U.S. patent number RE48,929 [Application Number 15/883,950] was granted by the patent office on 2022-02-15 for display device.
This patent grant is currently assigned to SONY SEMICONDUCTOR SOLUTIONS CORPORATION. The grantee listed for this patent is SONY SEMICONDUCTOR SOLUTIONS CORPORATION. Invention is credited to Masato Doi, Masaru Fujii, Hisashi Kadota, Izushi Kobayashi, Toshiya Takagishi, Hiroshi Terahara, Katsuhiro Tomoda.
United States Patent |
RE48,929 |
Tomoda , et al. |
February 15, 2022 |
Display device
Abstract
A display device includes a first substrate, a second substrate,
and a plurality of light emitting sections. The first substrate
includes a first surface and a second surface which faces the first
surface. The second substrate is arranged to face the first
substrate, and is configured with a first surface which faces the
second surface of the first substrate, and a second surface which
faces the first surface. The plurality of light emitting sections
is provided on the second surface of the first substrate while
being separated from the second substrate. A light transmission
suppression layer on which a light transmission section to transmit
light from light emitting sections is provided is formed on the
second surface of the second substrate in correspondence to each
light emitting section. An anti-reflection layer is formed in the
light transmission section.
Inventors: |
Tomoda; Katsuhiro (Kanagawa,
JP), Takagishi; Toshiya (Kanagawa, JP),
Kobayashi; Izushi (Tokyo, JP), Fujii; Masaru
(Kanagawa, JP), Terahara; Hiroshi (Kagoshima,
JP), Doi; Masato (Kanagawa, JP), Kadota;
Hisashi (Kanagawa, JP) |
Applicant: |
Name |
City |
State |
Country |
Type |
SONY SEMICONDUCTOR SOLUTIONS CORPORATION |
Kanagawa |
N/A |
JP |
|
|
Assignee: |
SONY SEMICONDUCTOR SOLUTIONS
CORPORATION (Kanagawa, JP)
|
Family
ID: |
51599198 |
Appl.
No.: |
15/883,950 |
Filed: |
January 30, 2018 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
Reissue of: |
14226903 |
Mar 27, 2014 |
9250456 |
Feb 2, 2016 |
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Foreign Application Priority Data
|
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Mar 27, 2013 [JP] |
|
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2013-066587 |
|
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G02F
1/133 (20130101); H01L 2924/0002 (20130101); G02F
2201/14 (20130101); H01L 2924/0002 (20130101); H01L
2924/00 (20130101) |
Current International
Class: |
G02F
1/133 (20060101) |
Field of
Search: |
;313/498 ;438/70 ;257/40
;359/280 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
Primary Examiner: Nguyen; Tuan H
Attorney, Agent or Firm: Chip Law Group
Claims
What is claimed is:
1. A display device.Iadd., .Iaddend.comprising: a first substrate
that includes a first surface and a second surface; a second
substrate on the first substrate, the second substrate having
.[.(a).]. a first surface which faces the second surface of the
first substrate.Iadd., .Iaddend.and .[.(b).]. a second surface
which faces away from the first surface of the second substrate;
and a plurality of light emitting sections on the second surface of
the first substrate.[.,.]..Iadd.; .Iaddend. a light transmission
suppression layer on the second surface of the second
substrate.[.,.]..Iadd.; .Iaddend. a light non-transmission section
layer on the first surface of the second substrate.[.,.]..Iadd.;
.Iaddend.and an anti-reflection layer on the second surface of the
second substrate, wherein.[.,.]. the light transmission suppression
layer has a first light transmission section that transmits light
from a corresponding light emitting section of the plurality of
light emitting sections, .Iadd.the light transmission suppression
layer tapers in thickness as the light transmission suppression
layer approaches the first light transmission section, .Iaddend.
the light non-transmission section layer has a second light
transmission section that transmits light from the corresponding
light emitting section, the second light transmission section is
between the first light transmission section and the corresponding
light emitting section, and an area of the second light
transmission section is different in size than an area of the first
light transmission section.
2. The display device according to claim 1, wherein the light
transmission suppression layer includes an anti-reflection
function.
3. The display device according to claim 1, wherein the
anti-reflection layer is between the light transmission suppression
layer and the second substrate.
4. The display device according to claim 1, wherein the
anti-reflection layer covers the light transmission suppression
layer.
5. The display device according to claim 1, wherein the light
transmission suppression layer includes patterns.
6. The display device according to claim 5, wherein a pattern
formation pitch of the patterns is .Iadd.one of .Iaddend.an integer
multiple, an equivalent multiple, or an integer fraction of a light
emitting section arrangement pitch of the plurality of light
emitting sections.
.[.7. The display device according to claim 1, wherein the light
transmission suppression layer tapers in thickness as the light
transmission layer approaches the light transmission
section..].
8. The display device according to clam 1, wherein a relationship
of
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied when (a) a shape of the first light transmission
section in plan view is a circle with a diameter D.sub.1, (b) a
shape of .[.the.]. .Iadd.a .Iaddend.light emitting section .Iadd.of
the plurality of light emitting sections .Iaddend.in plan view is a
circle with a diameter D.sub.0, (c) a distance from a top face of
the light emitting section to the .Iadd.first .Iaddend.light
transmission section is L.sub.1, and (d) an average refractive
index of a light path from the light emitting section to the light
transmission suppression layer provided with the .Iadd.first
.Iaddend.light transmission section is n.sub.1.
9. The display device according to claim 1, wherein the area of the
second light transmission section is smaller than the area of the
first light transmission section.
10. The display device according to claim 9, wherein a relationship
of
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied when (a) a shape of the second light transmission
section in plan view is a circle with a diameter D.sub.2, (b) a
shape of .[.the.]. .Iadd.a .Iaddend.light emitting section .Iadd.of
the plurality of light emitting sections .Iaddend.in plan view is a
circle with a diameter D.sub.0, (c) a distance from a top face of
the light emitting section to the second light transmission section
is L.sub.2, and (d) an average refractive index of a light path
from the light emitting section to the light non-transmission
section layer provided with the second light transmission section
is n.sub.2.
11. A display device.Iadd., .Iaddend.comprising: a first substrate
that includes a first surface and a second surface; a second
substrate having .[.(a).]. a first surface which faces the second
surface of the first substrate.Iadd., .Iaddend.and .[.(b).]. a
second surface which is opposite to the first surface of the second
substrate; and a plurality of light emitting sections on the second
surface of the first substrate, wherein.[.,.]. a light transmission
suppression layer, provided with a first light transmission section
which transmits light from .Iadd.the plurality of .Iaddend.light
emitting sections, is on the second surface of the second substrate
in correspondence to each light emitting section, .[.and.].
.Iadd.the light transmission suppression layer tapers in thickness
as the light transmission suppression layer approaches the first
light transmission section, .Iaddend. a light non-transmission
section layer, provided with a second light transmission section
which transmits light from .[.the.]. .Iadd.a .Iaddend.light
emitting section .Iadd.of the plurality of light emitting
sections.Iaddend., is on the first surface of the second substrate,
and an area of the second light transmission section is smaller
than an area of the first light transmission section.
12. The display device according to claim 11, wherein the light
transmission suppression layer includes an anti-reflection
function.
13. The display device according to claim 11, wherein light
transmission suppression layer includes patterns.
14. The display device according to claim 13, wherein a pattern
formation pitch of the patterns is .Iadd.one of .Iaddend.an integer
multiple, an equivalent multiple, or an integer fraction of a light
emitting section arrangement pitch of the plurality of light
emitting sections.
.[.15. The display device according to claim 11, wherein the light
transmission suppression layer tapers in thickness as the light
transmission layer approaches the first light transmission
section..].
16. The display device according to claim 11, wherein a
relationship of
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied when (a) a shape of the first light transmission
section in plan view is a circle with a diameter D.sub.1, (b) a
shape of the light emitting section .Iadd.of the plurality of light
emitting sections .Iaddend.in plan view is a circle with a diameter
D.sub.0, (c) a distance from a top face of the light emitting
section to the first light transmission section is L.sub.1, and (d)
an average refractive index of a light path from the light emitting
section to the light transmission suppression layer provided with
the .Iadd.first .Iaddend.light transmission section is n.sub.1.
17. The display device according to claim 16, wherein a
relationship of
tan(sin.sup.-1(1/n.sub.2)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied when (a) a shape of the second light transmission
section in plan view is a circle with a diameter D.sub.2, (b)
.[.a.]. .Iadd.the .Iaddend.shape of .[.the-light.]. .Iadd.the light
.Iaddend.emitting section in plan view is .[.a.]. .Iadd.the
.Iaddend.circle with .[.a.]. .Iadd.the .Iaddend.diameter D.sub.0,
(c) a distance from .[.a.]. .Iadd.the .Iaddend.top face of the
light emitting section to the second light transmission section is
L.sub.2, and (d) an average refractive index of a light path from
the light emitting section to the light non-transmission section
layer provided with the second light transmission section is
n.sub.2.
18. The display device according to claim 1, wherein each of the
plurality of light emitting sections comprises a light emitting
diode.
19. The display device according to claim 18, wherein each of the
plurality of light emitting sections comprises a plurality of
.[.the.]. light emitting diodes which are arranged in a straight
line.
20. A tiling-type display device.Iadd., .Iaddend.comprising.Iadd.:
.Iaddend. a plurality of .[.the.]. display devices .Iadd.including
the display device .Iaddend.according to claim 1.
21. The tiling-type display device according to claim 20,
wherein.[.:.]. the plurality of display devices are disposed in a
tile arrangement comprising a matrix in which each display device
.Iadd.of the plurality of display devices .Iaddend.represents a
tile in the tile arrangement, and the plurality of display devices
.[.include.]. .Iadd.includes .Iaddend.a plurality of colors or
patterns.
.Iadd.22. A display device, comprising: a first substrate; a
plurality of light emitting sections on a surface of the first
substrate; a protective layer over the plurality of the light
emitting sections; a light non-transmission section layer on a
first surface of a second substrate of the display device, wherein
the second substrate is on the first substrate, and the light
non-transmission section layer has a first light transmission
section configured to transmit light from a corresponding light
emitting section of the plurality of light emitting sections; a
light transmission suppression layer over a portion of the
protective layer, wherein the light transmission suppression layer
has a second light transmission section configured to transmit the
light from the corresponding light emitting section, and the light
transmission suppression layer tapers in thickness as the light
transmission suppression layer approaches the second light
transmission section; and an anti-reflection layer between the
light transmission suppression layer and the light non-transmission
section layer, wherein the anti-reflection layer is on a second
surface of the second substrate, and the second surface of the
second substrate is opposite to the first surface of the second
substrate. .Iaddend.
.Iadd.23. The display device according to claim 22, wherein an area
of the light transmission suppression layer is different in size
from an area acquired based on projection of the corresponding
light emitting section onto the second surface of the second
substrate. .Iaddend.
.Iadd.24. The display device according to claim 22, wherein the
light transmission suppression layer includes an anti-reflection
function. .Iaddend.
.Iadd.25. The display device according to claim 22, wherein the
light transmission suppression layer includes patterns.
.Iaddend.
.Iadd.26. The display device according to claim 25, wherein a
pattern formation pitch of the patterns is one of an integer
multiple, an equivalent multiple, or an integer fraction of an
arrangement pitch of the corresponding light emitting section.
.Iaddend.
.Iadd.27. The display device according to claim 22, further
comprising an adhesive layer on the protective layer. .Iaddend.
.Iadd.28. The display device according to claim 22, wherein first
light transmission section is on the protective layer.
.Iaddend.
.Iadd.29. The display device according to claim 28, wherein the
second light transmission section is on the first light
transmission section. .Iaddend.
.Iadd.30. The display device according to claim 29, wherein an area
of the first light transmission section is smaller than an area of
the second light transmission section. .Iaddend.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
This application .Iadd.is a reissue application of U.S. patent
application Ser. No. 14/226,903, filed Mar. 27, 2014, which
.Iaddend.claims the benefit of Japanese Priority Patent Application
JP 2013-066587 filed Mar. 27, 2013, the entire contents of which
are incorporated herein by reference.
BACKGROUND
The present disclosure relates to a display device.
In display device, it is extremely important to reduce the specular
reflectance of an image display section from displayed a viewpoint
of improving the contrast and the quality of image. As a technology
for reducing the specular reflectance of an image display section,
a method of forming a dielectric multilayer film on the surface of
the image display section or a method of forming an anti-reflection
film or a low-reflection film thereon has been known. In addition,
a technology for affixing a moth-eye film on the surface of an
image display section is widely known from, for example, Japanese
Unexamined Patent Application Publication No. 2010-092666.
SUMMARY
Meanwhile, in a dielectric multilayer film, an anti-reflection
film, and a low-reflection film according to the related art,
specular reflectance is about 1%, and thus it is difficult to say
that the glare of the image display section is sufficiently
prevented. In addition, in a tiling-type display device in which a
plurality of display devices (for convenience, referred to as
"display device units") is arranged, it is difficult to accomplish
high smoothness of the surfaces of the image display sections of
the entire display device when the display device units are placed.
Further, if some of the display device units are, for example,
tilted, the light reflection states of the display device units
differ from the light reflection state of other display device
units, and thus the tilted display device units are noticeable. It
is possible to accomplish low reflectance using the moth-eye film.
However, if the moth-eye film is polluted, variation in light
reflectance is generated. That is, the moth-eye film is low in
durability.
In addition, although depending on the type of the display device,
if patterns, pictures, or letters are drawn in the image display
section when the display device does not display an image, that is,
when the display device does not operate, it is possible to improve
a kind of visual effect of the entire display device.
Therefore, first, it is desirable to provide a display device that
includes a configuration and a structure which include high
durability and which can accomplish sufficient low reflectance. In
addition, second, it is desirable to provide a display device that
includes a configuration and a structure in which patterns are
visible or the like when the display device does not display an
image.
According to a first embodiment or a second embodiment of the
present disclosure, there is provided a display device including: a
first substrate that includes a first surface and a second surface
which faces the first surface; a second substrate that is arranged
to face the first substrate, and that is configured with a first
surface which faces the second surface of the first substrate, and
a second surface which faces the first surface; and a plurality of
light emitting sections that is provided on the second surface of
the first substrate while being separated from the second
substrate.
Further, in the display device of the first embodiment of the
present disclosure, a light transmission suppression layer on which
a light transmission section to transmit light from light emitting
sections is provided is formed on the second surface of the second
substrate in correspondence to each light emitting section, and an
anti-reflection layer is formed in the light transmission
section.
In addition, in the display device of the second embodiment of the
present disclosure, a light transmission suppression layer,
provided with a first light transmission section which transmits
light from light emitting sections, is formed on the second surface
of the second substrate in correspondence to each light emitting
section, and a light non-transmission section layer, provided with
a second light transmission section which transmits light from the
light emitting section, is formed on the first surface side of the
second substrate, and an area of the second light transmission
section is smaller than an area of the first light transmission
section. Also, the light non-transmission section layer is formed
on the first surface side of the second substrate. However, more
specifically, the light non-transmission section layer may be
formed on the first surface of the second substrate, and may be
formed in an area between the light emitting section and the first
surface of the second substrate. The facts are the same in the
description below.
In the display device according to the first embodiment of the
present disclosure, the light transmission suppression layer,
provided with the light transmission section which transmits light
from the light emitting section, is formed on the second surface of
the second substrate and the anti-reflection layer is formed on the
light transmission section in correspondence to each light emitting
section. In addition, in the display device according to the second
embodiment of the present disclosure, the light transmission
suppression layer, provided with the first light transmission
section which transmits light from the light emitting section, is
formed on the second surface of the second substrate and the light
non-transmission section layer, provided with the second light
transmission section which transmits light from the light emitting
section, is formed on the first surface side of the second
substrate in correspondence to each light emitting section.
Further, the area of the second light transmission section is
smaller than the area of the first light transmission section.
Therefore, it is possible to provide a display device which
includes high durability and which can accomplish sufficient low
reflectance, and a display device which can view patterns or the
like when the display device does not display an image.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1A and 1B are a partial schematic sectional view and a
partial schematic plan view illustrating a display device according
to a first example;
FIG. 2A a partial schematic sectional view illustrating a
modification example of the display device according to the first
example;
FIGS. 2B, 2C, and 2D are partial schematic enlarged sectional views
illustrating the part of a light transmission section of the
display device according to the first example;
FIGS. 3A and 3B are a partial schematic sectional view and a
partial schematic plan view illustrating a display device according
to a second example;
FIGS. 4A and 4B are partial schematic sectional views illustrating
display devices according to a third example and a modification
example;
FIG. 5A is a partial schematic sectional view illustrating a
modification example of the display device according to the second
example;
FIGS. 5B and 5C are partial schematic sectional views illustrating
another modification example of the display device according to the
third example;
FIG. 6 is a partial schematic plan view illustrating a display
device according to a fourth example;
FIG. 7 is a partial schematic plan view illustrating a modification
example of the display device according to the fourth example;
FIG. 8 is a partial schematic plan view illustrating another
modification example of the display device of the fourth
example;
FIG. 9 is a partial schematic plan view illustrating a still
another modification example of the display device according to the
fourth example;
FIG. 10 is a partial schematic plan view illustrating a still
another modification example of a display device according to the
fourth example;
FIG. 11 is a conceptual diagram illustrating a display device
(tiling-type display device) according to a fifth example;
FIGS. 12A and 12B are partial schematic sectional views
illustrating a display device according to a sixth example;
FIG. 13 is a partial schematic sectional view illustrating a
display device according to a seventh example;
FIGS. 14A, 14B, 14C and 14D are partial schematic sectional views
illustrating a light emitting element or the like in order to
describe a method of assembling a display device according to an
eighth example;
FIGS. 15A and 15B are partial schematic sectional views
illustrating the light emitting element or the like in order to
describe the method of assembling the display device according to
the eighth example following FIG. 14D;
FIGS. 16A, 16B, and 16C are partial schematic sectional views
illustrating the light emitting element in order to describe the
method of assembling the display device according to the eighth
example following FIG. 15B;
FIGS. 17A and 17B are a partial schematic sectional view and a
partial schematic plan view illustrating another modification
example of the display device according to the first example;
FIGS. 18A and 18B are a partial schematic sectional view and a
partial schematic plan view illustrating another modification
example of the display device according to the second example;
FIG. 19 is a partial schematic plan view illustrating a
modification example of the display device according to the first
example;
FIG. 20 is a partial schematic plan view illustrating a
modification example of the display device according to the second
example; and
FIG. 21 is a partial schematic plan view illustrating another
modification example of the display device according to the second
example.
DETAILED DESCRIPTION OF EMBODIMENTS
Hereinafter, although the present disclosure will be described
based on examples with reference to the accompanying drawings, the
present disclosure is not limited to the examples and various
numerical values and materials in the examples are examples. Also,
description will be performed in the following order:
1. Description related to entire display device according to first
and second embodiments of the present disclosure
2. First example (Display device according to first embodiment of
the present disclosure)
3. Second example (Display device according to second embodiment of
the present disclosure)
4. Third example (Modification of first example that is combined
with display device according to second example)
5. Fourth example (Modification of first to third examples)
6. Fifth example (Modification of first to fourth examples
7. Sixth example (Display device according to third embodiment)
8. Seventh example (Display device according to fourth embodiment),
and others
Description related to entire display device according to first and
second embodiments of the present disclosure
In a display device according to a first embodiment of the present
disclosure, it is possible for a light transmission suppression
layer to have an anti-reflection function, and thus it is possible
to accomplish a first advantage according to first and second
embodiments of the present disclosure. Further, in this case, it is
preferable that the light transmission suppression layer have
specular reflectance at the same level as the specular reflectance
of an anti-reflection layer. Here, although the "same level" is not
limited, "the same level" means that a condition .ltoreq.(the
specular reflectance of the light transmission suppression
layer/the specular reflectance of the anti-reflection
layer).ltoreq.2 is satisfied. Generally, the magnitude of
scattering reflectance on the surface of the display device
determines the black level depression when an image is displayed.
On the other hand, the magnitude of specular reflectance on the
surface of the display device determines the brightness of an image
which is reflected in the surface of the display device and has a
great influence on the quality of the image which is displayed. In
the display device according to the first embodiment of the present
disclosure, the specular reflectance is defined as described above,
and thus it is possible to accomplish high image display quality.
For example, if frosted printing is performed, the specular
reflectance is reduced. However, a value of the scattering
reflectance increases, and thus it is difficult to take appropriate
balance between the specular reflectance and the scattering
reflectance. In addition, in AG coating in which fine particles are
used, there is a problem in that pseudo deduction of a light
emitting section is generated.
In the display device according to the first embodiment of the
present disclosure which includes the above-described preferable
configuration, a configuration can be made such that the
anti-reflection layer extend between the light transmission
suppression layer and the second surface of a second substrate and
that the anti-reflection layer can cover the light transmission
suppression layer in order to accomplish the first advantage
according to the embodiment of the present disclosure.
Otherwise, in the display device according to the first and second
embodiments of the present disclosure, a configuration can be made
such that a pattern is attached to the light transmission
suppression layer in order to accomplish the second advantage
according to the embodiment of the present disclosure. Further, in
this case, a configuration can be made such that a pattern
formation pitch is set to the integer multiple, the equivalent
multiple, or the integer fraction of a light emitting section
arrangement pitch. Therefore, the boundary region between a pixel
(or a sub-pixel) which is configured with a light emitting section
and a pixel (or a sub-pixel) which is adjacent to the pixel (or a
sub-pixel) is obscure. Further, if a tiling-type display device is
used as the display device as described above, it is possible to
cause the boundary region between a display device (display device
unit), which configures the tiling-type display device, and a
display device unit to be obscure.
In the display device according to the first and second embodiments
of the present disclosure which includes the above-described
preferable configuration, it is preferable that a configuration be
made such that the thickness of the light transmission suppression
layer becomes thin as being close to the light transmission section
(first light transmission section) in order to accomplish further
wider view angle. The change in the thickness of the light
transmission suppression layer may be a linear-shaped change, a
smooth curved change, or a stepped change.
Further, in the display device according to the first and second
embodiments of the present disclosure which includes the
above-described preferable configuration, when it is assumed that
the external shape of the light transmission section (first light
transmission section) is a circle which has a diameter D.sub.1,
that the light emitting section is a circle which has a diameter
D.sub.0, that a distance from the top face of the light emitting
section to the light transmission section (first light transmission
section) is L.sub.1, and that the average refractive index of a
light path from the light emitting section to the light
transmission suppression layer, provided with the light
transmission section, is n.sub.1, it is preferable that
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied. Also, generally, n.sub.1 is a value in the range of
1.4 to 1.6, and tan(sin.sup.-1(1/n.sub.1)) is generally a value
included between 0.8 and 1.02. In this case, it is preferable that
the center of the light emitting section and the center of the
light transmission section (first light transmission section) be on
the same axis line. Here, when the light emitting section is
configured with a single light emitting element and the planar
shape of the section of a single light emitting element which
actually emits light is a circle, "assumption that the light
emitting section is a circle which has a diameter D.sub.0" means
that the diameter of a section which actually emits light is
D.sub.0, and means that, when the section which actually emits
light is not a circle, the diameter of a circle, acquired by
converting the area of the section which actually emits light into
an area of a circular, is D.sub.0. On the other hand, as will be
described later, when a single pixel of the light emitting element
type-display device is configured with, for example, a group (light
emitting unit) including a first light emitting element, a second
light emitting element, and a third light emitting element or a
group (light emitting unit) including four or more light emitting
elements, and these light emitting elements are assumed as a single
light emitting section, it means that when a circle including all
the light emitting elements is assumed, the diameter of the circle
is D.sub.0. Otherwise, when each of the light emitting elements is
not arranged in a straight line, it means that when a circle
connecting the centers of the respective light emitting elements is
assumed, the diameter of the circle is D.sub.0, and when each of
the light emitting elements is arranged in a straight line, it
means that when a line segment connecting the centers of two light
emitting elements positioned on the outermost side is assumed, the
diameter of the circle whose diameter is the line segment is
D.sub.0. The assumption is the same as in the following
description. In addition, the case in which the planar shape of the
light transmission section (first light transmission section) is
not a circle is included, an expression "it is assumed that the
external shape of the light transmission section (first light
transmission section) is a circle which has a diameter D.sub.1" is
used.
Further, in the display device of the first embodiment of the
present disclosure which includes the above-described preferable
configuration, a configuration can be made such that a light
non-transmission section layer, provided with a second light
transmission section that transmits light from the light emitting
section, is formed on the first surface side of the second
substrate in correspondence to each light emitting section, and the
area of the second light transmission section is smaller (narrower)
than the area of the light transmission section. Further, in the
display device according to the first embodiment of the present
disclosure which includes the above-described configuration or in
the display device according to the second embodiment of the
present disclosure which includes the above-described preferable
configuration, when it is assumed that the external shape of the
second light transmission section is a circle which has a diameter
D.sub.2, that the shape of the light emitting section is a circle
which has a diameter D.sub.0, that the distance from the top face
of the light emitting section to the second light transmission
section is L.sub.2, and that the average refractive index of a
light path from the light emitting section to the light
non-transmission section layer provided with the second light
transmission section is n.sub.2, it is preferable that
tan(sin.sup.-1(1/n.sub.2)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied. Further, it is desirable that the center of the light
emitting section, the center of the light transmission section (the
center of the first light transmission section), and the center of
the second light transmission section are on the same axis line,
and that the light transmission section (first light transmission
section) has a figure which is similar to the figure of the second
light transmission section. Also, since the case in which the
planar shape of the second light transmission section is not a
circle is included, an expression "it is assumed that the external
shape of the second light transmission is a circle which has a
diameter D.sub.2" is used.
Further, in the display device according to the first and second
embodiments of the present disclosure which includes the
above-described preferable configuration and structure, a
configuration can be made such that the light emitting section
includes a light emitting diode (LED). However, the present
disclosure is not limited thereto and a configuration can be made
such that the light emitting section includes a semiconductor laser
element and an Electro-Luminescence (EL) element in addition
thereto. Further, each light emitting section can be configured
with a plurality of the light emitting elements (light emitting
diodes) which are arranged in a straight line. Also, an expression
"arranged in a straight line" in the sentence of "the plurality of
the light emitting elements (light emitting diodes) are arranged in
a straight line" means that not only a case where a plurality of
the light emitting elements (light emitting diodes) are arranged
strictly in a straight line but also a case where a plurality of
the light emitting elements (light emitting diodes) are arranged so
as to slightly deviate from a straight line for the design or
manufacturing are included. That is, it means that a plurality of
the light emitting elements (light emitting diodes) are arranged in
an almost straight line. When the light emitting section is
configured with the light emitting element, such as the light
emitting diode or the semiconductor laser element, the size of the
light emitting element (for example, a chip size) is not
particularly restricted. The size of the light emitting element is
typically minute and, more specifically, for example, 1 mm or less,
for example, 0.3 mm or less, or, for example 0.1 mm or less. It is
possible to exemplify light emitting elements which each use, for
example, a nitride-based III-V group compound semiconductor as a
light emitting element which emits red color, a light emitting
element which emits green color and a light emitting element which
emits blue color, and it is possible to exemplify a light emitting
element which uses, for example, an AlGaInP-based compound
semiconductor as the light emitting element which emits red color.
When 1 pixel in the light emitting element type-display device is
configured with a group (light emitting unit) including the first
light emitting element, the second light emitting element and the
third light emitting element, there is a case in which it is
desirable that the group (light emitting unit) including the first
light emitting element, the second light emitting element and the
third light emitting element is assumed as a single light emitting
section depending on the arrangement state of the first light
emitting element, the second light emitting element and the third
light emitting element. That is, in the display device according to
the first embodiment or the second embodiment of the present
disclosure, a configuration can be made such that the light
transmission suppression layer, provided with a single light
transmission section which transmits light from the single light
emitting section including a single light emitting unit, is formed
on the second surface of the second substrate in correspondence to
the single light emitting section which is configured with the
single light emitting unit. In the display device according to the
second embodiment of the present disclosure, a configuration can be
made such that a single second light transmission section, which
transmits light from a single light emitting section configured
with a single light emitting unit, is provided on the light
non-transmission section layer.
In addition, it is possible to use the display device as a
tiling-type display device in which a plurality of the display
devices according to the first and second embodiments of the
present disclosure which includes the above-described preferable
configuration and structure are arranged. Further, in this case, a
configuration can be made such that different colors or patterns
are provided for respective tiles.
In the display device according to the first and second embodiments
of the present disclosure which includes the above-described
preferable configuration and structure (hereinafter, there is a
case in which the display device is collectively simply referred to
as "display device according to the embodiments of the present
disclosure"), the light transmission suppression layer and the
light non-transmission section layer are formed in such a way as to
straddle adjacent pixels (or sub-pixels), and gaps are not present
therebetween.
In the display device according to the embodiments of the present
disclosure, it is possible to exemplify a polyether sulfone (PES)
film, a polyethylene naphthalate (PEN) film, a polyimide (PI) film,
a polyethylene terephthalate (PET) film, or a polyolefin film as
the first substrate or the second substrate. Further, it is
possible to exemplify a glass substrate, a substrate acquired by
bonding the various films to the glass substrate, a substrate
acquired by forming a polyimide resin layer, an acrylic resin
layer, a polystyrene resin layer, or a silicone gum layer on the
glass substrate. In addition, in the first substrate, it is
possible to replace the glass substrate with a metallic substrate
or a metallic sheet, an alloy substrate, an alloy sheet, a ceramic
substrate, a ceramic sheet, a semiconductor substrate, a plastic
substrate, or a plastic sheet. Further, it is possible to exemplify
a printed-wiring board (which includes a rigid printed-wiring board
and a flexible printed-wiring board) on which wiring is formed as
the first substrate, and it is possible to exemplify a substrate,
the surface of which is formed with an insulating film.
As a material which configures the light transmission suppression
layer having an anti-reflection function or a light
non-transmission section layer, it is possible to exemplify a
material, such as glass paste or black pigment which includes
conductive particles, such as carbon, a metallic thin film (for
example, chrome, nickel, aluminum, molybdenum, or an alloy
thereof), metallic oxide (for example, chrome oxide), metallic
nitride (for example, chrome nitride), heat resistant organic
resin, glass paste, black pigment, or silver. Further, it is
possible to form such a layer using a method, which is
appropriately selected depending on a material to be used, such as,
for example, a combination of a vacuum deposition method or a
sputtering method and an etching method, a combination of a vacuum
deposition method and a sputtering method, a combination of a spin
coating method and a liftoff method, various print methods
including an ink-jet print method, and a lithography
technology.
It is possible to configure the anti-reflection layer using, for
example, various fluorine resin layers which each have a low
refractive index (for example, 1.35 or less), a dielectric
multilayer film, a mesoporous silica film, and the composite
membrane thereof.
It is possible to exemplify ink or paint which is appropriate to
form a pattern as a material which configures the light
transmission suppression layer to which pattern is attached. A
protective layer may be formed on the surface of the light
transmission suppression layer to which the pattern is attached in
order to improve durability or weatherability. The pattern includes
a picture, a letter, a logo, a symbol, a code, a mark, a seal, and
a design.
Otherwise, in order to accomplish the second advantage, a display
device according to a third embodiment of the present disclosure
includes: a first substrate which includes a first surface and a
second surface which faces the first surface; a second substrate
which is arranged to face the first substrate, and is configured to
include a first surface which faces the second surface of the first
substrate and a second surface which faces the first surface; and a
plurality of light emitting sections which are provided on the
second surface of the first substrate while being separated from
the second substrate. A pattern display device, which includes a
micro capsule type, an electron powder fluid type, a liquid crystal
type, an electrowetting type, an electrophoresis type, a chemical
change type or an electrophoresis type electronic paper or a
transparent liquid crystal display device, is arranged on the
second surface side or the first surface side of the second
substrate, and displays a pattern on the pattern display device.
When the pattern is displayed on the pattern display device, an
image is not displayed on the light emitting section. On the other
hand, when an image is displayed on the light emitting section, the
pattern is not displayed on the pattern display device.
Otherwise, in order to accomplish the second advantage, a display
device according to a fourth embodiment of the present disclosure
includes: a first substrate that includes a first surface and a
second surface which faces the first surface; a second substrate
that is arranged to face the first substrate, and that includes a
first surface which faces the second surface of the first substrate
and a second surface which faces the first surface; and a plurality
of light emitting sections that are provided on the second surface
of the first substrate while being separated from the second
substrate. A pattern is formed on the first surface side of the
second substrate. A configuration can be made such that the pattern
is expressed by irregularities on a layer which is positioned at
the bottom of the first surface of the second substrate.
The number, the kind, the implementation (arrangement), and the
intervals of light emitting sections (for example, light emitting
elements) which configure the display device are determined
depending on the purpose or the function of the display device and
the specification which is necessary for the display device. If the
display device is configured with a light emitting element which
emits red color, a light emitting element which emits green color
and a light emitting element which emits blue color, it is possible
to acquire a light emitting element type-display device which
displays color. If the display device is configured with the light
emitting element type-display device which displays colors, 1 pixel
in the light emitting element type-display device is configured
with a group (light emitting unit) including the first light
emitting element, the second light emitting element and the third
light emitting element. In addition, a sub-pixel is configured with
each light emitting element. Further, a plurality of light emitting
units is arranged in a 2-dimensional matrix shape in the first
direction and in the second direction which is perpendicular to the
first direction. When it is assumed that the number of first light
emitting elements which configure the light emitting unit is
N.sub.1, the number of second light emitting elements which
configure the light emitting unit is N.sub.2 and the number of
third light emitting elements which configure the light emitting
unit is N.sub.3, it is possible to exemplify an integer which is 1
or 2 or greater as N.sub.1, it is possible to exemplify an integer
which is 1 or 2 or greater as N.sub.2, and it is possible to
exemplify an integer which is 1 or 2 or greater as N.sub.3. The
values of N.sub.1, N.sub.2, and N.sub.3 may be equal or different.
When the values of N.sub.1, N.sub.2, and N.sub.3 are integers which
each are 2 or greater, the light emitting elements may be connected
in series or may be connected in parallel in a single light
emitting unit. Although the combination of the values of (N.sub.1,
N.sub.2, N.sub.3) is not limited, it is possible to exemplify (1,
1, 1), (1, 2, 1), (2, 2, 2), and (2, 4, 2). Also, as described
above, it is possible to assume that a single light emitting unit
is a single light emitting section. In this case, as described
above, in the display device according to the first embodiment or
the second embodiment of the present disclosure, a configuration
can be made such that a light transmission suppression layer,
provided with a single light transmission section which transmits
light from a single light emitting section configured with a single
light emitting unit, is formed on the second surface of the second
substrate in correspondence to the single light emitting section
configured with a single light emitting unit. In the display device
according to the second embodiment of the present disclosure, a
configuration can be made such that a single second light
transmission section which transmits light from the single light
emitting section configured with the single light emitting unit is
provided on the light non-transmission section layer.
First Example
A first example relates to the display device according to the
first embodiment of the present disclosure. FIG. 1A is a schematic
partial sectional view of the display device according to the first
example, and FIG. 1B is a schematic partial sectional view thereof.
Also, FIG. 1A is a schematic partial sectional view taken along the
line IA-IA in FIG. 1B. Each of the display device 10A according to
the first example and display devices 10B, 10C, and 10D according
to second to fourth examples which will be described later
includes: a first substrate 11 which includes a first surface 11A
and a second surface 11B which faces the first surface 11A; a
second substrate 12 which is arranged to face the first substrate
11, and which is configured to include a first surface 12A that
faces the second surface 11B of the first substrate 11 and a second
surface 12B that faces the first surface 12A; and a plurality of
light emitting sections 20 (20R, 20G, and 20B) which are provided
on the second surface 11B of the first substrate 11 while being
separated from the second substrate 12.
Further, in the display device 10A according to the first example,
a light transmission suppression layer 31, provided with light
transmission sections 32 that transmit light from the light
emitting sections 20, is formed on the second surface 12B of the
second substrate 12 in correspondence to the respective light
emitting sections 20. An anti-reflection layer 33 is formed in the
light transmission sections 32. Light from the light emitting
sections 20 passes through the light transmission sections 32 and
then is emitted to the outside.
Here, in the display device 10A according to the first example, the
light transmission suppression layer 31 includes an anti-reflection
function. Further, accordingly, it is possible to provide a display
device which includes high durability and includes a configuration
and a structure in which sufficient low reflectance can be
accomplished. The light transmission suppression layer 31 includes
a specular reflectance at the same level as that of the specular
reflectance of the anti-reflection layer 33. More specifically,
although the specular reflectance is not limited, the specular
reflectance satisfies 0.ltoreq.(the specular reflectance of the
light transmission suppression layer/the specular reflectance of
the anti-reflection layer).ltoreq.2.
Further, in the display device 10A according to the first example,
as shown in FIG. 1A, the anti-reflection layer 33 extends between
the light transmission suppression layer 31 and the second surface
12B of the second substrate 12. Otherwise, as shown in FIG. 2A, the
anti-reflection layer 33 covers the light transmission suppression
layer 31.
In addition, a protective film 13 which is formed of silicone resin
and an adhesive layer 14 which is formed of acrylic resin or
silicone resin are provided between the first substrate 11 and the
second substrate 12.
In the first example, each of the light emitting sections 20 is
configured with a light emitting element which is formed of a light
emitting diode. More specifically, the display device 10A is
configured with a light emitting element type-display device, and a
single pixel in the light emitting element type-display device is
configured with a group (light emitting unit) including a first
light emitting element 20R which emits red color, a second light
emitting element 20G which emits green color, and a third light
emitting element 20B which emits blue color. A sub-pixel is
configured with each of the light emitting elements 20R, 20G, and
20B. Further, a plurality of light emitting units is arranged in a
2-dimensional matrix shape in the first direction and in the second
direction which is perpendicular to the first direction. When it is
assumed that the number of first light emitting elements which
configure the light emitting unit is N.sub.1, that the number of
second light emitting elements which configure the light emitting
unit is N.sub.2 and that the number of third light emitting
elements which configure the light emitting unit is N.sub.3,
setting is made such that (N.sub.1, N.sub.2, N.sub.3)=(1, 1, 1).
However, the present disclosure is not limited thereto. Here, in
each example, it is assumed that a group (light emitting unit)
which includes the first light emitting element 20R, the second
light emitting element 20G and the third light emitting element 20B
is a single light emitting section 20. Further, the light
transmission suppression layer 31, provided with a single light
transmission section 32 that transmits light from the single light
emitting section 20 configured with a single light emitting unit,
is formed on the second surface 12B of the second substrate 12 in
correspondence to the single light emitting section 20 which is
configured with a single light emitting unit. Also, an external
shape of the light transmission section 32 is a circle which has a
diameter D.sub.1. The centers of the respective light emitting
elements 20R, 20G, and 20B are disposed at the apexes of a regular
triangle, and the respective light emitting elements 20R, 20G, and
20B are arranged on the circumference of a circle. Here, when a
circle including the respective light emitting elements 20R, 20G,
and 20B is assumed, the diameter of the circle is set to D.sub.0.
In addition, in FIGS. 1A, 2A, 3A, 4A, 4B, 5A, 5B, 5C, 12A, 12B, and
13, the light emitting units are indicated using dots as the light
emitting sections 20. In addition, in FIGS. 1B, 3B, 6, 7, 8, 9, and
10, the first light emitting element 20R is expressed by allocating
"R" at the center of a circular mark, the second light emitting
element 20G is expressed by allocating "G" at the center of a
circular mark, the third light emitting element 20B is expressed by
allocating "B" at the center of a circular mark, and the circle
connecting the centers of the respective light emitting elements
20R, 20G, and 20B is expressed by dotted lines.
In the first example, the first substrate 11 is configured with a
glass epoxy printed-wiring board on which wiring (not shown in the
drawing) is formed, and the second substrate 12 is configured with
a polyolefin film. In addition, the light transmission suppression
layer 31 is configured with solidified paint (ink) in which carbon
is dispersed and formed based on an ink-jet print method. The
anti-reflection layer 33 is configured with a fluorine resin layer
and formed based on a print method.
FIGS. 2B, 2C, and 2D are partial schematic sectional views
illustrating a part of the light transmission section which is
enlarged. The thickness of the light transmission suppression layer
31 may be the same (refer to FIGS. 1A and 2A) and may be thin as
being close to the light transmission section 32 in order to
accomplish a wider view angle. More specifically, the change in the
thickness of the light transmission suppression layer 31 may be
linear change (refer to FIG. 2B), smooth curved change (refer to
FIG. 2C), and step change (refer to FIG. 2D). It is possible to
control the thickness of light transmission suppression layer 31 by
controlling ink discharge amount when the light transmission
suppression layer 31 is formed based on, for example, the ink-jet
print method.
In addition, when it is assumed that the external shape of the
light transmission section 32 is a circle which has a diameter
D.sub.1, that the light emitting section 20 is a circle which has a
diameter D.sub.0, that the distance from the top face of the light
emitting section 20 to the light transmission section 32 is
L.sub.1, and that the average refractive index of a light path
(more specifically, a light path which passes through the
protective film 13, the adhesive layer 14, the second substrate 12
and the anti-reflection layer 33) from the light emitting section
20 to the light transmission suppression layer 31 provided with the
light transmission section 32 is set to n.sub.1,
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied. The center of the light emitting section 20 and the
center of the light transmission section 32 are on the same axis
line AX.sub.1.
As described above, in the display device according to the first
example, the light transmission suppression layer, provided with
the light transmission section which transmits light from the light
emitting section and configured to include an anti-reflection
function, is formed on the second surface of the second substrate
in correspondence to each light emitting section. Further, the
anti-reflection layer is formed on the light transmission section.
Therefore, it is possible to provide a display device which
includes high durability and which can accomplish sufficient low
reflectance.
Second Example
The second example relates to a display device according to the
second embodiment of the present disclosure. FIG. 3A is a partial
schematic sectional view illustrating the display device according
to the second example, and FIG. 3B is a partial schematic plan
view. Also, FIG. 3A is a partial schematic sectional view taken
along the line IIIA-IIIA in FIG. 3B. In a display device 10B
according to the second example, the light transmission suppression
layer 31, provided with a first light transmission section 32 which
transmits light from the light emitting section 20, is formed on
the second surface 12B of the second substrate 12 and a light
non-transmission section layer 34, provided with a second light
transmission section 35 which transmits light from the light
emitting section 20, is formed on the first surface side of a
second substrate 12 in correspondence to each light emitting
section 20. The area of the second light transmission section 35 is
smaller (narrower) than the area of the first light transmission
section 32. Here, although the light non-transmission section layer
34 is formed on the first surface side of the second substrate 12,
more specifically, the light non-transmission section layer 34 may
be formed on the first surface of the second substrate 12 and the
area between the light emitting section 20 and the first surface of
the second substrate 12. That is, as shown in the drawings, the
light non-transmission section layer 34 may be formed on the first
surface 12A of the second substrate 12 and, alternatively, may be
formed on the protective film 13 (refer to FIG. 5A). The light
non-transmission section layer 34 is formed in the same manner in
the description below. In addition, the single second light
transmission section 35, which transmits light from the single
light emitting section 20 configured with a group (a single light
emitting unit) including a first light emitting element 20R which
emits red color, a second light emitting element 20G which emits
green color, and a third light emitting element 20B which emits
blue color, is provided on the light non-transmission section layer
34. An external shape of the second light transmission section 35
is a circle which has a diameter D.sub.2.
In the second example, the light non-transmission section layer 34
is configured with a black matrix material for a liquid crystal
display device, and is formed based on a photolithography
technology. Like the first example, the light transmission
suppression layer 31 includes an anti-reflection function in the
second example. In addition, like the first example, the thickness
of the light transmission suppression layer 31 may be the same
thickness (refer to FIG. 3A), and may be thin as being close to the
first light transmission section 32 in order to accomplish a wider
view angle (refer to FIGS. 2B, 2C, and 2D). Light from the light
emitting section 20 passes through the second light transmission
section 35 and the first light transmission section 32, and is
emitted to the outside. The thickness of the light non-transmission
section layer 34 may be the same thickness and may be thin as being
close to second light transmission section 35 in order to
accomplish a wider view angle. More specifically, the change in the
thickness of the light non-transmission section layer 34 may be a
linear-shaped change, a smooth curved change, or a stepped change.
It is possible to control the thickness of the light
non-transmission section layer 34 by controlling ink discharge
amount when the light non-transmission section layer 34 is formed
based on, for example, the ink-jet print method.
Also, like the first example, when it is assumed that the external
shape of the first light transmission section 32 is a circle which
has a diameter D.sub.1, that the light emitting section 20 is a
circle which has a diameter D.sub.0, that the distance from the top
face of the light emitting section 20 to the first light
transmission section 32 is L.sub.1, and that the average refractive
index of a light path (more specifically, a light path which passes
through the protective film 13, the adhesive layer 14, and the
second substrate 12 in examples shown in FIGS. 3A and 5A, and a
light path which passes through the protective film 13, the
adhesive layer 14, the second substrate 12, and the anti-reflection
layer 33 in examples shown in FIGS. 4A, 4B, 5B, and 5C) from the
light emitting section 20 to the light transmission suppression
layer 31 provided with the light transmission section 32 is
n.sub.1,
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied. Further, when it is assumed that the external shape
of the second light transmission section 35 is a circle which has a
diameter D.sub.2, that the light emitting section 20 is a circle
which has a diameter D.sub.0, that the distance from the top face
of the light emitting section 20 to the second light transmission
section 35 is L.sub.2, and that the average refractive index of a
light path (more specifically, a light path which passes through
the protective film 13 and the adhesive layer 14 in examples shown
in FIGS. 3A and 4A, and 4B, a light path which passes through the
protective film 13 in the examples shown in FIGS. 5A, 5B, and 5C)
from the light emitting section 20 to the light non-transmission
section layer 34 provided with the second light transmission
section 35 is n.sub.2,
tan(sin.sup.-1(1/n.sub.2)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied. The center of the light emitting section 20, the
center of the first light transmission section 32, and the center
of the second light transmission section 35 are on the same axis
line AX.sub.2, and the first light transmission section 32 has a
figure which is similar to the figure of the second light
transmission section 35.
As describe above, in the display device of the second example, the
light transmission suppression layer, provided with the first light
transmission section which transmits light from the light emitting
section and configured to include the anti-reflection function, is
formed on the second surface of the second substrate in
correspondence to each light emitting section. Since the light
non-transmission section layer provided with the second light
transmission section which transmits light from the light emitting
section is formed on the first surface side of the second substrate
and the area of the second light transmission section is smaller
(narrower) than the area of the first light transmission section,
it is possible to provide a display device which includes high
durability and which can accomplish sufficient low specular
reflectance.
Third Example
A third example is a modification of the first example, and relates
to the combination of the display device 10A according to the first
example and the display device 10B according to the second example.
That is, as shown in partial schematic sectional views in FIGS. 4A,
5B, and 5C, in a display device 10C according to the third example,
in addition to the configuration of the display device 10A
according to the first example, the light non-transmission section
layer 34, provided with the second light transmission section 35
which transmits light from the light emitting section 20, is formed
on the first surface side of the second substrate 12 in
correspondence to each light emitting section 20, and the area of
the second light transmission section 35 is smaller (narrower) than
the area of the light transmission section 32. Also, in FIG. 4A,
the light non-transmission section layer 34 is formed on the first
surface 12A of the second substrate 12. On the other hand, in FIGS.
5B and 5C, the light non-transmission section layer 34 is formed on
the protective film 13.
The configurations and structures of the light non-transmission
section layer 34 and the second light transmission section 35 are
the same as in the description of the second example, the detailed
description thereof will not be repeated.
Fourth Example
A fourth example is a modification of the first example. In a
display device 10D according to the fourth example shown in partial
schematic plan views in FIGS. 6, 7, 8, 9 and 10, patterns (for
example, a "pattern A" and a "pattern B") are attached to the light
transmission suppression layer 41. Here, in FIGS. 6, 7, 8, 9 and
10, for the purpose of simplification of drawings, the pattern A is
expressed through hatching from the upper right side to the lower
left side, and the pattern B is expressed using hatching from the
upper right side to the lower left side. The light transmission
suppression layer 41 is formed based on the print method, more
specifically, for example, the ink-jet print method. More
specifically, it is possible to use, for example, a pattern which
has a short cycle like the wallpaper of a building material, a
favorite color (wine red, deep blue, or tender green), and two or
more colors which are slightly different from each other in units
of pixels, or a drawing which includes a pattern in units of pixels
(a geometrical pattern of a checker board design or a company name
logo) as a pattern which includes a picture, a letter, a logo, a
symbol, a code, a mark, a seal, and a design. Here, the pattern
formation pitch is the integer multiple (refer to FIGS. 6 and 7),
the equivalent multiple (refer to FIGS. 8 and 9), or the integer
fraction (refer to FIG. 10) of the arrangement pitch of the light
emitting section 20. In FIGS. 6, 7, 8 and 9, the pattern is
deviated by half of the arrangement pitch of light emitting
section. In addition, in FIGS. 6, 7, 8, 9, and 10, the boundary
between sub-pixels is expressed by dotted lines, and the boundary
between the patterns is expressed by dotted lines or dashed
lines.
It is possible to apply such a configuration in which patterns are
attached to the light transmission suppression layer 41 to the
display device 10B according to the second example and the display
device 10C according to the third example. That is, the light
transmission suppression layer 41 may replace the light
transmission suppression layer 31 according to the second example
and the third example.
When the display device does not display an image because of
attaching a pattern to the light transmission suppression layer,
that is, when the display device does not operate, it is possible
to apply preferable impression in an environment (for example, a
living room at home) in which the display device is arranged. In a
display device according to the related art in which the outermost
surface of the display device is black, it is difficult to respond
to such a demand of a customer. In addition, in a liquid crystal
display device or an organic electroluminunance display device
according to the related art, the light emitting sections occupy
almost all the pixel areas, and thus it is extremely difficult to
make patterns. In addition, in order to perform printing with a
higher freedom degree, it is desirable to perform printing on the
outermost surface of the display device. However, there are few
areas in the outermost surface of the display device on which
printing can be performed. On the other hand, in the light emitting
element type-display device according to the fourth example, an
area acquired when the light emitting section is projected onto the
second surface of the second substrate is small (narrow) and the
area of the light transmission suppression layer 41 which occupies
the second surface of the second substrate is large (wide), and
thus there is enough room for expression of patterns.
Fifth Example
A fifth example is a modification of the first example to the
fourth example. As shown in a conceptual diagram in FIG. 11, a
display device 10E according to the fifth example is a tiling-type
display device which is configured in such a way that a plurality
of display devices 10A, 10B, 10C, and 10D described in the first to
fourth examples are arranged as the display device units (more
specifically, configured in such a way as to be arranged in a tile
shape in a 2-dimensional matrix). Also, although FIG. 11
illustrates that the display devices 10A which configure the
display device units are arranged with gaps therebetween, actually,
the display devices 10A are arranged without gaps. Excepting for
this point, the display device units which configure the display
device 10E according to the fifth example each have the same
configuration and structure as those of the display devices 10A,
10B, 10C, and 10D according to the first to fourth examples, and
thus the detailed description thereof will not be repeated. As
described above, if the display devices according to the first to
fourth examples are applied, it is possible to efface tile-shaped
unevenness, the joint of display device units, gaps between the
display device units, light reflection, and the waviness of the
display device unit. Also, different colors or patterns may be
provided for the respective tiles (that is, for the respective
display device units or for the respective assemblies of the
display device units).
Sixth Example
A sixth example relates to the display device according to the
third embodiment of the present disclosure. As shown in a
conceptual diagram in FIG. 12A or 12B, a display device 10F
according to the sixth example includes: a first substrate 11 that
includes a first surface 11A and a second surface 11B which faces
the first surface 11A; a second substrate 12 that is arranged to
face the first substrate 11, and that includes a first surface 12A
which faces the second surface 11B of the first substrate 11 and a
second surface 12B which faces the first surface 12A; and a
plurality of light emitting sections 20 that is provided on the
second surface 11B of the first substrate 11 while being separated
from the second substrate 12. A pattern display device 51, which is
configured with a micro capsule type, an electron powder fluid
type, a liquid crystal type, an electrowetting type, an
electrophoresis type, a chemical change type or an electrophoresis
type electronic paper or a transparent liquid crystal display
device, is arranged on the second surface side (refer to FIG. 12A)
or the first surface side (refer to FIG. 12B) of the second
substrate 12, and displays patterns on the pattern display device
51. When the patterns are displayed on the pattern display device
51, an image is not displayed on the light emitting sections 20. On
the other hand, when an image is displayed on the light emitting
sections 20, the patterns are not displayed on the pattern display
device 51. Since the electronic paper or the liquid crystal display
device which configure the pattern display device 51 may be
configured with an electronic paper or a liquid crystal display
device which has existing configuration and structure, the detailed
description thereof will not be repeated. A pixel formation pitch
in the pattern display device 51 may be the integer multiple, the
equivalent multiple, or the integer fraction of a light emitting
section arrangement pitch. Also, the pattern display device 51 is
conceptually illustrated.
Since it is possible to make the configurations and structures of
the first substrate 11, the second substrate 12, and the light
emitting sections 20 be the same as the configurations and
structures of the first substrate 11, the second substrate 12, and
the light emitting sections 20 of the display device described in
the first example, the detailed description thereof will not be
repeated.
Seventh Example
A seventh example relates to a display device according to a fourth
embodiment of the present disclosure. As shown in a conceptual
diagram in FIG. 13, a display device 10G according to the seventh
example includes: a first substrate 11 that includes a first
surface 11A and a second surface 11B which faces the first surface
11A; a second substrate 12 that is arranged to face the first
substrate 11, and that includes a first surface 12A which faces the
second surface 11B of the first substrate 11 and a second surface
12B which faces the first surface 12A; and a plurality of light
emitting sections 20 that is provided on the second surface of the
first substrate 11 while being separated from the second substrate
12. Patterns are formed on the first surface side of the second
substrate 12. More specifically, the patterns are expressed by the
irregularities 52 of a layer (more specifically, the protective
film 13) which is positioned at the bottom of the first surface 12A
of the second substrate 12. Light from the light emitting section
20 passes through the light transmission section 53, and is emitted
to the outside.
Eighth Example
In an eighth example, a concept of a method of assembling a display
device which is configured with a group (light emitting unit)
including a first light emitting element 20R which emits red color,
a second light emitting element 20G which emits green color and a
third light emitting element 20B which emits blue color will be
described with reference to FIGS. 14A, 14B, 14C, 14D, 15A, 15B,
16A, 16B, and 16C. However, the method of assembling the display
device is not limited to a method which will be described
below.
Process-800
First, based on an existing method, a laminated structure 60 which
includes a first compound semiconductor layer 61, an active layer
63 which is formed of a compound semiconductor and a second
compound semiconductor layer 62 is formed on the first surface 70A
of a substrate 70 for light emitting element manufacture based on,
for example, a MOCVD method. Further, a second electrode 65 is
formed on the laminated structure 60. Also, the composition, the
configuration and the structure of the first compound semiconductor
layer 61, the active layer 63, and the second compound
semiconductor layer 62, which configure the laminated structure 60,
and the second electrode 65 may be determined based on the
specification which is necessary for the light emitting element.
Subsequently, the second electrode 65 and the laminated structure
60 are, for example, etched or milled for element isolation. In
this manner, as shown in FIG. 14A, the second electrode is formed,
and thus it is possible to acquire a laminated structure 60 on
which element isolation is performed. Also, in the drawings below,
there is a case in which then second electrode 65 is not
illustrated.
Process-810
A support substrate 71, over which an uncured adhesive layer 72 is
formed, is prepared. Further, the adhesive layer 72 is hardened in
such a way that the uncured adhesive layer 72 comes into contact
with the second compound semiconductor layer 62 of the laminated
structure 60, and thus the laminated structure 60 is bonded to the
support substrate 71 (refer to FIG. 14B). Thereafter, the substrate
70 for the light emitting element manufacture is caused to be thin
from a back surface 70B using a lapping method or a CMP method.
When lapping is performed, the substrate 70 for the light emitting
element manufacture is removed by performing etching using solution
in which ammonia water is mixed with hydrogen peroxide water.
Subsequently, the first electrode 64 is formed on the first
compound semiconductor layer 61 using a liftoff method and a vacuum
deposition method. In this way, it is possible to acquire a
structure shown in FIG. 14C. Also, the element isolation may not be
performed in Process-800 and the element isolation may be performed
in Process-810.
Process-820
A pad section formation substrate 73, in which an uncured adhesive
67 is formed in a portion to fix the laminated structure 60 and a
pad section 66 is formed, is prepared (refer to FIG. 14D). The pad
section 66 is formed on a release layer 74 which is formed on the
front surface of the pad section formation substrate 73. Further,
the uncured adhesive 67 comes into contact with the laminated
structure 60 (more specifically, the first compound semiconductor
layer 61) and laser abrasion is generated in such a way that, for
example, eximer laser radiates in the adhesive layer 72, the
laminated structure 60 is removed from the support substrate 71,
and thus the adhesive 67 is hardened. In this way, as shown in FIG.
15A, it is possible to acquire a structure (light emitting element
chip 21) in which the laminated structure 60 is fixed on the pad
section formation substrate 73 by the adhesive 67. Thereafter, the
first electrode 64 is electrically connected to the first pad
section 40A using a plating method.
Process-830
Subsequently, a sacrifice layer 75 is formed so as to extend from
the laminated structure 60 to a part of the second pad section 66B
(refer to FIG. 15B). The sacrifice layer 75 is not formed on a part
of the second compound semiconductor layer 62 of the laminated
structure 60.
Process-840
Subsequently, a wire layer 68 is formed so as to extend over the
second electrode 65, the sacrifice layer 75 and the second pad
section 66B (refer to FIG. 16A). The wire layer 68 is acquired by
forming a ground layer and forming the wire layer 68 on the ground
layer based on a plating method (more specifically, electrolysis
plating method). Also, it is possible to form the wire layer 68
based on a semi-additive process. More specifically, it is possible
to acquire the ground layer by sequentially forming a Titan (Ti)
layer which includes a thickness of 50 nm and a copper (Cu) layer
which includes a thickness of 200 nm on the entire surface thereof
based on a sputtering method. Subsequently, a resist mask, which
covers a region in which the wire layer 68 is not formed, is
formed, and the wire layer 68, which includes a copper layer having
a thickness of 2 .mu.m, is formed on a part of the ground layer
which is not covered by the resist mask based on an electrolysis
plating method. Thereafter, the resist mask is removed, the ground
layer is removed by performing soft etching, and the sacrifice
layer 75 is removed, and thus it is possible to acquire a light
emitting element 20' which includes a structure in which the second
electrode 65 is connected to the second pad section 66B through the
wire layer 68 (refer to FIG. 16B).
Process-850
Thereafter, it is possible to acquire a molding section 22 in which
the light emitting element 20' is molded by molding the light
emitting element 20' using a molding material (refer to FIG.
16C).
Process-860
A relay substrate, the entire surface of which is formed with an
adhesion layer, is prepared. Further, the adhesion layer comes into
contact with the molding section 22, and thus the molding section
22 is adhered to the adhesion layer. Thereafter, laser abrasion is
generated in such a way that eximer laser radiates in release layer
74, and the pad section formation substrate 73 is removed from the
light emitting element 20'. Thereafter, the pad section 66 of the
light emitting element 20' on the relay substrate is electrically
connected to wiring which is provided in the first substrate 11,
and the relay substrate is removed using an existing method. In
this way, it is possible to acquire a structure in which the light
emitting section 20 (light emitting element 20') is attached to the
first substrate 11.
More specifically, the first light emitting section is transcribed
from the pad section formation substrate, on which a plurality of
first light emitting sections that emits red color is arranged, to
a predetermined position of the relay substrate. In addition, the
second light emitting section is transcribed from the pad section
formation substrate, on which a plurality of second light emitting
sections that emits green color is arranged, to a predetermined
position of the relay substrate. Further, the third light emitting
section is transcribed from the pad section formation substrate, on
which a plurality of third light emitting sections that emits blue
color is arranged, to a predetermined position of the relay
substrate. In this way, it is possible to allocate a group (light
emitting unit) including the first light emitting section, the
second light emitting section and the third light emitting section
in the predetermined position of the relay substrate. Further, the
pad section 66 of each light emitting element 20', which configures
the light emitting unit on the relay substrate, is electrically
connected to the wiring which is provided on the first substrate
11, and then the relay substrate is removed using an existing
method. In this way, it is possible to acquire a structure in which
the light emitting sections 20 (light emitting elements 20') are
attached to the first substrate 11. Also, 1 pixel is configured
with a group (light emitting unit) including the first light
emitting section, the second light emitting section and the third
light emitting section. In addition, a sub-pixel is configured with
each light emitting section. Further, a plurality of light emitting
units is arranged in a 2-dimensional matrix in the first direction
and the second direction which is perpendicular to the first
direction.
Process-870
Thereafter, the protective film 13 is formed on the second surface
side of the first substrate 11 using an existing method.
Process-880
For example, when the display device according to the first example
is manufactured, the second substrate 12 on which the light
transmission suppression layer 31 and the anti-reflection layer 33
are formed is prepared, and the first substrate 11 is bonded to the
first surface 12A of the second substrate 12 while the adhesive
layer 14 is interposed therebetween. In addition, when the display
device according to the second example or the third example is
manufactured, the light non-transmission section layer 34 is formed
on the protective film 13, and the first surface 12A of the second
substrate 12 on which the light transmission suppression layer 31
is formed is bonded to the first substrate 11 while the adhesive
layer 14 is interposed therebetween. Otherwise, when the display
device according to the second example or the third example is
manufactured, the first surface 12A of the second substrate 12, in
which the light transmission suppression layer 31 is formed on the
second surface 12B and the light non-transmission section layer 34
is formed on the first surface 12A, is bonded to the first
substrate 11 while the adhesive layer 14 is interposed
therebetween.
Hereinbefore, although the present disclosure has been described
based on the preferred examples, the present disclosure is not
limited to the examples. The configurations and structures of the
display device, the light emitting section, and the light emitting
element type-display device built with the light emitting section,
which are described in the examples, are examples. The members and
the materials thereof are examples, and can be appropriately
changed.
A fourth light emitting section and a fifth light emitting section
may be added to the first light emitting section, the second light
emitting section, and the third light emitting section as the light
emitting sections which configure the light emitting unit.
Sub-pixels are configured with the light emitting sections, and 1
pixel is configured with the light emitting unit. As such an
example, it is possible to exemplify, for example, a light emitting
unit to which a sub-pixel that emits white light is added in order
to improve brightness, a light emitting unit to which a sub-pixel
that emits a complementary color is added in order to extend a
color range, a light emitting unit to which a sub-pixel that emits
a yellow color is added in order to extend a color range, and a
light emitting unit to which sub-pixels that emit a yellow color
and a cyan color are added in order to extend a color range. When
the light emitting section is configured with four or more light
emitting elements, a circle, which includes all the light emitting
elements, is assumed, and the diameter of the circle may be
D.sub.0. Otherwise, when the light emitting section is configured
with four or more light emitting elements, and the light emitting
elements are not disposed on a straight line, a circle, which
connects the centers of three light emitting elements positioned on
the outermost side in the light emitting section, is assumed, and
the diameter of the circle may be D.sub.0.
The modification example of the display device according to the
first example shown in FIGS. 1A and 1B is shown in FIGS. 17A and
17B, the modification example of the display device according to
the second example shown in FIGS. 3A and 3B is shown in FIGS. 18A
and 18B. In the modification examples, a single light emitting
section is configured with a single light emitting element. Also,
it is possible to apply such a configuration to the third to eight
examples.
Further, in the examples, the centers of the respective light
emitting elements 20R, 20G, and 20B are arranged on the
circumference of a circle, but the arrangement of the respective
light emitting elements 20R, 20G, and 20B is not limited thereto.
For example, the modification example of the arrangement of the
respective light emitting elements 20R, 20G, and 20B in the display
device according to the first example is shown in FIG. 19, and the
modification examples of the arrangement of the respective light
emitting elements 20R, 20G, and 20B in the display device according
to the second example are shown in FIGS. 20 and 21. Also, in FIG.
21, the planar shape of the second light transmission section 35 is
a rectangle. In the modification examples, the centers of the
respective light emitting elements 20R, 20G, and 20B are arranged
in a straight line. Further, in the cases, a circle, which includes
all the light emitting elements, is assumed, and the diameter of
the circle may be D.sub.0. Otherwise, a line segment, which
connects the centers of two light emitting elements 20G and 20B
positioned on the outermost side, is assumed, and the diameter of
the circle whose diameter is the line segment may be D.sub.0.
When the display device operates, that is, when the light emitting
section operates (when the light emitting section is turned on),
images which cancel patterns may be overlapped with each other.
When some processes are not performed, the brightness of a display
image in the light emitting section and brightness which
accompanies with the patterns are recognized, and an image in which
patterns are overlapped is recognized. Here, when an image from
which brightness corresponding to the brightness of patterns (for
convenience, referred to as "brightness after signal processing")
is subtracted from an original display image is displayed, that is,
when a signal corresponding to the brightness of a pattern is
subtracted from a signal used to display the original display
image, (brightness of original image display)+(brightness
accompanying with pattern)-(brightness after signal
processing)=(brightness of original image display). Therefore, when
the light emitting section operates (when the light emitting
section is turned on), it is possible to cancel patterns. It is
possible to perform such a signal processing based on an existing
signal processing, and it is possible to use an existing signal
processing circuit as a signal processing circuit. Also, actually,
there is a case in which brightness accompanying with patterns
differs depending on illumination or light from outside. Therefore,
when the brightness of the patterns is subtracted from the original
display image, there is a case in which it is necessary to multiply
a coefficient which depends on an environment in which the display
device is installed, by "brightness acquired after processing".
Also, the present disclosure can include structures as below.
[A01] Display Device
First Embodiment
A display device including: a first substrate that includes a first
surface and a second surface which faces the first surface; a
second substrate that is arranged to face the first substrate, and
that is configured with a first surface which faces the second
surface of the first substrate, and a second surface which faces
the first surface; and a plurality of light emitting sections that
is provided on the second surface of the first substrate while
being separated from the second substrate. A light transmission
suppression layer on which a light transmission section to transmit
light from light emitting sections is provided is formed on the
second surface of the second substrate in correspondence to each
light emitting section, and an anti-reflection layer is formed in
the light transmission section.
[A02] In the display device of [A01], the light transmission
suppression layer includes an anti-reflection function.
[A03] In the display device of [A01] or [A02], the light
transmission suppression layer includes specular reflectance at the
same level as the specular reflectance of the anti-reflection
layer.
[A04] In the display device of any one of [A01] to [A03], the
anti-reflection layer extends between the light transmission
suppression layer and the second surface of the second
substrate.
[A05] In the display device of any one of [A01] to [A03], the
anti-reflection layer covers the light transmission suppression
layer.
[A06] In the display device of [A01], patterns are attached to the
light transmission suppression layer.
[A07] In the display device of [A06], a pattern formation pitch is
an integer multiple, an equivalent multiple, or an integer fraction
of a light emitting section arrangement pitch.
[A08] In the display device of any one of [A01] to [A07], a
thickness of the light transmission suppression layer becomes thin
as being close to the light transmission section.
[A09] In the display device of any one of [A01] to [A08], when it
is assumed that an external shape of the light transmission section
is a circle which has a diameter D.sub.1, that the light emitting
section is a circle which has a diameter D.sub.0, that a distance
from a top face of the light emitting section to the light
transmission section is L.sub.1, and that an average refractive
index of a light path from the light emitting section to the light
transmission suppression layer provided with the light transmission
section is n.sub.1,
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied.
[A10] In the display device of [A09], the center of the light
emitting section and the center of the light transmission section
are on the same axis line.
[A11] In the display device of any one of [A01] to [A10], a light
non-transmission section layer, provided with a second light
transmission section which transmits light from the light emitting
section, is formed on the first surface side of the second
substrate in correspondence to each light emitting section, and an
area of the second light transmission section is smaller than an
area of the light transmission section.
[A12] In the display device of [A11], when it is assumed that an
external shape of the second light transmission section is a circle
which has a diameter D.sub.2, that the light emitting section is a
circle which has a diameter D.sub.0, that a distance from a top
face of the light emitting section to the second light transmission
section is L.sub.2, and that an average refractive index of a light
path from the light emitting section to the non-transmission
section layer provided with the second light transmission section
is n.sub.2,
tan(sin.sup.-1(1/n.sub.2)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied.
[A13] In the display device of [A12], the center of the light
emitting section, the center of the light transmission section and
the center of the second light transmission section are on the same
axis line, and the light transmission section has a figure which is
similar to the figure of the second light transmission section.
[B01] Display Device
Second Embodiment
A display device including: a first substrate that includes a first
surface and a second surface which faces the first surface; a
second substrate that is arranged to face the first substrate, and
that is configured with a first surface which faces the second
surface of the first substrate, and a second surface which faces
the first surface; and a plurality of light emitting sections that
is provided on the second surface of the first substrate while
being separated from the second substrate. A light transmission
suppression layer, provided with a first light transmission section
which transmits light from light emitting sections, is formed on
the second surface of the second substrate in correspondence to
each light emitting section, and a light non-transmission section
layer, provided with a second light transmission section which
transmits light from the light emitting section, is formed on the
first surface side of the second substrate, and an area of the
second light transmission section is smaller than an area of the
first transmission section.
[B02] In the display device of [B01], the light transmission
suppression layer includes an anti-reflection function.
[B03] In the display device of [B01], patterns are attached to the
light transmission suppression layer.
[B04] In the display device of [B03], a pattern formation pitch is
an integer multiple, an equivalent multiple, or an integer fraction
of a light emitting, section arrangement pitch.
[B05] In the display device of any one of [B01] to [B04], a
thickness of the light transmission suppression layer becomes thin
as being close to the first light transmission section.
[B06] In the display device of any one of [B01] to [B05], when it
is assumed that an external shape of the first light transmission
section is a circle which has a diameter D.sub.1, that, the light
emitting section is a circle which has a diameter D.sub.0, that a
distance from a top face of the light emitting section to the first
light transmission section is L.sub.1, and that an average
refractive index of a light path from the light emitting section to
the light transmission suppression layer provided with the light
transmission section is n.sub.1,
tan(sin.sup.-1(1/n.sub.1)).ltoreq.(D.sub.1-D.sub.0)/(2L.sub.1).ltoreq.2
is satisfied.
[B07] In the display device of [B06], when it is assumed that an
external shape of the second light transmission section is a circle
which has a diameter D.sub.2, that the light emitting section is a
circle which has a diameter D.sub.0, that a distance from a top
face of the light emitting section to the second light transmission
section is L.sub.2, and that an average refractive index of a light
path from the light emitting section to the light non-transmission
section layer provided with the second light transmission section
is n.sub.2,
tan(sin.sup.-1(1/n.sub.2)).ltoreq.(D.sub.2-D.sub.0)/(2L.sub.2).ltoreq.2
is satisfied.
[B08] In the display device of [B06] or [B07], the center of the
light emitting section, the center of the first light transmission
section and the center of the second light transmission section are
on the same axis line, and the first light transmission section has
a figure which is similar to the figure of the second light
transmission section.
[B09] A display device including: a first substrate that includes a
first surface and a second surface which faces the first surface; a
second substrate that is arranged to face the first substrate, and
that is configured with a first surface which faces the second
surface of the first substrate, and a second surface which faces
the first surface; and a plurality of light emitting sections that
is provided on the second surface of the first substrate while
being separated from the second substrate. A pattern display device
is arranged on the second surface or the first surface side of the
second substrate side, and patterns are displayed on the pattern
display device.
[B10] In the display device of [B09], the pattern display device
includes an electronic paper or a transparent liquid crystal
display device.
[B11] In the display device of [B09] or [B10], an image is not
displayed in the light emitting section when patterns are displayed
on the pattern display device, and patterns are not displayed on
the patter display device when an image is displayed in the light
emitting section.
[B12] A display device including: a first substrate that includes a
first surface and a second surface which faces the first surface; a
second substrate that is arranged to face the first substrate, and
that is configured with a first surface which faces the second
surface of the first substrate, and a second surface which faces
the first surface; and a plurality of light emitting sections that
is provided on the second surface of the first substrate while
being separated from the second substrate. Patterns are formed on
the first surface side of the second substrate.
[B13] In the display device of [B12], the patterns are expressed by
irregularities of a layer which is positioned at the bottom of the
first surface of the second substrate.
[C01] In the display device of any one of [A01] to [B13], the light
emitting section includes a light emitting diode.
[C02] In the display device of any one of [A01] to [B13], each of
the light emitting sections is configured with a plurality of the
light emitting diodes which are arranged in a straight line.
[C03] A tiling-type display device in which a plurality of display
devices of any one of [A01] to [C02] is arranged.
[C04] In the tiling-type display device of [C03] in which different
colors or patterns are provided for respective tiles.
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.
* * * * *