the three samples.
When white LEDs were evaluated by alternately arranging red LEDs and blue-green LEDs every 6 mm, it was confirmed that color mixing was insufficient at all three samples.
When white LEDs were evaluated by alternately arranging red LEDs and blue-green LEDs every 5 mm, two samples were 3 points and one sample was 4 points.
When white LEDs were evaluated by alternately arranging red LEDs and blue-green LEDs at intervals of 4 mm, all three samples satisfied white uniformity at four points.

From this examination result, the distance between the first light source and the second light source is preferably 5 mm or less, and particularly within 4 mm, it is possible to obtain an index that exhibits good characteristics in both white unevenness and yield. Therefore, in the case of the integrated form as shown in FIG. 1, not only the ease of handling in backlight production but also the light emission efficiency is improved.
Note that the 2.2-inch backlight in this study was used because the color mixing distance was the shortest, so it was the most stringent evaluation standard for color mixing. Since the distance of is also long, the distance between the first light source and the second light source can be increased. In this study, an edge-type optical device was examined, but in the case of a direct-type device configuration (LEDs are arranged directly below the liquid crystal panel), the thickness of the light-emitting device (backlight) is changed. In addition, since color mixing is possible using a light diffusing plate or sheet, the distance between the first light source and the second light source can be further increased, and the optical device can be used without any problem.

  As described in the above embodiments, according to the light emitting device and the optical device of the present invention, when the green phosphor having absorption in the red wavelength portion is used as the green phosphor, the second light source and the first light source are used. By optically separating the light source, it is possible to suppress the phosphor particles from being mixed in the red LED chip portion and to suppress the decrease in light emission efficiency. Furthermore, by integrating the blue LED and the red LED, handling in backlight manufacturing can be facilitated, the distance between the first light source and the second light source can be further reduced, and white unevenness can be suppressed. .

  Note that the numerical conditions such as the materials used, the amount thereof, the processing time, and the dimensions mentioned in the description of the above embodiments are only preferable examples, and the dimensional shape and the arrangement relationship in each drawing used for the description are also schematic. Is. That is, the present invention is not limited to this embodiment.

It is a schematic block diagram which shows the structure of an example of the light-emitting device which concerns on this invention. It is a schematic block diagram which shows an example of a structure of the optical apparatus which concerns on this invention. It is a schematic diagram which shows the light emission brightness | luminance of a green fluorescent substance in an example of the optical apparatus which concerns on this invention. It is a schematic diagram which shows a color gamut in an example of the optical apparatus which concerns on this invention. It is a schematic diagram which shows the emission spectrum in an example of the optical apparatus which concerns on this invention. It is a schematic diagram which shows the emission spectrum in the conventional optical apparatus. It is a schematic block diagram which shows the structure of the conventional light-emitting device. It is a schematic block diagram which shows the structure of the conventional light-emitting device.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Light-emitting device, 2 ... Housing | casing, 3 ... 1st light source, 4 ... 2nd light source, 5 ... 1st filler, 6 ... 2nd filler, 7 ... partition wall, 8 ... phosphor, 11 ... optical device, 12 ... light guide plate, 13 ... first prism sheet, 14 ... second prism sheet, 15 ... Diffusion sheet, 16 ... reflective sheet, 101 ... conventional light emitting device, 102 ... casing, 103 ... light source, 104 ... filler, 105 ... phosphor, 106 ... Lens: 201 ... Conventional light emitting device, 202 ... Case, 203 ... First light source, 204 ... Second light source, 205 ... Filler, 206 ... Phosphor

Claims (10)

A first light source, a second light source having a main emission wavelength band on the long wavelength side compared to the first light source, and a phosphor,
The excitation wavelength band of the phosphor is selected to be a band closer to the main emission wavelength band of the first light source than the main emission wavelength band of the second light source, at least for the central wavelength,
The phosphor is at least optically separated from the second light source. The light emitting device according to claim 1, wherein a large number of the phosphors are dispersed in a filler covering the first light source. The first light source and the second light source are coated with a filler having a common composition;
The light-emitting device according to claim 1, wherein the phosphor is disposed only in the filler on the first light source side. The partition wall made of a material whose reflectance is larger than the transmittance is provided between the first light source and the second light source at least in the main light emission wavelength band of the second light source. 2. The light emitting device according to 1. Between the first light source and the second light source, a partition wall made of a material whose reflectance is larger than the transmittance is provided at least in the main light emission wavelength band of the second light source,
The light emitting device according to claim 1, wherein a height of the partition wall is larger than a thickness of a filler covering the first light source and the second light source. 2. The light emitting device according to claim 1, wherein a main light emission wavelength band of the phosphor is selected on a shorter wavelength side than a main light emission wavelength band of the second light source. The light emitting device according to claim 1, wherein the first light source is a blue light source, the second light source is a red light source, and the phosphor is a green light source. The light emitting device according to claim 1, wherein a distance between the first light source and the second light source is 5 mm or less. An optical device having a configuration for outputting light from a light emitting device to the outside,
The light emitting device is
A first light source, a second light source having a main emission wavelength band on the long wavelength side compared to the first light source, and a phosphor,
The excitation wavelength band of the phosphor is selected to be a band closer to the main emission wavelength band of the first light source than the main emission wavelength band of the second light source, at least for the central wavelength,
The optical device, wherein the phosphor is at least optically separated from the second light source. The optical device according to claim 9, further comprising a back-illuminated pixel display unit using the light emitting device.

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