This application claims the benefit of Japanese Priority Patent Application JP 2013-159328 filed Jul. 31, 2013, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a light source device suitable for a planar light source and to a display unit performing image display with use of illumination light from the light source device.
Backlight system used in a liquid crystal display unit and the like includes a direct system and an edge light system. As these backlights, in recent years, a light emitting diode (LED) is often used for a light source. When the LED is used as the light source, for example, there is a method in which surroundings of a blue LED is sealed by a resin containing a fluorescent substance to mix blue light and light emitted from the fluorescent substance, and thus white light is obtained. As another method, there is a method in which a fluorescent substance layer is disposed separately from the light source to obtain white light (Japanese Unexamined Patent Application Publication No. 2009-140829).
The backlight as described above desirably has high uniformity as a planar light source. For example, uniform white light less in color unevenness and luminance unevenness may be desired. In the Japanese Unexamined Patent Application Publication No. 2009-140829, although there is proposed that a light control section that allows light from a light emitting element to enter a light emission surface of the fluorescent substance layer from a vertical direction or a substantially vertical direction is included and viewing angle dependency of chromaticity distribution of the fluorescent substance layer is suppressed, illumination light with higher quality is desired.
It is desirable to provide a light source device and a display unit that are capable of improving quality of illumination light.
According to an embodiment of the technology, there is provided a light source device including: a substrate; a plurality of light sources disposed on the substrate; a wavelength conversion member disposed to face the plurality of light sources; and a diffusion member disposed between the wavelength conversion member and the plurality of light sources, and configured to uniformize distribution of traveling direction angle of incident light.
According to an embodiment of the technology, there is provided a display unit provided with a light source device configured to emit illumination light and a display section configured to display an image based on the illumination light from the light source device. The light source device includes: a substrate; a plurality of light sources disposed on the substrate; a wavelength conversion member disposed to face the plurality of light sources; and a diffusion member disposed between the wavelength conversion member and the plurality of light sources, and configured to uniformize distribution of traveling direction angle of incident light.
In the light source device and the display unit according to the respective embodiments of the disclosure, the distribution of the traveling direction angle of the incident light is uniformized by the diffusion member disposed between the wavelength conversion member and the plurality of light sources.
In the light source device and the display unit according to the respective embodiments of the disclosure, the diffusion member is disposed between the wavelength conversion member and the plurality of light sources. Therefore, it is possible to improve quality of illumination light.
Note that the effects described here are not necessarily limited, and any effect described in the present disclosure may be obtained.
It is to be understood that both the foregoing general description and the following detailed description are exemplary, and are intended to provide further explanation of the technology as claimed.
The accompanying drawings are included to provide a further understanding of the disclosure, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments and, together with the specification, serve to explain the principles of the technology.
Hereinafter, preferred embodiments of the disclosure will be described in detail with reference to drawings. Note that description will be given in the following order:
1. First embodiment (a structure example in which a diffusion member is disposed)
2. Second embodiment (a structure example in which a prism sheet is additionally disposed)
3. Third embodiment (a structure example in which a cut filter is additionally disposed)
4. Numerical examples
5. Other embodiments
The light source device includes a light source substrate 1, a plurality of light sources 2, the wavelength conversion sheet 3 serving as a wavelength conversion member, a diffusion member 4, an optical sheet 5, a reflective sheet 6 serving as a reflection member, a resist layer 7, a back chassis 101, and a middle chassis 102.
The light source substrate 1 is disposed on a bottom surface of the back chassis 101. The back chassis 101 has a shape in which a peripheral part folded upward, and the middle chassis 102 is attached to an end of the peripheral part. In the peripheral part of the back chassis 101, a flat part is formed inside the part attached to the middle chassis 102, and a peripheral part of the diffusion member 4 is supported by the flat part. The wavelength conversion sheet 3 and the optical sheet 5 are disposed on a light emission surface (a front surface) side of the diffusion member 4. When the light source device is applied to a display unit, a display panel may be disposed on a light emission surface (a front surface) side of the optical sheet 5. In such a case, a peripheral part of the display panel may be supported by the middle chassis 102.
The wavelength conversion sheet 3 is disposed so as to face the plurality of light sources 2. The diffusion member 4 is disposed between the wavelength conversion sheet 3 and the plurality of light sources 2. The diffusion member 4 is to uniformize distribution of traveling direction angle of incident light. As the diffusion member 4, one diffusion plate or one diffusion sheet may be used, or two or more diffusion plates or two or more diffusion sheets may be used.
The optical sheet 5 is disposed on a light emission surface (a front surface) side of the wavelength conversion sheet 3. For example, the optical sheet 5 may be formed of a sheet or a film to improve luminance. For example, the optical sheet 5 may include a prism sheet. In addition, the optical sheet 5 may include a reflection type polarization film such as a dual brightness enhancement film (DBEF).
On the light source substrate 1, a not illustrated wiring pattern is formed to allow independent light emission control for every one or every two or more light sources 2. Therefore, local light emission control (local dimming) of the plurality of light sources 2 is allowed to be performed. As the light source substrate 1, a resin film such as polyethylene terephthalate (PET), fluorine, and polyethylene naphthalate (PEN) that is printed with a wiring pattern may be used. In addition, a metal base substrate such as aluminum (Al) that has a polyimide or epoxy-based insulation resin layer on a surface and is printed with a wiring pattern of a material having a light reflectivity on the insulation resin layer may be used. Moreover, a film substrate formed of a glass-containing resin such as glass epoxy resin (FR4) and glass composite resin (CEM3) on which a wiring pattern of the material having light reflectivity is printed may be used. Examples of the material having light reflectivity may include, for example, Al, silver (Ag), and an alloy thereof.
The resist layer 7 and the reflective sheet 6 are disposed in order on the light source substrate 1. The reflective sheet 6 is disposed in an in-plane region that is different from in-plane regions provided with the plurality of light sources 2 on the light source substrate 1.
The resist layer 7 is a white resist layer relatively high in reflectance to light from the light sources 2 and light that is wavelength-converted by the wavelength conversion sheet 3. Examples of white resist may include, for example, inorganic materials such as titanium oxide (TiO2) microparticles and barium sulfate (BaSO4) microparticles, and organic materials such as porous acrylic resin microparticles having myriad of holes for light scattering, and polycarbonate resin microparticles.
The reflective sheet 6 has a high reflectance to the light from the light sources 2 and the light that is wavelength-converted by the wavelength conversion sheet 3. The reflective sheet 6 may contain Ag as a material having high reflectance. As illustrated in
In the in-plane region provided with the through holes 61, the resist layer 7 is exposed around the light sources 2. Therefore, the outermost surface of the light source substrate 1 is the reflective sheet 6 in the in-plane region other than the through holes 61, and is the light sources 2 and the resist layer 7 in the in-plane regions provided with the through holes 61.
As illustrated in
As illustrated in
The light source 2 may be, for example, a blue light source (for example, wavelength of 440 nm to 460 nm), and the wavelength conversion material 31 absorbs blue light from the light source 2 and converts part of the absorbed light into red light (for example, wavelength of 620 nm to 750 nm) or green light (for example, wavelength of 495 nm to 570 nm). In this case, when the light from the light source 2 passes through the wavelength conversion material 31, red, green, and blue light are synthesized to generate white light. Moreover, the wavelength conversion material 31 may absorb the blue light to convert part of the absorbed light into yellow light. In this case, when the light from the light source 2 passes through the wavelength conversion material 31, yellow and blue light are synthesized to generate white light.
The wavelength conversion material 31 may preferably contain the quantum dots. The quantum dots are particles each having a diameter of about 1 nm to about 100 nm, and have discrete energy level. Since the energy state of the quantum dots depends on the size, changing the size makes it possible to freely select light emission wavelength. Moreover, light emitted from the quantum dots has a narrow spectrum width. Color gamut is expanded by combination of such light having steep peak. Therefore, using the quantum dots for the wavelength conversion material 31 makes it possible to easily expand the color gamut. Further, the quantum dots have high responsiveness, which makes it possible to efficiently utilize the light from the light sources 2. In addition, the quantum dots have high stability. For example, the quantum dots may be a compound of group 12 elements and group 16 elements, a compound of group 13 elements and group 16 elements, or a compound of group 14 elements and group 16 elements, and may be, for example, CdSe, CdTe, ZnS, CdS, PbS, PbSe, CdHgTe, or the like.
(Function of Entire Light Source Device)
Moreover, part of the light LB2 and LB3 that are not wavelength-converted becomes light (downward light LB1) directed rearward (the substrate 1 side) from the wavelength conversion sheet 3. Furthermore, part of the light directed frontward out of the light LB2 and LB3 that are not wavelength-converted becomes recurrent light by the optical sheet 5 such as DBEF, and becomes the downward light LB1. The downward light LB1 is reflected by the front surface (mainly the reflective sheet 6) of the light source substrate 1 and directs toward the wavelength conversion sheet 3 again, and part thereof is wavelength-converted. Likewise, downward light LY1 out of the wavelength-converted light LY is reflected by the front surface of the light source substrate 1 and thus becomes light directed frontward. In this way, the downward light LB1 and LY1 are reflected by the front surface of the light source substrate 1, and thus become recycle light to generate white light. The recycle of the downward light LB1 and LY1 may be performed, for example, four or five times in some cases. Therefore, final luminance of the white light emitted from the light source device is obtained from the light containing the recycle light.
(Function of Diffusion Member 4)
A function of the diffusion member 4 is described with reference to
On the other hand,
Displacement of the diffusion member 4 on the light incident side of the wavelength conversion sheet 3 makes it possible to suppress occurrence of the above-described color unevenness. For example, as illustrated in
As described above, in the first embodiment, the diffusion member 4 is provided between the wavelength conversion sheet 3 and the plurality of light sources 2. Therefore, it is possible to suppress occurrence of color unevenness and to improve quality of illumination light.
Note that the effects described in the present specification are merely examples without limitation, and other effects may be obtainable.
(Structure)
(Function and Effects)
Function and Effects obtained by using the diffuser with the shaped surface 40 are described below.
When the diffuser with the shaped surface 40 is omitted from the structure, in the wavelength conversion sheet 3, luminance difference occurs between a region directly above the light source 2 and a region between adjacent light sources 2, and luminance unevenness occurs. Hereinafter, such luminance unevenness is referred to as “granular unevenness”. To dissolve the granular unevenness, there is a method in which a post-attached lens 24 is provided to the light source 2 as with a light source device according to a comparative example illustrated in
On the other hand, when the diffuser with the shaped surface 40 is used, the apparent number of light sources 2 is allowed to be increased as described above. Therefore, it is possible to dissolve the granular unevenness without using the post-attached lens 24 as illustrated in
(Structure)
In the structure example illustrated in
The light emitting element chip 13 is electrically connected to the wiring layers 14A and 14B through wirings (bonding wires) 15A and 15B such as Al and Ag. The light emitting element chip 13 is driven by a current flowing through the wiring layers 14A and 14B and the wirings 15A and 15B, and emits light.
The light emitting element chip 13 is mounted directly on the chip mounting layer 14C. In this case, “directly” indicates that the back surface of the light emitting element chip 13 is bonded to the chip mounting layer 14C by die bonding or the like without packaging the light emitting element chip 13 or providing a reflective layer such as a tin or gold plating layer between the chip mounting layer 14C and the light emitting element chip 13. However, an adhesive layer such as transparent paste 16 for die bonding may be interposed between the chip mounting layer 14C and the light emitting element chip 13. Incidentally, although the transparent paste 16 does not have conductivity, when an LED chip having electrodes on both surfaces is used, the transparent paste 16 may have conductivity because the chip mounting layer 14C has a function as a current path.
For example, the resist layer 7 may be formed as a solid film on the entire surface of the light source substrate 1 other than a region mounted with the light emitting element chip 13 and a region where the light emitting element chip 13 is connected to the wiring layers 14A and 14B. The reflective sheet 6 is disposed on the resist layer 7. As with the structure example of
The sealing lens 12 protects the light emitting element chip 13 and improves extraction efficiency of light L emitted from the light emitting element chip 13. The sealing lens 12 is formed of a sealant (for example, a transparent resin such as silicone and acryl) so as to cover the entire light emitting element chip 13.
The sealing lens 12 is formed in a dome lens shape by the sealant. For a reason described later, in terms of a height h and a radius r of the dome lens shape, the sealing lens 12 may preferably satisfy the condition of 0.65≤h/r≤1.
In the light source 2A, the light emitted from the light emitting element chip 13 is extracted frontward through the sealing lens 12, and part of the light travels from the back surface side of the light emitting element chip 13 to the light source substrate 1 side (the back surface emitted light). The back surface emitted light L is reflected by the front surface of the chip mounting layer 14 that is mounted with the light emitting element chip 13 and has a high light reflection function, and is then extracted frontward as illustrated in
(Function and Effects)
A function and effects obtained by using the direct potting type light sources 2A is described below.
In a normal planar light source device, for example, a white LED package in which a sealant mixed with a fluorescent substance that converts a wavelength of light into a wavelength of yellow, or green and red is mounted on a blue LED chip is used as the light source. In this case, light emitted from (wavelength-converted by) the fluorescent substance is emitted in all directions. In addition, blue light that is not absorbed by the fluorescent substance and is reflected by the surface of the fluorescent substance is also reflected in all directions. In other words, the sealant itself functions as the fluorescent substance, and the extraction efficiency of light from the LED package is not greatly varied depending on the sealant, namely, the lens shape. However, in the present embodiment, as with the structure example in
In the case where the above-described blue LED package is considered to be used as the light source 2 to be combined with the wavelength conversion sheet 3, a lens (a sealant) on the normal LED package mainly has a flat shape. Although a small number of dome lenses are produced, an aspect ratio thereof is typically about 0.5 to about 0.6. In this example, the aspect ratio is a ratio of the height h and the radius r of the dome lens shape, namely, h/r. When the aspect ratio is 1, the shape is hemisphere shape.
In the case of the above-described blue LED package, the blue light is emitted from an LED chip smaller than the lens diameter. Therefore, in the case where the LED chip is assumed to be a point light source to the lens, in a flat lens shape, for example, when a refractive index of silicone as the lens material is assumed to be n=1.45, light at an angle of θ=43.6 degrees or more that is emitted from the LED chip is totally reflected and is returned to a bottom side, and is emitted to the outside of the package after being repeatedly reflected by side walls or a bottom surface in the package. In this way, since the part of light is repeatedly reflected in the package, which results in degradation of luminance efficiency. In contrast, in the LED package having the hemispherical dome lens, most of the light emitted from the LED chip located at the center of the lens directs in a normal direction to the lens outer shape, and therefore, the light is scarcely reflected and is emitted as it is. Accordingly, luminance efficiency becomes high.
Since the light source 2A according to the present modification has the direct potting type structure, the sealing lens 12 is easily formed in a dome shape having an aspect ratio of 0.65 or more and 1 or less, and thus the luminance efficiency is allowed to be increased. Moreover, the refractive index of the sealant (for example, silicone) is increased to be close to the refractive index of the base material (for example, sapphire) of the light emitting element chip 13, which makes it possible to suppress reflection between the light emitting element chip 13 and the sealant to further increase the luminance efficiency. Furthermore, it is possible to achieve dome-shaped LED package at a price lower than that of a normal LED package that is not of the direct potting type.
Table 1 illustrates a comparison results between the extraction efficiency of the blue light in the case where the direct potting type light source 2A is used and the extraction efficiency of the blue light in the case where the normal LED package (the normal PKG) that is not of the direct potting type. PKG indicates a package. The blue LED chip is used as the light emitting element chip 13, and silicone is used as the sealant. As is apparent from Table 1, when the lens shape is formed in a dome shape, the extraction efficiency is improved. In addition, when the aspect ratio is close to 1, the extraction efficiency is improved. As a result, when the direct potting type light source 2A according to the present modification is used, the extraction efficiency of the blue light is improved, and thus luminance efficiency is increased.
Also in the light source device according to a second embodiment, as with the case described with use of
(2.2 Function and Effects)
As described with use of
On the other hand, when the local dimming is performed, non-lighting part and finely-lighting part are generated in the plurality of light sources 2, and thus difference in light emission distribution of the plurality of light sources 2 is generated. In this case, intensity difference is generated for each optical path of light (for example, blue light) that enters the wavelength conversion sheet 3 from the respective light sources 2, and color unevenness in which the non-lighting part and the finely-lighting part turn yellow as compared with normal lighting part occurs. Moreover, in a state where the local dimming is performed, from above the light source 2 that emits light at normal intensity, light returning from the wavelength conversion sheet 3 and the optical sheet 5 to the back side (the substrate 1 side) is reflected while being diffused by the reflective sheet 6, is then spread to the front side of the non-lighting part and the finely-lighting part, and then returns to the wavelength conversion sheet 3 side again. The returned light passes through the wavelength conversion sheet 3 again, and for example, may be converted into green light or red light with use of part of blue light (while decreasing the blue light). Therefore, the light after passing through the wavelength conversion sheet 3 that is generated by returned light becomes yellowish, which enhances yellow coloring of the non-lighting part and the finely-lighting part. As a result, when it is applied to the display unit, an image at the finely-lighting luminance display part by the local dimming becomes yellowish to impair dignity. Note that, when it is used as a backlight of a liquid crystal display unit, color change to yellow by a planar light source is not observed because a pixel opening by liquid crystal is closed at a black display part. According to the second embodiment, it is possible to suppress occurrence of color unevenness at the time of the above-described local dimming, by a function of the prism sheet 8.
As described in the above-described second embodiment, when the local dimming is performed, the non-lighting part and the finely-lighting part are generated in the plurality of light sources 2, which causes color unevenness in which the non-lighting part and the finely-lighting part become, for example, yellowish as compared with the normal lighting part. According to the third embodiment, providing the cut filter 9 makes it possible to suppress reflection of the wavelength-converted downward light LY1 (for example, yellow light), and thus yellow light reused as recycle light is decreased. Accordingly, occurrence of color unevenness to yellowish is suppressed.
Effects of luminance improvement by dissolving the granular unevenness in the first modification of the first embodiment described above (in the structure example in which the diffuser with the shaped surface 40 is disposed as the diffusion member 4) were specifically simulated. Simulation results are illustrated in Table 2 and Table 3.
Table 2 and Table 3 illustrate results obtained by methods of dissolving granular unevenness that are roughly divided into following three methods.
Method 1: a structure in which the post-attached lens 24 (see
Method 2: a structure in which the diffuser with the shaped surface 40 is disposed (without the post-attached lens 24)
Method 3: a structure in which only the normal diffusion member 4 is disposed (a method in which the granular unevenness is eliminated by increasing the number of LEDs as the light sources 2A without providing the post-attached lens 24)
As a structure common to the respective methods, cross-arranged two prism sheets and the DBEF were disposed as the optical sheet 5, in addition to the normal diffusion member 4 or the diffuser with the shaped surface 40. Moreover, an optical distance between the light sources 2 or 2A and the wavelength conversion sheet 3 was set to 16 mm. The entire size of the light source device was 55 inches.
The calculation was made assuming that the number of LEDs as the light sources 2 or 2A necessary for dissolving the granular unevenness was as follows:
Method 1: 680 pieces
Method 2: 832 pieces
Method 3: 1360 pieces
Moreover, in the respective methods described above, the calculation was made assuming that the package size (PKG size) of the LED as the light source 2 was as follows. Note that, in the method 1, the direct potting type structure is not provided.
Normal size: 3.2 mm×2.85 mm
Small size 1: 4 mm×2 mm
Small size 2: 3 mm×1.4 mm
Direct potting type (Dir P): ϕ3 mm
The following values were used as the other conditions.
Transmittance of post-attached lens 24 (acryl): 93%
Reflectance of reflective sheet 6: 98%
Reflectance of resist layer 7: 70%
Reflectance of LED package (normal and small size): 88%
Reflectance of direct potting type LED package: 81%
Reflectance of LED package below post-attached lens 24: 79.4%
Reflectance of resist layer 7 below post-attached lens 24: 86.4%
Incidentally, as described above, in the reflective sheet 6, the through holes 61 to dispose the light sources 2 or 2A are formed. Therefore, in the region of the through holes 61, exposed surfaces of the resist layer 7 are provided around the light sources 2 or 2A. In Table 2, results obtained by calculating respective area ratios occupied by LED package, the exposed surfaces of the resist layer 7, the reflective sheet 6, and the like, on the outermost surface of the light source substrate 1 are illustrated for each method.
In Table 3, reflectance of the entire region of the outermost surface on the light source substrate 1 as a whole is illustrated as a total (TTL) reflectance. In addition, as described above, light recycle is performed between the light source substrate 1 and both of the wavelength conversion sheet 3 and the optical sheet 5 by reflection on the light source substrate 1. The inventor of the present application confirmed from experiment that luminance as the light source device is obtained by performing recycle four times. In other words, since reflection is performed four times on the light source substrate 1, fourth power of the TTL reflectance is calculated. The value of the fourth power of the TTL reflectance corresponds to final luminance. In Table 3, to compare difference in final luminance, results obtained by comparing and calculating the fourth power of the TTL reflectance for each method and for each size of the LED package are illustrated.
It is found from the simulation results that using the diffuser with the shaped surface 40 is advantageous in luminance improvement irrespective of the size and form of the LED package. Moreover, in the respective methods, it is found that when the distance of opposing corners of the LED package or the size ϕ of the direct potting type light source is equal to or smaller than 77% of the size of the normal LED package, the area ratio occupied by the reflective sheet 6 is increased, and the luminance is accordingly improved. In this example, the size of the opposing corners of the normal LED package is 4.3 mm, the size of the opposing corners of the LED package of the above-described small size 2 is 3.3 mm, and the ratio thereof is 0.77.
The technology of the present disclosure is not limited to those described in the respective embodiments, and is variously modified.
For example, the light source device according to any of the above-described embodiments may be applied as a backlight of a display unit 201 as illustrated in
For example, the present technology may be configured as follows:
(1) A light source device including:
a substrate;
a plurality of light sources disposed on the substrate;
a wavelength conversion member disposed to face the plurality of light sources; and
a diffusion member disposed between the wavelength conversion member and the plurality of light sources, and configured to uniformize distribution of traveling direction angle of incident light.
(2) The light source device according to (1), wherein the diffusion member is a diffuser with a shaped surface.
(3) The light source device according to (2), wherein the diffuser with the shaped surface has optical elements two-dimensionally arranged on a surface, each of the optical elements having a predetermined shape.
(4) The light source device according to any one of (1) to (3), wherein each of the light sources has a light emitting element chip and a sealant that seals the light emitting element chip on the substrate.
(5) The light source device according to (4), wherein a dome lens is formed of the sealant and a following condition is satisfied,
0.65h/r≤1
where h is a height of the dome lens and r is a radius of the dome lens.
(6) The light source device according to any one of (1) to (5), further including
a first prism sheet disposed between the wavelength conversion member and the diffusion member and having a plurality of first prisms on a surface, each of the plurality of first prisms extending in a first direction.
(7) The light source device according to (6), further including
a second prism sheet disposed between the wavelength conversion member and the diffusion member, and having a plurality of second prisms on a surface, each of the plurality of second prisms extending in a second direction orthogonal to the first direction.
(8) The light source device according to any one of (1) to (7), further including:
a reflective member disposed in a region on the substrate, the region being different from a region provided with the plurality of light sources; and
a cut filter disposed to cover the reflective member and having filter characteristics, the filter characteristics allowing a transmittance to light that is wavelength-converted by the wavelength conversion member, to be lower than a transmittance to light emitted from each of the light sources.
(9) The light source device according to any one of (1) to (7), further including
a reflective member disposed in a region on the substrate, the region being different from a region provided with the plurality of light sources, wherein
the reflective member has filter characteristics allowing a reflectance to light that is wavelength-converted by the wavelength conversion member, to be lower than a reflectance to light emitted from each of the light sources.
(10) The light source device according to any one of (1) to (9), wherein the plurality of light sources are two-dimensionally arranged on the substrate.
(11) The light source device according to (10), wherein the plurality of light sources are placed under individual light emission control for every one light source or every two or more light sources.
(12) The light source device according to any one of (1) to (11), wherein each of the plurality of light sources includes a light emitting element configured of an LED.
(13) The light source device according to any one of (1) to (12), wherein
the light sources each configured to emit blue light, and
the wavelength conversion member converts part of blue light emitted from the light sources into red light and green light.
(14) The light source device according to any one of (1) to (12), wherein
the light sources each configured to emit blue light, and
the wavelength conversion member converts part of blue light emitted from the light sources into yellow light.
(15) A display unit provided with a light source device configured to emit illumination light and a display section configured to display an image based on the illumination light from the light source device, the light source device including:
a substrate;
a plurality of light sources disposed on the substrate;
a wavelength conversion member disposed to face the plurality of light sources; and
a diffusion member disposed between the wavelength conversion member and the plurality of light sources, and configured to uniformize distribution of traveling direction angle of incident light.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations, and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
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Parent | 16881498 | May 2020 | US |
Child | 17835002 | US | |
Parent | 16449705 | Jun 2019 | US |
Child | 16881498 | US | |
Parent | 14333007 | Jul 2014 | US |
Child | 16449705 | US |